URFM, INRA, 84000, Avignon, France.
BIOGECO, INRA, Univ. Bordeaux, 33615, Pessac, France.
Ecol Lett. 2017 Nov;20(11):1437-1447. doi: 10.1111/ele.12851. Epub 2017 Sep 18.
Stomata play a significant role in the Earth's water and carbon cycles, by regulating gaseous exchanges between the plant and the atmosphere. Under drought conditions, stomatal control of transpiration has long been thought to be closely coordinated with the decrease in hydraulic capacity (hydraulic failure due to xylem embolism). We tested this hypothesis by coupling a meta-analysis of functional traits related to the stomatal response to drought and embolism resistance with simulations from a soil-plant hydraulic model. We report here a previously unreported phenomenon: the existence of an absolute limit by which stomata closure must occur to avoid rapid death in drought conditions. The water potential causing stomatal closure and the xylem pressure at the onset of embolism formation were equal for only a small number of species, and the difference between these two traits (i.e. safety margins) increased continuously with increasing embolism resistance. Our findings demonstrate the need to revise current views about the functional coordination between stomata and hydraulic traits and provide a mechanistic framework for modeling plant mortality under drought conditions.
气孔在地球的水循环和碳循环中起着重要作用,通过调节植物与大气之间的气体交换。在干旱条件下,长期以来人们一直认为气孔对蒸腾的控制与水力容量的下降(由于木质部栓塞导致的水力失效)密切相关。我们通过将与气孔对干旱和栓塞抗性的响应相关的功能性状的荟萃分析与土壤-植物水力模型的模拟相结合,检验了这一假设。我们在这里报告了一个以前未被报道的现象:存在一个绝对限制,即气孔关闭必须发生以避免在干旱条件下迅速死亡。只有少数物种的气孔关闭的水势和栓塞形成时木质部压力相等,这两个特征之间的差异(即安全裕度)随着栓塞抗性的增加而连续增加。我们的研究结果表明,有必要修正目前关于气孔和水力特征之间功能协调的观点,并为干旱条件下植物死亡率的建模提供一个机械框架。
