In this study, the authors cloned a glycosyltransferase gene PpUGT2 from Paris polyphylla var. yunnanensis with the ORF length of 1 773 bp and encoding 590 amino acids. The phylogenetic tree revealed that PpUGT2 belonged to the UGT80A subfamily and was named as UGT80A49 by the UDP-glycosyltransferase(UGT) Nomenclature Committee. The expression vector pET28a-PpUGT2 was constructed, and enzyme catalytic reaction in vitro was conducted via inducing protein expression and extraction. With UDP-glucose as sugar donor and diosgenin and pennogenin as substrates, the protein was found with the ability to catalyze the C-3 hydroxyl β-glycosylation of diosgenin and pennogenin. To further explore its catalytic characteristic, 15 substrates including steroids and triterpenes were selected and PpUGT2 showed its activity towards the C-17 position of sterol testosterone with UDP-glucose as sugar donor. Homology modelling and molecule docking of PpUGT2 with substrates predicted the key residues interacting with ligands. The re-levant residues of PpUGT2-ligand binding model were scanned to calculate the corresponding mutants, and the optimized mutants were obtained according to the changes in binding affinity of the ligand with protein and the surrounding residues within 5.0 Å of ligands, which had reference value for design of the mutants. This study laid a foundation for further exploring the biosynthetic pathway of polyphyllin as well as the structure of sterol glycosyltransferases.
Ligands ; Glycosyltransferases/genetics* ; Sterols ; Phylogeny ; Ascomycota ; Liliaceae/chemistry* ; Melanthiaceae ; Diosgenin ; Sugars ; Glucose ; Uridine Diphosphate

In plants, UDP-L-rhamnose is one of the major components of cell wall skeleton. Rhamnose synthase plays a key role in rhamnose synthesis which converts UDP-D-glucose into UDP-L-rhamnose in plants. In this study, we isolated the 1058 bp promoter region of the rhamnose synthase gene AtRHM1 from Arabidopsis genome by PCR, and created a series of deletions of AtRHM1 promoter ranging from -931 bp to +127 bp. The full length of the promoter and its deletion derivatives fused with GUS reporter gene were introduced into wild-type Arabidopsis by Agrobacterium-mediated transformation respectively. The GUS staining and GUS enzymatic activity assay showed that the expression of AtRHM1 is induced at transcriptional level by glucose and the regulatory elements involved in the glucose response are located in the region of -931 bp - -752 bp which contains three G-box motifs.
Arabidopsis ; genetics ; Arabidopsis Proteins ; genetics ; Glucosyltransferases ; genetics ; Plants, Genetically Modified ; genetics ; Promoter Regions, Genetic ; Uridine Diphosphate Glucose ; genetics ; metabolism ; Uridine Diphosphate Sugars ; genetics ; metabolism

Activities of hepatic cytosol enzymes involved in UDP-g1ucuronic acid synthesis as well as in glutathione reduction and conjugation systems were determined following administrations of butylated hydroxyanisole (approximately 5 mmol/kg body weight/day) and of equimolar intake doses of its structural anglogs. These compounds included the multi-functional group side chain compounds (t-butyl hydroquinone, 4-hydroxy- anisole, hydroquinone, benzoquinone) and the mono-functional side chain compounds (t-butyl benzene, anisole, phenol). They were administered to mice for 10 days either by mixing them in the diet or by oral intubations. Results showed that glutathione Stransferase activities were markedly increased by all tested compounds except for the t-butyl benzene. Activities of glutathione reductase and glucose 6-phosphate dehydrogenase were increased together on1y by BHA and t-butyl hydroguinone. UDP-glucose dehydrogenase and NADH:quinone reductase activities were significantly elevated by the multi-functional side chain compounds, but not by the mono-functional analogs. The relations between chemical structures of tested BHA analogs and elevations of the measured hepatic cytosol conjugation (detoxification) system enzyme activities for the metabolism and excretion of BHA analogs are discussed.
Animal ; Anisoles/metabolism* ; Butylated Hydroxyanisole/analogs & derivatives ; Butylated Hydroxyanisole/metabolism* ; Cytosol/enzymology* ; Glutathione/metabolism* ; Mice ; Uridine Diphosphate Glucuronic Acid/biosynthesis* ; Uridine Diphosphate Sugars/biosynthesis*

Oxidative Phosphorylation ; Acetylglucosamine ; Uridine Diphosphate N-Acetylglucosamine/metabolism*

