Evolutionary potential of thermal preference and heat tolerance in <i>Drosophila subobscura</i>

Castañeda, Luis E.; Romero‐Soriano, Valèria; Mesas, Andrés; Roff, Derek A.; Santos, Mauro

doi:10.1111/jeb.13483

Cited by 34 publications

(58 citation statements)

References 64 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…We also observed quite substantial genetic variation in thermal performance, while many studies have observed much lower heritabilities (e.g. Castañeda et al ., 2019).…”

Section: Discussionsupporting

confidence: 62%

Quantitative genetics of temperature performance curves ofNeurospora crassa

Moghadam

Sidhu

Summanen

et al. 2020

Preprint

View full text Add to dashboard Cite

1Earth's temperature is increasing due to anthropogenic CO 2 emissions; and organ-2 isms need either to adapt to higher temperatures, migrate into colder areas, or face 3 extinction. Temperature affects nearly all aspects of organism's physiology via its in-4 fluence on metabolic rate and protein structure. Compared to other abiotic stresses, 5 genetic adaptation to increased temperature may be much harder to achieve due to sys-6 temic effects of temperature. As the evolutionary potential for adaptation to higher 7 temperatures is relatively unknown, we studied the quantitative genetics of thermal 8 performance curves of the fungal model system Neurospora crassa. We asked whether 9 there is genetic variation for thermal performance curves and examined possible ge-10 netic of evolution constraints by estimating the G-matrix. We observed substantial 11 amount of genetic variation for growth in different temperatures, and most genetic 12 variation was for performance curve elevation. Contrary to common theoretical as-13 sumptions we did not find strong evidence for genetic trade-offs for growth between 14 hotter and colder temperatures. We also simulated short term evolution of thermal per-15 formance curves of N. crassa, and suggest that they can have versatile responses to 16 selection. 17 Earth's temperature is rising due to anthropogenic activities (IPCC, 2013). The challenge most 19 organisms will face in a warming world is that they have to either adapt to warmer conditions or 20 migrate into colder areas to avoid extinction (Deutsch et al., 2008; Dillon et al., 2010; Araújo et al., 21 2013; Merilä and Hendry, 2014). Temperature is a unique abiotic stress, because the kinetics of 22 all biochemical reactions and protein stability are affected by temperature. As such, temperature 23 influences nearly all aspects of an ectothermic organism's physiology (Schulte, 2015; Arcus et al., 24 2016). Therefore, adapting to a higher temperature may be much more difficult than adapting to 25 a more specific environmental stress. For some anthropogenic stresses, such as antibiotics or her-26 bicides, decades of research have revealed strong evolutionary adaptation to these stresses (Davies 27 and Davies, 2010; Powles and Yu, 2010). However, genetic basis of adaptation to temperature is 28 likely to much more complex (Hochachka and Somero, 2002). 29According to quantitative genetic theory, evolution is possible if variation in a trait is heritable 30 and selection acts on this variation. However, the evolution of multivariate traits can be complicated 31 by genetic correlations, allowing evolution to proceed only in few directions or possibly preventing 32 it altogether (Walsh and Blows, 2009). The more entangled traits are with each other, the more 33 difficult the evolution of the underlying genetic network and the phenotype can be. 34The ability of an organism to tolerate different temperatures is often described by thermal per-35 formance curve (Huey and Kingsolver, 1989, 1993), which describes the fitn...

show abstract

“…We also observed quite substantial genetic variation in thermal performance, while many studies have observed much lower heritabilities (e.g. Castañeda et al ., 2019).…”

Section: Discussionsupporting

confidence: 62%

Quantitative genetics of temperature performance curves ofNeurospora crassa

Moghadam

Sidhu

Summanen

et al. 2020

Preprint

View full text Add to dashboard Cite

show abstract

“…Heritability estimates are sensitive to environmental conditions (Hoffmann and Parsons 191). Low heritability estimates for thermal performance traits has been suggested to be a function of the intensity and duration of the thermal treatment (Castañeda et al, 2019). In some studies, increasing the length of the thermal assay lowers heritability, perhaps because additional stress factors (e.g., resource depletion, cellular damage, and dessication resistance), arising under chronic but not acute stress, increase environmental variance (Mitchell and Hoffmann, 2010;Castañeda et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

