Enzyme IIBcellobiose of the phosphoenol-pyruvate-dependent phosphotransferase system of Escherichia coli: backbone assignment and secondary structure determined by three-dimensional NMR spectroscopy.

The assignment of backbone resonances and the secondary structure determination of the Cys 10 Ser mutant of enzyme IIBcellobiose of the Escherichia coli cellobiose-specific phosphoenol-pyruvate-dependent phosphotransferase system are presented. The backbone resonances were assigned using 4 triple resonance experiments, the HNCA and HN(CO)CA experiments, correlating backbone 1H, 15N, and 13C alpha resonances, and the HN(CA)CO and HNCO experiments, correlating backbone 1H,15N and 13CO resonances. Heteronuclear 1H-NOE 1H-15N single quantum coherence (15N-NOESY-HSQC) spectroscopy and heteronuclear 1H total correlation 1H-15N single quantum coherence (15N-TOCSY-HSQC) spectroscopy were used to resolve ambiguities arising from overlapping 13C alpha and 13CO frequencies and to check the assignments from the triple resonance experiments. This procedure, together with a 3-dimensional 1H alpha-13C alpha-13CO experiment (COCAH), yielded the assignment for all observed backbone resonances. The secondary structure was determined using information both from the deviation of observed 1H alpha and 13C alpha chemical shifts from their random coil values and 1H-NOE information from the 15N-NOESY-HSQC. These data show that enzyme IIBcellobiose consists of a 4-stranded parallel beta-sheet and 5 alpha-helices. In the wild-type enzyme IIBcellobiose, the catalytic residue appears to be located at the end of a beta-strand.     

The NMR side-chain assignments and solution structure of enzyme IIBcellobiose of the phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli.

The assignment of the side-chain NMR resonances and the determination of the three-dimensional solution structure of the C10S mutant of enzyme IIBcellobiose (IIBcel) of the phosphoenolpyruvate-dependent phosphotransferase system of Escherichia coli are presented. The side-chain resonances were assigned nearly completely using a variety of mostly heteronuclear NMR experiments, including HCCH-TOCSY, HCCH-COSY, and COCCH-TOCSY experiments as well as CBCACOHA, CBCA(CO)NH, and HBHA(CBCA)(CO)NH experiments. In order to obtain the three-dimensional structure, NOE data were collected from 15N-NOESY-HSQC, 13C-HSQC-NOESY, and 2D NOE experiments. The distance restraints derived from these NOE data were used in distance geometry calculations followed by molecular dynamics and simulated annealing protocols. In an iterative procedure, additional NOE assignments were derived from the calculated structures and new structures were calculated. The final set of structures, calculated with approximately 2000 unambiguous and ambiguous distance restraints, has an rms deviation of 1.1 A on C alpha atoms. IIBcel consists of a four stranded parallel beta-sheet, in the order 2134. The sheet is flanked with two and three alpha-helices on either side. Residue 10, a cysteine in the wild-type enzyme, which is phosphorylated during the catalytic cycle, is located at the end of the first beta-strand. A loop that is proposed to be involved in the binding of the phosphoryl-group follows the cysteine. The loop appears to be disordered in the unphosphorylated state.     

Enzymatic synthesis of amylose

Amylose is a linear polymer of α-1,4-linked glucose and is expected to be used in various industries as a functional biomaterial. However, pure amylose is currently not available for industrial purposes, since the separation of natural amylose from amylopectin is difficult. It is known that amylose has been synthesized using various enzymes. Glucan phosphorylase, together with its substrate, glucose-1-phosphate, is the most suitable system for the production of amylose since the molecular size of amylose can be controlled precisely. However, the problem with this system is that glucose-1-phosphate is too expensive for industrial purposes. This review summarizes our work on the enzymatic synthesis of essentially linear amylose, together with recent progress in the production of synthetic amylose using sucrose or cellobiose through the combined actions of phosphorylases.     

