The chalcone isomerase gene OsCHI,one of the key genes in the flavonoid biosynthesis pathway,plays an important role in rice(Oryza sativa)resistance to abiotic stresses.This study reveals how the chalcone isomerase ge...The chalcone isomerase gene OsCHI,one of the key genes in the flavonoid biosynthesis pathway,plays an important role in rice(Oryza sativa)resistance to abiotic stresses.This study reveals how the chalcone isomerase gene family member OsCHI3 participates in rice responses to drought stress through the regulation of flavonoid biosynthesis.Overexpression of OsCHI3 increased the tolerance of rice to drought stress.In contrast,CRISPR/Cas9-mediated deletion of OsCHI3 reduced the drought tolerance of rice,an effect that is reversed by exogenous ABA treatment.Transcriptomic and physiological biochemical analyses indicated that flavonoids regulated by OsCHI3 not only scavenge reactive oxygen species(ROS)but also increase drought tolerance in rice by stimulating ABA biosynthesis through the regulation of OsNCED1 and OsABA8ox3 expression.These findings demonstrate that OsCHI3 increases drought stress tolerance in rice by activating the antioxidant defense system and the ABA metabolic pathway,providing new clues for drought-resistant rice breeding research.展开更多
The ratooning system enhances agricultural efficiency by reducing secondary sowing and resource input while maintaining rice yield parity with double cropping.However,the prolonged growth duration of the rice ratoonin...The ratooning system enhances agricultural efficiency by reducing secondary sowing and resource input while maintaining rice yield parity with double cropping.However,the prolonged growth duration of the rice ratooning system extends the exposure window to Magnaporthe oryzae infection,thereby elevating the probability of disease incidence.展开更多
Ratoon rice(Oryza sativa L.)is a sustainable planting model,and its planting area has been increasing year by year.However,there is a lack of literature reviewing the measures and mechanisms to regulate the regenerati...Ratoon rice(Oryza sativa L.)is a sustainable planting model,and its planting area has been increasing year by year.However,there is a lack of literature reviewing the measures and mechanisms to regulate the regeneration rate,as well as the challenges in the production of ratoon rice.This study explores the effects of different varieties,climatic conditions(light and temperature),and cultivation measures(fertilizer management,cropping system,harvest method,water management,and plant growth regulators)on the regeneration rate and grain yield of the ratoon season.It summarizes and analyzes the possible mechanisms that affect the germination of regenerated buds from the perspectives of material accumulation and transportation,hormone metabolism,and molecular mechanisms,and identifies main factors currently limiting the development of ratoon rice.A significant positive correlation between the regeneration rate and grain yield of the ratoon season was found,regulated by varieties,temperatures,light resources,and cultivation measures.Improving the regeneration rate can effectively increase the production of ratoon rice.Notably,rice varieties with high regeneration ability exhibit characteristics such as a suitable growth period,a developed root system,high single-stem weight,a relatively small ratio of grain number to green leaf area,and strong lodging resistance in the main season.Additionally,the germination of regenerated buds is regulated by the accumulation and transport of endogenous hormones(indole-3-acetic acid,gibberellins,and cytokinins),photoassimilates(non-structural carbohydrates),and reactive oxygen metabolism.To further demonstrate the grain yield potential of the ratoon season,improvements are needed in three key areas:the cultivation system of low-stubble ratoon rice,the development of specialized harvesters,and the breeding of rice varieties with high-temperature tolerance during the main crop and low-temperature tolerance during the ratoon crop.展开更多
