Phenotypic and molecular consequences of stepwise temperature increase across generations in a coral reef fish

Bernal, Moisés A.; Donelson, Jennifer M.; Veilleux, Heather D.; Ryu, Taewoo; Ravasi, Timothy

doi:10.1111/mec.14884

Cited by 38 publications

(81 citation statements)

References 77 publications

(119 reference statements)

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“…Unfortunately, obtaining a "control" year was logistically impossible because we could not predict the heatwave conditions sufficiently in advance, and due to an already very ambitious sampling scheme for species with no previous genomic resources (with the exception of A. polyacanthus). Despite these limitations, the functions of genes that showed expression changes over the duration of the heatwave concur with previous laboratory experiments on A. polyacanthus, one of the most studied tropical marine fish species in the context of global change (19,20).…”

Section: Discussionsupporting

confidence: 83%

“…When temperatures are too high, the cardiorespiratory system is no longer able to fulfill additional oxygen demands for aerobic activities, leading to a reduction in aerobic performance (15,16), alteration of growth rates (17), and reduction in swimming speeds (18). Previous studies focusing on gene expression of captive fishes have shown that increased oxygen demands at higher temperatures can lead to activation of genes related to mitochondrial activity, the electron-transport chain, fatty acid metabolism, and cellular stress response (19,20). Furthermore, reproductive hormones can be affected by warmer conditions, leading to changes in reproductive behavior and declines in reproductive output (21).…”

Section: Introductionmentioning

confidence: 99%

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Species-specific molecular responses of wild coral reef fishes during a marine heatwave

et al. 2020

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The marine heatwave of 2016 was one of the longest and hottest thermal anomalies recorded on the Great Barrier Reef, influencing multiple species of marine ectotherms, including coral reef fishes. There is a gap in our understanding of what the physiological consequences of heatwaves in wild fish populations are. Thus, in this study, we used liver transcriptomes to understand the molecular response of five species to the 2016 heatwave conditions. Gene expression was species specific, yet we detected overlap in functional responses associated with thermal stress previously reported in experimental setups. The molecular response was also influenced by the duration of exposure to elevated temperatures. This study highlights the importance of considering the effects of extreme warming events when evaluating the consequences of climate change on fish communities.

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Section: Discussionsupporting

confidence: 83%

Section: Introductionmentioning

confidence: 99%

Species-specific molecular responses of wild coral reef fishes during a marine heatwave

et al. 2020

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“…After all, the genome and, more especially, its regulation must be highly dynamic to allow for plasticity to occur and we need to learn more about both genetic and epigenetic mechanisms to understand how climate stressors can influence and shape genomes, transcriptomes and the epigenome, in particular, across generations. In recent years, considerable effort has been expended on trying to understand the molecular, genomic and epigenomic mechanisms underlying responses to climate stressors across a variety of species and populations, including fish [72][73][74][75][76], corals [77,78], other invertebrates [79 -81] and plants (review: [82]). In the process, we have substantially increased our knowledge of the molecular mechanisms underlying plasticity (e.g.…”

Section: Resultsmentioning

confidence: 99%

Beyond buying time: the role of plasticity in phenotypic adaptation to rapid environmental change

Fox

Donelson

Schunter

et al. 2019

Phil. Trans. R. Soc. B

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How populations and species respond to modified environmental conditions is critical to their persistence both now and into the future, particularly given the increasing pace of environmental change. The process of adaptation to novel environmental conditions can occur via two mechanisms: (1) the expression of phenotypic plasticity (the ability of one genotype to express varying phenotypes when exposed to different environmental conditions), and (2) evolution via selection for particular phenotypes, resulting in the modification of genetic variation in the population. Plasticity, because it acts at the level of the individual, is often hailed as a rapid-response mechanism that will enable organisms to adapt and survive in our rapidly changing world. But plasticity can also retard adaptation by shifting the distribution of phenotypes in the population, shielding it from natural selection. In addition to which, not all plastic responses are adaptive—now well-documented in cases of ecological traps. In this theme issue, we aim to present a considered view of plasticity and the role it could play in facilitating or hindering adaption to environmental change. This introduction provides a re-examination of our current understanding of the role of phenotypic plasticity in adaptation and sets the theme issue's contributions in their broader context. Four key themes emerge: the need to measure plasticity across both space and time; the importance of the past in predicting the future; the importance of the link between plasticity and sexual selection; and the need to understand more about the nature of selection on plasticity itself. We conclude by advocating the need for cross-disciplinary collaborations to settle the question of whether plasticity will promote or retard species' rates of adaptation to ever-more stressful environmental conditions. This article is part of the theme issue ‘The role of plasticity in phenotypic adaptation to rapid environmental change’.

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“…These included proteins related to the heat shock response (HSP), Abbreviations: CV, coefficients of variance; DDA, data-dependent acquisition; DIA, Data-independent acquisition. a well-documented expression change seen in fish exposed to elevated temperatures (Basu et al, 2002), cytochrome related genes involved in oxidative stress and several other previously identified stress response genes in marine fish representing protein degradation and cell death. In Figure 4, we see the combined DDA libraries provided the least identifications of the complex cellular stress response identified by the other libraries.…”

Section: Differential Expression and Functional Analysismentioning

confidence: 91%

Probing SWATH‐MS as a tool for proteome level quantification in a nonmodel fish

Monroe

Zhang

Schunter

et al. 2020

Molecular Ecology Resources

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Phenotypic and molecular consequences of stepwise temperature increase across generations in a coral reef fish

Cited by 38 publications

References 77 publications

Species-specific molecular responses of wild coral reef fishes during a marine heatwave

Species-specific molecular responses of wild coral reef fishes during a marine heatwave

Beyond buying time: the role of plasticity in phenotypic adaptation to rapid environmental change

Probing SWATH‐MS as a tool for proteome level quantification in a nonmodel fish

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