Jiajun Liu, Ye Song, Min Mei, Xuebin Zhao, Shu Wan, Qian Xun, Yayi Meng, Jianyu An, Ganghua Li, Yanfeng Ding, Chengqiang Ding
{"title":"基因编辑从曾经有害的RFL中解锁优质突变体,以提高水稻产量性状","authors":"Jiajun Liu, Ye Song, Min Mei, Xuebin Zhao, Shu Wan, Qian Xun, Yayi Meng, Jianyu An, Ganghua Li, Yanfeng Ding, Chengqiang Ding","doi":"10.1111/tpj.70454","DOIUrl":null,"url":null,"abstract":"<div>\n \n <p><i>RICE FLORICULA LEAFY/ABERRANT PANICLE ORGANIZATION 2</i> (<i>RFL/APO2</i>) is a master regulator of panicle morphogenesis and development in rice. Traditionally, mutations in <i>RFL</i> have led to severe growth phenotypes and decreased rice yield, labeling it as detrimental. However, the present study challenged this perception by utilizing CRISPR/Cpf1 and single-base gene-editing technologies to generate a series of site-directed <i>rfl</i> mutants. Our findings revealed that the evolutionarily conserved sterile alpha motif (SAM) domain and DNA-binding domain (DBD), as well as the intron region of <i>RFL</i>, all play roles in regulating rice morphological development and yield traits. Specifically, introns and the SAM domain are primarily involved in panicle development, whereas the DBD and its key functional sites are closely associated with morphological development and yield. Notably, the amino acid at position 266 was found to be a critical site for RFL regulation of grain shape, significantly affecting grain weight, with changes in the expression levels of genes involved in grain length and panicle weight regulation, such as <i>GRF1</i> and <i>SPL16</i>. This study not only expands our understanding of the role of RFL in monocot plants but also provides a novel perspective on how gene editing can transform a gene once considered detrimental to improve yield traits in cereal crops. These findings suggest that the number of genes available for optimizing rice phenotypes through gene editing can be significantly increased.</p>\n </div>","PeriodicalId":233,"journal":{"name":"The Plant Journal","volume":"123 5","pages":""},"PeriodicalIF":5.7000,"publicationDate":"2025-08-29","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Gene editing unlocks superior mutants from once detrimental RFL for enhanced rice yield traits\",\"authors\":\"Jiajun Liu, Ye Song, Min Mei, Xuebin Zhao, Shu Wan, Qian Xun, Yayi Meng, Jianyu An, Ganghua Li, Yanfeng Ding, Chengqiang Ding\",\"doi\":\"10.1111/tpj.70454\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<div>\\n \\n <p><i>RICE FLORICULA LEAFY/ABERRANT PANICLE ORGANIZATION 2</i> (<i>RFL/APO2</i>) is a master regulator of panicle morphogenesis and development in rice. Traditionally, mutations in <i>RFL</i> have led to severe growth phenotypes and decreased rice yield, labeling it as detrimental. However, the present study challenged this perception by utilizing CRISPR/Cpf1 and single-base gene-editing technologies to generate a series of site-directed <i>rfl</i> mutants. Our findings revealed that the evolutionarily conserved sterile alpha motif (SAM) domain and DNA-binding domain (DBD), as well as the intron region of <i>RFL</i>, all play roles in regulating rice morphological development and yield traits. Specifically, introns and the SAM domain are primarily involved in panicle development, whereas the DBD and its key functional sites are closely associated with morphological development and yield. Notably, the amino acid at position 266 was found to be a critical site for RFL regulation of grain shape, significantly affecting grain weight, with changes in the expression levels of genes involved in grain length and panicle weight regulation, such as <i>GRF1</i> and <i>SPL16</i>. This study not only expands our understanding of the role of RFL in monocot plants but also provides a novel perspective on how gene editing can transform a gene once considered detrimental to improve yield traits in cereal crops. 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Gene editing unlocks superior mutants from once detrimental RFL for enhanced rice yield traits
RICE FLORICULA LEAFY/ABERRANT PANICLE ORGANIZATION 2 (RFL/APO2) is a master regulator of panicle morphogenesis and development in rice. Traditionally, mutations in RFL have led to severe growth phenotypes and decreased rice yield, labeling it as detrimental. However, the present study challenged this perception by utilizing CRISPR/Cpf1 and single-base gene-editing technologies to generate a series of site-directed rfl mutants. Our findings revealed that the evolutionarily conserved sterile alpha motif (SAM) domain and DNA-binding domain (DBD), as well as the intron region of RFL, all play roles in regulating rice morphological development and yield traits. Specifically, introns and the SAM domain are primarily involved in panicle development, whereas the DBD and its key functional sites are closely associated with morphological development and yield. Notably, the amino acid at position 266 was found to be a critical site for RFL regulation of grain shape, significantly affecting grain weight, with changes in the expression levels of genes involved in grain length and panicle weight regulation, such as GRF1 and SPL16. This study not only expands our understanding of the role of RFL in monocot plants but also provides a novel perspective on how gene editing can transform a gene once considered detrimental to improve yield traits in cereal crops. These findings suggest that the number of genes available for optimizing rice phenotypes through gene editing can be significantly increased.
期刊介绍:
Publishing the best original research papers in all key areas of modern plant biology from the world"s leading laboratories, The Plant Journal provides a dynamic forum for this ever growing international research community.
Plant science research is now at the forefront of research in the biological sciences, with breakthroughs in our understanding of fundamental processes in plants matching those in other organisms. The impact of molecular genetics and the availability of model and crop species can be seen in all aspects of plant biology. For publication in The Plant Journal the research must provide a highly significant new contribution to our understanding of plants and be of general interest to the plant science community.
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