Woldegiorgis, Samuel Tareke and Wu, Ti and Gao, Linghui and Huang, Yunxia and Zheng, Yingjie and Qiu, Fuxiang and Xu, Shichang and Tao, Huan and Harrison, Andrew and Liu, Wei and He, Huaqin (2022) Identification of Heat-Tolerant Genes in Non-Reference Sequences in Rice by Integrating Pan-Genome, Transcriptomics, and QTLs. Genes, 13 (8). p. 1353. DOI https://doi.org/10.3390/genes13081353
Woldegiorgis, Samuel Tareke and Wu, Ti and Gao, Linghui and Huang, Yunxia and Zheng, Yingjie and Qiu, Fuxiang and Xu, Shichang and Tao, Huan and Harrison, Andrew and Liu, Wei and He, Huaqin (2022) Identification of Heat-Tolerant Genes in Non-Reference Sequences in Rice by Integrating Pan-Genome, Transcriptomics, and QTLs. Genes, 13 (8). p. 1353. DOI https://doi.org/10.3390/genes13081353
Woldegiorgis, Samuel Tareke and Wu, Ti and Gao, Linghui and Huang, Yunxia and Zheng, Yingjie and Qiu, Fuxiang and Xu, Shichang and Tao, Huan and Harrison, Andrew and Liu, Wei and He, Huaqin (2022) Identification of Heat-Tolerant Genes in Non-Reference Sequences in Rice by Integrating Pan-Genome, Transcriptomics, and QTLs. Genes, 13 (8). p. 1353. DOI https://doi.org/10.3390/genes13081353
Abstract
The availability of large-scale genomic data resources makes it very convenient to mine and analyze genes that are related to important agricultural traits in rice. Pan-genomes have been constructed to provide insight into the genome diversity and functionality of different plants, which can be used in genome-assisted crop improvement. Thus, a pan-genome comprising all genetic elements is crucial for comprehensive variation study among the heat-resistant and -susceptible rice varieties. In this study, a rice pan-genome was firstly constructed by using 45 heat-tolerant and 15 heat-sensitive rice varieties. A total of 38,998 pan-genome genes were identified, including 37,859 genes in the reference and 1141 in the non-reference contigs. Genomic variation analysis demonstrated that a total of 76,435 SNPs were detected and identified as the heat-tolerance-related SNPs, which were specifically present in the highly heat-resistant rice cultivars and located in the genic regions or within 2 kbp upstream and downstream of the genes. Meanwhile, 3214 upregulated and 2212 downregulated genes with heat stress tolerance-related SNPs were detected in one or multiple RNA-seq datasets of rice under heat stress, among which 24 were located in the non-reference contigs of the rice pan-genome. We then mapped the DEGs with heat stress tolerance-related SNPs to the heat stress-resistant QTL regions. A total of 1677 DEGs, including 990 upregulated and 687 downregulated genes, were mapped to the 46 heat stress-resistant QTL regions, in which 2 upregulated genes with heat stress tolerance-related SNPs were identified in the non-reference sequences. This pan-genome resource is an important step towards the effective and efficient genetic improvement of heat stress resistance in rice to help meet the rapidly growing needs for improved rice productivity under different environmental stresses. These findings provide further insight into the functional validation of a number of non-reference genes and, especially, the two genes identified in the heat stress-resistant QTLs in rice.
Item Type: | Article |
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Uncontrolled Keywords: | Genes, Plant; Oryza; Quantitative Trait Loci; Thermotolerance; Transcriptome |
Divisions: | Faculty of Science and Health Faculty of Science and Health > Mathematics, Statistics and Actuarial Science, School of |
SWORD Depositor: | Unnamed user with email elements@essex.ac.uk |
Depositing User: | Unnamed user with email elements@essex.ac.uk |
Date Deposited: | 14 Dec 2022 18:13 |
Last Modified: | 30 Oct 2024 20:49 |
URI: | http://repository.essex.ac.uk/id/eprint/34386 |
Available files
Filename: genes-13-01353.pdf
Licence: Creative Commons: Attribution 3.0