DOCSLIB.ORG

UC Berkeley Electronic Theses and Dissertations

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
UC Berkeley Electronic Theses and Dissertations UC Berkeley UC Berkeley Electronic Theses and Dissertations Title Elucidating the Evolutionary Consequences of Sociality Through Genome-wide Analyses of Social and Solitary Mammals Permalink https://escholarship.org/uc/item/8zr0f93f Author Crawford, Jeremy Chase Publication Date 2016 Peer reviewed|Thesis/dissertation eScholarship.org Powered by the California Digital Library University of California Elucidating the Evolutionary Consequences of Sociality Through Genome-wide Analyses of Social and Solitary Mammals By Jeremy Chase Crawford A dissertation submitted in partial satisfaction of the requirements for the degree of Doctor of Philosophy in Integrative Biology in the Graduate Division of the University of California, Berkeley Committee in charge: Professor Eileen A. Lacey, Chair Professor George E. Bentley Professor Montgomery W. Slatkin Professor Damian O. Elias Spring 2016 Elucidating the Evolutionary Consequences of Sociality Through Genome-wide Analyses of Social and Solitary Mammals Copyright © 2016 By Jeremy Chase Crawford Abstract Elucidating the Evolutionary Consequences of Sociality Through Genome-wide Analyses of Social and Solitary Mammals by Jeremy Chase Crawford Doctor of Philosophy in Integrative Biology University of California, Berkeley Professor Eileen A. Lacey, Chair Social affiliation and group living are seminal aspects of some of the most exciting and intensely studied topics in behavioral biology, from the field of human psychopathology to investigations of cooperation and reproductive skew in animal societies. Understanding how and why sociality evolves as an alternative to the much more common trait of solitary living has long been a topic of special interest among biologists, particularly in light of evidence that group living can impose a number of costs (e.g., increased exposure to pathogens or increased resource competition) that can negatively impact direct fitness. It is hypothesized that sociality only evolves when the benefits associated with cooperation outweigh the costs of competition. Social animals are therefore likely exposed to a unique set of evolutionary pressures as a result of the distinct costs and benefits inherent to their gregarious lifestyles, and social animals should consequently exhibit adaptations that specifically counterbalance the costs associated with sociality. For my dissertation, I set out to explore the evolutionary consequences of sociality by investigating patterns of genomic variation and change in social and solitary animals from a population-level and a broad, comparative perspective, respectively. The first two chapters of my dissertation serve as a comparative case study on the impacts of sociality on population structure in a novel rodent system. I present population-level genomic data from two species of pebble-mound mice (genus Pseudomys, family Muridae) endemic to mainland Australia: the solitary Queensland pebble-mound mouse (P. patrius) and the social Ngadji (P. chapmani). Like other pebble-mound mice, these focal species construct large aggregations of pebbles over their subterranean burrows that, although not necessary for survival, are required by females for mating. As a result of their distinct social systems, these closely related and ecologically similar congeners serve as compelling point of comparison. By characterizing patterns of genomic variation within each of these species, I demonstrate differences in population structure between the two species, particularly in relationship to pebble-mounds and kinship. In Chapter 1, I demonstrate that the Queensland pebble-mound mouse exhibits significant evidence of kin structure despite being solitary. In this particular case, 1 kin structure seems to arise as a result of the spatially fixed resources (i.e., pebble-mounds) sought out by females. Because affiliations among close kin are very typical of social animals, these findings raise questions about how social and solitary animals might aggregate differently. These questions are then addressed in Chapter 2, where I demonstrate that the social Ngadji also exhibits kin stratification around pebble-mounds, but on a much broader scale than in the Queensland pebble-mound mouse. Beyond describing the molecular ecology of these two non- model species, this work demonstrates that population-level studies that utilize