Limited plasticity in thermally tolerant ectotherm populations: evidence for a trade-off

Barley, Jordanna; Cheng, Brian S.; Sasaki, Matthew; Gignoux‐Wolfsohn, Sarah; Hays, Cynthia G.; Putnam, Alysha B.; Sheth, Seema N.; Villeneuve, Andrew; Kelly, Morgan W.

doi:10.1098/rspb.2021.0765

Cited by 51 publications

(57 citation statements)

References 110 publications

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“…In another study, Barley et al conducted a metaanalysis of within-species variation in thermal plasticity, but did not find support for the climate variability hypothesis [18]. Instead, their analysis showed that populations with greater thermal tolerance had reduced plasticity, which was evidence for trade-offs between thermal tolerance and thermal plasticity [18].…”

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confidence: 99%

“…Two studies in this Special Feature challenge the widespread notion that increased climate variability also increases thermal tolerance and plasticity [18,19]. Bitter et al reviewed theoretical predictions for the evolution of plasticity in fluctuating environments, and showed that it is the predictability (rather than the amplitude) of fluctuations that primarily drive the amount of phenotypic plasticity present in natural populations.…”

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confidence: 99%

“…They proposed an experimental design that future studies can use to tease apart the effects of the amplitude, predictability and novelty of climate fluctuations on population fitness and persistence [19]. In another study, Barley et al conducted a metaanalysis of within-species variation in thermal plasticity, but did not find support for the climate variability hypothesis [18]. Instead, their analysis showed that populations with greater thermal tolerance had reduced plasticity, which was evidence for trade-offs between thermal tolerance and thermal plasticity [18].…”

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confidence: 99%

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2021

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“…Evidence from natural study systems is required to clarify under which conditions plasticity is favored or hindered by evolution. A meta-study by Barley et al (2021) quantified thermal acclimation capacity across 19 species including arthropods, molluscs, and chordates, showing that within species, marginal populations experiencing the highest thermal conditions had decreased plasticity and acclimation capacity. A negative relationship between plasticity and adaptation to heat extremes was also found in laboratory experiments (Kelly et al, 2017;Sasaki & Dam, 2021).…”

Section: Introductionmentioning

confidence: 99%

Parallel adaptation to lower altitudes is associated with enhanced plasticity in Heliosperma pusillum (Caryophyllaceae)

Szukala

Bertel

Frajman

et al. 2022

Preprint

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High levels of phenotypic plasticity are thought to be inherently costly in stable or extreme environments, but enhanced plasticity may evolve as a response to novel environments and foster adaptation. Heliosperma pusillum forms pubescent montane and glabrous alpine ecotypes that diverged recurrently and polytopically (parallel evolution). The specific montane and alpine localities are characterized by distinct temperature conditions, available moisture and light. To disentangle the relative contribution of constitutive versus plastic gene expression to altitudinal divergence, we analyze the transcriptomic profiles of two parallely evolved ecotype pairs, grown in reciprocal transplantations at native altitudinal sites. In both ecotype pairs, only a minor proportion of genes appear constitutively differentially expressed between the ecotypes regardless of the growing environment. Both derived, montane populations bear comparatively higher plasticity of gene expression than the alpine populations that can be considered in this system as ‘ancestor-proxies’. Genes that change expression plastically and constitutively underlie similar ecologically relevant pathways, related to response to drought and trichome formation. Other relevant processes, such as photosynthesis, seem to rely mainly on plastic changes. The enhanced plasticity consistently observed in the montane ecotype likely evolved as a response to the newly colonized niche. Our findings confirm that directional changes in gene expression plasticity can shape initial stages of phenotypic evolution, likely fostering adaptation to novel environments.Significance StatementUnderstanding the importance of phenotypic plasticity for fast adaptation to stress is very timely for breeding and current environmental challenges. Our study of an alpine plant in the carnation family evidences an increased level of expression plasticity in early stages of adaptation to hotter and drier habitats.

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“…Motivated by current debate surrounding the Trade-off Hypothesis and increasing interest in the evolution of phenotypic plasticity and genetic assimilation under global change (Gunderson and Stillman 2015; Kelly 2019; Sasaki and Dam 2019; van Heerwaarden and Kellermann 2020; Barley et al 2021; Preston et al 2021; Sasaki and Dam 2021), we used simulations to explore the more general consequences of regression to the mean for tests of genetic assimilation at the macroevolutionary level. We conducted simulations that assumed mechanistically different models for plasticity evolution, as well as different experimental sampling designs for measuring species phenotypic traits.…”

Section: Introductionmentioning

confidence: 99%

Testing for genetic assimilation with phylogenetic comparative analysis: Conceptual, methodological, and statistical considerations

Gunderson

Revell

2021

Preprint

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Genetic assimilation is a process that leads to reduced phenotypic plasticity during adaptation to novel conditions, a potentially important phenomenon under global environmental change. Null expectations when testing for genetic assimilation, however, are not always clear. For instance, the statistical artifact of regression to the mean could bias us towards detecting genetic assimilation when it has not occurred. Likewise, the specific mechanism underlying plasticity expression may affect null expectations under neutral evolution. We used macroevolutionary numerical simulations to examine both of these important issues and their interaction, varying whether or not plasticity evolves, the evolutionary mechanism, trait measurement error, and experimental design. We also modified an existing reaction norm correction method to account for phylogenetic non-independence. We found: 1) regression to the mean is pervasive and can generate spurious support for genetic assimilation; 2) experimental design and post-hoc correction can minimize this spurious effect; and 3) neutral evolution can produce patterns consistent with genetic assimilation without constraint or selection, depending on the mechanism of plasticity expression. Additionally, we re-analyzed published macroevolutionary data supporting genetic assimilation, and found that support was lost after proper correction. Considerable caution is thus required whenever investigating genetic assimilation and reaction norm evolution at macroevolutionary scales.

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Limited plasticity in thermally tolerant ectotherm populations: evidence for a trade-off

Cited by 51 publications

References 110 publications

Evolution in changing seas

Evolution in changing seas

Parallel adaptation to lower altitudes is associated with enhanced plasticity in Heliosperma pusillum (Caryophyllaceae)

Testing for genetic assimilation with phylogenetic comparative analysis: Conceptual, methodological, and statistical considerations

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