Asian rice comprises two major subspecies:Xian(X)and Geng(G),and the diverged resistance genes(R)have provided a foundation for breeding improved cultivars to control rice blast disease.After conducting two-phase alle...Asian rice comprises two major subspecies:Xian(X)and Geng(G),and the diverged resistance genes(R)have provided a foundation for breeding improved cultivars to control rice blast disease.After conducting two-phase allele mining using six updated FNP marker systems,the functional haplotypes at Pit,Pib,and Pi63 strictly diverged into the X-populations and were defined as X-R loci,while those at Pi54,Pi37,and Pi36 into the G-populations as G-R loci.The genic diversity at the three X-R loci(16 alleles)was twofold higher than that at the three G-R loci(8 alleles),and the allelic diversity in the Southern region(21 alleles)was nearly double that in the Northeastern region(11 alleles).Both observations reflect a significant difference in genetic diversity between X-and G-populations,and indicate that the effective R-genes mainly originated from X-subspecies.Based on the allelic structures characterized by a set of 10 parameters,8 and 16 alleles were respectively recognized as favorable and promising ones for the regional breeding programs.The genotypic structures of the two regional populations were almost different,indicating that the diverged alleles have been further assembled into two series of regional genotypes through long-term breeding programs,despite the presence of one-third of region-common alleles.The genotypic diversity in the Southern region(55 genotypes)was nearly twice as high as that in the Northeastern region(28),which perfectly reflects the aforementioned differences in both genic and allelic diversities.After analyzing the genotypic structures using a set of 13 parameters,4 and 23 genotypes,respectively,can be recommended as the favorable and promising ones for the regional breeding programs.The case study serves as a concrete sample of how to identify the favorable and promising alleles and genotypes,and beneficial parents based their comprehensive population structures for gene-designed breeding.展开更多
Rice,a critical global staple crop,relies heavily on heading date,a key agronomic trait marking the transition from vegetative to reproductive growth.Understanding the genetic regulation of heading date is vital for e...Rice,a critical global staple crop,relies heavily on heading date,a key agronomic trait marking the transition from vegetative to reproductive growth.Understanding the genetic regulation of heading date is vital for enhancing the adaptability of high-quality rice varieties across diverse geographical regions and for bolstering local food security.In this study,we uncovered a novel role for OsCATA,a catalase gene,in the regulation of photoperiodic flowering in rice.We identified a novel allele of OsELF3.1,whose mutation resulted in delayed heading.Further analyses revealed that OsELF3.1 physically interacted with OsCATA.Notably,OsCATA exhibited rhythmic expression patterns similar to OsELF3.1 and,when mutated,also delayed flowering.Expression analyses showed that the delayed heading phenotype could be attributed to elevated Ghd7 expression under both long-day and short-day conditions,with OsCATA expression positively regulated by OsELF3.1.Double mutants of OsELF3.1 and OsCATA displayed a heading delay similar to that of oself3.1 single mutants.Additionally,OsELF3.1 could interact with Ghd7 in vivo,alleviating its suppression of Ehd1.Luciferase assays confirmed that Ghd7 repressed Ehd1 expression,while OsELF3.1 mitigated this repression.Collectively,our findings reveal that OsCATA is critical in suppressing Ghd7 expression through the OsELF3.1-OsCATA-Ghd7 transcriptional pathway,thereby regulating rice heading.展开更多
Leaf color mutants (LCMs) provide crucial insights into the regulatory mechanisms underlying chloroplast development,photo synthesis,and stre ss adaptation.In this study,we identified a temperature-sensitive albino mu...Leaf color mutants (LCMs) provide crucial insights into the regulatory mechanisms underlying chloroplast development,photo synthesis,and stre ss adaptation.In this study,we identified a temperature-sensitive albino mutant,tsa4,characterized by an albino phenotype at the seedling stage and abnormal chloroplast development at temperatures below 25℃.展开更多
Iron is an essential nutrient for plant growth,development,and disease resistance.Plants absorb iron through their roots,with citrate playing a key role in xylem transport of insoluble Fe3+.In this study,we identified...Iron is an essential nutrient for plant growth,development,and disease resistance.Plants absorb iron through their roots,with citrate playing a key role in xylem transport of insoluble Fe3+.In this study,we identified the cytoplasmic ATP-citrate lyase(ACL)subunit A2 in rice(Oryza sativa L.),OsACL-A2(Os12g0566300),as a critical factor for iron uptake and transport.The osacl-a2 mutant exhibited reduced leaf iron levels,leading to iron deficiency-induced chlorosis,activated defense signaling,and eventual necrosis in mature leaves.Additionally,blast resistance was weakened in immature osacl-a2 leaves.Exogenous iron supplementation rescued these defects.The mutant displayed reduced ATP-citrate lyase activity but increased citric acid levels compared with its wild type(WT),suggesting that the osacl-a2 mutation impairs enzyme activity.Thus,OsACL-A2-mediated citrate lyase activity plays a vital role in promoting iron uptake and associated blast resistance in rice.展开更多
