ESTIMATION OF GENETIC COMPONENTS FOR VARIOUS PHYSIOLOGICAL TRAITS IN MAIZE (Zea mays L.) UNDER WATER DEFICIT CONDITIONS

Journal of Global Innovations in Agricultural and Social Sciences ) Pub Date : 2014-06-01 DOI:10.17957/JGIASS/2.2.491

N. Khan, M. Ahsan, M. Randhawa, Ahmad Khan, A. Saeed, M. Naeem

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引用次数: 2

Abstract

Drought is a solemn environmental factor that causes great loss of yield in maize crop. Maize is highly sensitive to drought. There is need to develop drought tolerance maize genotypes to fulfill demand of feed for livestock and food for human. For this propose prescribed study was conducted to estimate genetic components for various physiological traits under normal and water tress conditions in the research area of the Department of Plant Breeding and Genetics, University of Agriculture Faisalabad, Pakistan. It was concluded that P1 (WFTMS) parent performed better under drought conditions for stomata frequency, stomata conductance, stomata size, cell membrane thermo stability, leaf water potential and excised leaf water loss while BC2 for stomata conductance, F1 for stomata size, F2 leaf water potential and BC1 for leaf temperature. Positive [h] dominance effects were recorded for cell membrane thermo stability, stomata frequency and leaf water potential while [d] additive effects for leaf water potential under normal conditions. It was reported that [i] additive × additive interaction were found for cell membrane thermo stability, stomata frequency and excised leaf water loss while negative for leaf water potential under normal conditions while under drought for cell membrane thermo stability, stomata frequency, stomata conductance and excised leaf water loss. It was suggested that the traits showed [d] additive and [i] additive × additive interaction may be used to fix the increase in the expression of traits in next generations and selection for the development of synthetic varieties for drought resistance may be helpful. The [h] dominance effects showed that the traits may be used for the development of hybrid. On the basis of genetic effects it was concluded that stomata frequency, stomata size, cell membrane thermo stability, leaf water potential and excised leaf water loss may be helpful for

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玉米(Zea mays L.)各生理性状遗传成分分析在缺水条件下

干旱是造成玉米作物严重减产的重要环境因素。玉米对干旱非常敏感。有必要开发耐旱玉米基因型，以满足牲畜饲料和人类食品的需求。为此，本研究在巴基斯坦费萨拉巴德农业大学植物育种与遗传学系研究区进行了正常和缺水条件下各种生理性状的遗传成分估算。结果表明，在干旱条件下，P1 (WFTMS)亲本在气孔频率、气孔导度、气孔大小、细胞膜热稳定性、叶片水势和切除叶片失水方面表现较好，而BC2在气孔导度、F1在气孔大小、F2在叶片水势、BC1在叶片温度方面表现较好。在正常条件下，细胞膜热稳定性、气孔频率和叶片水势表现为正[h]显性效应，叶片水势表现为加性效应。据报道，[i]添加剂与添加剂的交互作用对细胞膜热稳定性、气孔频率和切除的叶片失水有显著影响，正常条件下对叶片水势有显著影响，干旱条件下对细胞膜热稳定性、气孔频率、气孔导度和切除的叶片失水有显著影响。结果表明，[d]加性和[i]加性×加性互作的性状可以固定后代性状表达量的增加，并有助于选育抗旱合成品种。[h]显性效应表明，这些性状可用于杂交发育。在遗传效应的基础上，认为气孔频率、气孔大小、细胞膜热稳定性、叶片水势和切叶失水等因素可能对冬小麦的生长有帮助

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Journal of Global Innovations in Agricultural and Social Sciences )

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