Cold stress is one of the major abiotic stress factors affecting rice growth and development,leading to significant yield loss in the context of global climate change.Exploring natural variants that confer cold resist...Cold stress is one of the major abiotic stress factors affecting rice growth and development,leading to significant yield loss in the context of global climate change.Exploring natural variants that confer cold resistance and the underlying molecular mechanism responsible for this is the major strategy to breed cold-tolerant rice varieties.Here,we show that natural variations of a SIMILAR to RCD ONE(SRO)gene,OsSRO1c,confer cold tolerance in rice at both seedling and booting stages.Our in vivo and in vitro experiments demonstrated that OsSRO1c possesses intrinsic liquid–liquid phase-separation ability and recruits OsDREB2B,an AP2/ERF transcription factor that functions as a positive regulator of cold stress,into its biomolecular condensates in the nucleus,resulting in elevated transcriptional activity of OsDREB2B.We found that the OsSRO1c-OsDREB2B complex directly responds to low temperature through dynamic phase transitions and regulates key cold-response genes,including COLD1.Furthermore,we showed that introgression of an elite haplotype of OsSRO1c into a cold-susceptible indica rice could significantly increase its cold resistance.Collectively,our work reveals a novel cold-tolerance regulatory module in rice and provides promising genetic targets for molecular breeding of cold-tolerant rice varieties.展开更多
Liquid-liquid phase separation(LLPS)has become a widely accepted mechanism forthedynamic compartmentalization of different cellular components into membraneless organelles or other cellular bodies.LLPS occurs when the...Liquid-liquid phase separation(LLPS)has become a widely accepted mechanism forthedynamic compartmentalization of different cellular components into membraneless organelles or other cellular bodies.LLPS occurs when the concentration of a protein,nucleic acid,or other molecule reaches a saturation concentration and its partition into high-and low-concentration phases is energetically favorable.展开更多
基金supported by grants from the National Key Research and Development Program of China(2022YFF1001604)distinguished young scholar grant from the Department of Science and Technology of Hubei Province(2023AFA095)+1 种基金Fundamental Research Fund of Central Universities(2662023PY002 and 2662022SKYJ003)The computations in this paper were run on the bioinformatics computing platform of the National Key Laboratory of Crop Genetic Improvement,Huazhong Agricultural University.
文摘Cold stress is one of the major abiotic stress factors affecting rice growth and development,leading to significant yield loss in the context of global climate change.Exploring natural variants that confer cold resistance and the underlying molecular mechanism responsible for this is the major strategy to breed cold-tolerant rice varieties.Here,we show that natural variations of a SIMILAR to RCD ONE(SRO)gene,OsSRO1c,confer cold tolerance in rice at both seedling and booting stages.Our in vivo and in vitro experiments demonstrated that OsSRO1c possesses intrinsic liquid–liquid phase-separation ability and recruits OsDREB2B,an AP2/ERF transcription factor that functions as a positive regulator of cold stress,into its biomolecular condensates in the nucleus,resulting in elevated transcriptional activity of OsDREB2B.We found that the OsSRO1c-OsDREB2B complex directly responds to low temperature through dynamic phase transitions and regulates key cold-response genes,including COLD1.Furthermore,we showed that introgression of an elite haplotype of OsSRO1c into a cold-susceptible indica rice could significantly increase its cold resistance.Collectively,our work reveals a novel cold-tolerance regulatory module in rice and provides promising genetic targets for molecular breeding of cold-tolerant rice varieties.
基金Funding in our lab is provided by support from the ANR(ANR-19-CE20-0021).
文摘Liquid-liquid phase separation(LLPS)has become a widely accepted mechanism forthedynamic compartmentalization of different cellular components into membraneless organelles or other cellular bodies.LLPS occurs when the concentration of a protein,nucleic acid,or other molecule reaches a saturation concentration and its partition into high-and low-concentration phases is energetically favorable.
