NSW DPI Fish Receivers Coded Species List – Version 2 19 January 2018 �
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Biodiversity of Shallow Reef Fish Assemblages in Western Australia Using a Rapid Censusing Technique
Records of the Western Australian Museum 20: 247-270 (2001). Biodiversity of shallow reef fish assemblages in Western Australia using a rapid censusing technique J. Harry Hutchins Department of Aquatic Zoology, Western Australian Museum, Francis Street, Perth, Western Australia 6000, Australia email: [email protected] Abstract -A rapid assessment methodology was used to provide relative abundance data on selected families of Western Australian fishes. Twenty shallow water reef sites were surveyed covering the coastline between the Recherche Archipelago in the south east and the Kimberley in the north. Three groups of atolls located off the Kimberley coast were also included. Eighteen families that best represent the State's nearshore reef fish fauna were targeted. They are: Serranidae, Caesionidae, Lu~anidae, Haemulidae, Lethrinidae, Mullidae, Pempherididae, Kyphosidae, Girellidae, Scorpididae, Chaetodontidae, Pomacanthidae, Pomacentridae, Cheilodactylidae, Labridae, Odacidae, Acanthuridae, and Monacanthidae. Analysis of the dataset using a hierarchical classification technique indicates that four groups of reef fishes are present: a southwest assemblage, a northwest assemblage, an offshore atolls assemblage, and a Kimberley assemblage. The first assemblage is comprised mainly of temperate species, while the latter three are mostly tropical fishes; these two broader groupings narrowly overlap on the west coast between Kalbarri and the Houtman Abrolhos. Evidence of a wide zone of temperate/tropical overlap-as proposed by some previous studies-is not supported by this analysis, nor is the presence of a prominent subtropical fauna on the west coast. Ecological differences of the four assemblages are explored, as well as the impact by the Leeuwin Current on this arrangement. INTRODUCTION western and southern coasts of the State, but could Western Australia occupies about 23 degrees of only provide a brief comparison with other more latitude (12-35°5) covering a large and varied northern areas. -
The Parasitic Dinoflagellate Hematodinium Infects Marine Crustaceans
Marine Life Science & Technology (2021) 3:313–325 https://doi.org/10.1007/s42995-020-00061-z REVIEW The parasitic dinofagellate Hematodinium infects marine crustaceans Caiwen Li1,2,3,4 · Meng Li1,2 · Qian Huang1,4 Received: 27 April 2020 / Accepted: 8 July 2020 / Published online: 2 January 2021 © Ocean University of China 2021 Abstract Hematodinium is a type of parasitic dinofagellate that infects marine crustaceans globally. The parasite lives mainly in the hemolymph or hemocoels of afected hosts, and results in mortalities due to malfunction or loss of functions of major organs. In recent years, the parasite had developed into an emerging epidemic pathogen not only afecting wild populations of economically valuable marine crustaceans in western countries but also the sustainable yield of aquaculture of major crabs in China. The epidemics of the parasitic diseases expanded recently in the coastal waters of China, and caused frequent outbreaks in aquaculture of major crab species, especially Portunus trituberculatus and Scylla paramamosain. In addition, the pathogen infected two species of co-cultured shrimps and multiple cohabitating wild crabs, implying it is a signifcant threat to the sustainable culture of commercially valuable marine crustaceans. In particular, the polyculture system that is widely used along the coast of China may facilitate the spread and transmission of the pathogen. Thus, to provide a better understanding of the biological and ecological characteristics of the parasitic dinofagellate and highlight important direc- tions for future research, we have reviewed the current knowledge on the taxonomy, life cycle, pathogenesis, transmission and epidemiology of Hematodinium spp. Moreover, ecological countermeasures have been proposed for the prevention and control of the emerging infectious disease. -
Marine Biodiversity of the Northern and Yorke Peninsula NRM Region