Ginsenoside F1 is a rare ginsenoside in medicinal plants such as Panax ginseng,P. notogingseng and P. quinquefolius. It has strong pharmacological activities of anti-tumor,anti-oxidation and anti-aging. In order to directly produce ginsenoside F1 by using inexpensive raw materials such as glucose,we integrated the codon-optimized P.ginseng dammarenediol-Ⅱ synthase(Syn Pg DDS),P.ginseng protopanaxadiol synthase(Syn Pg PPDS),P. ginseng protopanaxatriol synthase(Syn Pg PPTS) genes and Arabidopsis thaliana cytochrome P450 reductase(At CPR1) gene into triterpene chassis strain BY-T3. The transformant BY-PPT can produce protopanaxatriol. Then we integrated the Sacchromyces cerevisiae phosphoglucomutase 1(PGM1),phosphoglucomutase 2(PGM2) and UDP-glucose pyrophosphorylase 1(UGP1) genes into chassis strain BY-PPT. The UDP-glucose supply module increased UDP-glucose production by 8. 65 times and eventually reached to 44. 30 mg·L-1 while confirmed in the transformant BY-PPT-GM. Next,we integrated the UDPglucosyltransferase Pg3-29 gene which can catalyze protopanaxatriol to produce ginsenoside F1 into chassis strain BY-PPT-GM. The transformant BY-F1 produced a small amount of ginsenoside F1 which was measured as 0. 5 mg·L-1. After the fermentation process was optimized,the titer of ginsenoside F1 could be increased by 900 times to 450. 5 mg·L-1. The high-efficiency UDP-glucose supply module in this study can provide reference for the construction of cell factories for production of saponin,and provide an important basis for further obtaining high-yield ginsenoside yeast cells.
Ginsenosides/metabolism* ; Glucose ; Panax ; Saccharomyces cerevisiae/metabolism* ; Uridine Diphosphate Glucose

Ginsenoside Rh_2 is a rare active ingredient in precious Chinese medicinal materials such as Ginseng Radix et Rhizoma, Notoginseng Radix et Rhizoma, and Panacis Quinquefolii Radix. It has important pharmacological activities such as anti-cancer and improving human immunity. However, due to the extremely low content of ginsenoside Rh_2 in the source plants, the traditional way of obtaining it has limitations. This study intended to apply synthetic biological technology to develop a cell factory of Saccharomyces cerevisiae to produce Rh_2 by low-cost fermentation. First, we used the high protopanaxadiol(PPD)-yielding strain LPTA as the chassis strain, and inserted the Panax notoginseng enzyme gene Pn1-31, together with yeast UDP-glucose supply module genes[phosphoglucose mutase 1(PGM1), α-phosphoglucose mutase(PGM2), and uridine diphosphate glucose pyrophosphorylase(UGP1)], into the EGH1 locus of yeast chromosome. The engineered strain LPTA-RH2 produced 17.10 mg·g~(-1) ginsenoside Rh_2. This strain had low yield of Rh_2 while accumulated much precursor PPD, which severely restricted the application of this strain. In order to further improve the production of ginsenoside Rh_2, we strengthened the UDP glucose supply module and ginsenoside Rh_2 synthesis module by engineered strain LPTA-RH2-T. The shaking flask yield of ginsenoside Rh_2 was increased to 36.26 mg·g~(-1), which accounted for 3.63% of the dry weight of yeast cells. Compared with those of the original strain LPTA-RH2, the final production and the conversion efficiency of Rh_2 increased by 112.11% and 65.14%, respectively. This study provides an important basis for further obtaining the industrial-grade cell factory for the production of ginsenoside Rh_2.
Fermentation ; Ginsenosides ; Humans ; Panax/genetics* ; Panax notoginseng ; Saccharomyces cerevisiae/genetics* ; Uridine Diphosphate Glucose

We amplified genes encoding UDP-glucose dehydrogenase, ecohasB from Escherichia coli and spyhasB from Streptococcus pyogenes. Both ecohasB and spyhasB were inserted into T7 expression vector pRX2 to construct recombinant plasmids pRXEB and pRXSB, and to express in E. coli BL21(DE3). After nickel column purification of UDP-glucose dehydrogenases, the enzymes were characterized. The optimum reaction condition of spyHasB was at 30 °C and pH 10. The specific activity reached 12.2 U/mg under optimum condition. The optimum reaction condition of ecoHasB was at 30 °C and pH 9. Its specific activity reached 5.55 U/mg under optimum condition. The pmuhasA gene encoding hyaluronic acid synthase was amplified from Pasteurella multocida and ligated with ecohasB and spyhasB to construct the coexpression vectors pBPAEB and pBPASB, respectively. The co-expression vectors were transformed into E. coli BW25113. Hyaluronic acid (HA) was produced by biotransformation and the conditions were optimized. When recombinant strains were used to produce hyaluronic acid, the higher the activity of UDP-glucose dehydrogenase was, the better its stability was, and the higher the HA production could reach. Under the optimal conditions, the yields of HA produced by pBPAEB/BW25113 and pBPASB/BW25113 in shake flasks were 1.52 and 1.70 g/L, respectively, and the production increased more than 2-3 folds as previously reported.
Biotransformation ; Escherichia coli ; enzymology ; Genetic Vectors ; Glucuronosyltransferase ; genetics ; Hyaluronan Synthases ; Hyaluronic Acid ; metabolism ; Pasteurella multocida ; enzymology ; Streptococcus pyogenes ; enzymology ; Uridine Diphosphate Glucose Dehydrogenase ; metabolism

