Biochemical characterization of WbdN, a β1,3-glucosyltransferase involved in O-antigen synthesis in enterohemorrhagic Escherichia coli O157

The enterohemorrhagic O157 strain of Escherichia coli, which is one of the most well-known bacterial pathogens, has an O-antigen repeating unit structure with the sequence [-2-d-Rha4NAcα1-3-l-Fucα1-4-d-Glcβ1-3-d-GalNAcα1-]. The O-antigen gene cluster of E. coli O157 contains the genes responsible for the assembly of this repeating unit and includes wbdN. In spite of cloning many O-antigen genes, biochemical characterization has been done on very few enzymes involved in O-antigen synthesis. In this work, we expressed the wbdN gene in E. coli BL21, and the His-tagged protein was purified. WbdN activity was characterized using the donor substrate UDP-[(14)C]Glc and the synthetic acceptor substrate GalNAcα-O-PO(3)-PO(3)-(CH(2))(11)-O-Ph. The enzyme product was isolated by high pressure liquid chromatography, and mass spectrometry showed that one Glc residue was transferred to the acceptor by WbdN. Nuclear magnetic resonance analysis of the product structure indicated that Glc was β1-3 linked to GalNAc. WbdN contains a conserved DxD motif and requires divalent metal ions for full activity. WbdN activity has an optimal pH between 7 and 8 and is highly specific for UDP-Glc as the donor substrate. GalNAcα derivatives lacking the diphosphate group were inactive as substrates, and the enzyme did not transfer Glc to GlcNAcα-O-PO(3)-PO(3)-(CH(2))(11)-O-Ph. Our results illustrate that WbdN is a specific UDP-Glc:GalNAcα-diphosphate-lipid β1,3-Glc-transferase. The enzyme is a target for the development of inhibitors to block O157-antigen synthesis.     

Genetic and structural analyses of Escherichia coli O107 and O117 O-antigens

The O-antigen, consisting of many repeats of an oligosaccharide, is an essential component of the lipopolysaccharide on the surface of Gram-negative bacteria. The O-antigen is one of the most variable cell constituents, and different O-antigen forms are almost entirely due to genetic variations in O-antigen gene clusters. In this paper, we present structural and genetic evidence for a close relationship between Escherichia coli O107 and E. coli O117 O antigens. The O-antigen of E. coli O107 has a pentasaccharide repeating unit with the following structure: →4)-β- d -Gal p NAc-(1→3)-α- l -Rha p -(1→4)-α- d -Glc p NAc-(1→4)-β- d -Gal p -(1→3)-α- d -Gal p NAc-(1→, which differs from the known repeating unit of E. coli O117 only in the substitution of d -GlcNAc for d -Glc. The O-antigen gene clusters of E. coli O107 and O117 share 98.6% overall DNA identity and contain the same set of genes in the same organization. It is proposed that one cluster was evolved from another via mutations, and the substitution of a few amino acids residues in predicted glycosyltransferases resulted in the functional change of one such protein for transferring different sugars in O107 ( d -GlcNAc) and O117 ( d -Glc), leading to different O-antigen structures. This is an example of the O-antigen alteration caused by nucleotide mutations, which is less commonly reported for O-antigen variations.     

Glycosyltransferase mechanisms: impact of a 5-fluoro substituent in acceptor and donor substrates on catalysis

In glycosyltransferase-catalyzed reactions a new carbohydrate-carbohydrate bond is formed between a carbohydrate acceptor and the carbohydrate moiety of either a sugar nucleotide donor or lipid-linked saccharide donor. It is currently believed that most glycosyltransferase-catalyzed reactions occur via an electrophilic activation mechanism with the formation of an oxocarbenium ion-like transition state, a hypothesis that makes clear predictions regarding the charge development on the donor (strong positive charge) and acceptor (minimal negative charge) substrates. To better understand the mechanism of these enzyme-catalyzed reactions, we have introduced a strongly electron-withdrawing group (fluorine) at C-5 of both donor and acceptor substrates in order to explore its effect on catalysis. In particular, we have investigated the effects of the 5-fluoro analogues on the kinetics of two glycosyltransferase-catalyzed reactions mediated by UDP-GlcNAc:GlcNAc-P-P-Dol N-acetylglucosaminyltransferase (chitobiosyl-P-P-lipid synthase, CLS) and beta-N-acetylglucosaminyl-beta-1,4 galactosyltransferase (GalT). The 5-fluoro group has a marked effect on catalysis when inserted into the UDP-GlcNAc donor, with the UDP(5-F)-GlcNAc serving as a competitive inhibitor of CLS rather than a substrate. The (5-F)-GlcNAc beta-octyl glycoside acceptor, however, is an excellent substrate for GalT. Both of these results support a weakly associative transition state for glycosyltransferase-catalyzed reactions that proceed with inversion of configuration.     

