作物学报 ›› 2022, Vol. 48 ›› Issue (1): 138-150.doi: 10.3724/SP.J.1006.2022.03072
于芮苏1(), 田小康1, 刘斌斌1, 段迎新1, 李婷1, 张秀英2, 张兴华1, 郝引川1, 李勤2, 薛吉全1,*(), 徐淑兔1,*()
YU Rui-Su1(), TIAN Xiao-Kang1, LIU Bin-Bin1, DUAN Ying-Xin1, LI Ting1, ZHANG Xiu-Ying2, ZHANG Xing-Hua1, HAO Yin-Chuan1, LI Qin2, XUE Ji-Quan1,*(), XU Shu-Tu1,*()
摘要:
倒伏是影响玉米高产和机械化收获的重要因素, 明确玉米抗倒伏相关性状的遗传基础, 增强玉米品种抗倒伏能力, 可为玉米高产宜机收育种提供理论依据。本研究以国内外收集的153份自交系为材料, 利用6H90K SNP芯片检测的70,438个高质量SNP标记对地上第3节茎秆强度、株高、穗位高和穗位系数进行全基因组关联分析, 分别检测到与茎秆强度、株高、穗位高和穗位系数相关位点5个、14个、16个和21个, 单个关联位点最大效应值为13.24。同时以KA105/KB020的F5群体为试验材料, 采用QTL IciMapping V4.2软件的完备区间作图法进行QTL定位, 检测到21个与抗倒伏相关的QTL, 可解释表型变异3.86%~16.58%。结合关联分析和连锁分析结果发现, 2个QTL区间与关联分析的候选区间重合。经过候选区段的基因功能注释和文献查阅, 挖掘到GRMZM2G105391、GRMZM2G014119和GRMZM2G341410等与细胞壁生物合成、细胞分裂和细胞伸长的相关基因可供进一步分析。本研究结果为进一步解析玉米抗倒伏性状的遗传基础提供参考。
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