蒸汽压亏缺对半干旱、半湿润和湿润地区珍珠粟种质生长和产量的影响。

Effect of vapor pressure deficit on growth and yield of pearl millet germplasm originating from semi-arid, semi-humid and humid regions.

作者信息

Garba Hadizatou, Hamidou Falalou, Abdou Harou, Burridge James, Vadez Vincent

机构信息

Department of Biology, Faculty of Science, University Abdou Moumouni of Niamey/Niger (UAM), Niamey, Niger.

International Crops Research Institute for the Semi-Arid Tropics (ICRISAT) Sahelian Centre, Niamey, Niger.

出版信息

Front Plant Sci. 2024 Dec 23;15:1465686. doi: 10.3389/fpls.2024.1465686. eCollection 2024.

DOI:10.3389/fpls.2024.1465686

PMID:39777085

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11705003/

Abstract

INTRODUCTION

The increase in vapor pressure deficit (VPD) is among the expected change in futur climate, and understanding its effect on crop growth is of much significance for breeeding programs. Three groups (G1,G2 and G3) of pearl millet germplasm, originating from regions with different rainfall intensities, were grown in the field during period of high and low VPDs. The groups G1,G2 and G3 were respectively from Guinean (rainfall above 1000 mm), Soudanian (rainfall between 600 mm and 900 mm), and Sahelian zones (rainfall between 600 and 300 mm) of Africa. The objective was to assess if there was any growth response difference among the germplasm groups.

METHOD

Four trials were conducted, two in the dry season of 2019 (Ds19) and 2020 (Ds20) with avarage VPDs of 3.62 kPa and 2.92 kPa, respectively, and two in the rainy season of 2019 (Rs19) and 2020 (Rs20) with avaerage VPDs of 1.14 kPa and 0.61 kPa, respectively.

RESULTS

In order to avoid possible confounding effects of radiation on millet growth and yield, data were normalized by the quantity of light received during each season. After this normalization, leaf area and grain yield decreased in the highest-VPD seasons whereas tiller number decreased only in Ds19 (one high VPD season). The comparison of the three germplasm groups indicates that G3 the germplasm group from Sahelian regions showed greater tolerance to high VPD than G1 and G2.

DISCUSSION

Germplasm from the G3 group could be a good material for developing tolerant germplasm to future climate that is bound to have high VPD.

摘要

引言

水汽压亏缺（VPD）的增加是未来气候变化预期中的一部分，了解其对作物生长的影响对于育种计划具有重要意义。来自不同降雨强度地区的三组（G1、G2和G3）珍珠粟种质在高VPD和低VPD时期进行了田间种植。G1、G2和G3组分别来自非洲的几内亚（降雨量超过1000毫米）、苏丹（降雨量在600毫米至900毫米之间）和萨赫勒地区（降雨量在600至300毫米之间）。目的是评估种质组之间是否存在生长反应差异。

方法

进行了四项试验，两项在2019年旱季（Ds19）和2020年旱季（Ds20），平均VPD分别为3.62千帕和2.92千帕，两项在2019年雨季（Rs19）和2020年雨季（Rs20），平均VPD分别为1.14千帕和0.61千帕。

结果

为了避免辐射对粟生长和产量可能产生的混杂影响，数据通过每个季节接收的光量进行了归一化。归一化后，在VPD最高的季节，叶面积和籽粒产量下降，而分蘖数仅在Ds19（一个高VPD季节）下降。对三个种质组的比较表明，来自萨赫勒地区的G3种质组比G1和G2对高VPD表现出更大的耐受性。

讨论

G3组的种质可能是培育适应未来必然具有高VPD气候的耐性种质的良好材料。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/3580/11705003/894888450b50/fpls-15-1465686-g001.jpg

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蒸汽压亏缺对半干旱、半湿润和湿润地区珍珠粟种质生长和产量的影响。

Effect of vapor pressure deficit on growth and yield of pearl millet germplasm originating from semi-arid, semi-humid and humid regions.

作者信息

机构信息

出版信息

INTRODUCTION

METHOD

RESULTS

DISCUSSION

引言

方法

结果

讨论

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