Thiosugar nucleotide analogues: synthesis of uridine 5'-(2,3,6-tri-O-acetyl-4-S-acetyl-4-thio-alpha-D-galactopyranosyl diphosphate)

The synthesis of a novel uridine diphosphate galactose (UDP-Gal) analog, (UDP-2,3,6-tri-O-acetyl-4-S-acetyl-4-thio-alpha-D-galactopyranose) (10) is described. Compound 10 contains a sulfur in the place of oxygen at the 4-position of the galactose moiety. Compound 10 represents a protected form of a novel sugar nucleotide analog that can potentially be used during chemoenzymatic synthesis to modify complex oligosaccharides.     

Synthesis of uridine 5'-[2-S-pyridyl-3-thio-alpha-D-galactopyranosyl diphosphate]: precursor of UDP-thiogal sugar nucleotide donor substrate for beta-1,4-galactosyltransferase

The syntheses of a novel uridine diphosphate galactose (UDP-Gal) analog, (UDP-2,4,6-tri-O-acetyl-3-S-acetyl-3-thio-alpha-D-galactopyranose) (11) and the thiolpyridine protected (Uridine 5'-[3-S-(2-S-pyridyl)-3-thio-alpha-D-galactopyranosyl diphosphate) analog (12) are described. The reported synthesis relies on the novel use of thiolpyridine to generate 12 which is a suitably protected intermediate for generating a UDP-thioGal derivative by reduction prior to enzyme transfer via beta-1,4-galactosyltransferase.     

The role of dolichol monophosphate in sugar transfer

The specificity of the transfer of monosaccharides from sugar nucleotides to dolichol monophosphate catalyzed by liver microsomes was studied. Besides uridine diphosphate glucose, uridine diphosphate-N-acetylglucosamine and guanosine diphosphate mannose were found to act as donors for the formation of the respective dolichol monophosphate sugars. Uridine diphosphate galactose and uridine diphosphate-N-acetylgalactosamine gave negative results.     

The synthesis of exopolysaccharide by Klebsiella aerogenes membrane preparations and the involvement of lipid intermediates

1. Membrane preparations from Klebsiella aerogenes type 8 were shown to transfer glucose and galactose from their uridine diphosphate derivatives to a lipid and to polymer. The ratio of glucose to galactose transfer in both cases was 1:2. This is the same ratio in which these sugars occur in native polysaccharide. Galactose transfer was dependent on prior glucosylation of the lipid. Mutants were obtained lacking (a) glucosyltransferase and (b) galactosyltransferase. The transferase activities in a number of non-mucoid mutants was examined. 2. Glucose transfer was partially inhibited by uridine monophosphate, and incorporation of either glucose or galactose into lipid was decreased in the presence of uridine diphosphate. The sugars are thought to be linked to a lipid through a pyrophosphate bond, and treatment of the lipid intermediates with phenol yielded water-soluble compounds. These could be dephosphorylated with alkaline phosphatase. Transfer of glucuronic acid to lipid or polymer from uridine diphosphate glucuronic acid was much lower than that of the other two sugars. 3. The fate of sugars incorporated into polymer was also followed. Some conversion of glucose into galactose and glucuronic acid occurred. Mutants unable to transfer glucose or galactose to lipid were unable to form polymer. Other mutants capable of lipid glycosylation were in some cases unable to form polymer. A model for capsular polysaccharide synthesis is proposed and its similarity to the formation of other polymers outside the cell membrane is discussed.     

Cloning and characterization of the phosphoglucomutase of Trypanosoma cruzi and functional complementation of a Saccharomyces cerevisiae PGM null mutant

