Records of the Museums and Art Galleries of the Northern Territory Volume 25 December 2009 The Beagle, Records of the Museums and Art Galleries of the Northern Territory (formerly ‘Records of the Northern Territory Museum of Arts and Sciences') EDITORIAL COMMITTEE Richard C. Willan Editor Christopher J. Glasby Philip Short The Beagle is a refereed journal published by the Museums and Art Galleries of the Northern Territory to disseminate the results of research in the following areas: Systematic and other studies of the terrestrial, marine and freshwater flora and fauna of the Northern Territory, tropical Australia, Southeast Asia and the Indo-Pacific; Australian Aboriginal, Southeast Asian and Oceanic art, material culture and archaeology; Northern Territory and Oceanic history and archaeology. The Beagle is published once or twice a year, depending upon the material available. All contributions to The Beagle are reviewed by two referees and, where possible, at least one is internationally-based. Whilst articles for The Beagle will normally be 10-50 pages in length, shorter communications, notes and review articles may also be acceptable. Longer articles, significant works or substantial revisions, which form integral studies, may be considered for separate publication as a Supplement. Prospective authors should contact the Editor, Academic Publications. The Beagle may be obtained by subscription or by exchange. The subscription rate for one year for individuals and institutions is $66.00 (includes postage and GST). All orders, subscriptions, back numbers and exchange enquiries should be addressed to the Library Manager, Museum and Art Gallery of the Northern Territory, GPO Box 4646, Darwin NT 0801, AUSTRALIA, or e-mail library.dam@nt.gov.au AUTHOR’S OFFPRINTS Twenty-five offprints are provided free for each published paper. Additional offprints may be ordered when returning proofs. SUBMISSION OF MANUSCRIPTS A Guide to Authors is provided on the inside back cover of each volume. Contributions should be posted or e-mailed to: The Editor, Academic Publications Museum and Art Gallerv of the Northern Territory GPO Box 4646, Darwin NT0801, AUSTRALIA E-mail: richard. willan@nt.gov. au ISSN 1833-7511 © Museums and Art Galleries of the Northern Territory, 2009. Printed by the Government Printing Office of the Northern Territory DARWIN200 MUSEUM AND ART GALLERY NORTHERN TERRITORY fiX Vir Northern Territory Government Front cover: In proposing his theory of evolution, Charles Darwin (1809-1882) caused a major shift in the way humans view the world. T year 2009 marks the 200th anniversary of Darwin’s birth and the 150th anniversary of publication of his most influential work On the Orig of Species ... . His theory continues to spark debate (see pages 1-5). This photograph, taken by Elliott and Fry, is one of the last to be taken Charles Darwin. Photograph reproduced, with permission, from: Berra, T. 2009. Charles Darwin: the concise story of an extraordinary ma John Hopkins University Press: Baltimore. Records of the Museums and Art Galleries of the Northern Territory Volume 25, December 2009 CONTENTS Charles Darwin: Shaping Our Science, Society and Future - Abstracts of Presentations.1 BARRKMAN, J. - The role of textiles in the royal funeral of Ain Le’u, Biboki, West Timor, Indonesia.7 ALVAREZ, B. and HOOPER, J.N.A - Taxonomic revision of the order Halichondrida (Porifera: Demospongiae) from northern Australia. Family Axinellidae.17 GORDON, D.P. - Baudina gen. nov., constituting the first record of Pasytheidae from Australia, and Sinoflustridae fam. nov., with a checklist of Bryozoa and Pterobranchia from Beagle Gulf.43 GLASBY, C.J. and AGUADO, M.T.-A new species and new records of the anthozoan commensal genus Alcyonosyllis (Polychaeta: Syllidae: Syllinae).55 LOWRY, J.K and SPR1NGTHORPE, R.T. - The genus Floresorchestia (Amphipoda: Talitridae) in tropical Australia.65 BROWN, G. - Description of two new pseudaposematic species with a review of defensive adaptations in the subfamily Thynninae (Hymenoptera: Thynnidae).71 WATSON, C. - A new species of Clavisyllis Knox, 1957 (Polychaeta: Syllidae): a genus with the unusual distribution of New Zealand and the Great Barrier Reef, northern Queensland, Australia.79 WILLAN, R.C., KOHLER, F., KESSNER, V. and BRABY, M.F. - Description of four new species of limestone-associated Torresitrachia land snails (Mollusca: Pulmonata: Camaenidae) from the Katherine District of the Northern Territory, Australia, with comments on their conservation.87 REID, A. - Sepioloidea magna sp. nov.: a new bottletail squid (Cephalopoda : Sepiadariidae) from northern Australia.103 McKAY, J.L., GRIFFITHS, A.D. and CRASE, B. - Distribution and habitat use by Hemidactylus frenatus Dumeril and Bibron (Gekkonidae) in the Northern Territory, Australia.111 Short communications BOURKE, P.M and R.C. WILLAN -Anadara granosa (Mollusca: Bivalvia: Arcidae) discovered live in Darwin Harbour, with implications for understanding climate change in northern Australia.117 BRABY, M.F. - Rectification of the type status for Philiris ziska titeus D’Abrera, 1971 (Lepidoptera: Lycaenidae).121 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25: 1-5 Charles Darwin: Shaping our Science, Society and Future ABSTRACTS OF PRESENTATIONS Since 2009 marks the 200th anniversary of the birth of Charles Darwin and the 150th anniversary of his most seminal work on evolutionary biology On the Origin of Species ... , the Northern Territory Government and Charles Darwin University sponsored a free public symposium held in the city of Darwin between 22 and 24 September to honour the life and achievements of this extraordinary man. His legacy has extended beyond biology and into the humanities and social sciences. This symposium presented opportunities to appreciate and debate Darwin’s findings and his legacy. The symposium was organised under the Northern Territory Government and Charles Darwin University Partnership Agreement and arranged by a Steering Committee headed by Dr Richard Willan and Professor Robert Wasson representing the Government and the University, respectively. Following a Welcome Reception at Parliament House hosted by the Chief Minister, The Honourable Paul Henderson MLA, delegates moved to the Darwin Convention Centre to hear a presentation on the life of Charles Darwin. The Symposium itself was divided into three themes across the next two days. National and international speakers reflected on the impact of Charles Darwin on their research in biology, medicine and history. The first theme was entitled ‘Brave new world: what is Darwin’s legacy in the era of modem medicine, biotechnology and technology-based societies?’ The second theme was entitled ‘Understanding the controversy between Darwinian science and religion’. The third theme was entitled ‘Social Darwinism and indigenous nations: the origin of socio-political policy’. The titles of the presentations by the keynote speakers and their abstracts arc as follows. Charles Darwin: the concise history of an extraordinary man TIM M. BERRA Department of Evolution, Ecology’ and Organismal Biology, The Ohio State University’, Mansfield, Ohio 44906, USA; and Research Associate, Museum and Art Gallery Northern Territory, GPO Box 4646, Darwin, NT0801, AUSTRALIA berra. I@osu.edu Charles Darwin is often considered the most influential scientist who ever lived because the theory of evolution is one of the most powerful ideas in science and may well be the greatest idea ever had by the human mind. 2009 is the 200th anniversary of Darwin’s birth and the 150th anniversary of the publication of On the Origin of Species ... . His message of descent with modification through natural selection presented in 1859 in The Origin precipitated a paradigm shift - the replacement of one world view by another. Darwin changed the way humans view their place in nature. He showed that humans were not above nature, but part of it. He supplied an explanation for the great diversity of life and showed that all life, including human, is related by descent from a common ancestor. No other biologist has had an impact of this magnitude. In the words of the eminent geneticist Theodosius Dobzhansky: “Nothing in biology makes sense except in the light of evolution”. The paradigm shift from creation to evolution has allowed a staggering array of advances in knowledge. Darwin was bom into a wealthy English family on 12 February 1809. He was educated at Edinburgh and Cambridge Universities and graduated 10th in his class of 178 at Cambridge in 1831. He was offered the unpaid position as naturalist- companion to Captain FitzRoy on the second voyage of H.M.S. Beagle from 1831-1836 on a surveying mission around South America. I fe considered this experience the first real education of his mind. The geology and biodiversity he experienced in rainforests, the pampas, the Andes, the Galapagos Islands, and on coral reefs influenced his thinking and the history of science. Darwin sent back 1529 species bottled in alcohol and 3907 dried specimens. Darwin (1837) drew the first evolutionary tree to show the relatcdness of all animal life. He explained how coral reefs fonn (1842) and contributed to geological observations on earth movements (1844) and the deformation theory of metamorphic rock (1846). He described all known barnacle species, fossil and living (1851-1854). Darwin explained how orchids are fertilised by insects (1862) and how plants climb (1865). He introduced the “control” in “controlled experiment” and he catalogued the bewildering variation in domestic plants and animals (1868). He explained human origins and sexual selection in ways never before articulated (1870-1871), and discussed human and animal emotions in similar terms (1872). The latter work was one of the first books to use photographs to illustrate a point. Darwin showed how insectivorous plants growing on impoverished soils utilise nitrogen-rich insects (1875), and he demonstrated that the offspring of cross- fertilised plants were more numerous and vigorous than self-fertilised ones (1876, 1877). His observations of climbing plants laid the foundation for the field of plant growth hormones (1880), and his work on earthworms (1881) is a classic study in ecology. Any one of these achievements could constitute a life’s work for most scientists. Evolutionary biology - the tree of life as a framework for comparative biology KEITH A. CRANDALL Department of Biology, Brigham Young University, Provo, Utah 94602, USA keith_crandall@byu. edit Evolutionary biology has undergone a renaissance of phylogenetic thinking and associated methods. While the phylogenetic concept has been around since Charles Darwin, only recently has the field of phylogenetics developed into a rigorous research endeavour. In this talk, I develop the idea of articulating evolutionary histories through the estimation ofphylogeny, motivate the study of the Tree of Life, and provide examples of how this knowledge of evolutionary relationships provides a powerful tool to study a wide variety of questions in biology. I provide examples of the application of phylogenetic questions to organismal biology (Crustacea), medicine (infectious diseases including HIV) and conservation biology. Co-evolution of infection and immunity PETER C. DOHERTY Department of Microbiology and Immunology, University of Melbourne, Victoria 3010, AUSTRALIA; and Department of Immunology, St Jude s Children s Research Hospital, Memphis, Tennessee, USA trispoli@unimelb.edu.au Infection shows us evolution at work in our day-to-day world. The overall pace of genetic adaption for slowly-reproducing, multi-cellular, multi-organ systems like us is glacial when compared with the rate of change possible for the plethora of unicellular (bacteria, protozoa) or sub-ccllular (viruses) organisms that seek to survive and multiply on our body surfaces (skin, mucosa) or within our tissues. As a consequence, vertebrates have evolved a very complex, broad-spectrum immune defence system to combat this process of parasitism. Conceptually, immunity is comprised of two distinct, but interactive components. Innate immunity provides a set of‘first response’ mechanisms, some of which (like phagocytosis) go back to the very beginnings of biology. Elements of the slower-developing, but more targeted adaptive immune response are first seen in the lampreys and the jawed fish from 350-450 million years ago. Though birds and mammals share the basic characteristics of adaptive immunity, like specific ‘killer’ T cell and antibody-mediated effector function and memory, there has been considerable divergence through phylogenetic time in the way that the various elements arc organized. When it comes to RNA viruses, we can see the interface between the selective pressures imposed by immunity and rapid molecular evolution operating at first hand, either on a population basis (influenza) or within the infected individual (HIV). Other one-host DNA viruses like the Herpesviruses and Poxviruses provide us with examples of long-term convergence as individual members of these virus groups have evolved much the same mechanisms to temper the consequences of immune control in the various species that they infect. In general, the fact that we can suffer autoimmune diseases makes it clear that immunity is an evolved rather than a designed system, with all the inherent compromises that are inevitable as species build on pre-existing mechanisms to adapt through time. Drilling for Darwin: Rescuing the science of evolution from beneath layers of controversy MARTINEZ J. HEWLETT University of Arizona, Tuscon, Arizona, USA; and Dominican School of Philosophy, Graduate Theological Union, Berkeley, California, USA hewlett@u. arizona. edu “My Dear Darwin ... I finished your book yesterday.” With these words Thomas Huxley began his November 1859 letter to Charles Darwin that would presage a series of reactions to On the Origin of Species ... . Darwin’s bold model for the diversity of life that we see on Earth was indeed groundbreaking science. However, reactions to this new view were immediate and varied. Huxley ultimately saw this as an argument against the Church of England and the entrenched position of the clerics. Herbert Spencer, who coined the phrase “survival of the fittest”, applied the evolutionary model to social, political, and economic systems. Darwin’s cousin, Francis Galton, argued for steps to control the breeding of the human population in order to force the selection of certain traits, establishing the field of eugenics. 2 Abstracts of Presentations at the Charles Darwin 2009 Symposium On the other side of the discussion, religious commentators were also reacting. Those who held to a literalist interpretation of Genesis were quick to argue against the implications of Darwin’s proposal. Others, who were more in the mould of St. Augustine in their approach to scripture, could accept the scientific implications but were less convinced of the social and theological interpretations. In any case, it was clear that the science of biological evolution was quickly being buried beneath strata of controversial and decidedly non-scientific interpretative schemes. This situation has continued until the present. We witness what the press calls the “evolution wars” being waged between the new militant atheists and the creationists and intelligent design advocates, each flying banners emblazoned with Darwinian, or anti-Darwinian slogans. And yet the science of evolution, especially when coupled with Mendel’s understanding of inheritance, has become the central paradigm of biology, leading us to an expanded understanding of how the living world functions. All of these positions arc scientifically and philosophically flawed. Creationism and intelligent design are not scientific and also not theologically sound. The neo-atheist position may have philosophical positions, but these conclusions are not directly related to or provable by the science of evolution. I propose a different approach. Theistic evolution is the broad and peaceful middle ground between these factions. In this view, the science of evolution is championed as the most reasonable explanation for the observed data, and the model that has been most fruitful in opening new avenues of investigation. However, the theological, philosophical, and social arguments are pried away from the scientific framework. For a theistic evolutionist, a belief in God is not in opposition to the science of evolution. While an atheist may disagree with this, the science of evolution does not justify that disagreement. Darwin and the ascent of emotionally modern man: how humans became such other-regarding apes SARAH B. HRDY University of California - Davis, One Shields Avenue, Davis, California 95616, USA sbh@citrona.com As proposed by Charles Darwin, humans are remarkably similar to other apes. Like their larger brained, bipedal ‘cousins’, Great Apes also use tools and exhibit a rudimentary understanding of causality and Theory of Mind. However, other apes fall short of humans in intention-reading and co-operation. In this lecture I explain why I am convinced that the psychological and emotional underpinnings for apes to care so much about what others intend and feel emerged as a by product of shared parental and alloparental care and provisioning of young, what sociobiologists refer to as ‘co-operative breeding’. According to widely accepted chronology, large-brained, anatomically modem humans evolved around 150 000 years ago, and behaviourally modem humans, capable of symbolic thought and language, more recently still, between 50 000-80 000 years ago. But (I argue) emotionally modem humans, newly interested in the mental and subjective states of others and characterised by prosocial impulses to give and share, emerged far earlier along with what, for an ape, was a peculiar mode of rearing young. Indigenous epistemologies and social Darwinism LESTER-1RABINNA RIGNEY Yunggorendi First Nations Centre for Higher Education and Research, Flinders University, Adelaide, AUSTRALIA I ester. rigney@flinders. edu. au During Charles Darwin’s voyage in the South Pacific in the 1800s, the foundations of modem scientific research and its ontological and epistemological pillars were being set in history. The inclusion of Pacific Indigenous peoples within such history was always as an object of study and never the producer or the consumer of research. Modem science today and its investigative methods are not detached from the social and historical circumstances of its origin. This paper will argue that from across Darwin’s ‘imagined’ South Pacific, Indigenous researchers are forging a new intellectual agenda which I call Contemporary Critical Indigenous Scholarship. This agenda seeks new and robust ways to conduct research while revealing insights on the role the Indigenous intellectual. 3 Darwinism and the Victorian soul: the reception of Darwin’s theory of human evolution in the 19th century and beyond EDWARD J. LARSON LeConte Hall, University of Georgia, Athens, Georgia 30602, USA. edlarson@uga. edu In an 1871 cartoon in the British magazine Punch , an earnest young husband reads to his wife and infant child from Charles Darwin’s just-published book Descent of Man. “So you see, Mary, baby is descended from a hairy quadruped, with pointed ears and a tail,” he explains. “Wc all are." His wife counters: “Speak for yourself. Jack. I’m not descended from anything of the kind, I beg to say; and baby takes after me.” This was the general attitude toward the question of human evolution in much of English-speaking world at the time Descent of Man arrived, a question cast into the spotlight by British naturalist Charles Darwin. Although the general concept of organic evolution was quickly and widely accepted by British and American scientists and much of the educated public, the specific case of humans - or at least distinctly human characteristics - proved more problematic. From the time his On the Origin of Species ... was published in 1859, scientists and others on both sides of the Atlantic had hotly debated the proposition that humans evolved from animals even if they accepted evolutionism generally. Review the editorial cartoons, read the scientific commentary, and the basic sentiment toward the idea is almost always the same: Most people simply refused to believe their highly developed minds, morals or emotions evolved from those of beasts. In some ways, little has changed in the past century. Many otherwise committed evolutionists draw the line on materialism when it comes to the ascent of man. Oxford ornithologist David Lack, whose 1947 study of Darwin’s finches gave wing to the modem neo-Darwinian synthesis, believed: “Science has not accounted for morality, truth, beauty, individual responsibility or self-awareness, and many people hold that, from its nature, it can never do so.” The American geneticist Francis Collins, who directed the Human Genome Project and now heads the National Institutes of Health, wrote: “Science will certainly not shed any light on what it means to love someone, what it means to have a spiritual dimension to our existence, nor will it tell us much about the character of God.” His w'ords continue a debate that began in the Victorian Era. RNA as the engine of complexity: a new view of human evolution and genomic planning JOHN S. MATTICK Institute for Molecular Bioscience, University of Queensland, St Lucia, QLD 4067, AUSTRALIA j. mattick@uq.edu. au It appears that the genetic programming of humans and other complex organisms may have been misunderstood for the past 50 years, because of the assumption - largely true for prokaryotes, but not for multicellular eukaryotes - that most genetic information is transacted by proteins. The human genome comprises three billion base pairs of DNA sequence information. It programs the development of a precisely sculptured individual of about 100 trillion cells with hundreds of different muscles, bones and organs, as well as the brain. It contains about 20 000 conventional protein-coding genes, surprisingly about the same number and in large part with similar functions as those in tiny worms that have only 1000 cells. On the other hand, the extent of non-protein-coding DNA does increase with increasing complexity, reaching 98.8% in humans, suggesting that much of the information required to program human development may reside in these sequences. This is supported by the observation that regulatory information scales quadratically with function, indicating that as complexity increases a greater proportion of the genome is devoted to regulation and that prokaryotes were limited in their complexity by a protein-based system, a problem the eukaryotes solved as a prerequisite to the appearance of developmentally complex species in the Cambrian. Consistent with this proposition, recent studies have shown that the majority of the mammalian genome is transcribed, mainly into non-protein-coding RN As, and that there are tens of thousands of long and short RNAs in mammals that show specific expression patterns and subcellular locations, especially in the brain. There is increasing evidence that these RNAs control gene expression at many levels, and comprise a massive hidden regulatory network that directs the precise patterns of gene expression during growth and development. Indeed, RNA-dirccted regulatory circuits underpin most, if not all, complex genetic and epigenetic phenomena in eukaryotes. Moreover, the editing of RNA (which has expanded in the vertebrates and especially in the primates) appears to be the means by which environmental signals modify epigenetic 4 Abstracts of Presentations at the Charles Darwin 2009 Symposium information, especially in the brain, thereby comprising the molecular basis of learning and the evolution of cognition. Thus, rather than simply being a passive intermediate between DNA and protein, RNA may represent the computational engine of the cell, becoming become progressively more sophisticated in more complex organisms. Thus, what was dismissed as junk because it was not understood may hold the key to understanding human evolution, development and intelligence, as well as our physical and psychological idiosyncrasies and susceptibilities to common diseases. Finally, the observation that some RNA-directed epigenetic changes can be inherited raises the intriguing question: has evolution leamt how to learn? The then and now of Social Darwinism for Indigenous Australia: imagining a different future MAGGIE WALTER School of Sociology and Social Work, University of Tasmania, Private Bag 1, Hobart, TAS 7001, AUSTRALIA margaret. walter@utas. edu.au The bi-centenary of Charles Darwin’s birth could also mark the end story of Social Darwinism in Australia. But an alternative narrative of country and race requires a paradigm shift in which the evolutionary gaze is swung 180 degrees from the Indigene to the non-indigene: a re-imagining of non-Indigenous self-concept and belongingness. This paper develops this idea by juxtaposing eras of Darwinian influenced terrain: the 1830s and 1840s and the 1990s and 2000s with a different vision for the era 2010 onwards. In February 1836, when Darwin visited what was known to the Europeans as Van Diemen’s Land, he had no or little contact with Aboriginal people. By then the last traditional people were imprisoned and dying at Wybalenna. If we fast forward to 2009 and imagine Darwin revisiting, again his Aboriginal contact would likely be sparse. Except in commodified objects such as dot paintings, or as anthropological curiosity, the Indigenous is absent from the nation’s view of itself and Indigenous peoples remain locked in what I refer to as the domain of Aboriginality. Darwin’s work rationalised the Tasmanian destruction post event via the concepts of evolutionary inevitabilities and Social Darwinism and Darwin himself contributed by requesting Tasmanian skulls. In contemporary times the iterations and societal adaptations of these concepts still echo into Indigenous lives. The socio-cultural hierarchy replaced the Chain of Being, but the imprint of the latter is embedded in the shape and interpretation of the former. How can the post-2010 era be different? The paradigm shift I propose reverses the discourses of evolutionary inevitabilities with the pivotal re-imagining the narrative of non-Indigenous evolvement of interaction and relating to country, perceptions of Australia’s identity and conceptions of fit within the land and its heritage. Indigenous understandings and peoples are inevitably central to these imaginings. 5 -1 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25 : 7-16 The role of textiles in the royal funeral of Ain Le’u, Biboki, West Timor, Indonesia JOANNA BARRKMAN Museum and Art Gallery Northern Territory, Department of Natural Resources, Environment, The Arts and Sport, GPO Box 4646, Darwin, NT0801, AUSTRALIA joanna.barrlanan@nt.gov.au ABSTRACT This paper explores the role and cultural significance attributed to textiles in the mortuary practices of the Atoin Meto people of West Timor, Indonesia, and the use of textiles as markers of extraordinary events. It also considers forms of foreign influence on attire and cultural practices. The case study of the royal funeral of Ain Le’u, the wife of the customary ruler of Biboki, in Kaubele, North Biboki, in 2006 provided the lens through which to observe and document the employment of various types of textiles, including the handwoven warp ikat textiles that feature indigenous motifs, in Biboki mortuary practices. Keywords: Atoin Meto, textiles, Biboki, West Timor, mortuary practices. LANGUAGE KEY Bahasa Indonesia = (I) Latin = (L) Bai Keno / Uab Meto language = (BK) Tetun = (T) INTRODUCTION Ain Le’u, the much loved wile of the Kaiser of Biboki, died on 12 March 2006.' I’d had the pleasure of meeting Ain Le’u in 2004 in Kefamenanu and she was a most gracious and urbane woman. ‘Next time you’re in Timor, please come and visit us in Kaubele’, were her parting words to me. Little did I know that it would be her royal funeral on 17 and 18 March 2006 that finally took me to Kaubele village in north Biboki, North Central Timor (TTU), West Timor, where she had resided with her husband the Kaiser of Biboki, until the time of her death. As a participant at Ain Le’u’s funeral I was given permission to document her funeral and witness the proceedings that are recorded in this paper. I also had the opportunity to discuss aspects of the ceremonies I witnessed with prominent members of the Biboki community during and upon completion of the funeral. Kaubele has been the home of the Kaiser of Biboki 2 over several centuries, Biboki being one often princely states into which West Timor was divided in the late colonial period. 3 Kaubele’s northern, coastal location historically enabled the Kaiser to oversee trading arrangements between the largely inland Biboki Kingdom and foreign traders from Java, South Sulawesi and China who frequented Timor’s coast from as early as the 12th century (Gunn 1999: 52-53). European traders frequented the area from the 16th century onwards. Kaubele’s location near the coastal ports of Mena and Atapupu would have facilitated the Biboki Kingdom’s access to trade goods and luxury items in return for local produce of sandalwood, beeswax and human slaves. However, the cultural and ceremonial centre of Biboki Kingdom is located at Tamkesi, approximately 50 kilometres inland from Kaubele (Fig. 1). Tamkesi, often referred to as the ‘sacred heart of Biboki’, is built on a rocky outcrop high on a mountain with expansive views over the Biboki lands 4 . It consists of two hilltops linked by a ridge, representative of cosmic dualism which permeates the Atoin Meto world view 5 .Tamkesi continues to be the ritual centre of the Biboki realm, where cultural knowledge is upheld and preserved. The Kingdom’s sacred relics, le’u (BK), have customarily been stored at Tamkesi due to its inland location, which provided greater protection from intruders 5 . Fig. 1. Map of Timor indicating Biboki, Kaubele and Tamkesi. 7 J. Barrkman It was at the foot of Tamkesi, in the village Tautpah that Ain Le’u was bom in 1920 to parents of Atoin Meto and Chinese ancestry. In this region Chinese traders successfully intermarried with aristocratic families, thus strengthening trade relationships, routes and economic power. Ain Le’u, whose given name was Lidwina Us Boko, married the current Kaiser of Biboki, Tnesi Iba Us Boko, the customary leader of Biboki culture 7 . Ain Le’u was a mother of four children, a grandmother to eighteen grandchildren and a great-grandmother to eleven great-grand children. The widespread respect and affection inspired by this Biboki queen was enshrined in her name, Ain Le’u, which translates to ‘Sacred Mother’ 8 . CLOTH IN LIFE CYCLE RITUALS Observing and participating in Ain Le’u’s funeral provided insights into contemporary Atoin Meto mortuary and cultural practices. In particular, this occasion provided a lens through which to view the specific role and function that textiles perform in this major life cycle event 9 . Cloth is universally present at life cycle events in Timor and eastern Indonesia, where textiles have been widely regarded and documented as important elements of life cycle rituals, used as attire, banners, mats, hangings and shrouds (Gittinger 1979; Maxwell 2003). In addition to serving functional purposes, textiles also operate as markers that indicate something extraordinary is happening. As forms of exchange used by Timorese people and cultures they: ... signal and materialise the establishment, renewal and termination of relationships. Messages of ethnicity, sense of place, gender, age, social rank political legitimacy and community longevity are contained within textiles. They convey ancestral tradition cross generationally, using a language of fonn and aesthetic that is deeply imbedded in local cultural consciousness. They can also be important vehicles of magical power, cocooning and protecting both people and objects from physical and metaphysical ills (Leibrick 1994: 9). THE FUNERAL PREPARATIONS Upon news of Ain Le’u’s death and the announcement of the location of her funeral, people began travelling to Kaubele village. Ain Le’u’s funeral was the first royal burial to occur outside the sacred Biboki centre of Tamkesi. This decision marked a departure from local cultural tradition. This choice of venue, determined by Ain Le’u’s children, highlighted current shifts and tensions within Atoin Meto society between tradition, customary practices and modernity. The family made a public commitment at the funeral to conduct a secondary burial in the future at which time Ain Le’u’s remains will be relocated to Tamkesi 10 . Approximately 2500 people from across the Biboki Kingdom, both commoners, amat (BK), and aristocrats, usiJ'(BK), walked for over two days and nights to Kaubele village to attend Ain Le’u’s funeral, which was held on Friday 17 and Saturday 18 March 2006 at the Kaisers’s family house. Atoin Meto people from all the Biboki clans, along with representatives from the neighbouring Atoin Meto regions of Insana and Miamafo, attended her funeral. Delegations ofTetun people from Belu joined Savunese, Rotinese mourners, all of whom converged in Kaubele to pay homage and farewell Ain Le’u to the afterlife. The official commencement ofmouming was marked by the lighting of a fire outside the front of the Kaiser’s house. This fire known Ain No’no (BK), continued to bum from the time of death until the interment of the corpse, which marks the formal completion of the funeral ceremony. The slow burning kusambi wood, Schleichera oleosa (L), is used for the Ain No ’no fire. This wood features in Atoin Meto ceremonies ofbirth and death 11 . During and following birth it is burnt inside the house. At times of death the kusambi wood is burnt outside, locating this life cycle ritual within the Atoin Meto world view of binary opposition, in this instance expressed through the dichotomy of the inner and outer realms. The/1/7; No ’no fire’s purpose was to ‘heat’ the ceremony and to guard Ain Le’u on her journey to the afterlife. This is in keeping with the extraordinary, dangerous heated state induced by Ain Le'u’s death. Only once the funeral is completed can the ‘cool’ state, denoting safety and calm, return. Hence, the forming and lighting of the fire was a protective device, which was the specific responsibility of three Biboki clan groups, Naek Le’u, Subun and Tas Au 12 . Senior clan representatives were duty bound to guard the fire, day and night, until Ain Le’u’s body was finally interred. With the Ain No 'no fire lit three days before the funeral, people began to gather at the Kaiser’s family house. Upon arrival, mourners were greeted by the Kaiser who was inside the mourning room or near the Ai No 'no fire. The Kaiser wore his headscarf, pilu (BK), slanted to the right side, symbolic of his wife’s death and his state of mourning in the sphere of death. Following the conclusion of the ceremony, the peak of his pilu would be worn in a central position signifying his return to the sphere of life (Meta pers. comm. Kaubele, 17 March 2006). Such practices are consistent with mortuary practices described by Middlekoop (1963:26). The procession of mourners was invited to enter the front living room where Ain Le’u lay in state. As each new guest or group of guests 13 entered the room a metal gong, sene (BK), was struck by a male chief mourner. Each arrival was announced by seven strikes of the gong 14 . In keeping with Atoin Meto tradition, many men and women entered the mourning room by crawling in on their knees and wailing, litu (BK). While paying homage to Ain Le’u many women wore their hair loose as a sign of grief 5 . This practice is in direct contrast to the social expectation that respectable Atoin Meto women must tic up their hair in public 16 . The role of textiles in the royal funeral of Ain Le’u, Biboki, West Timor, Indonesia Fig. 2. A canopy of a man’s single warp ikat cloth wrap protects Ain Le’u’s coffin. Other woven textiles gifted by mourners are hung delineating the mortuary space. Fig. 4. Women enter the mortuary space bearing handwoven cloths in baskets as offerings to Ain Le’u’s family. Ain Le’u’s body lay in state inside the front room of the house, within an open wooden coffin 17 . The primary mortuary space was defined by the use of suspended white cotton curtains, which delineated the space around the coffin (Figs 2-4). However, at no time were these curtains drawn closed. Suspended above the coffin was a canopy, neoba (BK) (Fig. 2), consisting of a men’s cloth wraps, bed naek (BK). This cloth wrap, woven in the warp ikat technique, futus (BK), featured a bed klaut motif. This canopy served to delineate the sacred mortuary space while also physically protecting the corpse from dust and dirt (Philipus Manek pers. comm. Kaubele, 18 March 2006). Beneath the canopy the open coffin was draped with a white tulle cloth shroud with embroidered edges (Fig. 5). This transparent cloth was referred to as kain tele (BK) and featured an embroidered Christian crucifix in the centre field, denoting Ain Le’u’s adherence to the Christian faith. Ain Le’u’s corpse wore a hand woven tube skirt, tais feto (BK) (Fig. 6), which she had made prior to her death using commercially spun cotton and a combination of chemical and natural dyes 18 . It is likely that she made this tube skirt with the intention of wearing it as her burial attire as it is customary in Atoin Meto society for women of mature years to weave a special cloth intended for this purpose (Meta cited in Bennett 2005: 26). The mak ’aif motif is featured on the tube skirt worn by Ain Le’u. This motif depicts a series of hooks in a lozenge form (Fig. 6) and is ubiquitous in Biboki textiles. According to one interpretation, it represents the linked arms of dancers and is a metaphor for social harmony (Meta cited in Bennett 2005: 26). Ain Le’u had chosen to weave a mak'aif motif known as Put Mak’aif Hint featuring seven hooks. According to local conceptions the wearer’s social status is indicated by the number of mak ’az/included in the motif. In this instance the use of seven mak ’at/signified Ain Le’u’s high social position. A relationship exists between the mak 'aif motif woven into Ain Le’u’s tube skirt and the bed klaut motif woven into the warp ikat canopy cloth. These two motifs form a pair of complementary opposites, likened to a bow and arrow 19 (Yovita Meta pers. comm. Kefamenanu 2005). The use of this complementary pair of motifs and All photographs by Joanna Barrkman. Fig. 3. Handwoven textiles gifted by mounters are hung delineating the mortuary space. 