作物学报 ›› 2020, Vol. 46 ›› Issue (10): 1557-1565.doi: 10.3724/SP.J.1006.2020.04007
荐红举1,2(), 霍强1,2(), 高玉敏1,2, 李阳阳1,2, 谢玲1,2, 魏丽娟1,2, 刘列钊1,2, 卢坤1,2, 李加纳1,2,*()
JIAN Hong-Ju1,2(), HUO Qiang1,2(), GAO Yu-Min1,2, LI Yang-Yang1,2, XIE Ling1,2, WEI Li-Juan1,2, LIU Lie-Zhao1,2, LU Kun1,2, LI Jia-Na1,2,*()
摘要:
提高油菜产量是保障国家粮油安全的重要举措。作物“源”“流”“库”理论表明, 充足的光合产物(源)是高产的前提, 而叶绿素是直接参与光合作用的物质, 因此, 选育高叶绿素含量的甘蓝型油菜是提高产量的重要途径。本课题组前期对全球收集的588份优异油菜种质资源进行5X重测序, 获得385,692个高质量SNP标记。利用SPAD-502叶绿素仪于2018—2019连续2年测定苗期完全伸展的叶片叶绿素总量, 结合获得的SNP标记进行全基因组关联分析(genome-wide association study, GWAS), 筛选与叶绿素含量显著关联的SNP位点。结果表明, 2018年鉴定到5个显著关联的SNP位点, 贡献率为5.51%~7.89%, 其中S6_3493805位点贡献率最大; 2019年检测到46个SNP位点, 贡献率为7.29%~10.34%, 其中S13_11413088位点贡献率最大。将显著关联SNP位点上下游各500 kb区间内的基因与参考基因组比对, 初步筛选出2022个油菜基因。将其基因序列在拟南芥基因组内进行BLAST比对, 结合前人已报道的拟南芥同源基因功能, 筛选到23个候选基因, 其中5个属于叶绿素合成途径同源基因。本研究结果为后续油菜叶片叶绿素含量的遗传改良奠定了基础。
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