Trypanosoma cruzi is the etiological agent of Chagas' disease, a chronic illness characterized by progressive cardiomyopathy and/or denervation of the digestive tract. The parasite surface is covered with glycoconjugates, such as mucin-type glycoproteins and glycoinositolphospholipids (GIPLs), whose glycans are rich in galactopyranose (Galp) and/or galactofuranose (Galf) residues. These molecules have been implicated in attachment of the parasite to and invasion of mammalian cells and in modulation of the host immune responses during infection. In T. cruzi, galactose (Gal) biosynthesis depends on the conversion of uridine diphosphate (UDP)-glucose (UDP-Glc) into UDP-Gal by an NAD-dependent reduction catalyzed by UDP-Gal 4-epimerase. Phosphoglucomutase (PGM) is a key enzyme in this metabolic pathway catalyzing the interconversion of Glc-6-phosphate (Glc-6-P) and Glc-1-P which is then converted into UDP-Glc. We here report the cloning of T. cruzi PGM, encoding T. cruzi PGM, and the heterologous expression of a functional enzyme in Saccharomyces cerevisiae. T. cruzi PGM is a single copy gene encoding a predicted protein sharing 61% amino acid identity with Leishmania major PGM and 43% with the yeast enzyme. The 59-trans-splicing site of PGM RNA was mapped to a region located at 18 base pairs upstream of the start codon. Expression of T. cruzi PGM in a S. cerevisiae null mutant-lacking genes encoding both isoforms of PGM (pgm1Delta/pgm2Delta) rescued the lethal phenotype induced upon cell growth on Gal as sole carbon source.     

The enzymatic transformation of uridine diphosphate glucose into a galactose derivative

Treatment of uridine diphosphate glucose (UDPG) with an enzyme of S. fragilis was found to produce about 25% of a galactose-containing compound. This compound is precipitated with mercuric ions like UDPG, and its migration in chromatography in acid-ethanol is similar. By alkaline treatment it gives, like UDPG, a doubly esterified hexose monophosphate. It is concluded that the compound is uridine diphosphate galactose, and the bearing of this finding on the mechanism of action of UDPG is discussed.     

The occurrence of uridine diphosphate N-acetylgalactosamine 6-sulfate in quail egg white and characteristic distribution of sulfated sugar nucleotides in different avian eggs

A sulfated sugar nucleotide has been isolated from quail egg white, and accounts for nearly 80% of the total sugar nucleotides found in the egg white. Evidence is presented that this nucleotide is uridine diphosphate N-acetylgalactosamine 6-sulfate, an isomer of the 4-sulfated derivative of uridine diphosphate N-acetylgalactosamine previously found in chicken egg white. Further studies on the distribution of sulfated sugar nucleotides in egg white of various birds (chicken, quail, pheasant, peafowl, turkey, goose, and duck) demonstrate that each species has a characteristic composition, differing from one another regarding the relative amounts of 4-sulfated, 6-sulfated, and 4,6-bissulfated derivatives of uridine diphosphate N-acetylgalactosamine.     

Characterization of a novel biochemical abnormality in galactosemia: deficiency of glycolipids containing galactose or N-acetylgalactosamine and accumulation of precursors in brain and lymphocytes

Classic galactosemia, an inborn error of human galactose metabolism, is characterized by a deficiency of the enzyme galactose-1-phosphate uridyltransferase (GALT). The current model for the pathophysiology of this disease ascribes most of its symptoms to the toxicity of intracellular galactose-1-phosphate (Gal-1-P), one of the substrates of GALT which accumulates in the untreated disease state. Recently, a reduction in the intracellular concentration of UDP-Gal (uridine diphosphogalactose), one of the products of GALT, has been described in treated galactosemic patients. We investigated whether galactosemic patients might also have reduced amounts of those macromolecules that depend on UDP-Gal for their biosynthesis. We report a reduction in glycolipids that contain either galactose or its derivative N-acetylgalactosamine and an accumulation of the precursors to these compounds in the brain of a neonate with galactosemia. We also found an imbalance in glycolipids in galactosemic lymphoblasts. This novel biochemical abnormality observed in galactosemic patients is not addressed by dietary galactose-restriction therapy and could explain some of the chronic neurologic and other complications of galactosemia.     

Biosynthesis of the O Antigen from Citrobacter 139

The biosynthesis of the O antigen of Citrobacter 139 (Escherichia coli 3 Zurich 4,5,12:z(20)) was shown to proceed through a series of lipid-linked intermediates, similar to those involved in O-antigen synthesis in Salmonella. Galactose was the first sugar incorporated, followed by rhamnose and mannose. Abequose was incorporated from cytidine diphosphate (CDP)-abequose only when all three of the other nucleotide sugars (uridine diphosphate galactose, guanosine diphosphate mannose, and thymidine diphosphate rhamnose) were present. Rhamnosyl-galactosyl 1-phosphate and mannosyl-rhamnosyl-galactosyl 1-phosphate were identified as the products of mild alkaline hydrolysis of the lipid-linked intermediates.     

