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Broader Terms:
   Labridae (Rainbowfishes) 

More Specific:
   Notolabrus celidotus (spotty) 
   Notolabrus cinctus (Girdled wrasse) 
   Notolabrus fucicola (Yellow-saddled wrasse) 
   Notolabrus gymnogenis (Wrasse) 
   Notolabrus inscriptus (Green wrasse) 
   Notolabrus parilus 
   Notolabrus poecilopleura 
   Notolabrus tetricus (Winter bream) 
Latest Articles on Notolabrus from uBioRSS
Could thermal sensitivity of mitochondria determine species distribution in... - PubMed: species

External Resources:

1.  An in vitro ovarian explant culture system to examine sex change in a hermaphroditic fish.LinkIT
Goikoetxea A, Damsteegt EL, Todd EV, McNaughton A, Gemmell NJ, Lokman PM
PeerJ, 2020

2.  Fishing in hot waters threatens phenotypic diversity.LinkIT
Aubry LM
The Journal of animal ecology J Anim Ecol Fishing in hot waters threatens phenotypic diversity. 1642-1644 10.1111/1365-2656.13066 In Focus: Morrongiello, J. R., Sweetman, P. C., & Thresher, R. E. (2019). Fishing constrains phenotypic responses of marine fish to climate variability. Journal of Animal Ecology, 88, 1645-1656. Forces of unnatural selection, such as climate change and harvest, are rarely studied in concert, yet hold the great potential to act synergistically on individual performance, susceptibility to harvest, tolerance to warming temperatures, and ultimately population persistence and resilience. In this paper, Morrongiello et al. (2019) used long-term monitoring of a site-attached temperate reef fish, the purple wrasse (Notolabrus fucicola), to test novel predictions about how fisheries management and climate variability could alter individual growth rates and thermal reaction norms within and across stocks. Otolith growth increments were collected from three south-east Australian populations between 1980 and 1999, pre- and post-harvest, throughout an intensive warming spell. Using hierarchical models to partition variation in growth within and between individuals and populations, Morrongiello et al. detected increased average growth rate with warming, a release from density dependence post-harvest, and a fishing-by-warming interaction that decreased diversity in thermal growth reaction norms because large individuals that tend to better tolerate warm temperatures were effectively culled from the population. This study outlines the importance of determining which phenotypes are more resilient to increasing temperatures, how fisheries should manage for them, and how such collective knowledge could help preserve and even promote resilience of managed populations to increasing temperatures in ecosystems threatened by climate change. © 2019 The Author Journal of Animal Ecology © 2019 British Ecological Society. Aubry Lise M LM 0000-0003-3318-7329 Fish, Wildlife and Conservation Biology Department, Colorado State University, Fort Collins, CO, USA. eng Journal Article England J Anim Ecol 0376574 0021-8790 IM Animals Australia Climate Change Ecosystem Fisheries Fishes Phenotype climate change fisheries harvest hierarchical model reaction norms unnatural selection wrasse 2019 06 18 2019 07 01 2019 11 7 6 0 2019 11 7 6 0 2019 12 18 6 0 ppublish 31691275 10.1111/1365-2656.13066 REFERENCES, 2019</i></font><br><font color=#008000><br></font></span><br>3.  <a href= class=title>Conservation and diversity in expression of candidate genes regulating socially-induced female-male sex change in wrasses.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Thomas JT, Todd EV, Muncaster S, Lokman PM, Damsteegt EL, Liu H, Soyano K, Gléonnec F, Lamm MS, Godwin JR, Gemmell NJ<br><font color=gray><i>PeerJ, 2019</i></font><br><font color=#008000><br></font></span><br>4.  <a href= class=title>Taking a deeper look: Quantifying the differences in fish assemblages between shallow and mesophotic temperate rocky reefs.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Williams J, Jordan A, Harasti D, Davies P, Ingleton T<br><font color=gray><i>PloS one, 2019</i></font><br><font color=#008000><br></font></span><br>5.  <a href= class=title>Effect of elevated temperature on membrane lipid saturation in Antarctic notothenioid fish.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Malekar VC, Morton JD, Hider RN, Cruickshank RH, Hodge S, Metcalf VJ<br><font color=gray><i>PeerJ, 2018</i></font><br><font color=#008000><br></font></span><br>6.  <a href= class=title>Post-Capture Survival and Implications for By-Catch in a Multi-Species Coastal Gillnet Fishery.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Bell JD, Lyle JM<br><font color=gray><i>PloS one, 2016</i></font><br><font color=#008000><br></font></span><br>7.  <a href= class=title>Temperature acclimation of mitochondria function from the hearts of a temperate wrasse (<b>Notolabrus</b> celidotus).</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Iftikar FI, Morash AJ, Cook DG, Herbert NA, Hickey AJ<br><font color=gray><i>Comparative biochemistry and physiology. Part A, Molecular & integrative physiology, 2015</i></font><br><font color=#008000><br></font></span><br>8.  <a href= class=title>Temperature-related variation in growth rate, size, maturation and life span in a marine herbivorous fish over a latitudinal gradient.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Trip ED, Clements KD, Raubenheimer D, Choat JH<br><font color=gray><i>The Journal of animal ecology, 2014</i></font><br><font color=#008000><br></font></span><br>9.  <a href= class=title>Could thermal sensitivity of mitochondria determine species distribution in a changing climate?</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Iftikar FI, MacDonald JR, Baker DW, Renshaw GM, Hickey AJ<br><font color=gray><i>The Journal of experimental biology, 2014</i></font><br><font color=#008000><br></font></span><br>10.  <a href= class=title>Do mitochondria limit hot fish hearts? Understanding the role of mitochondrial function with heat stress in <b>Notolabrus</b> celidotus.</a><a href=><img src=linkit.png border=0 title='LinkIT' alt='LinkIT'></a> <br><span class=j>Iftikar FI, Hickey AJ<br><font color=gray><i>PloS one, 2013</i></font><br><font color=#008000><br></font></span><br><br><br><table cellspacing=0 cellpadding=0 align=center><tr valign=bottom><td align=center><img src=p.png border=0></td><td align=center><img src=o_red.png border=0></td><td align=center><a href=><img src=o_yellow.png border=0></a></td><td align=center><a href=><img src=rtal.png border=0></a></td></tr><td align=center></td><td align=center>1</td><td align=center><a href=>2</a></td><td align=center><a href=>»</a></td></tr></table></table></tr></table></td><script src="" type="text/javascript"> </script> <script type="text/javascript"> _uacct = "UA-634822-1"; urchinTracker(); </script> </BODY> </HTML>