Intraspecific Trait Variation and Phenotypic Plasticity Mediate Alpine Plant Species Response to Climate Change

Henn, Jonathan J.; Buzzard, Vanessa; Enquist, Brian J.; Halbritter, Aud H.; Klanderud, Kari; Maitner, Brian S.; Michaletz, Sean T.; Pötsch, Christine; Seltzer, Lorah; Telford, Richard J.; Yang, Yan; Zhang, Li; Vandvik, Vigdis

doi:10.3389/fpls.2018.01548

Cited by 162 publications

(174 citation statements)

References 67 publications

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“…With a review of common garden experiments, Read et al (2014) found that genetic differentiation often explains a significant amount of intraspecific variation in LMA, Nmass and Narea among populations at different elevations and latitudes. However, few common garden experiments have recently highlighted the role of phenotypic plasticity to strongly mediate intraspecific plant traits' variation along elevation (Anderson & Gezon, 2015;Henn et al, 2018;Lajoie & Vellend, 2018).…”

Section: It Remains Uncertain Whether Trait Variation Across Elevationsmentioning

confidence: 99%

Global patterns of intraspecific leaf trait responses to elevation

Midolo

Frenne

Hölzel

et al. 2019

Global Change Biology

107

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Elevational gradients are often used to quantify how traits of plant species respond to abiotic and biotic environmental variations. Yet, such analyses are frequently restricted spatially and applied along single slopes or mountain ranges. Since we know little on the response of intraspecific leaf traits to elevation across the globe, we here perform a global meta‐analysis of leaf traits in 109 plant species located in 4 continents and reported in 71 studies published between 1983 and 2018. We quantified the intraspecific change in seven morpho‐ecophysiological leaf traits along global elevational gradients: specific leaf area (SLA), leaf mass per area (LMA), leaf area (LA), nitrogen concentration per unit of area (Narea), nitrogen concentration per unit mass (Nmass), phosphorous concentration per unit mass (Pmass) and carbon isotope composition (δ13C). We found LMA, Narea, Nmass and δ13C to significantly increase and SLA to decrease with increasing elevation. Conversely, LA and Pmass showed no significant pattern with elevation worldwide. We found significantly larger increase in Narea, Nmass, Pmass and δ13C with elevation in warmer regions. Larger responses to increasing elevation were apparent for SLA of herbaceous compared to woody species, but not for the other traits. Finally, we also detected evidences of covariation across morphological and physiological traits within the same elevational gradient. In sum, we demonstrate that there are common cross‐species patterns of intraspecific leaf trait variation across elevational gradients worldwide. Irrespective of whether such variation is genetically determined via local adaptation or attributed to phenotypic plasticity, the leaf trait patterns quantified here suggest that plant species are adapted to live on a range of temperature conditions. Since the distribution of mountain biota is predominantly shifting upslope in response to changes in environmental conditions, our results are important to further our understanding of how plants species of mountain ecosystems adapt to global environmental change.

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Section: It Remains Uncertain Whether Trait Variation Across Elevationsmentioning

confidence: 99%

Global patterns of intraspecific leaf trait responses to elevation

Midolo

Frenne

Hölzel

et al. 2019

Global Change Biology

107

View full text Add to dashboard Cite

show abstract

“…Plant species can display high intraspecific trait variation (ITV) under different growing conditions, reflecting heritable genetic variation and phenotypic plasticity (Henn et al, ). The variations between populations may be attributed to the differences in the selective pressures imposed by different ecological environments (Still, Kim, & Aoyama, ).…”

Section: Introductionmentioning

confidence: 99%

Will the climate of plant origins influence the chemical profiles of cuticular waxes on leaves of Leymus chinensis in a common garden experiment?

