Population genomics of parallel evolution in gene expression and gene sequence during ecological adaptation

Rivas, Mercedes; Saura, María; Pérez‐Figueroa, Andrés; Panova, Marina; Johansson, Tomas; André, Carl; Caballero, Armando; Rolán‐Alvarez, Emilio; Johannesson, Kerstin; Quesada, Humberto

doi:10.1038/s41598-018-33897-8

Cited by 21 publications

(26 citation statements)

References 99 publications

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“…These studies search to investigate phenotypic effects when variation in temperature is combined with variation in other environmental variables (Figure 2), including biotic and abiotic factors (Bubliy et al, 2013;Schou et al, 2013;Arambourou and Stoks, 2015;Saeed et al, 2018;Kutz et al, 2019). Some studies extend the analysis of plasticity in multifactorial environments to include: (1) multiple traits and/or to multiple genotypes (e.g,., Saastamoinen et al, 2013;Verspagen et al, 2020), (2) threeway environmental interactions (e.g., temperature × humidity × food; Bomble and Nath, 2019), and (3) quantifying underlying changes in gene expression (e.g., candidate genes, Rivas et al, 2018, and whole transcriptome, Koch and Guillaume, 2020). The results to date paint a complex picture, with distinct types of additive (e.g., Koch and Guillaume, 2020) and nonadditive (e.g., Yoshii et al, 2009;Arambourou and Stoks, 2015;Piggott et al, 2015) effects of multifactorial environments, and differences between traits and between genotypes.…”

Section: Phenotypic Plasticity In Complex Environmentsmentioning

confidence: 99%

Thermal Plasticity in Insects’ Response to Climate Change and to Multifactorial Environments

Rodrigues

Beldade

2020

Front. Ecol. Evol.

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Phenotypic plasticity, the property by which living organisms express different phenotypes depending on environmental conditions, can impact their response to environmental perturbation, including that resulting from climate change. When exposed to altered environmental conditions, phenotypic plasticity might help or might hinder both immediate survival and future adaptation. Because climate change will cause more than a global rise in mean temperatures, it is valuable to consider the combined effects of temperature and other environmental variables on trait expression (thermal plasticity), as well as trait evolution (thermal adaptation). In this review, we focus primarily on thermal developmental plasticity in insects. We discuss the genomics of thermal plasticity and its relationship to thermal adaptation and thermal tolerance, and to climate change and multifactorial environments.

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Section: Phenotypic Plasticity In Complex Environmentsmentioning

confidence: 99%

Thermal Plasticity in Insects’ Response to Climate Change and to Multifactorial Environments

Rodrigues

Beldade

2020

Front. Ecol. Evol.

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“…In Patagonia too, lakes that were ice-covered during the last glacial maximum (LGM) were colonized soon after deglaciation (Vera-Escalona, Habit, & Ruzzante, 2015Zemlak et al, 2011). An earlier colonization of lakes for the northernmost populations can explain their higher genetic differentiation from their TA B L E 3 Blast annotation results from the top 25 outliers that have a potential function described in Table S3 diadromous counterparts, while in the southern populations, recent colonization can explain the weak differentiation as the standing genetic variation from the ancestral population (diadromous ecotype) will likely be the source of variation (Rivas et al, 2018).…”

Section: Resident Populationsmentioning

confidence: 99%

The effects of diadromy and its loss on genomic divergence: The case of amphidromous Galaxias maculatus populations

et al. 2019

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Understanding the evolutionary mechanisms that affect the genetic divergence between diadromous and resident populations across heterogeneous environments is a challenging task. While diadromy may promote gene flow leading to a lack of genetic differentiation among populations, resident populations tend to be affected by local adaptation and/or plasticity. Studies on these effects on genomic divergence in nonmodel amphidromous species are scarce. Galaxias maculatus, one of the most widespread fish species in the Southern Hemisphere, exhibits two life histories, an ancestral diadromous, specifically, amphidromous form, and a derived freshwater resident form. We examined the genetic diversity and divergence among 20 estuarine and resident populations across the Chilean distribution of G. maculatus and assessed the extent to which selection is involved in the differentiation among resident populations. We obtained nearly 4,400 SNP markers using a RADcap approach for 224 individuals. As expected, collections from estuarine locations typically consist of diadromous individuals. Diadromous populations are highly differentiated from their resident counterparts by both neutral and putative adaptive markers. While diadromous populations exhibit high gene flow and lack site fidelity, resident populations appear to be the product of different colonization events with relatively low genetic diversity and varying levels of gene flow. In particular, the northernmost resident populations were clearly genetically distinct and reproductively isolated from each other suggesting local adaptation. Our study provides insights into the role of life history differences in the maintenance of genetic diversity and the importance of genetic divergence in species evolution.

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“…In such systems, divergent loci are difficult to detect as they contain low FST, which further makes detecting genetic parallelism highly unlikely in these systems. Finally, traditional approaches that sample SNPs across the genome will fail to detect variation in gene expression levels, which may also be involved in adaptation during parallel evolution (e.g., Rivas et al, 2018;Verta & Jones, 2019).…”

Section: The Effects Of Sampling On Parallelismmentioning

confidence: 99%

Phenotypic and genotypic parallel evolution in parapatric ecotypes ofSenecio

James

Wilkinson

Bernal

et al. 2020

Preprint

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7The independent and repeated adaptation of populations to similar environments often results 8 in the evolution of similar forms. This phenomenon creates a strong correlation between 9 phenotype and environment and is referred to as 'parallel evolution.' However, there is 10 ongoing debate as to when we should call a system either phenotypically or genotypically 11 'parallel.' Here, we suggest a novel and simple framework to quantify parallel evolution at 12 the genotypic and phenotypic levels. We apply this framework to coastal ecotypes of an 13 Australian wildflower, Senecio lautus. Our findings show that S. lautus populations 14 inhabiting similar environments have evolved strikingly similar phenotypes. These 15 phenotypes have arisen via mutational changes affecting common biological functions but 16 occurring in different genes. Our work not only provides a common framework to study the 17

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Population genomics of parallel evolution in gene expression and gene sequence during ecological adaptation

Cited by 21 publications

References 99 publications

Thermal Plasticity in Insects’ Response to Climate Change and to Multifactorial Environments

Thermal Plasticity in Insects’ Response to Climate Change and to Multifactorial Environments

The effects of diadromy and its loss on genomic divergence: The case of amphidromous Galaxias maculatus populations

Phenotypic and genotypic parallel evolution in parapatric ecotypes ofSenecio

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