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Genome‐Wide Association Mapping of Salinity Tolerance at the Seedling Stage in a Panel of Vietnamese Landraces Reveals New Valuable QTLs for Salinity Stress Tolerance Breeding in Rice

Le, T.D. and Gathignol, F. and Vu, H.T. and Nguyen, K.L. and Tran, L.H. and Vu, H.T.T. and Dinh, T.X. and Lazennec, F. and Pham, X.H. and Very, A.-A. and Gantet, P. and Hoang, G.T. (2021) Genome‐Wide Association Mapping of Salinity Tolerance at the Seedling Stage in a Panel of Vietnamese Landraces Reveals New Valuable QTLs for Salinity Stress Tolerance Breeding in Rice. Plants, 10 (1088). ISSN 2223-7747

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Abstract

Rice tolerance to salinity stress involves diverse and complementary mechanisms, such as the regulation of genome expression, activation of specific ion‐transport systems to manage excess sodium at the cell or plant level, and anatomical changes that avoid sodium penetration into the inner tissues of the plant. These complementary mechanisms can act synergistically to improve sa‐ linity tolerance in the plant, which is then interesting in breeding programs to pyramidize comple‐ mentary QTLs (quantitative trait loci), to improve salinity stress tolerance of the plant at different developmental stages and in different environments. This approach presupposes the identification of salinity tolerance QTLs associated with different mechanisms involved in salinity tolerance, which requires the greatest possible genetic diversity to be explored. To contribute to this goal, we screened an original panel of 179 Vietnamese rice landraces genotyped with 21,623 SNP markers for salinity stress tolerance under 100 mM NaCl treatment, at the seedling stage, with the aim of identifying new QTLs involved in the salinity stress tolerance via a genome‐wide association study (GWAS). Nine salinity tolerance‐related traits, including the salt injury score, chlorophyll and water content, and K+ and Na+ contents were measured in leaves. GWAS analysis allowed the identifica‐ tion of 26 QTLs. Interestingly, ten of them were associated with several different traits, which indi‐ cates that these QTLs act pleiotropically to control the different levels of plant responses to salinity stress. Twenty‐one identified QTLs colocalized with known QTLs. Several genes within these QTLs have functions related to salinity stress tolerance and are mainly involved in gene regulation, signal transduction or hormone signaling. Our study provides promising QTLs for breeding programs to enhance salinity tolerance and identifies candidate genes that should be further functionally studied to better understand salinity tolerance mechanisms in rice.

Item Type: Article
Subjects: Agriculture Technology
ISI-indexed journals
Divisions: Faculty of Agriculture Technology (FAT)
Depositing User: Nguy�n Lê Khanh
Date Deposited: 28 Jun 2021 02:06
Last Modified: 28 Jun 2021 02:06
URI: http://eprints.uet.vnu.edu.vn/eprints/id/eprint/4518

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