Trait differentiation and adaptation of plants along elevation gradients

Halbritter, Aud H.; Fior, Simone; Keller, Irene; Billeter, Regula; Edwards, Peter J.; Holderegger, Rolf; Karrenberg, Sophie; Pluess, Andrea R.; Widmer, Alex; Alexander, Jake M.

doi:10.1111/jeb.13262

Cited by 153 publications

(180 citation statements)

References 101 publications

(153 reference statements)

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“…We acknowledge that these metrics vary largely depending on the individuals, species and study under consideration; however, these metrics were all measured as indicators of plant reproductive output along elevations (see e.g. Halbritter et al, 2018). We only included leaf size values when it was reported as the area of the leaf (m 2 ), excluding leaf diameter, length or width.…”

Section: Methodsmentioning

confidence: 99%

“…Despite recent syntheses involving transplant and common‐garden experiments to elucidate patterns of plant performance and adaptation change along environmental gradients (Halbritter et al, 2018; Leimu & Fischer, 2008; Pulido et al, 2019), little efforts have been payed to summarize recent literature on the intraspecific responses along elevation across multiple reciprocal transplant experiments. Only Halbritter et al (2018) to our knowledge, reported a systematic review including transplant experiments across elevations showing significant evidence of higher biomass and survival in local individuals compared with foreign ones. However, their analysis on reciprocal transplants did not disentangle climatic variation (in temperature and precipitation) along elevation across transplant sites and focused on 22 species and 14 reciprocal transplant experiment studies available up to 2015.…”

Section: Introductionmentioning

confidence: 99%

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Plant performance and survival across transplant experiments depend upon temperature and precipitation change along elevation

Midolo

Wellstein

2020

Journal of Ecology

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Understanding how plant individuals perform in non‐local sites is key in the context of contemporary range shifts along elevation. Transplant experiments conducted in mountain ecosystems are rising as key tools to measure the intraspecific response of individuals transplanted across contrasting elevations. However, a synthesis quantifying patterns of plant performance in response to changes in abiotic factors across different species and mountain ranges is still lacking. We conducted a meta‐analysis to quantitatively summarize patterns of plant species' performance variation in response to changes in temperature and precipitation within their elevation range across multiple transplant experiment studies. We compiled a dataset obtained from 38 studies and 49 vascular plant species in total addressing intraspecific performance variation in terms of survival, germination, biomass, height, number of vegetative organs, number of reproductive units, SLA and leaf size. We both compared pairs of transplanted individuals to those growing at their site of origin (‘away vs. home’) and to the local individuals found at the site of transplant (‘foreign vs. local’). Overall, individuals transplanted downward showed larger biomass and height compared to their site of origin but failed to adjust these traits and survival to that of local individuals. Individuals transplanted upward adjusted their traits by decreasing plant growth and number of reproductive units to that of local individuals but showed lower survival. Importantly, changes in survival, biomass, height, leaf size, number of vegetative organs and reproductive units increased linearly with the difference in mean annual temperature between site of transplant and site of origin in the ‘away vs. home’ comparison. Conversely, changes in biomass, leaf size, number of vegetative organs and reproductive units increased with mean annual precipitation difference between sites in the ‘foreign vs. local’ comparison. Synthesis. We detected common trends in survival and intraspecific trait variation across different species and transplant experiments conducted along elevational gradients. Because plasticity and adaptation play a crucial role in plant shift, establishment and persistence under non‐local environmental conditions, our meta‐analysis contributes to better understand how rapid plant shifts are constrained by climatic conditions within species' elevational range.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Plant performance and survival across transplant experiments depend upon temperature and precipitation change along elevation

Midolo

Wellstein

2020

Journal of Ecology

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“…Alternatively, drift, divergent selection to locally-specific conditions and/or limited variation in the source populations would lead to regionally specific patterns of foothill-alpine differentiation (3). Independently of the region of origin, alpine A. arenosa populations exhibited consistently shorter stems and larger flowers demonstrating parallelism in typical traits associated with 'alpine syndrome' that are considered adaptive in alpine environments (25,50). Elevation gradients belong to the most frequently studied environmental gradients in plant evolutionary ecology since the rise of this field (51,52), however, cases of phenotypic parallelism demonstrated by a combination of genetic and experimental data are still very rare in plant literature (53).…”

