Polygenic routes lead to parallel altitudinal adaptation in <i>Heliosperma pusillum</i> (Caryophyllaceae)

Szukala, Aglaia; Lovegrove-Walsh, Jessica; Luqman, Hirzi; Fior, Simone; Wolfe, Thomas M.; Frajman, Božo; Paun, Ovidiu

doi:10.1111/mec.16393

Cited by 18 publications

(40 citation statements)

References 136 publications

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“…This is in congruence with findings in Senecio lautus (James et al 2021b,c), in which similar phenotypes with large divergence times within-population pairs have arisen via mutational changes in different genes, although many of these genes shared the same biological functions. However, even in the system of a recent postglacial alpine-montane divergence, such as Heliosperma pusillum (Trucchi et al 2017;Szukala et al 2022), similar phenotypes were also achieved via selection on different genes in the same functional pathways. In such polygenic systems, we expect genetic redundancy, that is, mutations in different genes (possibly within the same pathway) can lead to similar phenotypes and thus to phenotypic parallelism (Hermisson and Pennings 2017;Höllinger et al 2019;Barghi et al 2020).…”

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Genomic basis and phenotypic manifestation of (non‐)parallel serpentine adaptation in Arabidopsis arenosa

et al. 2022

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Parallel evolution is common in nature and provides one of the most compelling examples of rapid environmental adaptation. In contrast to the recent burst of studies addressing genomic basis of parallel evolution, integrative studies linking genomic and phenotypic parallelism are scarce. Edaphic islands of toxic serpentine soils provide ideal systems for studying rapid parallel adaptation in plants, imposing strong, spatially replicated selection on recently diverged populations. We leveraged threefold independent serpentine adaptation of Arabidopsis arenosa and combined reciprocal transplants, ion uptake phenotyping, and available genome‐wide polymorphisms to test if parallelism is manifested to a similar extent at both genomic and phenotypic levels. We found pervasive phenotypic parallelism in functional traits yet with varying magnitude of fitness differences that was congruent with neutral genetic differentiation between populations. Limited costs of serpentine adaptation suggest absence of soil‐driven trade‐offs. On the other hand, the genomic parallelism at the gene level was significant, although relatively minor. Therefore, the similarly modified phenotypes, for example, of ion uptake arose possibly by selection on different loci in similar functional pathways. In summary, we bring evidence for the important role of genetic redundancy in rapid adaptation involving traits with polygenic architecture.

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Genomic basis and phenotypic manifestation of (non‐)parallel serpentine adaptation in Arabidopsis arenosa

et al. 2022

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“…On the one hand, phenotypic plasticity may reduce the power of natural selection, hindering specialization via genetic differentiation [ 51 ]. On the other hand, enhanced plasticity may enable the colonization of new environments, fostering adaptation [ 29 ]. Arabidopsis arenosa represents an excellent system to test for the role of plasticity in response to habitat differentiation, and future studies could test for adaptive advantages, or disadvantages, of the extent of plasticity.…”

Section: Discussionmentioning

confidence: 99%

“…As small populations often bear limited/low genetic variation, the source of adaptive variation is reduced, and genetic drift is increased due to a smaller number of individuals leading to stochastic changes [ 27 , 28 ]. However, not only particular traits per se , but also the ability to adjust them plastically can be under selection and differ between ecotypes [ 29 , 30 ].…”

Section: Introductionmentioning

confidence: 99%

“…Grown under the same environmental conditions, genetically determined differences between populations remain, while environmentally induced plastic differences diminish [ 39 ]. Comparing traits of one ecotype in the native versus the foreign environment also allows concluding on its potential to plastically adjust a trait, which may be particularly important for phylogenetically young populations or ecotypes [ 29 ].…”

Section: Introductionmentioning

confidence: 99%

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Parallel Differentiation and Plastic Adjustment of Leaf Anatomy in Alpine Arabidopsis arenosa Ecotypes