Salt stress is a critical factor affecting the growth and yield of rice.Egypt,the largest rice producer in North Africa and the Middle East,is facing contrasting challenges related to salinity in its agroecosystems.In...Salt stress is a critical factor affecting the growth and yield of rice.Egypt,the largest rice producer in North Africa and the Middle East,is facing contrasting challenges related to salinity in its agroecosystems.In this study,we compared the salt-induced responses among three rice varieties:Giza 176(Egyptian variety),Kaituodao(Chinese variety),and Pokkali(Sri Lanka variety,used as control)under normal and saline stress(100 mmol/L NaCl)conditions at two seedling stages through RNA-seq expression analysis.Giza 176 displayed a salt tolerance score of 7 on the SES(Standard Evaluation Score).Its transcriptome showed dynamic changes,with the number of upregulated genes increasing from 180 to 735,and downregulated genes increasing from 918 to 2930 from the one-week to two-week stress stages,with activated pathways in ion transport,reactive oxygen species(ROS)scavenging,and protein biosynthesis.展开更多
Hybrid rice has significantly contributed to China’s food security.Mixed sowing and harvesting of parental lines have proven effective for mechanization and cost reduction.The hull color difference between red and ye...Hybrid rice has significantly contributed to China’s food security.Mixed sowing and harvesting of parental lines have proven effective for mechanization and cost reduction.The hull color difference between red and yellow makes the red hull an ideal germplasm resource for efficient hybrid seed separation.The rice hull of Chuan 7 is red,and genetic linkage analysis combined with fine mapping located the red hull gene,OsRH3,within an 83.5 kb interval,containing 18 predicted genes.展开更多
Rice grain size is a primary characteristic essential for artificial domestication and breeding,governed by grain length,width,and thickness.In this study,we cloned Grain Size 10(GS10),a novel gene via mapbased clonin...Rice grain size is a primary characteristic essential for artificial domestication and breeding,governed by grain length,width,and thickness.In this study,we cloned Grain Size 10(GS10),a novel gene via mapbased cloning.Biochemical,molecular,and genetic studies were performed to elucidate the GS10 involved grain size mechanism in rice.Mutant of GS10 lead to reduced grain size due to alterations in cell expansion.Additionally,GS10 is responsible for the formation of notched-belly grains,especially in smaller grain varieties possessing loss-function mutations.Overexpression of GS10 in Nipponbare results in increasing grain length,grain weight and improve the appearance quality of rice.GS10 encodes conserved protein with uncharacterized function.Furthermore,GS10 regulates the grain size by interacting OsBRICK1,a subunit of the WAVE complex that governs actin nucleation and affects the assembly of microfilaments in rice.Together,our study demonstrates that,GS10 positively regulates the grain length and grain weight,which is beneficial for further improvements in yield characteristics.展开更多
Grain shape as a major determinant of rice yield and quality is widely believed to be controlled by quantitative trait loci(QTL). We have identified a novel gene 'GS2' to largely regulate grain length and widt...Grain shape as a major determinant of rice yield and quality is widely believed to be controlled by quantitative trait loci(QTL). We have identified a novel gene 'GS2' to largely regulate grain length and width in rice. The GS2 allele in the big-grain rice line ‘CDL’functioned in a dominant manner. In the present study, we employed a chromosome walking strategy in the residual heterozygous lines from recombinant inbred population between cultivar 'R1126' and CDL, and located the GS2 gene in an interval of ~33.2 kb flanked by marker GL2-35-1 and GL2-12 in the long arm of rice chromosome 2. According to genome annotations, three putative gene loci, LOC_Os02g47280, LOC_Os02g47290 and LOC_Os02g47300, exist in this candidate region. In addition, allelic analysis with previously reported genes demonstrated that GS2 was novel for regulating rice grain shape. These results will help promote the cloning and functional characterization of the GS2 gene and further develop linked markers to be used in marker-assisted breeding.展开更多
基金supported by Science and Technology Innovation Program of Hunan province(2024NK1010,2023NK1010,2023ZJ1080)the National Natural Science Foundation of China(U21A20208).