9 J. Barrkman Fig. 5. Ain Le’u’s corpse covered with a tulle cloth decorated with a Christian crucifix. textiles supports the claim that clothing, in Southeast Asia is an important symbol of status for the dead, as well as the living, as a system of signals intended for supernatural beings (Maxwell 2003: 114). In addition to these indigenous motifs and paired cloths, other foreign influences were evident in Ain Le’u’s mortuary attire. Ain Le'u wore a pair of white gloves and a white lace blouse, kebaya (I). The kebaya is a traditional form of Malay women’s attire, commonly worn in Sumatra, Malacca and Java from the 19th century onwards. It is an adaptation of the baju panjang or long-sleeved blouse that is thought to have been introduced into the Malay archipelago by Arab traders, whose adherence to the Muslim faith prohibits women exposing their shoulders and upper arms. The kebaya became an accepted part of traditional Javanese attire and its influence extended to eastern Indonesia in the late 19th and early 20th century, where it has replaced the tradition of women wearing a tube skirt tied either beneath the armpits or waist, leaving the upper body exposed. The incorporation of the kebaya into eastern Indonesian cultures, such as the Atoin Meto, was advocated by Christian Dutch colonialists, who also embraced the kebaya as a form of attire. The kebaya, therefore became a symbol of status amongst Atoin Meto society, indicative of a cultured, modest woman of high status and Christian faith. Another consequence of Dutch influence evident in Ain Le’u’s funeral attire was her wearing a pair of white gloves. The Fig. 6. Ain Le’u's corpse attired with a tubeskirt featuring motif Mak’aif Huit, a white lace kebaya , gloves and head dress. Gifts of cloths and toiletries had been placed into her coffin. practice of wearing white gloves in Atoin Meto culture occurs at both weddings and funerals and is indicative of the formal nature of the occasion. In addition to this ceremonial attire, Ain Le’u wore a white cotton headband known as a lain pele (BK), adorned with numerous silver coins. Tain pele are only worn for death rites. This headdress exists in partnership with its counterpart Atoin Meto headdress, known as pet no 'o (BK), the traditional silver headdress worn during ceremonies by the living. A silver decorative hair comb, kiln none (BK), also made from smelted foreign coins, rested above Ain Le’u’s head. Dutch, Portuguese, Mexican and Indian silver alloy coins that had entered Timor during the Dutch and Portuguese colonial eras were sought by local silversmiths and forged into local body adornment (Rodgers 988: 31; Barrkman 2009: 35, 101-108). Ain Le’u also wore a necklace of Indian glass beads, molo (BK), silver bracelets, niti (BK) 20 and a rosary. Personal belongings such as eye glasses, a hand mirror, a pair of shoes, a makeup purse, a travel blanket, toothbrush and paste were also placed within Ain Lc’u’s coffin, as these were considered by her immediate family as necessities for her imminent journey to the afterlife. 10 The role of textiles in the royal funeral of Ain Le’u, Biboki, West Timor, Indonesia GIFT GIVING Mourners made offerings of customary gifts to Ain Le’u’s family including money, cloths (Fig. 3), rice, bracelets and animals (such as goats, pigs and cows). However, it was cloth that formed the primary exchange commodity to fulfil obligatory relationships between the mourners and the family of Kaiser and Ain Le’u. In some instances, the cloth offerings were chosen to be hung above the coffin. However, the majority of the gifted cloths were retained by the family to be counted and noted, so that in the future the same ‘value’ of gift can be reciprocated to the giver’s family as occasion determines. Ain Le'u’s family eventually divided the cloths amongst themselves, ensuring that each branch of the family had a suitable store of textiles to fulfil their future gift-giving obligations (Yovita Meta pers. comm. Kaubele, 18 March 2006). It is common in West Timor that gifts are given to indicate the prestige and wealth of the deceased and the powerful connections of the extended family (Coury 2004: 48). The use of textiles in funeral arrangements emphasises the social order of the living and the dead. In such cases textiles, considered a ‘female’ form of gift, are usually presented by one set of relatives and different types of ‘male’ grave goods, such as livestock, are presented by another set of relatives (Maxwell 2003: 114). From amongst the hundreds of cloths gifted to Ain Le’u and her family, specific tube skirts, taisfeto (BK), and men’s wraps, beti naek (BK), were chosen to be hung from the canopy surrounding her coffin (Figs 2 and 4). Other gifted textiles were selected by the family and placed inside Ain Le’u’s coffin, to accompany her to the afterlife. 21 Cloths selected for this purpose denoted specific clan alliances and relationships. One example of an intricate tube skirt with a motif from the Insana Kingdom was rolled up and strategically placed in Ain Le’u’s coffin (Fig. 6). This symbolised the relationship between the royal Us Boko clan of Biboki Kingdom and the royal Us Finit clan of Insana Kingdom. 22 Another tube skirt selected for inclusion in Ain Le’u’s coffin was a hand spun and naturally dyed tube skirt known as tais ha ma buna (BK), which featured the single warp ikat motif mak ’aifnim (BK) 2 -. It also featured three bands of motifs woven using the intricate discontinuous supplementary weft wrapping technique known as buna. This weaving technique is a significant marker of status on Atoin Meto women’s textiles. Three or more bands of buna motifs are only permitted to be worn by aristocratic women, who traditionally were the master weavers, having access to the requisite materials and time to execute the production of such complex textile techniques. The choice of this gifted tube skirt given to accompany Ain Lc’u to the afterlife was determined by the strong allegiance that exists between the Nahas clan of Sainup village and the royal Us Boko clan 24 . This relationship eventuated due to military support provided by the Nahas Fig. 7. Martha Ane wearing a peak metan, symbolic of her state of mourning. clan to the Kaiser of Biboki that resulted in the Nahas clan being bestowed with land and a marriage alliance with the royal Us Boko clan. However, before this magnificently woven tube skirt, produced by Belendina Kela of Sainuip village, could be placed into the coffin, Ain Le’u’s daughter was invited to cut into the edge of the buna decoration on the tube skirt. Using a small pair of scissors to perform this act, it ensured the cloth’s imperfection, thus making it an accurate reflection of the mundane, imperfect world of the living - in contrast to the perfect, ideal world of the ancestors, to which Ain Le’u was destined 25 . MOURNING ATTIRE AND CEREMONIAL PARAPHERNALIA Public displays of grief were evident in the attire worn by the mourners. As the elders of the clans gathered on 17 March 2006 to sing mourning song cycles known as Bain Nitu 26 and to dance the bone! boen nitu and naben dances throughout the night preceding the funeral, hundreds of the mourners wore a small black swatch of cloth pinned to their garments (Fig. 7). These black cloth swatches are known as pack metan (BK). This practice of wearing a black swatch of cloth occurs in both West Timor and Timor- Leste, suggesting it is derived from Catholic and European influence. While its origins arc likely to be found in Catholic practices, in Timor island both Protestants and Catholics J. Barrkman Fig. 8. Kaiser Us Boko with his children in mourning attire at Ain Le'u’s funeral. Fig. 9. Priests perform a Catholic Mass at Ain Le’u’s funeral service with robes adorned with Javanese batik cloth. alike wear pack metan. These public signs of mourning are worn for a minimum of forty days up to as long as ten years following the death of a family member. The Kaiser, as Ain Le’u’s chief mourner, was expected to wear his pack metan for a minimum period of five years (Yovita Meta pers. comm. Kaubclc, 18 March 2006). Upon the completion of the mourning period, the paek metan is either ceremonially released into a flowing river or else it is burnt 27 . As another sign of mourning, people wore plain ‘everyday’ clothes as opposed to their ceremonial tais or beti naek. Prohibitions during mounting, such as a taboo on wearing the colour red, with the exception of the chief mourners, were also respected. This is due to the association of red with celebration and power and as the traditional colour of rulers and the attire of meo, (BK), head-hunters. Ain Le’u’s Chinese ancestry was evident through the attire worn by the primary mourners, her four children. They wore white shirts with their traditional Biboki attire during Fig. 10. A woman is dressed in attire denoting Ain Le’u’s royal status enabling her to adopt the role of Ain Le’u’s living representative during the funeral ceremony. the formal funeral proceedings, upholding the Chinese custom of wearing white as a sign of purity and respect at funerals. On the morning of 18 March the formal funeral proceedings began. Several pigs were slaughtered with the intention of guarding Ain Le’u’s descendants against ill health and disaster. An indigenous mourning ceremony and a Catholic Requiem Mass officiated by three Atoin Meto priests occurred simultaneously. Several waq:> ikat textiles featuring Biboki motifs were chosen to form a backdrop to the pulpit where the priests delivered their sermon, providing another example of indigenous cloth being used to delineate sacred space. Beneath the pulpit, altar boys performed their incantations and burnt incense in front of both the priests and the ceremonial Ai No 'on fire, which continued to burn. The priests’ vestments included Javanese batik textiles (Fig. 9). Formerly considered as a foreign and ‘outside’ commodity, Javanese batik enjoyed prestige in Atoin Meto society over several centuries where its incorporation into local attire as men’s head scarves ,pilu (BK), or as women’s sarongs denoted exclusivity, status and privilege. In the contemporary era, the use of commercially printed batik cloth is commonplace and readily accessible to the wider population. In conjunction with the Mass, indigenous mortuary rites were performed. These rites were performed upon completion of the Mass, with no apparent disapproval from 12 The role of textiles in the royal funeral of Ain Le’u, Biboki, West Timor, Indonesia Fig. 11. A senior man holds katkili, a bundle of offerings of jewelry and money that were later carried in the funeral procession for Ain Le’u. the officiating priests. Prior to the commencement of the Mass, a woman appeared in the front of the gathering and publicly became dressed as a meo (BK), warrior (Fig. 10). This was a symbolic representation of Ain Le’u on the earth plane. She wore a headdress, tainpele (BK) 2S , made from a red cloth, and a set of seven sacred breast-discs, neon (BK), that earlier had been hung above Ain Lc’u’s coffin. These breast-discs were removed from the wall and placed around her neck, symbolic of her assuming a living form of Ain Le'u during the ceremony. She then proceeded to sit beside the Ai No 'on fire, as a representation of Ain Le’u, during the Mass and other proceedings. This phenomenon of women dressing in meo head¬ hunting attire traditionally occurs at life crisis rites 29 . The daughters of great head-hunters traditionally would wear meo attire and dance at their father’s funeral (Gittinger: 1979: 179). Upon return to society following a period of confinement of forty days after child bearing, traditionally the woman emerged wearing the meo attire ot her husband, indicating her warrior-like status achieved by surviving the life-threatening event of childbirth. This ceremony is known as ‘touching the ground’. As a symbol of fertility, the mother was adorned with ritual head-hunters’ regalia on the occasion of introducing her newborn child to the clan, ensuring continuance of the lineage. Women also wore head-hunters’ attire for the Ta Poen Olef ceremony, which requests the skills for life for newborn children 30 . In the instance of Ain Le’u’s funeral the physical ‘presence’ of Ain Le’u as a meo warrior affirmed the imminent and potentially dangerous journey awaiting Ain Le’u as she departed the mundane world and undertook to enter the world of her ancestors. She sat in the front of proceedings and oversaw the event. At her feet, a ritual known as Japan MofNes Nabala was perfonned by the senior representatives of the Biboki clans. This ceremony is synonymous with a sword and a sheath. The sheath was representative of Ain Le’u’s physical body, which was believed to be departing. The sword, representing her soul, was believed to be remaining. Initially, money was donated and collected in the presence of the ‘representative’Ain Le’u and then divided into two bundles known as huah maputu (BK). Bracelets were added to each bundle, before they were tied with cloth - one bundle with white cloth and the other with red cloth. These were then attached to either end of a stick along with two longer pieces of cloth similar to pennants, also white and red respectively. These pennants, katkiti (BK) (Fig. 11), were to be kept as a remembrance by the family. The white cloth was representative of Ain Le’u’s body and was referred to as the ‘toot’ of the stick. The red cloth represented her soul that was to remain, referred to as the ‘head’ of the stick. The katkiti were prepared by senior men from various clans in front of the representative Ain Le’u, who sat regally, adorned with the red head band, as opposed to the deceased Ain Le’u, who wore a white cloth head band (Fig. 6). PROCESSION, BURIAL AND PURIFICATION Once the katkiti was prepared, the family bade their final farewell to Ain Le’u and closed the coffin, which was then carried from the house to commence the procession to the graveyard 31 . Her coffin was draped with a hand woven beti naek , woven in the warp ikat technique, decorated with a Biboki motif. The white kain tele adorned with the crucifix (Fig. 5) was placed on top of this cloth. The procession carrying the coffin was led by Ain Le’u’s brother-in-law who carried the kakiti pennants and the buali maputu tied to the stick. Behind the coffin, mourners dressed in black with loose hair carried large baskets; bakul (BK) on their heads, filled with offerings of cloth that had been given to the family by mourners, signifying the respect and familial alliances offered to Ain Le’u and her descendants (Fig. 12). The procession proceeded through a guard of honour formed by the hundreds of mourners until it reached the compound border of the Us Boko residence. Here, in order to signify Ain Le’u’s final departure from her home, three gun shots were fired. This act was possibly an adaptation 13 J. Barrkman Fig. 12. Women carrying baskets of hand woven cloth as part of the funeral procession. This cloth had been gifted to Ain Le Vs family by mourners in recognition of clan alliances. of the tradition of burial in Tamkesi whereby the gong is struck and rings out advising the kingdom of the death of an aristocrat. Then a dog was strung and shot with the intention of ensuring that Ain Le'u would be accompanied by the dog’s soul on her journey from that point onward. Following this event, the chief mourners proceeded to the burial site where Ain Le’u was finally interred. The other mourners slowly returned to the house compound and gathered near the Ai No ’on fire for the completion of the proceedings for the ceremony that followed. The Kaiser’s younger brother was responsible for purifying all the mourners by splashing them with leaves dipped in water gathered from a sacred water source, oe le 'u (BK)? 2 For ceremonial purposes the water for the royal Us Boko clan is collected by a designated person of the Us Kenet clan, who must wear full ceremonial attire when collecting the water. Sacred water is not used at birth, but only at mortuary ceremonies. This enabled the mourners to leave the heated ceremonial state of the funeral ceremony and re-enter the cool state of everyday life and safely resume their journey homeward, avoiding otherwise anticipated danger such as being struck by lightning. Following the completion of the purification ceremony the Ai No 'on fire was extinguished using a grass, hum usu (BK), Imperata cylindrical (L)- 1 , as these leaves are considered to be the first natural element in creation. CONCLUSION It is evident from Ain Le’u’s funeral that cloth is used in a variety of contexts in funeral practices in Biboki. Intricate hand woven textiles are used to adorn the deceased and gifted to her with the intention of these finest cloths accompanying her to the afterlife. Her burial attire indicated her high status both through the motif and intricacy of her hand woven tube skirt as well as through the attire resulting from foreign Dutch and Javanese influence. In the instance of the mourners, their attire was tempered by indigenous or possibly Chinese protocol, which prohibited the wearing of red clothes. Pack inetan, a form of European influence, were worn to indicate the wearer’s state of mourning. Chinese protocols determined the use of white attire by the chief mourners, while batik cloth was featured on the priest’s vestments. Hand woven textiles were also gifted and consequently redistributed amongst the family of the deceased as a means of paying homage and reinforcing clan alliances. In the process of mourning, these gifted cloths were used to frame the sacred mortuary space, which was ultimately delineated by a pair of hand woven cloths featuring Biboki motifs (Fig. 2). This pair of cloths, identified as masculine and feminine, was a manifestation of the symbolic dualism that underpins Atoin Meto society. Other representations of this dualism were evident in the complementary opposites of the katiki, incorporating the red and white cloths representing the mundane world of the body and the afterlife into which Ain Le’u’s soul was being released, as evident in the mortuary practices described. Further dualism was evident in the headdresses worn by the deceased Ain Le’u and the living representation of her, adorned in meo attire. Again the duality of red and white cloth headbands indicated the counterparts of existence, life and death, physical and metaphysical. The final gesture of this adherence to complementary opposites, whether consciously done or not, was the placement of the white kain tele with the Christian crucifix embroidery over the hand woven warp ikat cloth featuring a Biboki motif on top of the coffin during the funeral procession. These shrouds physically illustrated the co-existence of the indigenous and Christian iconography and associated beliefs. Through the perspective of Ain Le’u’s funeral it has been possible to gain insights into the manner in which textiles uphold customary notions of dualism as well as embodying various cultural influences. Together, these beliefs and influences form a syncretic belief system, which is evident in the contemporary ceremonial practices of the indigenous, aristocratic clans of Biboki people. Furthermore, Ain Le’u’s funeral illustrates the dynamic nature of Atoin Meto culture, reminding us that the textile traditions of this culture are not static. By analysing the uses and symbolism attributed to the textiles used at Ain Le’u’s funeral, the continued significance of textiles in the formation and expression of Atoin Meto cultural identity, ceremonial practices and religious beliefs is asserted. 14 The role of textiles in the royal funeral of Ain Le’u, Biboki, West Timor, Indonesia ACKNOWLEDGEMENTS The author wishes to acknowledge her gratitude to Mrs Yovita Meta for the invitation to attend the funeral and to Tnesi Iba Us Boko and his family permission to document Ain Le’u’s funeral. Thanks are also extended to Mrs Yovita Meta, Mr Roy Hamilton and Mr James Bennett for their assistance and comments during the preparation of this paper. REFERENCES Barrkman, J. 2006. Symbols of power and life: Indian trade textiles and their inclusion into the ritual practices of headhunting and ceremonial houses of the Atoin Meto of West Timor. In Klienert, S. (ed.) Crossing cultures. Charles Darwin University: Darwin. Barrkman, J. 2007. Entwined: The Influence of Indian patola and trade cloths on the ritual practices and textile motifs of the Atoin Meto people of West Timor'. Unpublished MA thesis. Charles Darwin University: Darwin. Barrkman, J. 2009. Indian patola and trade cloth Influence on the textiles of the Atoin Meto People of West Timor. Archipel 77: 155-182. Barrkman, J. 2009. Husi bei ala Timor Sira nia liman - From the hands of our ancestors. Museum and Art Gallery Northern Territory: Darwin. Coury, W.G. 2004. Textiles of Insana, West Timor: women weaving and village development. White Lotus: Bangkok. Downs, R.E. 1977. Headhunting in Indonesia. In Structural anthropology in The Netherlands. Martinus Nijhoff: The Hague. Gittinger, M. 1979. Splendid symbol: textiles and tradition in Indonesia. The Textile Museum: Washington D.C. Gunn, G.C. 1999. Timor Loro Sae 500 years. Livros do Oriente: Macau. Leibrick, F, 1994. Binding culture into thread. Northern Territory University and Museum and Art Gallery Northern Territory: Darwin. Middlekoop, P. 1963. Headhunting in Timor and its historical implications. Pp. 260-423. In Oceanic Linguistic Monographs. University of Sydney: Sydney. Maxwell, R. 2003. Textiles of Southeast Asia: tradition, trade and transformation. Pcriplus: Hong Kong. Rodgers, S. 1988. Power and gold: jewellery from Indonesia, Malaysia, and the Philippines. (2nd edition). Prestel-Verlag: Germany. Schulte Nordholt, H.G. 1971. The political system of the Atoin of Timor. Martinus Nijhoff: The Hague. Accepted 21 October 2009 ENDNOTES 1. Ain Le’u was also widely known as Isteri Kaiser Biboki (I). ‘Kaiser’ was a term introduced into the region by Dutch colonisers. It replaced other terms such as Neon, Atupas (BK) and Raja (I). 2. The Kaiser of Biboki is known by several names including: Koko, Neno Anan, Paha Tuana, Hit Tua Ka (BK). 3. In addition to Biboki, the other kingdoms were Amarasi, Amfoang, Fateleu, Amanatun, Amanuban, Molo, Insana, Miamafo and Belu. 4. The origins of the Kingdom’s name and the location of Tamkesi are preserved in an ancient story. Some Atoin Meto people were travelling with a horse. This horse carried a boki (BK), a wooden stick balanced across its back for the transportation of goods. When the horse arrived at Tamkesi the boki balanced evenly across its back. This indicated to the people that this was a place of special power and so the name Biboki was given to the Kingdom and the site of Tamkesi was chosen as its sacred heart (Ibu M. Y. Meta pers. comm. November 2003, Kefamenanu), 5. The most eastern, male mountain is known as Bukit Tan Pah. The western, female mountain is known as Oepuah. Together they form pali-nifu (BK); land and water, considered to be a place of origin for Biboki people. 6. Located above Tautpah village to the west, arc a series of dwellings including ume le 'u of the Biboki Kingdom. It has the special name of panu (BK) as it is the sacred ceremonial house of Biboki. Nearby the panu is the Lopo Tain Lasi. 7. The Neno Biboki or Atupas is the sacral lord of the realm, and as such never leaves the navel centre. Neno Biboki can be translated to ‘He W'ho sleeps and eats’ (Schulte Nordholt 1971: 239-243) provides a detailed description of the ritual centre of Biboki. The current Neno Biboki is also known as Klemens Us Boko. 8. Ain Lc’u also refers to one who gives coolness and freshness to all she meets. 9. An invitation to attend the funeral was issued by Mrs Yovita Meta, Director of Yayasan Tafean Pah weaving co-operative. Permission to document the occasion w'as granted by Tnesi Iba Us Boko. 10. As part of the formal funeral proceedings a statement written by the four children of Ain Le’u was read explaining their preference for burying their mother in Kaubclc, in the first instance. Following a period of five years, it is their intention that her remains be relocated to Tamkesi. The practice of relocating human remains occurs in cases w'here people marry into other clans and consequently relocate to a new area. In such instances, the remains of deceased family members along with the objects they are buried with are dug up and then washed before being placed in a small wooden coffin. The sendees of a specially qualified person are required to perform these tasks and associated rites. This process occurs in a specially allocated place near the burial site. Once the remains are reburied at the new location, a special ceremony is undertaken by the family members in order to invite the spirit of the deceased to follow. 11. At birth, kusambi is burnt inside the house, beneath the mother’s birthing platform, and kept alight until she and baby emerge after approximately forty days of seclusion. At death, kusambi wood is burnt outside the house of the deceased. In both instances the purpose is to heat up the ceremonies and it serves as a protective agent; however, a comparison between the inner realm of life and the outer realm of death is also articulated by this ceremonial fire practice. 12. Naek Le’u clan (Mr Nikolas Bano), Subun clan (Mr Hendrikus Nesi) and Tas Au clan (Mr Tas Au). 13. Groups of guests included relations, neighbouring families, clans, villages, local officials and representatives of community associations, politicians, bureaucrats and school groups. 14. The number seven repeatedly appeared throughout the funeral ceremony including seven strikes of the sene; seven ceremonial breast plates, noen bena (BK), hung at the head of Ain Le’u’s coffin; seven strings of molo (molo are considered to be a friend with noen bena), seven ambulations of the dance, liqurai (BK). The significance of seven is attributed to a myth derived from Tamkesi, whereby seven hailstones fell from the sky, inspiring the textile single warp ikat textile motif known as son sien no ’o (motif showing the impressions of the hailstones on the land). In response to the dual nature of all things in Biboki, there also exists 15 J. Barrkman a motif known as san sene (depicting the seven hailstones). One motif represents the worldly, land based existence whilst the other represents the sky based, unseen, higher forces. This emphasises the notion of keeping seven and returning seven to the gods, i.e. seven for the Gods; seven for the earth/living. (Mr Philipus Manek pers. comm. Kaubcle village, Usat Nesi clan, speaker for the Kaiser on sacred matters Moin Le 'u/Atom Le 'u (BK). 15. Hair worn loose is also a custom practised in the nearby Belu region where people also avoid wearing jewellery and bathing until after the deceased has been buried. Also in Belu it is noted that men cannot cut their hair or wear head cloth, pilu (BK), during mourning (Yeager 2002: 50). 16. In neighbouring Timor-Leste women observe mourning by wearing a black head scarf, him (T), as a sign of mourning. 17. Traditionally coffins were made of wood from the gewang palm and kapok fibre. 18. Traditionally, it was the Kaiser’s wife who had the requisite time and access to materials to produce textiles of the highest quality. Furthermore, it was the Kaiser’s wife who had the position to introduce innovation in the textile arts, which were otherwise steadfastly guarded by clan protocols. 19. Bow and arrow is known as panah dan busu in Bahasa Indonesian. 20. Also known as nit none (BK), keke (T). 21. Various other gifts such as jewellery, notes and photos were also included. 22. Referred to as Us Boko mafut Us Finit, this textile illustrated and reinforced the relationship created by the Kaiser’s sister’s daughter having married into the royal Us Finit clan of Insana. 23. This tais ha ma buna was presented by Yayasan Tafean Pah weaving co-operative based in Biboki. Senior weavers from this organisation were present. Mrs Yuliana Nahas, of the Nahas clan from Sainuip village, South Biboki, presented the cloth on behalf of the co-operative. 24. One of the Nahas women married into the Us Boko clan, directly into the family of the Kaiser of Biboki. Such intermarriage was a result of a successful military campaign mounted by the Kaiser, which the Nahas clan supported. Recognising the support of the Nahas clan the Kaiser bestowed upon them land and a marriage allegiance was formed between the Usboko and Nahas clans. 25. The hand mirror placed inside the coffin had also been broken for this same purpose. 26. Alternatively a set of songs known as Boin Ma Mean, songs of happiness, are performed at celebratory occasions, such as Monet Tok Tan 'ni ceremonies when the newborn child’s placenta is buried. 27. In Timor-Leste it can be removed and placed at the burial site where it is simply left to disintegrate (Cecilia Assis pers. comm. 19 Dec 2007). 28. This style of headdress is also known as tefan (Coury 2004: 63). 29. Textiles, fertility and head-hunting were traditionally interrelated forming a symbolic triad, with the act of weaving being known as ‘the warpath of women’ (Howell 1912: 63 cited by Gittinger 1979:31-32). 30. These skills for life are known as Monet Tok Tan 'ni. For a boy child a knife, hoe, and besi kafa (BK) are the implements used in the ceremony asking that the son be endowed with fani benas na 'ik (BK), the ability to sharpen knives and axes, tua helna na ’oe (BK), the skill of cutting and milking the lontar palm and bae 'ka (BK), the skill of dancing and drumming. For a girl child ike. suti, keo (BK), represent the skill of weaving, kanot (BK), the skill of basketry and bae'ka (BK), the skills of dancing and drumming arc requested by the family. If she can master these arts she will be blessed with a good life (Barrkman 2007: 75-76). On this occasion the Bonet Pantun, a call and response chant is recited, which describes the beginning of the world. (Philipus Manek, Kaubele pers. comm. 18 March, 2006). 31. During funerals conducted at Tamkesi, a large pestle, esu (BK), used for pounding com, is wrapped with a woven shoulder cloth, bet ana (BK). In this way the esu is symbolic of a person being clothed. Otherwise it is like the deceased person remaining naked. The Naik Nahas, Hu Moin and Sikas clans are responsible for attending to the esu on these occasions. Usually during a death in the Usboko clan the pestle is wrapped at the time the Ai No ’no fire is lit. After burial of the corpse the Ai No ’no fire is extinguished and the bet ana removed from the pestle. 32. Each Biboki clan has two water sources - oe le ’u (BK), for sacred water and oe mata (BK), for daily use water. 33. This grass is known as along along (I) and is used for roofs on traditional domestic dwellings. 