Characterization of a novel alpha1,2-fucosyltransferase of Escherichia coli O128:b12 and functional investigation of its common motif

The wbsJ gene from Escherichia coli O128:B12 encodes an alpha1,2-fucosyltransferase responsible for adding a fucose onto the galactose residue of the O-antigen repeating unit via an alpha1,2 linkage. The wbsJ gene was overexpressed in E. coli BL21 (DE3) as a fusion protein with glutathione S-transferase (GST) at its N-terminus. GST-WbsJ fusion protein was purified to homogeneity via GST affinity chromatography followed by size exclusion chromatography. The enzyme showed broad acceptor specificity with Galbeta1,3GalNAc (T antigen), Galbeta1,4Man and Galbeta1,4Glc (lactose) being better acceptors than Galbeta-O-Me and galactose. Galbeta1,4Fru (lactulose), a natural sugar, was furthermore found to be the best acceptor for GST-WbsJ with a reaction rate four times faster than that of lactose. Kinetic studies showed that GST-WbsJ has a higher affinity for lactose than lactulose with apparent Km values of 7.81 mM and 13.26 mM, respectively. However, the kcat/appKm value of lactose (6.36 M(-1) x min(-1)) is two times lower than that of lactulose (13.39 M(-1) x min(-1)). In addition, the alpha1,2-fucosyltransferase activity of GST-WbsJ was found to be independent of divalent metal ions such as Mn2+ or Mg2+. This activity was competitively inhibited by GDP with a Ki value of 1.41 mM. Site-directed mutagenesis and a GDP-bead binding assay were also performed to investigate the functions of the highly conserved motif H152xR154R155xD157. In contrast to alpha1,6-fucosyltransferases, none of the mutants of WbsJ within this motif exhibited a complete loss of enzyme activity. However, residues R154 and D157 were found to play critical roles in donor binding and enzyme activity. The results suggest that the common motif shared by both alpha1,2-fucosyltransferases and alpha1,6-fucosyltransferases have similar functions. Enzymatic synthesis of fucosylated sugars in milligram scale was successfully performed using Galbeta-O-Me and Galbeta1,4Glcbeta-N3 as acceptors.     

alpha-Lactalbumin (LA) stimulates milk beta-1,4-galactosyltransferase I (beta 4Gal-T1) to transfer glucose from UDP-glucose to N-acetylglucosamine. Crystal structure of beta 4Gal-T1 x LA complex with UDP-Glc

beta-1,4-Galactosyltransferase 1 (Gal-T1) transfers galactose (Gal) from UDP-Gal to N-acetylglucosamine (GlcNAc), which constitutes its normal galactosyltransferase (Gal-T) activity. In the presence of alpha-lactalbumin (LA), it transfers Gal to Glc, which is its lactose synthase (LS) activity. It also transfers glucose (Glc) from UDP-Glc to GlcNAc, constituting the glucosyltransferase (Glc-T) activity, albeit at an efficiency of only 0.3-0.4% of Gal-T activity. In the present study, we show that LA increases this activity almost 30-fold. It also enhances the Glc-T activity toward various N-acyl substituted glucosamine acceptors. Steady state kinetic studies of Glc-T reaction show that the K(m) for the donor and acceptor substrates are high in the absence of LA. In the presence of LA, the K(m) for the acceptor substrate is reduced 30-fold, whereas for UDP-Glc it is reduced only 5-fold. In order to understand this property, we have determined the crystal structures of the Gal-T1.LA complex with UDP-Glc x Mn(2+) and with N-butanoyl-glucosamine (N-butanoyl-GlcN), a preferred sugar acceptor in the Glc-T activity. The crystal structures reveal that although the binding of UDP-Glc is quite similar to UDP-Gal, there are few significant differences observed in the hydrogen bonding interactions between UDP-Glc and Gal-T1. Based on the present kinetic and crystal structural studies, a possible explanation for the role of LA in the Glc-T activity has been proposed.     