The metal ion catalyzed decomposition of nucleoside diphosphate sugars.

The metal ion catalysed decomposition of the nucleotide diphosphate sugars, uridine diphosphate glucose, uriding diphosphate galactose, uridine diphosphate N-acetylglucosamine, guanosine diphosphate mannose, and guanosine diphosphate fucose (UDPGlc, UDPGal, UDPGlc-NAc, GDPMan, and GDPFuc, respectively), has been studies as a function of pH. UDPDlc and UDPGal decompose readily to the a,2-cycle phosphate derivative of the sugar and uridine 5'-phosphoric acid (UMP) in the presence of Mn2+. Under all conditions tested, UDPGal decomposes two to three times more rapidly than does UDPGlc. GDPFuc is slowly degraded to free fucose under similar conditions; the other nucleotide diphosphate sugars are stable. The rate of reaction increases with increasing hydroxide ion concentration from pH 6.5 to 7.9 and with metal ion concentration from 10 to 200 mm. Several metal ions are effective catalysts; at pH 7.5 WITH 20 mM UDPGal and 20 mM metal ion, the following apparent first-order rate constants (min-1 x 10(4)) were obtained: Eu3+ 700; Mn2+, 70; Co2+ 27; Zn2+, 22; Ca2+, 3.0; Cu2+, 2.4; and Mg2+, 0. It appears that Mn2+ concentrations that have been used in studies with nucleotide diphosphate sugars at neutral pH can catalyze significant decomposition leading to erroneous interpretation of kinetic and incorporation experiments.     

Enzymatic O-glycosylation of kappa-caseinomacropeptide by ovine mammary Golgi membranes

The results of subcellular fractionation of sheep mammary gland membranes indicate that N-acetylgalactosaminyl polypeptide transferase and galactosyl-N-acetylgalactosaminyl transferase, which are involved in the assembly of disaccharide units of kappa-casein, are localized chiefly in Golgi membranes. The glycosyltransferase activities incorporating N-acetyl [1-14C] galactosamine and [U-14C] galactose from uridine diphosphate N-acetyl [1-14C] galactosamine and uridine diphosphate [U-14C] galactose, respectively, were measured after membrane solubilization with Triton X-100 either with unglycosylated caseinomacropeptide, or with this polypeptide containing the N-acetylgalactosamine side chain residues (desialylated and degalactosylated caseinomacropeptide). Radioactive N-acetylgalactosamine was incorporated in the unglycosylated acceptor peptide, and the glycosidic bonds in the product were alkali labile, suggesting that they were linked to the hydroxyamino acid residues. In addition radioactive N-acetylgalactosamine was released after alpha N-acetyl-D-galactosaminidase treatment of labelled caseinomacropeptide. [U-14C] galactose was incorporated in the desialylated and degalactosylated acceptor peptide. Reductive alkaline treatment of [U-14C] galactose peptide resulted in the release of a major product, the chromatographic properties of which in TLC were identical with authentic galactosyl (1 leads to 3) N-acetylgalactosaminitol. The structure of the labelled disacchariditol determined after periodate oxidation (two equivalents) by gas liquid chromatography-mass spectrometry revealed that the [U-14C] galactose was linked to position C-3 on the N-acetylgalactosaminyl-residue. The anomery of the galactose, as determined by a chemical method, indicates unambiguously a beta configuration.     

