Reductions in tree performance during hotter droughts are mitigated by shifts in nitrogen cycling

Climate warming should result in hotter droughts of unprecedented severity in this century. Such droughts have been linked with massive tree mortality, and data suggest that warming interacts with drought to aggravate plant performance. Yet how forests will respond to hotter droughts remains unclear...

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Published in:Plant, cell and environment cell and environment, 2018-11, Vol.41 (11), p.2627-2637
Main Authors: Grossiord, Charlotte, Gessler, Arthur, Reed, Sasha C., Borrego, Isaac, Collins, Adam D., Dickman, Lee T., Ryan, Max, Schönbeck, Leonie, Sevanto, Sanna, Vilagrosa, Alberto, McDowell, Nate G.
Format: Article
Language:English
Subjects:
15N
acclimation
BASIC BIOLOGICAL SCIENCES
Biological Science
Carbon
Carbon - metabolism
Climate change
Cycles
Dehydration
Drought
Droughts
Earth Sciences
Environmental impact
ENVIRONMENTAL SCIENCES
forest ecosystems
Forests
Global warming
Hot Temperature
Juniperus - metabolism
Juniperus - physiology
Juniperus monosperma
Nitrogen
Nitrogen - metabolism
nitrogen allocation
Nitrogen cycle
Nitrogen Cycle - physiology
Pinus - metabolism
Pinus - physiology
Pinus edulis
Trees
Trees - metabolism
Trees - physiology
warming
Water balance
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Summary:Climate warming should result in hotter droughts of unprecedented severity in this century. Such droughts have been linked with massive tree mortality, and data suggest that warming interacts with drought to aggravate plant performance. Yet how forests will respond to hotter droughts remains unclear, as does the suite of mechanisms trees use to deal with hot droughts. We used an ecosystem‐scale manipulation of precipitation and temperature on piñon pine (Pinus edulis) and juniper (Juniperus monosperma) trees to investigate nitrogen (N) cycling‐induced mitigation processes related to hotter droughts. We found that while negative impacts on plant carbon and water balance are manifest after prolonged drought, performance reductions were not amplified by warmer temperatures. Rather, increased temperatures for 5 years stimulated soil N cycling under piñon trees and modified tree N allocation for both species, resulting in mitigation of hotter drought impacts on tree water and carbon functions. These findings suggest that adjustments in N cycling are likely after multi‐year warming conditions and that such changes may buffer reductions in tree performance during hotter droughts. The results highlight our incomplete understanding of trees' ability to acclimate to climate change, raising fundamental questions about the resistance potential of forests to long‐term, compound climatic stresses. Climate warming should result in hotter droughts of unprecedented severity in this century. Yet how forests will respond to hotter droughts remains unclear, as does the suite of mechanisms trees use to deal with hot droughts. We used an ecosystem‐scale manipulation of precipitation and temperature on piñon pine (Pinus edulis) and juniper (Juniperus monosperma) trees to investigate nitrogen (N) cycling‐induced mitigation processes related to hotter droughts. We found that although negative impacts on plant carbon and water balance are manifest after prolonged drought, performance reductions were not amplified by warmer temperatures. Rather, increased temperatures stimulated soil N cycling under piñon trees and modified tree N allocation for both species, resulting in mitigation of hotter drought impacts on tree water and carbon functions. These findings suggest that adjustments in N cycling are likely after multiyear warming conditions and that such changes may buffer reductions in tree performance during hotter droughts.
ISSN:0140-7791
1365-3040
DOI:10.1111/pce.13389