灌溉稻和旱稻的籽粒铁和锌含量、杂种优势、配合力及其与籽粒产量的关联

Grain Fe and Zn content, heterosis, combining ability and its association with grain yield in irrigated and aerobic rice.

作者信息

Anusha G, Rao D Sanjeeva, Jaldhani V, Beulah P, Neeraja C N, Gireesh C, Anantha M S, Suneetha K, Santhosha R, Prasad A S Hari, Sundaram R M, Madhav M Sheshu, Fiyaz A, Brajendra P, Tuti M D, Bhave M H V, Krishna K V Radha, Ali J, Subrahmanyam D, Senguttuvel P

机构信息

Indian Institute of Rice Research (ICAR-IIRR), Hyderabad, India.

Professor Jaya Shankar Telangana State Agricultural University (PJTSAU), Hyderabad, India.

出版信息

Sci Rep. 2021 May 19;11(1):10579. doi: 10.1038/s41598-021-90038-4.

DOI:10.1038/s41598-021-90038-4

PMID:34011978

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8134482/

Abstract

Genetic improvement of rice for grain micronutrients, viz., iron (Fe) and zinc (Zn) content is one of the important breeding objectives, in addition to yield improvement under the irrigated and aerobic ecosystems. In view of developing genetic resources for aerobic conditions, line (L) × tester (T) analysis was conducted with four restorers, four CMS lines and 16 hybrids. Both hybrids and parental lines were evaluated in irrigated and aerobic field conditions for grain yield, grain Fe and Zn content. General Combining Ability (GCA) effects of parents and Specific Combining Ability (SCA) effects of hybrids were observed to be contrasting for the micronutrient content in both the growing environments. The grain Fe and Zn content for parental lines were negatively correlated with grain yield in both the contrasting growing conditions. However, hybrids exhibited positive correlation for grain Fe and Zn with grain yield under limited water conditions. The magnitude of SCA mean squares was much higher than GCA mean squares implying preponderance of dominance gene action and also role of complementary non-allelic gene(s) interaction of parents and suitability of hybrids to the aerobic system. The testers HHZ12-SAL8-Y1-SAL1 (T1) and HHZ17-Y16-Y3-Y2 (T2) were identified as good combiners for grain Zn content under irrigated and aerobic conditions respectively.

摘要

除了在灌溉和有氧生态系统下提高产量外，提高水稻籽粒中微量营养素（即铁（Fe）和锌（Zn））含量的遗传改良是重要的育种目标之一。鉴于开发有氧条件下的遗传资源，利用4个恢复系、4个细胞质雄性不育系和16个杂交种进行了系（L）×测验种（T）分析。在灌溉和有氧田间条件下对杂交种和亲本系进行了籽粒产量、籽粒铁和锌含量的评估。在两种生长环境下，亲本的一般配合力（GCA）效应和杂交种的特殊配合力（SCA）效应在微量营养素含量方面表现出差异。在两种不同的生长条件下，亲本系的籽粒铁和锌含量与籽粒产量呈负相关。然而，在水分有限的条件下，杂交种的籽粒铁和锌与籽粒产量呈正相关。SCA均方值远高于GCA均方值，这意味着显性基因作用占优势，同时亲本的互补非等位基因相互作用也起作用，并且杂交种对有氧系统具有适应性。分别鉴定出测验种HHZ12 - SAL8 - Y1 - SAL1（T1）和HHZ17 - Y16 - Y3 - Y2（T2）在灌溉和有氧条件下是籽粒锌含量的优良配合系。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/78fa/8134482/2bed155666cc/41598_2021_90038_Fig1_HTML.jpg

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灌溉稻和旱稻的籽粒铁和锌含量、杂种优势、配合力及其与籽粒产量的关联

Grain Fe and Zn content, heterosis, combining ability and its association with grain yield in irrigated and aerobic rice.

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