Marine Environment and Ecology Benthic Ecology Subprogram Marine Biodiversity of the Northern and Yorke Peninsula NRM Region SARDI Publication No. F2009/000531-1 SARDI Research Report series No. 415 Keith Rowling, Shirley Sorokin, Leonardo Mantilla and David Currie SARDI Aquatic Sciences PO Box 120 Henley Beach SA 5022 December 2009 Prepared for the Department for Environment and Heritage 1 Marine Biodiversity of the Northern and Yorke Peninsula NRM Region Keith Rowling, Shirley Sorokin, Leonardo Mantilla and David Currie December 2009 SARDI Publication No. F2009/000531-1 SARDI Research Report Series No. 415 Prepared for the Department for Environment and Heritage 2 This Publication may be cited as: Rowling, K.P., Sorokin, S.J., Mantilla, L. & Currie, D.R. (2009) Marine Biodiversity of the Northern and Yorke Peninsula NRM Region. South Australian Research and Development Institute (Aquatic Sciences), Adelaide. SARDI Publication No. F2009/000531-1. South Australian Research and Development Institute SARDI Aquatic Sciences 2 Hamra Avenue West Beach SA 5024 Telephone: (08) 8207 5400 Facsimile: (08) 8207 5406 http://www.sardi.sa.gov.au DISCLAIMER The authors warrant that they have taken all reasonable care in producing this report. The report has been through the SARDI internal review process, and has been formally approved for release by the Chief of Division. Although all reasonable efforts have been made to ensure quality, SARDI does not warrant that the information in this report is free from errors or omissions. SARDI does not accept any liability for the contents of this report or for any consequences arising from its use or any reliance placed upon it. -
And Polyfluoroalkyl Substances (Pfass)
Food and Chemical Toxicology 127 (2019) 280–287 Contents lists available at ScienceDirect Food and Chemical Toxicology journal homepage: www.elsevier.com/locate/foodchemtox Do conventional cooking methods alter concentrations of per- and T polyfluoroalkyl substances (PFASs) in seafood? ∗ Matthew D. Taylora,b, , Sandra Nilssonb, Jennifer Bräunigb, Karl C. Bowlesc, Victoria Colea, Natalie A. Moltschaniwskyja, Jochen F. Muellerb a Port Stephens Fisheries Institute, New South Wales Department of Primary Industries, Locked Bag 1, Nelson Bay, NSW, 2315, Australia b The University of Queensland, Queensland Alliance for Environmental Health Sciences, 20 Cornwall Street, Woolloongabba, QLD, 4102, Australia c RPS AAP Consulting Pty Ltd, 255 Pitt St, Sydney, NSW, 2000, Australia ARTICLE INFO ABSTRACT Keywords: Per-and poly-fluoroalkyl substances (PFASs) are bioaccumulative chemicals of emerging concern. Some PFASs Human health accumulate in seafood, and can contribute to dietary exposure. Previous work has suggested cooking seafood Tolerable daily intake decreases concentrations of neutral organic contaminants, however, previous studies dealing with PFASs have PFOS shown conflicting results. In this study, the potential changes of PFAS concentrations as a result of boiling,frying Bioaccumulation and baking are systematically examined. Blue Swimmer Crab (Portunus armatus), Dusky Flathead (Platycephalus fuscus) and School Prawn (Metapenaeus macleayi) were obtained from near a known PFAS point source and a reference location (affected by diffuse sources). Raw and cooked samples were analysed for commonly found PFASs. Of 23 target analytes, PFOS was the most frequently detected compound. PFOS, PFHxS and PFOA concentrations in School Prawn effectively doubled after boiling, and PFOS increased when Dusky Flathead was baked. There was no significant difference in PFOS concentration when Dusky Flathead was fried, orwhenthe Blue Swimmer Crab was boiled. -
1 an Annotated Checklist of the Chondrichthyans of South Africa 1 2 3
1 An annotated checklist of the chondrichthyans of South Africa 2 3 4 DAVID A. EBERT1, 2, 3, 6, SABINE P. WINTNER4 & PETER M. KYNE5 5 6 1 Pacific Shark Research Center, Moss Landing Marine Laboratories, Moss Landing, 7 USA 8 2 South African Institute for Aquatic Biodiversity, Grahamstown, South Africa 9 3 Department of Ichthyology, California Academy of Sciences, San Francisco, USA 10 4 University of KwaZulu-Natal, School of Life Sciences, Durban, South Africa 11 5 Research Institute for the Environment and Livelihoods, Charles Darwin University, 12 Darwin, Australia 13 14 6 Corresponding author: E-mail: [email protected] 15 16 David A. Ebert ORCID ID 0000-0003-4604-8192 17 Sabine P. Wintner ORCID ID 0000-0001-7350-5999 18 Peter M. Kyne ORCID ID 