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Tiller Angle Control 1 Is Essential for the Dynamic Changes in Plant Architecture in Rice.

Hong WangRanran TuLianping SunDongfei WangZheyan RuanYue ZhangZequn PengXingpeng ZhouJunlin FuQunen LiuWeixun WuXiaodeng ZhanXihong ShenYingxin ZhangLiyong CaoShihua Cheng
Published in: International journal of molecular sciences (2022)
Plant architecture is dynamic as plants develop. Although many genes associated with specific plant architecture components have been identified in rice, genes related to underlying dynamic changes in plant architecture remain largely unknown. Here, we identified two highly similar recombinant inbred lines (RILs) with different plant architecture: RIL-Dynamic (D) and RIL-Compact (C). The dynamic plant architecture of RIL-D is characterized by 'loose tiller angle (tillering stage)-compact (heading stage)-loose curved stem (maturing stage)' under natural long-day (NLD) conditions, and 'loose tiller angle (tillering and heading stages)-loose tiller angle and curved stem (maturing stage)' under natural short-day (NSD) conditions, while RIL-C exhibits a compact plant architecture both under NLD and NSD conditions throughout growth. The candidate locus was mapped to the chromosome 9 tail via the rice 8K chip assay and map-based cloning. Sequencing, complementary tests, and gene knockout tests demonstrated that Tiller Angle Control 1 ( TAC1 ) is responsible for dynamic plant architecture in RIL-D. Moreover, TAC1 positively regulates loose plant architecture, and high TAC1 expression cannot influence the expression of tested tiller-angle-related genes. Our results reveal that TAC1 is necessary for the dynamic changes in plant architecture, which can guide improvements in plant architecture during the modern super rice breeding.
Keyphrases
  • cell wall
  • genome wide
  • high throughput
  • gene expression
  • dna methylation
  • transcription factor
  • low cost
  • genome wide identification