comparative frameworks of closely related and ecologically similar species can provide insights into the impacts of sociality on dispersal and mating system that might inform future studies on the ecological conditions and behavioral mechanisms underlying group living. Whereas the first two chapters consider the impacts of social system on general, population-level processes, the final chapter tests an explicit hypothesis about the evolutionary consequences of sociality on a broader comparative scale. Of all the proposed costs associated with group living, increased exposure to pathogens may be one of the most important: not only are pathogen exposure and disease susceptibility are two of the greatest influences on an individual’s reproductive success, but communicable diseases are known to thrive in communities characterized by group living and high rates of conspecific interaction. However, attempts to explicitly demonstrate the putative immunological consequences of sociality have historically proven difficult. For example, consider two ecologically similar species that share recent common ancestry but demonstrate distinct social organizations. One might attempt to characterize differences in immune pressures by measuring differences in pathogen exposure or parasite loads between the two species. However, divergence among species generally leads to divergence among their respective pathogens and parasites, such that measures of pathogen or parasite loads may become entirely incomparable between the two species. Similarly, this approach assumes that no adaptations (physiological, behavioral, or otherwise) have arisen since the divergence of the two species that might counteract their respective immune pressures. Rather than attempting to quantify the extent of immune-related evolutionary pressures by assessing pathogen or parasite prevalence, Chapter 3 characterizes the relative pathogen- mediated pressure acting on social and solitary species by assessing positive selection in immune orthologues from nine species across three divergent mammal lineages. These analyses demonstrate that relatively social and solitary mammals experience distinct evolutionary pressures, with group-living species experiencing faster rates of evolution at immune loci. When considered in conjunction with candidate loci studies in more limited taxonomic comparisons, these findings suggest that increased immune burden is one of the more common costs associated with sociality. 2 During my six years of graduate study, I traveled to more than thirty countries across five continents. This dissertation is dedicated to the innumerable strangers who showed me kindness during those adventures. i TABLE OF CONTENTS Dedication i Table of Contents ii List of Figures iv List of Tables v Acknowledgements vi Curriculum Vitae ix Chapter 1: Population genomics of the Queensland pebble-mound mouse 1 1.1 Abstract ...............................................................................................................1 1.2 Introduction .........................................................................................................2 1.3 Material and methods ..........................................................................................4 (a) Specimens and samples ..............................................................................4 (b) Genomic libraries .......................................................................................4 (c) Targeted enrichment experiment ................................................................4 (i) Probe design ......................................................................................5 (ii) In-solution hybridization ...................................................................5 (d) Data processing ..........................................................................................6 (e) Statistical analyses ......................................................................................8 (i) Inter-locality analyses ........................................................................8 (ii) Intra-locality analyses ........................................................................8 1.4 Results ...............................................................................................................10 (a) Genomic variation ....................................................................................10 (b) Inter-locality genetic structure ..................................................................10 (c) Intra-locality genetic structure ..................................................................10 (d) Genetic substructure of pebble-mounds ...................................................11 1.5 Discussion .........................................................................................................13 (a) Population-scaled mutation rate and effective population size ................13 (b) Genomic variation among localities .........................................................14 (c) Temporal genetic structure at Hidden Valley ...........................................15 (d) Implications for dispersal and mating system ..........................................15
Load more

Recommended publications
  • Checklist of the Mammals of Indonesia
    CHECKLIST OF THE MAMMALS OF INDONESIA Scientific, English, Indonesia Name and Distribution Area Table in Indonesia Including CITES, IUCN and Indonesian Category for Conservation i ii CHECKLIST OF THE MAMMALS OF INDONESIA Scientific, English, Indonesia Name and Distribution Area Table in Indonesia Including CITES, IUCN and Indonesian Category for Conservation By Ibnu Maryanto Maharadatunkamsi Anang Setiawan Achmadi Sigit Wiantoro Eko Sulistyadi Masaaki Yoneda Agustinus Suyanto Jito Sugardjito RESEARCH CENTER FOR BIOLOGY INDONESIAN INSTITUTE OF SCIENCES (LIPI) iii © 2019 RESEARCH CENTER FOR BIOLOGY, INDONESIAN INSTITUTE OF SCIENCES (LIPI) Cataloging in Publication Data. CHECKLIST OF THE MAMMALS OF INDONESIA: Scientific, English, Indonesia Name and Distribution Area Table in Indonesia Including CITES, IUCN and Indonesian Category for Conservation/ Ibnu Maryanto, Maharadatunkamsi, Anang Setiawan Achmadi, Sigit Wiantoro, Eko Sulistyadi, Masaaki Yoneda, Agustinus Suyanto, & Jito Sugardjito. ix+ 66 pp; 21 x 29,7 cm ISBN: 978-979-579-108-9 1. Checklist of mammals 2. Indonesia Cover Desain : Eko Harsono Photo : I. Maryanto Third Edition : December 2019 Published by: RESEARCH CENTER FOR BIOLOGY, INDONESIAN INSTITUTE OF SCIENCES (LIPI). Jl Raya Jakarta-Bogor, Km 46, Cibinong, Bogor, Jawa Barat 16911 Telp: 021-87907604/87907636; Fax: 021-87907612 Email: [email protected] . iv PREFACE TO THIRD EDITION This book is a third edition of checklist of the Mammals of Indonesia. The new edition provides remarkable information in several ways compare to the first and second editions, the remarks column contain the abbreviation of the specific island distributions, synonym and specific location. Thus, in this edition we are also corrected the distribution of some species including some new additional species in accordance with the discovery of new species in Indonesia.
    [Show full text]
  • Calaby References
    Abbott, I.J. (1974). Natural history of Curtis Island, Bass Strait. 5. Birds, with some notes on mammal trapping. Papers and Proceedings of the Royal Society of Tasmania 107: 171–74. General; Rodents; Abbott, I. (1978). Seabird islands No. 56 Michaelmas Island, King George Sound, Western Australia. Corella 2: 26–27. (Records rabbit and Rattus fuscipes). General; Rodents; Lagomorphs; Abbott, I. (1981). Seabird Islands No. 106 Mondrain Island, Archipelago of the Recherche, Western Australia. Corella 5: 60–61. (Records bush-rat and rock-wallaby). General; Rodents; Abbott, I. and Watson, J.R. (1978). The soils, flora, vegetation and vertebrate fauna of Chatham Island, Western Australia. Journal of the Royal Society of Western Australia 60: 65–70. (Only mammal is Rattus fuscipes). General; Rodents; Adams, D.B. (1980). Motivational systems of agonistic behaviour in muroid rodents: a comparative review and neural model. Aggressive Behavior 6: 295–346. Rodents; Ahern, L.D., Brown, P.R., Robertson, P. and Seebeck, J.H. (1985). Application of a taxon priority system to some Victorian vertebrate fauna. Fisheries and Wildlife Service, Victoria, Arthur Rylah Institute of Environmental Research Technical Report No. 32: 1–48. General; Marsupials; Bats; Rodents; Whales; Land Carnivores; Aitken, P. (1968). Observations on Notomys fuscus (Wood Jones) (Muridae-Pseudomyinae) with notes on a new synonym. South Australian Naturalist 43: 37–45. Rodents; Aitken, P.F. (1969). The mammals of the Flinders Ranges. Pp. 255–356 in Corbett, D.W.P. (ed.) The natural history of the Flinders Ranges. Libraries Board of South Australia : Adelaide. (Gives descriptions and notes on the echidna, marsupials, murids, and bats recorded for the Flinders Ranges; also deals with the introduced mammals, including the dingo).