Production and Characterization of Recombinant Phanerochaete chrysosporium Cellobiose Dehydrogenase in the Methylotrophic Yeast Pichia pastoris

The hemoflavoenzyme cellobiose dehydrogenase (CDH) from the white-rot fungus Phanerochaete chrysosporium has been heterologously expressed in the methylotrophic yeast Pichia pastoris. After 4 days of cultivation in the induction medium, the expression level reached 1800 U/L (79 mg/L) of CDH activity, which is considerably higher than that obtained previously for wild-type CDH (wtCDH) and recombinant CDH (rCDH) produced by P. chrysosporium. Analysis with SDS-PAGE and Coomassie Brilliant Blue (CBB) staining revealed a major protein band with an approximate molecular mass of 100 kDa, which was identified as rCDH by Western blotting. The absorption spectrum of rCDH shows that the protein contains one flavin and one heme cofactor per protein molecule, as does wtCDH. The kinetic parameters for rCDH using cellobiose, ubiquinone, and cytochrome c, as well as the cellulose-binding properties of rCDH were nearly identical to those of wtCDH. From these results, we conclude that the rCDH produced by Pichia pastoris retains the catalytic and cellulose-binding properties of the wild-type enzyme, and that the Pichia expression system is well suited for high-level production of rCDH.     

Kinetics of beta-glucosidase production by Saccharomyces cerevisiae recombinants harboring heterologous bgl genes

The maximum productivity of -glucosidase by Saccharomyces cerevisiaerecombinants under the control of GALI promoter was 100 IU l^–1 h^–1. The highest productivity of -glucosidase by a S. cerevisiae recombinant was 16-fold more than that supported by Cellulomonas biazotea. The recombinants also co-produced ethanol from cellobiose: maximum product yield and productivity were 0.5 and 1.1 g ethanol g^–1 cellobiose and g ethanol l^–1 h^–1, respectively.     

Using disaccharides to enhance in vitro and in vivo transgene expression mediated by a lipid-based gene delivery system

BACKGROUND: Lipid-based vectors have been widely applied to in vivo and in vitro gene delivery. Disaccharides can effectively stabilize lipid membranes. This study examined whether disaccharides could enhance the transgene expression mediated by lipid-based vectors. METHODS: Different disaccharides were incorporated into the vectors prepared with DOTAP/protamine/DNA (LPD) or with DNA/cationic liposomes containing DOTAP, DOTAP/Chol, DOTAP/DOPE, or DC-Chol/DOPE. The levels of transgene expression and internalized plasmid of CHO cells were represented by the percentages of GFP-positive cells and the fluorescence intensity of ethidium-monoazide covalently labeled plasmid, respectively. The vectors containing either cellobiose or trehalose were also intravenously injected into mouse tail vein to investigate the potentials of in vivo applications. RESULTS: For enhancing the transgene expression, cellobiose was found to be effective for all the vectors whereas maltose decreased the effectiveness of DOTAP/Chol liposomes and LPD. For the internalization of plasmid, most disaccharides were able to increase the cellular delivery of DOTAP, DOTAP/Chol, and DOTAP/DOPE liposomes, but caused decreases in the cellular entry of DC-Chol/DOPE liposomes. An approximately linear correlation between the internalized plasmid and the transgene expression was observed for all the treatments in this study. When the vectors were administered to mouse by intravenous injection, 10-fold and 3-fold increases in the luciferase expression of lung were observed for DOTAP liposomes containing 330 mM cellobiose and trehalose, respectively. CONCLUSIONS: This study showed that using trehalose and cellobiose with a lipid-based delivery system provides a straightforward approach to effectively enhance both in vitro and in vivo transgene expression.     

两种耐热磷酸化酶的构建及高效催化合成红景天苷

目的:使用表达耐热蔗糖磷酸化酶的大肠杆菌重组工程菌E. coli BL21/pET-Spase和耐热纤维二糖磷酸化酶的大肠杆菌重组工程菌E. coli BL21/pET-Cpase,发酵培养后粗酶液作为催化剂,以价格低廉的蔗糖为原料合成红景天苷。方法:分别构建耐热蔗糖磷酸化酶和耐热纤维二糖磷酸化酶大肠杆菌重组菌,然后将重组菌、蔗糖、酪醇和磷酸混合,得到反应混合物,使反应混合物在45℃下转化,而产生红景天苷。结果:在耐热蔗糖磷酸化酶酶液1200 U/L、耐热纤维二糖磷酸化酶酶液500 U/L、蔗糖110 g/L、酪醇30 g/L和磷酸50 m M的浓度下,反应条件为pH 7.0、温度45℃、转速50转/分、反应时间32小时后,红景天苷浓度达到23.7 g/L。结论:本研究使用蔗糖磷酸化酶和纤维二糖磷酸化酶联合催化的工艺,成功地高收率合成了红景天苷。同时,本研究构建的耐热磷酸化酶酶活高,处理简单,为拓展糖苷类似物的合成提供了一种新的方法。     

