Abstract
Phenotypic plasticity is important for species responses to global change and species coexistence. Phenotypic plasticity differs among species and traits and changes across environments. Here, we investigated phenotypic plasticity of the widespread grass Arrhenatherum elatius in response to winter warming and frost stress by comparing phenotypic plasticity of 11 geographically and environmentally distinct populations of this species to phenotypic plasticity of populations of different species originating from a single environment. The variation in phenotypic plasticity was similar for populations of a single species from different locations compared to populations of functionally and taxonomically diverse species from one environment for the studied traits (leaf biomass production and root integrity after frost) across three indices of phenotypic plasticity (RDPI, PIN, slope of reaction norm). Phenotypic plasticity was not associated with neutral genetic diversity but closely linked to the climate of the populations’ origin. Populations originating from warmer and more variable climates showed higher phenotypic plasticity. This indicates that phenotypic plasticity can itself be considered as a trait subject to local adaptation to climate. Finally, our data emphasize that high phenotypic plasticity is not per se positive for adaptation to climate change, as differences in stress responses are resulting in high phenotypic plasticity as expressed by common plasticity indices, which is likely to be related to increased mortality under stress in more plastic populations.
Highlights
Phenotypic plasticity, that is, the capacity of a genotype to realize different phenotypic values for a given trait under altered environ‐ mental conditions (Valladares, Sanchez‐Gomez, & Zavala, 2006), is of high interest in ecological and evolutionary research for improv‐ ing the understanding of species coexistence (Turcotte & Levine, 2016) and responses to global change (Merila & Hendry, 2014)
Based on morphological and physiological differences, one would expect a higher variation in phenotypic plasticity among het‐ erospecific populations rather than among conspecific populations
Traits under selec‐ tive pressure and related to stress response may be as vari‐ able within a given species, that is, for populations originating from different environments, as between species if the populations for all species stem from the same environment (Des Roches et al, 2018; Malyshev et al, 2016; Poirier, Durand, & Volaire, 2012)
Summary
Previous studies on A. elatius found high phenotypic and genetic variability for quantitative traits (Mahmoud, Grime, & Furness, 1975; Petit & Thompson, 1998) and differentiation across spatial scales (Kreyling et al, 2012; Petit & Thompson, 1998) We expand these studies by linking phenotypic plasticity to genetic diversity and to climatic origin of the populations. We hypothesized that (a) conspecific variation in phenotypic plasticity (across popula‐ tions originating from different locations) is high as hetero‐ specific variation in phenotypic plasticity (different species from one location) for stress‐related traits presumably under selection, that is, leaf biomass production and root integrity after frost stress. We hypothesized, given that plasticity has costs, (DeWitt et al, 1998) that (c) the most plastic populations have the highest mortality under stress
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