    [Show full text]
  • Listing Advice and Included This Species in the Extinct Category, Effective from 03/03/2021 Listing Advice Conilurus Capricornensis
    THREATENED SPECIES SCIENTIFIC COMMITTEE Established under the Environment Protection and Biodiversity Conservation Act 1999 The Minister approved this listing advice and included this species in the Extinct category, effective from 03/03/2021 Listing Advice Conilurus capricornensis Capricorn Rabbit-rat Taxonomy Conventionally accepted as Conilurus capricornensis Cramb & Hocknull, 2010. Summary of assessment Conservation status Following a listing assessment of Conilurus capricornensis (Capricorn Rabbit-rat), the Threatened Species Scientific Committee (the Committee) has determined that there is sufficient evidence to list the Capricorn Rabbit-rat in the Extinct category under the Environmental Protection and Biodiversity Conservation Act 1999 (EPBC Act). Species can be listed under state and territory legislation. For information on the listing status of this species under relevant state or territory legislation, see http://www.environment.gov.au/cgi- bin/sprat/public/sprat.pl Reason for listing assessment by the Threatened Species Scientific Committee This advice follows assessment of new information provided to the Committee to list the Capricorn Rabbit-rat. Public consultation Notice of the proposed amendment and a consultation document was made available for public comment for 31 business days between 31 July 2020 and 11 September 2020. Any comments received that were relevant to the listing of the species were considered by the Committee as part of the assessment process. Species/sub-species information Description No description of the Capricorn Rabbit-rat is available. The species is known only from skull and dental fragments. However, by comparing the remains with other species in the Conilurus genus, it is believed to have been similar to the extant C.
    [Show full text]
  • Pseudomys Auritus (Long-Eared Mouse)
    Consultation Document on Listing Eligibility Pseudomys auritus (Long-eared Mouse) You are invited to provide your views and supporting reasons related to the eligibility of Pseudomys auritus (Long-eared Mouse) for inclusion on the EPBC Act threatened species list in the Extinct category. Evidence provided by experts, stakeholders and the general public are welcome. Responses can be provided by any interested person. Anyone may nominate a native species, ecological community or threatening process for listing under the Environment Protection and Biodiversity Conservation Act 1999 (EPBC Act) or for a transfer of an item already on the list to a new listing category. The Threatened Species Scientific Committee (the Committee) undertakes the assessment of species to determine eligibility for inclusion in the list of threatened species and provides its recommendation to the Australian Government Minister for the Environment. Responses are to be provided in writing either by email to: [email protected] or by mail to: The Director Marine and Freshwater Species Conservation Section Biodiversity Conservation Division Department of Agriculture, Water and the Environment PO Box 787 Canberra ACT 2601 Responses are required to be submitted by 11 September 2020. Contents of this information package Page General background information about listing threatened species 2 Information about this consultation process 3 Draft information about the common name and its eligibility for listing 4 References cited 8 Collective list of questions – your views 8 Pseudomys auritus (Long-eared Mouse) consultation document Page 1 of 11 General background information about listing threatened species The Australian Government helps protect species at risk of extinction by listing them as threatened under Part 13 of the EPBC Act.
    [Show full text]
  • Factsheet: a Threatened Mammal Index for Australia
    Science for Saving Species Research findings factsheet Project 3.1 Factsheet: A Threatened Mammal Index for Australia Research in brief How can the index be used? This project is developing a For the first time in Australia, an for threatened plants are currently Threatened Species Index (TSX) for index has been developed that being assembled. Australia which can assist policy- can provide reliable and rigorous These indices will allow Australian makers, conservation managers measures of trends across Australia’s governments, non-government and the public to understand how threatened species, or at least organisations, stakeholders and the some of the population trends a subset of them. In addition to community to better understand across Australia’s threatened communicating overall trends, the and report on which groups of species are changing over time. It indices can be interrogated and the threatened species are in decline by will inform policy and investment data downloaded via a web-app to bringing together monitoring data. decisions, and enable coherent allow trends for different taxonomic It will potentially enable us to better and transparent reporting on groups or regions to be explored relative changes in threatened understand the performance of and compared. So far, the index has species numbers at national, state high-level strategies and the return been populated with data for some and regional levels. Australia’s on investment in threatened species TSX is based on the Living Planet threatened and near-threatened birds recovery, and inform our priorities Index (www.livingplanetindex.org), and mammals, and monitoring data for investment. a method developed by World Wildlife Fund and the Zoological A Threatened Species Index for mammals in Australia Society of London.
