Leaf gas exchange characteristics, biomass partitioning, and water use efficiencies of two C4 African grasses under simulated drought

Grassland Research Pub Date : 2023-03-02 DOI:10.1002/glr2.12040

Kevin Z. Mganga, Jana Kuhla, Andrea Carminati, Johanna Pausch, Mutez A. Ahmed

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Abstract

Background

Few studies have evaluated the effect of drought on the morpho-physiological characteristics of African C₄ grasses. We investigated how drought affects leaf gas exchange characteristics, biomass partitioning, and water use efficiencies of Enteropogon macrostachyus and Cenchrus ciliaris.

Methods

The grasses were grown in a controlled environment under optimum conditions, that is, 70% of the maximum water-holding capacity (WHC) for the first 40 days. Thereafter, half of the columns were maintained under optimum or drought conditions (30% of maximum WHC) for another 20 days.

Results

Under optimum conditions, C. ciliaris showed a significantly higher photosynthetic rate, stomatal conductance, and transpiration rate than E. macrostachyus. Drought decreased the photosynthetic rate, stomatal conductance and transpiration rate only in C. ciliaris. The net photosynthetic rate, stomatal conductance, and leaf transpiration of E. macrostachyus did not differ significantly under optimum and drought conditions. E. macrostachyus showed an increase in its water use efficiencies under drought to a greater extent than C. ciliaris.

Conclusions

Our results demonstrate that C. ciliaris is more sensitive to drought than E. macrostachyus. The decrease in the intercellular CO₂ concentration and the increase in stomatal limitation with drought in C. ciliaris and E. macrostachyus suggest that stomatal limitation plays the dominant role in photosynthesis of the studied African C₄ grasses.

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模拟干旱条件下两种C4非洲草的叶气交换特性、生物量分配和水分利用效率

背景很少有研究评估干旱对非洲C4草形态生理特征的影响。我们研究了干旱如何影响大盖肠杆菌和毛白杨的叶片气体交换特性、生物量分配和水分利用效率。方法在最佳条件下，即前40天最大持水量（WHC）的70%的条件下，在受控环境中生长。此后，将一半的柱在最佳或干旱条件下（最大WHC的30%）再维持20天。结果在最适条件下，纤毛藻的光合速率、气孔导度和蒸腾速率均显著高于巨大叶藻。干旱只降低了纤毛藻的光合速率、气孔导度和蒸腾速率。在最适和干旱条件下，大白菜的净光合速率、气孔导度和叶片蒸腾作用没有显著差异。在干旱条件下，E.macrostachys的水分利用效率比C.ciliaris的提高幅度更大。结论纤毛圆线虫对干旱的敏感性高于巨大圆线虫。随着干旱，C.ciliaris和E.macrostachyus细胞间CO2浓度的降低和气孔限制的增加表明，气孔限制在所研究的非洲C4草的光合作用中起主导作用。

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