A transcriptional regulator that boosts grain yields and shortens the growth duration of rice

Shaobo Wei; Xia Li; Zefu Lu; Hui Zhang; Xiangyuan Ye; Yujie Zhou; Jing Li; Yanyan Yan; Hongcui Pei; Fengying Duan; Danying Wang; Song Chen; Peng Wang; Chao Zhang; Lianguang Shang; Yue Zhou; Peng Yan; Ming Zhao; Jirong Huang; Ralph Bock; Qian Qian; Wenbin Zhou

doi:10.1126/science.abi8455

A transcriptional regulator that boosts grain yields and shortens the growth duration of rice

Shaobo Wei(Chinese Academy of Agricultural Sciences), Xia Li(Chinese Academy of Agricultural Sciences), Zefu Lu(Chinese Academy of Agricultural Sciences), Hui Zhang(Shanghai Normal University), Xiangyuan Ye(Chinese Academy of Agricultural Sciences), Yujie Zhou(Peking University), Jing Li(Chinese Academy of Agricultural Sciences), Yanyan Yan(Chinese Academy of Agricultural Sciences), Hongcui Pei(Chinese Academy of Agricultural Sciences), Fengying Duan(Chinese Academy of Agricultural Sciences), Danying Wang(Chinese Academy of Agricultural Sciences), Song Chen(Chinese Academy of Agricultural Sciences), Peng Wang(Chinese Academy of Sciences), Chao Zhang(Agricultural Genomics Institute at Shenzhen), Lianguang Shang(Agricultural Genomics Institute at Shenzhen), Yue Zhou(Peking University), Peng Yan(Peking University), Ming Zhao(Chinese Academy of Agricultural Sciences), Jirong Huang(Shanghai Normal University), Ralph Bock(Max Planck Institute of Molecular Plant Physiology), Qian Qian(Chinese Academy of Agricultural Sciences), Wenbin Zhou(Chinese Academy of Agricultural Sciences)

Science

July 21, 2022

10.1126/science.abi8455

Cited by 296

Abstract

Complex biological processes such as plant growth and development are often under the control of transcription factors that regulate the expression of large sets of genes and activate subordinate transcription factors in a cascade-like fashion. Here, by screening candidate photosynthesis-related transcription factors in rice, we identified a DREB (Dehydration Responsive Element Binding) family member, OsDREB1C, in which expression is induced by both light and low nitrogen status. We show that OsDREB1C drives functionally diverse transcriptional programs determining photosynthetic capacity, nitrogen utilization, and flowering time. Field trials with OsDREB1C -overexpressing rice revealed yield increases of 41.3 to 68.3% and, in addition, shortened growth duration, improved nitrogen use efficiency, and promoted efficient resource allocation, thus providing a strategy toward achieving much-needed increases in agricultural productivity.

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