2015
DOI: 10.1111/mec.13047
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RNA‐seq reveals regional differences in transcriptome response to heat stress in the marine snail Chlorostoma funebralis

Abstract: To investigate the role of gene expression in adaptation of marine ectotherms to different temperatures, we examined the transcriptome-wide thermal stress response in geographically separated populations of the intertidal snail Chlorostoma funebralis. Snails from two southern (heat tolerant) and two northern (heat sensitive) populations were acclimated to a common thermal environment, exposed to an environmentally relevant thermal stress and analysed using RNA-seq. Pooling across all populations revealed 306 g… Show more

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Cited by 150 publications
(141 citation statements)
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“…Physiological responses of species to thermal stress are also highly variable among populations [38,39]. Whereas relatively few studies have measured intra-population physiological polymorphisms in intertidal species, the few studies that exist also suggest high inter-individual variability in physiological responses to thermal stress [40 -42].…”
Section: Introductionmentioning
confidence: 99%
“…Physiological responses of species to thermal stress are also highly variable among populations [38,39]. Whereas relatively few studies have measured intra-population physiological polymorphisms in intertidal species, the few studies that exist also suggest high inter-individual variability in physiological responses to thermal stress [40 -42].…”
Section: Introductionmentioning
confidence: 99%
“…This can be expected because when a population evolves tolerance to a certain stressor that environmental condition is no longer experienced as a stressor (Vam Straalen, 2003). With regard to warming, the acquisition of genetic adaptation to higher temperatures has been demonstrated in several taxa and has been linked to changes in gene expressions (e.g., Garvin, Thorgaard, & Narum, 2015; Gleason & Burton, 2015; Narum, Campbell, Meyer, Miller, & Hardy, 2013; Porcelli, Butlin, Gaston, Joly, & Snook, 2015; for the study species: Jansen et al., 2017; Yampolsky et al., 2014). Thermal evolution is expected to reduce the energetic costs of dealing with warming, thus leaving more energy to deal with stressors such as toxicants, thereby potentially offsetting the synergism between the toxicant and warming.…”
Section: Introductionmentioning
confidence: 99%
“…These factors play an important role in developing acute response models related to gene expression patterns (Wu, 1995;Morimoto, 1998). Specifically, thermally tolerant species may possess higher basal transcript levels and a less pronounced induction profile of heat shock proteins compared with thermally sensitive species (Gleason and Burton, 2015). This could allow thermally tolerant species to withstand a strong thermal insult because of the greater standing pool of heat shock proteins resulting from higher transcript levels (Bedulina et al, 2013;Barshis et al, 2013;Fangue et al, 2006;Luo et al, 2014).…”
Section: Molecular Response To Acute Heat Shockmentioning
confidence: 99%