Pre-harvest sprouting(PHS)or vivipary is a major problem affecting cereal quality and grain quantity and is primarily linked to the dysregulation of abscisic acid(ABA)biosynthesis in plants.Therefore,elucidating the m...Pre-harvest sprouting(PHS)or vivipary is a major problem affecting cereal quality and grain quantity and is primarily linked to the dysregulation of abscisic acid(ABA)biosynthesis in plants.Therefore,elucidating the molecular mechanisms governing seed dormancy is crucial for developing strategies to improve crop productivity.In this study,we identified a novel viviparous maize mutant,viviparous-like 5(vp-like5),which exhibits precocious germination in developing seeds.Through map-based cloning,we discovered that ZmCNX6,which encodes a small subunit of molybdopterin synthase essential for molybdenum cofactor(MoCo)biosynthesis,is the causal gene responsible for the vp-like5 phenotype.Biochemical assays have demonstrated significantly reduced activities of MoCo-dependent enzymes,including aldehyde oxidase(AO),xanthine dehydrogenase(XDH),and nitrate reductase(NR),in vplike5.AO is essential for the ABA biosynthesis,and the observed ABA deficiency in vp-like5 likely drives the viviparous phenotype.Expression analysis showed that ZmCNX6 was stably expressed during seed development,indicating its significant role in seed development.Furthermore,overexpression of ZmCNX6 not only enhanced the activities of MoCo-dependent enzymes but also improved drought tolerance in maize.Collectively,our study revealed ZmCNX6 as a multifunctional hub coordinating MoCo metabolism,ABA-dependent dormancy regulation,and abiotic stress responses,offering a potential target for simultaneously mitigating vivipary and improving drought resistance in maize.展开更多
In the current era of molecular biology,where the major components of transcription,translation,and chromatin regulation have been extensively described,identifying fine regulators that confer spatial and temporal spe...In the current era of molecular biology,where the major components of transcription,translation,and chromatin regulation have been extensively described,identifying fine regulators that confer spatial and temporal specificity to gene expression becomes increasingly necessary.Among the most intriguing of these are long non-coding RNAs(lncRNAs).Once defined by their lack of coding potential and considered as transcriptional noise,lncRNAs have been,for the last decades,emerging as critical regulators with unique structural and functional versatility:they can fold into complex conformations or scaffold protein complexes,interact with DNA or other RNAs,guide chromatin remodelers,or act as molecular decoys.As such,they are increasingly recognized not merely as byproducts of transcription but as central players in gene regulation(Yang et al.,2023).展开更多
Bistorta vivipara is a facultative reproductive plant capable of asexual reproduction through underground rhizomes and bulbils,as well as sexual reproduction via seeds.The phenomenon of vegetative organ vivipary is a ...Bistorta vivipara is a facultative reproductive plant capable of asexual reproduction through underground rhizomes and bulbils,as well as sexual reproduction via seeds.The phenomenon of vegetative organ vivipary is a complex biological process regulated by a network of genes.However,the developmental mechanism regulating bulbil vivipary in B.vivipara remains largely unexplored.This study investigated different developmental stages of B.vivipara using RNA sequencing and transcriptome analysis.Approximately 438 million high-quality reads were generated,with over 61.65%of the data mapped to the de novo transcriptome sequence.A total of 154,813 reads were matched in at least one public database,and 49,731 genes were differentially expressed across developmental stages.Functional analysis revealed significant enrichment of these genes in phenylpropanoid biosynthesis,plant hormone signal transduction,protein processing,starch and sucrose metabolism,and plant-pathogen interaction.Ninety-four genes involved in phytohormones,plant pigments,enzymes,and transcription factors were identified as potential candidates for inducing vegetative organ vivipary.These differentially expressed genes(DEGs),detected through comparative transcriptome analysis,may serve as candidate genes for bulbil vivipary in B.vivipara,establishing a foundation for future studies on the molecular mechanisms underlying vegetative organ vivipary.展开更多
Dormancy is an adaptive trait which prevents seeds from germinating under unfavorable environmental conditions.Seeds with weak dormancy undergo pre-harvest sprouting(PHS)which decreases grain yield and quality.Underst...Dormancy is an adaptive trait which prevents seeds from germinating under unfavorable environmental conditions.Seeds with weak dormancy undergo pre-harvest sprouting(PHS)which decreases grain yield and quality.Understanding the genetic mechanisms that regulate seed dormancy and resistance to PHS is crucial for ensuring global food security.In this study,we illustrated the function and molecular mechanism of TaSRO1 in the regulation of seed dormancy and PHS resistance by suppressing TaVP1.The tasro1 mutants exhibited strong seed dormancy and enhanced resistance to PHS,whereas the mutants of tavp1 displayed weak dormancy.Genetic evidence has shown that TaVP1 is epistatic to TaSRO1.Biochemical evidence has shown that TaSRO1 interacts with TaVP1 and represses the transcriptional activation of the PHS resistance genes TaPHS1 and TaSdr.Furthermore,TaSRO1 undermines the synergistic activation of TaVP1 and TaABI5 in PHS resistance genes.Finally,we highlight the great potential of tasro1 alleles for breeding elite wheat cultivars that are resistant to PHS.展开更多
