Alfalfa is the most widely cultivated perennial legume forage crop worldwide.Drought is one of the major environmental factors influencing alfalfa productivity.However,the molecular mechanisms underlying alfalfa respo...Alfalfa is the most widely cultivated perennial legume forage crop worldwide.Drought is one of the major environmental factors influencing alfalfa productivity.However,the molecular mechanisms underlying alfalfa responses to drought stress are still largely unknown.This study identified a drought-inducible gene of unknown function,designated as Medicago sativa DROUGHT-INDUCED UNKNOWN PROTEIN 1(MsDIUP1).MsDIUP1 was localized to the nucleus,chloroplast,and plasma membranes.Overexpression of MsDIUP1 in Arabidopsis resulted in increased tolerance to drought,with higher seed germination,root length,fresh weight,and survival rate than in wild-type(WT)plants.Consistently,analysis of MsDIUP1 over-expression(OE)alfalfa plants revealed that MsDIUP1 also increased tolerance to drought stress,accompanied by physiological changes including reduced malondialdehyde(MDA)content and increased osmoprotectants accumulation(free proline and soluble sugar),relative to the WT.In contrast,disruption of MsDIUP1 expression by RNA interference(RNAi)in alfalfa resulted in a droughthypersensitive phenotype,with a lower chlorophyll content,higher MDA content,and less osmoprotectants accumulation than that of the WT.Transcript profiling of alfalfa WT,OE,and RNAi plants during drought stress showed differential responses for genes involved in stress signaling,antioxidant defense,and osmotic adjustment.Taken together,these results reveal a positive role for MsDIUP1 in regulating drought tolerance.展开更多
As the second most abundant natural polymer,accounting for approximately 30%of the organic carbon in the biosphere,lignin plays an essential role in plant development.However,a high lignin content affects the nutritio...As the second most abundant natural polymer,accounting for approximately 30%of the organic carbon in the biosphere,lignin plays an essential role in plant development.However,a high lignin content affects the nutritional quality of alfalfa(Medicago sativa L.),the most widely cultivated perennial legume forage crop.Histological analysis indicated that G-lignin and S-lignin were present in the stem,leaf,and petiole of alfalfa,and the deposition of lignin increased gradually in descending internodes.Neutral detergent fiber(NDF),acid detergent fiber(ADF),and acid detergent lignin(ADL)contents continually increased from the top to the bottom of the stem,and ADL content showed a similar trend in leaves.Alfalfa leaves and stems from five different nodes(1,2,4,6,and 8)were used as materials to investigate molecular regulatory mechanisms in lignin synthesis by RNA sequencing.Respectively 8074 and 7752 differentially expressed genes(DEGs)were identified in leaves and stems,and 1694 DEGs were common to the two tissues.‘‘Phenylpropanoid biosynthesis”was the most enriched pathway in both leaves and stems,and 134 key regulatory genes in lignin synthesis were identified by a weighted gene co-expression network analysis.The NAC family transcription factor MsNST1 gene was highly expressed in old leaf and stem tissues.The deposition pattern of G-and S-lignin differed among M.truncatula wild-type,nst1 mutants,and overexpression lines,and the transcription levels of lignin synthesis genes such as HCT,F5H,and COMT in these three materials also differed.These results suggest that MsNST1 affects lignin synthesis in alfalfa.These findings provide a genetic basis and abundant gene resources for further study of the molecular mechanisms of lignin synthesis,laying a foundation for low-lignin alfalfa breeding research.展开更多
基金supported by the Strategic Pilot Projects of Chinese Academy of Sciences(XDA26030103)the National Natural Science Foundation of China(31722055 and 31672476)the Key Science and Technology Foundation of Gansu Province(19ZD2NA002)。
文摘Alfalfa is the most widely cultivated perennial legume forage crop worldwide.Drought is one of the major environmental factors influencing alfalfa productivity.However,the molecular mechanisms underlying alfalfa responses to drought stress are still largely unknown.This study identified a drought-inducible gene of unknown function,designated as Medicago sativa DROUGHT-INDUCED UNKNOWN PROTEIN 1(MsDIUP1).MsDIUP1 was localized to the nucleus,chloroplast,and plasma membranes.Overexpression of MsDIUP1 in Arabidopsis resulted in increased tolerance to drought,with higher seed germination,root length,fresh weight,and survival rate than in wild-type(WT)plants.Consistently,analysis of MsDIUP1 over-expression(OE)alfalfa plants revealed that MsDIUP1 also increased tolerance to drought stress,accompanied by physiological changes including reduced malondialdehyde(MDA)content and increased osmoprotectants accumulation(free proline and soluble sugar),relative to the WT.In contrast,disruption of MsDIUP1 expression by RNA interference(RNAi)in alfalfa resulted in a droughthypersensitive phenotype,with a lower chlorophyll content,higher MDA content,and less osmoprotectants accumulation than that of the WT.Transcript profiling of alfalfa WT,OE,and RNAi plants during drought stress showed differential responses for genes involved in stress signaling,antioxidant defense,and osmotic adjustment.Taken together,these results reveal a positive role for MsDIUP1 in regulating drought tolerance.
基金supported by the National Natural Science Foundation of China(32071862 and 31722055)the China Postdoctoral Science Foundation(2020M683609)the Key Science and Technology Foundation of Gansu Province(19ZD2NA002).
文摘As the second most abundant natural polymer,accounting for approximately 30%of the organic carbon in the biosphere,lignin plays an essential role in plant development.However,a high lignin content affects the nutritional quality of alfalfa(Medicago sativa L.),the most widely cultivated perennial legume forage crop.Histological analysis indicated that G-lignin and S-lignin were present in the stem,leaf,and petiole of alfalfa,and the deposition of lignin increased gradually in descending internodes.Neutral detergent fiber(NDF),acid detergent fiber(ADF),and acid detergent lignin(ADL)contents continually increased from the top to the bottom of the stem,and ADL content showed a similar trend in leaves.Alfalfa leaves and stems from five different nodes(1,2,4,6,and 8)were used as materials to investigate molecular regulatory mechanisms in lignin synthesis by RNA sequencing.Respectively 8074 and 7752 differentially expressed genes(DEGs)were identified in leaves and stems,and 1694 DEGs were common to the two tissues.‘‘Phenylpropanoid biosynthesis”was the most enriched pathway in both leaves and stems,and 134 key regulatory genes in lignin synthesis were identified by a weighted gene co-expression network analysis.The NAC family transcription factor MsNST1 gene was highly expressed in old leaf and stem tissues.The deposition pattern of G-and S-lignin differed among M.truncatula wild-type,nst1 mutants,and overexpression lines,and the transcription levels of lignin synthesis genes such as HCT,F5H,and COMT in these three materials also differed.These results suggest that MsNST1 affects lignin synthesis in alfalfa.These findings provide a genetic basis and abundant gene resources for further study of the molecular mechanisms of lignin synthesis,laying a foundation for low-lignin alfalfa breeding research.