Wrasse Infograph-Lores-F

Total Page:16

File Type:pdf, Size:1020Kb

Wrasse Infograph-Lores-F WRASSES Are wrasses endangered? Some species, such as the humphead wrasse, are listed as endangered due to over-shing and destruction of coral reefs where they live. Humphead wrasse How long do Cheilinus undulatus wrasses live? Wrasses are marine shes that belong to the Labridae family. Humphead wrasses can survive three to 30 years, most species live There are more than 500 species of wrasses that can be found from three to ve years. in tropical and subtropical waters of the Indian, Pacic and Atlantic oceans. Wrasses inhabit coastal areas, rocky shores, Fascinating fact: Wrasses are born female are able change sex coral reefs, tide pools and the sandy sea oor. to male during their lifetime. This is usually driven by the loss of the dominant male, allowing the largest (formerly) female to then Wrasse species common to the tropical Pacific take control of the harem. Blackstripe coris wrasse Coris avovittata Bluestreak cleaner wrasse What do Labroides dimidiatus Birdnose wrasse Gomphosus varius wrasses eat? Wrasses are carnivores. Their diets are based on small invertebrates (crabs, shrimp, mollusks, snails and Christmas wrasse Thalassoma trilobatum sea urchins) and sh. Occasionally they follow large marine predators and collect leftovers of their meals. Cleaner wrasses collect and eat Pink asher wrasse dead tissue and parasites Ornate wrasse Paracheilinus carpenteri Halichoeres ornatissimus accumulated in the mouths of large Psychedelic wrasse Anampses chrysocephalus marine sh. Who are wrasse predators? Saddle wrasse Thalassoma duperrey Natural enemies of wrasses are Rockmover wrasse Novaculichthys taeniourus lionsh, barracudas and sharks. Some Sixline wrasse wrasses can bury themselves in the Pseudocheilinus hexataenia sand or quickly swim away, thanks to well-developed pectoral and caudal ns, to escape from predators. Some species hide among the large tentacles of mushroom coral and Shortnose wrasse Yellowtail coris wrasse Macropharyngodon georoy Coris gaimard sea anemones..
Recommended publications
  • Marine Fish Conservation Global Evidence for the Effects of Selected Interventions
    Marine Fish Conservation Global evidence for the effects of selected interventions Natasha Taylor, Leo J. Clarke, Khatija Alliji, Chris Barrett, Rosslyn McIntyre, Rebecca0 K. Smith & William J. Sutherland CONSERVATION EVIDENCE SERIES SYNOPSES Marine Fish Conservation Global evidence for the effects of selected interventions Natasha Taylor, Leo J. Clarke, Khatija Alliji, Chris Barrett, Rosslyn McIntyre, Rebecca K. Smith and William J. Sutherland Conservation Evidence Series Synopses 1 Copyright © 2021 William J. Sutherland This work is licensed under a Creative Commons Attribution 4.0 International license (CC BY 4.0). This license allows you to share, copy, distribute and transmit the work; to adapt the work and to make commercial use of the work providing attribution is made to the authors (but not in any way that suggests that they endorse you or your use of the work). Attribution should include the following information: Taylor, N., Clarke, L.J., Alliji, K., Barrett, C., McIntyre, R., Smith, R.K., and Sutherland, W.J. (2021) Marine Fish Conservation: Global Evidence for the Effects of Selected Interventions. Synopses of Conservation Evidence Series. University of Cambridge, Cambridge, UK. Further details about CC BY licenses are available at https://creativecommons.org/licenses/by/4.0/ Cover image: Circling fish in the waters of the Halmahera Sea (Pacific Ocean) off the Raja Ampat Islands, Indonesia, by Leslie Burkhalter. Digital material and resources associated with this synopsis are available at https://www.conservationevidence.com/
