Morphological and Genetic Variation along a North-to-South Transect in Stipa purpurea, a Dominant Grass on the Qinghai-Tibetan Plateau: Implications for Response to Climate Change.

Wensheng Liu,Zhiping Song,Danhui Qi,Yin Zhou,Jianling You,Yao Zhao,Jiakuan Chen

doi:10.1371/journal.pone.0161972

Abstract

Estimating the potential of species to cope with rapid environmental climatic modifications is of vital importance for determining their future viability and conservation. The variation between existing populations along a climatic gradient may predict how a species will respond to future climate change. Stipa purpurea is a dominant grass species in the alpine steppe and meadow of the Qinghai-Tibetan Plateau (QTP). Ecological niche modelling was applied to S. purpurea, and its distribution was found to be most strongly correlated with the annual precipitation and the mean temperature of the warmest quarter. We established a north-to-south transect over 2000 km long on the QTP reflecting the gradients of temperature and precipitation, and then we estimated the morphological by sampling fruited tussocks and genetic divergence by using 11 microsatellite markers between 20 populations along the transect. Reproductive traits (the number of seeds and reproductive shoots), the reproductive-vegetative growth ratio and the length of roots in the S. purpurea populations varied significantly with climate variables. S. purpurea has high genetic diversity (He = 0.585), a large effective population size (Ne >1,000), and a considerable level of gene flow between populations. The S. purpurea populations have a mosaic genetic structure: some distant populations (over 1000 km apart) clustered genetically, whereas closer populations (< 100 km apart) had diverged significantly, suggesting local adaptation. Asymmetrical long-distance inter-population gene flow occurs along the sampling transect and might be mediated by seed dispersal via migratory herbivores, such as the chiru (Pantholops hodgsonii). These findings suggest that population performance variation and gene flow both facilitate the response of S. purpurea to climate change.

Highlights

Continuous climate change has a major impact on population persistence and species distribution [1]
We examine the morphological and genetic variation of Stipa purpurea and assess the role of gene flow and biomass allocation in explaining the population divergence of S. purpurea along the strong environmental gradients occurring in the Qinghai-Tibetan Plateau (QTP) to assess population features that may be useful to respond to climate change
The Ecological niche modelling (ENM) model showed that the mean temperature of the warmest quarter (Twarm, bio10), the annual precipitation (AP, bio12) and the precipitation of wettest quarter (Pwet, bio16) were the most influential climatic variables for S. purpurea distribution, because they explained about 54% of the variance (Fig 2)

Summary

Introduction

Continuous climate change has a major impact on population persistence and species distribution [1]. Organisms can respond to environmental changes by shifting their range or by adapting. Phenotypic plasticity enables species to survive rapidly changing local environmental conditions and persist for a longer period of time, during which evolutionary adaptation may occur [5,6,7,8]. On a longer time scale, there is the possibility that morphological modifications will occur through natural selection in response to environmental conditions, resulting in local adaptation and maintaining species persistence and integrity and adaptive population divergence [2, 3, 9,10]

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