Significantly increasing crop yield is a major and worldwide challenge for food supply and security.It is well-known that rice cultivated at Taoyuan in Yunnan of China can produce the highest yield worldwide.Yet,the g...Significantly increasing crop yield is a major and worldwide challenge for food supply and security.It is well-known that rice cultivated at Taoyuan in Yunnan of China can produce the highest yield worldwide.Yet,the gene regulatory mechanism underpinning this ultrahigh yield has been a mystery.Here,we systematically collected the transcriptome data for seven key tissues at different developmental stages using rice cultivated both at Taoyuan as the case group and at another regular rice planting place Jinghong as the control group.We identified the top 24 candidate high-yield genes with their network modules from these well-designed datasets by developing a novel computational systems biology method,i.e.,dynamic cross-tissue(DCT)network analysis.We used one of the candidate genes,Os SPL4,whose function was previously unknown,for gene editing experimental validation of the high yield,and confirmed that Os SPL4 significantly affects panicle branching and increases the rice yield.This study,which included extensive field phenotyping,cross-tissue systems biology analyses,and functional validation,uncovered the key genes and gene regulatory networks underpinning the ultrahigh yield of rice.The DCT method could be applied to other plant or animal systems if different phenotypes under various environments with the common genome sequences of the examined sample.DCT can be downloaded from https://github.com/ztpub/DCT.展开更多
Dear Editor, Oryza Iongistaminata is an African wild rice species with AA genome type possessing special traits that are highly valued for improving cultivated rice, such as strong resistance to biotic and abiotic str...Dear Editor, Oryza Iongistaminata is an African wild rice species with AA genome type possessing special traits that are highly valued for improving cultivated rice, such as strong resistance to biotic and abiotic stresses (Song et al., 1995) for improving resistance of cultivars, rhizomatousness for perennial breeding (Glover et al., 2010), and self-incompatibility (SI) for new ways to produce hybrid seeds (Ghesquiere, 1986). Deciphering the genome of O. Iongistaminata will be the key to uncovering the mechanism of these hallmark traits and improving cultivated rice.展开更多
基金the National Basic Research Program of China(Grant No.2013CB835200)the National Key R&D Program of China(Grant No.2017YFA0505500)+4 种基金the Key Grant of Yunnan Provincial Science and Technology Department(Grant No.2013GA004)the Strategic Priority Research Program of the Chinese Academy of Sciences(Grant No.XDB13040700)the National Natural Science Foundation of China(Grant Nos.11871456 and 31771476)the Shanghai Municipal Science and Technology Major Project(Grant No.2017SHZDZX01)the Open Research Fund of State Key Laboratory of Hybrid Rice(Wuhan University,Grant No.KF201806),China。
文摘Significantly increasing crop yield is a major and worldwide challenge for food supply and security.It is well-known that rice cultivated at Taoyuan in Yunnan of China can produce the highest yield worldwide.Yet,the gene regulatory mechanism underpinning this ultrahigh yield has been a mystery.Here,we systematically collected the transcriptome data for seven key tissues at different developmental stages using rice cultivated both at Taoyuan as the case group and at another regular rice planting place Jinghong as the control group.We identified the top 24 candidate high-yield genes with their network modules from these well-designed datasets by developing a novel computational systems biology method,i.e.,dynamic cross-tissue(DCT)network analysis.We used one of the candidate genes,Os SPL4,whose function was previously unknown,for gene editing experimental validation of the high yield,and confirmed that Os SPL4 significantly affects panicle branching and increases the rice yield.This study,which included extensive field phenotyping,cross-tissue systems biology analyses,and functional validation,uncovered the key genes and gene regulatory networks underpinning the ultrahigh yield of rice.The DCT method could be applied to other plant or animal systems if different phenotypes under various environments with the common genome sequences of the examined sample.DCT can be downloaded from https://github.com/ztpub/DCT.
基金This work was supported by the National Natural Science Foundation of China (U1302264) to F.H., the National Basic Research Program of China (2013CB835200, 2013CB835201) and the Department of Sciences and Technology of Yunnan Province (2013GA004) to W.W. and F.H.We would like to thank Xueyan Li of the Kunming Institute of Zoology, Chinese Academy of Science, for helpful discussions. We would also like to thank Andrew Willden for English language editing of the manuscript. No conflict of interest declared.
文摘Dear Editor, Oryza Iongistaminata is an African wild rice species with AA genome type possessing special traits that are highly valued for improving cultivated rice, such as strong resistance to biotic and abiotic stresses (Song et al., 1995) for improving resistance of cultivars, rhizomatousness for perennial breeding (Glover et al., 2010), and self-incompatibility (SI) for new ways to produce hybrid seeds (Ghesquiere, 1986). Deciphering the genome of O. Iongistaminata will be the key to uncovering the mechanism of these hallmark traits and improving cultivated rice.