Hou

et al. 2019

Ecology and Evolution

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Cuticular wax covering the leaf surface plays important roles in protecting plants from biotic and abiotic stresses. Understanding the way in which plant leaf cuticles reflect their growing environment could give an insight into plant resilience to future climate change. Here, we analyzed the variations of cuticular waxes among 59 populations of Leymus chinensis in a common garden experiment, aiming to verify how environmental conditions influence the chemical profiles of cuticular waxes. In total, eight cuticular wax classes were identified, including fatty acids, aldehydes, primary alcohols, alkanes, secondary alcohols, ketones, β-diketones, and alkylresorcinols, with β-diketones the predominant compounds in all populations (averaged 67.36% across all populations). Great intraspecific trait variations (ITV) were observed for total wax coverage, wax compositions, and the relative abundance of homologues within each wax class. Cluster analysis based on wax characteristics could separate 59 populations into different clades. However, the populations could not be separated according to their original longitudes, latitudes, annual temperature, or annual precipitation. Redundancy analysis showed that latitude, arid index, and the precipitation from June to August were the most important parameters contributing to the variations of the amount of total wax coverage and wax composition and the relative abundance of wax classes. Pearson's correlation analysis further indicated that the relative abundance of wax classes, homologues in each wax class, and even isomers of certain compound differed in their responses to environmental factors. These results suggested that wax deposition patterns of L. chinensis populations formed during adaptations to their long-term growing environments could inherit in their progenies and exhibit such inheritance even these progenies were exported to new environments. K E Y W O R D S adaptation, common garden experiment, intraspecific trait variation, leaf wax, Leymus chinensis

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“…Recently, lots of studies have highlighted the importance of intraspecific trait variation (including phenotypic plasticity and genetic variation among populations) for plants in response to environmental change and for maintaining community stability (Henn et al, ; Lajoie & Vellend, ; Nicotra et al, ; Violle et al, ). However, the plasticity of functional traits in response to different water conditions was low in our study relative to studies conducted on other flora (Sadras & Trentacoste, ), and no significant correlation was observed between the plasticity and the biomass for all species.…”

Section: Discussionmentioning

confidence: 99%

Section: Plastic Responses To Soil Water Availabilitymentioning

confidence: 99%

Trait means predict performance under water limitation better than plasticity for seedlings of Poaceae species on the eastern Tibetan Plateau

Zhou

2020

Ecology and Evolution

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Water availability may be altered by changes in precipitation under global climate change in alpine areas. Trait means and plasticity are important for plants in response to a changing environment. In an examination of alpine plant responses to changed water availability, and for determination of how trait means and plasticity predict the performance (e.g., biomass) of these species, seeds of ten Poaceae species from the eastern Tibetan Plateau were sown and grown in a manipulated environment during a growing season in which rainfall was removed and other climate conditions remained unchanged. Growth and leaf traits of these species were measured. We found significant effects of moderate water stress on the seedling biomass of these species; however, the responses of these species to changed water condition were strongly dependent on species identity. For example, the biomass of some species significantly decreased under moderate drought, whereas that of others were either significantly increased or unaffected. This pattern was also observed for growth and leaf traits. Overall, the alpine Poaceae species showed low plasticity of traits in response to water availability relative to reports from other areas. Notably, the results show that trait means were better correlated with the productivity than with the plasticity of traits; thus, we argue that the trait means were better predictors of performance than plasticity for alpine Poaceae species. Poaceae species in alpine areas are important for forage production and for water catchment health worldwide, and these species may face water shortage because of current and future climate change. Understanding the response of alpine Poaceae species to water availability would facilitate our ability to predict the impacts of climate change on the alpine vegetation.

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Intraspecific Trait Variation and Phenotypic Plasticity Mediate Alpine Plant Species Response to Climate Change

Cited by 162 publications

References 67 publications

Global patterns of intraspecific leaf trait responses to elevation

Global patterns of intraspecific leaf trait responses to elevation

Will the climate of plant origins influence the chemical profiles of cuticular waxes on leaves of Leymus chinensis in a common garden experiment?

Trait means predict performance under water limitation better than plasticity for seedlings of Poaceae species on the eastern Tibetan Plateau

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