Bertel

Kaplenig

Ralser

et al. 2022

Plants

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Functional and structural adjustments of plants in response to environmental factors, including those occurring in alpine habitats, can result in transient acclimation, plastic phenotypic adjustments and/or heritable adaptation. To unravel repeatedly selected traits with potential adaptive advantage, we studied parallel (ecotypic) and non-parallel (regional) differentiation in leaf traits in alpine and foothill ecotypes of Arabidopsis arenosa. Leaves of plants from eight alpine and eight foothill populations, representing three independent alpine colonization events in different mountain ranges, were investigated by microscopy techniques after reciprocal transplantation. Most traits clearly differed between the foothill and the alpine ecotype, with plastic adjustments to the local environment. In alpine populations, leaves were thicker, with altered proportions of palisade and spongy parenchyma, and had fewer trichomes, and chloroplasts contained large starch grains with less stacked grana thylakoids compared to foothill populations. Geographical origin had no impact on most traits except for trichome and stomatal density on abaxial leaf surfaces. The strong parallel, heritable ecotypic differentiation in various leaf traits and the absence of regional effects suggests that most of the observed leaf traits are adaptive. These trait shifts may reflect general trends in the adaptation of leaf anatomy associated with the colonization of alpine habitats.

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“…Second, vague or imprecise terms are likely to impact early career researchers and newcomers to the field, who are sedimenting their knowledge, creating a superfluous barrier to their understanding. For instance, in biodiversity genomics parallel evolution has been used to refer to 'parallel changes at the molecular sequence level' (Natarajan et al, 2015), 'parallel replacements/substitutions' (Natarajan et al, 2015;Mendes et al, 2016;Lee et al, 2018), 'parallel evolution and fixation of mutations' (Stern, 2013), 'parallel selection on standing genetic variation' (Pease et al, 2016), 'parallel adaptation' (Stoltzfus & McCandlish, 2017;Bohutínská et al, 2021;Konečná et al, 2021;Szukala et al, 2022), 'parallel evolution of phenotypes' (Colosimo et al, 2005;Szukala et al, 2022), among other terms. Third, because nuances in the terms are likely field-specific (when considering developmental biology, physiology, ecology, genomics as di erent fields within biology), they may obstruct multidisciplinary e orts.…”

Section: Introductionmentioning

confidence: 99%

A simple conceptual framework and nomenclature for studying repeated, parallel and convergent evolution

Cerca¹

2022

Preprint

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Parallel and convergent evolution are textbook examples of the role of natural selection in evolution. However, these terms are used interchangeably, and sometimes with conflicting meanings. This has resulted in confusion, which hampers the understanding of the processes underlying these important forms of evolution. In this synthesis, I discuss the issues with current definitions of parallel, repeated and convergent evolution, and provide a framework aimed at solving these issues. This framework makes an important distinction between environmental properties and organismal properties, with the first involving the role of similar and non-similar environmental and selective pressures. The organismal properties include the genomic-basis where the process (mutation, standing genetic variation and gene flow) and the location (homologous nucleotide, homologous gene region or non-homologous gene region) are emphasised, and the phenotype (convergent or parallel evolved). I restrict the use of the terms parallel (evolution of similar and derived phenotypes, from similar ancestral phenotypes) and convergent (evolution of similar and derived phenotypes, from dissimilar ancestral phenotypes) evolution to the phenotypic level, thereby restoring its original meaning before the genomic revolution. I argue that this framework and nomenclature provide a clear resolution to study parallel and convergent phenotypic evolution across fields while maintaining the interest in its genomic and ecological grounds. Crucially, this framework stresses the importance of a multidisciplinary focus, integrating ecology, genomics, and phenotypes to determine whether parallel or convergent phenotypic evolution has taken place.

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Polygenic routes lead to parallel altitudinal adaptation in Heliosperma pusillum (Caryophyllaceae)

Cited by 18 publications

References 136 publications

Genomic basis and phenotypic manifestation of (non‐)parallel serpentine adaptation in Arabidopsis arenosa

Genomic basis and phenotypic manifestation of (non‐)parallel serpentine adaptation in Arabidopsis arenosa

Parallel Differentiation and Plastic Adjustment of Leaf Anatomy in Alpine Arabidopsis arenosa Ecotypes

A simple conceptual framework and nomenclature for studying repeated, parallel and convergent evolution

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