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Suppressing spikelet degeneration increases grain yield under moderate soil drying during meiosis in rice

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  • Zhong, Xiaohan
  • Lin, Chenyu
  • Gu, Yunyi
  • Zhu, Kuanyu
  • Xu, Yunji
  • Wang, Weilu
  • Zhang, Hao
  • Gu, Junfei
  • Wang, Zhiqin
  • Zhang, Zujian
  • Liu, Lijun
  • Zhang, Jianhua
  • Yang, Jianchang
  • Zhang, Weiyang

Abstract

Spikelet degeneration is a critical physiological issue that limits grain yield in rice (Oryza sativa L.), influenced by soil moisture conditions during meiosis. The study aimed to investigate the role and mechanism of moderate soil drying in spikelet degeneration and grain yield, as well as to establish a strategy and irrigation regime for suppressing spikelet degeneration to increase grain yield in rice. Field experiments were conducted involving two irrigation regimes: conventional well-watered (C-WW) and moderate soil drying (M-SD) during meiosis. Transgenic rice lines and chemical regulators were employed to elucidate the underlying partial biological mechanisms of this process. The results showed that M-SD regime effectively reduced spikelet degeneration rate and increased grain yield compared to C-WW. This improvement under M-SD regime was primarily attributed to the enhanced proline and aquaporin-mediated osmotic balance and redox homeostasis in young rice panicles, as well as the increased root activity during meiosis. The increased levels of brassinosteroids (BRs) and decreased levels of ethylene (ETH) in young panicles under the M-SD were closely associated with the enhanced proline and aquaporin-mediated osmotic balance and redox homeostasis, decreased oxidative damage, and reduced spikelet degeneration rate. The intrinsic relationship among key aquaporin genes expression and proline levels, osmotic balance and redox homeostasis, spikelet degeneration rate, as well as BRs and ETH levels, was further confirmed through the use of transgenic rice lines and chemical regulators. Collectively, an M-SD regime during meiosis can effectively suppress spikelet degeneration and thereby enhance grain yield, primarily through well-maintained osmotic balance and redox homeostasis in rice.

Suggested Citation

  • Zhong, Xiaohan & Lin, Chenyu & Gu, Yunyi & Zhu, Kuanyu & Xu, Yunji & Wang, Weilu & Zhang, Hao & Gu, Junfei & Wang, Zhiqin & Zhang, Zujian & Liu, Lijun & Zhang, Jianhua & Yang, Jianchang & Zhang, Weiya, 2024. "Suppressing spikelet degeneration increases grain yield under moderate soil drying during meiosis in rice," Agricultural Water Management, Elsevier, vol. 301(C).
    • Handle: RePEc:eee:agiwat:v:301:y:2024:i:c:s0378377424003007
    DOI: 10.1016/j.agwat.2024.108965
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    References listed on IDEAS

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    1. Xing Huo & Shuang Wu & Zuofeng Zhu & Fengxia Liu & Yongcai Fu & Hongwei Cai & Xianyou Sun & Ping Gu & Daoxin Xie & Lubin Tan & Chuanqing Sun, 2017. "NOG1 increases grain production in rice," Nature Communications, Nature, vol. 8(1), pages 1-11, December.
    2. Tao Guo & Zi-Qi Lu & Yehui Xiong & Jun-Xiang Shan & Wang-Wei Ye & Nai-Qian Dong & Yi Kan & Yi-Bing Yang & Huai-Yu Zhao & Hong-Xiao Yu & Shuang-Qin Guo & Jie-Jie Lei & Ben Liao & Jijie Chai & Hong-Xuan, 2023. "Optimization of rice panicle architecture by specifically suppressing ligand–receptor pairs," Nature Communications, Nature, vol. 14(1), pages 1-15, December.
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