Enzymatic synthesis of blood group A and B trisaccharide analogues

Glycosyltransferases A and B utilize the donor substrates UDP-GalNAc and UDP-Gal, respectively, in the biosynthesis of the human blood group A and B trisaccharide antigens from the O(H)-acceptor substrates. These enzymes were cloned as synthetic genes and expressed in Escherichia coli, thereby generating large quantities of enzyme for donor specificity evaluations. The amino acid sequence of glycosyltransferase A only differs from glycosyltransferase B by four amino acids, and alteration of these four amino acid residues (Arg-176-->Gly, Gly-235-->Ser, Leu-266-->Met and Gly-268-->Ala) can change the donor substrate specificity from UDP-GalNAc to UDP-Gal. Crossovers in donor substrate specificity have been observed, i.e., the A transferase can utilize UDP-Gal and B transferase can utilize UDP-GalNAc donor substrates. We now report a unique donor specificity for each enzyme type. Only A transferase can utilize UDP-GlcNAc donor substrates synthesizing the blood group A trisaccharide analog alpha-D-Glcp-NAc-(1-->3)-[alpha-L-Fucp-(1-->2)]-beta-D-Galp-O-(CH2 )7CH3 (4). Recombinant blood group B was shown to use UDP-Glc donor substrates synthesizing blood group B trisaccharide analog alpha-D-Glcp-(1-->3)-[alpha-L-Fucp-(1-->2)]-beta-D-Galp-O-(CH2) 7CH3 (5). In addition, a true hybrid enzyme was constructed (Gly-235-->Ser, Leu-266-->Met) that could utilize both UDP-GlcNAc and UDP-Glc. Although the rate of transfer with UDP-GlcNAc by the A enzyme was 0.4% that of UDP-GalNAc and the rate of transfer with UDP-Glc by the B enzyme was 0.01% that of UDP-Gal, these cloned enzymes could be used for the enzymatic synthesis of blood group A and B trisaccharide analogs 4 and 5.     

Inhibition of glycosyltransferases by bis-(p-nitrophenyl)phosphate: general effect and relation to their membrane integration

The effect of bis-(p-nitrophenyl)phosphate on various glycosyltransferases involved in protein glycosylation (sialyl-, fucosyl-, galactosyl-, mannosyl- and glucosyltransferases) have been studied using crude enzyme preparations solubilized from rat spleen lymphocytes. Bis-(p-nitrophenyl)phosphate appears as a common inhibitor for every glycosyltransferase reaction utilizing sugar nucleotides as direct donors. In most cases 10 mM inhibitor is sufficient to obtain a 90 per cent inhibition. Kinetic studies achieved with a purified galactosyltransferase preparation reveal that bis-(p-nitrophenyl)phosphate exerts a competitive inhibition towards UDP-galactose binding. Concerning membrane-bound enzymes, the interaction of bis-(p-nitrophenyl)phosphate depends on its accessibility to the enzyme active site. This is shown by the different effect obtained with two UDP-Glc utilizing membrane-bound enzymes : UDP-Glc : phospho-dolichyl glucosyltransferase and UDP-Glc : ceramide glucosyltransferase : the first one not being affected but the second one being markedly inhibited under the same condition, although both are inhibited when the membrane environment is disturbed by detergent. Bis-(p-nitrophenyl)phosphate appears to be a tool to study membrane topology of glycosyltransferases.     

Acceptor substrate specificity of UDP-Gal: GlcNAc-R β1,3-galactosyltransferase (WbbD) from Escherichia coli O7:K1

Most of the glycosyltransferases involved in O antigen biosynthesis have not yet been characterized. We recently demonstrated that the wbbD gene of the O7 lipopolysaccharide biosynthesis cluster in E. coli strain VW187 (O7:K1) encodes WbbD, a UDP-Gal: GlcNAcα-pyrophosphate-lipid β1,3-Gal-transferase (EC 2.4.1., accession number AAC27537) that transfers the second sugar moiety in the assembly of the O7 repeating unit. The enzyme utilizes undecaprenol-pyrophosphate-GlcNAc as a natural acceptor substrate, but can also transfer Gal to GlcNAcα-PO₃-PO₃-(CH₂)₁₁-O-phenyl (GlcNAc-PP-PhU). A number of acceptor substrate analogs have now been tested to further characterize the acceptor specificity of WbbD and to determine the roles of the pyrophosphate bond and the lipid moiety in the acceptor substrate. The enzyme was found to have a low activity with a substrate containing only one phosphate group directly α-linked to GlcNAc, and the enzyme was inactive when the phosphate was absent or further removed from the anomeric carbon of GlcNAc. Modifications of the lipid chain yielded substrates with variable activities. GlcNAc derivatives that were inactive as substrates did not inhibit WbbD suggesting that these compounds did not bind to the active site of the enzyme. The specificity of mammalian β4-galactosyltransferase I has been compared to that of WbbD. The results indicate that the bacterial WbbD enzyme has a distinct specificity for GlcNAc-PP-lipid, and that WbbD recognition of its acceptor substrate is very different from that of the ubiquitous mammalian β4-galactosyltransferase I. These studies help to understand mechanisms of O antigen synthesis, to develop methods to synthesize defined oligosaccharide structures and to develop specific O antigen inhibitors.     