0000-0003-4494-2625 19 20 21 1 1 Abstract 2 3 An annotated checklist of chondrichthyan fishes (sharks, batoids, and chimaeras) 4 occurring in South African waters is presented. The checklist is the result of decades of 5 research and on-going systematic revisions of the regional fauna. The chondrichthyan 6 fauna of South Africa is one of the richest in the world with 191 species, comprising 50 7 families and 103 genera. It consists of 30 families, 64 genera, and 111 species of sharks; 8 17 families, 36 genera, and 72 species of batoids; and, 3 families, 5 genera, and 8 species 9 of chimaeras. The most species-rich shark families are the whaler sharks Carcharhinidae 10 with 20 species followed by the deepwater catsharks Pentanchidae with 13 species. -
Assessing the Effectiveness of Surrogates for Conserving Biodiversity in the Port Stephens-Great Lakes Marine Park
Assessing the effectiveness of surrogates for conserving biodiversity in the Port Stephens-Great Lakes Marine Park Vanessa Owen B Env Sc, B Sc (Hons) School of the Environment University of Technology Sydney Submitted in fulfilment for the requirements of the degree of Doctor of Philosophy September 2015 Certificate of Original Authorship I certify that the work in this thesis has not been previously submitted for a degree nor has it been submitted as part of requirements for a degree except as fully acknowledged within the text. I also certify that the thesis has been written by me. Any help that I have received in my research work and preparation of the thesis itself has been acknowledged. In addition, I certify that all information sources and literature used as indicated in the thesis. Signature of Student: Date: Page ii Acknowledgements I thank my supervisor William Gladstone for invaluable support, advice, technical reviews, patience and understanding. I thank my family for their encouragement and support, particularly my mum who is a wonderful role model. I hope that my children too are inspired to dream big and work hard. This study was conducted with the support of the University of Newcastle, the University of Technology Sydney, University of Sydney, NSW Office of the Environment and Heritage (formerly Department of Environment Climate Change and Water), Marine Park Authority NSW, NSW Department of Primary Industries (Fisheries) and the Integrated Marine Observing System (IMOS) program funded through the Department of Industry, Climate Change, Science, Education, Research and Tertiary Education. The sessile benthic assemblage fieldwork was led by Dr Oscar Pizarro and undertaken by the University of Sydney’s Australian Centre for Field Robotics. -
South Australian Recreational Fishing Survey 2013/14
South Australian Recreational Fishing Survey 2013/14 July 2015 Fisheries Victoria Internal Report Series No. 62 South Australian Recreational Fishing Survey 2013/14 Khageswor Giri and Kylie Hall July 2015 Fisheries Victoria Internal Report Series No. 62 Published by the Victorian Government, Department of Economic Development, Jobs, Transport and Resources (DEDJTR), July 2015 © The State of Victoria, Department of Economic Development, Jobs, Transport and Resources Melbourne 2015 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, 1 Spring Street, Melbourne. Printed by DEDJTR Queenscliff, Victoria. Preferred way to cite this publication: Giri K and Hall K (2015) South Australian Recreational Fishing Survey. Fisheries Victoria Internal Report Series No. 62. Author Contact Details: Khageswor Giri C/- Fisheries Management and Science Branch, Fisheries Victoria PO Box 114, Queenscliff Vic 3225 Copies are available from the website www.ecodev.vic.gov.au/fishing For more information contact the DEDJTR Customer Service Centre 136 186 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 which may arise from you relying on any information in this publication. Accessibility If -
Social Dimensions of Blue Swimmer Crab Fishing, Restocking and Other
