Frontiers in Plant Science (Jul 2022)

Identification of candidate genes and clarification of the maintenance of the green pericarp of weedy rice grains

  • Zhenyun Han,
  • Fei Li,
  • Weihua Qiao,
  • Weihua Qiao,
  • Baoxuan Nong,
  • Yunlian Cheng,
  • Lifang Zhang,
  • Jingfen Huang,
  • Yanyan Wang,
  • Danjing Lou,
  • Jinyue Ge,
  • Meng Xing,
  • Weiya Fan,
  • Yamin Nie,
  • Wenlong Guo,
  • Shizhuang Wang,
  • Ziran Liu,
  • Danting Li,
  • Xiaoming Zheng,
  • Xiaoming Zheng,
  • Xiaoming Zheng,
  • Qingwen Yang,
  • Qingwen Yang

DOI
https://doi.org/10.3389/fpls.2022.930062
Journal volume & issue
Vol. 13

Abstract

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The weedy rice (Oryza sativa f. spontanea) pericarp has diverse colors (e.g., purple, red, light-red, and white). However, research on pericarp colors has focused on red and purple, but not green. Unlike many other common weedy rice resources, LM8 has a green pericarp at maturity. In this study, the coloration of the LM8 pericarp was evaluated at the cellular and genetic levels. First, an examination of their ultrastructure indicated that LM8 chloroplasts were normal regarding plastid development and they contained many plastoglobules from the early immature stage to maturity. Analyses of transcriptome profiles and differentially expressed genes revealed that most chlorophyll (Chl) degradation-related genes in LM8 were expressed at lower levels than Chl a/b cycle-related genes in mature pericarps, suggesting that the green LM8 pericarp was associated with inhibited Chl degradation in intact chloroplasts. Second, the F2 generation derived from a cross between LM8 (green pericarp) and SLG (white pericarp) had a pericarp color segregation ratio of 9:3:4 (green:brown:white). The bulked segregant analysis of the F2 populations resulted in the identification of 12 known genes in the chromosome 3 and 4 hotspot regions as candidate genes related to Chl metabolism in the rice pericarp. The RNA-seq and sqRT-PCR assays indicated that the expression of the Chl a/b cycle-related structural gene DVR (encoding divinyl reductase) was sharply up-regulated. Moreover, genes encoding magnesium-chelatase subunit D and the light-harvesting Chl a/b-binding protein were transcriptionally active in the fully ripened dry pericarp. Regarding the ethylene signal transduction pathway, the CTR (encoding an ethylene-responsive protein kinase) and ERF (encoding an ethylene-responsive factor) genes expression profiles were determined. The findings of this study highlight the regulatory roles of Chl biosynthesis- and degradation-related genes influencing Chl accumulation during the maturation of the LM8 pericarp.

Keywords