Glucose-1-phosphotransferase and N-acetylglucosamine-1-phosphotransferase have distinct acceptor specificities

UDP-glucose:glycoprotein glucose-1-phosphotransferase (Glc-phosphotransferase) catalyzes the transfer of alpha Glc-1-P from UDP-Glc to endoglycosidase H-sensitive oligosaccharides on acceptor glycoproteins. We have previously demonstrated that Glc-phosphotransferase was specific for UDP-Glc as its nucleotide sugar substrate and thus appeared to be distinct from UDP-N-acetylglucosamine:glycoprotein N-acetylglucosamine-1-phosphotransferase (GlcNAc-phosphotransferase), an enzyme specific for lysosomally destined acceptor glycoproteins. Here, sodium dodecyl sulfate-polyacrylamide gel electrophoresis autoradiographs of endogenous acceptor glycoproteins in embryonic chick neural retina homogenates labeled by the presence of [beta-32P]UDP-Glc were shown to be distinct from those labeled by [beta-32P]UDP-GlcNAc, indicating that the two enzymatic activities recognize different populations of endogenous glycoproteins. To further probe the acceptor specificities of these enzymes, three glycoproteins known to be exogenous acceptors for GlcNAc-phosphotransferase were included in assays for Glc-phosphotransferase from retinal homogenates. Cathepsin D and beta-N-acetylhexosaminidase had no significant effects on phosphoglucose incorporation. Uteroferrin, an acid phosphatase, had a pronounced inhibitory effect on incorporation from UDP-Glc, and subsequent experiments suggested that phosphorylation of the Glc-phosphotransferase or another protein may be necessary for maximal activity to be seen. Also, I-cells, which have previously been shown to possess no GlcNAc-phosphotransferase activity, and control human fibroblasts were assayed for both Glc-phosphotransferase and GlcNAc-phosphotransferase. GlcNAc-phosphotransferase activity was observed only in control cells, whereas Glc-phosphotransferase was observed in both I-cells and controls at similar specific activities.     

X-ray crystal structures of rabbit N-acetylglucosaminyltransferase I (GnT I) in complex with donor substrate analogues

The Golgi-resident glycosyltransferase, UDP-N-acetyl-d-glucosamine:alpha-3-d-mannoside beta-1,2-N-acetylglucosaminyltransferase I (GnT I), initiates the conversion of high-mannose oligosaccharides to complex and hybrid structures in the biosynthesis of N-linked glycans. Reported here are the X-ray crystal structures of GnT I in complex with UDP-CH2-GlcNAc (a non-hydrolyzable C-glycosidic phosphonate), UDP-2-deoxy-2-fluoro-glucose, UDP-glucose and UDP. Collectively, these structures provide evidence for the importance of the GlcNAc moiety and its N-acetyl group in donor substrate binding, as well as insight into the role played by the flexible 318-330 loop in substrate binding and product release. In addition, the UDP-CH2-GlcNAc complex reveals a well-defined glycerol molecule poised for nucleophilic attack on the C1 atom of the donor substrate analogue. The position and orientation of this glycerol molecule have allowed us to model the binding of the Manalpha1,3Manbeta1 moiety of the acceptor substrate and, based on the model, to suggest a rationalization for the main determinants of GnT I acceptor specificity.     