Beyond biology: social dimensions of Blue Swimmer Crab fishing, restocking and other management options Submitted by Sarah Jean Poulton This thesis is presented for the degree of Bachelor of Science Honours School of Veterinary and Life Sciences, of Murdoch University, 2018 Declaration I declare that this thesis is my own account of my research and contains as its main content work which has not previously been submitted for a degree at any tertiary education institution Sarah Poulton i Acknowledgements Firstly, I would like to acknowledge and extend a huge thank you to my wonderful supervisors Michael Hughes and James Tweedley. I cannot express in words how appreciative I am to both of you, for all your time, continued support and invaluable feedback throughout this last year and a half. I feel incredibly fortunate to have had you both as my supervisors. Coming from a biological science background made it difficult to understand all the social science terminology at the beginning of my Honours degree, so Mike, I thank you for your patience and for continually helping me to better understand this area of science. And to James, thank you for always making time to answer my endless questions, at all hours of the day. Your enthusiasm and passion for this project has been a huge inspiration. Also, to Neil Loneragan, thank you for all your guidance, advice and insights over this past year, I have really appreciated all of your help. This project was supported through funding from the Fisheries Research and Development Corporation of Australia (FRDC 2016/034) on behalf of the Australian Government, Recfishwest and Department of Primary Industries and Regional Development through funding from the Recreational Fishing Initiatives Fund and Murdoch University. -
Identification Guide to the Deep-Sea Cartilaginous Fishes Of
Identification guide to the deep–sea cartilaginous fishes of the Southeastern Atlantic Ocean FAO. 2015. Identification guide to the deep–sea cartilaginous fishes of the Southeastern Atlantic Ocean. FishFinder Programme, by Ebert, D.A. and Mostarda, E., Rome, Italy. Supervision: Merete Tandstad, Jessica Sanders (FAO, Rome) Technical editor: Edoardo Mostarda (FAO, Rome) Colour illustrations, cover and graphic design: Emanuela D’Antoni (FAO, Rome) This guide was prepared under the “FAO Deep–sea Fisheries Programme” thanks to a generous funding from the Government of Norway (Support to the implementation of the International Guidelines on the Management of Deep-Sea Fisheries in the High Seas project) for the purpose of assisting states, institutions, the fishing industry and RFMO/As in the implementation of FAO International Guidelines for the Management of Deep-sea Fisheries in the High Seas. It was developed in close collaboration with the FishFinder Programme of the Marine and Inland Fisheries Branch, Fisheries Department, Food and Agriculture Organization of the United Nations (FAO). The present guide covers the deep–sea Southeastern Atlantic Ocean and that portion of Southwestern Indian Ocean from 18°42’E to 30°00’E (FAO Fishing Area 47). It includes a selection of cartilaginous fish species of major, moderate and minor importance to fisheries as well as those of doubtful or potential use to fisheries. It also covers those little known species that may be of research, educational, and ecological importance. In this region, the deep–sea chondrichthyan fauna is currently represented by 50 shark, 20 batoid and 8 chimaera species. This guide includes full species accounts for 37 shark, 9 batoid and 4 chimaera species selected as being the more difficult to identify and/or commonly caught. -
Appendices Appendices
APPENDICES APPENDICES APPENDIX 1 – PUBLICATIONS SCIENTIFIC PAPERS Aidoo EN, Ute Mueller U, Hyndes GA, and Ryan Braccini M. 2015. Is a global quantitative KL. 2016. The effects of measurement uncertainty assessment of shark populations warranted? on spatial characterisation of recreational fishing Fisheries, 40: 492–501. catch rates. Fisheries Research 181: 1–13. Braccini M. 2016. Experts have different Andrews KR, Williams AJ, Fernandez-Silva I, perceptions of the management and conservation Newman SJ, Copus JM, Wakefield CB, Randall JE, status of sharks. Annals of Marine Biology and and Bowen BW. 2016. Phylogeny of deepwater Research 3: 1012. snappers (Genus Etelis) reveals a cryptic species pair in the Indo-Pacific and Pleistocene invasion of Braccini M, Aires-da-Silva A, and Taylor I. 2016. the Atlantic. Molecular Phylogenetics and Incorporating movement in the modelling of shark Evolution 100: 361-371. and ray population dynamics: approaches and management implications. Reviews in Fish Biology Bellchambers LM, Gaughan D, Wise B, Jackson G, and Fisheries 26: 13–24. and Fletcher WJ. 2016. Adopting Marine Stewardship Council certification of Western Caputi N, de Lestang S, Reid C, Hesp A, and How J. Australian fisheries at a jurisdictional level: the 2015. Maximum economic yield of the western benefits and challenges. Fisheries Research 183: rock lobster fishery of Western Australia after 609-616. moving from effort to quota control. Marine Policy, 51: 452-464. Bellchambers LM, Fisher EA, Harry AV, and Travaille KL. 2016. Identifying potential risks for Charles A, Westlund L, Bartley DM, Fletcher WJ, Marine Stewardship Council assessment and Garcia S, Govan H, and Sanders J. -