Fungicidal activity of cellobiose lipids from culture broth of yeast <Emphasis Type="Italic">Cryptococcus humicola</Emphasis> and <Emphasis Type="Italic">Pseudozyma fusiformata</Emphasis>

Cellobiose lipids of yeast fungi Cryptococcus huminola and Pseudozyma fusiformata have similar fungicidal activities against different yeast, including pathogenic Cryptococcus and Candida species. Basidiomycetic yeast reveals maximum sensitivity to these preparations; e.g., cells of cryptococcus Filobasidiella neoformans almost completely die after 30-min incubation in a glycolipid solution at a concentration of 0.02 mg/ml. The same effect toward ascomycetous yeast, including pathogenic Candida species, is achieved only at five to eight times higher concentrations of glycolipids. The cellobiose lipid from P. fusiformata, which, unlike glycolipid from Cr. humicola, has hydroxycaproic acid residue as O-subtituent of cellobiose and additional 15-hydroxy group in aglycone, inhibits the growth of the studied mycelial fungi more efficiently than the cellobiose lipid from Cr. humicola.     

Plasma bikunin: Half-life and tissue uptake

Bikunin is a chondroitin sulfate-containing plasma protein synthesized in the liver. In vitro, it has been shown to inhibit proteases and to have additional activities, but its biological function is still unclear. Here we have studied the dynamics of plasma bikunin in rats and mice. A half-life of 7 ± 2 min was obtained from the time course of the decrease of the plasma level of bikunin following hepatectomy. Clearance experiments with intravenously injected radiolabeled bikunin with or without the chondroitin sulfate chain showed that the polysaccharide had little influence on the elimination rate of the protein. The uptake of bikunin by different tissues was studied using bikunin labeled with the residualizing agent ¹²⁵I-tyramine cellobiose; 60 min after intravenous injection, 49% of the radioactivity was recovered in the kidneys and 6–11% in the liver, bones, skin, intestine and skeletal muscle. The uptake in the liver was analyzed by intravenous injection of radiolabeled bikunin followed by collagenase perfusion and dispersion of the liver cells. These experiments indicated that bikunin is first trapped extracellularly within the liver before being internalized by the cells. (Mol Cell Biochem 271: 61–67, 2005)     

Inhibition of the Trichoderma reesei cellulases by cellobiose is strongly dependent on the nature of the substrate

The inhibition effect of cellobiose on the initial stage of hydrolysis when cellobiohydrolase Cel 7A and endoglucanases Cel 7B, Cel 5A, and Cel 12A from Trichoderma reesei were acting on bacterial cellulose and amorphous cellulose that were [(3)H]- labeled at the reducing end was quantified. The apparent competitive inhibition constant (K(i)) for Cel 7A on [(3)H]-bacterial cellulose was found to be 1.6 +/- 0.5 mM, 100-fold higher than that for Cel 7A acting on low-molecular-weight model substrates. The hydrolysis of [(3)H]-amorphous cellulose by endoglucanases was even less affected by cellobiose inhibition with apparent K(i) values of 11 +/- 3 mM and 34 +/- 6 mM for Cel 7B and Cel 5A, respectively. Contrary to the case for the other enzymes studied, the release of radioactive label by Cel 12A was stimulated by cellobiose, possibly due to a more pronounced transglycosylating activity. Theoretical analysis of the inhibition of Cel 7A by cellobiose predicted an inhibition analogous to that of mixed type with two limiting cases, competitive inhibition if the prevalent enzyme-substrate complex without inhibitor is productive and conventional mixed type when the prevalent enzyme-substrate complex is nonproductive.