Evidence of local adaptation to fine‐ and coarse‐grained environmental variability in<i>Poa alpina</i>in the Swiss Alps

Hamann, Elena; Kesselring, Halil; Armbruster, Georg F. J.; Stöcklin, Jürg

doi:10.1111/1365-2745.12628

Cited by 32 publications

(22 citation statements)

References 75 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…genotype × environment interactions), but also result in differentiation in the degree of phenotypic plasticity (Kawecki & Ebert ; Hamann et al . ). While plastic variation between populations, reflected by the genotype × environment interaction, has been repeatedly demonstrated (reviewed e.g.…”

Section: Introductionmentioning

confidence: 97%

Genetic differentiation and plasticity interact along temperature and precipitation gradients to determine plant performance under climate change

et al. 2017

View full text Add to dashboard Cite

show abstract

Section: Introductionmentioning

confidence: 97%

Genetic differentiation and plasticity interact along temperature and precipitation gradients to determine plant performance under climate change

et al. 2017

View full text Add to dashboard Cite

show abstract

“…Therefore, the elevational gradient has been considered as the most important factor in studies on phenotypic variation of plant species in mountains (e.g. Stöcklin et al 2009;Št'astná et al 2012;Kim and Donohue 2013;Scheepens and Stöcklin 2013;Gugger et al 2015;Hamann et al 2016;Stöcklin and Armbruster 2016;Sakurai and Takahashi 2016;Takahashi and Matsuki 2016). Plants can respond to elevational changes based on their morphological and physiological plasticity and through local adaptations (Hirano et al 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Neuffer and Bartelheim 1989;Hirano et al 2017) or reciprocal transplantation to plots located at different elevations (e.g. Gonzalo-Turpin and Hazard 2009;Hautier et al 2009;Scheepens et al 2010;Hamann et al 2016) are essential. However, knowledge on variations in morphological traits and plant performance in natural populations along elevational gradients is also important to understand the role of natural selection in plant adaptation to alpine environments and plant phenotypic responses to such conditions (Clausen et al 1948;Gonzalo-Turpin and Hazard 2009;Bastida et al 2015).…”

mentioning

confidence: 99%

Variation of vegetative and floral traits in the alpine plant Solidago minuta: evidence for local optimum along an elevational gradient

Kiełtyk

2017

Alp Botany

View full text Add to dashboard Cite

Alpine plants growing along wide elevational gradients experience very different abiotic and biotic conditions across elevations. As a result of genetic differentiation and/or plastic response, conspecific plants growing in high elevations, as compared to low elevations, generally have shorter stems and lower number of flowers, but larger flower size. However, most often, detailed models of elevational variations were not examined. To reveal the pattern of elevational changes in a set of fitnessrelated morphological traits, tests of linear and unimodal models were performed based on measurements of 1047 Solidago minuta plants collected from 47 sites distributed along a 1000 m elevational gradient in the Tatra Mountains. Nearly all of the investigated floral traits, i.e. inflorescence and flower heads size, and number and size of individual flowers, expressed unimodal relationships with elevation having their maxima in the centre of the elevation range. This pattern suggests the existence of a local optimum with respect to sexual reproduction at the centre of the elevational range. Possible explanations of observed elevational variations are discussed in the context of pollinator selection and the 'resource-cost compromise' hypothesis. Best floral performance in the centre of the elevational range of S. minuta may also support the idea that the favourability of habitat conditions declines from the centre to the margin of the distribution, and species are expected to be more abundant, increase reproduction and perform better in the centre of the range.

show abstract

“…Evidence for local adaptation has been found in a number of alpine plant populations (Gonzalo-Turpin and Hazard 2009;Fischer et al 2011;Giménez-Benavides et al 2011;Hamann et al 2016); however, an extensive meta-analysis and another recent study suggest that local adaptation may be less common than frequently assumed (Leimu and Fischer 2008;Hirst et al 2016). Extensive gene flow among populations has been recognized as a main hindrance for local adaptation (Kawecki and Ebert 2004).…”

Section: Little Evidence For Local Adaptationmentioning

confidence: 99%

“…Moreover, strong phenotypic plasticity is likewise common in alpine species, and has been shown to provide a potential advantage for the persistence and survival of alpine species in a heterogeneous environment (Stöcklin et al 2009;Frei et al 2014). While the relative role of these two non-mutually exclusive strategies (i.e., adaptive genetic differentiation and plasticity), as well as the conditions for their evolution under divergent selection, are theoretically well understood, empirical evidence is rather scarce (Baythavong 2011; Hamann et al 2016). The spatial grain size of environmental variation, defined by the degree of environmental variation as perceived by an individual plant across its dispersal distance, is likely to determine which of these mechanisms prevails (Alpert and Simms 2002;Pigliucci et al 2003;Kawecki and Ebert 2004).…”

Section: Introductionmentioning

confidence: 99%

High intraspecific phenotypic variation, but little evidence for local adaptation in Geum reptans populations in the Central Swiss Alps

et al. 2017

Self Cite

View full text Add to dashboard Cite

that gene flow is maintained at close range, but decreased with distance. Although extensive phenotypic variation was found across site × population transplant combinations, our study revealed little evidence for local adaptation in G. reptans populations. Plant traits also showed strong plasticity, as revealed by pronounced site effects, yet no direct linear selection was detected on leaf trait values within field sites. We suggest that the glacier forelands studied here, which are representative of the habitat of large G. reptans populations, are too similar in environmental conditions to lead to among population intraspecific differentiation in line with local adaptation. As G. reptans showed a great capacity to respond plastically to environmental conditions, we cautiously advocate that the evolution of phenotypic plasticity might have prevailed over genetic differentiation for the adaptation to the relatively narrow niche of this species.

show abstract

Evidence of local adaptation to fine‐ and coarse‐grained environmental variability inPoa alpinain the Swiss Alps

Cited by 32 publications

References 75 publications

Genetic differentiation and plasticity interact along temperature and precipitation gradients to determine plant performance under climate change

Genetic differentiation and plasticity interact along temperature and precipitation gradients to determine plant performance under climate change

Variation of vegetative and floral traits in the alpine plant Solidago minuta: evidence for local optimum along an elevational gradient

High intraspecific phenotypic variation, but little evidence for local adaptation in Geum reptans populations in the Central Swiss Alps

Contact Info

Product

Resources

About