Climate warming may increase the frequency of cold-adapted haplotypes in alpine plants

Johannes Wessely,Dietmar Moser,Günther Klonner,Frédéric Guillaume,Karl Hülber,Andreas Gattringer,Stefan Dullinger

doi:10.1038/s41558-021-01255-8

Johannes Wessely, Dietmar Moser + Show 5 more

Open Access

https://doi.org/10.1038/s41558-021-01255-8

Copy DOI

Abstract

Modelling of climate-driven range shifts commonly treats species as ecologically homogeneous units. However, many species show intraspecific variation of climatic niches and theory predicts that such variation may lead to counterintuitive eco-evolutionary dynamics. Here, we incorporate assumed intraspecific niche variation into a dynamic range model and explore possible consequences for six high-mountain plant species of the European Alps under scenarios of twenty-first century climate warming. At the species level, the results indicate massive range loss independent of intraspecific variation. At the intraspecific level, the model predicts a decrease in the frequency of warm-adapted haplotypes in five species. The latter effect is probably driven by a combination of leading-edge colonization and priority effects within the species’ elevational range and was weakest when leading-edge expansion was constrained by mountain topography The resulting maladaptation may additionally increase the risk that alpine plants face from shrinkage of their ranges in a warming climate.

Highlights

Modelling of climate-driven range shifts commonly treats species as ecologically homogeneous units
Among the most widespread simplifications inherent to most modelling studies is the interpretation of climatic niches as traits characteristic of species as a whole
Theory suggests that intraspecific variation in climatic niches may result in maladaptation of migrating populations under climate change as a consequence of leading-edge colonization and founder effects[18,19,20]

Summary

Introduction

Modelling of climate-driven range shifts commonly treats species as ecologically homogeneous units. Evaluating the scale and impact of these processes on the response of species to twenty-first century climate warming requires models that integrate the inheritance of genetically determined individual niche variation with simulations of demographic and dispersal processes.

Results

Conclusion