    [Show full text]
  • Endangered Species Research 38:135
    Vol. 38: 135–145, 2019 ENDANGERED SPECIES RESEARCH Published March 14 https://doi.org/10.3354/esr00942 Endang Species Res OPENPEN ACCESSCCESS Substantial impacts of subsistence fishing on the population status of an Endangered reef predator at a remote coral atoll Robert J. Lennox1,2,*, Alexander Filous2,3,4, Steven J. Cooke1, Andy J. Danylchuk2,3 1Fish Ecology and Conservation Physiology Laboratory, Department of Biology, Carleton University, Ottawa, Ontario K1S 5B6, Canada 2Indifly, PO Box 4460, St Paul, Minnesota 55104, USA 3Department of Environmental Conservation, University of Massachusetts Amherst, 160 Holdsworth Way, Amherst, Massachusetts 01003, USA 4The Island Initiative, Papeete, French Polynesia ABSTRACT: Napoleon wrasse Cheilinus undulatus has declined drastically throughout most of its range, owing, in large part, to overexploitation. In Anaa, French Polynesia, the species is har- vested as part of the subsistence catch by fishers using rockpile traps, spearguns, handmade har- poons, and baited handlines. We sampled 70 Napoleon wrasse captured by artisanal fishers of Anaa between 2015 and 2018 to assess the status of this population, and we applied data-poor fisheries models to assess the stock status of this iconic reef predator. The species was determined to be overexploited at a rate of 0.82 based on values of natural (0.14; Hoenig method) and fishing (0.58; difference of total and natural mortality) mortality as components of total mortality (0.72; Beverton-Holt estimation). The left-skewed length distribution (mean = 36 ± 13 cm SL) suggested an under-representation of large adults in the population, which would predominantly be terminal males in this sequentially hermaphroditic protogynous fish.
    [Show full text]
  • Updated Checklist of Marine Fishes (Chordata: Craniata) from Portugal and the Proposed Extension of the Portuguese Continental Shelf
    European Journal of Taxonomy 73: 1-73 ISSN 2118-9773 http://dx.doi.org/10.5852/ejt.2014.73 www.europeanjournaloftaxonomy.eu 2014 · Carneiro M. et al. This work is licensed under a Creative Commons Attribution 3.0 License. Monograph urn:lsid:zoobank.org:pub:9A5F217D-8E7B-448A-9CAB-2CCC9CC6F857 Updated checklist of marine fishes (Chordata: Craniata) from Portugal and the proposed extension of the Portuguese continental shelf Miguel CARNEIRO1,5, Rogélia MARTINS2,6, Monica LANDI*,3,7 & Filipe O. COSTA4,8 1,2 DIV-RP (Modelling and Management Fishery Resources Division), Instituto Português do Mar e da Atmosfera, Av. Brasilia 1449-006 Lisboa, Portugal. E-mail: [email protected], [email protected] 3,4 CBMA (Centre of Molecular and Environmental Biology), Department of Biology, University of Minho, Campus de Gualtar, 4710-057 Braga, Portugal. E-mail: [email protected], [email protected] * corresponding author: [email protected] 5 urn:lsid:zoobank.org:author:90A98A50-327E-4648-9DCE-75709C7A2472 6 urn:lsid:zoobank.org:author:1EB6DE00-9E91-407C-B7C4-34F31F29FD88 7 urn:lsid:zoobank.org:author:6D3AC760-77F2-4CFA-B5C7-665CB07F4CEB 8 urn:lsid:zoobank.org:author:48E53CF3-71C8-403C-BECD-10B20B3C15B4 Abstract. The study of the Portuguese marine ichthyofauna has a long historical tradition, rooted back in the 18th Century. Here we present an annotated checklist of the marine fishes from Portuguese waters, including the area encompassed by the proposed extension of the Portuguese continental shelf and the Economic Exclusive Zone (EEZ). The list is based on historical literature records and taxon occurrence data obtained from natural history collections, together with new revisions and occurrences.