    [Show full text]
  • Ba3444 MAMMAL BOOKLET FINAL.Indd
    Intot Obliv i The disappearing native mammals of northern Australia Compiled by James Fitzsimons Sarah Legge Barry Traill John Woinarski Into Oblivion? The disappearing native mammals of northern Australia 1 SUMMARY Since European settlement, the deepest loss of Australian biodiversity has been the spate of extinctions of endemic mammals. Historically, these losses occurred mostly in inland and in temperate parts of the country, and largely between 1890 and 1950. A new wave of extinctions is now threatening Australian mammals, this time in northern Australia. Many mammal species are in sharp decline across the north, even in extensive natural areas managed primarily for conservation. The main evidence of this decline comes consistently from two contrasting sources: robust scientifi c monitoring programs and more broad-scale Indigenous knowledge. The main drivers of the mammal decline in northern Australia include inappropriate fi re regimes (too much fi re) and predation by feral cats. Cane Toads are also implicated, particularly to the recent catastrophic decline of the Northern Quoll. Furthermore, some impacts are due to vegetation changes associated with the pastoral industry. Disease could also be a factor, but to date there is little evidence for or against it. Based on current trends, many native mammals will become extinct in northern Australia in the next 10-20 years, and even the largest and most iconic national parks in northern Australia will lose native mammal species. This problem needs to be solved. The fi rst step towards a solution is to recognise the problem, and this publication seeks to alert the Australian community and decision makers to this urgent issue.
    [Show full text]
  • Pseudomys Fumeus
    National Recovery Plan for the Smoky Mouse Pseudomys fumeus Peter Menkhorst and Linda Broome Prepared by Peter Menkhorst (Department of Sustainability and Environment, Victoria) and Linda Broome (Department of Environment and Climate Change, New South Wales) © State of Victoria Department of Sustainability and Environment 2006 This publication is copyright. No part may be reproduced by any process except in accordance with the provisions of the Copyright Act 1968. Authorised by the Victorian Government, 8 Nicholson Street, East Melbourne. ISBN 978-1-74208-712-2 This is a Recovery Plan prepared under the Commonwealth Environment Protection and Biodiversity Conservation Act 1999, with the assistance of funding provided by the Australian Government. This Recovery Plan has been developed with the involvement and cooperation of a range of stakeholders, but individual stakeholders have not necessarily committed to undertaking specific actions. The attainment of objectives and the provision of funds may be subject to budgetary and other constraints affecting the parties involved. Proposed actions may be subject to modification over the life of the plan due to changes in knowledge. Disclaimer This publication may be of assistance to you but the State of Victoria and its employees do not guarantee that the publication is without flaw of any kind or is wholly appropriate for your particular purposes and therefore disclaims all liability for any error, loss or other consequence that may arise from you relying on any information in this publication. Published by the Victorian Government Department of Sustainability and Environment (DSE) Melbourne, 2008 An electronic version of this document is available on the Department of the Environment, Water, Heritage and the Arts website www.environment.gov.au and on the NSW website www.threatenedspecies.environment.nsw.gov.au.
    [Show full text]
  • An Overdue Break-Up of the Genus Pogonomys Milne-Edwards, 1877 (Mammalia: Muridae) Into Two Genera and the Formal Naming of Five Long Overlooked Species
    42 Australasian Journal of Herpetology Australasian Journal of Herpetology 49:42-63. Published 6 August 2020. ISSN 1836-5698 (Print) ISSN 1836-5779 (Online) An overdue break-up of the genus Pogonomys Milne-Edwards, 1877 (Mammalia: Muridae) into two genera and the formal naming of five long overlooked species. LSIDURN:LSID:ZOOBANK.ORG:PUB:33BC1FC2-DC2E-49EB-8003-1DD4E3528194 RAYMOND T. HOSER LSIDurn:lsid:zoobank.org:author:F9D74EB5-CFB5-49A0-8C7C-9F993B8504AE 488 Park Road, Park Orchards, Victoria, 3134, Australia. Phone: +61 3 9812 3322 Fax: 9812 3355 E-mail: snakeman (at) snakeman.com.au Received 1 May 2020, Accepted 23 July 2020, Published 6 August 2020. ABSTRACT An audit of all previously named species and synonyms within the putative genus of mainly New Guinean prehensile tailed mice Pogonomys Milne-Edwards, 1877 found a number of distinctive and divergent species that were not yet recognized by science. Five species were recognized by most authorities as of early 2020. A sixth species, Mus mollipilosus Peters and Doria, 1881, is resurrected from the synonymy of Pogonomys macrourus Milne-Edwards, 1877 on the basis of dentition and body form. Five species and two other subspecies are formally named for the first time in this paper, including one newly named species based on a pair of Holocene age upper and lower left molar teeth collected in Irian Jaya. The divergent lineage including P. loriae Thomas, 1897, P. mollipilosus (Peters and Doria, 1881), P. fergussoniensis Laurie, 1952 and four closely related taxa that are newly named are also placed in a newly erected and named genus Macropogonomys gen.
