Influence of No-Till System with or without Cover Crops on Stomata Sensitivity of Glyphosate-Tolerant Soybeans to Vapor Pressure Deficit

Physiologia Pub Date : 2023-10-25 DOI:10.3390/physiologia3040039

Jérôme Bernier Brillon, Matthieu Moingt, Marc Lucotte

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Abstract

Soybeans are vulnerable to drought and temperature increases potentially induced by climate change. Hydraulic dysfunction and stomatal closure to avoid excessive transpiration are the main problems caused by drought. The vulnerability of soybeans to drought will depend on the intensity and duration of water stress. The purpose of this study was to determine if the use of cover crops (CCs) can influence the gas exchange potential of glyphosate-tolerant soybeans when the vapor pressure deficit (Vpd) increases. This two-year study was conducted in an open experimental field comprising direct seeding plots with or without CCs. Stomatal conductance (Gs) was measured five times on the same identified leaves following glyphosate-based herbicide application. These leaves were then collected in order to observe the stomata and foliar traits with a scanning electron microscope. The Vpd was calculated concomitantly to Gs measurements at the leaf surface. The results suggest that the use of CCs promotes phenotypic change in soybean leaves (more elaborate venation and a higher abaxial stomatal density), which in turn may enhance their tolerance to drier conditions. In 2019, Gs could be up to 29% higher in plots with CCs compared to those without CCs with similar Vpd values. This study shows that the benefits of using CCs can be observed via the morphological development strategies of the crop plants and their higher tolerance to drought.

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有无覆盖作物免耕制度对耐草甘膦大豆气孔对蒸汽压亏缺敏感性的影响

大豆很容易受到气候变化可能引起的干旱和温度升高的影响。干旱造成的主要问题是水力功能障碍和气孔关闭以避免过度蒸腾。大豆对干旱的脆弱性将取决于水分胁迫的强度和持续时间。本研究的目的是确定当蒸汽压赤字(Vpd)增加时，覆盖作物(CCs)的使用是否会影响耐草甘膦大豆的气体交换潜力。这项为期两年的研究是在一个开放的试验田进行的，包括有或没有CCs的直接播种地块。使用草甘膦除草剂后，对同一鉴定叶片的气孔导度(Gs)进行了5次测量。收集这些叶片，用扫描电子显微镜观察气孔和叶片特征。Vpd与叶片表面的Gs测量值一起计算。结果表明，CCs的使用促进了大豆叶片的表型变化(更精细的脉络和更高的背面气孔密度)，这反过来可能增强它们对干燥条件的耐受性。2019年，与Vpd值相似的无CCs地块相比，有CCs地块的Gs可能高出29%。本研究表明，使用CCs的好处可以通过作物的形态发育策略和更高的耐旱性来观察。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Physiologia

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