Mediators of galactose sensitivity in UDP-galactose 4'-epimerase-impaired mammalian cells

UDP-galactose 4'-epimerase (GALE) catalyzes the final step in the Leloir pathway of galactose metabolism, interconverting UDP-galactose and UDP-glucose. Unlike its Escherichia coli counterpart, mammalian GALE also interconverts UDP-N-acetylgalactosamine and UDP-N-acetylglucosamine. Considering the key roles played by all four of these UDP-sugars in glycosylation, human GALE therefore not only contributes to the Leloir pathway, but also functions as a gatekeeper overseeing the ratios of important substrate pools required for the synthesis of glycosylated macromolecules. Defects in human GALE result in the disorder epimerase-deficiency galactosemia. To explore the relationship among GALE activity, substrate specificity, metabolic balance, and galactose sensitivity in mammalian cells, we employed a previously described GALE-null line of Chinese hamster ovary cells, ldlD. Using a transfection protocol, we generated ldlD derivative cell lines that expressed different levels of wild-type human GALE or E. coli GALE and compared the phenotypes and metabolic profiles of these lines cultured in the presence versus absence of galactose. We found that GALE-null cells accumulated abnormally high levels of Gal-1-P and UDP-Gal and abnormally low levels of UDP-Glc and UDP-GlcNAc in the presence of galactose and that human GALE expression corrected each of these defects. Comparing the human GALE- and E. coli GALE-expressing cells, we found that although GALE activity toward both substrates was required to restore metabolic balance, UDP-GalNAc activity was not required for cell proliferation in the presence of otherwise cytostatic concentrations of galactose. Finally, we found that uridine supplementation, which essentially corrected UDP-Glc and, to a lesser extent UDP-GlcNAc depletion, enabled ldlD cells to proliferate in the presence of galactose despite the continued accumulation of Gal-1-P and UDP-Gal. These data offer important insights into the mechanism of galactose sensitivity in epimerase-impaired cells and suggest a potential novel therapy for patients with epimerase-deficiency galactosemia.     

Lipid-bound sugars in Rhizobium meliloti

Incubation of an enzyme preparation of Rhizobium meliloti with labeled uridine diphosphate glucose led to the formation of radioactive substances soluble in organic solvents. These substances are probably polyprenyl diphosphate saccharides. They behaved like these on treatment with ammonia or with hot phenol and were decomposed by heating for 10 min at pH 2 yielding a mono- and a disaccharide. The monosaccharide was identified as galactose by paper chromatography. The disaccharide gave glucose and galactose by acid hydrolysis. Following reduction with borohydride it yielded glucose and galactitol. After treatment with periodate followed by paper chromatography only galactose was detectable. The disaccharide was hydrolyzed by β- but not by α-glucosidase. Therefore the disaccharide is glucosyl β1-3-galactose.     

Galactose Transport in Saccharomyces cerevisiae III. Characteristics of Galactose Uptake in Transferaseless Cells: Evidence Against Transport-Associated Phosphorylation

The characteristics of the inducible galactose transport system in bakers' yeast were studied in uridine diphosphate, galactose-1-phosphate uridylyl-transferaseless cells. Transferaseless cells transport galactose at the same initial rate as wild-type cells and accumulate a mixture of free galactose and galactose-1-phosphate. The addition of ¹⁴C-labeled galactose to cells preloaded with unlabeled galactose and galactose-1-phosphate results in a higher rate of labeling of the free-sugar pool than of the galactose-1-phosphate pool. These results support other evidence that galactose uptake in bakers' yeast is a carrier-mediated, facilitated diffusion and that phosphorylation is an intracellular event after uptake of the free sugar.     

Polygalactolipids in Spinach Chloroplast

Two polygalactolipids, designated as components A and B, were isolated from spinach chloroplasts and were also obtained from glycolipid products synthesized with chloroplast enzymes using uridine diphosphate galactose as a galactose donor. These lipids were purified by column and thin layer chromatography. Chemical analysis of component A indicates that the lipid is trigalactosyl diglyceride, whereas component B behaves like tetragalactosyl diglyceride on a thin layer plate. The major fatty acid in trigalactosyl diglyceride was alpha-linolenic acid. Relative amount (molar ratio) of galactolipids in spinach chloroplasts was monogalactosyl diglyceride:digalactosyl diglyceride:trigalactosyl diglyceride:(tetragalactosyl diglyceride) = 60:30:5:1.     

