Admixture between old lineages facilitated contemporary ecological speciation in Lake Constance stickleback

Marques, David Alexander; Lucek, Kay; Sousa, Vítor C.; Excoffier, Laurent; Seehausen, Ole

doi:10.1038/s41467-019-12182-w

Cited by 60 publications

(120 citation statements)

References 78 publications

(138 reference statements)

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“…To characterize the extent of phenotypic and genotypic parallelism within a system, it is necessary to rigorously demonstrate that populations adapting to similar environments (collectively referred to as an ecotype) have arisen multiple times independently. We refer the reader to our previous analyses of parallel evolution in Senecio lautus (Roda et al, 2013b;James et al, 2020) and to systems such as the marine snail, Littorina saxatilis (Quesada et al, 2007;Johannesson et al, 2010;Bierne et al, 2013;Butlin et al, 2014;Pérez-Pereira et al, 2017), and the threespine stickleback, Gasterosteus aculeatus (Colosimo et al, 2005;Chan et al, 2010;Dean et al, 2019;Marques et al, 2019) where one can find some of the strongest evidence for the independent origin of populations, and to the increasing number of potential cases of parallel evolution in plants (Foster et al, 2007;Ostevik et al, 2012;Trucchi et al, 2017;Cai et al, 2019;Konečná et al, 2019;Knotek et al, 2020).…”

Section: A Framework To Measure Parallel Evolutionmentioning

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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Section: A Framework To Measure Parallel Evolutionmentioning

confidence: 99%

Phenotypic and genotypic parallel evolution in parapatric ecotypes ofSenecio

James

Wilkinson

Bernal

et al. 2020

Preprint

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“…Such comparisons must be made with caution however, as marine populations are also diverging, and can be grouped into several genetically distinct clusters as well (DeFaveri et al, 2012;deFaveri and Merilä, 2014;Fang et al, 2018Fang et al, , 2020aMorris et al, 2018). Furthermore, geographically adjacent marine and freshwater populations and species do not necessarily share the same common ancestor (Dean et al, 2019;Marques et al, 2019a). Within freshwater, ecotypic diversification occurs frequently along a lake-stream axis of divergence and rarely along a benthic-limnetic axis within lakes, where the latter has been found exclusively in coastal sectors of British Columbia, Canada (Bentzen and McPhail, 1984;Schluter and McPhail, 1992;Foster and Bell, 1994;McPhail, 1994;McKinnon and Rundle, 2002;Gow et al, 2008;Willacker et al, 2010;Østbye et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Threespine Stickleback in Lake Constance: The Ecology and Genomic Substrate of a Recent Invasion

et al. 2021

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Invasive species can be powerful models for studying contemporary evolution in natural environments. As invading organisms often encounter new habitats during colonization, they will experience novel selection pressures. Threespine stickleback (Gasterosteus aculeatus complex) have recently colonized large parts of Switzerland and are invasive in Lake Constance. Introduced to several watersheds roughly 150 years ago, they spread across the Swiss Plateau (400–800 m a.s.l.), bringing three divergent hitherto allopatric lineages into secondary contact. As stickleback have colonized a variety of different habitat types during this recent range expansion, the Swiss system is a useful model for studying contemporary evolution with and without secondary contact. For example, in the Lake Constance region there has been rapid phenotypic and genetic divergence between a lake population and some stream populations. There is considerable phenotypic variation within the lake population, with individuals foraging in and occupying littoral, offshore pelagic, and profundal waters, the latter of which is a very unusual habitat for stickleback. Furthermore, adults from the lake population can reach up to three times the size of adults from the surrounding stream populations, and are large by comparison to populations globally. Here, we review the historical origins of the threespine stickleback in Switzerland, and the ecomorphological variation and genomic basis of its invasion in Lake Constance. We also outline the potential ecological impacts of this invasion, and highlight the interest for contemporary evolution studies.

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“…The lack of SGV to fuel local adaptation can be mitigated by introgression between divergent clades as this can substantially increase the genetic variation in the affected populations (Anderson 1949;Arnold 1997;Marques et al 2019). This appears to be the case for the Baltic Sea nine-spined stickleback populations which have experienced introgression from divergent western European populations (Feng et al 2020;Shikano et al 2010b;Teacher et al 2011); a comparison of admixed and non-admixed populations revealed the former to have significantly higher heterozygosity than the latter.…”

Section: Implications For Local Adaptationmentioning

confidence: 99%

“…In the case of the threespined stickleback "species pairs", speciation seems to progress rapidly towards completion, but full reproductive isolation is not usually reached (McKinnon & Rundle 2002). In fact, whenever the ecological conditions that drove the evolution of reproductive isolation in the first place cease to exist, hybridization and reverse speciation is known to occur (Marques et al 2019;Rudman & Schluter 2016). Hence, this suggests that strong genetic incompatibilities have not had time to evolve.…”

Section: Genetic Differentiation and Speciationmentioning

confidence: 99%

Population structure limits parallel evolution

Fang

Kemppainen

Momigliano

et al. 2021

Preprint

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Population genetic theory predicts that small effective population sizes (Ne) and restricted gene flow limit the potential for local adaptation. In particular, the probability of evolving similar phenotypes based on shared genetic mechanisms (i.e. parallel evolution), is expected to be reduced. We tested these predictions in a comparative genomic study of two ecologically similar and geographically co-distributed stickleback species (viz. Gasterosteus aculeatus and Pungitius pungitius). We found that P. pungitius harbours less genetic diversity and exhibits higher levels of genetic differentiation and isolation-by-distance than G. aculeatus. Conversely, G. aculeatus exhibits a stronger degree of genetic parallelism across freshwater populations than P. pungitius: 2996 vs. 379 SNPs located within 26 vs nine genomic regions show evidence of selection in multiple freshwater populations of G. aculeatus and P. pungitius, respectively. Most regions involved in parallel evolution in G. aculeatus showed increased levels of divergence, suggestive of selection on ancient haplotypes. In contrast, regions involved in freshwater adaptation in P. pungitius were younger, and often associated with reduced diversity. In accordance with theory, the results suggest that connectivity and genetic drift play crucial roles in determining the levels and geographic distribution of standing genetic variation, providing evidence that population subdivision limits local adaptation and therefore also the likelihood of parallel evolution.

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Admixture between old lineages facilitated contemporary ecological speciation in Lake Constance stickleback

Cited by 60 publications

References 78 publications

Phenotypic and genotypic parallel evolution in parapatric ecotypes ofSenecio

Phenotypic and genotypic parallel evolution in parapatric ecotypes ofSenecio

Threespine Stickleback in Lake Constance: The Ecology and Genomic Substrate of a Recent Invasion

Population structure limits parallel evolution

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