The separation of enzymatic hydrolysis products of yeast RNA by ion-pair HPLC was studied.A modified chromatographic response function(MCRF) was proposed to appraise the effectiveness of chromatographic separation.T...The separation of enzymatic hydrolysis products of yeast RNA by ion-pair HPLC was studied.A modified chromatographic response function(MCRF) was proposed to appraise the effectiveness of chromatographic separation.This function takes the number of peaks,resolution and the retention time of the last peak into consideration.It shows advantages for optimization of HPLC separation of complex mixtures.An orthogonal array design was used to separate the hydrolysate of yeast RNA and the optimal chromatographic conditions were obtained.展开更多
On the basis of two types of calcium transport system detected in the barley root plasma membrane,the mechanisms of the calcium transport have been further studied.Ionophore CCCP has been found to inhibit Mg^(2+) -dep...On the basis of two types of calcium transport system detected in the barley root plasma membrane,the mechanisms of the calcium transport have been further studied.Ionophore CCCP has been found to inhibit Mg^(2+) -dependent calcium transport by 20%.In contrast,Mg^(2+) -independent calcium trans- port is insensitive to CCCP.The Mg^(2+) -dependent calcium transport following the collapse of H^+ gradient across the plasma membrane could be driven by the H^+ gradient either set up by ATP or imposed artificially. Any relation between Mg^(2+) -independent calcium transport and H^+ gradient has not been observed.These results indicate that Mg^(2+) -dependent calcium transport is accompanied by the decrease of H^+ gradient,and Mg^(2+) -independent calcium transport has nothing to do with the H^+ gradient.It is therefore suggested that the calcium transport across the barley root plasma membrane is driven by ATPase that is independent of Mg^(2+),and H^+/Ca^(2+) antiporter that is dependent on Mg^(2+).展开更多
The mechanisms underlying rootzone-localized responses to salinity during early stages of barley development remain elusive.In this study,we performed the analyses of multi-root-omes(transcriptomes,metabolomes,and lip...The mechanisms underlying rootzone-localized responses to salinity during early stages of barley development remain elusive.In this study,we performed the analyses of multi-root-omes(transcriptomes,metabolomes,and lipidomes)of a domesticated barley cultivar(Clipper)and a landrace(Sahara)that maintain and restrict seedling root growth under salt stress,respectively.Novel generalized linear models were designed to determine differentially expressed genes(DEGs)and abundant metabolites(DAMs)specific to salt treatments,genotypes,or rootzones(meristematic Z1,elongation Z2,and maturation Z3).Based on pathway over-representation of the DEGs and DAMs,phenylpropanoid biosynthesis is the most statistically enriched biological pathway among all salinity responses observed.Together with histological evidence,an intense salt-induced lignin impregnation was found only at stelic cell wall of Clipper Z2,compared with a unique elevation of suberin deposition across Sahara Z2.This suggests two differential salt-induced modulations of apoplastic flow between the genotypes.Based on the global correlation network of the DEGs and DAMs,callose deposition that potentially adjusted symplastic flow in roots was almost independent of salinity in rootzones of Clipper,and was markedly decreased in Sahara.Taken together,we propose two distinctive salt tolerance mechanisms in Clipper(growth-sustaining)and Sahara(salt-shielding),providing important clues for improving crop plasticity to cope with deteriorating global soil salinization.展开更多
文摘The separation of enzymatic hydrolysis products of yeast RNA by ion-pair HPLC was studied.A modified chromatographic response function(MCRF) was proposed to appraise the effectiveness of chromatographic separation.This function takes the number of peaks,resolution and the retention time of the last peak into consideration.It shows advantages for optimization of HPLC separation of complex mixtures.An orthogonal array design was used to separate the hydrolysate of yeast RNA and the optimal chromatographic conditions were obtained.
文摘On the basis of two types of calcium transport system detected in the barley root plasma membrane,the mechanisms of the calcium transport have been further studied.Ionophore CCCP has been found to inhibit Mg^(2+) -dependent calcium transport by 20%.In contrast,Mg^(2+) -independent calcium trans- port is insensitive to CCCP.The Mg^(2+) -dependent calcium transport following the collapse of H^+ gradient across the plasma membrane could be driven by the H^+ gradient either set up by ATP or imposed artificially. Any relation between Mg^(2+) -independent calcium transport and H^+ gradient has not been observed.These results indicate that Mg^(2+) -dependent calcium transport is accompanied by the decrease of H^+ gradient,and Mg^(2+) -independent calcium transport has nothing to do with the H^+ gradient.It is therefore suggested that the calcium transport across the barley root plasma membrane is driven by ATPase that is independent of Mg^(2+),and H^+/Ca^(2+) antiporter that is dependent on Mg^(2+).
基金supported by funding from the Australian Research Council(Future Fellowship:FT130100326)the University of Melbourne.
文摘The mechanisms underlying rootzone-localized responses to salinity during early stages of barley development remain elusive.In this study,we performed the analyses of multi-root-omes(transcriptomes,metabolomes,and lipidomes)of a domesticated barley cultivar(Clipper)and a landrace(Sahara)that maintain and restrict seedling root growth under salt stress,respectively.Novel generalized linear models were designed to determine differentially expressed genes(DEGs)and abundant metabolites(DAMs)specific to salt treatments,genotypes,or rootzones(meristematic Z1,elongation Z2,and maturation Z3).Based on pathway over-representation of the DEGs and DAMs,phenylpropanoid biosynthesis is the most statistically enriched biological pathway among all salinity responses observed.Together with histological evidence,an intense salt-induced lignin impregnation was found only at stelic cell wall of Clipper Z2,compared with a unique elevation of suberin deposition across Sahara Z2.This suggests two differential salt-induced modulations of apoplastic flow between the genotypes.Based on the global correlation network of the DEGs and DAMs,callose deposition that potentially adjusted symplastic flow in roots was almost independent of salinity in rootzones of Clipper,and was markedly decreased in Sahara.Taken together,we propose two distinctive salt tolerance mechanisms in Clipper(growth-sustaining)and Sahara(salt-shielding),providing important clues for improving crop plasticity to cope with deteriorating global soil salinization.