Biosynthesis of T1 Antigen in Salmonella: Biosynthesis in a Cell-Free System

A particulate fraction from a T1 form of Salmonella typhimurium incorporated radioactivity from uridine diphosphate (UDP)-(14)C-glucose into products associated with the particulate enzyme. A major fraction of the incorporated radioactivity was found in the cell wall lipopolysaccharide fraction. Acid hydrolysis of incorporation products produced labeled galactose, ribose, and also glucose. The incorporation of glucose could be dissociated from the incorporation of galactose and ribose under certain conditions, and was assumed to represent incorporation into a polymer not related to T1 antigen. The incorporation of galactose and ribose probably represented the synthesis of T1 side chains of lipopolysaccharide, because (i) particulate fractions from non-T1 strains incorporated much less of these sugars and (ii) periodate oxidation and borohydride reduction converted a large portion of incorporated galactose residues into arabinose. The latter finding indicates that the galactose residues are galactofuranosides substituted either at C2 or C3; about 70% of the galactose residues in T1 side chains are known to be galactofuranosides substituted at C3. UDP-(14)C-galactose preparation used was not contaminated by UDP-(14)C-galactofuranose; therefore pyranose-to-furanose conversion must have taken place at some step during the reactions described above. The mechanism of conversion of galactose to ribose is not clear, but it was not found to involve a selective elimination of C1 or C6 of galactose or glucose.     

Enzymatic synthesis of UDP-galactose on a gram scale

Uridine 5′-diphospho-- -galactose (UDP-Gal) was synthesized on a gram scale from uridine 5′-diphospho-- -glucose and - -galactose 1-phosphate using the enzymes galactose-1-phosphate uridyltransferase (EC 2.7.7.12), phosphoglucomutase (EC 2.7.5.1) and glucose-6-phosphate dehydrogenase (EC 1.1.1.27). The synthesis was performed in a repetitive batch mode in which the enzymes, some of which are expensive, were used in 16 subsequent batches without any loss of enzyme activity. The space time yield of the synthesis was 7.1 g/l d. The overall yield of the synthesis amounted to 40% and 1.1 gram of pure UDP-Gal was obtained.     

Glycoproten biosynthesis in Trypanosoma brucei. The glycosylation of Glycoproteins located in and attached to the plasma membrane

1. Glycosyltransferase activity incorporating N-[14C]acetylglucosamine ([14C]GlcNAc) from uridine diphosphate N-[14C]acetylglucosamine (UDP-[14C]GlcNAc) into endogenous proitein acceptors was localized primarily in the plasma membrane of Trypanosoma brucei. 2. The acceptor site for the nucleotide sugar was further localized exclusively to the cytoplasmic face of the plasma membrane. 3. The glycosyltransferase produced elongation of the growing oligosaccharide chains while they were attached to their peptide acceptors. 4. This glycosyltransferase activity was incapable of initiating sugar attachment directly to amino acid residues within peptide acceptors. 5. The dolichyl-phosphate-sugar pathway for glycoprotein biosynthesis was either absent of only present at a very low level in T. brucei when compared to rat liver. 6. All oligosaccharide chains accepting GlcNAc were of the same or very similar lengths. 7. Both O-glycosidic (26%) and N-glycosidic (74%) linkages (exclusive of hydroxylysine attachment) were found. 8. Glycosyltransferase activity required either Mn2+ or Mg2+, had a pH optimum of 6.5 and was temperature-dependent. 9. The kinetics of incorporation were complex, probably a result of multiple acceptors or glycosyltransferases whose activities were characterized by a Km of 30 microM for UDP-GlcNAc with a V of 40 pmol x mg protein -1 x min-1 for the highest affinity system and a Km of approximately 2 mM for UDP-GlcNAc with a V of approximately 400 pmol x mg protein-1 x min-1 for the lowest affinity system. 10. Glycosyltransferases using UDP-GlcNAc, uridine diphosphate glucose, uridine diphosphate galactose and guanidine diphosphate mannose as glycosyl donors were observed. Each peptide acceptor was specific for a singloe labelled sugar in the absence of other unlabelled nucleotide sugars. 11. The final extent of incorporation of GlcNAc was due primarily to exhaustion of peptide acceptor. 12. An inhibitor of UDP-[14C]GlcNAc incorporation into plasma membranes was found in the cytoplasmic fraction.     