    [Show full text]
  • Findings and Recommendations of Effectiveness of the West Hawai'i Regional Fishery Management Area (WHRFMA)
    Report to the Thirtieth Legislature 2020 Regular Session Findings and Recommendations of Effectiveness of the West Hawai'i Regional Fishery Management Area (WHRFMA) Prepared by: Department of Land and Natural Resources Division of Aquatic Resources State of Hawai'i In response to Section 188F-5, Hawaiʹi Revised Statutes November 2019 Findings and Recommendations of Effectiveness of the West Hawai'i Regional Fishery Management Area (WHRFMA) CORRESPONDING AUTHOR William J. Walsh Ph.D., Hawai′i Division of Aquatic Resources CONTRIBUTING AUTHORS Stephen Cotton, M.S., Hawai′i Division of Aquatic Resources Laura Jackson, B. S., Hawai′i Division of Aquatic Resources Lindsey Kramer, M.S., Hawai′i Division of Aquatic Resources, Pacific Cooperative Studies Unit Megan Lamson, M.S., Hawai′i Division of Aquatic Resources, Pacific Cooperative Studies Unit Stacia Marcoux, M.S., Hawai′i Division of Aquatic Resources, Pacific Cooperative Studies Unit Ross Martin B.S., Hawai′i Division of Aquatic Resources, Pacific Cooperative Studies Unit Nikki Sanderlin. B.S., Hawai′i Division of Aquatic Resources ii PURPOSE OF THIS REPORT This report, which covers the period between 2015 - 2019, is submitted in compliance with Act 306, Session Laws of Hawai′i (SLH) 1998, and subsequently codified into law as Chapter 188F, Hawaiʹi Revised Statutes (HRS) - West Hawai'i Regional Fishery Management Area. Section 188F-5, HRS, requires a review of the effectiveness of the West Hawai′i Regional Fishery Management Area shall be conducted every five years by the Department of Land and Natural Resources (DLNR), in cooperation with the University of Hawai′i (Section 188F-5 HRS). iii CONTENTS PURPOSE OF THIS REPORT .................................................................................................
    [Show full text]
  • Gonadotropin-Releasing Hormone and Receptor Distributions in the Visual Processing Regions of Four Coral Reef Fishes
    Original Paper Brain Behav Evol 2007;70:40–56 Received: July 31, 2006 DOI: 10.1159/000101068 Returned for revision: September 24, 2006 Accepted after revision: October 20, 2006 Published online: March 26, 2007 Gonadotropin-Releasing Hormone and Receptor Distributions in the Visual Processing Regions of Four Coral Reef Fishes Karen P. Maruska Timothy C. Tricas University of Hawaii at Manoa, Department of Zoology, Honolulu , and Hawai’i Institute of Marine Biology, K a n e o h e , H a w a i i , U S A Key Words ganglion cell axons primarily within the stratum album cen- Brain Fish GnRH Neuromodulation Receptor trale and stratum griseum centrale of the tectum in all spe- Sensory Tectum Terminal nerve Vision cies, and were concentrated in several diencephalic visual processing centers. GnRH receptors are also localized to di- encephalic visual centers and the stratum griseum periven- Abstract triculare of the tectum, where motion perception and Gonadotropin-releasing hormone (GnRH) is widely distrib- coordination of motor behavioral responses in three-dimen- uted in the brain of fishes where it may function as a neuro- sional space occur. This work demonstrates that the basic modulator of sensory processing and behavior. Immunocy- neural substrates for peptide-sensory convergence are con- tochemical and neuronal label experiments were conducted served at multiple processing levels in the visual system of on species from four families of coral reef fishes (Chaetodon- several reef fishes. Species differences in GnRH innervation tidae, butterflyfish; Pomacentridae, damselfish; Gobiidae, to the retina and GnRH receptor distributions may be related goby; and Labridae, wrasse) to assess conservation of GnRH to phylogeny, their use of vision in natural behaviors, or pos- targets in the visual processing retina and brain.
    [Show full text]
  • Ray by Design Stingray
    Sponsored by Blue Lagoon Island & Vendors from Nassau Dolphin Encounters - Project BEACH Contest Deadline: March 4th, 2016 Beautifully graceful underwater, Southern The unique hunting abilities of a stingray – stingrays choose the turquoise waters of digging, sucking, and crushing – also benefit The Bahamas as their home. Like many other reef animals looking for lunch. These other reef animals, stingrays play an gentle winged fish are key predators in a important role in our marine ecosystem. healthy, marine habitat, so it’s time to “Rays the Roof” and start protecting our stingrays! When a stingray hunts along the bottom, it mixes the sand and stirs up hidden Learn more about this unique animal and the creatures in search of food. Sea birds challenges it faces from the MEPC 2016 Info will often follow the path of a stingray Sheet and express your feelings through art hoping to make a meal from the animals in the Marine Education Poster Contest 2016. disturbed by the ray. Call for a FREE Marine Assembly Program at your school to introduce you to the marine topic “Rays the Roof!” Ray By Design Southern stingrays can be gills As masters of disguise Stingray 101 found in tropical and (camouflage), stingrays can subtropical waters of the completely bury themselves in Animal Type: Boneless Fish southern Atlantic Ocean, the sand or soft seafloor. Caribbean and Gulf of When swimming, if viewed Diet: Carnivore Mexico. These rays have been ventral side mouth from below, the bright belly Ave. Lifespan: 15-25 years found in depths of up to 180 of the ray matches the bright feet and are usually found Unlike sharks, rays crush their sky above, helping to escape Maximum Width: 4 feet roaming the ocean alone or in food -- prey such as conch, large predatory fish such as Maximum Weight: 200+ lbs.
