High-throughput phenotyping of soybean (Glycine max) transpiration response curves to rising atmospheric drying in a mapping population.

IF 2.6 4区生物学 Q2 PLANT SCIENCES

Functional Plant Biology Pub Date : 2024-11-01 DOI:10.1071/FP23281

Daniel Monnens, José R López, Erik McCoy, Bishal G Tamang, Aaron J Lorenz, Walid Sadok

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引用次数: 0

Abstract

In soybean (Glycine max ), limiting whole-plant transpiration rate (TR) response to increasing vapor pressure deficit (VPD) has been associated with the 'slow-wilting' phenotype and with water-conservation enabling higher yields under terminal drought. Despite the promise of this trait, it is still unknown whether it has a genetic basis in soybean, a challenge limiting the prospects of breeding climate-resilient varieties. Here, we present the results of a first attempt at a high-throughput phenotyping of TR and stomatal conductance response curves to increasing VPD conducted on a soybean mapping population consisting of 140 recombinant inbred lines (RIL). This effort was conducted over two consecutive years, using a controlled-environment, gravimetric phenotyping platform that enabled characterizing 900 plants for these responses, yielding regression parameters (R 2 from 0.92 to 0.99) that were used for genetic mapping. Several quantitative trait loci (QTL) were identified for these parameters on chromosomes (Ch) 4, 6, and 10, including a VPD-conditional QTL on Ch 4 and a 'constitutive' QTL controlling all parameters on Ch 6. This study demonstrated for the first time that canopy water use in response to rising VPD has a genetic basis in soybean, opening novel avenues for identifying alleles enabling water conservation under current and future climate scenarios.

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在制图群体中对大豆（Glycine max）蒸腾作用对大气干燥上升的响应曲线进行高通量表型分析。

在大豆（Glycine max）中，限制全株蒸腾速率（TR）对蒸气压不足（VPD）增加的响应与 "慢萎 "表型以及在终旱条件下提高产量的节水作用有关。尽管这一性状前景广阔，但其在大豆中是否具有遗传基础仍不得而知，这一挑战限制了培育气候适应性品种的前景。在此，我们首次尝试在由 140 个重组近交系（RIL）组成的大豆图谱群体中，对 TR 和气孔导度对 VPD 增加的响应曲线进行高通量表型分析。这项工作连续进行了两年，使用的是一个可控环境重力表型平台，该平台可对 900 株植物的这些反应进行表征，得出的回归参数（R 2 在 0.92 到 0.99 之间）可用于基因图谱绘制。在 4 号、6 号和 10 号染色体上为这些参数确定了几个数量性状位点（QTL），包括 4 号染色体上的一个 VPD 条件 QTL 和 6 号染色体上的一个控制所有参数的 "组成型 "QTL。这项研究首次证明了大豆冠层水分利用对 VPD 上升的响应具有遗传基础，为鉴定等位基因开辟了新的途径，从而在当前和未来的气候条件下实现节水。

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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来源期刊

Functional Plant Biology 生物-植物科学

CiteScore

5.50

自引率

3.30%

发文量

156

审稿时长

1 months

期刊介绍： Functional Plant Biology (formerly known as Australian Journal of Plant Physiology) publishes papers of a broad interest that advance our knowledge on mechanisms by which plants operate and interact with environment. Of specific interest are mechanisms and signal transduction pathways by which plants adapt to extreme environmental conditions such as high and low temperatures, drought, flooding, salinity, pathogens, and other major abiotic and biotic stress factors. FPB also encourages papers on emerging concepts and new tools in plant biology, and studies on the following functional areas encompassing work from the molecular through whole plant to community scale. FPB does not publish merely phenomenological observations or findings of merely applied significance. Functional Plant Biology is published with the endorsement of the Commonwealth Scientific and Industrial Research Organisation (CSIRO) and the Australian Academy of Science. Functional Plant Biology is published in affiliation with the Federation of European Societies of Plant Biology and in Australia, is associated with the Australian Society of Plant Scientists and the New Zealand Society of Plant Biologists.