基金supported by the Open Project of Key Laboratory,Xinjiang Uygur Autonomous Region(2023D04070)the Agricultural Science and Technology Innovation Program of CAAS(CAAS-CSCB-202403)。
文摘Pre-harvest sprouting(PHS)or vivipary is a major problem affecting cereal quality and grain quantity and is primarily linked to the dysregulation of abscisic acid(ABA)biosynthesis in plants.Therefore,elucidating the molecular mechanisms governing seed dormancy is crucial for developing strategies to improve crop productivity.In this study,we identified a novel viviparous maize mutant,viviparous-like 5(vp-like5),which exhibits precocious germination in developing seeds.Through map-based cloning,we discovered that ZmCNX6,which encodes a small subunit of molybdopterin synthase essential for molybdenum cofactor(MoCo)biosynthesis,is the causal gene responsible for the vp-like5 phenotype.Biochemical assays have demonstrated significantly reduced activities of MoCo-dependent enzymes,including aldehyde oxidase(AO),xanthine dehydrogenase(XDH),and nitrate reductase(NR),in vplike5.AO is essential for the ABA biosynthesis,and the observed ABA deficiency in vp-like5 likely drives the viviparous phenotype.Expression analysis showed that ZmCNX6 was stably expressed during seed development,indicating its significant role in seed development.Furthermore,overexpression of ZmCNX6 not only enhanced the activities of MoCo-dependent enzymes but also improved drought tolerance in maize.Collectively,our study revealed ZmCNX6 as a multifunctional hub coordinating MoCo metabolism,ABA-dependent dormancy regulation,and abiotic stress responses,offering a potential target for simultaneously mitigating vivipary and improving drought resistance in maize.
基金the support of Saclay Plant Sciences(SPS,ANR-17-EUR-0007)supported by the RIBORES grant from the French Agence Nationale pour la Recherche(ANR-22-CE92-0018).
文摘In the current era of molecular biology,where the major components of transcription,translation,and chromatin regulation have been extensively described,identifying fine regulators that confer spatial and temporal specificity to gene expression becomes increasingly necessary.Among the most intriguing of these are long non-coding RNAs(lncRNAs).Once defined by their lack of coding potential and considered as transcriptional noise,lncRNAs have been,for the last decades,emerging as critical regulators with unique structural and functional versatility:they can fold into complex conformations or scaffold protein complexes,interact with DNA or other RNAs,guide chromatin remodelers,or act as molecular decoys.As such,they are increasingly recognized not merely as byproducts of transcription but as central players in gene regulation(Yang et al.,2023).
基金supported by the National Natural Science Foundation of China(31960222)the Qinghai Provincial Major Science and Technology Special Funds(2023-NK-A3).
文摘Bistorta vivipara is a facultative reproductive plant capable of asexual reproduction through underground rhizomes and bulbils,as well as sexual reproduction via seeds.The phenomenon of vegetative organ vivipary is a complex biological process regulated by a network of genes.However,the developmental mechanism regulating bulbil vivipary in B.vivipara remains largely unexplored.This study investigated different developmental stages of B.vivipara using RNA sequencing and transcriptome analysis.Approximately 438 million high-quality reads were generated,with over 61.65%of the data mapped to the de novo transcriptome sequence.A total of 154,813 reads were matched in at least one public database,and 49,731 genes were differentially expressed across developmental stages.Functional analysis revealed significant enrichment of these genes in phenylpropanoid biosynthesis,plant hormone signal transduction,protein processing,starch and sucrose metabolism,and plant-pathogen interaction.Ninety-four genes involved in phytohormones,plant pigments,enzymes,and transcription factors were identified as potential candidates for inducing vegetative organ vivipary.These differentially expressed genes(DEGs),detected through comparative transcriptome analysis,may serve as candidate genes for bulbil vivipary in B.vivipara,establishing a foundation for future studies on the molecular mechanisms underlying vegetative organ vivipary.
基金supported by grants from the Natural Science Foundation of Shandong Province(ZR2019ZD16ZR2020JQ14)+2 种基金National Natural Science Foundation of China(32171935,U1906202)the Agricultural Variety Improvement Project of Shandong Province(2022LZGC002)National Key R&D Program of China(2022YFD1201700).
文摘Dormancy is an adaptive trait which prevents seeds from germinating under unfavorable environmental conditions.Seeds with weak dormancy undergo pre-harvest sprouting(PHS)which decreases grain yield and quality.Understanding the genetic mechanisms that regulate seed dormancy and resistance to PHS is crucial for ensuring global food security.In this study,we illustrated the function and molecular mechanism of TaSRO1 in the regulation of seed dormancy and PHS resistance by suppressing TaVP1.The tasro1 mutants exhibited strong seed dormancy and enhanced resistance to PHS,whereas the mutants of tavp1 displayed weak dormancy.Genetic evidence has shown that TaVP1 is epistatic to TaSRO1.Biochemical evidence has shown that TaSRO1 interacts with TaVP1 and represses the transcriptional activation of the PHS resistance genes TaPHS1 and TaSdr.Furthermore,TaSRO1 undermines the synergistic activation of TaVP1 and TaABI5 in PHS resistance genes.Finally,we highlight the great potential of tasro1 alleles for breeding elite wheat cultivars that are resistant to PHS.