    [Show full text]
  • The Global Trade in Marine Ornamental Species
    From Ocean to Aquarium The global trade in marine ornamental species Colette Wabnitz, Michelle Taylor, Edmund Green and Tries Razak From Ocean to Aquarium The global trade in marine ornamental species Colette Wabnitz, Michelle Taylor, Edmund Green and Tries Razak ACKNOWLEDGEMENTS UNEP World Conservation This report would not have been The authors would like to thank Helen Monitoring Centre possible without the participation of Corrigan for her help with the analyses 219 Huntingdon Road many colleagues from the Marine of CITES data, and Sarah Ferriss for Cambridge CB3 0DL, UK Aquarium Council, particularly assisting in assembling information Tel: +44 (0) 1223 277314 Aquilino A. Alvarez, Paul Holthus and and analysing Annex D and GMAD data Fax: +44 (0) 1223 277136 Peter Scott, and all trading companies on Hippocampus spp. We are grateful E-mail: [email protected] who made data available to us for to Neville Ash for reviewing and editing Website: www.unep-wcmc.org inclusion into GMAD. The kind earlier versions of the manuscript. Director: Mark Collins assistance of Akbar, John Brandt, Thanks also for additional John Caldwell, Lucy Conway, Emily comments to Katharina Fabricius, THE UNEP WORLD CONSERVATION Corcoran, Keith Davenport, John Daphné Fautin, Bert Hoeksema, Caroline MONITORING CENTRE is the biodiversity Dawes, MM Faugère et Gavand, Cédric Raymakers and Charles Veron; for assessment and policy implemen- Genevois, Thomas Jung, Peter Karn, providing reprints, to Alan Friedlander, tation arm of the United Nations Firoze Nathani, Manfred Menzel, Julie Hawkins, Sherry Larkin and Tom Environment Programme (UNEP), the Davide di Mohtarami, Edward Molou, Ogawa; and for providing the picture on world’s foremost intergovernmental environmental organization.
    [Show full text]
  • Cerritos Library Aquarium - Current Fish Residents
    Cerritos Library Aquarium - Current Fish Residents Blue Tang (Paracanthurus hepatus) Location: Indo-Pacific, seen in reefs of the Philippines, Indonesia, Japan, the Great Barrier Reef of Australia, New Caledonia, Samoa, East Africa, and Sri Lanka Length: Up to 12 inches Food: Omnivores, feed on plankton and algae Characteristics: Live in pairs, or in small groups. Belong to group of fish called surgeonfish due to sharp spines on caudal peduncle (near tailfin). Spines are used only as a method of protection against aggressors Naso Tang (Naso lituratus) Other Names: Orangespine Unicornfish, Lipstick Tang, Tricolor Tang Location: Indo-Pacific reefs Length: Up to 2 feet Food: Primarily herbivores, mostly feed on algae with some plankton Characteristics: Like other surgeonfish, have a scalpel- like spine at the base of the tail for protection against aggressors. Mata tang (Acanthurus mata) Other Names: Elongate Surgeonfish, Pale Surgeonfish Location: Central Pacific, Eastern Asia Length: Up to 20 inches Food: Primarily herbivorous; diet includes algae, seaweed; occasionally carnivorous Characteristics: Like other surgeonfish, have a scalpel- like spine at the base of the tail for protection against aggressors. Yellow Tang (Zebrasoma flavescens) Other Names: Yellow Sailfin Tang, Lemon Surgeonfish, Yellow Surgeonfish Location: Hawaiian islands Length: Up to 8 inches Food: Primarily herbivorous; diet includes algae, seaweed Characteristics: Males have a patch of raised scales that resemble tiny white, fuzzy spikes to the rear of the spine; females do not Mustard tang (Acanthurus guttatus) Other Names: White spotted Surgeonfish Location: Shallow waters on reefs in the Indo-Pacific Length: Up to 12 inches Food: Primarily herbivorous; diet includes algae, seaweed Characteristics: Rarely seen; hide under shallow reefs to protect themselves from predators.