16 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25; 17-42 Taxonomic revision of the order Halichondrida (Porifera: Demospongiae) from northern Australia. Family Axinellidae BELINDA ALVAREZ 1 and JOHN N.A. HOOPER 2 'Museum and Art Gallery Northern Territory, GPO Box 4646, Darwin, NT 0801, AUSTRALIA belinda.glasby@nt.gov.au 2 Queensland Museum. PO Box 3300, South Brisbane, QLD 4101, AUSTRALIA johnh@qm.qld.gov.au ABSTRACT Nine species in five genera of the family Axinellidae, including three new species, Axinella loribellae sp. nov. A. sinoxea sp. nov. and Phakellia tropicalis sp. nov., are recorded for the tropical northern Australian waters of Western Australia, the Northern Territory and the Queensland coast as part of a revision of the order Halichondrida (Porifera; Demospongiae) in this region. One species, Dragmacidon durissimum (Dendy, 1905), generally found in the Indian Ocean, represents a new record for Australia. Taxonomic descriptions and discussion of those species arc presented here. The position of Reniochalina within the Axinellidae is also discussed based on new evidence found in this and other studies. Keywords: Sponge, Porifera, Halichondrida, Axinellidae, northern Australia, new species, taxonomy. INTRODUCTION The northern marine region of Australia, or the Northern Province as defined by the Interim Marine and Coastal Regionalisation of Australia (IMCRA, version 3.3, www.environment.gov.au/coasts/mpa/imcra/indcx. html) includes tropical waters off the Northern Territory (from the Admiralty Gulf in the west) and the Queensland coasts (western coast of Cape York to Torres Strait in the cast). The continental shelf of this area is generally shallow (less than 70 m) and extensive, reaching approximately 400 km in width in the Timor Sea and adjoining the coast of New Guinea in the Arafura Sea and Torres Strait (Bunt 1987; Ferns 1999). The area is part of the central Indo-West Pacific, which is well known for its high species-richness, high levels of endemism and is considered to be centre of origin of many tropical marine species (Veron 1995). Sponges are one of the most diverse and prevalent groups of marine invertebrates of northern Australia, but also one of the most poorly known in terms of proportions of known and new species, and levels of endemism. According to Hooper el al. (1997) the northern sponge fauna includes approximately 800 species, 60% of which remain undescribed. Further studies based on ‘presence-absence’ analyses of the diversity of tropical Australian sponges (Hooper et al. 2002) identified at least two ‘hot spots' of biodiversity for the northern area, one in the region of Darwin and Cobourg Peninsula and the other in the Wessel Islands region. Only 30% of the sponge species included in that biodiversity study could be assigned to a known taxon indicating that a great percentage of the fauna of that region is not well known. Taxonomic knowledge of northern Australian sponges is limited to a few studies. The first sponges collected from this area were described by Ridley (1884) and included 24 species, of which only 17 are currently recognised as valid species. Bergquist and Tizard (1967) later described 19 species from the rich intertidal area of Darwin Harbour. Since 1967, there have been 50 additional records to the fauna of northern Australia and only one revision of a particular group, i.e. the family Halichondriidae (Hooper et at. 1997 and references within ). Recent descriptions of some species have also been included in major taxonomic revisions of the demosponge families Raspailiidae (Hooper 1991) and Microcionidae (Hooper 1996). The order Halichondrida is presently represented in northern Australia by 41 nominal species (Hooper and Wiedenmayer 1994; Hooper et al. 1997), and a large number of specimens recently collected and deposited in the Museum and Art Gallery Northern Territory and the Queensland Museum (see abbreviations below). Data gathered from these collections clearly indicate that new species and records are represented in the area, and that species previously recorded also need to be revised using more sophisticated taxonomical tools. The Halichondrida is a group with an uncertain classification and definition. As with many other sponge groups, it is defined by traditional morphological characters, such as growth form, surface characteristics and skeletal features. But in the Halichondrida, however, these characters are extremely simple, polymorphic and few, and as a consequence the discrimination of taxa within this group is ambiguous. Halichondrid sponges have diverse growth forms (e.g. encrusting, massive, ramose, tubular, fiabellate). 17 B. Alvarez and J. N. A. Hooper The skeletons are plumoreticulate, dendritic or confused, constructed with three types of spicules (strongyles, styles and oxeas), or transitional forms, in any combination and not functionally localised. The order includes five families (Axinellidae, Dictyonellidae, Heteroxyidae, Halichondriidae and Bubaridae), and 45 genera, most of which remain poorly defined despite recent efforts to clarify and redefined the taxonomy of these families (Alvarez and Hooper 2002; Alvarez and Van Soest 2002; Hooper 2002a; Van Soest et al. 2002; Van Soest and Hooper 2002). Evidence from molecular studies (Alvarez et al. 2000) indicates also that some of the genera are not monophyletic. Moreover, species allocated to some genera (e.g. Axinella, Acanthella, Phakellia) have fuzzy boundaries and overlapping characters and include numerous forms (or varieties/morphs). Similarly, some allegedly widely distributed species may represent complexes of cryptic species hiding under morphotypes that span a continuum, and which cannot be resolved easily using morphometric data alone. The taxonomic confusion around the Halichondrida, has generated long-lasting debates at higher levels of sponge classification. Further studies using larger groups of species, revisions at the regional level and different kinds of genetic and chemical approaches have been recommended to refine the current concept of this taxon (Van Soest and Hooper 2002 ). The aim of this study is to revise the fauna of the Halichondrida from northern Australia and the status of all the nominal halichondrid species in this region. The present paper represents the first part of this revision and includes the family Axinellidae. Revision of the remaining families represented in the area (i.e. Dictyonellidae, Halichondriidae and Heteroxyidae) will follow in separate papers. MATERIALS AND METHODS This revision includes material of the family Axinellidae recorded for the tropical northern Australian waters of the Western Australia, Northern Territory and Queensland coast (from Admiralty Gulf in the west to Torres Strait in the east, approx, between the 125° E and 142° E meridians (Fig. 1). The area does not represent a tme biogeographical area and it was delimited based on the marine bioregions defined by 1MCRA. This area also corresponds with two of the ecoregions (i.e. Arafura Sea, Arnhem Coast to Gulf of Carpenteria) of the Sahul Shelf marine province as defined by Spalding et al. (2007). All specimens recorded for the selected area and registered under Axinellidae at the Queensland Museum and the Museum and Art Gallery Northern Territory sponge collections were examined and identifications were verified. Specimens and relevant type material from adjacent areas including western Australia, the Ashmore, Cartier and Hibernia reefs on the Sahul Shelf, Lesser Sunda Islands, Aru Islands, the south coast of Papua New Guinea and Great Fig. 1 . Study area included in this taxonomic revision. Barrier Reef were also examined if the species distribution was included in the studied area. Complete locality and collection data of material included in this revision is indicated under the species description as usual, whereas non type voucher material deposited at the Queensland Museum and the Museum and Art Gallery Northern Territory, is listed in Appendix 1. Specimens were prepared for light microscopy using the usual methods (e.g. Hooper 1996; Van Soest and Hooper 2005). Spicule measurements are in micrometres, based on 25 spicules (otherwise indicated in brackets), of each category and denoted as range (and mean ± 1 S.E.) of spicule length x spicule width. Measurements were made using a digital video camera attached to a light microscope in combination with the software V++ Precision Digital Imaging System v 4.0 (© Digital Optics Ltd). Scanning Electron Microscope photographs were taken in a JEOL JSM 5610LV. The higher systematic arrangement follows classification in the current version of World Porifera Database (Van Soest et al. 2008). Terminology used here follows Boury-Esnault and Riitzler (1997) and Alvarez and Hooper (2002). ABBREVIATIONS Abbreviations used in the paper are: AIMS, Australian Institute of Marine Sciences; BMNH, Natural History Museum, London (formerly British Museum Natural History); CRRF, Coral Reef Research Foundation, Palau; GBR, Great Barrier Reef, NTM, Museum and Art Gallery Northern Territory, Darwin, Australia (formerly Northern Territory Museum); MONZ, Museum of New Zealand; NTM, Museum and Art Gallery Northern Territory (formerly Northern Territory Museum), Darwin; SMF, Senckenberg Research Institute and Natural History Museum, Frankfurt; QLD, Queensland, Australia; QM, Queensland Museum, Brisbane; WA, Western Australia, 18 Axinellidae from northern Australia Australia; ZMA, Zoologisch Museum, University of Amsterdam, Amsterdam. Numbers prefixed with Q666C, OCDN, 0M9H are the cross-reference sample number collected for the United States National Cancer Institute, under the ‘Collection of shallow-water organisms’ program, by the Australian Institute of Marine Sciences, CRRF and NTM (subcontracted through CRRF), respectively. TAXONOMY Order Halichondrida Gray, 1867 Family Axinellidae Carter, 1875 Nine species of Axinellidae, listed below, were recorded within the studied area; three of these being new species. Axinella antensis (Hentschel, 1912) Axinelki loribellae sp. nov Axinella sinoxea sp. nov Cymbaslela stipitata (Bergquist and Tizard, 1967) Cymbastela vespertina Hooper and Bergquist, 1992 Dragmacidon australe (Bergquist, 1970) Dragmacidon durissimum (Dendy, 1905) Phakellia tropicalis sp. nov. Reniochalina stalagmitis Lendenfeld, 1888 Genus Axinella Schmidt, 1862 Gender feminine. Type species, by subsequent designation of De Laubenfels (1936), Axinella polypoides Schmidt, 1862. Recent, Adriatic Sea. Axinella antensis (Hentschel, 1912) (Figs 2 A-F, 3, 4, Table 1) Phakellia aruensis Hentschel, 1912: 420; Hooper el al. 1992 [in part]; Pulitzer-Finali 1993: 283. Axinella aruensis. - Hooper and Wiedenmayer 1994:72; Alvarez et al. 2000 [form II, see below]; Alvarez, Krishan and Gibb 2007[form II]; Holmes and Blanch 2007. Material examined. The material examined for this species is separated according to the moiphotypes described below. Holotype - SMF 953, E side, Aru I., Indonesia, 31 August 1908, coll. Merton, H.. Additional specimens - Laccpcdc Is, NW Shelf, WA: NTM Z.2284, Z.2304, Z.2331, Z.2345. Joseph Bonaparte Gulf: QM G301197, Cartier I.: QM G301092. Melville I. NT: NTM Z.615, Table 1. Comparison of spicule dimensions among specimens and varieties oi Axinella aruensis. Measurements in micrometres. Specimen Locality Oxeas Styles Axinella aruensis SMF 953 Aru Is. Indonesia 257.1-423.9(360.6138.1) 249.1-382.2 (313.6140.7) [12] x 13.8-21.4(16.511.9) x 14.1-21.7 (17.412.2) [12] Z.2304 Lacepedc Is, WA 245.5-337.6(285.4121) 213.2-271.4 (244.8120.9) [9] x 8.6-17.2 (1312.6) x 11.9-15.7 (13.511.6) [9] G301092 Cartier Is, WA 281.2-450.2 (360.7139.9) 242.8-419(301.1136) x 10.3 19.4 (15.612.2) x 12.6-20.3'( 16.811.9) Z.619 Melville I., NT 236.1-406(302.4139.4) 186-362.8 (267.2143.3) [22] x 9.3-17.5 (13.912.3) x 9.8-17.1 (14.111.9) [22] Z.3141 Parry Shoals, NT 267.1-372.9(307.1123.3) 248.6-294.6 (270.4118.8) [4] x 9.4-17.2 (13.612.3) x 11.1-16.7 (13.912.3) [4] Z.5053 Darwin Harbour, NT 297.6-498.6 (392.1147) 263.6-417.2(342.7137.6) x 7.3-22.5 (16.513.7) x 12-23.5(17.112.9) Z.4465 Wessel Is, NT 194.4-396.4 (299.5148.6) [24] 204.6-331.7 (269.7144.1) [15] x 5.6-17.4 (1213.3) x 8.6-18 (13.812.8) [15] Axinella aruensis form 1 Z.5816 Bynoe Harbour, NT 305-451.7 (376.7136.3) 283.1^106.6 (334.7140.7) [6] x 13.1-25.9 (18.313.9) x 14.7-19.6(16.511.8) [6] Z.3068 Parry Shoals, NT 187.1-318.2(237.2126.6) 167.2-222.5(200115.3) x 8.5-17.2 (13.212.4) x 9.3-15.5 (13.211.7) Z.5819 East Point, Darwin, NT 266.7-354.5 (312.1123.3) 200.1-353.2 (260.7134.1) x 13.1-18.8(16.311.4) x 10.3-22.8(15.412.9) Z.3946 Wessel Is, NT 274.8-392.8 (333132.8) 248.6-363.3 (297131) [10] x 8.346.4 (13.312.3) x 11.5-18 (15.112.3) [10] Axinella aruensis form II Z.4490 Stevens Rock, Darwin 209.1-278.6(246.3115.8) 163.6-231.4(191.1117.4) x 12.7-19.9(15.111.8) x 6.5-12.5 (9.811.6) Z.5054 Wessel Is 173.8-247.4 (214.7118.9) 166.4-262.3 (218.2122.4) x 7.5-16.7 (10.311.9) x 7.8-17.9 (13.912.4) 19 B. Alvarez and J. N. A. Hooper Fig. 2. Axinella cintensis: A, B, specimens at Raragala I., Wessel Is; C, specimen at South Shell I., Darwin Harbour; D, form I, Z.5816, Dawson Rock, Bynoe Harbour; E, form II, specimen at Raragala I, Wessel Is; F, Axinella sinoxea sp.nov., NTM Z.2719. Axinella loribellae sp. nov.; G, Holotype, NTM Z.4427; H, NTM Z.5662. Photos: A-B. P. Colin; C-D, G, B. Alvarez; E, D. DeMaria; F, J. Hooper; H, A. Ayling. 20 Axinellidae from northern Australia Z.619, Z.630, Z.632. Parry Shoals, Arafura sea, NT: QM G310136 (Q66C0514-X), NTM Z.3062 (Q66C87-0514-X), Z.3141 .Bynoe Harbour, NT: NTM Z.5071 (0M9H2464-U). Darwin Harbour, NT: NTM Z.5053 (0M9H2168-X), Z.5057 (0M9H2665-O), Z.5058 (0M9H2675-Y), Z.5072 (0M9H2579-U), Z.5830. Cobourg Peninsula, NT: NTM Z. 1363, Z. 1388, Z.2511, Z.2526, Z.2529. English Company Is., NT: NTM Z.3956. Wessel Is, Gove Peninsula, NT: QM G3.609 (Q66C4762-R), G300768 (=Q66C4737P, QM G311873 and NTM Z.3945), Z.3922 (Q66C4687-L), Z.3935 (=Q66C4785-R, QM G300752), Z.3936 (Q66C4831-R), Z.4465 (0M9H2770-C), Z.5055 (0M9H2650-W). Papua New Guinea: QM G312913, G312935. Axinella amensis, form I, Bynoe Harbour, NT: NTM Z.5816, Z.5817, Z.5818. Darwin Harbour, NT: NTM Z.2156, Z.5819-Z.5823. Wessel Is, Gove Peninsula, NT: NTM Z.3925, Z.3946. Axinella aruensis, form II. Darwin Harbour, NT: QM G303332, Z.196I, Z.2249, Z.2402, Z.2632, Z.4425 (0M9H2044-O), Z.4490, Z.4491, Z.5824-Z.5829, Z.5831, Z.5232. Parry Shoals, Arafura sea, NT: NTM Z.3137, Z.3068. Wessel Is, Gove Peninsula, NT: QM G300759 (Q66C-4831-R), NTM Z.5054 (0M9H2648-U). Yampy sound, WA, NTM Z.665. Description. Three different morphotypes of this species with one corresponding to the holotype are recognisable among the material examined and they will be described below separately under the heading of ‘forms’. Axinella aruensis, typical form. Shape (Fig. 2A-C). Thickly flabcllated, on broad and short, or long and narrow, peduncle, uni or bi-planar, sometimes folded, with round margins projecting in most cases into short and broad extensions with square, round or pointed tips, or in long rounded to flat branches which tend to fuse laterally. Specimens up to 400 mm high. Colour. Orange, pale yellow or yellowish brown alive. Dark brown in alcohol. Oscula. Regularly distributed in one or both sides of fan, stellate, flush or with elevated rims, less than 5 mm diameter. Surface. Evenly microconulose-conulose, nodulose, rough, marked with primary longitudinal choanosomal fibres. Skeleton (Fig. 3A). Plumose, vaguely reticulated to halichondroid, very compact, with plumose columns up to 600 pm thick, diverging toward surface, ending in fan-shappcd spicule brushes and projecting through ectosome. Axial skeleton differentiated only towards base of attachment or peduncle, halichondroid. Spicules (Fig. 3B). Oxeas with blunt, pointed or telescoped tips; slightly bent and sometimes slightly sinuous, 195-498 x 5-22 pm. Styles, less frequent or rare, similar in size to oxeas (see Table 1) with blunt ends, enlarged or slightly narrow bases, straight or slightly bent. Transitional forms (e.g. styloids, strongyles) are common. Fig. 3. Axinella aruensis: light microphotograph of skeleton and diagram of spicules: A, B, SMF 953, holotype; C, D, Z.5819 (form I); E, F, NTM Z.5054 (form II). Scale bars: A, 200 pm; B, D, F, 50 pm; C, E, 500 pm. Axinella aruensis, form I. Shape (Fig. 2D). Erect, fan-shaped or narrow long and flat digits with few simple ramifications, generally with square margins. Specimens up to 20 cm high and 10 cm wide. Colour. Light orange, brown, beige or yellow. Same colour in alcohol. Oscula. Regularly distributed, less than 5 mm diameter, with distinctive raised margins. Surface. Minutely hispid, marked with choanosomal skeletal tracts in a regular reticulation or with radial grooves. Skeleton (Fig. 3C). Plumose and slightly compressed at axial region, with thick plumo-echinated multispicular columns, up to 1 mm thick, and radiating outwards towards surface, anastomosing or connected irregularly by short and thick paucispicular or multispicular tracts, or by single spicules oriented in any direction. Main tracts end at surface in fan-shaped brushes with spicules projecting shortly through ectosome; light spongin embedding tracts. Spicules (Fig. 3D, Table 1). Oxeas, 187-451 x 8-25 pm, with pointed or blunt ends, straight or bent; thinner forms are common. Styles less frequent or rare, slightly smaller, 21 B. Alvarez and J. N. A. Hooper including intermediate forms similar to styloids, anisoxeas or strongyles. Fused spicules are characteristically common. Axinella aruensis, form II. Shape (Fig. 2E). Thick fans or lamellae with round margins, folding in more than one perpendicular plane, or joining at angles from 45-90 degrees; or short single or digitate projections, stipitate, on short narrow peduncles or on broad base. Generally small with individuals reaching up to 13 cm high. Colour. Bright or light orange alive. Light beige in alcohol. Oscula. Stellate with minute drainage canals, sometimes located at margin of fans or evenly distributed in both sides of fan, 3-5 mm in diameter. Surface. Pierced uniformly with minute ostia. Microconulose; minutely hispid, firm but some has mucous consistency after collection. Marked by regular choanosomal reticulation. Skeleton (Fig. 3E). Thick and dense plumo-echinated multispicular tracts up to 600 pm wide, forming regular, nearly radial reticulation which is marked on surface. Main columns end at surface in fan-shaped brushes, with spicules projecting shortly through ectosome. Axial skeleton not differentiated. Spicules (Fig. 3F, Table 1). Oxeas and styles in nearly equal proportions, 174-279 x 7-20pm. Styles arc dominant and slightly smaller than oxeas. Remarks. Although some features allowed distinction of two additional morphotypes within this species, the limits among them are not clear and some individuals could be considered intermediate forms. Axinella aruensis sensu stricto is distinguished from its two other forms by shape and colour, generally observed to be thickly fiabellate and orange when alive, by the change of colour in alcohol (it turns brown) and by the dominance of oxeas in relation to styles. Form 1 differs slightly in shape from A. aruensis ; the colour in life is always beige or pale yellow and does not change in alcohol; oxeas are also dominant and styles are relatively more common. Form II is always beige in alcohol and styles are dominant relative to oxeas. Some other features of shape and surface consistency and texture are also distinctive within this form. Some data included in Hooper et al. (1992) indicate there are some differences in the biochemistry between populations (i.e. North West Shelf versus Darwin Harbour) of this species, however the published results do not seem to be related to the forms distinguished here. Alvarez et al. (2007) detected up to 29% of intra-genomic polymorphism within the Internal Transcribe Spacer (ITS) of the rDNA in individuals of Axinella aruensis from Darwin Harbour. These levels of intra-genomic variation are so far the highest reported for Porifera and correspond in most cases to hybrid species reported for other groups, including corals of the genus Acropora. Thus, it is possible that the forms here distinguished to document the variability present within species are the result of a hybridisation processes with sympatric species or populations. Future population genetic studies will help to determine whether the variability observed across these forms are significant to justify their recognition as different species or as hybrids. Axinella aruensis is very similar in shape, skeletal architecture and spicule composition and dimensions to some Axinella species recorded from the Indian Ocean (e.g.A. donnani (Bowerbank, 1873);/!. mantis Dendy, 1905 and A. symmetrica (Dendy, 1905, as Phakellia)). Skeletal reticulation of the Indian Ocean species, in particular A. donnani , is much more regular, with thicker primary lines. Interesting also is the change in colouration, from orange to brown after few hours of collection, reported for A. donnani (Bowerbank, 1873), a characteristic also seen in A. aruensis. A detailed revision of the Indian Ocean species complemented with population genetic studies is essential to define their limits and phylogenetic relationships with the northern Australian populations of A. aruensis and its forms. Distribution. Axinella aruensis and its forms appear to occur sympatrically and are common throughout northern Australia (Fig. 4). The type locality is the Aru Is, Indonesia, but the species is also known from other Indonesian localities (Alvarez and de Voogd, unpublished data) and from Papua New Guinea. It is found in subtidal areas from 5 to 76 m. Pulitzer-Finali’s (1993) record for East Africa, is dubious and requires confirmation. Axinella lorihellae sp. nov (Figs 2G-H; 5) Material examined. Holotype - NTM Z.4427 (0M9H2041-L), Stevens Rock, Weed Reef, Darwin Harbour, 12°29.2001'S, 130°47.1'E, NT, 5-19 m depth, 8 May 2002, coll. B. Alvarez and party. Paratypes - NTM Z.5834 Stevens Rock, Weed Reef, Darwin Harbour, Northern Territory, Australia, 12°29.1667'S, 130°47.19'E, 17 m depth, 8 May 2006, coll. B. Alvarez. Additional specimens. Melville I., NT, NTM Z.631. Darwin Harbour, NT: QM G303388, NTM Z.822, Z.868, Z.5662. Wessel Is, NT: NTM Z.3938, Z.5059 (0M9H2771-F). 120” E 128” 136” E Fig. 4. Distribution of Axinella aruensis (open circles) and its forms (I, black circles; II, grey circles) based on confirmed records from QM and NTM. 22 Axinellidae from northern Australia Fig. 5. Axinella loribellae sp. nov.: A, Paratype, NTM Z.5834; B, light microphotograph of skeleton; C, diagram of spicules. Scale bars: A, 2 cm; B, 100 pm; C, 50 pm. Description. Shape (Figs 2G-H, 5A). Fan-shaped; thin lamellae, 1-5 mm thick, single or bifurcated, sometimes convoluted with rounded margins and indentations on short stalks or broad base. Specimens are 300 mm high and up to 400 mm wide. Colour. Burnt orange alive, brown in alcohol. Oscula. Small, 2-5 mm diameter, with stellate drainage canals, evenly distributed. Consistency. Flexible, easy to tear, rubbery. Surface. Smooth, velvety, marked irregularly with ribs. Skeleton (Fig. 5B). Plumose, differentiated in extra- axial and axial region. Axial skeleton compressed with wavy longitudinal paucispicular-multispicular tracts, lightly embedded in collagenous spongin, interwoven, and radiating towards the extra-axial region. Extra-axial region a close-set reticulation of plumose paucispicular tracts oriented perpendicular to surface and laterally close, connected by single spicules or uni-paucispicular tracts up to 2 spicules long, cemented with thin and clear spongin, to each other and ending in brushes of spicules that protrude shortly through ectosome. Spicules (Fig. 5C; Table 2). Styles slightly bent; strongyles straight, slightly sinuous, bent in middle; oxeas fusiform, straight. Transitional shapes between monoactins and diactins are common. All types in a wide range of sizes and thickness. Dominant types vary among specimens (see below). Remarks. A great variability in the shape and size of spicules was observed among specimens of this species. Styles and strongyles of 190-270 by 7-13 pm, are the dominant types, however they were absent in some of the examined specimens (i.e. NTM Z.631 and NTM Z.3938). Apart from these differences in spicule composition and dimensions, no other characters seem to vary among specimens examined here, and consequently they are considered at this stage to belong to a single species. Further genetic studies may help to confirm whether or not variability in spicule dimensions and composition is indicative of sibling species differentiation. The new species differs from Axinella aruensis and its related species from the Indian Ocean (see above) mainly in shape (thinly instead of thickly flabellate); in skeletal architecture (clearly differentiated into axial and extra- axial skeleton with thinner extra-axial spicular tracts and more regular reticulation when compared to the thicker multispicular columns present in A. aruensis ) and in spicule composition (with common transitional shapes between oxeas and styles not observed in A. aruensis). Axinella ceylonensis (Dendy, 1905, as Phakellia ) from the Gulf of Manaar is similar to A. loribellae in shape (although shortly stipitate) and in thickness of the lamellae. Both species share the variability observed in the size and shape of oxeas and styles. The two species differ in skeletal and surface characteristics. The skeleton of A. ceylonensis is not differentiated in axial and extra-axial region but described as plumose, with columns radiating outwards into small surface conules. No other species in the study area or in the Indian Ocean is similar to this new species. Indeed, most nominal species of Axinella reported for the Indian Ocean, do not agree with the current diagnosis of the genus and need to be re-examined. Some of these are massive forms with styles and trichodragmata in the skeleton and might belong in the axinellid genus Dragmacidon (e.g. Axinella Table 2. Comparison of spicule dimensions among specimens of Axinella loribellae sp. nov. Measurements in micrometres. Specimen Locality Styles Strongyles Oxeas Z.4427 (Holotype) Darwin Harbour 196.3-352.9 (274.6147.7) x 8.33-18.3 (13.512.7) 103.6-396.3 (190.1174.0) x 6.01-13.09 (10.311.9) 148.5-440.2(226.8163.6) x 4.8-12.9 (8.712.1) Z.5059 Wessel Is 159.7-365.4 (250.6150.4) x 5.8-14.43 (10.012.1) 93.7-531.8 (243.11128.6) x 5.8-13.3 (8.812.3) 100.8-302.2 (208.5150.1) x 3.7-11.4 (6.512.1) Z.631 Melville Is 187.6-307.9 (228.9129.0) x 4.3-11.3 (7.311.8) _ 142.8-351.6 (217.8144.1) x 3.5-13.2 (7.112.7) 23 B. Alvarez and J. N. A. Hooper bidden Burton, 1959 and A. massed is Burton, 1959). Some others are Stylissa-Uke, or other dictyonellid genera, with the surface marked by ridges or conules and with a dense and irregular skeleton of multispicular tracts of styles (e.g. Axinella bubarinoides Dendy, 1922; A. dragmaxioides Burton, 1959 [?]; A. flabelloreticulata (Burton, 1959); A. labyrinthica Dendy, 1889; A. minor Thomas, 1981; A. proliferous Ridley, 1884; A. tenuidigitata Dendy, 1905; A. ventilabrum Burton, 1959), or closer to halichondrid genera (e.g. Axinella halichondrioides Dendy, 1905, which is encrusting and has only oxeas) or to the raspailiid genus Ceratopsion (i.e. Axinella lamellata Dendy, 1905, with a dermal and tangential layer of small oxeas). Distribution. Axinella loribellae seems to be restricted to northern Australia between Darwin Harbour and the Wessel Is. It is found between 11-32 m depth. Etymology. Named after Lori Bell, Coral Reef Research Foundation, Palau, for her considerable contribution to the knowledge of Indo-Pacific sponge diversity and distribution. It is intended as a noun in apposition. Axinella sinoxea sp. nov. (Figs 2F, 6A-D) Material examined. Holotype - NTM Z.940, East Point, Darwin Harbour, NT, 12 o 24.05’S,130 o 48.01'E, 12m depth, 13 September 1982, coll. Hooper, J.N.A. Paratypes - Z.5833, East Point, Darwin Harbour, NT, 12° 24.484'S, 130° 48.47 l'E, 11 m depth, 7 June 2007, coll. B. Alvarez. Additional specimens. NW Shelf, WA: NTM Z.2310, Z.2322. Darwin Harbour, NT: NTM Z.2246, Z.2719. Description. Shape (Figs 2F, 6A). Single or multiple fans, 4-6 mm thick, 8-14 cm long and up to 30 cm wide, on common stalk, 3-5 cm long and 7-10 mm in diameter; erect, uniplanar with digitate to irregular margins or bifurcate tips. Colour. Orange, pale yellow or beige with light pink tinge alive; brown-grey in alcohol. Oscula. Regularly distributed in one or both sides of fan, round to elongated or irregularly shaped, some stellate, with slightly elevated rims, less than 1 mm diameter. Consistency. Soft, floppy, flexible, slightly compressible. Surface. Smooth but slightly rough to touch; pierced regularly by minute pores, microhispid due to projections of brushes of choanosomal spicules. Encrusted irregularly with detritus in some specimens. Skeleton (Figs 6B-C). Plumoreticulated, with ascending multispicular tracts connected regularly by single spicules or unispicular tracts, 1 or 2 spicules long, ending in brushes at surface; slightly compressed in axial region. Spicule tracts bound only slightly with clear collagenous spongin. Spicules (Fig. 6D; Table 3). Styles robust, bent, or less often, straight, enlarged in the middle section, 159-245 x 7-17 pm; thinner category, 97-201 x 2-6 pm also present. Long thin raphids abundant. Smaller oxeas and thick and short strongyles, very rare. Remarks. This species conforms in most of its characteristics with the current concept of Axinella. The absence or low frequencies of oxeas observed in the examined specimens are also seen in other Caribbean species of the genus (e.g. Axinella xvaltonsmithi (de Laubenfels, 1953) and A. pomponiae Alvarez, Van Soest and Rutzler, 1998), which might be considered a common feature among Axinella species. The new species resembles Axinella aruensis in gross morphology and as such can be easily mistaken for it in the field; both are fan-shaped on a common stalk and both have a similar surface pierced with minute ostia and microconulose. But A. sinoxea is clearly different from A. aruensis in skeletal architecture and spicule composition, having a regular plumoreticulated skeleton of ascending tracts and long thin raphids in the skeleton. As is the case with A. loribellae, no other species recorded in the study area or in the Indian Ocean was found to be related to A. sinoxea. Distribution. Common in the vicinity of East Point Sponge Gardens, Darwin Harbour, but also found in deeper waters (down to 40 m) of Western Australia. Etymology. Latin, sine- without; sinoxea referring to the lack of proper oxeas characteristic of the species. It is intended as a noun in apposition. Remarks on Axinella. Axinella is a widespread genus of sponges with approximately 100 accepted species (Van Soest et al. 2008), many of which, however, need to be verified against the current definition of the genus (Alvarez and Hooper 2002). Ongoing revisions of species ol 'Axinella and related genera by one of the authors (BA) are undertaken on a regional basis with the purpose to verify the identity of the reported species and the monophyly of the genus, which is currently proven as polyphylctic based on molecular studies (Alvarez et al. 2000; Erpenbcck et al. 2005). Three species of Axinella (A. aruensis, A. loribellae, A. sinoxea ) are reported in this work. No other species of the genus, as far as we know, have been reported within the area of northern Australia that is the subject of this present study. Axinella echidnaea reported by Ridley 1884 is accepted as Reniochalina stalagmitis (see below). Table 3. Comparison of spicule dimensions among specimens of Axinella sinoxea sp. nov. Measurements in micrometres. Specimen Locality Thick styles Thin styles Raphids Z.940 (Holotype) East Point, NT 184.5-245.1 (223.7± 12.92) 7.35-17.4 (13.11 ±2.49) 97.77-201.3 (179.64±22.84) [23] x 2.48-5.6 (3.8±1) [23] 192.9-249.6 (227.2± 14.9) x 0.8-3.0 (2.0±0.6) Z.2310 NW Lacepede Is WA 153.4-197.6 (183.4± 10.2) x 7.8-12.2 (10.2±1) 131.3-191.2 (152.1 ±14.8) X2.2-6.4 (4.4±1.) 131.9-258.6 (201.5±35.1) x 0.37-2.69 (1.6±0.5) 24 Axinellidae from northern Australia Fig. 6. Axinella sinoxea sp. nov. NTM Z.940: A, photograph of the holotype; B, light microphotograph of the skeleton; C, SEM, raphids in choanosomal skeleton; D, scale bars: A, 5 cm; B, 500 pm; C, 100 pm; D, 20 pm. In the present study area, the genus Axinella seems to be less speciose than in other taxonomically revised regions: seven species in the Western Central Atlantic (Alvarez et al. 1998); six (recorded) species and nine possible new species (Kelly et al. 2009); at least five species in Indonesia (Alvarez and De Voogd, unpublished data). Unfortunately little is known about the biology of these species to explain why the genus might be more diverse in some areas than others. Many more putative Axinella species are known for the GBR (pers. obs.), but these remain unresolved pending future studies. Distinction of Axinella species continues to be subjective and is based on a combination of characters as discussed by Alvarez et al (1998). Variability and plasticity of all the morphological characters that characterise the species are seen in all the species described above. The morphological variability of A. aruensis , for example, is remarkable and suggestions from molecular data (Alvarez et al. 2007) that it may be due to hybridisation should be further explored. Genus Cymbastela Hooper & Bergquist, 1992 Gender feminine. Type species, by original designation, Pseudaxinyssa stipitata Bergquist and Tizard, 1967. Recent, Darwin Harbour, Arafura Sea. Cymbastela stipitata (Bergquist and Tizard, 1967) (Figs 7A-B) Pseudaxinyssa stipitata Bergquist and Tizard, 1967:189; Hooper et al. 1992: 265. Cymbastela stipitata. - Hooper and Bergquist 1992: 106; Hooper and Wiedenmayer 1994 : 75; Alvarez et al. 2000: 195; Alvarez and Hooper 2002: 733. Material examined. Specimens as listed in Hooper and Bergquist (1992). Additional Specimens - Bynoe Harbour, NT: Z.5065 (0M9H2333-C). Darwin Harbour, NT: QM G303262, NTM Z.4078 (0CDN8001-H, Fig. 7A), Z.4104 (0CDN8026-J), Z.4131, Z.4435 (0M9H2008-Y), Z.5064 (0M9H2134-M), Z.5835, Z.5836, Wessel Is, NT: Z.5066 (0M9H2658-H), Z.5067 (0M9H2785-T). Remarks. Cymbastella stipitata, was re-described extensively by Hooper and Bergquist (1992) and the type material re-examined by Alvarez and Hooper (2002). This is one of the most common sponges in the studied area. It is particularly abundant in the intertidal zone of Darwin Harbour, which becomes greatly exposed during the nocturnal king tides of the dry season (May-June) and the diurnal king tides during the wet season (September- November, Fig. 7B). It is found, but less commonly, in subtidal areas down to 19 m depth. New records indicated that its distribution within northern Australia extends from 25 B. Alvarez and J. N. A. Hooper Fig. 7. Cymbastela stipitata: A, NTM Z.4078 (0CDN-8001-H); B, specimens exposed at the reef flat of East Ann. Darwin Harbour during the low tide of 20 September 2001. Dragmacidon australe: C, specimen at Channel I. Darwin Harbour; D. QM G304246, Lizard I. GBR, QLD. Phakellia tropicalis sp. nov.; E. 1 lolotype (NTM Z.5847); F, Paratype (NTM Z.5845). Reniochalina stalagmites'. G, specimen at East Point. Darwin; H, specimen at Cotton I., Wessel Is. Photos: A. B, E, F, B. Alvarez; C, H. Nguyen; D, J. Hooper; G, A. Ayling; H, P. Colin. 