Li Zhi, Chen Yongyan, Ou Xia, Wang Mengning, Wang Nanxin, Li Wei, Deng Yawen, Diao Yixin, Sun Zixin, Luo Qinyi, Li Xinli, Zhao Liqi, Yan Tong, Peng Wanhua, Jiang Qing, Fang Yi, Ren Zhenglong, Tan Feiquan, Luo Peigao, Ren Tianheng
State Key Laboratory of Crop Gene Exploration and Utilization in Southwest China, Sichuan Agricultural University, Wenjiang, Chengdu, 611130, Sichuan, China.
College of Agronomy, Sichuan Agricultural University, Wenjiang, Chengdu, 611130, Sichuan, China.
Theor Appl Genet. 2022 Dec;135(12):4183-4195. doi: 10.1007/s00122-022-04211-y. Epub 2022 Sep 6.
A major and stable QTL cQSGR.sau.3D, which can explain 33.25% of the phenotypic variation in SGR, was mapped and validated, and cQSGR.sau.3D was found to be independent of GI. In this study, a recombinant inbred line (RIL) population containing 304 lines derived from the cross of Chuan-nong17 (CN17) and Chuan-nong11 (CN11) was genotyped using the Wheat55K single-nucleotide polymorphism array. A high-density genetic map consisting of 8329 markers spanning 4131.54 cM and distributed across 21 wheat chromosomes was constructed. QTLs for whole spike germination rate (SGR) were identified in multiple years. Six and fourteen QTLs were identified using the Inclusive Composite Interval Mapping-Biparental Populations and Multi-Environment Trial methods, respectively. A total of 106 digenic epistatic QTLs were also detected in this study. One of the additive QTLs, cQSGR.sau.3D, which was mapped in the region from 3.5 to 4.5 cM from linkage group 3D-2 on chromosome 3D, can explain 33.25% of the phenotypic variation in SGR and be considered a major and stable QTL for SGR. This QTL was independent of the seeds' germination traits, such as germination index. One Kompetitive Allele-Specific PCR (KASP) marker, KASP-AX-110772653, which is tightly linked to cQSGR.sau.3D, was developed. The genetic effect of cQSGR.sau.3D on SGR in the RIL and natural populations was successfully confirmed. Furthermore, within the interval in which cQSGR.sau.3D is located in Chinese Spring reference genomes, thirty-seven genes were found. cQSGR.sau.3D may provide new resources for pre-harvest sprouting resistance breeding of wheat in the future.
定位并验证了一个主要且稳定的QTL cQSGR.sau.3D,其可解释种子发芽率(SGR)表型变异的33.25%,且发现cQSGR.sau.3D独立于发芽指数(GI)。本研究中,利用小麦55K单核苷酸多态性芯片对由川农17(CN17)和川农11(CN11)杂交产生的包含304个株系的重组自交系(RIL)群体进行了基因分型。构建了一张由8329个标记组成、覆盖4131.54 cM且分布于21条小麦染色体上的高密度遗传图谱。在多年中鉴定了全穗发芽率(SGR)的QTL。分别使用包容性复合区间作图-双亲群体法和多环境试验法鉴定出6个和14个QTL。本研究中还共检测到106个双基因上位性QTL。其中一个加性QTL cQSGR.sau.3D定位在3D染色体上连锁群3D-2距3.5至4.5 cM的区域,可解释SGR表型变异的33.25%,被认为是SGR的一个主要且稳定的QTL。该QTL独立于种子的发芽性状,如发芽指数。开发了一个与cQSGR.sau.3D紧密连锁的竞争性等位基因特异性PCR(KASP)标记KASP-AX-110772653。成功证实了cQSGR.sau.3D对RIL群体和自然群体中SGR的遗传效应。此外,在中国春参考基因组中cQSGR.sau.3D所在区间内发现了37个基因。cQSGR.sau.3D未来可能为小麦抗穗发芽育种提供新资源。
