狗尾草
突变体
狗尾草
生物
遗传学
基因
叶绿体
正向遗传学
功能基因组学
野生型
基因表达
表型
位置克隆
植物
基因组学
基因组
杂草
作者
Wen Li,Sha Tang,Shuo Zhang,Jianguo Shan,Chanjuan Tang,Qiannan Chen,Guanqing Jia,Yuanhuai Han,Hui Zhi,Xianmin Diao
摘要
Setaria italica and its wild ancestor Setaria viridis are emerging as model systems for genetics and functional genomics research. However, few systematic gene mapping or functional analyses have been reported in these promising C4 models. We herein isolated the yellow‐green leaf mutant ( siygl1 ) in S. italica using forward genetics approaches. Map‐based cloning revealed that SiYGL1 , which is a recessive nuclear gene encoding a magnesium‐chelatase D subunit ( CHLD ), is responsible for the mutant phenotype. A single Phe to Leu amino acid change occurring near the ATPase ‐conserved domain resulted in decreased chlorophyll (Chl) accumulation and modified chloroplast ultrastructure. However, the mutation enhanced the light‐use efficiency of the siygl1 mutant, suggesting that the mutated CHLD protein does not completely lose its original activity, but instead, gains novel features. A transcriptional analysis of Chl a oxygenase revealed that there is a strong negative feedback control of Chl b biosynthesis in S. italica . The SiYGL1 mRNA was expressed in all examined tissues, with higher expression observed in the leaves. Comparison of gene expression profiles in wild‐type and siygl1 mutant plants indicated that SiYGL1 regulates a subset of genes involved in photosynthesis ( rbcL and LHCB1 ), thylakoid development ( DEG2 ) and chloroplast signaling ( SRP54CP ). These results provide information regarding the mutant phenotype at the transcriptional level. This study demonstrated that the genetic material of a Setaria species could be ideal for gene discovery investigations using forward genetics approaches and may help to explain the molecular mechanisms associated with leaf color variation.
科研通智能强力驱动
Strongly Powered by AbleSci AI