“…Low heritability estimates for thermal performance traits has been suggested to be a function of the intensity and duration of the thermal treatment (Castañeda et al, 2019). In some studies, increasing the length of the thermal assay lowers heritability, perhaps because additional stress factors (e.g., resource depletion, cellular damage, and dessication resistance), arising under chronic but not acute stress, increase environmental variance (Mitchell and Hoffmann, 2010;Castañeda et al, 2019). However, we find increased broad-sense heritability at higher temperatures with no correlation between heat-induced sterility and other environmental stress factors such as desiccation resistance that may contribute to environmental variance.…”

Section: Discussionmentioning

confidence: 99%

“…Upper critical thermal limits of terrestrial ectotherms show considerably less geographical variation than lower limits (Addo-Bediako et al, 2000;Deutsch et al, 2008;Kellermann et al, 2012) and many species are thought to operate close to their upper performance limits (Huey et al, 2012;van Heerwaarden et al, 2016). Although some Drosophila species have latitudinal clines of CTmax (Castañeda et al, 2015;O'Brien et al, 2017), suggesting the ability to locally adapt to varying temperatures, most evidence on the evolutionary potential for increasing heat tolerance (e.g., shifting critical thermal maximum) suggests limited genetic variability to respond to selection (Castañeda et al, 2019;Kellermann and van Heerwaarden, 2019). Phenotypic plasticity of thermal tolerance parameters, such as CTmax, may be critical to species persistence but many species appear to have a small capacity to shift CTmax via phenotypic plasticity (Sørensen et al, 2016;Kellermann and Sgrò, 2018).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Phenotypic Responses to and Genetic Architecture of Sterility Following Exposure to Sub-Lethal Temperature During Development

et al. 2020

View full text Add to dashboard Cite

“…However, upper thermal limits seem to be evolutionary constrained in some small ectothermic insects (particularly studied in Drosophila) (Kellermann et al, 2012;Schou et al, 2014; but see discussion in Logan and Cox, 2020), while not in some species of phytoplankton (Kontopoulos et al, 2020). The constraint among species of Drosophila is not founded in an apparent lack of additive genetic variation, as significant levels of genetic variation for heat tolerance in the same species of Drosophila have been documented (Williams et al, 2012;Castaneda et al, 2019). Theory predicts that evolution of plasticity should be favored in predictably variable environments (Lande, 2009;Ashander et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Pronounced Plastic and Evolutionary Responses to Unpredictable Thermal Fluctuations in Drosophila simulans

et al. 2020

View full text Add to dashboard Cite

Organisms are exposed to temperatures that vary, for example on diurnal and seasonal time scales. Thus, the ability to behaviorally and/or physiologically respond to variation in temperatures is a fundamental requirement for long-term persistence. Studies on thermal biology in ectotherms are typically performed under constant laboratory conditions, which differ markedly from the variation in temperature across time and space in nature. Here, we investigate evolutionary adaptation and environmentally induced plastic responses of Drosophila simulans to no fluctuations (constant), predictable fluctuations or unpredictable fluctuations in temperature. We whole-genome sequenced populations exposed to 20 generations of experimental evolution under the three thermal regimes and examined the proteome after short-term exposure to the same three regimes. We find that unpredictable fluctuations cause the strongest response at both genome and proteome levels. The loci showing evolutionary responses were generally unique to each thermal regime, but a minor overlap suggests either common laboratory adaptation or that some loci were involved in the adaptation to multiple thermal regimes. The evolutionary response, i.e., loci under selection, did not coincide with induced responses of the proteome. Thus, genes under selection in fluctuating thermal environments are distinct from genes important for the adaptive plastic response observed within a generation. This information is key to obtain a better understanding and prediction of the effects of future increases in both mean and variability of temperatures.

show abstract

Evolutionary potential of thermal preference and heat tolerance in Drosophila subobscura

Cited by 34 publications

References 64 publications

Quantitative genetics of temperature performance curves ofNeurospora crassa

Quantitative genetics of temperature performance curves ofNeurospora crassa

Phenotypic Responses to and Genetic Architecture of Sterility Following Exposure to Sub-Lethal Temperature During Development

Pronounced Plastic and Evolutionary Responses to Unpredictable Thermal Fluctuations in Drosophila simulans

Contact Info

Product

Resources

About