Optimal stomatal drought response shaped by competition for water and hydraulic risk can explain plant trait covariation

Optimal stomatal drought response shaped by competition for water and hydraulic risk can explain plant trait covariation

• The classical theory of stomatal optimization stipulates that stomata should act to maximize photosynthesis while minimizing transpiration. This theory, despite its remarkable success in reproducing empirical patterns, does not account for the fact that the available water to plants is dynamically...

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Bibliographic Details
Published in:The New phytologist Vol. 225; no. 3; pp. 1206 - 1217
Main Authors: Lu, Yaojie, Duursma, Remko A., Farrior, Caroline E., Medlyn, Belinda E., Feng, Xue
Format: Journal Article
Language:English
Published: England Wiley 01-02-2020
Wiley Subscription Services, Inc
Subjects:
Biological competition
Carbon
Competition
Damage
Drought
Droughts
Environmental regulations
evolutionarily stable strategy (ESS)
Gas exchange
Hydraulics
Models, Biological
Opportunity costs
Optimization
Photosynthesis
Plant Stomata - physiology
plant water competition
Rain
Rainfall
Recovery
Risk
Soil
stochastic rainfall
Stochasticity
Stomata
stomatal optimization
stomatal response to drought
Theories
Theory
trait covariation
Transpiration
Water
Water - physiology
Water availability
Xylem
Xylem - physiology
xylem cavitation and recovery
evolutionarily stable strategy (ESS)
stomatal response to drought
trait covariation
xylem cavitation and recovery
plant water competition
stomatal optimization
stochastic rainfall
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Summary:• The classical theory of stomatal optimization stipulates that stomata should act to maximize photosynthesis while minimizing transpiration. This theory, despite its remarkable success in reproducing empirical patterns, does not account for the fact that the available water to plants is dynamically regulated by plants themselves, and that plants compete for water in most locations. • Here, we develop an alternative theory in which plants maximize the expected carbon gain under stochastic rainfall in a competitive environment. We further incorporate xylem hydraulic limitation as an additional constraint to transpiration and evaluate its impacts on stomatal optimization by incorporating the direct carbon cost of xylem recovery and the opportunity cost of reduced future photosynthesis as a result of irrecoverable xylem damage. • We predict stomatal behaviour to be more conservative with a higher cost induced by xylem damage. By varying the unit carbon cost and extent of xylem recovery, characterizing the direct and opportunity cost of xylem damage, respectively, our model can reproduce several key patterns of stomatal-hydraulic trait covariations. • By addressing the key elements of water limitation in plant gas exchange simultaneously, including plants’ self-regulation of water availability, competition for water and hydraulic risk, our study provides a comprehensive theoretical basis for understanding stomatal behaviour.
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ISSN:0028-646X
1469-8137
DOI:10.1111/nph.16207