TY - JOUR
T1 - Intraspecific trait variation in alpine plants relates to their elevational distribution
AU - Rixen, Christian
AU - Wipf, Sonja
AU - Rumpf, Sabine B.
AU - Giejsztowt, Justyna
AU - Millen, Jules
AU - Morgan, John W.
AU - Nicotra, Adrienne B.
AU - Venn, Susanna
AU - Zong, Shengwei
AU - Dickinson, Katharine J.M.
AU - Freschet, Grégoire T.
AU - Kurzböck, Claudia
AU - Li, Jin
AU - Pan, Hongli
AU - Pfund, Beat
AU - Quaglia, Elena
AU - Su, Xu
AU - Wang, Wei
AU - Wang, Xiangtao
AU - Yin, Hang
AU - Deslippe, Julie R.
N1 - Publisher Copyright:
© 2022 The Authors. Journal of Ecology published by John Wiley & Sons Ltd on behalf of British Ecological Society.
PY - 2022/4
Y1 - 2022/4
N2 - Climate warming is shifting the distributions of mountain plant species to higher elevations. Cold-adapted plant species are under increasing pressure from novel competitors that are encroaching from lower elevations. Plant capacity to adjust to these pressures may be measurable as variation in trait values within a species. In particular, the strength and patterns of intraspecific trait variation along abiotic and biotic gradients can inform us whether and how species can adjust their anatomy and morphology to persist in a changing environment. Here, we tested whether species specialized to high elevations or with narrow elevational ranges show more conservative (i.e. less variable) trait responses across their elevational distribution, or in response to neighbours, than species from lower elevations or with wider elevational ranges. We did so by studying intraspecific trait variation of 66 species along 40 elevational gradients in four countries in both hemispheres. As an indication of potential neighbour interactions that could drive trait variation, we also analysed plant species’ height ratio, its height relative to its nearest neighbour. Variation in alpine plant trait values over elevation differed depending on a species’ median elevation and the breadth of its elevational range, with species with lower median elevations and larger elevational range sizes showing greater trait variation, i.e. a steeper slope in trait values, over their elevational distributions. These effects were evidenced by significant interactions between species’ elevation and their elevational preference or range for several traits: vegetative height, generative height, specific leaf area and patch area. The height ratio of focal alpine species and their neighbours decreased in the lower part of their distribution because neighbours became relatively taller at lower elevations. In contrast, species with lower elevational optima maintained a similar height ratio with neighbours throughout their range. Synthesis. We provide evidence that species from lower elevations and those with larger range sizes show greater intraspecific trait variation, which may indicate a greater ability to respond to environmental changes. Also, larger trait variation of species from lower elevations may indicate stronger competitive ability of upslope shifting species, posing one further threat to species from higher ranges.
AB - Climate warming is shifting the distributions of mountain plant species to higher elevations. Cold-adapted plant species are under increasing pressure from novel competitors that are encroaching from lower elevations. Plant capacity to adjust to these pressures may be measurable as variation in trait values within a species. In particular, the strength and patterns of intraspecific trait variation along abiotic and biotic gradients can inform us whether and how species can adjust their anatomy and morphology to persist in a changing environment. Here, we tested whether species specialized to high elevations or with narrow elevational ranges show more conservative (i.e. less variable) trait responses across their elevational distribution, or in response to neighbours, than species from lower elevations or with wider elevational ranges. We did so by studying intraspecific trait variation of 66 species along 40 elevational gradients in four countries in both hemispheres. As an indication of potential neighbour interactions that could drive trait variation, we also analysed plant species’ height ratio, its height relative to its nearest neighbour. Variation in alpine plant trait values over elevation differed depending on a species’ median elevation and the breadth of its elevational range, with species with lower median elevations and larger elevational range sizes showing greater trait variation, i.e. a steeper slope in trait values, over their elevational distributions. These effects were evidenced by significant interactions between species’ elevation and their elevational preference or range for several traits: vegetative height, generative height, specific leaf area and patch area. The height ratio of focal alpine species and their neighbours decreased in the lower part of their distribution because neighbours became relatively taller at lower elevations. In contrast, species with lower elevational optima maintained a similar height ratio with neighbours throughout their range. Synthesis. We provide evidence that species from lower elevations and those with larger range sizes show greater intraspecific trait variation, which may indicate a greater ability to respond to environmental changes. Also, larger trait variation of species from lower elevations may indicate stronger competitive ability of upslope shifting species, posing one further threat to species from higher ranges.
KW - climate change
KW - cold-adapted plants
KW - elevation gradient
KW - elevation range
KW - neighbour interactions
KW - plant traits
KW - species distribution
UR - http://www.scopus.com/inward/record.url?scp=85125201313&partnerID=8YFLogxK
U2 - 10.1111/1365-2745.13848
DO - 10.1111/1365-2745.13848
M3 - Article
SN - 0022-0477
VL - 110
SP - 860
EP - 875
JO - Journal of Ecology
JF - Journal of Ecology
IS - 4
ER -