26 Axinellidae from northern Australia 125”E 135” 145” Fig. 8. Distribution of Cymbastela slipitala, based on confirmed records from QM and NTM. Bynoe Harbour to the Wessel Is (Fig. 8), inferring it is a narrow range endemic within northern Australia. Cymbastela vespertina Hooper and Bcrgquist, 1992 Cymbastela vespertina Hooper and Bcrgquist, 1992: 110; Hooper and Wiedenmayer 1994: 75; Alvarez et al. 2000: 195; Alvarez and Hooper 2002: 733. Pseudaxiyssa sp. nov. Hooper et al. 1992: 265. Material examined. Specimens as listed in Hooper and Bcrgquist (1992). Remarks. Cymbastela vespertina is a sibling species of C. stipitata. Separation of the two species based in morphology is difficult and very subjective. Biochemical and molecular evidence (Hooper et al. 1992; Alvarez et al. 2000) indicates the sympatric populations arc heterogeneous. Future genetic population studies might reveal whether or not these populations can be reliably separated into different species, but based on current external gross morphological differences and skeletal characters the two laxa are maintained as distinct. Remarks on Cymbastela. Two species of Cymbastela arc present within the area of the present study (i.e. C. stipitata (Bcrgquist and Tizard, 1967) and C. vespertina Hooper and Bergquist, 1992). Other species of Cymbastela represented in other regions including Australia are: C. cantharella (Levi, 1983), New Caledonia; C. concentrica (Lendenfeld, 1887), Queensland coast; C. coralliophila Hooper and Bergquist, 1992, GBR; C. marshae Hooper & Bergquist, 1992, Houman-Abrolhos, WA; C. notiaina Hooper and Bergquist, 1992, South Australia; and C. tricalyciformis (Bergquist, 1970) from New Zealand. Comprehensive descriptions of these species are given by the respective authors of the species. Phylogenetic relationships of the genus with other axinellid species based on molecular characters indicate that the northern Australian species of Cymbastela are closely related to other members of Dictyonellidae, such as Acanthella (Alvarez et al. 2000; Erpenbeck et al. 2005). There is no doubt, however, that species of Cymbastela are related to the Axinellidae based on their morphology. Thus the phylogenetic relationships derived from these molecular analyses remain enigmatic at this stage. Genus Dragmacidon Hallmann, 1917 Gender neuter. Type species, by original designation, Tlirinacophora agariciformis Dendy, 1905. Recent, Gulf of Manaar, Indian Ocean. Dragmacidon australe (Bergquist, 1970) (Figs 7 C-D, 9 A-B) Psetidaxinella australis Bergquist, 1970: 20; Hooper and Levi 1993: 1441; Hooper and Wiedenmayer 1994: 80; Alvarez et al. 2000: 196. Dragmacidon australe. - Alvarez and Hooper 2002: 735; Kelly et al. 2009 (In press). Material examined. Holotype -NMNZ Por. 26, Takatu Channel, Northland, New Zealand, 11 m. Additional Specimens - Cartier I, WA: QM G301089. Bynoe Harbour, NT: G303444. Darwin Harbour, NT: NTM Z.5068. Coral Sea, GBR, QLD: QM G300295, G304182, G304246, G304253, G320664, NTM Z.2727. Description. Shape (Fig. 7 C-D). Thickly encrusting, following substrate, globular, bulbous or semispherical, approx. 100 mm in diameter by 20 mm thick. Colour. Bright red, orange alive. Consistency. Slightly compressible or stiff. Mucous surface. Oscula. Irregularly distributed, less than 1 mm diameter, with slightly elevated rims surrounded by thin drainage channels in stellate arrangement. Surface. Highly conulose; evenly pierced by pores 120 400 pm in diameter. Conules, approx. 1-3 mm long, single or grouped in reticulated pattern, unevenly echinated by spicules, 2-3 mm apart. Skeleton (Fig. 9A). Plumoreticulate to halichondroid; formed by thick plumose or plumo-echinated multispicular tracts, up to 500 pm thick, ascending nearly perpendicularly from base and becoming thicker and bushy near surface; projecting through ectosome into surface conules. Main tracts connected by shorter and thinner plumose tracts, sometimes ill-defined, forming irregular reticulation of large round meshes. Spicules (Fig. 9B; Table 4). Oxeas and styles in equal proportions, 176-510 x 7-21 pm (Table 4). Remarks. The species was originally assigned to Pseudaxinella and transferred to Dragmacidon by Alvarez Fig. 9. Dragmacidon australe: A, light microphotograph of skeleton; B, diagram of spicules. Scale bars: A, 500 pm; B, 50 pm. 27 B. Alvarez and J. N. A. Hooper Table 4. Comparison of spicule dimensions among specimens of Dragmacidon australe. Measurements in micrometres. Specimen Locality Styles Oxcas G303444 Bynoe Harbour 254.1-510.4 (349.1 ±78.8) x 7.3-20.9 (13.6±3) 286.2-434.5 (361.5139.8) x 7.3-17.9 (13.412.4) Z.5068 Darwin Harbour 176.4-397.3 (290.1161.4) x 7-17.2(1312.8) 271.9-412.5 (340.7131.9) x 9.5-18.9 (14.312.4) and Hooper (2002) because it conformed more closely with the type species of that genus. Hooper and Levi (1993) compared specimens from the GBR with the holotype of Dragmacidon australe from New Zealand and with material from New Caledonia described as D. debitusae (Hooper and Levi, 1993). Very subtle differences were found between the two species. The material from northern Australia reported here agrees with D. australe in the majority of its features and is therefore assigned to this species. This species is also very similar to D. reticulatum (Ridley and Dendy, 1886) from the central West Atlantic both in external morphology and spicule composition. Distribution. Dragmacidon australe was first recorded for New Zealand and additional records from the GBR were reported in Hooper and Levi (1993). The present revision extends the distribution range of this species into northern Australia. The species is not very common in this region with only isolated records registered through the extension of the studied area (Fig. 10) and thus is probably at the edge of its range. It is also found along more temperate areas of the Queensland coast (Hooper pers. obs.). Dragmacidon durissimum (Dendy, 1905) (Figs 11 A-C) Thrinacopbora durissima Dendy, 1905:187. Sigmaxinella durissima. - Dendy 1922: 113. Axinella durissima. - Burton 1959: 259. Pseudaxinella durissima. - Alvarez et al. 2000: 196. Dragmacidon durissima. - Hallmann 1917:639; Alvarez and Hooper 2002: 735. Material examined. Ashmore Reef, WA: QM G300181. Description. Shape (Fig. 11 A). Hemispherical, cushion¬ shaped. Colour. Orange alive, red on deck, beige in ethanol. Oscula. Round, irregularly distributed at top, with slightly elevated rims. Surface. Very rugose, composed of minute projections or conules, compact and close-knit; membranous skin stretched over conules. Skeleton (Fig. 11B). Plumoreticulate. Multispicular, plumose or plumoechinated spicule tracts, ascending toward surface and connected by shorter and thinner ones, or loose spicules, forming irregular reticulation of oval to square meshes; projecting through ectosome in surface conules or projections. 125”E 135° 145° Fig. 10. Distribution of Dragmacidon australe in northern Australia, based on confirmed records from QM and NTM. Species distribution extends along the Queensland coast (Hooper pers. obs.) and New Zealand (type locality). Fig. 11. Dragmacidon durissimum : A, QM G300181; B, light microphotograph of skeleton; C, diagram of spicules. Scale bars: A. I cm; B, 500 pm, C, 50 pm. 28 Axinellidae from northern Australia Spicules (Fig. 11C). Styles 203.1-312.5 pm(251.8±33.4) by 11.7-16.4 pm (13.7±1.2). Oxeas in equal proportions, 229.8-312.7 pm (283.2±18) by 7.4-19 pm (13.4±3.1). Trichodragmata short and thick, 15-20 by 5-10 pm. Distribution. Indian Ocean, including Seychelles Is, Amirante, Providence, SayadeMalha(Dendy 1905; Dendy 1922; Burton 1959), Maldivc Is (Alvarez and de Voogd, unpublished data) and Ashmore Reef, Australia. Remarks. The material examined here agrees in all its characteristics with Dragmacidon durissimum , an Indian Ocean species never previously recorded in Australia. Only one specimen from WA was found among the collections examined in this revision. More isolated populations might be present along the WA coast, given that the species is widely distributed throughout the Indian Ocean. The species was included originally in Thrinacophora due the presence of trichodragmata, later transferred to Sigmaxinella by Dendy (1922), and subsequently to Axinella by Burton (1959) without sufficient justification. Hallman (1917) erected Dragmacidon for D. agariciformis (Dendy, 1905), D. durissimum, D. clathriformis ( Lendenfeld, 1888) and D. incrustans (Whitelegge, 1897). All these species are very similar in habitat, spicule composition and all include trichodragmata. They closely resemble to the West African species D. lunaecharta (Ridley and Dendy, 1886). Also similar are the Western Atlantic species D. reticulation (Ridley and Dendy, 1886) and D. australe (see above), but they lack trichodragmata. Remarks on Dragmacidon. An additional species of Dragmacidon (described as Pseudaxinella sp. in Alvarez et al. 2000: 196) remains undescribed as no additional material has yet been found to fully characterise the species. The existing material is a fragment of a thin asymmetric lamella, found detached from original substrate that does not agree with the characteristically thickly encrusting shape of Dragmacidon species. Genus Phakellia Bowerbank, 1862 Gender feminine. Type species, by original designation, Spongia ventilabrum Linnaeus, 1767. Recent, Lervig, Norway, North Sea. Phakellia tropicalis sp. nov (Figs 7 E-F, 12 A-B) Phakellia sp. Alvarez et al., 2000: 195; Holmes and Blanch 2007: 761; Alvarez et al. 2007: 1600. Material examined. Holotype - NTM. Z.5847 (Fig. 7E), Stevens Rock, West Arm, Darwin Harbour, 12°29.1667'S, 130°47.19'E, NT, 9 m depth, 8 May 2006, coll. Alvarez, B. Paratypes - NTM Z.5845 (Fig. 7F), Stevens Rock, West Arm, Darwin Harbour, 12°29.1667'S, 130°47.19'E, NT, 9 m depth, 8 May 2006, coll. B. Alvarez. Additional Specimens - Bynoe Harbour, NT:, NTM Z.4198, Z.4486, Z.4488. Darwin Harbour, NT: NTM Z.866, Z.877, Z. 1948, Z.4197, Z.4428, Z.5665, Z.5839-Z.5842, Z.5844, Z.5848, QM G303365, G303383. Wessel Is: NTM Z.4463. Fig. 12. Phakellia tropicalis sp nov.: A, light microphotograph of skeleton in cross section; B, schematic drawing of skeleton; C, diagram of spicules. Scale bars: A, 500 pm; B, 100 pm. Papua New Guinea: QM G312926, G312937. Malaysia: NTM Z.5843. Description. Shape (Fig. 7E-F). Small convoluted thin fans, up to 250 mm high and 300 mm wide, on short and thin peduncle, flexible, less than 5 mm thick, arranged in multiple planes, with fluted or planar flanges, ragged or crenulated margins. Colour. Bright orange, beige-orange, or yellow-brown (Darwin and Bynoe Harbour specimens) alive. Oscula. Star-shape oscula, minute. Surface. Velvety, felty, with choanosomal spicules projecting shortly; marked with fine network of excurrent channels ending in oscula and reinforced close to the peduncle by thick choanosomal axes or ‘veins’. Skeleton (Fig. 12A, B). A core of interwoven spicules, occupying most of specimen’s thickness, laterally compressed, echinated by a dense palisade of single spicules, sometimes aggregated in loose brushes, protruding through surface. Spicules (Fig. 12C). Strongyles wavy, 222-800 in length by 3-8 pm thick and styles 231-703 in length by 6-16 pm thick (Tabic 5). Remarks, (see Carvalho et al. 2007 for extensive review of Phakellia species.) 29 B. Alvarez and J. N. A. Hooper The species is atypical of Phakellia, although it agrees with the diagnosis given by Alvarez and Hooper (2002) in most aspects. It is fan-shaped, with styles projecting through the ectosome, and includes the typical spicule composition of the genus. However the reticulation of thick ‘veins’ or thick axes observed in most species of Phakellia , seems to be either incomplete or obscured by the habit of the species here described. The skeleton of this species (especially when seen in cross section, as in Fig. 12A) resembles some species of Acanthella (Dictyonellidae), a genus often confused with Phakellia. Phakellia tropicalis however, lacks two of the main diagnostic features of Acanthella - the cartilaginous to membranous surface and the cavernous structure of the choanosomal skeleton, with sheets of aspiculous collagen joining the primary axes in the skeleton. Instead, the surface of P. tropicalis is velvety, felty, with choanosomal spicules projecting shortly through the surface, a character shared with other axinellid genera such as Axinella and Cymbastela, and the skeleton is fonned by a core of interwoven strongyles with a regular and dense palisade of erect styles that occupies most of the thickness of the sponge. A phylogenetic analyses based on morphological characters by Alvarez et al. (2000) showed this species to be closely related to other species of Acanthella (i.e. A acuta, A. cavernosa and A. pulcherriina). In the same study, however, an analysis based on 28S rDNA sequences with the same set of species, indicated that P. tropicalis was closely related to typical axinellid genera such as Axinella and Dragmacidon supporting its allocation to Axinellidae instead of Dictyonellidae. Furthermore, the skeletal architecture of P. tropicalis corresponds with the basic plan observed in species of Bubaris Gray, 1867, a genus of the family Bubaridae and currently used in the strict sense to include encrusting forms (Alvarez and Van Soest 2002). Thus, one could interpret the new species as an ‘erect Bubaris ’ and be tempted to allocate it to that genus. It is possible that species with erect forms originally described under Bubaris, but transferred to Acanthella and Phakellia in order to preserve the revised concept of Bubaridae by Alvarez and Van Soest (2002), might be related to the new species. If that is the case, those species could be grouped under a new genus following a revised version of Hentschel’s (1923) concept of Bubaridae, which accepted sponges of erect forms, where the core of interwoven strongyles echinated by styles is placed in the centre (or in the axis) instead of at the base, as in the encrusting forms. However, it would be premature to erect a new genus here based on the characteristic of one single species and without re-examining species currently hidden under Acanthella or Phakellia which might also share such characteristics and could justify the creation of the new genus. In the absence of such evidence, we assign the new species provisionally to Phakellia and propose to expand the definition of Alvarez and Hooper (2002) (and modified by Carvalho et al. 2007) as: Axinellidae of planar habit, with skeleton formed by multiple axes or a single core ol sinuous megascleres (frequently strongyles), echinated either by single spicules or by secondary tracts of a second class of megascleres (frequently styles). Phakellia tropicalis is the only species of Phakellia recorded in this study and as far as we know the first one recorded from warm waters and shallow depths. Note that some species currently accepted under Phakellia from similar habitats are likely to be misidentifications (sec Carvalho et al. 2007 for an extensive review of Phakellia species). Other species of Phakellia recorded from northern Australia and adjacent areas are currently accepted undef Acanthella (Van Soest et al. 2008) or Axinella (i.e. Phakellia aruensis Hentschel, 1912, see above). Yet other species described under Phakellia in the Indian Ocean are not typical of the genus: P. ceylonensis Dendy, 1905: 192 is an Axinella (see above); P. crassistylifera Dendy, 1905: 192 is likely to belong in Stylissa and Phakellia ridleyi Dendy, 1887: 159 is currently accepted as a species of Phakettia. Distribution. This species is found along the NT coast and is very common in both Darwin and Bynoe harbours. It is also recorded for Papua New Guinea and Malaysia. It is found between 5-20 m depth Etymology. Referring to its tropical habitat. It is intended as a noun in apposition. Genus Reniochalina Lendenfeld, 1888 Gender feminine. Type species, by subsequent designation ofHallmann (1914), Reniochalina stalagmitis Lendenfeld, 1888. Recent, Western Australia. Reniochalina stalagmitis Lendenfeld, 1888 (Figs 7G-H, 13A-F, 14A-E, 15) Reniochalina stalagmitis Lendenfeld, 1888: 82; Whitelegge 1902: 283; Hallmann 1914: 346; Hooper and Wiedenmayer 1994: 81; Hooper and Levi 1993: 1404; Alvarez, et al. 2000: 197; Alvarez and Hooper 2002: 746; Holmes and Blanch 2007. Axinella echidnaea. - Ridley 1884: 462; Kieschnick 1896: 533; Hentschel 1912: 419 [misidentification; not Ridley and Dendy 1887: 183] Reniochalina lamella Lendenfeld, 1888: 83; Whitelegge 1902: 283; Hallmann 1914: 346. Axiamon folium Hallmann, 1914: 441 [objective synonym, see Wiedenmayer (1989: 49) and Hooper and Levi (1993: 1403)] Material examined. Type material - Reniochalina stalagmitis: Lectotype, BMNH 1887.4.27.122, Western Australia, Fig. 13A; paralectotype, AM G9004, wet, West Australia, Fig. 13B [also holotypc of Axiamon folium]. Reniochalina lamella: AM B5478, syntype, wet, no locality data [also paratype of A. folium]. Additional specimens - Ridley’s (1884) material: BMNH 1882.2.23.261, Prince of Wales Channel, Torres strait. North Queensland, coll. HMS Alert-, BMNH 1881.10.21.259, Thursday I., Torres strait. North Queensland, coll. HMS Alert. Hentschel’s 30 Axinellidae from northern Australia Table 5. Comparison of spicule dimensions among specimens of Phakellia tropicalis. Measurements in micrometres. Specimen Locality Strongyles Styles Z.5847 Holotype, Stevens Rock 284.1-651.2 (480.4±105.3) x 3.8-8.4 (5.7±1.2) 231.9-549.2 (385.7182.5) x 7.3-430.9 (29.8183.6) Z.4488 Bynoe Harbour 222.8-670.7 (435.5±135) x 3.7-9.5 (7± 1.6) 353.9-703.6 (484.61102.2) x 9-16.4 (13.812) Z.4463 Wessel Is 293.1-800(553.4±134.6) X4.4-8.4 (6.611.1) 273.6-658.2(439.61111.1) x 8.3-16 (11.212.2) G312926 Papua New Guinea 277.8-696.3 (476.41117.6) [24] x4.2-8.4(6.311.1) 239.6-490.6(343.5169.5) x 5.9-11.5 (8.711.8) (1912) specimen, SMF 1687, Aru-Inseln, bei Pulu Bambu, Indonesia, 10 m depth, 3 April 1908, coll. H. Merton, dredge. NW Shelf, WA: NTM Z.2358, Z.2361, Z.2273, Z.724, Z.738. Ashmore reef, WA: QM G301093, G301112, G301139. NE Joseph Bonaparte Gulf, QM G301202. Fog Bay, NT, QM G303548. Bynoc Harbour, NT: NTM, Z.4462 (0M9H2388-N), Z.5074 (0M9H2451-H), Z.5853. Darwin Harbour, NT: QM G303329, G303362, G303374, G303579, NTM Z.227, Z.285, Z.474, Z.483, Z.815, Z. 1107, Z. 1989, Z.2686, Z.4448 (0M9H2005-V), Z.5854, Z.5855, Gunn Point, NT, QM G303535. Parry Shoals, NT, Z.525. Melville I., NT, NTM Z.608. Cobourg Peninsula, NT: NTM Z.67, Z.135, Z.537, Z.565, Z.1335, Z.2527. Groote Eylandt, NT, G313555. Wessel Is, Z.5075 (0M9H2647-T). Gulf of Carpenteria, NT, QM G300817. Torres Strait, QM G316882. Description, Shape (Figs 7G-H, 13 A-B). Arborescent, branching or fan-shaped, generally stalked, and erect with specimens up to 60 cm high. Branches, flat to cylindrical, dichotomous or fused, 1-2 cm diameter, generally with pointed tips, dividing and anastomosing irregularly in different planes. Colour. Two colour forms, orange-red and beige-yellow. Always brown in alcohol. Oscula. Small, less than 5 mm diameter, with elevated rims thin, membranous and transparent, irregularly distributed through the branches. Surface. Long surface processes or conules with projecting spicules, up to 5 mm long, evenly distributed and separated by more-or less longitudinal and parallel channels, 1 mm apart, 1 mm deep. Skeleton (Fig. 13C-F). Specialised ectosomal skeleton absent; choanosomal skeleton differentiated into axial and extra-axial regions. Extra-axial skeleton reticulated with ascending spongin fibres, 50-100 pm interconnected at all angles by single spicules or short fibres, or anastomosing and forming oval to round meshes up to 200 pm in diameter; spongin fibres slightly developed and cored with paucispicular tracts of spicules, sometimes plumose; projecting into surface processes and becoming dense and disorganised at tips. Axial skeleton slightly condensed and reticulated as in extra-axial region. Spicules (Fig. I4A-E; Table 6). Oxeas or anisoxeas, occasionally modified to styles, straight, bent or slightly sinuous; with tips surmounted by microspines, which might be rudimentary or absent; microspines at one end might be half the compared size to those at other end (175^150 x 6-20 pm). Thin, sinuous styles or oxeas with smooth or slightly spined ends, 156-288 x 3-6 pm (Fig. 14A-C), scattered through the choanosomal skeleton, rare in most examined specimens. Few long styles, projecting through ectosome, present in some specimens but extremely rare. Remarks. The thin and sinuous styles (Fig. 14) were first mentioned by Hallmann (1914) in his description of Axiamon folium. The presence of these spicules was confirmed in all the specimens examined here and point out relationships of Reniochalina with other members of the family Raspailiidae (order Poecilosclerida). Long and slightly sinuous styles, most of which were broken, were also observed in the type material of Axiamon folium (AM G9004) and in some of the specimens examined. These were extremely rare and scattered throughout the extra- axial skeleton and projecting through the surface, indicating further affinities with raspailid taxa and challenging the position of the genus within Axinellidae (see below). Distribution. Reniochalina stalagmitis is one of the most abundant sponge species of northern Australia. It is found from the intertidal to depths of 60 m. Its distribution extends well beyond the boundaries of the studied region (Fig. 15) with validated records from the northern region of WA (down to W Buccaneer Archipelago) and QLD (down to the Howick Is region). It also occurs in Indonesia. Notes on Reniochalina. Reniochalina was defined by Alvarez and Hooper (2002) as ‘Axinellidae with extra-axial spongin fibres projecting into surface processes and cored with paucispicular tracts of oxeas, anisoxeas and styles. Oxeas with tips surmounted by micro-spines’. The genus was considered to be closely related to other axinellid genera (i.c. Ptilocaulis and Phycopsis) by Alvarez and Hooper (2002), based on the shared presence of conspicuous, long, filamentous surface processes and their skeletal features. The close affinities with Ptilocaulis were further confirmed by molecular phylogenetic analyses (Alvarez et al. 2000). Recent molecular studies (Erpenbeck et al. 2007; Holmes and Blanch 2007) also showed strong affinities of Reniochalina stalagmitis with the raspaillid species Axechina raspailoides. As previously indicated (Hooper 1991; Hooper 2002b), these species have similar growth forms and choanosomal skeletons, and it is now confirmed that they also share the presence of styles 31 B. Alvarez and J. N. A. Hooper Fig. 13. Reniochalina stalagniitis: A, lectotype, BMNH 1887.4.27.122; B, paralcctotype, AM G9004; C, lectotype, BMNH 1887.4.27.122, light microphotograph of skeleton; and D, SEM of skeleton; E. paralectotype, AM G9004, light microphotograph of skeleton and F, SEM of skeleton. Scale bars; A, B, 2 cm; C-F, 500 pm. 32 Axinellidae from northern Australia with spined tips and identical shape (Fig. 14B, C), a fact overlooked by previous authors with the exception of Hallmann (1914). Additional molecular analysis based on the COl fragment (Erpenbeck 2007) also indicated affinities of the Caribbean species Ptilocaulis marquezi (Duchassaing and Michelotti, 1864) with other raspailiid species (i.e. Pandaros acanthifolium (Duchassaing and Michelotti, 1864) and Ecyoplasia ferox (Duchassaing and Michelotti, 1864) suggesting strongly that both Ptilocaulis and Reniochalina are closely related to the Raspailiidae. These relationships however, remain unresolved as neither Reniochalina nor Ptilocaulis have the typical raspailiid ectosomal skeleton which is clearly present in Axechina and other raspailiid taxa. Unfortunately, the range of taxa sampled in the molecular analyses mentioned above was inadequate to conclude further on the affinities of the axinellid genera Reniochalina and Ptilocaulis (and likely Phycopsis too) with the family Raspailiidae. Therefore, if more evidence from molecular analyses becomes available to support the current results, these genera might be relocated to the Raspailiidae. Other species of Reniochalina reported in the literature do not agree with the current definition of the genus and are referred here to more appropriate genera: Reniochalina condylia Hooper and Levi, 1993, to Dragmacidoir, R. plumosa Levi and Levi, 1983 to Axinella and, R. sectilis Wiedenmayer, 1989 to Rhaphoxya in Dictyoncllidac. Additional species of Reniochalina including Reniochalina sp., reported in Alvarez etal. (2000), remain to be described from other areas of Australia (Hooper, pers. obs.). It is likely also that some species of Reniochalina are niisidentified as species of Ptilocaulis (e.g. P. rigidus Carter, 1883:322). DISCUSSION The results of this revision indicate that the Axinellidae is represented in the area covered by this study by only five genera (i.e. Axinella, Cymbastela, Dragmacidon, Phakellia and Reniochalina ) and nine species, three of which are new. Data gathered from NTM and QM collections during the initial stages of this revision indicated that the Axinellidae was represented in the area by a larger number of species. This observation turned out to be contrary to what was found after a thorough examination of recorded material. Many of the species thought to belong to the Axinellidae were in fact found to be members of other families and orders, particularly Raspailiidae (Poecilosclerida).This reflects that separation of species within this group is extremely subjective and could be erroneous if is taken in an isolated context. Examination of the taxonomic characters across a large number of specimens is critical to detect the variability and plasticity of moqdiological characters present in this group and to avoid incorrect splitting of taxa. It is possible that cryptic species or hybrid forms are hidden within the continuum of variability commonly observed in species of Axinellidae; but only results of population genetic studies can reveal such cryptic species, and indeed verify the occurrence of hybridisation among the Porifera, as has been demonstrated for the Cnidaria (e.g. Veron 1995, Van Oppen 2000 and references within). The five remaining genera of the Axinellidae (i .c.AuIetta, Dragmaxia, Pipestela, Ptilocaulis and Phycopsis ) are curiously not represented in the studied material despite the fact that they do include tropical species. Axinella loribellae, Cymbastela stipitata and C. vespertina are the only species of axinellids reported here with distributions restricted to northern Australia, reflecting some degree of endemism in the area. The latter sibling species pair represent western components of east-west coast species pairs of the genus Cymbastela, with C. coralliophila and C. concentrica of the east coast, presumed remnants of Pleistocene separation of northern Australian faunas during low strand sea levels (e.g. Hooper and Ekins 2004). Axinella sinoxea displays a similar distribution but can be found in deep waters of WA. The remaining species seem to have a more widespread distribution throughout Indonesia, Papua New Guinea and Malaysia. Axinella aruensis and Reniochalina stalagmitis are widely distributed in the northern region of Australia and Indonesia. Dragmacidon australe has a disjunct distribution with isolated records from New Zealand, GBR and northern Table 6. Comparison of spicule dimensions among specimens of Reniochalina stalagmitis. Measurements in micrometres. Specimen Locality Oxeas Thin styles/oxeas Lectotype BMNH1887.4.27.122 WA 190-315 (248.6127.9) x 8 15.2(12.112.4) 157.1-287.6 (240.2135.3) [18] x 2.6-5.8(4.510.9) [18] AM G9004 WA 175M50 (243.9161.8) x 7.9-20 (10.713) 211.7-268 (244122.7) [9] x 2.6-5 (3.810.8) [9] AM B5478 WA 197-376.6 (248.3149.5) x 10.1-19(14.411.9) 156.4-235 (203.7125.3) [12] x 3.5-6.3(4.910.8) [12] G303362 Darwin 209.1-356.6(253.3143.4) x 9.2-17 (1312.2) 206.5-232.6 (219.5118.4) [2] x 3.9^t (3.910) [2] Z.4462 Bynoe Harbour 195.1-379.1 (293.5139.1) x 7.1-18.2(13,912.6) 158.2-244.4 (213.2140.2) [4] x 2.6-5.2(4.211.1) [4] Z.5075 Wessel Is 199.6-380.2 (286.4144.6) x 6.3-18 (12.412.8) 205.8x3.7 [1] 33 B. Alvarez and J. N. A. Hooper A Fig. 14. Reniochalina stalagmitis: A, diagram of spicules; B, C, SEM of sinuous style with spined tip (AM G9004); D, E, tip of oxeas, (AM G9004). Scale bars: A, 50 pm; B, 5 pm; C, 20 pm; D, E, 2 pm. Australia. Dramacidon durissimum is a species common from Indian Ocean but its distribution is now extended to the Ashmore Reef, WA of northern Australia. The position of Reniochalina within the Axinellidae is now debatable. The presence of sinuous styles with spiny tips in R. stalagmitis and the recent evidence based on molecular data (see above) suggest strongly that the species is closely related to the raspailiid species Axechina raspailioides (Poecilosclerida) and challenges the position of Reniochalina stalagmitis within the family. The typical ectosomal skeleton present in raspailiid species and considered a synapomorphy for that family is absent in R. stalagmitis, thus no definitive conclusions can be made at this stage. New studies as suggested above are needed 120° E 130° 140° Fig. 15. Distribution of Reniochalina stalagmitis in northern Australia, based on confirmed records from QM and NTM. Species distribution extends along the Queensland coast (Hooper, unpublished data). 34 Axinellidae from northern Australia to decide whether Reniochalina should remain classified under the Axinellidae. Phylogenetic relationships within the family Axinellidae and other related groups have been explored previously, using either morphological, molecular or chemical characters (Alvarez et al. 2000; Erpenbcck et al. 2002; Erpenbeck et al. 2005; Erpenbeck et al. 2006; Erpenbeck et al. 2007). The relationships shown in those studies remain inconclusive at this stage but suggest strongly that the Axinellidae is a polyphyletic taxon with uncertain affinities. The taxonomic revision of species of the Axinellidae and its sister groups is critical to support conclusions derived from those studies and is currently the focus of ongoing studies undertaken at regional basis (e.g. Indonesia, Eastern Australia, Central- West Pacific, Southern Australia and New Zealand). ACKNOWLEDGEMENTS This work was funded by an Australian Biological Research Studies (ABRS) research grant (Grant No 205- 10) and by the 'Col lection and Taxonomy of Shallow Water Marine Organisms’ program for the US National Cancer Institute (Contract N02-CM-27003) subcontracted to NTM through CRRF. We specially thank Michael Browne and Huy Nguyen, for their invaluable assistance during 2002-2004 NTM field collections; Dr Pat Colin (CRRF) and Don DeMaria, for their assistance and photographic work during NTM field collections in the 2004 Wessel Is; Terry Yumbuluy, Wessel Is, to allow collections in his home-land area; Merrick Erins (QM) for his assistance in interrogating the QM database and making specimens available for study; Elbe Hayward (Charles Darwin University) for her assistance with SEM preparations; Drs Rob W.M. 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A collection of marine sponges from east Africa. Annali del Mttseo civico di Storia naturale Giacomo Doria 89: 247-350. Ridley, S.O. 1884. Spongiida Report on the Zoological Collections made in the Indo-Pacific Ocean during the Voyage oj'H.M.S. 'Alert' 1881-2. Pp. 366-684. British Museum, Natural History: London. 