Sensitive Hydraulic and Stomatal Decline in Extreme Drought Tolerant Species of California Ceanothus.

IF 6 1区 生物学 Q1 PLANT SCIENCES
Joseph Zailaa, Santiago Trueba, Marvin Browne, Leila R Fletcher, Thomas N Buckley, Craig R Brodersen, Christine Scoffoni, Lawren Sack
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Abstract

Identifying the physiological mechanisms by which plants are adapted to drought is critical to predict species responses to climate change. We measured the responses of leaf hydraulic and stomatal conductances (Kleaf and gs, respectively) to dehydration, and their association with anatomy, in seven species of California Ceanothus grown in a common garden, including some of the most drought-tolerant species in the semi-arid flora. We tested for matching of maximum hydraulic supply and demand and quantified the role of decline of Kleaf in driving stomatal closure. Across Ceanothus species, maximum Kleaf and gs were negatively correlated, and both Kleaf and gs showed steep declines with decreasing leaf water potential (i.e., a high sensitivity to dehydration). The leaf water potential at 50% decline in gs was linked with a low ratio of maximum hydraulic supply to demand (i.e., maximum Kleaf:gs). This sensitivity of gs, combined with low minimum epidermal conductance and water storage, could contribute to prolonged leaf survival under drought. The specialized anatomy of subg. Cerastes includes trichomous stomatal crypts and pronounced hypodermis, and was associated with higher water use efficiency and water storage. Combining our data with comparative literature of other California species, species of subg. Cerastes show traits associated with greater drought tolerance and reliance on leaf water storage relative to other California species. In addition to drought resistance mechanisms such as mechanical protection and resistance to embolism, drought avoidance mechanisms such as sensitive stomatal closure could contribute importantly to drought tolerance in dry-climate adapted species.

极端耐旱的加州刺芹物种的敏感水力和气孔衰退。
确定植物适应干旱的生理机制对于预测物种对气候变化的反应至关重要。我们测量了生长在普通花园中的七种加州刺芹的叶片水力和气孔导度(分别为 Kleaf 和 gs)对脱水的反应及其与解剖学的关联,其中包括半干旱植物区系中一些最耐旱的物种。我们测试了最大水力供求的匹配情况,并量化了 Kleaf 的衰退在推动气孔关闭方面的作用。在所有西洋接骨木物种中,最大Kleaf和gs呈负相关,并且Kleaf和gs都随着叶片水势的下降而急剧下降(即对脱水的高度敏感性)。gs 下降 50%时的叶片水势与最大水力供求比(即最大 Kleaf:gs)较低有关。gs 的这种敏感性,再加上较低的最小表皮传导率和储水量,可能有助于延长叶片在干旱条件下的存活时间。Cerastes 亚种的特化解剖结构包括毛状气孔隐窝和明显的下表皮,这与较高的水分利用效率和储水量有关。将我们的数据与其他加利福尼亚物种的比较文献相结合,发现 Cerastes 亚种与其他加利福尼亚物种相比,具有更强的耐旱性和依赖叶片储水的特性。除了机械保护和抗栓塞等抗旱机制外,敏感的气孔关闭等避旱机制也会对适应干旱气候的物种的耐旱性产生重要影响。
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来源期刊
Plant, Cell & Environment
Plant, Cell & Environment 生物-植物科学
CiteScore
13.30
自引率
4.10%
发文量
253
审稿时长
1.8 months
期刊介绍: Plant, Cell & Environment is a premier plant science journal, offering valuable insights into plant responses to their environment. Committed to publishing high-quality theoretical and experimental research, the journal covers a broad spectrum of factors, spanning from molecular to community levels. Researchers exploring various aspects of plant biology, physiology, and ecology contribute to the journal's comprehensive understanding of plant-environment interactions.
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