    [Show full text]
  • Saltwater Fish Identification Guide
    Identification Guide To South Carolina Fishes Inshore Fishes Red Drum (Spottail, redfish, channel bass, puppy drum,) Sciaenops ocellatus May have multiple spots along dorsal surface.. RKW Black Drum Pogonias cromis Broad black vertical bars along body. Barbells on chin. Spotted Seatrout (Winter trout, speckled trout) Cynoscion nebulosus Numerous distinct black spots on dorsal surface. Most commonly encountered in rivers and estuaries. RKW Most commonly encountered just offshore around live bottom and artificial reefs. Weakfish (Summer trout, Gray trout) Cynoscion regalis RKW Silver coloration with no spots. Large eye Silver Seatrout Cynoscion nothus RKW Spot Leiostomus xanthurus Distinct spot on shoulder. RKW Atlantic Croaker (Hardhead) Micropogonias undulatus RKW Silver Perch (Virginia Perch) Bairdiella chrysoura RKW Sheepshead Archosargus probatocephalus Broad black vertical bars along body. RKW Pinfish (Sailors Choice) Lagodon rhomboides Distinct spot. RKW Southern Kingfish (Whiting) Menticirrhus americanus RKW Extended 1st dorsal filament Northern Kingfish SEAMAP- Menticirrhus saxatilis SA:RPW Dusky 1st dorsal-fin tip Black caudal fin tip Gulf Kingfish SEAMAP- Menticirrhus littoralis SA:RPW Southern flounder Paralichthys lethostigma No ocellated spots . RKW Summer flounder Paralichthys dentatus Five ocellated spots in this distinct pattern. B. Floyd Gulf flounder Paralichthys albigutta B. Floyd Three ocellated spots in a triangle pattern. B. Floyd Bluefish Pomatomus saltatrix RKW Inshore Lizardfish Synodus foetens RKW RKW Ladyfish Elops saurus Florida Pompano Trachinotus carolinus RKW Lookdown Selene vomer RKW Spadefish Chaetodipterus faber Juvenile RKW Juvenile spadefish are commonly found in SC estuaries. Adults, which look very similar to the specimen shown above, are common inhabitants of offshore reefs. Cobia Rachycentron canadum Adult D. Hammond Juvenile RKW D.
    [Show full text]
  • Patterns of Evolution in Gobies (Teleostei: Gobiidae): a Multi-Scale Phylogenetic Investigation
    PATTERNS OF EVOLUTION IN GOBIES (TELEOSTEI: GOBIIDAE): A MULTI-SCALE PHYLOGENETIC INVESTIGATION A Dissertation by LUKE MICHAEL TORNABENE BS, Hofstra University, 2007 MS, Texas A&M University-Corpus Christi, 2010 Submitted in Partial Fulfillment of the Requirements for the Degree of DOCTOR OF PHILOSOPHY in MARINE BIOLOGY Texas A&M University-Corpus Christi Corpus Christi, Texas December 2014 © Luke Michael Tornabene All Rights Reserved December 2014 PATTERNS OF EVOLUTION IN GOBIES (TELEOSTEI: GOBIIDAE): A MULTI-SCALE PHYLOGENETIC INVESTIGATION A Dissertation by LUKE MICHAEL TORNABENE This dissertation meets the standards for scope and quality of Texas A&M University-Corpus Christi and is hereby approved. Frank L. Pezold, PhD Chris Bird, PhD Chair Committee Member Kevin W. Conway, PhD James D. Hogan, PhD Committee Member Committee Member Lea-Der Chen, PhD Graduate Faculty Representative December 2014 ABSTRACT The family of fishes commonly known as gobies (Teleostei: Gobiidae) is one of the most diverse lineages of vertebrates in the world. With more than 1700 species of gobies spread among more than 200 genera, gobies are the most species-rich family of marine fishes. Gobies can be found in nearly every aquatic habitat on earth, and are often the most diverse and numerically abundant fishes in tropical and subtropical habitats, especially coral reefs. Their remarkable taxonomic, morphological and ecological diversity make them an ideal model group for studying the processes driving taxonomic and phenotypic diversification in aquatic vertebrates. Unfortunately the phylogenetic relationships of many groups of gobies are poorly resolved, obscuring our understanding of the evolution of their ecological diversity. This dissertation is a multi-scale phylogenetic study that aims to clarify phylogenetic relationships across the Gobiidae and demonstrate the utility of this family for studies of macroevolution and speciation at multiple evolutionary timescales.