文摘The chalcone isomerase gene OsCHI,one of the key genes in the flavonoid biosynthesis pathway,plays an important role in rice(Oryza sativa)resistance to abiotic stresses.This study reveals how the chalcone isomerase gene family member OsCHI3 participates in rice responses to drought stress through the regulation of flavonoid biosynthesis.Overexpression of OsCHI3 increased the tolerance of rice to drought stress.In contrast,CRISPR/Cas9-mediated deletion of OsCHI3 reduced the drought tolerance of rice,an effect that is reversed by exogenous ABA treatment.Transcriptomic and physiological biochemical analyses indicated that flavonoids regulated by OsCHI3 not only scavenge reactive oxygen species(ROS)but also increase drought tolerance in rice by stimulating ABA biosynthesis through the regulation of OsNCED1 and OsABA8ox3 expression.These findings demonstrate that OsCHI3 increases drought stress tolerance in rice by activating the antioxidant defense system and the ABA metabolic pathway,providing new clues for drought-resistant rice breeding research.
基金supported by the Key Research and Development Program Project of Hunan Province, China (Grant No. 2023NK2003)the National Key Research and Development Program of China (Grant No. 2022YFD2301001-03)the National Key Research and Development Program of China (Grant No. 2022YFD2301003)
文摘The ratooning system enhances agricultural efficiency by reducing secondary sowing and resource input while maintaining rice yield parity with double cropping.However,the prolonged growth duration of the rice ratooning system extends the exposure window to Magnaporthe oryzae infection,thereby elevating the probability of disease incidence.
基金supported by the National Natural Science Foundation of China(Grant No.32301934)the Hunan Provincial Natural Science Foundation,China(Grant No.2023JJ40470)+1 种基金Ten Key Technological Projects in Hunan Province Project,China(Grant No.2025QK1006)Changsha Science and Technology Program Project,China(Grant No.kq2404003).
文摘Ratoon rice(Oryza sativa L.)is a sustainable planting model,and its planting area has been increasing year by year.However,there is a lack of literature reviewing the measures and mechanisms to regulate the regeneration rate,as well as the challenges in the production of ratoon rice.This study explores the effects of different varieties,climatic conditions(light and temperature),and cultivation measures(fertilizer management,cropping system,harvest method,water management,and plant growth regulators)on the regeneration rate and grain yield of the ratoon season.It summarizes and analyzes the possible mechanisms that affect the germination of regenerated buds from the perspectives of material accumulation and transportation,hormone metabolism,and molecular mechanisms,and identifies main factors currently limiting the development of ratoon rice.A significant positive correlation between the regeneration rate and grain yield of the ratoon season was found,regulated by varieties,temperatures,light resources,and cultivation measures.Improving the regeneration rate can effectively increase the production of ratoon rice.Notably,rice varieties with high regeneration ability exhibit characteristics such as a suitable growth period,a developed root system,high single-stem weight,a relatively small ratio of grain number to green leaf area,and strong lodging resistance in the main season.Additionally,the germination of regenerated buds is regulated by the accumulation and transport of endogenous hormones(indole-3-acetic acid,gibberellins,and cytokinins),photoassimilates(non-structural carbohydrates),and reactive oxygen metabolism.To further demonstrate the grain yield potential of the ratoon season,improvements are needed in three key areas:the cultivation system of low-stubble ratoon rice,the development of specialized harvesters,and the breeding of rice varieties with high-temperature tolerance during the main crop and low-temperature tolerance during the ratoon crop.
