TY - JOUR
T1 - Acclimation of thermal tolerance in juvenile plants from three biomes is suppressed when extremes co-occur
AU - Harris, Rosalie J.
AU - Alvarez, Philippa R.
AU - Bryant, Callum
AU - Briceño, Verónica F.
AU - Cook, Alicia M.
AU - Leigh, Andrea
AU - Nicotra, Adrienne B.
N1 - Publisher Copyright:
© The Author(s) 2024.
PY - 2024/5/22
Y1 - 2024/5/22
N2 - Given the rising frequency of thermal extremes (heatwaves and cold snaps) due to climate change, comprehending how a plant’s origin affects its thermal tolerance breadth (TTB) becomes vital. We studied juvenile plants from three biomes: temperate coastal rainforest, desert and alpine. In controlled settings, plants underwent hot days and cold nights in a factorial design to examine thermal tolerance acclimation. We assessed thermal thresholds (Tcrit-hot and Tcrit-cold) and TTB. We hypothesized that (i) desert species would show the highest heat tolerance, alpine species the greatest cold tolerance and temperate species intermediate tolerance; (ii) all species would increase heat tolerance after hot days and cold tolerance after cold nights; (iii) combined exposure would broaden TTB more than individual conditions, especially in desert and alpine species. We found that biome responses were minor compared to the responses to the extreme temperature treatments. All plants increased thermal tolerance in response to hot 40◦C days (Tcrit-hot increased by ∼3.5◦C), but there was minimal change in Tcrit-cold in response to the cold −2◦C nights. In contrast, when exposed to both hot days and cold nights, on average, plants exhibited an antagonistic response in TTB, where cold tolerance decreased and heat tolerance was reduced, and so we did not see the bi-directional expansion we hypothesized. There was, however, considerable variation among species in these responses. As climate change intensifies, plant communities, especially in transitional seasons, will regularly face such temperature swings. Our results shed light on potential plant responses under these extremes, emphasizing the need for deeper species-specific thermal acclimation insights, ultimately guiding conservation efforts.
AB - Given the rising frequency of thermal extremes (heatwaves and cold snaps) due to climate change, comprehending how a plant’s origin affects its thermal tolerance breadth (TTB) becomes vital. We studied juvenile plants from three biomes: temperate coastal rainforest, desert and alpine. In controlled settings, plants underwent hot days and cold nights in a factorial design to examine thermal tolerance acclimation. We assessed thermal thresholds (Tcrit-hot and Tcrit-cold) and TTB. We hypothesized that (i) desert species would show the highest heat tolerance, alpine species the greatest cold tolerance and temperate species intermediate tolerance; (ii) all species would increase heat tolerance after hot days and cold tolerance after cold nights; (iii) combined exposure would broaden TTB more than individual conditions, especially in desert and alpine species. We found that biome responses were minor compared to the responses to the extreme temperature treatments. All plants increased thermal tolerance in response to hot 40◦C days (Tcrit-hot increased by ∼3.5◦C), but there was minimal change in Tcrit-cold in response to the cold −2◦C nights. In contrast, when exposed to both hot days and cold nights, on average, plants exhibited an antagonistic response in TTB, where cold tolerance decreased and heat tolerance was reduced, and so we did not see the bi-directional expansion we hypothesized. There was, however, considerable variation among species in these responses. As climate change intensifies, plant communities, especially in transitional seasons, will regularly face such temperature swings. Our results shed light on potential plant responses under these extremes, emphasizing the need for deeper species-specific thermal acclimation insights, ultimately guiding conservation efforts.
KW - Chlorophyll fluorescence
KW - cold tolerance
KW - common conditions
KW - heat tolerance
KW - plant communities
KW - PSII
UR - http://www.scopus.com/inward/record.url?scp=85194081557&partnerID=8YFLogxK
U2 - 10.1093/conphys/coae027
DO - 10.1093/conphys/coae027
M3 - Article
AN - SCOPUS:85194081557
SN - 2051-1434
VL - 12
JO - Conservation Physiology
JF - Conservation Physiology
IS - 1
M1 - coae027
ER -