We report a case of 15 days old newborn presenting with hypergalactosemia detected by newborn screening who had intrahepatic arterio-venous shunts with multiple pin-head sized cutaneous hemangiomas. Plasma level of galactose was elevated to 11.3 mg/dL at age of 7 days, but the activity of galactose-metabolizing enzymes including galactose-1- phosphate uridyltransferase, galactokinase, and uridine diphosphate galactose-4-epimerase were all normal. Intrahepatic arterio-venous shunts were diagnosed by abdominal ultrasonography with color doppler ultrasonography and abdominal computed tomography. At age of 3 months, the plasma level of galactose further elevated to 14.73 mg/dL, at which time lactose-free cows milk formula was started. At age of 6 months, the plasma level of galactose decreased to within normal range with disappearance of previously noted multiple cutaneous hemangiomas. In hypergalactosemia of the newborn, the intrahepatic shunts should be considered as a possible cause, once hereditary enzyme deficiencies have been ruled out.
Galactokinase ; Galactose ; Hemangioma ; Humans ; Infant, Newborn ; Mass Screening ; Milk ; Neonatal Screening* ; Plasma ; Reference Values ; Ultrasonography ; Ultrasonography, Doppler, Color ; Uridine Diphosphate

PURPOSE: The genetic disturbance of galactosemia is expressed as a cellular deficiency of either galactose-1-phosphate uridyltransferase(GALT) or galactokinase(GALK) or UDP galactose 4-epimerase(GALE). To find-out the pattern of galactosemia in Korea, we retrospectively analyzed cases of galactosemia detected by neonatal screening program. METHODS: We analyzed medical records of patients who visited Soonchunhyang University Hospital at age of 1 month after showing abnormalities in neonatal screening of galactosemia. For accurate diagnosis, galactose was measured by enzyme immunoassay(EIA) and fluorophotometer, also galactose-1-phosphate by fluorophotometer. Enzyme activities of GALK, GALT and GALE in RBC and galactose-1-phosphate were measured by radioisotope assay(RIA). Beutler test were done. Patients went on a lactose-free diet and follow-up tests for galactose, galactose-1-phosphate level and enzyme activity were performed. RESULTS: 10 patients(male : 6, female : 4) were diagnosed as galactosemia. Two patients had GALK deficiency and two had GALT deficiency. Six were GALE deficient showing the largest number. In two patients with GALK deficiency, GALT and GALE activities were normal but GALK activities showed respectively reduced activity. For GALT deficiency, two patients had low GALT activity in RBC and showed genotype of Duarte 2/G(galactosemia) in DNA analysis. In one patient, GALT activity was normal. Three patients seemed to be heterozygote state of GALE deficiency according to GALE activity levels. Four patients showed GALK hyperactivity. CONCLUSION: GALE deficiency provided the highest number. After lactose-free diet, galactose and galactose-1-phosphate were normaly maintained. Neonatal screening on galactosemia is essential for preventing life-threatening symptoms and an accurate diagnosis is needed for finding out the type of galactosemia which is important for prognosis.
Diagnosis ; Diet ; DNA ; Female ; Follow-Up Studies ; Galactokinase ; Galactose ; Galactosemias* ; Genotype ; Heterozygote ; Humans ; Infant, Newborn ; Korea ; Medical Records ; Neonatal Screening* ; Prognosis ; Retrospective Studies ; Uridine Diphosphate Galactose

To study the effects of glycosylation on survival of cold-storage human platelets by using rabbit model. (51)Cr-labeling platelets were used to detect the platelet storage survival. The human platelets (2.0 x 10(12)/L) treated with 5 g/L uridine diphosphate galactose (UDP-Gal) were stored in 4 degrees C refrigeratory up to 10 days. The survival of human platelets in rabbits whose reticuloendothelial system was inhibited by the administration of ethyl palmitate was monitored in blood drawn at various times after the platelet transfusion. The results showed that the survival rate of platelets was significantly increased in cold-storage human platelets by UDP-Gal treatment. The survival rates of platelets at 2 hours after transfusion into rabbits in groups of fresh platelets group, UDP-Gal + cold platelets group and cold platelets group were (68.9 +/- 8.5)%, (65.4 +/- 8.0)% and (5.0 +/- 2.6)%, respectively. Compared with cold platelets group, significant differences were seen among all groups (P < 0.01). UDP-Gal + cold platelets group had no significant differences compared with fresh platelets group (P > 0.05). It is concluded that UDG-Gal can provide the protective effect on cold-storage human platelets and prolong the survival time of refrigerated human platelets in rabbit model.
Animals ; Blood Platelets ; cytology ; metabolism ; Blood Preservation ; Cell Survival ; drug effects ; Cryopreservation ; methods ; Glycosylation ; drug effects ; Humans ; Models, Animal ; Platelet Transfusion ; Rabbits ; Uridine Diphosphate Galactose ; pharmacology