Generation Mean Analysis for quantitative traits in the population of AKDRMS 21-54 x YH3 cross of rice (Oryza sativa L.)

IF 0.6 Q4 ENVIRONMENTAL SCIENCES

Journal of environmental biology Pub Date : 2023-11-01 DOI:10.22438/jeb/44/6/5111

M. K. Duppala, T. Srinivas, Y. Suneetha, G. Suresh

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Abstract

Aim: To study the genetic components of inheritance for 12 quantitative traits which leads into genetic improvement by identification of gene actions for yield and yield related traits. Methodology: Twelve quantitative traits for yield and yield attributing traits were studied at Agricultural College, Bapatla during Rabi 2021-22 deploying Hayman's five parameter model generation mean analysis in estimating the gene effects in the population (P1, P2, F1, F2 and F3) generated from the cross AKDRMS 21-54 x YH3. Estimated mean effects affirm the existence of significant variation in the traits studied. Significance of either one or both, scales C or D inferred the existence of epistatic interaction for the traits studied. Digenic non-allelic interaction model explained the gene action of the traits studied in the present investigation. Results: The generation mean for all the traits showed the importance of both additive and dominance type of gene effects. Among the epistatic gene effects, the additive x additive gene interaction was reported predominant for shoot length, plant height, flag leaf length, spikelet fertility and flag test weight. The gene interaction is associated with homozygosity, therefore, pedigree method of breeding may be adopted for isolation of desirable lines, while for all other traits, along with grain yield per plant, dominance x dominance gene interaction was found to be pre-dominant. The gene interaction is not fixable, hence, population improvement approaches, would be effective. Interpretation: Dominance x dominance gene interaction was predominant for grain yield per plant and majority of yield component traits studied coupled with duplicate epistasis, infers to takeup population improvement approaches, such as bi-parental mating and recurrent selection, followed by isolation of purelines in later generations for competent improvement. Key words: Epistasis, Five parameter model, Generation Mean Analysis, Quantitative traits, Rice

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水稻（Oryza sativa L.）AKDRMS 21-54 x YH3 杂交群体数量性状的世代平均数分析

目的：研究 12 个数量性状的遗传成分，通过确定产量和产量相关性状的基因作用，进而进行遗传改良。研究方法：2021-22 年 Rabi 期间，在 Bapatla 农业学院对产量和产量相关性状的 12 个数量性状进行了研究，采用 Hayman 的五参数模型生成均值分析，估算 AKDRMS 21-54 x YH3 杂交产生的群体（P1、P2、F1、F2 和 F3）中的基因效应。估计的平均效应证实所研究的性状存在显著变异。量表 C 或 D 中任何一个或两个量表的显著性推断所研究的性状存在表观交互作用。双源非等位基因互作模型解释了本次调查所研究性状的基因作用。结果所有性状的世代平均值都显示了加性和显性基因效应的重要性。在外显基因效应中，加性 x 加性基因互作在芽长、株高、旗叶长度、小穗生育力和旗试验重量方面占主导地位。基因互作与同源杂交有关，因此可采用血统育种法分离出理想的品系，而对于所有其他性状以及单株谷物产量，则发现显性 x 显性基因互作是先占优势的。这种基因交互作用是不可修复的，因此，群体改良方法将是有效的。解释在所研究的单株谷粒产量和大多数产量组成性状中，显性×显性基因互作占主导地位，再加上重复的外显性，这说明应采取群体改良方法，如双亲交配和循环选择，然后在后代分离纯系，以进行有效改良。关键字外显率五参数模型世代均值分析数量性状水稻

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