Trait variation along elevation gradients in a dominant woody shrub is population-specific and driven by plasticity.

Alix A Pfennigwerth,Jennifer A Schweitzer,Joseph K Bailey

doi:10.1093/aobpla/plx027

Alix A Pfennigwerth, Jennifer A Schweitzer + Show 1 more

Open Access

https://doi.org/10.1093/aobpla/plx027

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Journal: AoB PLANTS	Publication Date: Jun 19, 2017
Citations: 39	License type: cc-by

Affiliation: University of Tennessee at Knoxville

Abstract

Elevation gradients are frequently used as space-for-time substitutions to infer species' trait responses to climate change. However, studies rarely investigate whether trait responses to elevation are widespread or population-specific within a species, and the relative genetic and plastic contributions to such trait responses may not be well understood. Here, we examine plant trait variation in the dominant woody shrub, Rhododendron maximum, along elevation gradients in three populations in the South Central Appalachian Mountains, USA, in both field and common garden environments. We ask the following: (i) do plant traits vary along elevation? (ii) do trait responses to elevation differ across populations, and if so, why? and (iii) does genetic differentiation or phenotypic plasticity drive trait variation within and among populations? We found that internode length, shoot length, leaf dry mass, and leaf area varied along elevation, but that these responses were generally unique to one population, suggesting that trait responses to environmental gradients are population-specific. A common garden experiment identified no genetic basis to variation along elevation or among populations in any trait, suggesting that plasticity drives local and regional trait variation and may play a key role in the persistence of plant species such as R. maximum with contemporary climate change. Overall, our findings highlight the importance of examining multiple locations in future elevation studies and indicate that, for a given plant species, the magnitude of trait responses to global climate change may vary by location.

Highlights

Contemporary climate change is altering the availability of resources and habitats critical to plant performance (Parmesan and Yohe 2003)
We addressed three questions: (i) do plant traits vary along elevation gradients? (ii) does trait variation along elevation differ among populations, and if so, why? and (iii) does genetic divergence or phenotypic plasticity drive trait variation within and among populations? To address the first question, we examined variation in eight quantitative leaf, stem, and phenology traits in three R. maximum populations occurring along geographically distinct elevation gradients
We addressed the second question by exploring the relative importance of five climatic, edaphic, and topographic variables on trait variation within and among populations and predicted that the magnitude of trait responses to elevation varies across populations due to environmental

Summary

Introduction

Contemporary climate change is altering the availability of resources and habitats critical to plant performance (Parmesan and Yohe 2003). In a rapidly changing climate, the ability of a plant species to acclimate via phenotypic plasticity or undergo genetic change will play a key role in that species’ persistence (Walther et al 2002; Franks et al 2014; Nicotra et al 2015). Examining how a plant species’ traits respond plastically or genetically to existing climatic gradients is critical for understanding and predicting whether and how plants may persist in situ despite a changing climate (Chevin and Lande 2010; Nicotra et al 2010; Anderson and Gezon 2015).

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