Asian cultivated rice is one of the most important cereal crops globally,feeding approximately 50%of the world's population.Increasing rice nitrogen use efficiency(NUE)is crucial for achieving high yields with low...Asian cultivated rice is one of the most important cereal crops globally,feeding approximately 50%of the world's population.Increasing rice nitrogen use efficiency(NUE)is crucial for achieving high yields with low nitrogen inputs(Xu et al.,2012;Hu et al.,2023).However,modern cultivars are typically bred for high yields through excessive nitrogen fertilizer use,leading to the loss of beneficial alleles associated with high NUE during the breeding process(Wang and Peng,2017;Hu et al.,2023).Genetic improvement for high NUE should be a key strategy in breeding“Green Super Rice”(GSR)(Yu et al.,2021)and water-saving and drought-resistance rice(WDR)(Luo,2010;Xia et al.,2022)for sustainable agriculture.Asian cultivated rice is highly diverse and harbors vital genetic variants essential for adaptation to different environments(Wing et al.,2018).展开更多
Rice has a large number of nitrate or peptide transporter family(NPF) genes, but the effects of most members on rice growth and development are unknown. We report that Os NPF5.16, a nitrate transporter gene with natur...Rice has a large number of nitrate or peptide transporter family(NPF) genes, but the effects of most members on rice growth and development are unknown. We report that Os NPF5.16, a nitrate transporter gene with natural variation in its promoter sequence, is essential for rice growth and yield. The promoter sequence showed various differences between indica and japonica cultivars, and higher expression of Os NPF5.16 was found in indica cultivars with higher plant weight and more tillers than japonica cultivars.Os NPF5.16 was highly expressed in roots, tiller basal parts, and leaf sheaths, and its protein was localized on the plasma membrane. In c RNA-injected Xenopus laevis oocytes, Os NPF5.16 transport of nitrate at high nitrate concentration depended on p H. Overexpression of Os NPF5.16 increased nitrate content and total nitrogen content in leaf sheath as well as biomass and tiller bud length in rice. Elevated expression of Os NPF5.16 increased rice tiller number and grain yield by regulating cytokinin levels. Inhibition of Os NPF5.16 expression showed the opposite effects. Regulating Os NPF5.16 expression has potential for improving rice grain yield.展开更多
The overuse of nitrogen(N)fertilizer in fields has increased production costs and raised environmental concerns.Increasing the N use efficiency(NUE)of rice varieties is crucial for sustainable agriculture.Here we repo...The overuse of nitrogen(N)fertilizer in fields has increased production costs and raised environmental concerns.Increasing the N use efficiency(NUE)of rice varieties is crucial for sustainable agriculture.Here we report the cloning and characterization of OsNPF3.1,a gene that controls rice NUE.An amino acid mutation in the OsNPF3.1 coding region caused different NUEs in wild and cultivated rice.OsNPF3.1,which is expressed mainly in the aerial parts of rice,also affects rice plant height,heading date,and thousand-grain weight.The OsNPF3.1 protein is located in the plasma membrane.When OsNPF3.1 was subjected to artificial selection,two naturally varying loci were associated with NUE,of which OsNPF3.1Chr6_8741040differed between indica and japonica rice.OsNPF3.1 can be used as a new target gene for breeding rice varieties with high NUE.展开更多
基金supported by Joint Funds of National Natural Science Foundation of China(U24A20399)Natural Science Foundation of Shanghai(23JC1403500,22ZR1455300)+2 种基金Specific university discipline construction project(2023B10564002,2023B10564004)Shanghai Agricultural Science and Technology Innovation Program(2024-02-08-00-12-F00028)Earmarked Fund for China Agriculture Research System(CARS-01).
文摘Asian cultivated rice is one of the most important cereal crops globally,feeding approximately 50%of the world's population.Increasing rice nitrogen use efficiency(NUE)is crucial for achieving high yields with low nitrogen inputs(Xu et al.,2012;Hu et al.,2023).However,modern cultivars are typically bred for high yields through excessive nitrogen fertilizer use,leading to the loss of beneficial alleles associated with high NUE during the breeding process(Wang and Peng,2017;Hu et al.,2023).Genetic improvement for high NUE should be a key strategy in breeding“Green Super Rice”(GSR)(Yu et al.,2021)and water-saving and drought-resistance rice(WDR)(Luo,2010;Xia et al.,2022)for sustainable agriculture.Asian cultivated rice is highly diverse and harbors vital genetic variants essential for adaptation to different environments(Wing et al.,2018).
基金supported by the National Key Research and Development Program(2016YFD0100700)the Wuhan Science and Technology Project(2020020601012259)+4 种基金Hubei Natural Science Foundation(2020CFB117)the National Natural Science Foundation of China(31301250)the Talent Project from Guizhou Education Department(Qian jiao he KY zi(2021)024)the Key Cultivation Project of Guizhou University(201903)the Talent Project from Thousands of Innovative and Entrepreneurial in Guizhou Province。
文摘Rice has a large number of nitrate or peptide transporter family(NPF) genes, but the effects of most members on rice growth and development are unknown. We report that Os NPF5.16, a nitrate transporter gene with natural variation in its promoter sequence, is essential for rice growth and yield. The promoter sequence showed various differences between indica and japonica cultivars, and higher expression of Os NPF5.16 was found in indica cultivars with higher plant weight and more tillers than japonica cultivars.Os NPF5.16 was highly expressed in roots, tiller basal parts, and leaf sheaths, and its protein was localized on the plasma membrane. In c RNA-injected Xenopus laevis oocytes, Os NPF5.16 transport of nitrate at high nitrate concentration depended on p H. Overexpression of Os NPF5.16 increased nitrate content and total nitrogen content in leaf sheath as well as biomass and tiller bud length in rice. Elevated expression of Os NPF5.16 increased rice tiller number and grain yield by regulating cytokinin levels. Inhibition of Os NPF5.16 expression showed the opposite effects. Regulating Os NPF5.16 expression has potential for improving rice grain yield.
基金supported by the National Natural Science Foundation of China(32060476 and 31860371)Guangxi Department of Science and Technology(AA22068087-4)+3 种基金Guangxi Natural Science Foundation of China(2015GXNSFAA139054,2018GXNSFAA138124,and 2020GXNSFAA259041)Guangxi Ministry of Science and Technology(AB21238009)Special Fund of Local Science and Technology Development for the Central Guidance(ZY21195034)Guangxi Academy of Agricultural Sciences(2021JM04,2021JM49,2021YT030,QN-25,and QN-35)。
文摘The overuse of nitrogen(N)fertilizer in fields has increased production costs and raised environmental concerns.Increasing the N use efficiency(NUE)of rice varieties is crucial for sustainable agriculture.Here we report the cloning and characterization of OsNPF3.1,a gene that controls rice NUE.An amino acid mutation in the OsNPF3.1 coding region caused different NUEs in wild and cultivated rice.OsNPF3.1,which is expressed mainly in the aerial parts of rice,also affects rice plant height,heading date,and thousand-grain weight.The OsNPF3.1 protein is located in the plasma membrane.When OsNPF3.1 was subjected to artificial selection,two naturally varying loci were associated with NUE,of which OsNPF3.1Chr6_8741040differed between indica and japonica rice.OsNPF3.1 can be used as a new target gene for breeding rice varieties with high NUE.