36 Axinellidae from northern Australia Ridley, S. O. and Dendy, A. 1886. Preliminary report on the Monaxonida collected by H.M.S “Challenger”. Part I. The Annals and Magazine of Natural History (Series 5) 18: 325-351. Ridley, S.O. and Dendy, A. 1887. Report on the Monaxonida collected by H.M.S. “Challenger” during the Years 1873-76 Report on the Scientific Results of the Voyage of H.M.S. ‘Challenger’ during the Years 1873-76. Pp. 1-275 pis 1-51. Her Majesty’s Stationery Office: Edinburgh, Dublin, London. Thomas, P. A. 1981. A second collection of marine Demospongiae from Mahe Island in the Seychelles Bank (Indian Ocean). Musec Royal dc PAfrique Centrale: Tervurcn, Belgique. Soest, R.W.M. Van, Boury-Esnault, N., Hooper. J„ Riitzler, K., De Voogd, N.J., Alvarez, B., Hajdu, E., Pisera, A., Vacelet, J., Manconi, R., Schoenberg, C., Janussen, D., Tabachnick, K.R. and Klautau, M„ 2008. World Porifera database. Available online at http://www.marinespecies.org/porifera. Last consulted on 18 October 2009. Soest, R.W.M. Van, Erpenbeck, D. and Alvarez, B. 2002. Family Dictyonellidae. Pp. 773-786. In Hooper, J.N.A. and Soest, R.W.M. Van (eds) Systema Porifera. A guide to the supraspecific classification of the phylum Porifera. Plenum: New York. Soest, R.W.M. Van and Hooper, J.N.A. 2002. Order Halichondrida. Pp. 773-786. In: I looper, J.N.A. and Soest, R.W.M. Van (eds) Systema Porifera. A guide to the supraspecific classification of the phylum Porifera. Plenum: New York. Soest, R.W.M. Van and Hooper, J.N.A. 2005. Resurrection of Desmoxya (Porifera: Halichondrida), with the description of a new species front Rockall Bank bathyal coral reefs, North Atlantic. Journal of the Marine Biological Association of the United Kingdom 85: 1367-1371. Spalding, M.D., Fox, 11.E., Allen, G.R., Davidson, N., Ferdana, Z.A., Finlayson, M., Halpern, B.S., Jorge, M.A., Lombana, A., Lourie, S.A., Martin, K.D., McManus, E., Molnar, J., Recchia, C.A. and Robertson, J. 2007. Marine Ecorcgions of the World: A Bioregionalization of Coastal and Shelf Areas. Bioscience 57: 573-583. Veron, J.E.N. 1995. Corals in space and time, the biogeography and evolution of the Scleractinia. University of New South Wales Press: Australian Institute of Marine Science, Townsville. Whitelegge, T. 1897. The Sponges of Funafuti. Memoirs of the Australian Museum 3: 323-332, pi. 18. Whitelegge, T. 1902. Notes on Lendenfeld’s Types described in the Catalogue of Sponges in the Australian Museum. Records of the Australian Museum 4: 274-288. Wiedenmayer, F. 1989. Demospongiae (Porifera) from Northern Bass Strait, Southern Australia. Memoirs of the Museum of Victoria 50: 1-242. Accepted 21 October 2009 37 B. Alvarez and J. N. A. Hooper APPENDIX Collection and locality data of material examined in the collections of QM and NTM. QM material G300181 Passage West I., outer reef, Ashmore Reef, WA, 12°14'S, 122°56'E, 15.5 m, 27 Jul 1986, coll. Hooper, JNA G300295 Snake Reef, Howick Group, GBR, QLD, 14°27'S, 145 0 l'E, 12.5 m, 14 Dec 1990, coll. Hooper, JNA G300609 N side of Cumberland Strait, Wessel Is, Gove, NT, 11°28'S, 136°29'E, 13 m, 14 Nov 1990, coll. NCI, AIMS G300759 Marinbar I, SE Cape Wessel, Wessel Is, NT, 11°1.13'S, 136°46.04'E, 20 m, 17 Nov 1990, coll. NCI, AIMS G300768 Gugari Rip 100m NE, E Guluwuru I, Wessel Is, NT, 11°34'S, 136°22.12'E, 8 m, 13 Nov 1990, coll. NCI, AIMS G300817 Duyfken Point, W Gulf of Carpentaria, QLD. 12°34'S, 141°0'E, 58 m, 26 Nov 1991, coll. Cook, SD. on CSIRO RV Southern Surveyor G301089 Cartier I, outer reef slope, N side reef, WA, 12°31.07'S, 123°33.05'E, 14m,6May 1992, coll. Hooper, JNA G301092 Cartier I, outer reef slope, N side reef. WA, 12°31.07'S, 123°33.05'E, 22 m, 7 May 1992, coll. Hooper, JNA G301093 Cartier I, outer reef slope, N side reef, WA, 12°31.07'S, 123°33.05'E, 22 m, 7 May 1992, coll. Hooper, JNA G301I12 Cartier I. outer reef slope, S side of reef, WA, 12°32.I5'S, 123°33.12'E, 23 m, 8 May 1992, coll. Hooper, JNA G301139 Hibernia Reef, entrance to lagoon, NE side reef, WA, 11°57.13'S, 123°22.06'E, 23 m, 10 May 1992, coll. Hooper, JNA G301197 Flattop Bank, NE Joseph Bonaparte Gulf, NT, 12°16'S, 129°15'E, 32 m, 17 May 1992, coll. Hooper, JNA G301202 Flattop Bank, NE Joseph Bonaparte Gulf, NT, 12°16'S, 129°15'E, 32 m, 17 May 1992, coll. Hooper, JNA G303262 South Shell [., reef N of boat ramp. East Arm, Darwin Harbour, NT, 12°29.1334'S, 130°53.09'E, 0 m, 19 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303322 East Point Bomniics, Darwin Harbour, NT, 12°24.08'S, 130°48.14'E, 10 in, 23 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303329 East Point Bommies, Darwin Harbour. NT, 12°24.08'S, 130°48.14'E, 10 m, 23 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303332 East Point Bommies, Darwin Harbour, NT, 12°24.0834'S, 130°48.14’E, 10 m. 23 Sep 1993, coll. Hooper, JNA and Hobbs. LJ G303362 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17’S, 130°47.19'E, 19 m, 24 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303365 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17'S, 130°47.19'E, 19 m, 24 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303374 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17'S, 130°47.19'E, 19 m, 23 Sep 1993, coll. Hooper, JNA and Hobbs. LJ G303383 Stevens Rock, Weed Reef. Darwin Harbour, NT, 12°29.17'S, 130°47.19'E, 19 tn, 24 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303388 Stevens Rock, West Arm, Darwin Harbour, 12°29.1667'S. 130°47.19'E, NT, 19 m depth, 24 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303444 Fish Reef, west side. Bynoe Harbour. NT, 12°26.01 'S, 130°26.09 E, 11 m, 26 Sep 1993, coll. Hooper, JNA and Hobbs, LJ G303535 Shoal Bay, W Gunn Point, NT, 12°9.I5'S, 130°56.02'E, 14 m, 11 Oct 1993 G303548 Fog Bay, 1 nml E Point Blaze, NT, 12°54.15'S. I30°7.16'E, 7 m, 4 Oct 1993 G303579 Lee Point near Anglers Reef, Darwin Harbour, NT, 12°18.13'S, 130°52.14'E, 10m, 11 Oct 1993 G304182 Granite Bluff Lizard I., S headland Mermaid Cove, QLD, 14°39'S, 145°27’E, 18 m, 4 Apr 1994, coll. Hooper, JNA and party G304246 Cobia Hole, Mrs Watson's Bay, Lizard I„ QLD, 14°39.03'S, 145°26.15'E, 18 m, 5 Apr 1994, coll. Hooper, JNA and party G304253 Palfrey I„ W side. Lizard I., QLD, 14°42.03'S, I45°26.09’E, 16 m, 6 Apr 1994, coll. Hooper, JNA and party G310136 Parry Shoals 35nm W Bathurst I., NT, 1 l°7.03'S, 129°25.9'E, 16 m, 12 Aug 1987 G311873 100m NE Gugari Rip, East side Guluwuru IS, Wessel Is, NT, 1 l°20.4'S, 136°13.63'E, 8 m, 13 Nov 1990 G312926 12 mile sandbank, Kupiano, SE Papuan Lagoon, Papua New Guinea, 10°1I.05'S, 148°I0.I4'E, 20 m, 15Dcc 1996, coll. Hooper. JNA G312913 Coutance Islet, Kupiano, SE. Papuan Barrier Reef, Papua New Guinea, 10° 14.0167'S, 148°6.14'E, 41 m, 14 Dec 1996, coll. Hooper. JNA G312935 12 mile sandbank. Kupiano, SE Papuan Lagoon. Papua New Guinea, 10° 11,0501'S, 148°10.14'E, 20 m, 15 Dec 1996, coll. Hooper, JNA G312937 12 mile sandbank, Kupiano, SE Papuan Lagoon, Papua New Guinea, 10°11.05'S, 148°10.14'E, 20 m, 15 Dec 1996, coll. Hooper. JNA G313555 S Groote Eylandt, NT, 14°27.1801'S, 136°14.29'E, 22.5 m, 12 Oct 1997, coll. Cook, SD. on CSIRO RV Southern Surveyor G316882 Torres Strait. QLD, 10°46.8'S, 142°15'E, 16.4 m, 19 Jan 2004, coll. TSMap GM 01 2004 Gwendoline May G320664 Munro Reef Coral Sea, QLD, 14°18.15'S, 144°48.82'E, 23 m, 2 Jul 2003, coll. Hooper, JNA and party 38 Axinellidae from northern Australia APPENDIX (continued) Collection and locality data of material examined in the collections of QM and NTM. NTM material Z.67 Coral Bay, Port Essington, Cobourg Peninsula, NT, 11 ° 11.50’S, 132°3.01 'E, 17 Oct 1981, coll. Hooper, JNA & Alderslade, PN Z.135 Sandy I. No.2, Cobourg Peninsula, NT, 11°5.50'S, 132°17’E, 10 m, 21 Oct 1981, coll. Hooper, JNA & Alderslade. PN Z.227 Lee Point, Darwin, NT, 12°19.0I67'S, 130°53'E, 14 Nov 1981, coll. Hooper, JNA Z.285 Dudley Point Reef, East Point, Darwin, NT, 12°25.00'S, 130°48.01 'E, 1 m, 18 Sep 1981, coll. Hooper, JNA & Murray, P Z.474 Fannie Bay. Darwin, NT, 12°25.00’S, 130°50'E, 9 Feb 1982, coll. Hooper, JNA Z.483 Fannie Bay, Darwin, NT. 12°25.00’S, 130°50'E. 9 Feb 1982, coll. Hooper. JNA Z.525 Parry Shoals 35ntn W Bathurst I„ NT, 11°7.03’S, 129°25.9'E, 1 m, 30 Apr 1982, coll. Hooper, JNA & Alderslade, PN Z.537 Port Bremer. Cobourg Peninsula, NT, 11°8.5’S, 132°18.8’E, 1 May 1982, coll. Hooper, JNA & Alderslade, PN Z.565 Sandy I. No.2, Cobourg Peninsula. NT, 11°5’S, 132°16.51'E, 14 m, 2 May 1982, coll. Hooper, JNA Z.608 Cootamundra Shoals, North of Melville I„ NT, 10°49.07'S, 129°12.09'E, 31 m, 6 May 1982, coll. Thom, B & Lockyer, R Z.615 Cootamundra Shoals.North of Melville I., NT, 10°50.22'S, 129° 13.17'E, 22 m, 10 May 1982, coll. Lockyer, R Z.619 Unnamed shoal N Melville I, NT, 11°38.23'S, 129°51.00’E. 24 m, 17 May 1982, coll. Thom, B & Lockyer, R Z.630 Unnamed shoal N Melville I, NT, 1 l°32.58’S, 130°02.50'E, 18 m, 25 May 1982. coll. Lockyer, R Z.631 Unnamed shoal N Melville I, NT, 1 l°32.58'S, 130°02.50'E, 18 m, 25 May 1982. coll. Lockyer, R Z.632 Unnamed shoal N Melville I, NT, 1 i°32.57’S, 130 o 2.51'E, 18 m, 25 May 1982, coll. Lockyer. R Z.665 NW Yam pi Sound, NW Shelf, NVA, 15°27.0334’S. 121°49.01 'E, 76 m. 29 Apr 1982, coll. CSIRO R.V. Sprightly Z.724 N Adele I.,Collicr Bay, NW Shelf. WA, 15°58.02’S, 122°39.07'E, 59 m, 21 Apr 1982. coll. CSIRO R.V. Sprightly Z.738 N Adele I.,Collier Bay, NW Shelf, WA, 15°58.02’S, 122°39.07'E, 59 m, 21 Apr 1982, coll. CSIRO R.V. Sprightly Z.815 Channel I.. Middle Arm, Darwin, NT, 12°32.02’S, I30°51.02’E, 11m, 16 Jul 1982, coll. Scott Chidgey (Caldwell Connell Ass Z.822 Channel I., Middle Arm, Darwin, NT, 12°33.08'S, 130°51.04'E, 20 m, 18 Jul 1982, coll. Scott Chidgey (Caldwell Connell Ass) Z.866 Channel I., Middle Arm, Darwin, NT, 12°32.07'S, 130°52.04'E, 13 m, 20 Aug 1982, coll. Alderslade, PN. Z.868 Channel I., Middle Arm, Darwin, NT, 12°32.07'S, 130°52.04'E, 13 m, 20 Aug 1982, coll. Alderslade, PN. Z.877 Channel 1., Middle Arm, Darwin, NT, 12°32.07'S, 130°52.04'E, 13 m, 20 Aug 1982, coll. Alderslade. PN. Z.1107 Dudley Point Reef, East Point, Darwin, NT. 12°25.00'S, 130°48.01’E, 22 Dec 1982, coll. Hooper, JNA Z.1335 Table Head, Port Essington, Cobourg Peninsula, NT. 11 0 13.5'S, 132° 10.51 'H, 11 May 1983, coll. Hooper, JNA Z.1363 Coral Bay, Port Essington, Cobourg Peninsula, NT, 11 0 11.3'S, 132°3.71 'E, .5-6 m, 16 May 1983, coll. Hooper, JNA Z.1388 Coral Bay, Port Essington, Cobourg Peninsula, NT, 11 ° 11.3'S, 132°3.71 'E, 6tn, 17 May 1983, coll. Hooper, JNA Z.1948 Stevens Rock, Weed Reef, Darwin Harbour, NT. 12°29.2'S, 130 o 47.1'E, 27 Apr 1984, coll. Hooper, JNA Z.1961 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.2'S, 130°47.1 'E. 27 Apr 1984. coll. Hooper, JNA Z.1989 West side of Weed Reef, Darwin, NT, 12°29.2001 'S, 130°47.1 'E, m, 11 May 1984, coll. Hooper, JNA and party Z.2156 Northern tip of Weed Reef, outer reef slope, Darwin Harbour, NT, 12°29.2'S, 130°37.61 'E, 5 Oct 1984, coll. Hooper, JNA Z.2246 Dudley Point Reef, East Point, Darwin, NT, 12°24.5'S, 130°48.01 'E, 10 m, 12 Apr 1985, coll. Hood, C and party Z.2249 Dudley Point Reef, East Point, Darwin, NT, I2°24.5'S, 130°48.01 'E, 10 m, 12 Apr 1985, coll. Hood, C and party Z.2273 NW Lacepede Is, NW Shelf, WA, 16°31,00'S, 121°28.01'E, 38-40 m, 17 Apr 1985, coll. Russell, BC (TRASH Fish project) Z.2284 NW Lacepede Is, NW Shelf, WA, 16°31.00'S, 121°28.01’E, 38^40 m, 17 Apr 1985, coll. Russell, BC (TRASH Fish project) Z.2304 NW Lacepede Is, NW Shelf, WA, 16°31.00’S, 121 o 28.01'E, 38-40 m, 17 Apr 1985, coll. Russell, BC (TRASH Fish project) Z.2310 NW Lacepede Is, NW Shelf, WA, 16°31.00’S, 121°28.01 'E, 38-40 m, 17 Apr 1985, coll. Russell, BC (TRASH Fish project) Z.2322 NW Lacepede Is, NW Shelf, WA, 16°31.00'S, 121°28.0I'E, 38-40 m, 17 Apr 1985, coll. Russell, BC (TRASH Fish project) Z.2331 NW Lacepede Is, NW Shelf, WA, 16°3 LOO'S, 121°28.01 E, 38-40 m, 17 Apr 1985, coll. Russell, BC (TRASH Fish project) Z.2345 NW Lacepede Is, NW Shelf. WA, 16°34'S, 121°27.01 'E, 4(T46 m, 17 Apr 1985, coll. Russell, BC Z.2358 NW Lacepede Is, NW Shelf, WA, 16°34'S, 121°27.01 'E, 40-46 m, 17 Apr 1985. coll. Russell, BC Z.2361 NW Lacepede Is, NW Shelf, WA, 16°34'S, 121°27.01'E, 40-46 m, 17 Apr 1985, coll. Russell, BC Z.2402 Dudley Point Reef, East Point, Darwin, NT, 12°24.5'S, 130°48.01'E, 8 m, 29 Jul 1985, coll. Hooper, JNA Z.2511 Coral Bay, Port Essington, Cobourg Peninsula, NT, 11 0 11.3'S, 132°3.71'E, 15 Sep 1985, coll. Hooper, JNA 39 B. Alvarez and J. N. A. Hooper APPENDIX (continued) Collection and locality data of material examined in the collections of QM and NTM. NTM material Z.2526 Orontes Reef.mouth of Port Essington.Cobourg Peninsula, NT, 11°3.60'S, 132°5.41'E, 18-20 m, 16Sep 1985,coll. Hooper, JNA Z.2527 Orontes Reef.mouth of Port Essington.Cobourg Peninsula, NT, 11°3.60'S, 132°5.41'E, 18-20 m, 16 Sep 1985, coll. Hooper, JNA Z.2529 Orontes Reef.mouth of Port Essington.Cobourg Peninsula, NT, 11°3.60'S, 132°5.41 'E, 17 Sep 1985, coll. Hooper, JNA Z.2632 Dudley Point Reef East Point. Darwin, NT. I2°24.5'S, 130°48.0I 'E, 3 Apr 1986, coll. Hooper, JNA and party Z.2686 Dudley Point Reef, East Point, Darwin, NT, 12°24.5 S, 130°48.01 'E, 3 Apr 1986, coll. Hooper, JNA and party Z.2719 Dudley Point Reef, East Point, Darwin. NT, 12°24.5"S. 130°48.01 'E, 3 Apr 1986, coll. Hooper, JNA and party Z.2727 Myrmidon ReefGBR, QLD, I8°10.00'S, I47°23'E, 15 m. 1 Jan 1985, coll. Wilkinson,CR Z.3062 Parry Shoals, Arafura Sea, NT, 11°11.72'S, I29°43.26'E, 16 m, 12 Aug 1987, coll. Mussig, AM and NCI team Z.3068 Parry Shoals, Arafura Sea, NT, 11°11.72'S, 129°43.26'E, 16 m. 12 Aug 1987, coll. Mussig, AM and NCI team Z.3137 Parry Shoals. Arafura Sea. NT, 11°12.27'S, I29°42.7I'E, 16 m. 14 Aug 1987, coll. Mussig, AM and NCI team Z.3141 Parry Shoals, Arafura Sea. NT, 11°12'S, 129°43.01 E, 16 m, 14 Aug 1987, coll. Mussig, A.M. and NCI (AIMS) Z.3922 Cumberland Strait, northern bay, Wessel Is, Gove Peninsula, NT, 11°27.5 S. I36°28.8'E, 20 m. 14 Nov 1990. coll. Hooper JNA Z.3925 Cumberland Strait, northern bay, Wessel Is, Gove Peninsula. NT, 11°27.5’S, 136°28.8'E, 20 m, 14 Nov 1990, coll. Hooper, JNA Z.3935 N side of Cumberland Strait, Wessel Is, Gove Peninsula, NT, 11°27.60 S, 136°28.7'E, 32 m, 15 Nov 1990, coll. Hooper, JNA Z.3936 N side of Cumberland Strait, Wessel Is, Gove Peninsula, NT, 11°27.60'S, 136°28.7'E, 32 m, 15 Nov 1990, coll. Hooper, JNA Z.3938 N side of Cumberland Strait, Wessel Is, Gove Peninsula, NT, 11°27.60'S, 136°28.7'E, 32 m, 15 Nov 1990, coll. Hooper, JNA Z.3946 S W headland, Rimbija I., Cape Wessel, Wessel Is, Gove Peninsula, NT, 11°0.5'S, 136°43.79'E, 15 m, 16 Nov 1990, coll. Hooper, JNA Z.3956 N side Pugh Shoal, reef slope, NE of Truant I.. English Company IS. Gove Peninsula, NT, 11°36.57'S, 136°53.39'E, 20 m. 18 Nov 1990, coll. Hooper, JNA Z.4078 Near boat ramp. East Arm Port. Darwin, NT, 12°29.8'S, 130°53.5'E, coll. B. Glasby & party, by hand Z.4104 Near boat ramp. East Arm Port. Darwin, NT, 12°29.8'S, 130°53.5'E, coll. B. Glasby & party, by hand Z.4131 Near boat ramp. East Arm Port. Darwin, NT, 12°29.8'S, 130°53.5'E, coll. B. Glasby & party, by hand Z.4197 “Town Half hole, SW Channel I., Middle Arm of Darwin Harbour, NT, 12°33.74'S, 130°51.67'E, 19.5 m, 9 Sep 2004, coll. Alvarez, B Z.4198 Sand Island. Middle Arm, Darwin Harbour, NT, Australia, Australia, 12°35.291'S, 130°52.264’E, 7 m, 9 Sep 2004, coll. Alvarez, B Z.4425 Stevens Rock, 1.25 km SE Talc Head, off Cox Peninsula, Darwin Harbour, NT, 12°29.09'S, I30°47.TE, 5-19 m, 8 May 2002, coll. Alvarez, B and party Z.4428 Stevens Rock. 1.25 km SE Talc Head, off Cox Peninsula, Darwin Harbour, NT, I2°29.09'S, 130°47.1'E, 5-19 m, 8 May 2002, coll. Alvarez, B and party Z.4435 Channel Island, 100 400 m N of bridge. Middle Arm, Darwin Harbour, NT, Australia, Australia, 12°33.09'S, 130°52.43'E, 4 -8 m. 6 May 2002. coll. Alvarez. B and party Z.4448 Channel Island, 100-400 m N of bridge, Middle Arm, Darwin Harbour. NT, Australia, Australia, 12°33.09'S, 130°52.43'E. 4 -8 m, 6 May 2002, coll. Alvarez, B and party Z.4462 Dawson Rock. 3 km SSE Rankin Point, Bynoe Harbour, NT, 12°42.21'S, 130°35.46'E, 5-10 m, 26 May 2003, coll. Alvarez, B and party Z.4463 Rimbija I.. 2.8 km W of Cape Wessel, Wessel Is, eastern Arnhem Land, NT, 11 °00.21 'S, 136°43.84'E, 17-20 m, 1 Apr 2004, coll. Colin. P Z.4465 Raragala I„ bay on SW coast. Wessel Is, eastern Arnhem Land, NT, 11°38.57'S, 136°17.86'E, 11-20 m, 5 Apr 2004, coll. Alvarez B and party Z.4486 Raft Point, Bynoe Harbour, NT. 12°37.69'S, I30°32.16'E. 5-8 m, 26 Jun 2003, coll. Alvarez. B and party Z.4488 Dawson Rock, 3 km SSE Rankin Point. Bynoe Harbour, NT, I2°42.2LS, 130°35.46'E, 5 m, 1 Jun 2005, coll. Alvarez, B Z.4490 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17’S, 130°47.I9'E, 5 m, 8 May 2006, coll. Alvarez, B Z.4491 Stevens Rock, Weed Reef. Darwin Harbour, NT, 12°29.17'S, 130°47.19'E, 14 m, 8 May 2006, coll. Alvarez, B Z.5053 South Shell 1„ East Arm, Darwin Harbour, NT, 12°29.87'S, 130°53.12'E, 4-11 m, 18 Aug 2002, coll. Alvarez, B and party Z.5054 Raragala I., bay on SW coast, Wessel Is, eastern Arnhem Land, NT, 11°38.6'S, 136°17.84'E, 17-20 m, 30 Mar 2004, coll. Alvarez, B and party 40 Axinellidae from northern Australia APPENDIX (continued) Collection and locality data of material examined in the collections of QM and NTM. NTM material Z.5055 Raragala I., bay on SW coast, Wessel Is, eastern Arnhem Land, NT, 11°38.6'S, 136°17.84'E, 17-20 m, 30 Mar 2004, coll. Alvarez, B and party Z.5057 Raragala I„ bay on SW coast, Wessel Is, eastern Arnhem Land, NT, 1 l°38.6’S, 136°17.84'E, 17-20 m, 30 Mar 2004, coll. Alvarez, B and party Z.5058 Raragala I„ 700 m oil NE tip Wessel Is, eastern Arnhem Land, NT, 11°32.85'S, 136°21.28'E, 13-16 m, 31 Mar 2004, coll. Alvarez, B Z.5059 Raragala L, bay on SW coast, Wessel Is, eastern Arnhem Land, NT, 11°38.55'S, 136°17.96'E, 25-30 m, 5 Apr 2004, coll. Alvarez, B and party Z.5064 Weed Reef, entrance to West Arm, Darwin Harbour, NT, 12°29.25'S, 130°47.54’E, 9-15 m, 3 Aug 2002, coll. Alvarez, B and party Z.5065 Dawson Rock, 3 km SSE Rankin Point, Bynoe Harbour, NT. 12°42.24’S, 130°35.56 E, 5-10 m, 23 May 2003, coll. Alvarez, B and party Z.5066 Raragala L, bay on SW coast, Wessel Is. eastern Arnhem Land, NT, 11 °38.6 S, 136°17.84'E, 17-20 m, 30 Mar 2004, coll. Alvarez, B and party Z.5067 Raragala L. bay on SW coast, Wessel Is, eastern Arnhem Land, NT, 11°38.28'S, 136°17.52'E, 13-14 m, 5 Apr 2004, coll. Alvarez B. and party Z.5068 "Town Hall” hole, SW Channel L, Middle Arm of Darwin Harbour, NT, 12°33.74'S, 130°51.67'E, 10-18 m, 17 Sep 2002, coll. Alvarez, B and party Z.5071 Spencer Point, Indian I„ Bynoe Harbour, NT, 12°35.35'S. 130°31.45'E, 6-8 m, 11 Jun 2003, coll. Alvarez, B and nartv Z.5072 Weed Reef, entrance to West Arm, Darwin Harbour, NT, 12°29.25'S. 130°47.54'E, 9-12 m. 6 Sep 2003, coll. Alvarez. B Z.5074 Spencer Point. Indian I.. Bynoe Harbour, NT. 12°35.49'S, 130°31.29'E, 9-10 m. 11 Jun 2003. coll. Alvarez. B and nartv Z.5075 Raragala L, bay on SW coast. Wessel Is, eastern Arnhem Land, NT, 11°38.6'S, 136°17.84'E. 17-20 m, 30 Mar 2004, coll. Alvarez, B and party Z.5662 East Point, Darwin Harbour, NT. 12°24.16'S, 130°47.66'E. 11 m depth. 8 November 2008, coll. Aylinsi, A Z.5665 East Point, Darwin Harbour, NT, 12°24.16'S. 130°47.66’E, 11 m depth, 8 November 2008, coll. Ayling, A Z.5816 Dawson Rock, 3 km SSE Rankin Point, Bynoe Harbour, NT, 12°42.21 'S, 130°35.46'E, 3-12 m, 1 Jun 2005, coll Alvarez B Z.5817 Dawson Rock, 3 km SSE Rankin Point, Bynoe Harbour, NT, 12°42.21 'S, 130°35.459'E, 6 m, 27 Apr 2007 coll Alvarez B Z.5818 Dawson Rock, 3 km SSE Rankin Point, Bynoe Harbour, NT, 12°42.2I'S, 130°35.459'E, 6 m, 27 Apr 2007, coll Alvarez B Z.5819 East Point, Fannie Bay, Darwin, Australia, 12° 24.484'S, 130° 48.471., 11 m, 7 Jun 2007, coll. Alvarez. B Z.5820 East Point, Fannie Bay, Darwin, Australia, 12° 24.484’S, 130° 48.471., 11 m, 7 Jun 2007, coll. Alvarez. B Z.5821 East Point, Fannie Bay, Darwin, Australia. 12°24.484'S, 130°48.471., 11 m, 7 Jun 2007, coll. Alvarez, B Z.5822 East Point, Fannie Bay, Darwin, Australia, 12°24.484 S, 130"48.471., 11 m, 7 Jun 2007, coll. Alvarez, B Z.5823 East Point, Fannie Bay, Darwin, Australia, 12° 24.484'S, 130° 48.471., 11 m, 7 Jun 2007, coll. Alyarez, B Z.5824 East Point, Fannie Bay, Darwin, Australia, 12° 24.48'S. I30°48.47'E, 11 m, 7 Jun 2007, coll. Alvarez, B Z.5825 East Point, Fannie Bay, Darwin, Australia, 12° 24.48'S, I30°48.47'E, 11 m, 7 Jun 2007, coll. Alvarez, B Z.5826 East Point, Fannie Bay, Darwin, Australia, 12° 24.48'S, 130°48.47'E, 11 m, 7 Jun 2007, coll. Alvarez, B Z.5827 East Point, Fannie Bay, Darwin, Australia, 12° 24.48'S. 130°48.47'E, 11 m, 7 Jun 2007, coll. Alvarez, B Z.5828 East Point, Fannie Bay, Darwin, Australia, 12" 24.48'S, 130°48.47'E, 11 m, 7 Jun 2007, coll. Alvarez, B Z.5829 East Point, Fannie Bay, Darwin, NT, 12°24.49'S. 130°48.43'E, 14 m, 25 May 2007, coll. Alvarez, B Z.5830 South Shell I., East Arm, Darwin Harbour, NT, 12°29.87'S, 130°53.14'E, 7 11. m, 19 Aug 2002, coll. Alvarez, B and party Z.5831 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17'S, I30°47.19 E, 17 m, 8 May 2006, coll. Alvarez. B Z.5832 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17'S, 130°47.19'E, 14 m, 8 May 2006, coll. Alvarez, B Z.5835 Stevens Rock. 1.25 km SE Talc Head, off Cox Peninsula, Darwin Harbour, NT, 12°29.103'S, 130°47.11 l'E, 8-14 m, 7 May 2002, coll. Alvarez, B and party Z.5836 Stevens Rock, 1.25 km SE Talc Head, off Cox Peninsula, Darwin Harbour, NT, 12°29.07TS, 130°47.103'E, 10-15m,9 May 2002, coll. Alvarez, B and party Z.5839 East Point, Fannie Bay, Darwin, Australia, 12° 24.48'S. 130°48.47'E, 11 m, 7 Jun 2007, coll. Alvarez, B Z.5840 East Point, Fannie Bay, Darwin, NT, 12° 24.49'S. 130° 48.43.. 14 m, 25 May 2007, coll. Alvarez. B Z.5841 East Point, Fannie Bay, Darwin, NT, 12° 24.49'S, 130" 48.43., 14 m, 25 May 2007, coll. Alvarez, B Z.5842 East Point, Fannie Bay, Darwin, NT, 12" 24.49'S, 130° 48.43., 14 m, 25 May 2007, coll. Alvarez, B Z.5843 Mengalum I., off Kota Kinabalu, Malaysia, 6 10.87'N, 115 35.97'E, 10-13 m, 24 Oct 2005, coll. Alvarez, B Z.5844 Stevens Rock, 1.25 km SE Talc Head, off Cox Peninsula, Darwin Harbour. NT, 12°29.103'S, 130°47.11 l'E, 8-14 m, 7 May 2002, coll. Alvarez, B and party 41 B. Alvarez and J. N. A. Hooper APPENDIX (continued) Collection and locality data of material examined in the collections of QM and NTM. NTM material Z.5848 Stevens Rock, Weed Reef, Darwin Harbour, NT, 12°29.17'S, 130°47.19'E, 14 in. 8 May 2006, coll. Alvarez, B Z.5853 Dawson Rock, 3 km SSE Rankin Point, Bynoe Harbour, NT, 12°42.2'S, 130°35.459'E, 3-12 m depth, 1 June 2005, coll. Alvarez, B Z.5854 Dawson Rock, 3 km SSE Rankin Point. Bynoe Harbour, NT, 12°42.2'S, 130°35.459’E, 3-12 m depth, 1 June 2005, coll. Alvarez, B Z.5855 Stevens Rock, 1.25 km SE Talc Head, off Cox Peninsula, Darwin Harbour, NT, 12°29.103'S, 130°47.11 l'E, 8-14 m, 7 May 2002, coll. Alvarez, B and party 42 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25: 43-54 Baudina gen. nov., constituting the first record of Pasytheidae from Australia, and Sinoflustridae fam. nov., with a checklist of Bryozoa and Pterobranchia from Beagle Gulf DENNIS P. GORDON National Institute of Water and Atmospheric Research, Private Bag 14901 Kilbirnie, Wellington, NEW ZEALAND d.gordon@niwa. co. nz ABSTRACT Baudina gen. nov., comprising two new species from the Beagle Gulf of Australia’s Northern Territory, is the first pasytheid bryozoan to be recorded from Australian continental waters. Colonies are wholly encrusting, forming uni- to triserial ramifying colonies. The zooids have the largest gymnocystal perforations of any other pasytheid, living or fossil. The new Baudina taxa constitute two of 84 bryozoan species so far known from Beagle Gulf, including Darwin Harbour. Sinoflustra Liu and Yang, 1995, a genus of uncertain affinity, is herein designated the type species of a new family, Sinoflustridae, which also includes Membraniporopsis Liu in Liu, Yin and Xia, 1999. The bryozoan diversity of the Beagle Gulf is small relative to what may be expected of tropical Indo-Pacific bryozoans for an area this size and it is likely that several hundred more species will be discovered upon further dedicated sampling. Keywords: Bryozoa, Pasytheidae, Sinoflustridae, new family, Baudina, new genus, Beagle Gulf, Darwin, Northern Territory, new genera, new species, taxonomy. INTRODUCTION This paper reports upon bryozoans collected in the Beagle Gulf by the former Conservation Commission of the Northern Territory (CCNT). A survey of the invertebrate fauna was made from the western side of Anson Bay (13°29.64'S, I29°51.00'E) to the eastern side of Cape Hotham (12°12.36'S, 131°23.22’E) in October 1993. The survey included 162 stations sampled by dredging in water depths of 4-39 m. Substrata sent to the author for examination included molluscan shell, and coral and bryozoan rubble. These were thoroughly examined for bryozoan diversity and a checklist of species was included as Appendix 3 in the final report of the survey by the then Parks and Wildlife Commission of the Northern Territory (Smit et al. 2000). The bryozoan diversity in the samples is representative of the tropical Indo-Pacific bryozoan fauna, with most of the species covered in the four-volume series on Bryozoa in the Siboga Expedition Reports (Hanner 1915,1926, 1934, 1957), for example. The most notable taxonomic discovery in the collection was two undescribed species representing a new genus of Pasytheidae, a family of cheilostomc bryozoans not previously recorded in Australian continental waters. A forthcoming volume on Australian bryozoans in the Australian Biological Resources Study Fauna of Australia series, which aims to be comprehensive in its coverage, necessitates fonnal description of these new taxa so that they can be included in the Fauna volume. The Pasytheidae currently comprises six genera. All are characterised by perforate gymnocystal frontal walls and the complete absence of ovicells and polymorphs like articulated oral spines and avicularia. Some species have stolons that ramify across the substratum and erect branches arise from these. The new genus discovered in the Beagle Gulf, is striking for the large size of the gymnocystal perforations and one of the two new species has a stout pair of non-articulated horn-like processes adjacent to the orifice. This paper formally describes the new genus and its constituent species and provides a checklist of all known species of bryozoans and pterobranchs in the vicinity of Darwin. MATERIAL AND METHODS Specimens collected during the survey were fixed in a 10% formalin-seawater solution on board the chartered fishing vessel Kunmunyah and later sorted by staff at the Museum and Art Gallery of the North Territory (NTM), Darwin. The new bryozoan species described below were studied by scanning electron microscopy (SEM), using type and other specimens. Sorted material was immersed in sodium hypochlorite solution to remove all cuticularised membranes and dried soft parts in preparation for SEM. All 43 D. P. Gordon specimens thus prepared were coated in gold-palladium and photographed using a LEO 440 SEM. Measurements of zooids were made directly from specimens using a light microscope (Zeiss Stereomicroscope SV-11) with an eyepiece graticule. Primary types of the new species are lodged at NTM. SYSTEMATICS Order Cheilostomata Busk, 1852 Suborder Neocheilostomina d’Hondt, 1985 Superfamily Hippothooidea Busk, 1859 Family Pasytheidae Davis, 1934 Genus Baudina gen. nov. Type species. Baudina geographae sp. nov. Gender. Feminine. Diagnosis. Colony encrusting, uni- to pluriserial, ramifying. Zooids with 5-15 relatively large gymnocystal perforations. Orifice circular, no condyles. Horn-like lateral- oral processes present or absent. No polymorphs or ovicells. Ancestrula with imperforate frontal gymnocyst. Budding of zooids lateral and/or distal. Etymology. The genus name honours Nicolas-Thomas Baudin, captain, explorer and leader of the 1800-1804 expedition of Geographe and Naturaliste to Australia (Dunmore 1969; Homer 1987; Gordon et al. 1998). Baudin’s voyage was tragically marred by the deaths of most of the savants on the voyage and by his own death from tuberculosis at Mauritius on the return trip; nevertheless, his expedition returned to Paris one of the most significant natural-history collections ever amassed during a single voyage. Owing to biased reporting of the expedition by Francis Peron, Baudin’s name was deliberately omitted from the official account and his personal achievement was inadequately appreciated for more than a century. Surprisingly, his name has not previously been commemorated in a genus and it is my desire to correct this oversight. Remarks. Baudina is clearly a member of the neocheilostome superfamily Hippothooidea, which comprises the hippothoomorph families Hippothoidae, Chorizoporidae, Trypostegidae and Pasytheidae. Allied with this group is the genus Haplopoma Levinscn, 1909. Often included in the lepralioid family Microporellidae (e.g. Hayward and Ryland 1999), it is gymnocystal- shielded and requires its own family. Although relatively character-poor, Baudina has distinctive features and the question is, to which of the above taxa is it most closely allied? flippothoidae and Chorizoporidae are ruled out on two counts - all species in these families have ovicells and lack frontal gymnocystal perforations. Additionally, orifices are sinusoid in Hippothoidae and hemispherical in Chorizoporidae. Both species of Baudina, described below, have gymnocystal foramina and circular orifices and lack ovicells. Species of Trypostegidae and Haplopoma have gymnocystal perforations, but all genera have ovicells. Additionally, many trypostegids have avicularium-like zooidal polymorphs while Haplopoma species have an ascopore and well-developed basal pore-chambers; none of these characters is found in Baudina. Taking all characters into consideration, Baudina is closest to the Pasytheidae. All genera in this family have perforated frontal shields and lack ovicells and other polymorphs. Further, the orifice is typically weakly sinusoid or subcircular. Baudina differs from other pasytheids less in zooidal morphology than in colonial morphology. Pasytheids form ramifying colonies (like Baudina ) but in these the zooids are mostly proximally attenuated, tending to claviform, are mostly basally jointed, and some species produce erect jointed branches, lacking in Baudina. Nevertheless, in general morphology, zooidal rows of Baudina naturalistae (below) are most similar to the unjointed linear chains of basal zooids in the pasytheid Gemellipora eburnea Smitt (see Gordon 1984; pi. 44A), which differs in the form of the orifice (slightly sinusoid, with condyles) and in having only tiny perforations and erect branches. The family Pasytheidae currently comprises the genera Pasythea Lamouroux, 1812, Dittosaria Busk, 1866, Gemellipora Smitt, 1873, Euteleia Marcus, 1938, Tecatia Morris, 1980 and Unifissurinella Poignant, 1991, with Baudina only the seventh genus to be recognised. Baudina differs from all other pasytheid genera in the large size of the gymnocystal foramina; zooids are also proximally unjointed but joints are not universal in Pasytheidae. Baudina geographae sp. nov. Figs 1-5 Holotype - NTM G.273 (unique specimen; no paratypes). Type locality. CCNT Beagle Gulf station 103, off Charles Point, 12°18.96'S, 130°40.74'E, 23 m depth, attached to the interior surface near the umbo of a dead valve of the spiny oyster Spondylus victoriae G.B. Sowerby II, 1869 (Bivalvia: Spondylidae) from a sandy mud and gravel bottom. Description. Colony encrusting, hyaline and inconspicuous, comprising uni- to pluriserial ramifying chains of zooids not more than 4 zooid rows wide. Zooids small, 347-438 pm long, 156-224 pm wide, with a smooth frontal shield that may have a slightly undulating surface. Gymnocystal foramina from 6 (post-ancestrular zooid to 15 per zooid, relatively large, 9-19 pm diameter. Orifice circular to slightly subcircular, 57-77 pm diameter, with no condyles or peristome. No articulated spines or avicularia. No ovicells. Ancestrula 250-262 pm long, 181-200 pm wide, with near-circular orifice 56-67 mm diameter; proximal end rounded, frontal shield smooth, imperforate, merging smoothly with gymnocyst of mid-distal daughter zooid. 44 A new family and a new genus of Bryozoa from Beagle Gulf Figs 1-5. Baudina geographae gen. nov., sp. nov., holotype: 1. whole colony, showing uni-pluriserial rows ofzooids; 2, part of colony showing bifurcations of zooid rows; 3, zooidal orifices; 4, ancestrula (proximal rim of orifice damaged) and daughter zooid; 5, damaged ancestrula (lower right) and daughter zooid, with a zooid row commencing from a lateral budding site on the daughter zooid. Scale bars in pm for Figs 2-5. 45 D. P. Gordon Further budding takes place mid-proximally from ancestrula and mid-distally from first daughter zooid, thus establishing a linear, uniserial chain in both directions; proximal end of daughter zooid originating from both sides of ancestrular orifice. Colony spread achieved by mid-lateral budding of some zooids in chain and by zooid bifurcation of those at each end of chain; zooids budded laterally have shortly tapering proximal ends. Ramifying zooid chains may merge and fuse. Etymology. The species name alludes to the Geographe, one of the vessels of the Baudin expedition. It is intended as a noun in apposition. Remarks. The unique holotype colony is known only from the type locality where it encrusted a shell fragment. Baudina naturalistae sp. nov. Figs 6-10 Holotype -NTM G.274. Paratype-NTM G.275, from same locality as holotype. Type locality. CCNT Beagle Gulf station 103, off Charles Point, 12°18.96'S, 130°40.74'E, 23 m depth, on the erect branching bryozoan Nellia tenella from a sandy mud and gravel bottom. Description. Colony encrusting, hyaline and inconspicuous, comprising uni- to biserial linear chains of zooids. Zooids very small, 224-291 pm long, 112-123 pm wide, with very smooth frontal shield. Gymnocystal foramina relatively large, 12-24 pm diameter, 5-6 per zooid, their rims very slightly elevated. Orifice circular, 67-72 pm diameter, no condyles, rim sometimes very slightly elevated. A stout, hollow, non-articulated horn-like process at each distolateral comer of orifice; when fully developed these curve and taper toward each other, almost meeting, forming an arch across orifice. No articulated spines or avicularia. No ovicells. Budding of zooids occurs distally, with branching occurring through the bifurcation of zooid rows. Ancestrula not seen. Etymology. The species name alludes to the Naturciliste, the second of the vessels of the Baudin expedition that set out from France in 1800. It is intended as a noun in apposition. Remarks. Colonies encrust erect branching cheilostome bryozoans. Two hosts have been encountered - Nellia tenella (Quadricellariidae) and Scrupocellaria diadema (Candidae), on both of which B. naturalistae may grow down the branch towards the substratum in the opposite growth direction to the host, or it may grow upwards in the same direction. On the latter host, B. naturalistae accommodates itself remarkably to the varied surface topography, with individual zooids achieving very twisted profiles (Fig. 10). The species is so far known only from the northeastern comer of Fog Bay to the Vernon Islands east of Cape Hotham at depths of 6 to 23 m. Order Cheilostomata Busk, 1852a Suborder Malacostegina Levinsen, 1902 Superfamily Membraniporoidea Busk, 1852b Family Sinofiustridae fam. nov. Diagnosis. Colony solely encrusting or producing erect unilaminar or bilaininar lobes or fronds from encrusting base. Zooids elongate-oval (neanic colonies) to rectangular, with a membranous frontal wall occupying entire frontal area. Cryptocyst narrow, usually granular, often developed more proximally and sometimes with horizontal spinous processes around opesia; gymnocyst typically absent but may be present or vestigial in periancestrular and some neanic zooids. Some zooids aviculariform, slightly larger than autozooids, expanded distally with large mandible- like opercula. Paired kenozooids budded distolaterally just below level of cryptocystal shelf but projecting frontalwards, having the form of short funnels or spines, with or without branching processes. Ancestrula single, bearing distolateral kenozooids. Reproduction involves many small ova, larval form unknown. Type genus. Sinoflustra Liu and Yang, 1995. Remarks. A specimen of Sinoflustra amoyensis (Robertson, 1921), the type species of Sinoflustra , was found at the Port of Darwin on an anthropogenic substratum in August 2002 and photographs of it were sent to the author for identification. The taxonomic status of this genus, and its family attribution, have been unclear and the opportunity is taken here to clarify the situation. The species was originally described as Membranipora amoyensis by Robertson (1921) from Amoy (Xiamen), China, encrusting a molluscan shell in water of presumed lowered salinity. It has since been found on the west coast of India (Menon and Nair 1967, 1975) and throughout the coast of southern China (Liu 1992) at depths of 0-25 m. Although the zooids of S. amoyensis and its congeners are membraniporiform, they have long been recognised as differing substantially in having polymorphs that resemble avicularia, which are otherwise unknown in malacostegine cheilostomes. These polymorphs are slightly larger than regular autozooids and were first described in Sinoflustra annae (Osbum, 1953) by Hastings (1930) [as Acantbodesia serrata sensu Hastings, non Hincks, 1882], who noted that they have a normal polypide and parietal muscles. Sinoflustra species also have a single ancestrula, not twinned as in membraniporids in the strict sense (see Taylor and Monks 1997). For these reasons, Liu and Yang (1995) established Sinoflustra , which they attributed to the neocheilostome family Flustridae. In addition to the type species S. amoyensis they also included A. annae. There is one other potential species, originally described as Alderina arabianensis