Separation and characteristics of galactose-1-phosphate and glucose-1-phosphate uridyltransferase from fruit peduncles of cucumber

Galactose-1-phosphate uridyltransferase (EC 2.7.7.10), responsible for the conversion of galactose-1-phosphate (Gal-1-P) to uridine diphosphate galactose (UDPgal) was examined in fruit peduncles of Cucumis sativus L. Two uridyltransferases (pyrophosphorylases), from I and II, were partially purified and resolved on a diethylamino-ethyl-cellulose column. Form I can utilize glucose-1-phosphate (Glc-1-P), while form II can utilize either Gal-1-P or Glc-1-P, with a preference for Gal-1-P. Form I was more heat stable than form II. Both Glc-1-P and Gal-1-P activities of form II were inactivated at the same rate by heating. The finding of a uridyltransferase with preference for Gal-1-P indicates that cucumber may have a Gal-1-P uridyltransferase (pyrophosphorylase) pathway for the catabolism of stachyose in the peduncles. The absence of the enzyme UDP-glucose-hexose-1-phosphate uridyltransferase (EC 2.7.7.12) in this tissue rules out catabolism by the classical Leloir pathway. The incorporation of carbon from UDPglc into Glc-1-P as opposed to sucrose may be regulated by the activities of the uridyltransferases. Pyrophosphate, in the same concentration range, inhibits UDP-gal formation (K_i=0.58±0.10 mM) and stimulates Glc-1-P formation. The ratio of units of pyrophosphatase to units of Gal-1-P uridyltransferase was higher in peduncles from growing fruit than from unpollinated fruit. Modulation of carbon partitioning through a uridyltransferase pathway may be a factor controlling growth of the cucumber fruit.Abbreviations Gal-1-P Galactose-1-phosphate - Glc-1-P glucose-1-phosphate - UDPgal uridine diphosphate galactose - UDPglc uridine diphosphate glucose Paper No. 6908 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh. The use of trade names in this publication does not imply endorsement by the North Carolina Agricultural Research Service of products named, nor criticism of similar ones not mentioned     

Galactose Expulsion during Lactose Metabolism in Lactococcus lactis subsp. cremoris FD1 Due to Dephosphorylation of Intracellular Galactose 6-Phosphate

In Lactococcus lactis subsp. cremoris FD1, galactose and lactose are both transported and phosphorylated by phosphotransferase systems. Lactose 6-phosphate (lactose-6P) is hydrolyzed intracellularly to galactose-6P and glucose. Glucose enters glycolysis as glucose-6P, whereas galactose-6P is metabolized via the tagatose-6P pathway and enters glycolysis at the tagatose diphosphate and fructose diphosphate pool. Galactose would therefore be a gluconeogenic sugar in L. lactis subsp. cremoris FD1, but since fructose 1,6-diphosphatase is not present in this strain, galactose cannot serve as an essential biomass precursor (glucose-6P or fructose-6P) but only as an energy (ATP) source. Analysis of the growth energetics shows that transition from N limitation to limitation by glucose-6P or fructose-6P gives rise to a very high growth-related ATP consumption (152 mmol of ATP per g of biomass) compared with the value in cultures which are not limited by glucose-6P or fructose-6P (15 to 50 mmol of ATP per g of biomass). During lactose metabolism, the galactose flux through the tagatose-6P pathway (r(max) = 1.2 h) is lower than the glucose flux through glycolysis (r(max) = 1.5 h) and intracellular galactose-6P is dephosphorylated; this is followed by expulsion of galactose. Expulsion of a metabolizable sugar has not been reported previously, and the specific rate of galactose expulsion is up to 0.61 g of galactose g of biomass h depending on the lactose flux and the metabolic state of the bacteria. Galactose excreted during batch fermentation on lactose is reabsorbed and metabolized when lactose is depleted from the medium. In vitro incubation of galactose-6P (50 mM) and permeabilized cells (8 g/liter) gives a supernatant containing free galactose (50 mM) but no P(i) (less than 0.5 mM). No organic compound except the liberated galactose is present in sufficient concentration to bind the phosphate. Phosphate is quantitatively recovered in the supernatant as P(i) by hydrolysis with alkaline phosphatase (EC 3.1.3.1), whereas inorganic pyrophosphatase (EC 3.6.1.1) cannot hydrolyze the compound. The results indicate that the unknown phosphate-containing compound might be polyphosphate.