基金funded by grants from the National Key R&D Project(2023YFD1400201-02,2023YFD1400203-02)the National Natural Science Foundation of China(31870137)+1 种基金the National Transgenic Research Project(2015ZX08001-002)the Key R&D Project of Guangdong Province(2022B0202060005).
文摘Asian rice comprises two major subspecies:Xian(X)and Geng(G),and the diverged resistance genes(R)have provided a foundation for breeding improved cultivars to control rice blast disease.After conducting two-phase allele mining using six updated FNP marker systems,the functional haplotypes at Pit,Pib,and Pi63 strictly diverged into the X-populations and were defined as X-R loci,while those at Pi54,Pi37,and Pi36 into the G-populations as G-R loci.The genic diversity at the three X-R loci(16 alleles)was twofold higher than that at the three G-R loci(8 alleles),and the allelic diversity in the Southern region(21 alleles)was nearly double that in the Northeastern region(11 alleles).Both observations reflect a significant difference in genetic diversity between X-and G-populations,and indicate that the effective R-genes mainly originated from X-subspecies.Based on the allelic structures characterized by a set of 10 parameters,8 and 16 alleles were respectively recognized as favorable and promising ones for the regional breeding programs.The genotypic structures of the two regional populations were almost different,indicating that the diverged alleles have been further assembled into two series of regional genotypes through long-term breeding programs,despite the presence of one-third of region-common alleles.The genotypic diversity in the Southern region(55 genotypes)was nearly twice as high as that in the Northeastern region(28),which perfectly reflects the aforementioned differences in both genic and allelic diversities.After analyzing the genotypic structures using a set of 13 parameters,4 and 23 genotypes,respectively,can be recommended as the favorable and promising ones for the regional breeding programs.The case study serves as a concrete sample of how to identify the favorable and promising alleles and genotypes,and beneficial parents based their comprehensive population structures for gene-designed breeding.
基金funded by the Biological Breeding-National Science and Technology Major Projects,China(Grant No.2023ZD04066)the Zhejiang Provincial Natural Science Foundation of China(Grant Nos.LZ24C130006,LTGN24C130007)+5 种基金the Open Project Program of the State Key Laboratory of Rice Biology and Breeding,China(Grant No.20240107)the Xi’nan League Science and Technology Project,China(Grant No.2023DXZD0001)the Joint Research and Development Program on Rice Breeding in Inner Mongolia Autonomous Region,China(Grant No.YZ2023004)the China Agriculture Research System(Grant No.CARS-01)the Central Public-interest Scientific Institution Basal Research Fund,China(Grant No.CPSIBRF-CNRRI-202301)the Agricultural Science and Technology Innovation Program(ASTIP).
