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   Thalassoma hardwicke (Sixbar wrasse) 
   Thalassoma hardwickei 
   Thalassoma hardwicki 
   Thalassoma hardwickii 

Broader Terms:
   Perciformes (perch-likes) 
Latest Articles on Thalassoma hardwickii from uBioRSS
Thalassoma schwaneveldi (Bleeker, 1853) - WoRMS latest edits
Competition encourages cooperation: client fish receive higher-quality serv... - ScienceDirect Search: species

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Common Names: Bayan, Pakou, Girelle paon de hardwicke, Arinamawa, parrotfish, Soh karang, Tamarin, Girelle taches d'encre, Sesbalk-lipvis, Sixbar wrasse, Sugale-a'au, Talasoma hardwika, Alle, Liburbur, Cave, Tangalangal, Po'ou, Arinai, Senganangan, Lape-ele'ele, Bungat, Bagondon, Garde police, Kaashi hikaa, Senasujibera ....

1.  Lunar rhythms in growth of larval fish.LinkIT
Shima JS, Osenberg CW, Noonburg EG, Alonzo SH, Swearer SE
Proceedings. Biological sciences, 2021

2.  Reproductive phenology across the lunar cycle: parental decisions, offspring responses, and consequences for reef fish.LinkIT
Shima JS, Osenberg CW, Alonzo SH, Noonburg EG, Mitterwallner P, Swearer SE
Ecology Ecology Reproductive phenology across the lunar cycle: parental decisions, offspring responses, and consequences for reef fish. e03086 10.1002/ecy.3086 Most organisms reproduce in a dynamic environment, and life-history theory predicts that this can favor the evolution of strategies that capitalize on good times and avoid bad times. When offspring experience these environmental changes, fitness can depend strongly upon environmental conditions at birth and at later life stages. Consequently, fitness will be influenced by the reproductive decisions of parents (i.e., birth date effects) and developmental decisions (e.g., adaptive plasticity) of their offspring. We explored the consequences of these decisions using a highly iteroparous coral reef fish (the sixbar wrasse, Thalassoma hardwicke) and in a system where both parental and offspring environments vary with the lunar cycle. We tested the hypotheses that (1) reproductive patterns and offspring survival vary across the lunar cycle and (2) offspring exhibit adaptive plasticity in development time. We evaluated temporal variation in egg production from February to June 2017, and corresponding larval developmental histories (inferred from otolith microstructure) of successful settlers and surviving juveniles that were spawned during that same period. We documented lunar-cyclic variation in egg production (most eggs were spawned at the new moon). This pattern was at odds with the distribution of birth dates of settlers and surviving juveniles-most individuals that successfully survived to settlement and older stages were born during the full moon. Consequently, the probability of survival across the larval stage was greatest for offspring born close to the full moon, when egg production was at its lowest. Offspring also exhibited plasticity in developmental duration, adjusting their age at settlement to settle during darker portions of the lunar cycle than expected given their birth date. Offspring born near the new moon tended to be older and larger at settlement, and these traits conveyed a strong fitness advantage (i.e., a carryover effect) through to adulthood. We speculate that these effects (1) are shaped by a dynamic landscape of risk and reward determined by moonlight, which differentially influences adults and offspring, and (2) can explain the evolution of extreme iteroparity in sixbars. © 2020 by the Ecological Society of America. Shima Jeffrey S JS 0000-0001-5770-4859 School of Biological Sciences, Victoria University of Wellington, Wellington, 6140, New Zealand. Osenberg Craig W CW 0000-0003-1918-7904 Odum School of Ecology, University of Georgia, 140 East Green Street, Athens, Georgia, 30602, USA. Alonzo Suzanne H SH Department of Ecology and Evolutionary Biology, University of California at Santa Cruz, Santa Cruz, California, USA. Noonburg Erik G EG Biological Sciences, Florida Atlantic University, Davie, Florida, 33314, USA. Mitterwallner Pauline P School of Biological Sciences, Victoria University of Wellington, Wellington, 6140, New Zealand. Swearer Stephen E SE 0000-0001-6381-9943 School of Biosciences, University of Melbourne, Melbourne, Victoria, 3010, Australia. eng VUW1503 Royal Society of New Zealand Marsden Fund International OCE- 1130359 U.S. National Science Foundation International Victoria University of Wellington International Journal Article Research Support, Non-U.S. Gov't Research Support, U.S. Gov't, Non-P.H.S. 2020 05 21 United States Ecology 0043541 0012-9658 IM Adult Animals Coral Reefs Fishes Humans Moon Perciformes Reproduction adaptive plasticity carryover effect coral reef fish ecoevolutionary feedback life history lunar periodicity otolith microstructure recruitment reproductive output seasonality selection settlement 2019 12 13 2020 03 19 2020 04 01 2020 4 23 6 0 2021 1 22 6 0 2020 4 23 6 0 ppublish 32320474 10.1002/ecy.3086 Literature Cited, 2020</i></font><br><font color=#008000><br></font></span><br>3.  <a href= class=title>Born at the right time? A conceptual framework linking reproduction, development, and settlement in reef fish.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Shima JS, Noonburg EG, Swearer SE, Alonzo SH, Osenberg CW<br><font color=gray><i>Ecology, 2018</i></font><br><font color=#008000><br></font></span><br>4.  <a href= class=title>Tool-like behavior in the sixbar wrasse, Thalassoma hardwicke (Bennett, 1830).</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Pa?ko ?<br><font color=gray><i>Zoo biology, 2011</i></font><br><font color=#008000><br></font></span><br>5.  <a href= class=title>Order of arrival affects competition in two reef fishes.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Geange SW, Stier AC<br><font color=gray><i>Ecology, 2009</i></font><br><font color=#008000><br></font></span><br>6.  <a href= class=title>Quantifying site quality in a heterogeneous landscape: recruitment of a reef fish.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Shima JS, Osenberg CW, St Mary CM<br><font color=gray><i>Ecology, 2008</i></font><br><font color=#008000><br></font></span><br>7.  <a href= class=title>Regulation of local populations of a coral reef fish via joint effects of density- and number-dependent mortality.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Shima JS<br><font color=gray><i>Oecologia, 2001</i></font><br><font color=#008000><br></font></span><br>8.  <a href= class=title>The genus Deretrema Linton, 1910 (Digenea: Zoogonidae) from southern Great Barrier Reef fishes, with a description of Deretrema woolcockae n. sp.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Cribb TH, Wright T, Bray RA<br><font color=gray><i>Systematic parasitology, 1999</i></font><br><font color=#008000><br></font></span><br></table></tr></table></td><script src="" type="text/javascript"> </script> <script type="text/javascript"> _uacct = "UA-634822-1"; urchinTracker(); </script> </BODY> </HTML>