    [Show full text]
  • Annotated Checklist of the Fishes of Wake Atoll1
    Annotated Checklist ofthe Fishes ofWake Atoll 1 Phillip S. Lobel2 and Lisa Kerr Lobel 3 Abstract: This study documents a total of 321 fishes in 64 families occurring at Wake Atoll, a coral atoll located at 19 0 17' N, 1660 36' E. Ten fishes are listed by genus only and one by family; some of these represent undescribed species. The first published account of the fishes of Wake by Fowler and Ball in 192 5 listed 107 species in 31 families. This paper updates 54 synonyms and corrects 20 misidentifications listed in the earlier account. The most recent published account by Myers in 1999 listed 122 fishes in 33 families. Our field surveys add 143 additional species records and 22 new family records for the atoll. Zoogeo­ graphic analysis indicates that the greatest species overlap of Wake Atoll fishes occurs with the Mariana Islands. Several fish species common at Wake Atoll are on the IUCN Red List or are otherwise of concern for conservation. Fish pop­ ulations at Wake Atoll are protected by virtue of it being a U.S. military base and off limits to commercial fishing. WAKE ATOLL IS an isolated atoll in the cen­ and Strategic Defense Command. Conse­ tral Pacific (19 0 17' N, 1660 36' E): It is ap­ quentially, access has been limited due to the proximately 3 km wide by 6.5 km long and military mission, and as a result the aquatic consists of three islands with a land area of fauna of the atoll has not received thorough 2 approximately 6.5 km • Wake is separated investigation.
    [Show full text]
  • Northwestern Hawaiian Islands/Kure Atoll Assessment and Monitoring Program
    Northwestern Hawaiian Islands/Kure Atoll Assessment and Monitoring Program Final Report March 2002 Grant Number NA070A0457 William j. Walsh1, Ryan Okano2, Robert Nishimoto1, Brent Carman1. 1 Division of Aquatic Resources 1151 Punchbowl Street Rm. 330 Honolulu, HI 96813 2 Botany Department University of Hawai`i Mānoa Honolulu, HI 96822 2 INTRODUCTION The Northwest Hawaiian Islands (NWHI) consist of 9,124 km2 of land and approximately 13,000 km2 of coral reef habitat. They comprise 70% of all coral reef areas under U.S. jurisdiction. This isolated archipelago of small islands, atolls, reefs and banks represent a unique and largely pristine coral reef ecosystem. The islands support millions of nesting seabirds and are breeding grounds for the critically endangered Hawaiian monk seal and threatened green sea turtle. The reefs include a wide range of habitats and support a diverse assemblage of indigenous and endemic reef species, many of which have yet to be described. Kure Atoll, located at the northwestern end of the NWHI chain (approximately 28º 25’ N latitude and 178º 20’ W longitude) is the northernmost atoll in the world. The atoll is located 91 km northwest of Midway Islands and nearly 1,958 km northwest of Honolulu. It is a nearly circular atoll with a diameter of 10 km (6mi). The outer reef is continuous Figure 1. IKONOS satellite image of Kure Atoll 3 and almost encircles the atoll’s lagoon except for passages to the southwest (Fig. 1). An emergent rock ledge consisting primarily of coralline algae and algally bound and encrusted coral is present along some sections of the reef crest.
    [Show full text]