2012
DOI: 10.1098/rstb.2012.0019
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Defining the limits of physiological plasticity: how gene expression can assess and predict the consequences of ocean change

Abstract: Anthropogenic stressors, such as climate change, are driving fundamental shifts in the abiotic characteristics of marine ecosystems. As the environmental aspects of our world's oceans deviate from evolved norms, of major concern is whether extant marine species possess the capacity to cope with such rapid change. In what many scientists consider the post-genomic era, tools that exploit the availability of DNA sequence information are being increasingly recognized as relevant to questions surrounding ocean chan… Show more

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Cited by 149 publications
(135 citation statements)
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“…Cytoskeleton proteins have dynamic structures, which help maintain cell shape, and aid in cellular division, cell movement and support. Changes in the expression of cytoskeletal gene transcripts in response to abiotic stress have been reported in many marine organisms (Lockwood and Somero, 2011;Evans and Hofmann, 2012). In the present study, exposure to thermal stress reduced the expression of genes involved in the formation of major cytoskeletal structures, such as tubulin (0.47-fold compared to the control group), and myosin (0.31-fold compared to the control group).…”
Section: Cytoskeletal Reorganization Under Thermal Stresssupporting
confidence: 56%
“…Cytoskeleton proteins have dynamic structures, which help maintain cell shape, and aid in cellular division, cell movement and support. Changes in the expression of cytoskeletal gene transcripts in response to abiotic stress have been reported in many marine organisms (Lockwood and Somero, 2011;Evans and Hofmann, 2012). In the present study, exposure to thermal stress reduced the expression of genes involved in the formation of major cytoskeletal structures, such as tubulin (0.47-fold compared to the control group), and myosin (0.31-fold compared to the control group).…”
Section: Cytoskeletal Reorganization Under Thermal Stresssupporting
confidence: 56%
“…This information may indicate areas that might be refuges from acidification in the future, and could reveal regions that are adaptation "hot spots"; i.e., places where selection for undersaturation-tolerant genotypes has been underway for long periods of time (Jacobs et al, 2004). Finally, discovery of tolerant populations within the environmental mosaic of the CCLME can provide an opportunity to identify mechanisms that underlie tolerance (Evans et al, 2013a;Evans and Hofmann, 2012). We also hope to address whether some species possess sufficient physiological and genetic variation to adapt to future change.…”
mentioning
confidence: 99%
“…Many studies have used DNA microarrays to infer how organisms respond to different environments (Gracey and Cossins, 2003;Cossins et al, 2006;Gracey, 2007;Evans and Hofmann, 2012), such as temperature Yang et al, 2010;Long et al, 2012;Aguado-Urda et al, 2013;Logan and Buckley, 2015), osmolality (Posas et al, 2000;Evans and Somero, 2008;Melamed et al, 2008;Halbeisen andGerber, 2009), oxygen (Ton et al, 2003;Garnczarska, 2006;Swiderek et al, 2008;Otsuka et al, 2010;Gracey et al, 2011;Shinde et al, 2015) and pH (Leaphart et al, 2006;Serrano et al, 2006;Worden et al, 2009;Evans et al, 2013). Detection of genes with expression changes in response to environmental change helps to predict the fragility, resistance, and adaptability of an organism, tissue, or cell in the environment.…”
Section: Evaluation For Environmental Effectsmentioning
confidence: 99%