树木对干旱胁迫及复水的生理生态响应研究进展

doi:10.11707/j.1001-7488.LYKX20220250

摘要/Abstract

摘要：

树木在干旱胁迫下的死亡是一个重要的生理生态过程，不仅可以改变森林的结构和功能，还可能影响森林管理决策。在干旱胁迫条件下，树木体内水分代谢与碳代谢会出现失效现象，从而导致树木的死亡。但是在干旱胁迫环境下，树木死亡的生理机制以及干旱—复水过程中树木各个器官的生理生态响应还未探明，这一科学问题也是当前世界的前沿问题。树木的干旱致死机制至少有3种假说：水力失效、碳饥饿和生物攻击假说。水力失效假说认为在干旱胁迫环境下，树木木质部栓塞达到阈值后无法恢复水分传导从而使得树木脱水干燥死亡；碳饥饿假说认为树木在干旱胁迫环境下，气孔紧缩甚至关闭，树木不能进行光合作用产生有机物，但树木为了维持自身正常的生长发育及新陈代谢，使得树木自身可利用碳耗竭；生物攻击假说认为干旱胁迫影响生物因子的分布及生长速率等，使得树木易受到昆虫和病原体的攻击，从而导致树木的死亡。3种假说都已经被证实可以解释一部分树木死亡的现象，但是又不足以解释所有树木在干旱胁迫环境下死亡的现象，特别是非结构性碳水化合物的损耗在死亡过程中的作用仍不清楚。本文介绍干旱胁迫下的水分关系，对水力失效假说中木质部栓塞具体的生理过程进行整体阐述。然后，讨论长期干旱胁迫对树木生长发育、蒸腾作用的影响，以及由此产生的非结构性碳水化合物动态变化，探讨干旱致死过程中树木各个器官生理机制，并总结干旱—复水过程中树木的生理生态变化的研究进展。研究表明，水力失效假说仍然是干旱胁迫下树木死亡的主要假说，而树木体内非结构性有机碳的变化对树木死亡的贡献率未确定。干旱后复水能够使植物的生理功能得到恢复，可在一定程度上弥补干旱对植物造成的伤害, 对树木的形态特征、生理特征都造成影响。本文还对未来树木死亡的研究方向提出建议，旨在为今后树木的合理种植经营提供建议。

关键词: 树木死亡, 干旱胁迫, 水力失效, 复水, 碳饥饿

Abstract:

Tree mortality under drought stress is an important physiological and ecological process that alters the structure and function of forests and influences forest management decisions. Under drought stress conditions, the water and carbon metabolisms in trees have malfunctioned, which leads to tree mortality. However, the exact physiological mechanisms of tree mortality in drought-stressed environments and the physiological-ecological response of various organs in trees during the drought-rewatering process have not yet been elucidated, and this scientific question is currently at the forefront of research worldwide. There are at least three hypotheses for the mechanism of drought mortality in trees: hydraulic failure, carbon starvation and the biological attack hypothesis. The hydraulic failure hypothesis suggests that under drought stress, the xylem of a tree reaches a threshold of embolism and is unable to restore water conduction, thus causing the tree to die of dehydration and desiccation; the carbon starvation hypothesis suggests that under drought stress, stomata are tightened or even closed and the tree cannot photosynthesize to produce organic matter, but the tree is depleted of available carbon in order to maintain its normal growth and metabolism; the biological attack hypothesis suggests that drought stress affects the distribution of biological factors and growth rate, making the tree vulnerable to attack by insects and pathogens, thus causing the tree to die. All hypotheses have been shown to explain a proportion of tree mortality, but are insufficient to explain all tree mortality in drought-stressed environments, and in particular the role of non-structural carbohydrate depletion in the mortality process remains unclear. This paper introduces water relations under drought stress and provides an overall account of the specific physiological processes involved in xylem embolism in the hydraulic failure hypothesis. It then discusses the effects of long-term drought stress on tree growth and development, transpiration, and the resulting changes in non-structural carbohydrate dynamics, explores the physiological mechanisms of individual tree organs during drought mortality, and summarizes the progress of research on physiological and ecological changes in trees during the drought-rehydration process. The current study shows that the hydraulic failure hypothesis remains the dominant hypothesis for tree mortality under drought stress, while the contribution of changes in non-structural organic carbon in trees to tree mortality remains undetermined. Post-drought rehydration can restore plant physiological functions and can compensate to a certain extent for the damage caused by drought, which affects both the morphological and physiological characteristics of trees. This paper also suggests directions for future research on tree mortality, with the aim of providing recommendations for the rational planting and management of trees in the future.

Key words: tree mortality, drought stress, hydraulic failure, rehydration, carbon starvation

中图分类号:

S718.43

游韧,邓湘雯,胡彦婷,欧阳帅,陈亮,项文化. 树木对干旱胁迫及复水的生理生态响应研究进展[J]. 林业科学, 2023, 59(11): 124-136.

Ren You,Xiangwen Deng,Yanting Hu,Shuai Ouyang,Liang Chen,Wenhua Xiang. Progress on Physiological and Ecological Responses of Trees to Drought Stress and Rewatering[J]. Scientia Silvae Sinicae, 2023, 59(11): 124-136.

图/表 2

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