ICAR-Vivekananda Parvatiya Krishi Anusandhan Sansthan, Almora, Uttarakhand, India.
The University of Trans-Disciplinary Health Sciences and Technology, Jarakabande Kaval, Bengaluru, Karnataka, India.
PLoS One. 2023 Mar 10;18(3):e0280762. doi: 10.1371/journal.pone.0280762. eCollection 2023.
Magnaporthe oryzae, the rice blast fungus, is one of the most dangerous rice pathogens, causing considerable crop losses around the world. In order to explore the rice blast-resistant sources, initially performed a large-scale screening of 277 rice accessions. In parallel with field evaluations, fifty-two rice accessions were genotyped for 25 major blast resistance genes utilizing functional/gene-based markers based on their reactivity against rice blast disease. According to the phenotypic examination, 29 (58%) and 22 (42%) entries were found to be highly resistant, 18 (36%) and 29 (57%) showed moderate resistance, and 05 (6%) and 01 (1%), respectively, were highly susceptible to leaf and neck blast. The genetic frequency of 25 major blast resistance genes ranged from 32 to 60%, with two genotypes having a maximum of 16 R-genes each. The 52 rice accessions were divided into two groups based on cluster and population structure analysis. The highly resistant and moderately resistant accessions are divided into different groups using the principal coordinate analysis. According to the analysis of molecular variance, the maximum diversity was found within the population, while the minimum diversity was found between the populations. Two markers (RM5647 and K39512), which correspond to the blast-resistant genes Pi36 and Pik, respectively, showed a significant association to the neck blast disease, whereas three markers (Pi2-i, Pita3, and k2167), which correspond to the blast-resistant genes Pi2, Pita/Pita2, and Pikm, respectively, showed a significant association to the leaf blast disease. The associated R-genes might be utilized in rice breeding programmes through marker-assisted breeding, and the identified resistant rice accessions could be used as prospective donors for the production of new resistant varieties in India and around the world.
稻瘟病菌(Magnaporthe oryzae)是最危险的水稻病原体之一,在全球范围内造成了相当大的作物损失。为了探索水稻抗稻瘟病的来源,我们首先对 277 个水稻品种进行了大规模筛选。同时,我们利用基于功能/基因的标记对 52 个水稻品种进行了 25 个主要稻瘟病抗性基因的基因型分析,这些标记是根据它们对稻瘟病的反应设计的。根据表型检查,发现 29 个(58%)和 22 个(42%)品种对叶片和穗颈稻瘟病表现出高度抗性,18 个(36%)和 29 个(57%)表现出中度抗性,而 05 个(6%)和 01 个(1%)对叶片和穗颈稻瘟病表现出高度敏感。25 个主要稻瘟病抗性基因的遗传频率为 32%至 60%,其中两种基因型各有 16 个 R 基因。根据聚类和群体结构分析,将 52 个水稻品种分为两组。利用主坐标分析,将高抗和中抗品种分为不同的组。根据分子方差分析,发现群体内的多样性最大,而群体间的多样性最小。两个标记(RM5647 和 K39512)分别对应抗性基因 Pi36 和 Pik,与穗颈稻瘟病显著相关,而三个标记(Pi2-i、Pita3 和 k2167)分别对应抗性基因 Pi2、Pita/Pita2 和 Pikm,与叶片稻瘟病显著相关。这些关联的 R 基因可以通过标记辅助选择应用于水稻育种计划,而鉴定出的抗性水稻品种可以作为印度和世界各地新抗性品种的潜在供体。