文摘Rice,a critical global staple crop,relies heavily on heading date,a key agronomic trait marking the transition from vegetative to reproductive growth.Understanding the genetic regulation of heading date is vital for enhancing the adaptability of high-quality rice varieties across diverse geographical regions and for bolstering local food security.In this study,we uncovered a novel role for OsCATA,a catalase gene,in the regulation of photoperiodic flowering in rice.We identified a novel allele of OsELF3.1,whose mutation resulted in delayed heading.Further analyses revealed that OsELF3.1 physically interacted with OsCATA.Notably,OsCATA exhibited rhythmic expression patterns similar to OsELF3.1 and,when mutated,also delayed flowering.Expression analyses showed that the delayed heading phenotype could be attributed to elevated Ghd7 expression under both long-day and short-day conditions,with OsCATA expression positively regulated by OsELF3.1.Double mutants of OsELF3.1 and OsCATA displayed a heading delay similar to that of oself3.1 single mutants.Additionally,OsELF3.1 could interact with Ghd7 in vivo,alleviating its suppression of Ehd1.Luciferase assays confirmed that Ghd7 repressed Ehd1 expression,while OsELF3.1 mitigated this repression.Collectively,our findings reveal that OsCATA is critical in suppressing Ghd7 expression through the OsELF3.1-OsCATA-Ghd7 transcriptional pathway,thereby regulating rice heading.
基金financially supported by the National Natural Science Foundation of China(Grant Nos.32341026 and 32171998)the Hunan Provincial Science and Technology Innovation Program,China(Grant No.2023NK1010)the Changsha Natural Science Foundation,China(Grant No.20209001).
文摘Leaf color mutants (LCMs) provide crucial insights into the regulatory mechanisms underlying chloroplast development,photo synthesis,and stre ss adaptation.In this study,we identified a temperature-sensitive albino mutant,tsa4,characterized by an albino phenotype at the seedling stage and abnormal chloroplast development at temperatures below 25℃.
基金supported by the Basic Public Welfare Research Program of Zhejiang Province,China(Grant No.LY23C130003)the Fund of the State Key Laboratory of Rice Biology and Breeding,China(Grant No.2023ZZKT20203)+5 种基金the Major Science and Technology Project of Guangxi,China(Grant No.AA23062015)the Agricultural Science and Technology Innovation Program of the Chinese Academy of Agricultural Sciences,China(Grant No.CAAS-ASTIP-2013-CNRRI)the China Rice Research System,China(Grant No.CARS-01-011)the Central Public-Interest Scientific Institution Basal Research Fund,China(Grant No.CPSIBRF-CNRRI-202301)High-Quality and Resistant Hybrid Rice Germplasm Creation and New Varieties Development with International Competitiveness,China(Grant Nos.2022KJCX45 and YBXM2437)Xi’nan League Science and Technology Project,China(Grant No.2023DXZD0001).
文摘Iron is an essential nutrient for plant growth,development,and disease resistance.Plants absorb iron through their roots,with citrate playing a key role in xylem transport of insoluble Fe3+.In this study,we identified the cytoplasmic ATP-citrate lyase(ACL)subunit A2 in rice(Oryza sativa L.),OsACL-A2(Os12g0566300),as a critical factor for iron uptake and transport.The osacl-a2 mutant exhibited reduced leaf iron levels,leading to iron deficiency-induced chlorosis,activated defense signaling,and eventual necrosis in mature leaves.Additionally,blast resistance was weakened in immature osacl-a2 leaves.Exogenous iron supplementation rescued these defects.The mutant displayed reduced ATP-citrate lyase activity but increased citric acid levels compared with its wild type(WT),suggesting that the osacl-a2 mutation impairs enzyme activity.Thus,OsACL-A2-mediated citrate lyase activity plays a vital role in promoting iron uptake and associated blast resistance in rice.
基金funded by the National Key R&D Program of China(Grant No.2022YFE0139400)the Egyptian-Chinese Research Fund,and Science,Technology&Innovation Funding Authority Egypt(Grant No.46512)the National Natural Science Foundation of China(Grant No.261143470).
文摘Salt stress is a critical factor affecting the growth and yield of rice.Egypt,the largest rice producer in North Africa and the Middle East,is facing contrasting challenges related to salinity in its agroecosystems.In this study,we compared the salt-induced responses among three rice varieties:Giza 176(Egyptian variety),Kaituodao(Chinese variety),and Pokkali(Sri Lanka variety,used as control)under normal and saline stress(100 mmol/L NaCl)conditions at two seedling stages through RNA-seq expression analysis.Giza 176 displayed a salt tolerance score of 7 on the SES(Standard Evaluation Score).Its transcriptome showed dynamic changes,with the number of upregulated genes increasing from 180 to 735,and downregulated genes increasing from 918 to 2930 from the one-week to two-week stress stages,with activated pathways in ion transport,reactive oxygen species(ROS)scavenging,and protein biosynthesis.
