INTERACTIVE EFFECTS OF GENOTYPE AND WATER DEFICIT ON YIELD AND QUALITY TRAITS OF MAIZE INBRED LINES AND F1 DIALLEL CROSSES

Q4 Agricultural and Biological Sciences

Plant Cell Biotechnology and Molecular Biology Pub Date : 2022-10-18 DOI:10.56557/pcbmb/2022/v23i37-387899

A. Al-Naggar, A. Soliman, Elham Mohamed Hassan Mohamed

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Abstract

Maize (Zea mays L.) is vulnerable to drought stress at flowering stage, which has a detrimental impact on yield characteristics. Drought tolerance is genotype dependent. The present study was conducted to investigate the effects of Water Deficit Stress (WDS) at flowering stage, genotype and their interaction on some agronomic, physiologic, grain yield and quality traits of 8 maize inbred lines and their 28 diallel crosses and also attempt to identify the maize genotypes tolerant to WDS conditions. The parents and F1 crosses were evaluated in two seasons. A split plot design with three replications was used, where main plots were allotted to two irrigation treatments, i.e., Well Watering (WW) by giving all recommended irrigations and WDS by withholding the 4th and 5th irrigations, while sub plots were allotted to genotypes. Water deficit stress caused a significant decrease in grain yield/plant (32.3%), grain yield/ha (26.7%), ears/plant (30.6%), rows/ear (10.2%), kernels/row (9.3%), kernels/plant (43.8%), 100-kernel weight (19.9%), plant height (8.5%), ear height (11.9%), and chlorophyll concentration index (17.3%) and a significant increase in anthesis-silking interval (58.82 %), days to anthesis (4.29%), days to silking (6.40%), barren stalks (20.0%), and grain protein content (16.0%). On average, means across F1 crosses were higher than those across inbreds for all studied traits, except for grain protein content and days to 50% silking, where the opposite was true, under both WDS and WW conditions. The rank of inbreds and crosses for studied traits under WDS was changed from that under WW conditions. The reduction in grain yield/ha of inbred lines due to drought (37.36%) was generally higher than that in F1 hybrids (25.67%). It was possible to identify some inbreds and hybrids characterized by high yield and high tolerance to WDS conditions, which were recommended for use in breeding programs for improving drought tolerance in maize.

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基因型和水分亏缺对玉米自交系和F1双列杂交种产量和品质性状的交互作用

玉米(Zea mays L.)在开花期易受干旱胁迫，干旱胁迫对其产量特性有不利影响。耐旱性依赖于基因型。研究了花期水分亏缺胁迫(WDS)、基因型及其互作对8个玉米自交系及其28个双列杂交的部分农艺、生理、产量和品质性状的影响，并尝试鉴定耐水分亏缺胁迫的玉米基因型。亲本和F1杂交分两个季节进行评价。采用3个重复的分割小区设计，将主小区分配给两种灌溉处理，即井水处理(WW)采用所有推荐灌溉，WDS采用不进行第4和第5次灌溉，而子小区分配给基因型。水分亏缺胁迫使单株产量(32.3%)、单株产量(26.7%)、穗数/株(30.6%)、行数/穗(10.2%)、粒数/株(9.3%)、粒数/株(43.8%)、百粒重(19.9%)、株高(8.5%)、穗高(11.9%)和叶绿素浓度指数(17.3%)显著降低，使开花-吐丝间隔(58.82%)、开花-吐丝天数(4.29%)、吐丝天数(6.40%)、枯秆(20.0%)和籽粒蛋白质含量(16.0%)显著增加。除籽粒蛋白质含量和出丝天数~ 50%外，在WDS和WW条件下，F1杂交的平均值均高于自交系。在WDS条件下，所研究性状的自交系和杂交系的等级与WW条件下相比发生了变化。干旱对自交系单产的影响(37.36%)普遍高于F1杂交种(25.67%)。有可能鉴定出一些高产、耐白化条件的自交系和杂交种，推荐用于玉米抗旱性改良的育种计划。

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

Plant Cell Biotechnology and Molecular Biology Agricultural and Biological Sciences-Horticulture

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179