Menon and Nair, 1975, but Liu and Yang (1995) included it in the synonymy of S. amoyensis. Curiously, Menon and Nair (1975) described both “ Membranipora amoyensis ” 46 A new family and a new genus of Bryozoa from Beagle Gulf figs 6-10. Baudina naturalistae sp. nov. (Iiolotype figs 6-9): 6, part of uniserial colony growing proximally on host colony of Nellia tenella; 7, close-up of zoo ids showing diagnostic characters of orificial processes and large gymnocystal foramina; 8. bifurcation of zooid row; 9, orifice and bases of orificial processes; 10, zooids on Scrupocellaria host. Scale bars in pm. 47 D. P. Gordon and “ Alderina arabianensis" in the same paper, each well illustrated, attributing them to different genera and families. Liu (1992), Liu and Yang (1995), and Liu et al. (2001) have discussed variability in this species, with the degree of calcification evidently related to salinity (Liu 1992); both spinosity (of opesial and kcnozooidal spines) and the relative size of the cryptocyst can vary among populations but the precise causes remain unknown. One other genus may be allied with Sinoflustra (Gordon et al. 2006), i.e. Membraniporopsis Liu in Liu, Yin and Xia, 1999, attributed by its author to the Membraniporidae. Like Sinoflustra it has distinctive distolateral kenozooids, but in the two known species of Membraniporopsis - M. bifloris (Wang and Tung, 1976) and M. tubigera (Osbum, 1940) - these are infundibuliform (somewhat funnel-shaped) with short lateral processes, not spine-like. Two other species may be allied with these genera. Although it has not yet been discovered to have avicularium-like polymorphs, Membranipora serrilamelloides Liu and Li, 1987 has short spine-like kenozooids like those of Sinoflustra annae and hence probably belongs to Sinoflustra. Conopeum tniitti Osbum, 1944 may be a species of Membraniporopsis. Osbum (1944) compared it to M. tubigera, commenting on the kenozooidal processes in the zooidal comers. They produce only cuticular tubercles frontally and it is not clear from Osbum’s illustrations how the kenozooids originate, so the question is open. Gordon et al. (2006) discussed the relationship between Sinoflustra and Membraniporopsis, concluding that the two genera were obviously closely related but remarked that, in the absence of information about embryos and/or larvae, choice of a family was uncertain (possibly Electridae or Flustridae), and noted that, if it should turn out that either of these genera should have planktotrophic larvae, then a new family should be created to accommodate them. In the event, McCann et al. (2007) [who, like Gordon et al. (2006), provisionally included Sinoflustra in the Flustridae] noted that Karande and Udhayakumar (1992) had also given some information on reproduction in S. annae from western India. In Mumbai harbour waters, S. annae co¬ occurs with three other malacostegine species, all of which have relatively large numbers of small eggs, as is typical of forms that produce planktotrophic cyphonautes larvae. Although Karande and Udhayakumar (1992) did not record cyphonautes larvae in the harbour plankton or attribute such larvae to S. annae, they noted that reproductive zooids of S. annae contained six to seven small eggs. This is conclusive evidence that Sinoflustra is a malacostegine cheilostome, not a neocheilostome. Accordingly, a new family, Sinoflustridae, is created here for the constituent genera Sinoflustra (two or three species) and Membraniporopsis (two or three species). The Sinoflustridae differs from the Membraniporidae chiefly in having a non-twinned ancestrula and from the Electridae in having distinctive polymorphs - the avicularium-like zooids in Sinoflustra and the distolateral kenozooids in both genera. CHECKLIST OF BRYOZOA FROM BEAGLE GULF AND DARWIN HARBOUR The checklist of species mostly comprises bryozoans collected during the CCNT surveys (station data in Appendix 1), to which have been added Ampbibiobeania epiphylla, a remarkable endemic genus and species of mangrove epiphyte (Metcalfe et al. 2007), plus some alien species reported by Russell and Hewitt (2000) and Sinoflustra amoyensis, found in Darwin Harbour on anthropogenic substrata. There is a range of colonial morphologies. Of the indigenous species, 26 (33%) are two-dimensional encrusters. This is a smaller proportion of this morphology than would be expected for the total range of habitats available in the Darwin region and may be an artifact of sampling or, what is more likely, subsequent sorting of samples sent for analysis. It is usual for visually obvious erect and large bryozoans to be collected in the field by non- bryozoologists, whereas relatively high diversities of small encrusting species can found on dead molluscan shells, and the samples analysed by the author contained very little such material. Ten additional encrusters form more or less inconspicuous ramifying uni-pluriserial colonies. Fifteen species form fixed-erect colonies that may be tree-like, reticulate or planar from a relatively small attachment point. Nine species (mostly species of Celleporaria plus Cigclisula occlusa) start life as two-dimensional encrusters but soon become mounded and/or erect and coralline owing to frontal budding of zooids that results in thick, rigid multilamcllate colonies. Several of the Celleporaria species are large and robust, serving as important substrata for other bryozoans. The most important of these are C. oculata and C. fusca, which resemble small corals - the latter bore 14 other cheilostome species. One striking growth form is free- living (vagrant), with two exemplars in the Darwin area, viz Cupuladria guineensis and Selenaria punctata, which form discoidal colonies that live on sandy substrata. Russell and Hewitt (2000) reported five species of alien/cryptogenic bryozoans from the vicinity of the Port of Darwin. Bugula neritina, Savignyella lafontii and Watersipora subtorquata are distinctive and easily recognised; the records of Amathia distans and Zoobottyon verticillatum need confirming on the basis of voucher specimens in so far as A. distans may be confused with native Amathia species and Z. verticillatum has some similarities to native Vesicularia papuensis. ACKNOWLEDGEMENTS Thanks are due to Leandro M. Vieira (University of Sao Paulo) for his helpful comments on the manuscript. Research on the collection was funded by the New Zealand Foundation for Research, Science and Technology (Contract CO 1X0502). 48 A new family and a new genus of Bryozoa from Beagle Gulf CHECKLIST OF BRYOZOA OF BEAGLE GULF (CCNT Beagle Gulf station numbers given for those species collected during the survey) Phylum BRYOZOA Ehrenberg, 1831 Class STENOLAEMATA Borg, 1926 Order CYCLOSTOMATA Busk, 1852 Suborder TUBUL1PORINA Johnston, 1847 Superfamily TUBULIPOROIDEA Johnston, 1838 Family TUBULIPOR1DAE Johnston, 1838 Idmidronea sp. BG/95 Family TERVIIDAE Canu and Bassler, 1920 Nevianipora pulcherrima (Kirkpatrick, 1890) BG/95 Suborder ART1CULINA Busk, 1959 Superfamily CRISIOIDEA Johnston, 1838 Family CRISI1DAE Johnston, 1838 Crisia elongata Milne Edwards, 1838 BG/69, BG/95, BG/122, BG/148, BG/153 Class GYMNOLAEMATA Allman, 1856 Order CTENOSTOM ATA Busk, 1852 Suborder EUCTENOSTOMATINA Jebram, 1973 Superfamily ARACHNIDIOIDEA Hincks, 1880 Family NOLELL1DAE Hamier, 1915 Nolella papuensis (Busk, 1886) BG/103 Superfamily WALKERIOIDEA Hincks, 1877 Family AEVERRILLI1DAE Jebram, 1973 Aeverrillia setigera (Hincks, 1887) BG/42, BG/67, BG/69 Family WALKERIIDAE Hincks, 1877 Walkeria atlcintica (Busk, 1886) BG/27 Superfamily VES1CULARIOIDEA Johnston, 1847 Family VESICULARIIDAE Johnston, 1847 Amathia crispa (Lamarck, 1816) BG/26, BG/46, BG/91, BG/95, BG/160 Amathia sp. BG/69 Vesicularia papuensis Busk, 1886 BG/72, BG/73 Order CHEILOSTOMATA Busk, 1852 Suborder INOV1CELLINA Jullien, 1888 Superfamily AETEOIDEA Smitt, 1867 Family AETEIDAE Smitt, 1867 Aetea anguina (Linnaeus, 1758) BG/121 Aetea tnmcata (Landsborough, 1852) BG/103, BG/122 Suborder MALACOSTEGINA Levinsen, 1902 Superfamily MEMBRAN1POROIDEA Busk, 1852 Family MEMBRANIPORIDAE Busk, 1852 Bi/lustra savartii auctt. BG/38, BG/57, BG/91, BG/119 Jellyella tuberculata (Bose, 1802) BG/78 Family SINOFLUSTRIDAE fam. nov. Sinoflustra amoyensis (Robertson, 1921) Port of Darwin Suborder NEOCHE1LOSTOMINA d’Hondt, 1985 Superfamily CALLOPOROIDEA Norman, 1903 Family ANTROPORIDAE Vigneaux, 1949 Parantropora laguncula (Canu and Bassler, 1929) BG/122, BG/160 Family CALLOPORIDAE Norman, 1903 Parellisina curvirostris (Hincks, 1862) BG/38 Family CUPULADRIIDAE Lagaaij, 1952 Cupuladria guineensis (Busk, 1854) BG/27, BG/28, BG/33, BG/49, BG/77, BG/79, BG/91, BG/97, BG/101, BG/105, BG/113, BG/116, BG/117, BG/123 Family QUADRICELLARI1DAE Gordon, 1984 Ncilia tenella (Lamarck, 1816) BG/27, BG/36, BG/38, BG/40, BG/54, BG/67, BG/69, BG/73, BG/95, BG/103, BG/116, BG/119, BG/120, BG/126, BG/144, BG/153 Family FLUSTRIDAE Fleming, 1828 Retiflustra cornea (Busk, 1852) BG/78, BG/82, BG/110, BG/111, BG/127, BG/136, BG/150, BG/159, BG/160, BG/161 Superfamily BUGULOIDEA Gray, 1848 Family BEANUDAE Canu and Bassler, 1927 Amphibiobeania epiphylla Metcalfe, Gordon and Hayward, 2007 Darwin Harbour Beania regularis Thornely, 1916 BG/38, BG/67, BG/91, BG/95 Family BUGUL1DAE Gray, 1848 Bugula neritina (Linnaeus, 1758) Russell and Hewitt 2000 Port Darwin Bugula robusta MacGillivray, 1869 BG/95, BG/137 Bugula vectifera Planner, 1926 BG/95 Family EP1STOMIIDAE Gregory, 1893 Synnotum aegyptiacum (Audouin, 1826) BG/160 Synnotum pembaense Waters, 1913 BG/122 Family CAND1DAE d’Orbigny, 1851 Caberea lata Busk, 1852 BG/48, BG/67, BG/69, BG/73, BG/84, BG/95 Scrupocellaria curvata Hanner, 1926 BG/88, BG/144 Scrupocellaria diadema Busk, 1852 BG/38, BG/40, BG/48, BG/69, BG/84, BG/88, BG/91, BG/95, BG/97, BG/103, BG/113, BG/116, BG/119, BG/121, BG/135, BG/141, BG/160 Scrupocellaria longispinosa Hanner, 1926 BG/95, BG/103 Scrupocellaria spatulata (d’Orbigny, 1851) BG40, BG/95 Superfamily MICROPOROIDEA Gray, 1848 Family CHLIDONIIDAE Busk, 1884 Crepis verticillata Hanner, 1926 BG/91, BG/93, BG/95, BG/103, BG/106, BG/120, BG/121, BG/144, BG/153 Family SELENAR1IDAE Busk, 1854 Selenaria punctata Tenison-Woods, 1880 BG/27, BG/47, BG/49, BG/97 Family STEGINOPORELLIDAE Hincks, 1884 Steginoporella dilatata Harmer, 1926 BG/27, BG/127, BG/158 49 D. P. Gordon Family THALAMOPORELLIDAE Levinsen, 1909 Thalamoporella novaehollandiae (Haswell, 1880) BG38 Superfamily CELLARIOIDEA Lamouroux, 1821 Family CELLARIIDAE Lamouroux, 1821 Cellariapunctata (Busk, 1852) BG/40, BG/69, BG/95 Suborder ASCOPHORINA Levinsen, 1909 Superfamily CRIBRILINOIDEA Hincks, 1879 Family CR1BRILINIDAE Hincks, 1879 Puellina sp. BG/97 Superfamily CATENICELLOIDEA Busk, 1852 Family CATENICELLIDAE Busk, 1852 Catenicella uberrima Harmer, 1957 BG/67, BG/69, BG/95, BG/103, BG/116, BG/121, BG/137 Family SAVIGNYELLIDAE Savignyella lafontii (Audouin, 1826) Russell and Hewitt 2000 Port Darwin Superfamily HIPPOTHOOIDEA Busk, 1859 Family HIPPOTHOIDAE Busk, 1859 Hippothoa calciophilia Gordon, 1984 BG/95, BG/103, BG/119 Family PASYTHE1DAE Davis, 1934 Baudina geographae Gordon, described herein BG/103 Baudina naturalistae Gordon, described herein BG/69, BG/95, BG/103, BG/106, BG/119, BG/122, BG/144, BG/153 Superfamily LEPRALIELLOIDEA Vigneaux, 1949 Family LEPRALIELLIDAE Vigneaux, 1949 Celleporaria aperta (Hincks, 1882) BG/119 Celleporaria discoidea (Busk, 1881) BG/85, BG/91, BG/92, BG/94, BG/97, BG/113, BG/121 Celleporariafusca (Busk, 1854) BG/38, BG/103, BG/113, BG/121 Celleporaria granulosa (Haswell, 1880) BG/38 Celleporaria oculata (Lamarck, 1816) BG/38, BG/40, BG/48, BG/69, BG/84, BG/88, BG/119, BG/121, BG/122, BG/136, BG/141, BG/144 Celleporaria sibogae Winston and Heimberg, 1986 BG/38, BG/40, BG/46, BG/84, BG/85, BG/92 BG/95, BG/103, BG126, BG/127, BG/160 Celleporaria tridenticulata (Busk, 1881) BG/144 Celleporaria sp. BG/121 Superfamily ADEONOIDEA Busk, 1884 Family ADEONIDAE Busk, 1884 Adeona foliifera Lamarck, 1816 BG/26, BG/81, BG/84, BG/88, BG/93, BG/95, BG/97, BG/99, BG/103, BG/114, BG/119, BG/120, BG/131 BG/143, BG/144 Adeonella intricaria Busk, 1884 BG/50, BG/72, BG/78, BG/83, BG/88, BG/95, BG/103, BG/127 BG/152, BG/160 Adeonella lichenoides (Lamarck, 1816) BG/27, BG/38, BG/40, BG/50, BG/69, BG/80, BG/81, BG/82, BG/95, BG/119, BG/124, BG/147 Superfamily SCHIZOPORELLOIDEA Jullien, 1883 Family SCHIZOPORELL1DAE Jullien, 1883 Schizobrachiella subhexagona (Ortmann, 1890) BG/103, BG/119 Stylopoma duboisii (Audouin, 1826) BG/103 Thomelyaperarmata Harmer, 1957 BG/36 Family HIPPOPODIN1DAE Levinsen, 1909 Hippopodina feegeensis (Busk, 1884) BG/121, BG/122 Family CHE1LOPORINIDAE Bassler, 1936 Cheiloporina haddoni (Harmer, 1902) BG/38 Family LANCEOPORIDAE Harmer, 1957 Calyptotheca australis (Haswell, 1880) BG/38, BG/91, BG/103, BG/119, BG/121, BG/142 Calyptotheca inaequalis Manner, 1957 BG/103 Calyptotheca wasinensis (Waters, 1913) BG/38, BG/88, BG/92, BG/93, BG/95, BG/122, BG/126 Calyptotheca sp. BG119, BG/121, BG/126, BG/152 Family COLATOOEC1IDAE Winston, 2005 Cigclisula occlusa (Busk, 1884) BG/38, BG/69, BG/78, BG/91, BG/95, BG/126, BG/136, BG/144, BG/160 Family PORINIDAE d’Orbigny, 1852 Porina longicollis (Canu and Bassler, 1929) BG/69 Porina vertebralis (Stolickza, 1865) BG/38, BG/40, BG/42, BG/57, BG/67, BG/87, BG/144 Family MARGARETT1DAE Harmer, 1957 Margaretta tenuis Harmer, 1957 BG/40, BG/148 Family PETRALIELL1DAE Harmer, 1957 Hippopetraliella dorsiporosa (Busk, 1884) BG/40, BG/95, BG/97 Mucropetraliella loculifera Hanner, 1957 BG/38, BG/48, BG/95, BG/103, BG/132, BG/136 Mucropetraliella serrata (Livingstone, 1926) BG/95 Petraliella arafurensis Stach, 1936 BG/81 Superfamily SMITTINOIDEA Levinsen, 1909 Family SMITTINIDAE Levinsen, 1909 Parasmittina hastingsae Soule and Soule, 1973 BG/91 Parasmittina vaettramosa Lu, Nie and Zhong MS in Lu, 1991 BG/38, BG/48, BG/91, BG/113, BG/116, BG/119, BG/121, BG/122, BG/124, BG/126, BG/132 Family WATERSIPORIDAE Watersipora subtorquata (d’Orbigny, 1852) Russell and Hewitt 2000 Port Darwin Superfamily MAMILLOPOROIDEA Canu and Bassler 1927 Family CLEIDOCHASMATIDAE Cheetham and Sandberg, 1964 Characodoma laterale (Harmer, 1957) BG/92 Superfamily CELLEPOROIDEA Johnston, 1838 Family CELLEPORIDAE Johnston, 1838 Turbicellepora sp. BG/69, BG/95 50 A new family and a new genus of Bryozoa from Beagle Gulf Family PHIDOLOPORIDAE Gabb and Horn, 1862 Iodictyum gibberosum (Buchner, 1924) BG/121, BG/149 Reteporella graeffei (Kirchenpauer, 1869) BG/40, BG/46, BG/89, BG/103, BG/148 Reteporella granulata (MacGillivray, 1869) BG/149 Rhynchozoon bifurcum Harmer, 1957 BG/38, BG/78, BG/97, BG/142, BG/152, BG/160 Rhynchozoon incrassatum (Hincks, 1882) BG/67, BG/92 Schedocleidochasma poreellaniforme Soule, Soule and Chaney, 1991 BG/91 Triphyllozoon benemunitum (Hastings, 1932) BG/36, BG/38, BG/39, BG/40, BG/46, BG/48, BG/50, BG/52, BG/67, BG/69, BG/71, BG/81, BG/92, BG/93, BG/95, BG/97, BG/121, BG/129, BG/132, BG/136, BG/137, BG/140, BG/141, BG/142, BG/154, BG/155, BG/156, BG/158 Triphyllozoon hirsutum (Busk, 1884) BG148 Triphyllozoon tabulation (Busk, 1884) BG/40, BG/103, BG/121 Phylum HEMICHORDATA Bateson, 1885 Class PTEROBRANCHIA Lankcster, 1877 Order RHABDOPLEURIDA Fowler, 1893 Family RHABDOPLEURIDAE Harmer, 1905 Rhabdopleura annulata Harmer. 1905 BG/121, BG/126, BG/144 DISCUSSION The total of 84 bryozoan species in the Beagle Gulf samples is small relative to what may be expected of tropical Indo-Pacific bryozoans for an area this size and it is likely that several hundred more species will be discovered upon further dedicated sampling. 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[In Chinese with English summary] Accepted 4 September 2009 52 A new family and a new genus of Bryozoa from Beagle Gulf APPENDIX: CCNT BEAGLE GULF (BG) STATION DATA (All samples collected 3-9 October 1993) Stn No. Location Latitude S Longitude E Depth (m) Substratum 26 Anson Bay 13° 16.08 129°55.92 23 Coarse sand, shale, gravel 27 Anson Bay 13°15.90 129°58.86 19 Coarse sand 28 Anson Bay 13° 15.96 130°01.86 20 Coarse sand, shale 33 Anson Bay 13°13.26 130°01.92 9 Coarse sand, shale 36 Anson Bay 13°10.26 129°55.62 15 Coarse sand, shale 38 Anson Bay 13°09.24 130°05.52 20 Barnacle-encrusted gravel 39 Peron Islands 13°07.08 129°56.04 15 Coarse sand, mud 40 Peron Islands 13°06.96 129°58.86 8 Fine mud, rocks 42 Peron Islands 13°04.44 129°56.10 14 Coarse sand, shale 46 Peron Islands 13°00.90 129°58.92 14 Coarse sand, shale 47 Peron Islands 13°00.96 130°01.92 17 Coarse sand, shale 48 Peron Islands 13°00.06 130°04.98 13 Mud, shale, sand 49 Peron Islands 13°57.90 130°01.92 16 Mud 50 Peron Islands 13°57.96 130°04.98 10 Sandy mud 52 Fog Bay 12°54.96 130°07.98 7 Mud, shale 54 Fog Bay 12°54.96 I30°15.60 4 Sandy mud 57 Fog Bay 12°51.96 130° 14.10 7 Mud, shale 67 Bynoe Harbour 12°40.92 130°33.I2 9 Coarse sand, shale 69 Fog Bay 12°40.02 130°19.92 6 Mud 71 Grose Islands 12°36.96 130° 16.98 13 Mud 72 Port Patterson 12°35.76 130°26.22 3 Fine sand, silt 73 Port Patterson 12°37.08 130°28.08 14 Mud 77 Port Patterson 12°33.60 130°27.90 16 Sandy mud, gravel 78 Bynoe Harbour 12°34.02 130°32.04 28 Coarse sand, shale, gravel 79 Grose Islands 12°31.02 130° 14.04 19 Sand 80 Grose Islands 12°31.02 130° 17.22 17 Coarse sand, shale, gravel 81 Grose Islands 12°31.02 130°20.04 15 Gravel (sponge bed) 82 Grose Islands 12°30.96 130°22.92 9 Coarse sand, gravel 83 Bynoe Harbour 12°31.02 130°28.98 28 Sandy mud, gravel 84 Bynoe Harbour 12°31.20 130°31.74 11 Coarse sand, gravel 85 Grose Islands 12°27.96 130°20.16 19 Coarse sand, shale, mud 87 Grose Islands I2°27.90 130°26.70 6 Coarse sand 88 Bynoe Harbour 12°28.02 130°28.98 38 Mud. gravel, rocks 89 Bynoe Harbour 12°28.80 130°32.10 14 Mud, gravel 91 Grose Islands I2°25.44 130°25.92 19 Mud, gravel 92 Bynoe Harbour 12°24.84 130°28.92 17 Coarse sand, gravel 93 Bynoe Harbour 12°24.96 130°31.98 29 Sandy mud 94 Charles Point 12°21.96 130°28.74 34 Mud, gravel 95 Charles Point 12°21.90 130°31.92 15 Gravel (sponge bed) 97 Charles Point 12°21.84 130°37.86 14 Coarse sand, shale 99 Darwin Harbour 12°22.14 I30°43.98 20 Sandy mud, shale 101 Charles Point 12° 19.02 130°34.02 19 Sand, gravel, mud 103 Charles Point 12° 18.96 130°40.74 23 Sandy mud, gravel 105 Darwin Harbour 12° 19.02 130°47.10 15 Muddy sand, shale, seagrass 106 Darwin Harbour 12° 19.08 130°50.04 12 Mud, gravel, shale 110 Charles Point 12°15.84 130°37.86 27 Sandy mud 111 Charles Point 12° 16.08 130°40.98 28 Sandy mud 113 Darwin Harbour 12° 15.84 130°47.22 20 Sandy mud, shale 114 Darwin Harbour 12° 16.08 130°50.04 18 Mud. gravel, shale 116 Shoal Bay 12° 15.96 130°55.86 13 Sandy mud, seagrass 117 Shoal Bay 12° 16.08 130°58.98 9 Mud 119 Darwin Harbour 12° 12.90 130°47.04 23 Mud 120 Darwin Harbour 12°13.02 130°50.04 22 Coarse sand, shale, mud 53 D. P. Gordon APPENDIX: CCNT BEAGLE GULF (BG) STATION DATA (continued) (All samples collected 3-9 October 1993 121 Shoal Bay 12° 13.02 130°52.92 19 Mud 122 Shoal Bay 12° 13.08 130°55.98 17 Sandy mud, sparse seagrass 123 Shoal Bay 13°13.02 130°58.98 13 Sandy mud 124 Adam Bay 13° 12.36 13I°12.72 6 Sandy mud, shale, gravel 126 Darwin Harbour 13° 10.08 130°46.92 30 Mud, gravel 127 Darwin Harbour 13° 10.02 130°49.86 27 Coarse sand, shale, mud 129 Shoal Bay 13°09.96 130°56.10 15 Gravel 131 Gunn Point 12°09.36 131°08.22 4 Sandy mud 132 Adam Bay 12° 10.02 131 °11.40 4 Sandy mud, shale, gravel 135 Chambers Bay 12°09.84 I31°23.22 7 Mud 136 Shoal Bay 12°06.90 130°49.92 18 Sponge bed 137 Shoal Bay 12°07.02 130°52.92 20 Sponge bed 140 Vernon Islands 12°06.90 131°04.80 13 Coral rubble 141 Vernon Islands 12°07.02 131°07.02 20 Large rock 142 Adam Bay 12°06.90 131 ° 11.04 11 Gravel 143 Adam Bay 12°07.02 131 ° 13.98 9 M ud, shale, gravel 144 Chambers Bay 12°07.08 131°20.04 22 Shale, coral rubble 147 Vernon Islands 12°04.02 131 °58.86 33 Shale, gravel 148 Vernon Islands 12°03.96 131 °01.92 25 Large rock 149 Vernon Islands 12°04.98 DUOS.40 26 Gravel, shale, sand 150 Vernon Islands 12°03.96 131°11.10 22 Gravel 152 Cape Hotham 12°04.02 131 °20.04 21 Shale 153 Cape Hotham 12°04.08 131 °22.80 6 Sponge bed 154 Vernon Islands 12°01.02 130°58.86 30 Rocky bottom 155 Vernon Islands 12°01.02 131°01.86 38 Shale, gravel 156 Vernon Islands 12°01.20 131°03.96 22 Coarse sand, shale, rocks 158 Vernon Islands 12°01.08 131 0 11.04 20 Gravel, sand 159 Cape Hotham 12°01.32 131° 13.92 34 Coarse sand, shale 160 Cape Hotham 12°00.96 131 ° 16.92 29 Coarse sand, shale, gravel 161 Cape Hotham 12°00.96 13I°19.86 22 Coarse sand, shale 54 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25 : 55-63 A new species and new records of the anthozoan commensal genus Alcyonosyllis (Polychaeta: Syllidae: Syllinae) CHRISTOPHER J. GLASBY 1 and M. TERESA AGUADO 2 ‘Museum and Art Gallery Northern Territoiy, GPO Box 4646, Darwin NT 0801, AUSTRALIA chris.glasby@nt.gov.au 2 Departamento de Biologia (Zoologia), Universidad Autonoma de Madrid, Canto Blanco, 28049 Madrid, SPAIN maite. aguado@uam. es ABSTRACT A new species of Alcyonosyllis (Polychaeta: Syllidae),/!. hinterkircheri, is described from a scleractinian coral, Goniopora cf. stokesi Edwards and Haime (Poritidae) from shallow coastal waters near Bohol Island, Philippine Islands. It represents the first record of an Alcyonosyllis species on a scleractinian coral and the first record of a commensal polychaete on a Goniopora species. The new polychaete differs from other described species of Alcyonosyllis in having long, slender dorsal cirri exhibiting a strong, long-short alternation pattern over the entire body; in its olive-green colour pattern; and that all chaetae are unidentate. Also, new records of the type species of the genus, A. phili Glasby and Watson, 2001, from Australia and the Philippine Islands extend the known range of this species. Lastly, a possible new species from Sumba, Indonesia, similar to A. xeniaecola (Hartmann-Schroder, 1993) is mentioned but not formally described because only one specimen is known to date. A dichotomous key is provided to distinguish the seven species known with certainty in the genus. Keywords: Annelida, Polychaeta, Syllidae, Alcyonosyllis, coral, octocoral, taxonomy, systematics, symbiotic, aquarium. INTRODUCTION The anthozoan commensal polychaete genus Alcyonosyllis Glasby and Watson, 2001 is so far only known from the Indo-west Pacific and the Red Sea. Five species are presently known, all from octocorals. The type species, A. phili Glasby and Watson, 2001 occurs on soft corals of the family Nephtheidae and gorgonians ( Melithaea sp., family Melithaeidae) and it is known from the tropical northern half of Australia and New Guinea; A. goigoniacolo (Sun and Yang, 2004) from an unidentified orange-red gorgonian from Chenhang Islands, Paracel Group, South China Sea [nation disputed]; A. glasbyi San Martin and Nishi, 2003 from Izu Peninsula, Japan, is also commensal with a Melithaea species; A. xeniaecola (Hartmann- Schroder, 1993) from Maluku, Indonesia, is commensal on the octocoral Xenia; and A. bisetosa (Hartmann-Schroder, 1960) from Gubal, Red Sea, from an octocoral. The genus could contain further species having compound chaetae in addition to the characteristic simple hooks, including Syllis onkylochaeta Hartmann-Schroder, 1991, Syllis exiliformis Imajima, 2003 and other similar species currently assigned to Syllis (sensu San Martin and Nishi, 2003; Aguado el al., 2008). However, in this paper we will only consider those species that coincide with the type species A. phili in having only simple chaetae. Recent collections by Johann Hinterkircher in 2004 and 2008 in shallow coastal waters around Bohol Island, Philippine Islands, have yielded an undescribed Alcyonosyllis species living on a scleractinian coral, Goniopora cf. stokesi Edwards and Haime (Poritidae). The specimens are herein described as a new species. The 2004 collecting trip also yielded a specimen of Alcyonosyllis phili, commensal on a gorgonian, making this the northern-most record for this species. Other specimens of A. phili from northern Australia, previously misidentified as belonging to the Pilargidae in the collection of the Museum and Art Gallery of the Northern Territoiy, Darwin, are also reported and new information is provided on the distribution and habitat of this species. In addition, a specimen of Alcyonosyllis from Sumba, Indonesia, collected on the Dutch-Indonesian Snellius II Expedition (1984-1985) to Indonesian waters is also described; although it resembles A. xeniaecola, it possibly represents a new species, but further material is required before formally naming it. Given the occurrence of all species of Alcyonosyllis on both octocorals and scleractinian corals, it is likely that further specimens of existing and new species, will be collected by persons within the aquarium trade. Images of Alcyonosyllis species on their hosts in aquaria are already circulating among these persons (Leslie Harris pers. comm.), but unfortunately species of Alcyonosyllis cannot be recognised by colour pattern alone and definitive identification will require examination of appropriately preserved specimens. 55 C. J. Glasby and M. T. Aguado MATERIAL AND METHODS All specimens were fixed in a 10% formaldehyde- seawater solution and preserved in a 70% ethanol solution. Observations were made using an Olympus SZ30 stereomicroscope and an Olympus CH30 compound microscope. Drawings were made to scale, with a camera lucida drawing tube on a Nikon Optiphot microscope equipped with differential interference contrast optics (Nomarsky). Observations on A. hinterkircheri were made using a Nikon SMZ 1500 stereomicroscope and a Nikon Eclipse 80i compound microscope with Nomarsky optics and photographs were made on both microscopes using a Qimaging Micropublisher 5.0 RTV digital camera. The width of specimens was measured at the level of the proventricle, excluding parapodia. One paratype (NTM W.23000) of A. hinterkircheri sp. nov. was dissected ventrally in order to describe features of the anterior gut. The studied material is deposited at the Museum and Art Gallery of the Northern Territory, Darwin (NTM; formerly Northern Territory Museum) and the Museum of Natural History, Naturalis, Leiden (RMNH; formerly Rijks Museum van Natuurlijke Historic). Comparative material on loan from the Forschungsinstitut und Naturmuseum Senckenberg, Frankfurt (SMF) and the Zoologisches Museum, Universitat Hamburg, Hamburg (HZM) was also examined. TAXONOMY Family Syllidae Grube, 1850 Subfamily Syllinae Grube, 1850 Genus Alcyonosyllis Glasby and Watson, 2001 Gender feminine. Type species, by original designation, Alcyonosyllisphili Glasby and Watson, 2001. Recent, indo- west Pacific Ocean. Diagnosis. Syllinae with long body and large number of chaetigers. Prostomium with 2 pairs of eyes, 3 antennae; palps free to base. Nuchal organs as inconspicuous ciliated ridge between prostomium and tentacular segment. Two pairs of tentacular cirri. Antennae, tentacular-, dorsal-, and anal cirri unarticulated to weakly articulated. Dorsal cirri showing typical syllid length-alternation pattern, LSSLSLSSLSLSLSLS..., with long (L) type displaced dorsally and sometimes substantially thicker than short ones. Ventral cirri present, extending short of, or beyond, parapodial lobes. Parapodia uniramous, bearing I or 2 types of subacicular simple hook chaetae, both with subdistal boss. One to several aciculae per parapodium, tapered or distally rounded. Pygidium with paired anal cirri. Pharynx with single antcrodorsal tooth and 10 ciliated terminal papillae; trepan absent. Reproduction by schizogamy, single stolons attached to parental body in posterior (= terminal) position; parent regenerates new posterior end ventral to the stolon prior to its detachment. Remarks. The diagnosis of the genus is broadened slightly in this work to account for the weakly articulated dorsal cirri in the new species described below. Alcyonosyllis and Haplosyllides are among a few Syllinae genera that do not have strongly articulated dorsal cirri, a feature considered to be the result of a reversal to the plesiomorphic condition by Aguado and San Martin (2009). In the occurrence of simple chaetae only in parapodia, Alcyonosyllis resembles Haplosyllis, Haplosyllides, Parahaplosyllis and Trypanoseta and some species of Syllis ; however, as the form of the simple chaetae differs significantly between these taxa, it is highly likely that each has acquired them independently, and that those in Alcyonosyllis represent an adaptation to symbiosis with a cnidarian host. In addition, stolons of Alcyonosyllis are attached terminally to the parental body (Glasby and Watson 2001; San Martin and Nishi 2003; Aguado and San Martin 2009) and a new posterior end is regenerated ventrally to the stolon before its release (Fig. 3D). This ability has been reported only in four other Syllinae: Haplosyllis, Megasyllis, Parahaplosyllis and Trypanosyllis (Martin el al. 2002; Aguado and San Martin 2009). In most Syllinae, stolons appear terminally but the posterior end does not regenerate until the stolon is detached. Glasby and Watson (2001) list several other differences between Alcyonosyllis and other syllid genera that have simple chaetae. The following key provides a means of identifying all species currently known in the genus including A. gorgoniacolo, which was recently transferred from Haplosyllis by Lattig and Martin (2009). Key to species of Alcyonosyllis la. A single chaeta (occasionally 2) of 1 type per parapodium. A. glasbyi lb. More than one chaeta (usually 2-4), of 2 types per parapodium.2 2a. Dorsal cirri highly dimorphic (longer ones very thick and arising higher on dorsum than short ones); several aciculae per parapodium.3 2b. Dorsal cirri all slender, though may differ slightly in length and elevation; 1-2 aciculae per parapodium. .4 3a. Each parapodium with 1-3 chaetae; smaller types with minute subdistal tooth. A. phili 3b. Each parapodium with 3-5 chaetae; smaller types without subdistal tooth. A. gorgoniacolo* 4a. Dorsal cirri with strong length-alternation pattern over whole body; dorsal cirri weakly articulated (most obvious anteriorly).5 4b. Dorsal cirri on posterior chaetigers more or less same length (greater than body width); dorsal cirri smooth . A. xeniaecola 5a. Large species; chaetae all unidentate; 2-6 aciculae.... . A. hinterkircheri sp. nov. 56 New species and new records of Alcyonosyllis 5b. Small species; some cliaetae bidentate; 1-2 aciculae.. .6 6a. Bidentate chaetae with subdistal tooth just below primary tooth; aciculae in anterior parapodia very large. Alcyonosyllis sp. (mentioned below) 6b. Bidentate chaetae with subdistal tooth well below primary tooth (1/3 way to boss); aciculae in anterior parapodia not enlarged. A. bisetosa * This is the correct spelling of this specific name. Wc believe the specific name gorgoniacolo was intended as a noun in apposition by Sun and Yang (2004: 313) and could not have been a lapsus or printer’s error at the point of first introduction (which might have been grounds for emending it) since it is spelt consistently in this same form in four other places in the original description. Accordingly, the change to gorgoniacolo (sic) by Lattig and Martin (2009: 37) is not followed here. Alcyonosyllis hinterkircheri sp. nov. (Figs 1-3, 4A, Table 1) Material examined. Holotype - Philippine Islands, Panglao Island, south-west of Bohol Island, Alona Beach 3 km from Panglao City (9°34.683’N, 123°44.75’E), 1-4 m, coll. Johann Hinterkirchcr, 4 October 2004, NTM W.22998 Paratypes- same collection details as for holotype, 1 (NTM W.22999); same location as holotype but 0.5-1.5 m, coll. Johann I linterkircher, October 2008, 3 (NTM W.23000). Description (based on holotype, except where indicated otherwise). Holotype 53 mm long, 0.13 mm wide, with 178 segments; developing female stolon at rear end. Paratypes 88-102 mm long, 1.3-1.5 mm wide, with 194-242 segments; one paratype (NTM W.23000) with well-developed female stolon at rear of body. Body of similar width throughout, tapering over first and last several segments. Dorsum highly convex, venter more or less flat. Body pigmentation (olive green in life, faded to light brown in ethanol) restricted to dorsal surface of broad intersegmental furrows (Fig. 1 A,B). Distinctive yellow-white glandular region between segmental furrows, becoming elevated in mid and posterior chaetigers. In life, worms well camouflaged against coral host, ranging from 100-200 mm long (Fig. 1A; Johann Hinterkircher pers. comm.). Prostomium broader than long, rectangular to ovate, with 2 closely-set pairs of eyes in trapezoidal arrangement, anterior pair larger than posterior pair. Palps broad, basaliy free, longer than prostomium (Fig. 2A-C). Median antenna inserted on middle of prostomium, weakly articulated, approximately 2.5 times length of lateral antennae. Lateral antennae inserted on anterior part of prostomium, weakly articulated, similar in length to combined length of prostomium and palps. Peristomium slightly shorter than anterior segments. Dorsal tentacular cirri weakly articulated, Fig. 1. Alcyonosyllis hinterkircheri sp. nov, A. Several individuals in sitti on Goniopora cf. slokesi at Panglao Island, near Bohol Island, Philippine Islands. Note that most coral polyps arc retracted. Photo: J. Hinterkircher. B. Paratype (NTM W.22999) alive, removed from host. Head at bottom right. Photo: J. Hinterkircher. Scale: 5.0 mm. similar in length to median antennae; twice length of ventral pair (Fig. 2C). Parapodia comprising dorsal and ventral cirri and broad parapodial lobe; prc-chaetal lip slightly more prominent than post-chaetal lip throughout. Dorsal cirri weakly articulated, more so distally, of two distinct forms: longer, dorsally- displaced ones on chaetigers 1,4,6,9, 11 and thereafter on odd chaetigers (Fig. 3B,D), and shorter laterally-directed ones arising closer to parapodial lobes on chaetigers 2, 3, 5, 7, 8, 10 and thereafter on even chaetigers (Fig. 3A,C). Longest dorsal cirri in midbody up to 2.5 x body width; shorter ones about V 2 -V 3 length of longer ones. Ventral cirri smooth, approximately 'h length of parapodial lobe anteriorly, equal in length to parapodial lobe in mid and posterior chaetigers (Figs 2B, 3D). Parapodia each bearing two types of unidentate hooked chaetae, thicker prominently hooked type, and thinner, less hooked type, both with subdistal boss (Fig. 3F,G); chaetae sometimes withdrawing into parapodium (Fig. 3E); four chaetae per parapodium (n = 4), some paratypes with only two chaetae per parapodium - one thick, one thinner. Neuroaciculae straight, with slight subdistal swelling, varying in number from 6 (anteriorly) to 2 (posteriorly) (Fig. 3E). Single, slender, notopodial acicula 57 C. J. Glasby and M. T. Aguado Fig. 2. Alcyonosyllis hinterkircheri sp. nov. preserved specimen. A, Holotype, anterior end, dorsal view; B, Holotype, anterior end, ventral view; C, Holotype, anterior end, lateral view; D, Paratype (NTM W.2300), posterior end, showing developing stolon and regenerating pygidium of parent (indicated with arrow). Scale A-D: 1.0 mm. in each posterior parapodium most likely associated with developing schizogamous stolon. Pygidium swollen, slightly upturned and bearing a pair of long slender weakly articulated cirri on ventral edge (Fig. IB). One paratype (NTM W.23000) with well- developed female stolon attached to posterior body; at point of attachment stock developing new tail end ventrally (Fig. 2D). Pharynx retracted and together with proventricle not visible through body wall. Pharynx short (about 2 h length proventricle) extending to anterior chaetiger 4, relatively thick (about 2 h width proventricle) and slightly coiled with curved, anterodorsal hyaline tooth (Fig. 4A). Number and form of distal papillae could not be determined on dissected pharynx. Proventricle extending from anterior of chaetiger 4 to posterior of chaetiger 7, with about 25 muscle rows (Fig. 4A). Remarks. The new species is generally similar to A. phili in having multiple aciculae and two or more chaetae per parapodium of two different types. It differs from this species and all other Alcyonosyllis species in: (I) having longer, more slender dorsal cirri with a strong long-short alternation pattern until the pygidium; (2) that its antennae and pygidial cirri are also longer and more slender; (3) having an olive-green banding colour pattern (A. phili has red-brown bands), although this may reflect the colour of the host; (4) that the thinner of the two hooked chaetae lacks the secondary (subdistal) tooth; and (5) that the ventral cirri are about half the length of the parapodial lobe anteriorly and equal in length to the parapodial lobe in mid and posterior chaetigcrs (see also Tabic 1). Etymology. The species is named in honour of the collector, Johann Hinterkirchcr, of Munich in Germany, a keen underwater photographer and collector who has donated many interesting polychaete specimens to the NTM. Distribution. Presently only known from the Philippine Islands (Panglao Island, south-west of Bohol Island). Habitat. As many as 20-50 individuals of Alcyonosyllis hinterkircheri were found on a single Goniopora cf. stokesi coral according to Johann Hinterkirchcr (pers. comm. 24 March 2006). In life, the polychaetes were well hidden at the bases of the long polyps of the host, and the colour pattern and shape of the polychaetes matched closely that of the coral making them difficult to see. When the coral was disturbed and the polyps withdrawn, the polychaetes 58 New species and new records of Alcyonosyllis Fig. 3. Alcyonosyllis hinterkircheri sp. nov. parapodia. A, I lolotype, parapodium from chaetiger 12, left side; B, Holotype, parapodium from chaetiger 13, right side; C, Paratype, NTM W.22999, parapodium from chaetiger 210 (Nomarski), left side?; D. Paratype, NTM W.22999, parapodium from chaetiger 211, left side; E, I lolotype, close-up of midbody parapodium; F, paratype, NTM W.22999, two large-type chaetae from chaetiger 50; G, paratype, NTM W.22999, smaller-type chaetae from chaetiger 50. Scale A-D: 0.2 mm; E: 0.1 mm; F: 0.05 mm; G: 0.025 mm. 59 C. J. Glasby and M. T. Aguado could be easily seen (Fig. 1 A). Although scleractinians like Goniopora are not closely related to octocorals (the most common hosts of Alcyonosyllis), their long polyps perhaps make them similar both structurally and functionally to the typical octocoral hosts. Among the many associations between polychaetes and cnidarians, this appears to be the first record of a commensal polychaete on a species of Goniopora (see Martin and Britayev 1998). Further, this is the first record of an Alcyonosyllis species associated with a scleractinian coral. Alcyonosyllis pltili Glasby and Watson, 2001 (Table 1) Alcyonosyllis phili Glasby and Watson, 2001: 45-49, figs 1-5. Material examined. Philippine Islands, Bohol Island, Alona Beach 3 km from Panglao City (9°34.683'N, 123°44.75'E), 15 m, coll. Johann Hinterkircher, 3 September 2003, 1 (NTM W.23001). Australia, Darwin Harbour, East Arm Port 1 (NTM W.4175), 1 (NTM W4176), 2 (NTM W.4178), 2 (NTM W.423I), Casuarina Beach 1 (NTM W.4230), Nightcliff 5 (NTM W.4244), Timor Sea, Ashmore Reef, 21 m depth 1 (NTM W.4991). Remarks. The single specimen of A. phili from Bohol, Philippine Islands, which was found on a gorgonian, agreed well with the material from Australia and New Guinea described by Glasby and Watson (2001). The specimen from Ashmore Reef was commensal on a sea fan. The Darwin Harbour specimens from East Ann Port were all collected from reef flat sediments (coarse sand); all were relatively small (< 10 mm long), which suggests that young forms may be free-living. The specimens from Bohol Island and Ashmore Reef are the northern and western-most records, respectively, for the species. Alcyonosyllis sp. (Figs 4B, 5A-F; Table 1) Material examined. 