    [Show full text]
  • Wildlife Matters
    AWC-newsletter/v10 23/5/02 12:11 PM Page 1 Newsletter of Australian Wildlife Conservancy Wildlife Matters AWC TO SAVE THREATENED AWC: Protecting WILDERNESS AND ITS WILDLIFE Australian Wildlife Welcome to the first MT ZERO, NORTH QUEENSLAND newsletter from Australian Wildlife Conservancy (AWC). We trust you will enjoy reading Wildlife Matters, which we hope to fill with good news about the wildlife in AWC’s sanctuaries. Unfortunately, for most of the last 200 years the news regarding Australia’s wildlife has not been good. The Toolache Wallaby, widely regarded as the most beautiful and graceful member of the kangaroo family, is gone forever. The Thylacine, the Paradise Parrot and the enigmatic Lesser Bilby are just some of the other animals that Australia has lost. continued on page 2 CONTENTS Is Mt Zero the Last Chance for the Northern Bettong? 3 Northern Bettong Photo: QPWS Eastern Pebble-mound Mouse Wet Sclerophyll Forest Sanctuary News 4 ustralian Wildlife Conservancy is proposing to acquire a The Evolution of AWC 6 remarkable wilderness area in north Queensland that is AWC Provides New Hope Ahome to more than 35 native mammal species. Located for Five Threatened Species 7 approximately 65 kilometres north-west of Townsville, Mt Zero is a biodiversity-rich property covering nearly 40,000 hectares adjacent to the Wet Tropics World Heritage Area. Sadly, Mt Zero and its wildlife are threatened by logging and grazing. AWC discovered Mt Zero, deep in the Coane Mountain Range, when our scientists visited north Queensland last year. They were delighted to find a property rich in native mammals - a real ‘hotspot’ for Australia’s threatened mammal fauna.
    [Show full text]
  • Dental Adaptation in Murine Rodents (Muridae): Assessing Mechanical Predictions Stephanie A
    Florida State University Libraries Electronic Theses, Treatises and Dissertations The Graduate School 2010 Dental Adaptation in Murine Rodents (Muridae): Assessing Mechanical Predictions Stephanie A. Martin Follow this and additional works at the FSU Digital Library. For more information, please contact [email protected] THE FLORIDA STATE UNIVERSITY COLLEGE OF ARTS AND SCIENCES DENTAL ADAPTATION IN MURINE RODENTS (MURIDAE): ASSESSING MECHANICAL PREDICTIONS By STEPHANIE A. MARTIN A Thesis in press to the Department of Biological Science in partial fulfillment of the requirements for the degree of Master of Science Degree Awarded: Spring Semester, 2010 Copyright©2010 Stephanie A. Martin All Rights Reserved The members of the committee approve the thesis of Stephanie A. Martin defended on March 22, 2010. ______________________ Scott J. Steppan Professor Directing Thesis _____________________ Gregory Erickson Committee Member _____________________ William Parker Committee Member Approved: __________________________________________________________________ P. Bryant Chase, Chair, Department of Biological Science The Graduate School has verified and approved the above-named committee members. ii TABLE OF CONTENTS List of Tables......................................................................................................................iv List of Figures......................................................................................................................v Abstract...............................................................................................................................vi