基金supported by the National Natural Science Foundation of China(Grant No.32172000)the Agricultural Science and Technology Innovation Project of Hunan Province,China(Grant No.2023CX10)+1 种基金the Hunan Province Key Research and Development Program Project,China(Grant No.2023NK2004)the Project of State Key Laboratory of Hybrid Rice,China(Grant Nos.2023MS05 and 2022ZD06).
文摘Hybrid rice has significantly contributed to China’s food security.Mixed sowing and harvesting of parental lines have proven effective for mechanization and cost reduction.The hull color difference between red and yellow makes the red hull an ideal germplasm resource for efficient hybrid seed separation.The rice hull of Chuan 7 is red,and genetic linkage analysis combined with fine mapping located the red hull gene,OsRH3,within an 83.5 kb interval,containing 18 predicted genes.
基金supported by Projects of International Cooperation NSFC(31961143016,31101203)Guizhou Provincial Science and Technology Projects(QKHJC-ZK[2022]YB537)+4 种基金the Fundamental Research Funds of Central Public Welfare Research Institutions(CPSIBRF-CNRRI-202102,Y2020YJ17)Independent Project of State Key Laboratory of Rice Biology(2020Z2KT10201)High-quality and Resistant Hybrid Rice Germplasm Creation and New Varieties Development with International Competitiveness(2022KJCX45,YBXM2437)Zhejiang Provincial Science and Technology Projects(2022R51009)Inner Mongolia Breeding Joint Research Project(YZ2023004).
文摘Rice grain size is a primary characteristic essential for artificial domestication and breeding,governed by grain length,width,and thickness.In this study,we cloned Grain Size 10(GS10),a novel gene via mapbased cloning.Biochemical,molecular,and genetic studies were performed to elucidate the GS10 involved grain size mechanism in rice.Mutant of GS10 lead to reduced grain size due to alterations in cell expansion.Additionally,GS10 is responsible for the formation of notched-belly grains,especially in smaller grain varieties possessing loss-function mutations.Overexpression of GS10 in Nipponbare results in increasing grain length,grain weight and improve the appearance quality of rice.GS10 encodes conserved protein with uncharacterized function.Furthermore,GS10 regulates the grain size by interacting OsBRICK1,a subunit of the WAVE complex that governs actin nucleation and affects the assembly of microfilaments in rice.Together,our study demonstrates that,GS10 positively regulates the grain length and grain weight,which is beneficial for further improvements in yield characteristics.
基金supported by the National High Technology Research and Development Program of China (2011AA10A101)the Hunan Provincial Natural Science Foundation of China (10JJ2025)
文摘Grain shape as a major determinant of rice yield and quality is widely believed to be controlled by quantitative trait loci(QTL). We have identified a novel gene 'GS2' to largely regulate grain length and width in rice. The GS2 allele in the big-grain rice line ‘CDL’functioned in a dominant manner. In the present study, we employed a chromosome walking strategy in the residual heterozygous lines from recombinant inbred population between cultivar 'R1126' and CDL, and located the GS2 gene in an interval of ~33.2 kb flanked by marker GL2-35-1 and GL2-12 in the long arm of rice chromosome 2. According to genome annotations, three putative gene loci, LOC_Os02g47280, LOC_Os02g47290 and LOC_Os02g47300, exist in this candidate region. In addition, allelic analysis with previously reported genes demonstrated that GS2 was novel for regulating rice grain shape. These results will help promote the cloning and functional characterization of the GS2 gene and further develop linked markers to be used in marker-assisted breeding.
