Yeast strain Y68 producing high level of pullulan was isolated from the phyton collected in Toulouse, France. This strain was identified to be Rhodotorula bacarum by BIOLOG analysis. This is the first report that pull...Yeast strain Y68 producing high level of pullulan was isolated from the phyton collected in Toulouse, France. This strain was identified to be Rhodotorula bacarum by BIOLOG analysis. This is the first report that pullulan was produced by Rhodotorula bacarum. The optimal medium (g L -1) for pullulan production by this strain was 80 glucose, 20 soybean cake hydrolysate, 5 K 2HPO 4, 1 NaCl, 0.2 MgSO 4·7H 2O, 0.6 (NH 4) 2SO 4, pH 7.0. Under this condition, 54 g L -1 pullulan was produced within 60 h at 30 ℃. Pullulan is a better starting material for producing marine prodrugs.展开更多
Little information is available on the interactive effects of inorganic and organic pollutants on carbon utilization by soil microorganisms.This study examined the effects of two common soil pollutants,lead(Pb) and be...Little information is available on the interactive effects of inorganic and organic pollutants on carbon utilization by soil microorganisms.This study examined the effects of two common soil pollutants,lead(Pb) and bensulfuron-methyl herbicide(BSM),on decomposition of an adscititious carbon source(14C-glucose).Two contrasting paddy soils,a silty clay soil and a clay loam soil,were incubated with different concentrations and combinations of pollutants for 60 days.Orthogonal rotatable central composite design was adopted to design the combinations of the pollutant concentrations so that rate response curves could be derived.Rapid decomposition of 14C-glucose occurred in the first three days for both soils where no Pb or BSM was added(control).Overall,63%-64% of the added 14C-glucose was decomposed in the control over the 60-day incubation.The addition of Pb or BSM significantly decreased the decomposition of 14C-glucose during the first week but increased the decomposition thereafter;as a result,the percentages of 14C-glucose decomposed(57%-77%) over the 60-day period were similar to or higher than those of the control.Application of the pollutants in combination did not further inhibit decomposition compared with the control.Overall,decomposition rates were lower in the silty clay soil than in the clay loam soil,which was related to the soil texture,cation exchange capacity,and pH.The relationship between the decomposition rates and the pollutants could be well characterized by the quadratic regression orthogonal rotation model.The initial antagonistic effects of the pollutants followed by the synergistic effects on microbial activity might result from changes of the concentrations of the pollutants.展开更多
Studies have provided indirect evidence that cellulolytic activity of some anaerobic bacteria is repressed by carbohydrates, such as glucose. This effect is known as carbon catabolite repression (CCR). Previous work...Studies have provided indirect evidence that cellulolytic activity of some anaerobic bacteria is repressed by carbohydrates, such as glucose. This effect is known as carbon catabolite repression (CCR). Previous work has found that cellulolytic activity of Clostridium cellulovorans and Eubacterium cellulosolvens are regulated. Many cellulolytic systems of these organisms are expressed only in the presence of cellulose or cellobiose (the disaccharide of cellulose). Some of these cellulose-induced systems also appear subject to CCR when more soluble substrates, such as glucose, are also available. To determine if such repression directly effects cellulolytic activity of C. cellulovorans and E. cellulosolvens, these organisms were cultivated in media containing a glucose analog. We then measured the ability of low levels of analog to inhibit growth of the organisms when cellobiose or cellulose were the energy substrates. Our results found that growth of both C. cellulovorans and E. cellulosolvens in cellobiose-containing medium are strongly inhibited by glucose analogs. In addition, both organisms exhibited delayed and slower growth in cellulose-containing medium when a glucose analog was added. These results provide direct demonstration that these cellulolytic bacteria are subject to CCR. This repression of cellulolysis may affect both of these organisms' ability to serve as industrial platforms for biomass degradation, and may interfere with the contribution of E. cellulosolvens toward animal digestion of cellulose. These results were also in sharp contrast to what has been reported regarding CCR activity in Clostridium cellulolyticum, which actively expresses cellulases in the presence of low levels of glucose.展开更多
基金National Natural Science Foundation of China(Grant No.39970005)for its financial support
文摘Yeast strain Y68 producing high level of pullulan was isolated from the phyton collected in Toulouse, France. This strain was identified to be Rhodotorula bacarum by BIOLOG analysis. This is the first report that pullulan was produced by Rhodotorula bacarum. The optimal medium (g L -1) for pullulan production by this strain was 80 glucose, 20 soybean cake hydrolysate, 5 K 2HPO 4, 1 NaCl, 0.2 MgSO 4·7H 2O, 0.6 (NH 4) 2SO 4, pH 7.0. Under this condition, 54 g L -1 pullulan was produced within 60 h at 30 ℃. Pullulan is a better starting material for producing marine prodrugs.