    [Show full text]
  • Mammals of the Avon Region
    Mammals of the Avon Region By Mandy Bamford, Rowan Inglis and Katie Watson Foreword by Dr. Tony Friend R N V E M E O N G T E O H F T W A E I S L T A E R R N A U S T 1 2 Contents Foreword 6 Introduction 8 Fauna conservation rankings 25 Species name Common name Family Status Page Tachyglossus aculeatus Short-beaked echidna Tachyglossidae not listed 28 Dasyurus geoffroii Chuditch Dasyuridae vulnerable 30 Phascogale calura Red-tailed phascogale Dasyuridae endangered 32 phascogale tapoatafa Brush-tailed phascogale Dasyuridae vulnerable 34 Ningaui yvonnae Southern ningaui Dasyuridae not listed 36 Antechinomys laniger Kultarr Dasyuridae not listed 38 Sminthopsis crassicaudata Fat-tailed dunnart Dasyuridae not listed 40 Sminthopsis dolichura Little long-tailed dunnart Dasyuridae not listed 42 Sminthopsis gilberti Gilbert’s dunnart Dasyuridae not listed 44 Sminthopsis granulipes White-tailed dunnart Dasyuridae not listed 46 Myrmecobius fasciatus Numbat Myrmecobiidae vulnerable 48 Chaeropus ecaudatus Pig-footed bandicoot Peramelinae presumed extinct 50 Isoodon obesulus Quenda Peramelinae priority 5 52 Species name Common name Family Status Page Perameles bougainville Western-barred bandicoot Peramelinae endangered 54 Macrotis lagotis Bilby Peramelinae vulnerable 56 Cercartetus concinnus Western pygmy possum Burramyidae not listed 58 Tarsipes rostratus Honey possum Tarsipedoidea not listed 60 Trichosurus vulpecula Common brushtail possum Phalangeridae not listed 62 Bettongia lesueur Burrowing bettong Potoroidae vulnerable 64 Potorous platyops Broad-faced
    [Show full text]
  • Terrestrial Native Mammals of Western Australia
    TERRESTRIALNATIVE MAMMALS OF WESTERNAUSTRALIA On a number of occasionswe have been asked what D as y ce r cus u ist ica ud q-Mul Aara are the marsupialsof W.A. or what is the scientiflcname Anlechinusfla.t,ipes Matdo given to a palticular animal whosecommon name only A n t ec h i nus ap i ca I i s-Dlbbler rs known. Antechinusr osemondae-Little Red Antechinus As a guide,the following list of62 speciesof marsupials A nteclt itus mqcdonneIlens is-Red-eared Antechi nus and 59 speciesof othersis publishedbelow. Antechinus ? b ilar n i-Halney' s Antechinus Antec h in us mqculatrJ-Pismv Antechinus N ingaui r idei-Ride's Nirfaui - MARSUPALIA Ningauirinealvi Ealev's-KimNinsaui Ptaiigole*fuilissima beiiey Planigale Macropodidae Plani gale tenuirostris-Narrow-nosed Planigate Megaleia rufa Red Kangaroo Smi nt hopsis mu rina-Common Dulnart Macropus robustus-Etro Smin t hop[is longicaudat.t-Long-tailed Dunnart M acr opus fu Ii g inos,s-Western Grey Kangaroo Sminthops is cras sicaudat a-F at-tailed Dunnart Macrcpus antilo nus Antilope Kangaroo S-nint hopsi s froggal//- Larapinla Macropu"^agi /rs Sandy Wallaby Stnintllopsirgranuli,oer -Whire-railed Dunnart Macrcpus rirra Brush Wallaby Sninthopsis hir t ipes-Hairy -footed Dunnart M acro ptrs eugenii-T ammar Sminthopsiso oldea-^f r oughton's Dunnart Set oni x brac ltyuru s-Quokka A ntec h inomys lanrger-Wuhl-Wuhl On y ch oga I ea Lng uife r a-Kar r abul M.yr nte c o b ius fasc ialrls-N umbat Ony c hogalea Iunq ta-W \rrur.g Notoryctidae Lagorchest es conspic i Ilat us,Spectacied Hare-Wallaby Notorlctes
    [Show full text]