Report on the Bycatch and Byproduct Risk Assessments for the East Coast
Smart State smart fishing Report on the Bycatch and byproduct risk assessment for the East Coast Spanish Mackerel Fishery ISSN 0727-6273 QI06023 The Department of Primary Industries and Fisheries (DPI&F) seeks to maximise the economic potential of Queensland’s primary industries on a sustainable basis. This publication provides information on a bycatch and byproduct risk assessment undertaken for the East Coast Spanish Mackerel Fishery. While every care has been taken in preparing this publication, the State of Queensland accepts no responsibility for decisions or actions taken as a result of any data, information, statement or advice, expressed or implied, contained in this report. © The State of Queensland, Department of Primary Industries and Fisheries 2005 Copyright protects this publication. The State of Queensland has no objection to this material being reproduced but asserts its right to be recognised as author of its original material and the right to have its material remain unaltered. Inquiries should be addressed to: Manager, DPI&F Publications Department of Primary Industries and Fisheries GPO Box 46 Brisbane Qld 4001 2 Executive Summary This report documents the outcomes of an ecological risk assessment undertaken on bycatch and byproduct associated with the East Coast Spanish Mackerel Fishery (ECSMF). The ECSMF has always been considered a highly selective fishery, based on a relatively benign fishing method. The risk assessment was designed to formalise, quantitatively wherever possible, the risks to non-target species associated with the fishery. The risk assessment was valuable in that it exposed a number of invalid views about the fishery, but also helped confirm some of the long-standing assumptions. -
Historic Naturalis Classica, Viii Historic Naturalis Classica
HISTORIC NATURALIS CLASSICA, VIII HISTORIC NATURALIS CLASSICA EDIDERUNT J. CRAMER ET H.K.SWANN TOMUS vm BIBUOGRAPHY OF THE LARVAE OF DECAPOD CRUSTACEA AND LARVAE OF DECAPOD CRUSTACEA BY ROBERT GURNEY WITH 122 FIGURES IN THE TEXT REPRINTED 1960 BY H. R. ENGELMANN (J. CRAMER) AND WHELDON & WESLEY, LTD. WEINHEIM/BERGSTR. CODICOTE/HERTS. BIBLIOGRAPHY OF THE LARVAE OF DECAPOD CRUSTACEA AND LARVAE OF DECAPOD CRUSTACEA BY ROBERT GURNEY WITH 122 FIGURES IN THE TEXT REPRINTED 1960 BY H. R. ENGELMANN (J. CRAMER) AND WHELDON & WESLEY, LTD. WEINHEIM/BERGSTR. CODICOTE/HERTS. COPYRIGHT 1939 & 1942 BY THfi RAY SOCIETY IN LONDON AUTHORIZED REPRINT COPYRIGHT OF THE SERIES BY J. CRAMER PUBLISHER IN WEINHEIM PRINTED IN GERMANY I9«0 i X\ T • THE RAY SOCIETY INSTITUTED MDCCCXLIV This volume (No. 125 of the Series) is issued to the Svhscribers to the RAY SOCIETY JOT the Year 1937. LONDON MCMXXXIX BIBLIOGKAPHY OF THE LARVAE OF DECAPOD CRUSTACEA BY ROBERT GURNEY, M.A., D.Sc, F.L.S. LONDON PRINTED FOR THE RAT SOCIETY SOLD BT BERNARD QUARITCH, LTD. U, GBAFTOK STBKET, NBW BOND STEBBT, LONDON, "W. 1 1939 PRINTED BY ADLABD AND SON, LIMITED 2 1 BLOOJlSBUBY WAY, LONDON, W.C. I Madt and printed in Great Britain. CONTENTS PAOE PBBFACE . " V BiBUOGRAPHY CLASSIFIED LIST . 64 Macrura Natantia 64 Penaeidea 64 Caridea 70 Macrura Reptantia 84 Nephropsidea 84 Eryonidea 88 Scyllaridea 88 Stenopidea 91 Thalassinidea 92 Anomura ; 95 Galatheidea . 95 Paguridea 97 Hippidea 100 Dromiacea 101 Brachyura 103 Gymnopleura 103 Brachygnatha 103 Oxyrhyncha 113 Oxystomata . 116 INDEX TO GENERA 120 PREFACE IT has been my intention to publish a monograph of Decapod larvae which should contain a bibliography, a part dealing with a number of general questions relating to the post-embryonic development of Decapoda and Euphausiacea, and a series of sections describing the larvae of all the groups, so far as they are known.