Xia Sijia, Liu Yinuo, Wang Jiaqi, Li Chengxin, Wang Mengge, Liu Hualong, Zheng Hongliang, Yang Luomiao, Zou Detang, Xin Wei, Wang Jingguo
Key Laboratory of Germplasm Enhancement, Physiology and Ecology of Food Crops in Cold Region, Northeast Agricultural University, Ministry of Education, Harbin, 150030, China.
Harbin Academy of Agricultural Sciences, Harbin, 150030, China.
Sci Rep. 2025 Sep 26;15(1):33190. doi: 10.1038/s41598-025-17400-8.
Nitrogen is an essential nutrient, which plays an important role in plant growth and development process and increases crop production. However, excessive nitrogen application will lead to a series of problems such as water eutrophication and economic costs. Therefore, it is of great significance to explore rice low-nitrogen tolerance genes and breed new varieties with higher nitrogen utilization efficiency for improving the economic benefits and agricultural sustainability of agricultural production. In this study, 295 japonica rice varieties were used as materials to measure root dry weight, leaf dry weight and root-shoot ratio at seedling stage under low and high nitrogen conditions. By using Genome-wide association analysis and haplotype analysis of 587 genes among the 47 QTLs obtained, we finally identified significant phenotypic differences between the different haplotypes of the 96 genes. Based on the criteria of |logFC| > 1 and p < 0.05, 5 genes (Os06g0538400, Os11g0195500, Os11g0213700, Os11g0213800, Os12g0472800) were significantly different in the expression of Longjing 31 (low-nitrogen tolerant variety), but not in Songjing 10 (low-nitrogen sensitive variety), and they were named the more valuable candidate genes for low-nitrogen tolerance. Os11g0213700 and Os11g0213800, as genes containing LRR structure, may regulate root development and low nitrogen stress response by interacting with KAI2. Mining low-nitrogen tolerance genes in rice is of great significance to rice growth and agricultural development. The results of this study provide an important molecular basis for identifying low-nitrogen tolerance genes and breeding low-nitrogen tolerant rice varieties.
氮是一种必需营养素,在植物生长发育过程中发挥着重要作用,并能提高作物产量。然而,过量施用氮肥会导致一系列问题,如水体富营养化和经济成本增加。因此,探索水稻耐低氮基因并培育氮利用效率更高的新品种,对于提高农业生产的经济效益和农业可持续性具有重要意义。本研究以295个粳稻品种为材料,测定了低氮和高氮条件下苗期的根干重、叶干重和根冠比。通过对获得的47个QTL中的587个基因进行全基因组关联分析和单倍型分析,最终确定了96个基因的不同单倍型之间存在显著的表型差异。基于|logFC|>1和p<0.05的标准,5个基因(Os06g0538400、Os11g0195500、Os11g0213700、Os11g0213800、Os12g0472800)在耐低氮品种龙井31中的表达有显著差异,但在低氮敏感品种松粳10中无显著差异,它们被命名为更有价值的耐低氮候选基因。Os11g0213700和Os11g0213800作为含有LRR结构的基因,可能通过与KAI2相互作用来调节根系发育和低氮胁迫响应。挖掘水稻耐低氮基因对水稻生长和农业发展具有重要意义。本研究结果为鉴定耐低氮基因和培育耐低氮水稻品种提供了重要的分子基础。