1 (RMNH 21117). NE coast of Sumba (9°57’S 120°48’E), sandy bottom with unidentified sponges and gorgonians, 50 m, 1.2 m Agassiz trawl, 16 September 1984. Snellius II expedition. Comparative material. Haplosyllis xaeniaecola Hartmann-Schroder, 1993: Holotypc(SMF4431/1 (Termite, Moluccas, Indonesia, on Xenia viridis Schenk. Haplosyllis hisetosa Hartmann-Schroder, 1960: Holotype (HZM P-14745), Djubal, Red Sea, 1 m on alcyonarian, coll. Table 1 . Comparative list of selected characters for the Alcyonosyllis species having simple chaetae, together with information on host, distribution and literature reference. Species Length (nun) Dorsal cirri Large-tvpe hooks (greatly curved) Small-type hooks (gently curved) Aciculac (no.) Host(s) Distribution References A. pliili Glasby and Watson, 2001 28-56 Smooth: elevated ones thicker than non-elevated ones present present, minute secondary tooth 3-5 soft corals (Neptheidae), gorgonian (Melithaea sp: Melithaeidae) Philippines, New Guinea, northern Australia Glasby and Watson (2001); this study A. xaeniaecola (Hartmann- Schroder, 1993) 15 Smooth; all same thickness present present, unidentate ? soft coral (Xenia viridis: Xeniidae) Ternate (Maluku I.), Moluccas, Indonesia Hartmann- Schroder (1993), Glasby and Watson (2001) A. glasbyi San Martin and Nishi, 2003 16 Weakly articulated: all same thickness absent? present; minute secondary tooth 1 gorgonian (Melithaea flabellifera: Melithaeidae) Shimoda, Japan San Martin and Nishi (2003) A. hinterkircheri sp. nov. 100- 200 Weakly articulated: all same thickness present present, unidentate 2-6 hard coral (Goniopora cf. stokesi) Bohol, Philippines This study Alcyonosyllis sp. 7 Weakly articulated; all same thickness present present, bidentate 1-2 gorgonian Sumba, Indonesia This study A. bisetosa (Hartmann- Schroder, 1960) 5.8 Weakly articulated; all same thickness present present, secondary tooth 2 soft coral Gubal, Red Sea Hartmann- Schroder (1960); San Martin and Nishi (2003); Lattig and Martin (2009) A. gorgoniacolo (Sun and Yang, 2004) 75-85 Smooth; elevated ones thicker than non-elevated ones present present, minute secondary tooth absent 3M Orange-red gorgonian Chenhang Island, Paracel Group, South China Sea Sun and Yang (2004); Lattig and Martin (2009) 60 New species and new records of Alcyonosyllis Fig. 4. A. Alcyonosyllis liinterkircheri sp. nov. Paratype, NTM W.23000, pharynx and proventricle dissected out to show anterodorsal tooth (indicated by arrow); B, Alcyonosyllis sp. Anterior end, dorsal view. Note muscle rows of proventriclc and weakly articulated anterior dorsal cirri. Scale A: 0.5 mm; B: 0.3 mm. Gerlacli, 29 October 1957; ?paratype I (HZM unregistered), collection details as for holotype. Description. Specimen 7 mm long, 0.5 mm wide, with 38 segments (posteriorly incomplete). Dorsum convex and venter flat. Body unpigmented, whitish; pharynx red (Fig. 4B). Anterior segments without marked intersegmental furrows; after proventricular chaetigers, segments well delimitated, with secondary posterior ring (Fig. 5A,E). Prostomium broader than long, rectangular to oval, with 2 pairs of eyes in trapezoidal arrangement, posterior ones larger than anterior ones. Palps broad, close-set basally, longer than prostomium. Median antenna inserted on middle of prostomium, weakly articulated, approximately twice as long as lateral antennae. Lateral antennae inserted on anterior part of prostomium, weakly articulated, as long as combined length of prostomium and palps (Figs 4B, 5A). Peristomium shorter than subsequent segments (Fig. 5A). Dorsal tentacular cirri weakly articulated, as long as median antennae; twice as long as ventral pair. Dorsal cirri slender and distally tapering, anterior ones weakly articulated, those from mid- and posterior body less so (Figs 4B; 5A,E), with granular material inside. Anterior dorsal cirri alternating in length, some of them extremely long, those from chaetiger 15, about 12 segments in length. Shortest anterior dorsal cirri slightly longer than body width. Midbody and posterior dorsal cirri alternating in length, but distally shorter than anterior ones, longest cirri about 5 segments in length and twice length of short ones (Fig. 5E). Some parapodia with less difference in length between both types of dorsal cirri, but still alternating. Cirrophores present on all chaetigers, from midbody onward as distinct constricted ring (Fig. 5F). Ventral cirri digitiform, slightly extending beyond tips of parapodia (Fig. 5F). Anterior parapodia with 2 simple bidentate chaetae, similar in size, distally curved with both teeth similar in length and size (Fig. 5B). Midbody parapodia with 3 simple chaetae, 2 similar to anterior ones, third hook-shaped, unidentate, distally curved, larger than others (Fig. 5C). Posterior parapodia with 3 chaetae, similar in shape to those from midbody (Fig. 5D); sometimes only 1 bidentate chaeta and 2 unidentate hooked chaetae; hooked chaetae larger than midbody ones and more curved distally. Anterior parapodia with 1 large acicula, orange coloured, straight and distally pointed (Fig. 5B). Midbody and posterior parapodia with 2 aciculae, smaller than anterior ones, 1 straight and pointed, the other distally bent (Fig. 5C, D). Pygidium missing. Pharynx extending through four segments, narrower than proventricle, with 1 conical anterodorsal tooth (Fig. 5A). Proventriclc extending through 4 segments, with about 31 rows of muscle cells (Figs 4B, 5A). Remarks. Alcyonosyllis sp. resembles Alcyonosyllis xaeniaecola in having a strongly pigmented red-coloured pharynx. However, all the chaetae in A. xaenicola are unidentate, whereas the slender, less hooked, chaetae in Alcyonosyllis sp. are bidentate. in addition, A. xaenicola has smooth dorsal cirri, while the anterior-most ones in Alcyonosyllis sp. are weakly articulated and gradually become smoother towards the posterior end. The presence of weakly articulated anterior dorsal cirri also occurs in A. hinterkircheri, which differs from Alcyonosyllis sp. in the shape of chaetae and number of chaetae and aciculae. Alcyonosyllis sp. differs from A. bisetosa in having the smaller chaetae with bidentate hooks with the two apical teeth very close together (Table 1). Pharyngeal colour has not been considered before as a diagnostic character for syllid species, since it could depend on the preservation state and time spent in ethanol, and it could also be related to their habitat. For instance, several specimens of Haplosyllis found in the same sample as Alcyonosyllis sp. also had a strongly red-coloured pharynx. Therefore, Alcyonosyllis sp. and A. xaeniaecola probably acquired the colouration independently, perhaps as a result of similar diets. Although Alcyonosyllis sp. might be a new species, only one specimen is known to date. Therefore, until more material is collected and studied, we prefer not to formally name the species. Distribution. Moluccas, Savu Sea (Indonesia). 61 C. J. Glasby and M. T. Aguado Fig. 5. Alcyonosyllis sp. A, Anterior end, dorsal view; B, Anterior parapodium; C, Midbody parapodium; D, Posterior parapodium; E, Midbody segments, dorsal view; F, Midbody parapodium, anterior view. Scale A: 0.2 mm; B-D: 20 pm; E: 0.4 mm; F: 48 pm. 62 New species and new records of Alcyonosyllis ACKNOWLEDGEMENTS We gratefully acknowledge the help of Carden Wallace in the identification of the scleractinian coral host of the new species, Vivian Wei for translating the description of Haplosyllis gorgoniacolo given by Sun and Yang (2004), Richard Willan for clarifying the derivation of the species name goigoniacolo, Harry A. ten Hove for the loan of the specimen from Indonesia, and Dieter Fiege for lending us comparative material. Also, we thank Daniel Martin and an anonymous reviewer for constructive reviews, and Leslie Harris for information on Alcyonosyllis occurrences in aquaria. This project was partly financed by the European Commission’s Research Infrastructure Action via the SYNTHESYS Project, financed by European Community Research Infrastructure Action under the FP6 ‘Structuring the European Research Area’ Programme. REFERENCES Aguado M.T. and San Martin, G. 2009. Phylogeny of Syllidae (Polychaeta) based on morphological data. Zoologica Scripta 38: 379-102. Aguado, M.T., San Martin, G. andNishi, E. 2008. Contribution to the knowledge of Syllidae (Polychaeta) from Japan. Systematics and Biology 6(4): 521-550. Glasby, C. J. and Watson, C. 2001. A new genus and species of Syllidae (Annelida: Polychaeta) commensal with octocorals. The Beagle, Records of the Museums and Art Galleries of the Northern Territory 17: 43-51. Hartmann-Schroder, G. 1960. Polychaeten aus dem Roten Meer. Kieler Meeresforschungen 16: 69-125. Hartmann-Schroder, G. 1991. Syllis onkylochaeta sp. n., ein korallenfressender Polychaet (Syllidae) aus dem Korallenaquarium des Lobbecke-Museums. Helgolander Wissenschaftliche Meeresuntersuchungen 45: 59-63. Hartmann-Schroder, G. 1993. Haplosyllis xeniaecola, ein neuer polychaet (Syllidae) von den Molukken (Indonesien). Helgolander Meeresuntersuchungen 47: 305-310. Imajima, M. 2003. Polychactous annelids from Sagami Bay and Sagami Sea collected by the Emperor Showa of Japan and deposited at the Showa Memorial Institute. National Science Museum, Tokyo (II). Orders included within the Phyllodocida, Amphinomida, Spintherida and Eunicida. Natural Science Museum Monographs 23: 1-221. Lattig, P. and Martin, D. 2009. A taxonomic revision of the genus Haplosyllis Langcrhans, 1887 (Polychaeta: Syllidae: Syllinae). Zootaxa2220: 1—10. Martin, D. and Britayev, T.A. 1998. Symbiotic polychaetes: review of known species. Oceanography and Marine Biology: an Annual Review 36: 217-340. Martin, D., Nunez, J., Riera, R. and Gil, J. 2002. On the associations between Haplosyllis (Polychaeta, Syllidae) and gorgonians (Cnidaria, Octocorallia), with the description of a new species. Biological Journal of the Linnean Society 77: 455-477. San Martin, G. and Nishi, E. 2003. A new species of Alcyonosyllis Glasby and Watson, 2001 (Polychaeta: Syllidae: Syllinae) from Shimoda, Japan, commensal with the gorgonian Melithaea flabellifera. Zoological Science 20: 371-375. Sun, R. and Yang, D.J. 2004. Annelida. Polychaeta II. Nereidida (=Nereimorpha). Nereididae, Syllidae, Hesionidae, Pilargidae, Nephtyidae. In: Huo, C. and Zhao, G. (eds). Fauna Sinica, Invertebrata Vol. 33. Pp xii + 520 pp. Science Press: Beijing. Accepted 29 October 2009 63 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25: 65-70 The genus Floresorchestia (Amphipoda: Talitridae) in tropical Australia JAMES K. LOWRY AND ROGER T. SPRINGTHORPE Crustacea Section, Australian Museum, 6 College Street, Sydney, NSW2010, AUSTRALIA Corresponding author: jim.lowiy@austmus.gov.au ABSTRACT The widespread Indo-West Pacific and Caribbean talitrid genus Floresorchestia is reported from Australia for the first time and a new species, F. australis, is described. Floresorchestia australis is known from pebble beaches in Darwin Harbour, Northern Territory, Australia. KEYWORDS: Crustacea, Amphipoda, Talitridae, Australia, taxonomy, new species, Floresorchestia australis. INTRODUCTION Lowry and Springthorpe (2009a) recently described Talorchestia brucei from sandy beaches in Darwin, Northern Territory, Australia. A second talitrid species, living on pebble beaches also in Darwin, lias since come to our attention. It is described here as Floresorchestia australis. This is the first record of the widespread Indo-west Pacific and Caribbean genus Floresorchestia Bousfield in Australia. There are now five tropical talitrid genera known from Australia: Chelorchestia Bousfield, 1984 (sec Sercjo2009); Chroestia Marsden and Fenwick, 1984; Floresorchestia Bousfield, 1984; Microrchestia Bousfield, 1984 (see Serejo 2009; Lowry and Peart In press); and Talorchestia Dana, 1852 (see Serejo 2009). Chelorchestia has five species distributed between north-eastern Australia, the eastern Pacific and the Caribbean Sea. Microrchestia (five species) appears to be a Papua New Guinea and tropical-warm temperate eastern Australian endemic genus. Chroestia (monotypic) appears to be endemic to tropical-warm temperate eastern Australia. Talorchestia (eight species, senstt stricto) is a widespread Indo-west Pacific tropical endemic genus. Floresorchestia (15 species) is also widespread on Indo-west Pacific tropical islands, but like Chelorchestia it also occurs in the tropical Caribbean Sea. Bousfield (1984) recognised Floresorchestia for a group of described species with unique stridulating organs on the epimera. Recently Miyamoto and Morino (2008) and Lowry and Springthorpe (2009b) have both discussed the morphology of the genus, refining characters and describing additional new species. In this paper we report the genus from Australia for the first time and describe a new species, F. australis, from Darwin, Northern Territory, Australia. MATERIAL AND METHODS The description was generated from a DELTA (Dallwitz 2005) database to world talitrid genera and species. Material is lodged in the Museum and Art Gallery of the Northern Territory (NTM; formerly Northern Territory Museum), Darwin and the Australian Museum (AM), Sydney. The following abbreviations arc used on the plates: C, coxa; EP, epimeron; G, gnathopod; MD, mandible; MP, maxilliped; OOST, oostegite; P, pereopod; T, telson; U, uropod; OR, outer ramus. SYSTEMAT1CS Family Talitridae Floresorchestia Bousfield, 1984 Gender feminine. Type species, by original designation, Orchestia floresiana Weber, 1892. Recent, Flores Island, Indonesia. Remarks. For the most recent diagnosis of the genus and a complete list of species see Lowry and Springthorpe (2009b). Floresorchestia australis sp. nov. (Figs 1-4) Type material. Holotype - NTM Cr. 16878, male, 8.5 mm, near the boat ramp, Nightcliff, Darwin, Northern Territory, Australia (12°22.759'S 130°50.487’E). Paratypes - NTM Cr. 16879, ovigerous female, 9.16 mm; NTM Cr. 13149, male, 9.16 mm; NTM Cr. 13149, male, 7.4 mm; NTM Cr. 16882, 5 males, 4 females; AM. P.80701, 1 male, 1 female, same locality. 65 J. K. Lowry and R. T. Springthorpe Fig 1. Floresorchestia australis sp. nov., paratype, male (NTM Cr. 16881). Type locality. Near the boat ramp, Nightcliff, Darwin, Northern Territory, Australia (12°22.759'S 130°50.487'E). Etymology. Named for the country to signal the presence of this wide ranging genus in Australia. Description. Based on holotype, male, 8.5 mm, NTM Cr. 16878. Head. Eye large (greater than 1/3 head length). Antenna 1 short, rarely longer than article 4 of antenna 2 peduncle. Antenna 2 peduncular articles narrow; article 5 longer than article 4. Mandible left laciniamobilis4-dentate. Maxilliped palp article 2 distomedial lobe well developed, 4 reduced, button-shaped. Pereon. Gnathopod 1; subchelate; smaller than coxa 2; posterior margin of merus, carpus and propodus each with lobe covered in palmate setae; propodus ‘subtriangular’ with well developed posterodistal lobe, anterior margin with 2 groups of robust setae, lateral surface with 3 cuspidate seta, posterolateral surface with 4 serrate setae, medial surface without cuspidate setae, with 5 or 6 serrate setae, posterior margin without cuspidate or serrate setae; palm transverse, with about 7 serrate setae; dactylus slightly longer than palm. Gnathopod 2 sexually dimorphic; subchelate; basis slightly expanded; ischium with anterodistal cradle; posterior margin of merus, carpus and propodus each without lobe covered in palmate setae; propodus subovate, 1.5 times as long as wide; palm extremely acute, reaching less than 60% along posterior margin, smooth, lined with robust setae; posteromedial surface of propodus with groove; with cuticular patch at corner of palm; dactylus longer than palm, attenuated distally; gill simple, not incised. Pereopods 2-4 coxae wider than deep. Pereopods 3-7 cuspidactylate; dactyli with distal patch of many rows of tiny denticles on anterior margin. Pereopod 4 dactylus thickened proximally with notch midway along posterior margin. Pereopod 5 propodus distinctly longer than carpus. Pereopods 6-7 longer than pereopods 3-5. Pereopod 6 not sexually dimorphic; carpus not expanded. Pereopod 7 not sexually dimorphic; basis lateral sulcus absent, posterior margin with distinct minute serrations, each with 1 small seta, posterodistal lobe present, shallow, broadly rounded; distal articles (merus and carpus) slender; merus posterior margin evenly rounded. Pleon. Pleopodsall well developed. Pleopod 1 peduncle with marginal slender and robust setae; biramous, outer ramus subequal in length to peduncle, with 8 articles. Pleopod 2 and 3 biramous. Epimera 2 subequal in length to epimeron, 3 with stridulating organ just above ventral margins, with 31 ridges. Epimeron 3 posterior margin smooth, with minute setae, posteroventral corner with small subacute tooth, ventral margin without robust setae. Uropod 1 not sexually dimorphic, peduncle with 11 robust setae, peduncle distolateral robust seta present, small (less than 1/4 length of outer ramus), with simple tip, without apical spear-shaped setae; inner ramus subequal in length to outer ramus, with 4 marginal robust setae; outer ramus with 1 long midmedial seta, 1 robust seta on margins. Uropod 2 not sexually dimorphic; peduncle with 6 robust setae; inner ramus subequal in length to outer ramus; outer ramus with 1-2 marginal robust setae. Uropod 3 peduncle with 2 robust setae; ramus subequal in length to peduncle, linear (narrowing), with 2 marginal robust setae, ramus with 4-5 apical setae. Telson about as broad as long, completely incised, partially coalesced, dorsal midline entire, with marginal and apical robust setae, with 5 robust setae per lobe. Female (sexually dimorphic characters). Based on ovigerous female, 9.16 mm, NTM Cr. 16879. Gnathopod 66 New Floresorchestia from tropical Australia Fig 2. Floresorchestia australis sp. nov., holotype, male (NTM Cr. 16878), head, paratype, male “b”, (NTM Cr. 16880), paratype, female (NTM Cr. 16879). Scale bars represent 0.1 mm, except oostegite tip represents 0.01 mm. I posterior margin of merus, carpus and propodus each without lobe covered in palmate setae; propodus subrectangular; palm acute; dactylus subequal in length to palm. Gnathopod 2 mitten-shaped; coxal gill lobate; basis expanded proximally; ischium without posterodistal lobe on medial surface; posterior margin of merus, carpus and propodus each with lobe covered in palmate setae; carpus well developed (not enclosed by merus and propodus), posterior lobe present, projecting between merus and propodus; palm obtuse, not lined with robust setae, without cuticular patch at corner of palm; dactylus subequal in length to palm. Oostegites setae with spatulate tips. Uropod 1 outer ramus without robust setae. Habitat. Apparently living on a pebble beach in the supralittoral zone and on the cliff face behind the beach. Remarks. Only three species of Floresorchestia (i.e., F. australis from tropical northern Australia, F. monospina (Stephensen, 1935) from the Marquesas Islands, and F. pectenispina (Bousficld, 1970) from the Solomon Islands) have a large, modified, robust seta on the outer ramus of male uropod 1. Of these species, F. monospina has a row of stridulating ridges on cpimera 2 and 3 similar to other species in the genus, but F australis and F. pectenispina have the stridulating ridges located only on cpimeron 2. We think that both of these characters 67 J. K. Lowry and R. T. Springthorpe Fig 3. Floresorchestia australis sp. nov., liolotype, male (NTM Cr. 16878). Scale bars represent 0.2 nun. (the modified robust seta and the stridulating ridges) are powerful synapomorphies indicating sister species status. Floresorchestia australis and F. pectenispina differ from each other in the shape and structure of the male gnathopod 2, in the setation of uropod 3 and in the depth of the telson cleft. Distribution. Australia. Northern Territory: Darwin (this study). 68 New Floresorchestia from tropical Australia Fig 4. Floresorchestia australis sp. nov., paratypc, male (NTM Cr. 16880). Scale bars for UR, Epimera 1-3 represent 0.2 mm, remainder represent 0.1 mm. ACKNOWLEDGEMENTS Thanks to Alan Myers and Niel Bruce for constructive comments which significantly improved our paper. REFERENCES Bousfield, E.L., 1970. Terrestrial and aquatic amphipod Crustacea from Rcnnell Island. The Natural History ofRennell Island, British Solomon Islands 6: 155-168. Bousfield, E.L. 1984. Recent advances in the systematics and biogeography of landhoppers (Amphipoda: Talitridae) of the Indo-Pacific Region. Bishop Museum Special Publication 72: 171-210. Dallwitz, M.J. 2005. Overview of the DELTA System, http:// delta-intkey.com/www/overview.htm. (8/9/2007). Dana, J.D.. 1852. Conspectus Crustaceorum quae in OrbisTerramm circumnavigatione, Carolo Wilkes e Classe Reipublicae Foederatae Duce, lexit et descripsit Jacobus D. Dana. Pars III. Proceedings of the American Academy of Arts and Sciences 2 : 201 - 220 . Lowry, J.K. and Peart, R. In press. The genus Microrchestia (Amphipoda: Talitridae) in eastern Australia. Zootaxa. 69 J. K. Lowry and R. T. Springthorpe Lowry, J.K. and Springthorpe, R.T. 2009a. Talorchestia brucei sp. nov. (Amphipoda, Talitridae), the first talitrid from the Northern Territory, Australia. Crustaceana 82(7): 897-912. Lowry, J.K. and Springthorpe, R.T. 2009b. The genus Floresorchestia (Amphipoda: Talitridae) on Cocos (Keeling) and Christmas Islands. Memoirs of Museum Victoria 66: 117-127. Marsden, I.D. and Fenwick, G.D. 1984. Chroestia, a new supralittoral amphipod genus from Queensland, Australia (Talitroidea: Talitridae). Journal of Natural History, London 18: 843-851. Miyamoto, H. and Morino, H. 2008. Taxonomic studies on the Talitridae (Amphipoda) from Taiwan, III. The genus Floresorchestia Bousfield, 1984. Crustaceana 81(7): 837-860. Serejo, C.S. 2009. Talitridae. Pp 892-903. In: Lowry, J.K. and Myers, A. A. (eds) Benthic Amphipoda (Crustacea: Peracarida) of the Great Barrier Reef, Australia. Zootaxa 2260: 1-930. Stephensen, K.H., 1935. Terrestrial Talitridae from the Marquesas. Bulletin of the Bernice P. Bishop Museum 142: 19-32. Accepted 30 October 2009 70 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25: 71-78 Description of two new pseudaposematic species with a review of defensive adaptations in the subfamily Thynninae (Hymenoptera: Thynnidae) GRAHAM R. BROWN Museum and Art Gallery Northern Territory, GPO Box 4646, Darwin,'NT0801, AUSTRALIA thynnini@hotmail.com ABSTRACT Two new species of thynnine wasps, Lestricothynnus abispoides and Zaspilothynnus scolioides, are described, the males of which are mimics in size and colour pattern of Abispa spp. (Hymenoptera: Vespidae) and Scolia spp. (Hymenoptera: Scoliidae), respectively. Defensive mechanisms found in the Australian Thynninae are reviewed, including newly discovered defensive pheromones and stridulation. Keywords. Hymenoptera, Thynninae, Lestricothynnus, Zaspilothynnus, Australia, pseudaposematic, defence pheromones, stridulation, colour patterns INTRODUCTION The Australian Thynninae contains about 600 described species with at least a further 1000 species yet to be described, but present in collections (pers. obs.). Little is known of the biology of the group although they are known to be parasites of scarab larvae (Ridsdill-Smith 1970) and the males of some are specific orchid pollinators (e.g. Bower 1996; Brown 1997a, b; Peakall 1990). One of the most obvious features of the subfamily is the extreme dimorphism between the sexes. Males arc fully winged and are typical wasps in appearance. Females are wingless and somewhat ant-like, but with stouter bodies and the legs partially spinose. This dimorphism has led to a dependence on the males for females to be flown to a food source such as nectar and hemipteran exudates (Given 1954). Strong but flexible coupling mechanisms (Brown 2000) enable pairs to remain in copula for prolonged periods including flight and feeding. There has been nothing published on the defensive mechanisms within this group, however, as in all Hymenoptera (ants, bees and wasps), it is only the female that can sting using the ovipositor and associated venom glands. The ovipositor’s primary function is to lay eggs, but in most Hymenoptera it is also used to paralyse prey or to inject venom as a defensive weapon against larger predators. Males sometimes attempt to “sting” by jabbing a predator with the apex of the abdomen, but males lack both an ovipositor and venom glands. An examination of museum collections suggests that a number of thynnine wasp species bear a resemblance to paper wasps (Hymenoptera: Vespidae: Polistinae). The females of the latter possess a painful sting. The two Northern Territory thynnines described here are unusual in that their colour patterns are both distinctive within the Australian fauna and that they bear a close resemblance to either potter wasps (Hymenoptera: Vespidae: Eumeninae) or hairy flower wasps (Hymenoptera: Scoliidae). Other defensive strategies used by males, including stridulation and pheromones, are newly reported and discussed. Terminology follows Snodgrass (1941), Brown (1997a, b) and Naumann (1991). Relative terms relating to microsculpture are interpreted as follows: sparsely punctate = punctures greater than two puncture-diameters apart; punctate = punctures at most two puncture-diameters apart, but never confluent; closely punctate = punctures almost confluent; rugosely punctate = punctures partially confluent; finely punctate = punctures small and shallow; coarsely punctate = punctures large and deep; obscurely punctate = punctures small, sparse, shallow and only visible at certain angles. Abbreviations. Morphological characters: Tl-7, metasomal tergites 1-7; Sl-8, metasomal stemites 1-8. Specimen repositories: AM, Australian Museum, Sydney; ANIC, Australian National Insect Collection, CSIRO, Canberra; BMNI I, The Natural History Museum, London (formerly British Museum (Natural History)); NTM, Museum and Art Gallery of the Northern Territory, Darwin (formerly Northern Territory Museum). SYSTEMATICS Lestricothynnus Turner, 1910 Type species Thynnus nubilipennis Smith, 1879, by original designation. Gender masculine. Diagnosis. Males arc distinguished by antennal prominence broadly rounded (rarely discontinuous 71 G. R. Brown medially), broader than long, and flat (without raised margins) and the body including the metasoma usually extensively coloured; and females by the pygidium oblique, about 4 times longer than wide or longer, longitudinally multicarinate often slightly constricted, never spinose. Wasps of this genus are medium to small. Typically males are black with yellow or orange markings including paired lateral spots on the abdominal segments and females orange to dark brown without yellow markings. Remarks. Based on published records, the known distribution is in eastern and southern coastal regions of mainland Australia but discontinuous between north and south Queensland, and between the Eyre Peninsula of South Australia and south-western Western Australia. The genus has not been recorded previously from the Northern Territory. Lestricothynnus abispoides sp. nov. (Figs 1-4) Type material (all Northern Territory). Holotype -AM, c?, Stokes Creek, George Gill Range, 26-27 May 1983, G.A. Holloway. Paratypes - AM, 5cf, same data as holotype; BMNH, 7c?, same data as holotype; NTM 1.5374-1.5378, 5c?, same data as holotype; NTM 1.5379-1.5380, 2cf, 8 km N of Alice Springs, 8 November 1979, G. Griffin; NTM 1.5381, 19, Corroborree Rock Conservation Reserve, visiting Melaleuca bracteata flowers, 2 December 1993, G.R. Brown; ANIC,21000 m from the nearest vehicle access or artificial structure. The greatest portion of NTVFA records had no attached habitat data. Those that did provided various information including canopy height, canopy cover percentage and a general site description. RESULTS Current range. Based on NTVFA and field survey data, Hemidactylus frenatus is currently confined to areas north of the Tropic of Capricorn in the Northern Territory, and is most densely represented by localities in the north¬ western Top End (Fig. 2). There are scattered records throughout other parts of the Top End, including coastal Arnhem Land, and the Tiwi, Croker, Marchinbar and Groote islands. South of I5°S localities become sparser, with records along the Stuart Highway, three records from the Gulf country and one from the Victoria River District. South of 17°S H. frenatus is confined to localities on the Stuart and Barkly Highways, and there arc no records south of Ti Tree at 22°S. Current habitat associations. Based on the field survey data, Hemidactylusfrenatus utilises both artificial structures and natural habitats in the Northern Territory (Table 1). Most records from artificial structures are within the region of highest regional abundance (the western Top End), which is also the region with the largest infrastructure and human population. One record provided the second locality at which artificial structures are used in the sparsely populated Gulf of Carpentaria region. Fig. 2. Current distribution of Hemidactylus frenatus in the Northern Territory, from the combined records of the Northern Territory Vertebrate Fauna Atlas and field surveys. In field surveys, Hemidactylus frenatus was recorded from riparian vegetation {n= 8), eucalypt woodland («=4), coastal monsoon forest (n= 3), riparian monsoon forest («=3), Melaleuca swamp forest (n=l), and coastal Casuarina forest («=1). Of the 18 total locations where If frenatus occupied natural habitats, 13 represented records within 500 m of structures or vehicle access. Hemidactylus frenatus occurred up to 1 km from a structure or vehicle access at two localities in the Darwin area, in coastal monsoon forest and Melaleuca swamp forest habitats. Records from greater than 1 km from a structure or vehicle access occurred in both the Darwin area (two localities, in coastal monsoon forest and coastal Casuarina forest) and Kakadu National Park (one locality, in riparian monsoon forest). Twenty site records from the NTVFA also included data on habitat association for H. frenatus. Habitats were monsoon forest (n=15), woodland (n=3), woodland on foreshore («=1), and floodplain edge with scattered low trees (n=l). The monsoon forests had canopy heights of between 7 and 20 m, and canopy covers of between 20 and 90%. Woodlands had canopy heights of 9-12 m, and canopy covers of 8-40%. Neither field surveys nor the NTVFA provided any records from natural habitats south of 15°S. 113 J. L. McKay, A. D. Griffiths and B. Crase Table 1. Habitat associations of Hemidactylus frenatus in the Northern Territory, from field survey records. Abbreviations: DVA - distance from vehicle access or artificial structure; KNP = Kakadu National Park. DVA DVA DVA Habitat 0-500 500- >1000 Date Location Latitude, Longitude Ill 1000 m ni 23/07/02 East Point Recreation Reserve, Darwin 12°24'43.8"S, 130°49'24.2"E Monsoon forest X X 29/12/02 Walker Creek, Litchfield National Park 13°05'10.6"S, I30°41'57.8’'E Riparian vegetation X 07/02/04 Mataranka Hot Springs 14°57'29.8"S, 133°19'56.2"E Riparian forest X 24/03/04 Casuarina Coastal Reserve, 12°21 '46.7"S, 130°52'02.2"E to Coastal monsoon forest X X X Free Beach carpark to Lee 12° 19'55.1 "S, 130°53'42.9"E dominated by large Acacia Point auriculiformis and coastal Casuarina forest dominated by Casuarina equisetifolia 14/05/04 Fogg Dam 12°34'48.5"S, 131°20'23.6"E Riparian vegetation dominated by Acacia auriculiformis X 05/08/04 Gunlom, KNP 13°26'00.8"S, 132°24'54.6"E Riparian vegetation X 22/08/04 South Alligator river, KNP 12°39'29"S, 132°30T9"E riparian strip along river bank X 22/08/04 Aurora South Alligator resort campground, KNP 12°40'29''S, 132°28'47"E Artificial structure 23/08/04 East Alligator Day Use area, KNP 12°25'23.8”S, 132°57”57.9"E Riparian forest X 23/08/04 Manngarre Walk, KNP 12°25'15.0"S, 132°58'01.4"E Riparian monsoon forest X X X 25/08/04 Nourlangie, KNP 12°51'51.7"S, 132°48'53.5"E Eucalypt woodland dominated by Eucalyptus miniata X 25/08/04 Jabiru 12°40'31"S, 132°50'09"E Artificial structure 26/08/04 Jim Jim billabong 12°56'30.9"S, 132°33’13.9"E Woodland adjacent to X campground, KNP riparian zone 29/08/04 Nitmiluk National Park 14°19'08"S 132°25T7"E Large dense trees in the campground X 05/09/04 Mandorah 12°25'59"S 130°45'46"E Artificial structure 18/11/04 Hyptis Heights, KNP 12°48'48.5”S, 132°35 '40.1 "E Artificial structure 01/12/04 Jim Jim ranger station, KNP 12°55 '48.1 "S, 132°34'08.5"E Artificial structure 06/12/04 Mardugal campground, 12°55'55.8"S, 132 0 32'19.1"E Woodland and riparian X KNP vegetation, dominant trees include Acacia auriculiformis and Pandanus spiralis 11/12/04 Holmes Jungle Nature 12°24'06.5"S 130°55'53.6"E Monsoon and Melaleuca X X Reserve, Darwin swamp forest 14/12/04 Nourlangie Camp, KNP 12°45’42.7"S, 132°39'37.9"E Monsoon forest X 16/12/04 Bowali Visitor Centre, KNP 12°40'32"S 132°49'02"E Artificial structure 16/12/04 Bark Hut (Annaburroo) 12°54'00.7"S, 131°40'32.4"E Artificial structure 22/12/04 Manton Dam 12°51'44.0"S, 131°07'01.4"E Riparian forest dominated by Acacia auriculiformis and X Melaleuca 23/12/04 Bardedjilidji walk, KNP 12°25'58.5"S, 132°58'11.2"E Woodland dominated by Eucalyptus spp. and Pandanus spiralis X 08/05/05 Cape Crawford 16°41’01.7"S, 135°43'30.5"E Artificial structure 20/08/05 Gunbalanya (Oenpelli) 12°19'35.9'S 133°03’21.5’E Artificial structure 04/09/05 Gunn Point 12°09'33.4"S 131°01T6.2"E Coastal monsoon forest, largest trees Bombax ceiba and Acacia auriculiformis X X X 114 Distribution and habitat use by an invasive gecko Fig. 3. Distribution of Hemidactylus frenatus in natural habitats in the north-east and central-north of the Northern Territory, Australia, from the combined records of the Northern Territory Vertebrate Fauna Atlas and field surveys. Dashed line indicates the border of Kakadu National Park. DISCUSSION The collation of site records clearly shows that Hemidactylus frenatus is established in many areas of the tropical Northern Territory, in particular the Top End north of 16°S, although some records may represent temporary introductions. Recent literature (e.g. Cogger 2000) portrays a distribution confined to localities along the Stuart Highway - essentially a strip down the centre of the Northern Territory. But here we show that //. frenatus is present to the east and to the west of the Stuart Highway, with many localities broadly distributed north of I6°S, and more sparsely separated localities further south. Both this study and previous literature indicate a southerly range limit of 22° S. Ota (1994) found that eggs of H. frenatus would not hatch below 19° C, and this is probably one factor limiting the southerly distribution. Habitat association data presented here show Hemidactylus frenatus utilising both artificial and natural habitats (Table 1). Much recent literature has regarded the species as dependant on artificial habitats (e.g. Cogger 2000, Wilson 2005) and overlooked or ignored the few documentations of natural habitat use (Kikkawa and Montcith 1980; Gambold and Woinarski 1993; Keim 2002). From this study it can be seen that H. frenatus commonly occurs in natural vegetation proximate to human habitation or vehicle access in the Northern Territory north of 15°S (Fig. 3). The most frequently recorded of these natural habitats were forests with comparatively dense canopies or eucalypt woodland adjacent to closed forests. These types of forests possibly provide a preferable thermal range for a species adapted to mesic tropical conditions. Alternatively, tree species associated with denser forests may provide more suitable refugia for the colonisers than the smooth- barked cucaiypts that predominate in open woodland. In the one woodland site not adjacent to denser forest where H. frenatus was recorded (Nourlangie carpark. Kakadu National Park), repeat surveys in 2004 did not record the species, and we suspect that the population has not persisted there. Although data do not show the habitat association for records south of 16°S, the distribution along major highways suggests that with the lack of mesic vegetation the species is more likely to be restricted to artificial structures in this part of the Northern Territory. It is probable that our data underestimates the distribution of the species in natural habitats, as we are aware that some NTFVA sites, although having no data attached, are from natural habitats. One area for which this is the case is the coast of the Cobourg Peninsula (J. Woinarski pers. comm.). One specimen was collected at Port Essington by John Gilbert between 1838 and 1841 (Fisher and Calaby 2009), but the habitat was not recorded [Incidentally there was no sign of the species there during CSIRO visits between 1966 and 1969 (Fisher and Calaby 2009).] These sites, on the extreme north of Australia’s coast, may represent the oldest sites of colonisation by this gecko in the country. Hemidactylus frenatus has occurred in the Northern Territory since at least the 1800’s (Cogger and Lindner 1974), however trepang fishers from Sulawesi, Timor and New Guinea (popularly known as Macassans) regularly visited northern Australia from as far back as 100 years before European settlement (Macknight 1976), and the Cobourg Peninsula was a well-known destination of these traders (see Mitchell 1995). Many features of the biology of Hemidactylus frenatus make this gecko well suited for colonisation, such as the ability of females to store sperm for up to 36 weeks (Murphy-Walker and Haley 1996), the ability tooutcompete other geckos without costly agonistic interactions (Petren and Case 1996), and the ability to use its own species as a food source (Galina-Tessaro et al. 1999). Given these findings, it seems probable that H. frenatus will colonise suitable artificial anthropogenic and natural habitats throughout tropical Australia. We are aware of a number of undocumented populations in Arnhem Land (P. Homer pers. comm.) and inland Queensland (JLM unpub. data). Further study of H. frenatus provides numerous opportunities for research into both theoretical issues, such as the mechanisms of competition, and applied management issues, such as the anthropogenic means of dispersal in invasive species. ACKNOWLEDGEMENTS Many thanks to John Woinarski, Greg Connors and Craig Hempel (NRETAS) for assistance with the NTVFA, Alaric Fisher (NRETAS) for his helpful review of the manuscript, and to Wendy Telfer, Jo Dingle and NRETAS staff for their generous help with the data mapping. Paul Horner and an anonymous referee kindly commented on an earlier version of this paper. 115 J. L. McKay, A. D. Griffiths and B. Crase REFERENCES Case, T. J., Bolger, D.T. and Petren, K. 1994. Invasions and competitive displacement among house geckos in the tropical Pacific. Ecology 75(2): 464-177. Clarke, R. 2006. Southern Exploration Drilling Area (Boyd Bay and Norman Creek) Flora and Fauna Baseline Survey, Biosis Research Report to Comalco, Weipa. Cogger, H. 2000 (sixth edition). Reptiles ami amphibians of Australia. New Holland, Sydney. Cogger, H. and Lindner, D. 1974. Frogs and Reptiles. In: Frith, H., and Calaby, J. (eds). Fauna survey of the Port Essington district, Coburg Peninsula, Northern Territory of Australia. Division of Wildlife Research Technical Paper no. 28, CSIRO Australia: Canberra. Cole, N.C., Jones, C.G. and Harris, S. 2005. The need for enemy-free space: The impact of an invasive gecko on island endemics. Biological Conservation 125: 467-474. Cook, R. 1990. Range extension of the Darwin House Gecko, Hemidaclyhts frenatus. Herpetofauna 20( 1): 23-27. Fisher, C. and Calaby, J. 2009. The top of the Top End: John Gilbert’s manuscript notes for John Gould on vertebrates from Port Essington and Cobourg Peninsula (Northern Territory, Australia); with comments on specimens collected during the settlement period 1838 to 1849, and subsequently. The Beagle, Records of the Museums and Art Galleries of the Northern Territory Supplement 4: 1-244. Frankenberg, E. and Werner, Y. 1981. Adaptability of the daily activity pattern to changes in longitude, in a colonizing lizard, Hemidactylus frenatus. Journal of Herpetology 15(3): 373-376. Galina-Tessaro, P., Ortega-Rubio, A., Alvarez-Cardenas, S. and Amaud, G. 1999. Colonization of Socorro Island (Mexico) by the tropical house gecko Hemidactylus frenatus (Squamata: Gekkonidae). Revista de Biologia Tropical 47(1-2): 237 - 238. Gambold, N. and Woinarski, J.C.Z. 1993. Distributional patterns of herpetofauna in monsoon rainforests of the Northern Territory, Australia. Australian Journal of Ecology 18: 431-449. Goris, R., and Maeda, N. 2004. Guide to the amphibians and reptiles of Japan. Kriegcr: Malabar. Keim, L.D. 2002. The spatial distribution of the introduced Asian House Gecko (Hemidactylus frenatus) across suburban/ forest edges. Unpublished BSc Honours thesis, Department of Zoology and Entomology, University of Queensland: Brisbane. Kendrick, P. and Rolfe, J. 1991. The reptiles and amphibians of Kimberley rainforests. In. Kimberley rainforests of Australia. McKenzie, N., Johnston, R., and Kendrick, P. (eds). Surrey Beatty and Sons: Chipping Norton, New South Wales. Kikkawa, J. and Monteith, G. 1980. Animal ecology of monsoon forests of the Kakadu region, Northern Territory. Consultancy report to the Director, Australian National Parks and Wildlife Service, Canberra. Lee, J. 2000. Field guide to the amphibians and reptiles of the Maya world. Cornell University Press: New York. Manthey, U. and Grossmann, W. 1997. Amphibien & Reptilien Sudostasiens. Natur und Tier - Verlag: Munster. McCoy, M. 2000. Reptiles of the Solomon Islands. Zoographics: Kuranda. (cd rom). McKay, J.L. and Homer, P. 2007. First records of the Mourning Gecko Lepidodactylus lugubris (Dumeril and Bibron, 1836) from the Northern Territory mainland. Herpetofauna 37(2): 75-80. Macknight, C. 1976. The voyage to Marege. Macassan trepangers in northern Australia. Melbourne University Press: Melbourne. Mitchell, S. 1995. A transient heritage: trepanging sites on the Cobourg Peninsula. Historic Environment Il(2&3): 37-46. Murphy-Walker, S. and Haley, S.R. 1996. Functional sperm storage duration in female Hemidactylusfrenatus (Family Gekkonidae). Herpetologica 52(3): 365-373. Newbery, B. and Jones, D.N. 2007. Presence of Asian House gecko Hemidactylus frenatus across an urban gradient in Brisbane: influence of habitat and potential for impact on native gecko species. Pp. 59-65. In Lunney, D., Eby, P., Hutchings, P. and Burgin, S. (eds) Pest or guest: the zoology’ of overabundance. Royal Zoological Society of New South Wales: Mosman, New South Wales. Ota, H. 1994. Female reproductive cycles in northernmost populations of the two gekkonid lizards, Hemidactylus frenatus and Lepidodactylus lugubris. Ecological Research 9: 121-130. Petren, K. and Case, T.J. 1996. An experimental demonstration of exploitation competition in an ongoing invasion. Ecology 77(1): 118-132. Rivas Fuenmayor, G„ Ugucto, G., Bauer, A., Barros, T. and Manzanilla, J. 2005. Expansion and natural history of a successful colonizing gecko in Venezuela (Reptilia: Gekkonidae: Hemidactylus mabouia ) and the discovery of H. frenatus in Venezuela. Heipetological Review 36(2): 121-125. Savage, J.M. 2002. The amphibians and reptiles of Costa Rica: A herpetofauna between two continents, between two seas. University of Chicago Press: Chicago. Schmidt Ballardo, W„ Mendoza Quijano, F. and Martinez Solis, M. 1996. Range extensions lot Hemidactylus frenatus in Mexico. Heipetological Review 27(1): 40. Spawls, S, Howell, K., Drewes, R. and Ashe, J. 2001. Field guide to the reptiles of East Africa. Academic Press: London. Townsend, J. and Kiysko, K. 2003. The distribution of Hemidactylus frenatus (Sauria: Gekkonidae) in northern peninsular Florida. Florida Scientist 66(3): 204-208. Wilson, S. 2005. A Field guide to reptiles of Queensland. Reed New Holland: Sydney. Wilson, S. and Knowles, D. 1988. 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Accepted 11 November 2009 116 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25 : 117-120 Short Communication Anadara granosa (Mollusca: Bivalvia: Arcidae) discovered live in Darwin Harbour, with implications for understanding climate change in northern Australia PATRICIA M. BOURKE 1 AND RICHARD C. WILLAN 2 'Heritage Branch, Department of Natural Resources, Environment, The Arts and Sport, PO Box 496, Palmerston, NT0831, AUSTRALIA patricia.hourke@nt.gov.au 2 Museum and Art Gallery Northern Territory, Department of Natural Resources, Environment, The Arts and Sport, GPO Box 4646, Darwin, NT0801, AUSTRALIA richard. willan@nt.gov. au In August 2008, sampling of mudflats on the southern shoreline of Middle Arm peninsula, Darwin Harbour, located an extant population of Anadara granosa (Linne), a bivalve mollusc commonly called Roughback Cockle [the FAO name is Granular Ark], This species occurs in huge quantities in prehistoric shell middens around Darwin, but is now very rare and was thought to be possibly locally extinct. The discovery came out of the need to locate live specimens for comparison with archaeological shells submitted for isotope analysis as part of a larger project ‘Climate Change and Human Behavioural Variability in the Coastal Wet-Dry Tropics of Northern Australia’. This collaborative project, being lead by Dr Sally Brockwell of the Australian National University, seeks to explore links between climatic/environmental/ecological/malacological Fig. 1. Location of sampling site, Middle Arm peninsula, Darwin Harbour, Northern Territory. Illustration courtesy M. Fegan. change and the interpretations of major cultural change in the archaeological record in three geographically distinct coastal regions of tropical northern Australia. The site at which the Anadara granosa (hereafter Anadara) were located is on the shoreline of Middle Arm, the largest sub-estuary of Darwin Harbour (Fig. 1), fed mainly by the Blackmore River with freshwater flows during the wet season. This site, in an embayment on the Middle Arm mainland downstream of Channel Island, was chosen because of the relatively easy access to mudflats close to existing Aboriginal shell middens that are dominated by Anadara shells. These tidal mudflats are mainly formed from intertidal marine alluvium, mud, clay and silt (Pietsch 1986; Michie 1988). Access to the site was gained through the wide mangrove forest that today fringes much of the Harbour (Brocklehurst and Edmeades 1996) via a low rocky ridge extending to an oyster-dominated ( Saccostrea cucullata (Born)) reef at the seaward edge. The main mangrove species observed on this tidal mudflat arc Rhizophora stylosa Griff, in the central zone and Sonneratia alba Smith in A. Rees on the seaward fringe. The area is generally undeveloped, apart from an aquaculture farm that presently operates some two kilometres south of this site. The site was sampled on 5 and 22 August 2008, in the second half of the seven month long dry season that characterises Darwin’s monsoonal climate. Sampling on both occasions was conducted over an area of approximately 10 m 2 and over approximately 1.5 hr on a spring low tide (Fig. 2). One adult Anadara (shell length 36.1 mm) was found live on the first occasion (Fig. 3). On the second occasion, four live adults (shell lengths 47.3, 43.6, 39.0, 51.6 mm) and one freshly dead Anadara with conjoined valves (shell length 49.8 mm) were found. Of this total of six live/fresh Anadara , three were located at the surface and three were buried 6-10 cm down in very soft fine black silty mud that was 80-90 cm deep and contained abundant disarticulated dead valves of Anadara and Placuna placenta. 117 P. M. Bourke and R. C. Willan Fig. 2. M. Fegan thigh-deep in mud at sampling site. Note pneumatophores of Sonneratia alba in foreground. Photo. R.C. Willan. Fig. 3. Ventral view of live Anadara granosa individual (NT M P.41871) photographed soon after collection. Photo. R.C. Willan. When collected, and immediately thereafter, the Anadara were crawling very actively, indicating the probability of considerable movement within the substrate when alive. Following fixation in absolute ethanol enabling future genetic analyses, all the animals were dissected from their shells and deposited in the mollusc collection of the Museum and Art Gallery Northern Territory under the registration numbers P.41871 (for the specimen collected on 5 August) and P.41930 (for the specimens collected on 22 August). The shells themselves were then sent overseas for isotope analyses. The results of this analysis will be compared with the results of isotope analysis of archaeological Anadara shells sampled from radiocarbon-dated shell mounds during excavations in 1996 on the same section of southern shoreline of Middle Arm peninsula and from Hope Inlet, Shoal Bay. Since no study has been conducted on the growth of Anadara in northern Australia we do not know precisely how old these individuals from Darwin Harbour might be. In India, Narasimhan (1968) reported that Anadara reaches 31.5 mm shell length after one year, 49.5 mm after two years, and attains sexual maturity at seven months old. Valves of Anadara dominate prehistoric shell mounds around Darwin Harbour (Fig. 4), suggesting large populations once existed that must have been easily exploited by the local inhabitants. All /f/mr/ara-dominated mounds that have been radiocarbon dated thus far belong to the pre- European period, formed mainly between 1500 and 500 years BP (Bourke 2004; Bourke and Crassweller 2006). Anadara , whose preferred habitat is mudflats in protected bays and estuaries (Poutiers 1998; R.C. Willan pers. obs.), no longer occurs in any significant quantity in the Darwin coastal environment of extensive mangrove-colonised tidal flats, suggesting extirpation through local environmental change (Hiscock 1997). Cessation of th e Anadara mound building period across the northern Australian coast by 500 years BP also suggests regional climatic/environmental change (Bourke et al. 2007). While it may have declined in abundance, people continued to harvest Anadara after the mound-building period ceased. Local Aboriginal people in the Darwin area report that when they were children (some 3(M0 years ago) they knew of areas supporting enough Anadara to collect a couple of buckets (Bill Risk pers. comm.), but that even this quantity has declined in recent years. By contrast, today the most common edible molluscs associated with mangroves in Darwin Harbour are the gastropods Telescopium telescopium (Linnc) (family Potamididae), Terebralia spp. (family Potamididae) and Nerita balteata Reeve (previously known as N. lineata Gmelin, but this name is preoccupied) (family Neritidae) (Smith et al. 1997; Bourke and Willan pers. obs.). These gastropods occur only in small numbers in the shell mounds around Darwin. Significantly, these species of molluscs, together with others - of Potamididae and Ellobiidae, and bivalves of the family Corbiculidae - that occur sympatrically with them, are euryhaline and much more tolerant of long temporal extremes and wide fluctuations in salinity and temperature than stenohaiine mudfiat bivalves such as Anadara (Healy and Wells 1998; Peterson and Wells 1998; R.C. Willan pers. obs.). While Anadara is known to tolerate a range of physical environmental factors, proliferation to abundance does require an optimal habitat setting. Shore elevation, slope of the seabed and substrate type are some known factors that affect successful Anadara recruitment, growth and population stability (Broom 1985). Studies elsewhere in the Indo-Pacific have established that the highest population densities of Anadara occur in the fine soft brackish muds of open intertidal mudflats bordering, but not within, mangrove swamps and near, but not in, the mouths of large rivers (Broom 1982,1985; Pathansali 1 966). These habitats provide the optimal conditions of soft brackish (salinity between 26 to 31 ppt) fine silt-mud substrate, intertidal or marginally subtidal elevation level with a particular slope of seabed, and 118 Andara granosa living in Darwin Harbour Fig. 4. Typical Anadara-dominatcd prehistoric shell midden on Middle Arm peninsula coast near sampling site. Photo P.M. Bourke. temperature of25 to 32"C (Broom 1982:136-7; Pathansali 1966:91). Broom (1982: 137-138) noted that in Aitadara beds on Malaysian mudflats there was a black sulphide-rich layer 3-4 cm below the surface, and comments that sandier substrates represent a suboptimal habitat for this species. Of particular interest to us is the distinct difference between the habitat of the modem Anadara reported here for Darwin Harbour and that reported for Anadara collected by the Anbarra people of the Blyth River area of central Arnhem Land in the 1970s. As noted above, the fine silty black mud of these Middle Arm mudflats is 80-90 cm deep. Collection of the five live Anadara was extremely difficult and physically exhausting in this habitat, requiring ploughing through thigh-high mud (Fig. 2) for over two hours. This is in sharp contrast to the Blyth River habitat, where Anadara is collected from much sandier mudflats: “gatherers remain upright and mobile, moving over large areas during one session” ... and ... “Groups of women and children ... rove slowly over the area containingH. granosa, pausing to dig out a shell, when one is sighted, with their fingers, a digging stick or a file”. In 80 minutes on 16 August 1972, 37 kg of Anadara (approximately 1000 individuals) were collected by this method (Meehan 1982: 97). It is known that Anadara can recruit to a range of (muddy to muddy-sandy) substrates in sheltered habitats, but it appears that peak settlement - or peak survivorship - only occurs on muddy sand flats that fall within a restricted range of silt/clay fraction/particle size of the substrate (cf. Broom 1985: 5). More research is needed to explore the role played by other factors in the decline of Anadara in this region, such as possible increasing extremes in range of salinity and temperature conditions. Our observations of low densities of living Anadara are in accord with evidence for ongoing progradation of mudflats and subsequent colonisation by mangroves in the Darwin region (Woodrofl'e and Grime 1999: 319). In fact, the specimens we collected may be cxisting/surviving in a suboptimal habitat in the face of an accreting shoreline and seaward mangrove growth, as has been observed to rapidly encroach on Anadara culture sites on a Malaysian foreshore (Macintosh 1982: 13). ACKNOWLEDGEMENTS We are particularly grateful to Matthew Fegan (Biodiversity Group, Department of Natural Resources, Environment, the Arts and Sport) for venturing into, and wading through, thigh-deep mud to collect these specimens for us, and also for preparing Fig. 1. Bill Risk kindly shared his recollections of the occurrence of Anadara in times gone by with us. REFERENCES Bourke, P. 2004. Three Aboriginal shell mounds at Hope Inlet: evidence for coastal, not maritime Late Holocene economies on the Beagle Gulf mainland, northern Australia. Australian Archaeology 59: 10-22. Bourke P. and Crasswellcr, C. 2006. Radiocarbon dates from middens around Darwin I larbour: cultural chronology of a pre-European landscape. Australian Aboriginal Studies 2: 116-119. Bourke P, Brockwell, S., Faulkner, P. and Meehan, B. 2007. Climate variability in the mid to late Holocene Arnhem Land region. North Australia: Archaeological archives of environmental and cultural change. Archaeology in Oceania 42(3): 91-101. Brocklehurst, P. and Edmeades, B. 1996 .Mangrove survey of Darwin Harbour, Northern Territory, CCNT/NFI Project 1994-5. Technical Report No. 96/7. Northern Territory Department of Lands, Planning and Environment: Darwin. Broom. M.J. 1982. 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Notes on the biology of the cockle Anadara granosa L. Proceedings of the Indo-Pacific Fisheries Council 11:84-98. Peterson, C.H. and Wells, F.E. 1998. Molluscs in marine and estuarine sediments. Pp. 36-46. In. Beesley, P.L., Ross, G.J.B. and Wells, A.E. (eds) Mollusca: The Southern Synthesis. Fauna of Australia Vol.5, Part B. CSIRO Publishing: Melbourne. Pietsch, B.A. 1986. Bynoe 5072, 1:100 000 geological map series , explanatory' notes. Department of Mines and Energy, Northern Territory Geological Survey: Government Printer of the Northern Territory, Darwin. Poutiers, J.M. 1998. Bivalves (Acephala, Lamellibranchia, Pelecypoda). Pp. 123-362. In. Carpenter, K.E. and Niem, V.H. (eds). The living marine resources of the western central Pacific volume 1 seaweeds, coral, bivalves and gastropods. Food and Agriculture Organization of the United Nations: Rome. Smith, A.N., Hanley, J.R. and Love. B. 1997. Comparisons of different quadrat sizes for measuring the densities of crabs and macromolluscs of the mangrove forest floor. Pp. 461-466. In. Hanley, J.R., Caswell, G., Megirian, D. and Larson, H.K. (eds) The marine flora andfauna of Darwin Harbour, Northern Territory, Australia. Proceedings of the sixth international marine biological workshop. Museums and Art Galleries of the Northern Territory and the Marine Sciences Association: Darwin. Woodroffe, C.D. and Grime, D. 1999. Storm impact and evolution of a mangrove-fringed chenier plain, Shoal Bay, Darwin, Australia. Marine Geology 159: 303-321. Accepted 20 July 2009 120 The Beagle, Records of the Museums and Art Galleries of the Northern Territory, 2009 25: 121-123 Short Communication Rectification of the type status for Philiris ziska titeus D’Abrera, 1971 (Lepidoptera: Lycaenidae) MICHAEL F. BRABY Museum and Art Gallery Northern Territory, GPO Box 4646, Darwin, NT 0801, AUSTRALIA, and School of Botany and Zoology, The Australian National University, Canberra, ACT 0200, AUSTRALIA michael. braby@nt.gov. an Kerr (1967) recorded Philiris ziska (Grose-Smith, 1898) from Australia based on a series of 11 males collected from near the Claudie River (now incorporated in Iron Range National Park, Cape York Peninsula, Queensland) during April and May 1966. Kerr’s material was subsequently dispersed among three collections: Australian National Insect Collection, Canberra (ANIC: J. Macqueen and L.E. Couchman collections), Natural History Museum, London (BMNH), and his own private collection, Brisbane. Kerr (1967: 49) noted that two of his specimens were examined by lycaenid expert G.E. Tite, and commented on phenotypic differences in comparison with material from mainland New Guinea in the BMNH, but cautioned that “...the question of subspecific status must await further material”. D’Abrera (1971), however, shortly proceeded to describe it as a subspecies Philiris ziska titeus D’Abrera, 1971 from Australia, based on material collected from Cape York Peninsula, Queensland, and illustrated three syntypes (2cf, 19) housed in the BMNH. Other than stating the range as “Claudie River (Cape York)” (D’Abrera 1971: 373) the label data of this material was not given, and D’Abrera neither provided a diagnosis nor indicated how the taxon differed from the nominate subspecies from mainland New Guinea. It has been assumed (Sands 1979) that the two males included as syntypes by D’Abrera (1971) in his description of titeus were, in fact, the same two specimens lodged in the BMNH by Kerr; however, because D'Abrera (1971) did not provide label data of the material examined this assumption has not been validated. Moreover, the location and to some extent the identity of the female have remained uncertain because this sex was not mentioned by Kerr. Braby (2000) did not formally recognise P. ziska titeus, mainly because of the cautionary comments made by Kerr (1967), and Edwards et al. (2001) subsequently synonymised this taxon under the nominate species. However, Samson and Johnson (2009) recently reinstated the subspecies P. ziska titeus and noted several differences between the two subspecies. They also confirmed the identity of the female sex, which until that stage had not been determined with certainty. Compared with P. ziska ziska (Grose-Smith, 1898), adults of P. ziska titeus from Iron Range are smaller, the male frequently possesses a white suffusion in the postmedian area on the upperside of the fore wing (with the white are varying from few scattered scales to a prominent patch), and the female has more extensive white central areas on the upperside of both wings (Samson and Johnson 2009). Comparison of the illustrations of the two subspecies shown in D’Abrera (1971), Parsons (1998), Braby (2000) and Samson and Johnson (2009) indicate that P. ziska titeus male is also distinguished in having the black apex and termen of the fore wing broader, and the white costal streak on the hind wing more prominent and extending to the base. In describing Philiris ziska titeus in his popular book, D’Abrera (1971) made reference to a ‘type’ specimen amongst the three he illustrated, but did not designate a holotype. That description is unquestionably valid, so the name is available from that work. Although the specimen was depicted above a large red spot, the spot is ambiguous because D’Abrera nowhere explicitly stated that specimens with red spots constituted holotypes, but made an implicit statement to the effect that “I have used type specimens in the illustrations...contained in the British Museum collections..(D’Abrera 1971: 7). Furthermore, according to Article 72.1.2 of the ICZN (1999) regarding the use of the term ‘type’ relating to specimens, the name-bearing type is either a holotype if fixed originally or a lectotype i [fixed subsequently. Hence, D’Abrera’s vague reference to a type for P. ziska titeus does not constitute an original fixation, unlike, for example, Pseudodipsas eone una D’Abrera, 1971 in which he provided type data of the specimen with the red spot and used the word ‘holotype’ (D’Abrera 1971: 341). Both Edwards et al. (2001) and Samson and Johnson (2009) referred to a ‘holotype’ of P. ziska titeus', however, this action is herein interpreted to constitute an incorrect subsequent fixation. Moreover, their nomenclatural action was based on an illustrated syntype and is not evidence that the specimen is fixed (Article 72.4.7). According to Article 73.2 of the ICZN (1999), all the specimens of the type series are automatically syntypes if neither the holotype nor a 121 M. F. Braby Figs I-IO. Philirisziska titeiis D’Abrera, 1971 type material in The Natural History Museum, London (BMNH). 1-3, lectotype male, showing upperside, underside and labels; 4-6, paralectotype male, showing upperside, underside and labels; 7-9, paralectotype female, showing upperside, underside and labels; 10, paralectotype female showing upperside. Scale bar is 10 mm. lectotype has been fixed. In other words, when a nominal species-group taxon has multiple syntypes, all have equal status in nomenclature as components of the name-bearing type. Further. Recommendation 73F states that where there is more than one specimen in which no holotype was fixed for a nominal species-group taxon established before 2000, an author should proceed as though syntypes may exist and, where appropriate, should designate a lectotype rather than assume a holotype. Examination of D’Abrera’s syntypes in the BMNH indicate that R.I. Vane-Wright had earlier labelled one of the syntype males as ‘holotype’ and the two other specimens as ‘paratypes’; however, these designations are incorrect because D’Abrera (1971) designated neither a holotype nor a paratype. Therefore, in accordance with Article 72.2 (fixation of name-bearing types from the type series of nominal species-group taxa established before 2000) and Article 74.1 (designation of a lectotype) of the 1CZN (1999) I hereby designate one of D’Abrera’s syntypes as the lectotype to become the unique bearer of the name Philiris ziska titeiis and to constitute a formal subsequent fixation since the name was first introduced almost four decades ago. This nomenclatural action does not affect the name of the taxon. Of the syntypes in the BMNH, the male specimen illustrated by D’Abrera (1971:373) with the red spot below it is selected as the lectotype (Figs 1-3) because: (1) this is apparently the specimen that D’Abrera intended to be the unique bearer of the name P. ziska titeiis ; (2) R.I. Vane- Wright assumed that this was the ‘holotype’; and (3) the specimen was previously illustrated showing the upperside, which portrays the diagnostic features of the taxon. The label data for the lectotype male is as follows: “CLAUDIE R„ CAPE YORK, 1 MAY, 1966” [printed label prepared by J.F.R. Kerr], “Specimen photo-graphed by B. D’Abrera, 1970”, “B.M. Reg. No. 1966-587.”, “253”, “Holo-type”, “Philiris ziska titeus, D’Abrera, det. R.I. Vane-Wright, HOLOTYPE cf”. Comparison of the image of this specimen in D’Abrera (1971) with that of Figure 1 indicate damage to the antennae, with the clubs missing, but otherwise it is identical. The two other syntypes illustrated by D’Abrera (1971) must now be regarded as paralectotypes, and not paratypes as considered by R.I. Vane-Wright or Samson and Johnson (2009). The label data for these paralectotypes is as follows: \