基金supported by the National Natural Science Foundation of China (No.40371062)the National Natural Science Foundation for Distinguished Young Scholars of China (No.40425007)the Science and Technology Program of Zhejiang Province,China (No.2006C12027)
文摘Little information is available on the interactive effects of inorganic and organic pollutants on carbon utilization by soil microorganisms.This study examined the effects of two common soil pollutants,lead(Pb) and bensulfuron-methyl herbicide(BSM),on decomposition of an adscititious carbon source(14C-glucose).Two contrasting paddy soils,a silty clay soil and a clay loam soil,were incubated with different concentrations and combinations of pollutants for 60 days.Orthogonal rotatable central composite design was adopted to design the combinations of the pollutant concentrations so that rate response curves could be derived.Rapid decomposition of 14C-glucose occurred in the first three days for both soils where no Pb or BSM was added(control).Overall,63%-64% of the added 14C-glucose was decomposed in the control over the 60-day incubation.The addition of Pb or BSM significantly decreased the decomposition of 14C-glucose during the first week but increased the decomposition thereafter;as a result,the percentages of 14C-glucose decomposed(57%-77%) over the 60-day period were similar to or higher than those of the control.Application of the pollutants in combination did not further inhibit decomposition compared with the control.Overall,decomposition rates were lower in the silty clay soil than in the clay loam soil,which was related to the soil texture,cation exchange capacity,and pH.The relationship between the decomposition rates and the pollutants could be well characterized by the quadratic regression orthogonal rotation model.The initial antagonistic effects of the pollutants followed by the synergistic effects on microbial activity might result from changes of the concentrations of the pollutants.
文摘Studies have provided indirect evidence that cellulolytic activity of some anaerobic bacteria is repressed by carbohydrates, such as glucose. This effect is known as carbon catabolite repression (CCR). Previous work has found that cellulolytic activity of Clostridium cellulovorans and Eubacterium cellulosolvens are regulated. Many cellulolytic systems of these organisms are expressed only in the presence of cellulose or cellobiose (the disaccharide of cellulose). Some of these cellulose-induced systems also appear subject to CCR when more soluble substrates, such as glucose, are also available. To determine if such repression directly effects cellulolytic activity of C. cellulovorans and E. cellulosolvens, these organisms were cultivated in media containing a glucose analog. We then measured the ability of low levels of analog to inhibit growth of the organisms when cellobiose or cellulose were the energy substrates. Our results found that growth of both C. cellulovorans and E. cellulosolvens in cellobiose-containing medium are strongly inhibited by glucose analogs. In addition, both organisms exhibited delayed and slower growth in cellulose-containing medium when a glucose analog was added. These results provide direct demonstration that these cellulolytic bacteria are subject to CCR. This repression of cellulolysis may affect both of these organisms' ability to serve as industrial platforms for biomass degradation, and may interfere with the contribution of E. cellulosolvens toward animal digestion of cellulose. These results were also in sharp contrast to what has been reported regarding CCR activity in Clostridium cellulolyticum, which actively expresses cellulases in the presence of low levels of glucose.