Section: Parallel Ecotypic Differentiationmentioning

confidence: 99%

Parallel alpine differentiation inArabidopsis arenosa

Knotek

Konečná

Wos

et al. 2020

Preprint

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Parallel evolution provides powerful natural experiments for studying repeatability of evolution. Well-documented examples from plants are, however, still rare, as are inquiries of mechanisms driving convergence in some traits while divergence in others. Arabidopsis arenosa, a predominantly foothill species with scattered morphologically distinct alpine occurrences is a promising candidate. Yet, the hypothesis of parallelism remained untested. We sampled foothill and alpine populations in all regions known to harbour the alpine ecotype and used SNP genotyping to test for repeated alpine colonisation. Then, we combined field surveys and a common garden experiment to quantify phenotypic parallelism. Genetic clustering by region but not elevation and coalescent simulations demonstrated parallel origin of alpine ecotype in four mountain regions. Alpine populations exhibited parallelism in height and floral traits which persisted after two generations in cultivation. In contrast, leaf traits were distinctive only in certain region(s), reflecting a mixture of plasticity and genetically determined non-parallelism. We demonstrate varying degrees and causes of parallelism and nonparallelism across populations and traits within a plant species. Parallel divergence along a sharp elevation gradient makes A. arenosa a promising candidate for studying genomic basis of adaptation.

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“…Fine-scale environmental variation has frequently been associated with high levels of adaptive phenotypic variation. In particular, the highly heterogeneous landscapes from mountain ranges provide ample opportunity for adaptive radiation at fine spatial scales (Halbritter et al 2018; Waterhouse et al 2018). Moreover, high-altitudinal secondary valleys and cold air sinks typical of topographically complex landscapes designate topographical factors other than altitude as contributing determinants of temperature and soil moisture levels (Körner 2007; Günther et al 2016; O’Brien et al 2017; Pfennigwerth et al 2017).…”

Section: Introductionmentioning

confidence: 99%

Pre-adaptation to climate change through topography-driven evolution of traits and their plasticity

Kort

Panis

Janssens

et al. 2019

Preprint

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Climate change is expected to increase the level of drought stress experienced by many plant populations, yet the spatial distribution of changes in dryness remains highly uncertain. Species can, to some extent, adapt to climate uncertainty through evolving increased trait plasticity. Biodiversity conservation could capitalize on such natural variation in the ability of populations to cope with climate variability. Yet, disentangling evolution of trait means vs. trait plasticity is challenging, as it requires a sampling design with genetic replicates grown under distinct environmental conditions. Here, we applied different soil moisture treatments to clones of Fragaria vesca plants that were raised from seeds that were sampled in distinct mountainous topographical settings, to study adaptive trait and plasticity divergence in response to drought. We demonstrate that various fitness traits evolved along topographical gradients, including increased specific leaf area (SLA) with increasing slope, and increased growth plasticity with increasing altitude. Our results indicate that traits and their plasticity can evolve independently in response to distinct topographical stressors. We further show that trait heritability varies considerably among traits and topographical settings. Heritability of phenotypic plasticity tended to increase with altitude for all traits, with populations from high altitudes harboring more than twice the heritability for growth and SLA plasticity compared to populations from low altitudes. We conclude that (i) low altitudinal populations, which are expected to be least vulnerable to climate change, may only withstand limited increases in drought stress, while (ii) populations that evolved to thrive under more heterogeneous mountain conditions are pre-adapted to climate change through high plasticity and heritability. Highly heterogeneous landscapes may thus represent invaluable sources of quantitative genetic variation that could support conservation under climate change across the globe.

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Trait differentiation and adaptation of plants along elevation gradients

Cited by 153 publications

References 101 publications

Plant performance and survival across transplant experiments depend upon temperature and precipitation change along elevation

Plant performance and survival across transplant experiments depend upon temperature and precipitation change along elevation

Parallel alpine differentiation inArabidopsis arenosa

Pre-adaptation to climate change through topography-driven evolution of traits and their plasticity

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