Intraspecific Functional Trait Responses to Experimental Warming Vary With Precipitation and Growth Form
Publikation: Beiträge in Zeitschriften › Zeitschriftenaufsätze › Forschung › begutachtet
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in: Journal of Vegetation Science, Jahrgang 36, Nr. 6, e70098, 01.11.2025.
Publikation: Beiträge in Zeitschriften › Zeitschriftenaufsätze › Forschung › begutachtet
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TY - JOUR
T1 - Intraspecific Functional Trait Responses to Experimental Warming Vary With Precipitation and Growth Form
AU - Erkelenz, Joshua
AU - Geange, Sonya R.
AU - Atkinson, Joe
AU - Anderson, Emil
AU - Correia, Marta
AU - Ahler, Sam J.
AU - Bradler, Pia
AU - Löwenstein, Cora E.
AU - Elsy, Alexander
AU - Maré, Celesté
AU - Eshelman, Susan
AU - Mauki, Dickson
AU - Guclu, Coskun
AU - Eckberg, Julia
AU - Maitner, Brian
AU - Gya, Ragnhild
AU - Töpper, Joachim
AU - Klanderud, Kari
AU - Enquist, Brian J.
AU - Michaletz, Sean T.
AU - Ray, Courtenay A.
AU - von Oppen, Jonathan
AU - Cubino, Josep Padullés
AU - Halbritter, Aud H.
AU - Vandvik, Vigdis
N1 - Publisher Copyright: © 2025 International Association for Vegetation Science.
PY - 2025/11/1
Y1 - 2025/11/1
N2 - Aims: Rising ambient air temperatures may have adverse effects on alpine plant communities. To avoid extinction and to mitigate the demographic impacts of climate warming, migration and the ability to adapt become increasingly important. Experimental studies that simulate warming help test the extent and direction of functional adaptation. We ask: (1) To what extent does experimental warming drive intraspecific trait shifts in alpine species? (2) Do these trait responses vary across a precipitation gradient? (3) Do responses vary between forbs and graminoids?. Location: Alpine grasslands along a precipitation gradient in south-western Norway. Methods: At three alpine sites spanning 1315–3601 mm of annual precipitation, we measured 10 plant functional traits across 17 species of graminoids, perennial forbs and dwarf shrubs. We compared the traits of plants in open-top warming chambers with those under ambient temperature conditions. Effect sizes were estimated using Cohen's d and analysed with respect to precipitation regimes and growth form. Results: Plant height generally increased in response to warming across all sites for both growth forms. For other traits, warming effects were context-dependent and varied among species. At the medium precipitation site, plants showed shifts toward more conservative resource-use strategies in response to warming, characterised by increased leaf area and leaf dry matter content, along with reduced species leaf area and leaf nitrogen concentration. The enrichment in heavier nitrogen and carbon isotopes with warming is consistent with the expectation that warming selects for individuals with high water-use efficiency. Forbs generally exhibited stronger but more variable responses to warming than graminoids. Conclusion: Warming induces trait shifts in alpine species, but responses depend on local conditions and growth form. Predicting alpine community responses to climate change requires trait-based approaches and research designs that allow assessing and exploring patterns in both taxonomic and environmental context dependencies.
AB - Aims: Rising ambient air temperatures may have adverse effects on alpine plant communities. To avoid extinction and to mitigate the demographic impacts of climate warming, migration and the ability to adapt become increasingly important. Experimental studies that simulate warming help test the extent and direction of functional adaptation. We ask: (1) To what extent does experimental warming drive intraspecific trait shifts in alpine species? (2) Do these trait responses vary across a precipitation gradient? (3) Do responses vary between forbs and graminoids?. Location: Alpine grasslands along a precipitation gradient in south-western Norway. Methods: At three alpine sites spanning 1315–3601 mm of annual precipitation, we measured 10 plant functional traits across 17 species of graminoids, perennial forbs and dwarf shrubs. We compared the traits of plants in open-top warming chambers with those under ambient temperature conditions. Effect sizes were estimated using Cohen's d and analysed with respect to precipitation regimes and growth form. Results: Plant height generally increased in response to warming across all sites for both growth forms. For other traits, warming effects were context-dependent and varied among species. At the medium precipitation site, plants showed shifts toward more conservative resource-use strategies in response to warming, characterised by increased leaf area and leaf dry matter content, along with reduced species leaf area and leaf nitrogen concentration. The enrichment in heavier nitrogen and carbon isotopes with warming is consistent with the expectation that warming selects for individuals with high water-use efficiency. Forbs generally exhibited stronger but more variable responses to warming than graminoids. Conclusion: Warming induces trait shifts in alpine species, but responses depend on local conditions and growth form. Predicting alpine community responses to climate change requires trait-based approaches and research designs that allow assessing and exploring patterns in both taxonomic and environmental context dependencies.
KW - Alpine communities
KW - climate change adaptation
KW - environmental filtering
KW - global warming
KW - high-latitudes
KW - plasticity
KW - resilience
KW - Biology
UR - http://www.scopus.com/inward/record.url?scp=105026660306&partnerID=8YFLogxK
U2 - 10.1111/jvs.70098
DO - 10.1111/jvs.70098
M3 - Journal articles
AN - SCOPUS:105026660306
VL - 36
JO - Journal of Vegetation Science
JF - Journal of Vegetation Science
SN - 1100-9233
IS - 6
M1 - e70098
ER -