利用形态生理性状和SSR标记研究终末热胁迫条件下春小麦分子多样性

IF 1 4区生物学 Q3 PLANT SCIENCES

Indian Journal of Genetics and Plant Breeding Pub Date : 2022-02-25 DOI:10.31742/ijgpb.82.1.7

Vijay Kamal Meena, Rohit Kumar Sharma, S. Chand, Monu Kumar, Naresh Kumar, N. Jain, Attar Singh

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引用次数: 1

摘要

对36个小麦基因型在不同环境条件下的遗传多样性和末端耐热性进行了为期2年的分析。根据不同季节的最小平均胁迫敏感性指数，HD3090、HD3086、HD3266、DW1636和DW1638 5个基因型表现出末端耐热性。D2分析将36个基因型在2016-17年和2017-18年分别分为8个和6个聚类。主成分分析结果与层次聚类分析结果一致。在研究分子多样性的82个SSR标记中，有45个具有多态性。多态性信息含量估计值从0.09 (GWM297)到0.50 (GWM111和CFD46)不等，标记指数从0.22 (WMC213)到1.33 (WMC232)不等，分辨能力从1.6 (GWM194和CFD127)到4.69 (WMC505)不等。共检测到102个等位基因，其中罕见等位基因20个，独特等位基因3个。每个标记的等位基因数为2 ~ 4个，平均为2.2个。根据SSR多态性，将其分为6个不同的多基因型群。利用分子标记和形态生理性状进行比较基因型分组，发现不同作物季节的基因型聚类没有相似性。然而，根据D2值和SSR标记聚类分析，HD3090、HD3086和HD3266 3个基因型在不同的聚类中被鉴定为末端耐热型。因此，这些具有遗传多样性的基因型可以作为提高小麦末端耐热性的潜在供体。

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Elucidating molecular diversity in spring wheat (Triticum aestivum L. em.Thell.) under terminal heat stress environment using morpho-physiological traits and SSR markers

A set of 36 wheat genotypes was analysed for genetic diversity and terminal heat tolerance under diverse environmental conditions for two years. Based on a minimum mean stress susceptibility index over the seasons, five genotypes, namely, HD3090, HD3086, HD3266, DW1636 and DW1638 emerged as terminal heat tolerant. The D2 analysis grouped the 36 genotypes into eight and six clusters in 2016-17 and 2017-18, respectively. The result of the principal component analysis was also in agreement with the results of hierarchical cluster analysis. Out of 82 SSR markers used to study the molecular diversity, 45 were polymorphic. Estimates for polymorphism information content varied from 0.09 (GWM297) to 0.50 (GWM111 and CFD46), marker index varied from 0.22 (WMC213) to 1.33 (WMC232), and resolving power varied 1.6 (GWM194 and CFD127) to 4.69 (WMC505). A total of 102, including 20 rare and three unique alleles were detected. The number of alleles per marker ranged from 2 to 4 with an average value of 2.2 alleles per marker. Based on SSR polymorphism, the genotypes were grouped into six divergent multi-genotypic clusters. Comparative genotypic grouping using molecular markers and morpho-physiological traits revealed no similarities of genotypic clustering in different crop seasons. However, three out of five genotypes, HD3090, HD3086 and HD3266 identified as terminal heat-tolerant in different clusters based on D2 values and SSR marker cluster analysis. Therefore, these genetically diverse genotypes could be used as a potential donor for improving the terminal heat tolerance in wheat.

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来源期刊

Indian Journal of Genetics and Plant Breeding PLANT SCIENCES-

CiteScore

1.80

自引率

10.00%

发文量

审稿时长

6-12 weeks

期刊介绍： Advance the cause of genetics and plant breeding and to encourage and promote study and research in these disciplines in the service of agriculture; to disseminate the knowledge of genetics and plant breeding; provide facilities for association and conference among students of genetics and plant breeding and for encouragement of close relationship between them and those in the related sciences; advocate policies in the interest of the nation in the field of genetics and plant breeding, and facilitate international cooperation in the field of genetics and plant breeding.