Characterization of a protein:glucosyltransferase activity in human platelets

Human platelets exhibited significant glucosyltransferase activity, that transfer [14C]glucose from UDP-Glc to an endogenous protein acceptor. The enzyme protein:glucosyltransferase responsible for the catalysis was characterized and compared with glycogen:glucosyltransferase. We describe a partial separation of both activities, the ratio of protein:glucosyltransferase/glycogen:glucosyltransferase varied from 7:1 in a crude homogenate of platelets to 36:1 in the Sephadex G-100 column. This procedure failed to separate the protein:glucosyltransferase from its endogenous acceptor. Glucosylation of protein demonstrated dependence with respect to time and both protein and UDP-Glc concentration, and was saturated by very low concentration of donor and acceptor substrates. It was inhibited 76% by 5 mM Mn2+ concentration and was activated 23 and 11% by 5 mM concentrations of Ca2+ and Mg2+, respectively. With respect to glycogen:glucosyltransferase, when the effect of time, protein, and substrate concentration were determined under identical conditions, it did not show the same dependence. At 5 mM concentration, Mn2+, Ca2+, and Mg2+ were activators of the enzyme 43, 80, and 200%, respectively. On the basis of these characteristics, we conclude that the synthesis of glucoprotein and glycogen are catalyzed by two distinct enzymes. Addition of exogenous glycogen (range 0.002-1%) inhibited the protein:glucosyltransferase, whereas at 0.001-0.007% concentration it was acceptor substrate for glycogen:glucosyltransferase activity. At higher concentrations this activity was strongly inhibited. The concentration of glycogen in platelets could play a regulatory role in forming the glucoprotein and the glycogen molecules.     

Dolichyl sulphate and H-phosphonate: enzymatic reactions with activated sugars.

Two phosphate-modified analogues of dolichyl phosphate were evaluated as substrates or inhibitors of the reactions catalyzed by mammalian microsomal enzymes. Dolichyl H-phosphonate could serve as an efficient acceptor for mannosyl and glucosyl transfer. The reaction products were chromatographically different from those formed from dolichyl phosphate. Lower activity of the H-phosphonate was observed for the reaction of N-acetylglucosaminyl phosphate transfer from UDP-GlcNAc. Dolichyl sulphate was shown not to serve as a substrate for the transfer of mannosyl (from GDP-Man), glucosyl (from UDP-Glc) or N-acetylglucosaminyl phosphate (from UDP-GlcNAc) residues in the presence of rat liver microsomes. Weak inhibitory properties of this analogue were demonstrated.     

Biochemical characterization of UDP-Gal:GlcNAc-pyrophosphate-lipid β-1,4-Galactosyltransferase WfeD, a new enzyme from Shigella boydii type 14 that catalyzes the second step in O-antigen repeating-unit synthesis

The O antigen is the outer part of the lipopolysaccharide (LPS) in the outer membrane of Gram-negative bacteria and contains many repeats of an oligosaccharide unit. It contributes to antigenic variability and is essential to the full function and virulence of bacteria. Shigella is a Gram-negative human pathogen that causes diarrhea in humans. The O antigen of Shigella boydii type 14 consists of repeating oligosaccharide units with the structure [→6-d-Galpα1→4-d-GlcpAβ1→6-d-Galpβ1→4-d-Galpβ1→4-d-GlcpNAcβ1→]n. The wfeD gene in the O-antigen gene cluster of Shigella boydii type 14 was proposed to encode a galactosyltransferase (GalT) involved in O-antigen synthesis. We confirmed here that the wfeD gene product is a β4-GalT that synthesizes the Galβ1-4GlcNAcα-R linkage. WfeD was expressed in Escherichia coli, and the activity was characterized by using UDP-[³H]Gal as the donor substrate as well as the synthetic acceptor substrate GlcNAcα-pyrophosphate-(CH₂)₁₁-O-phenyl. The enzyme product was analyzed by liquid chromatography-mass spectrometry (LC-MS), high-performance liquid chromatography (HPLC), nuclear magnetic resonance (NMR), and galactosidase digestion. The enzyme was shown to be specific for the UDP-Gal donor substrate and required pyrophosphate in the acceptor substrate. Divalent metal ions such as Mn²⁺, Ni²⁺, and, surprisingly, also Pb²⁺ enhanced the enzyme activity. Mutational analysis showed that the Glu101 residue within a DxD motif is essential for activity, possibly by forming the catalytic nucleophile. The Lys211 residue was also shown to be required for activity and may be involved in the binding of the negatively charged acceptor substrate. Our study revealed that the β4-GalT WfeD is a novel enzyme that has virtually no sequence similarity to mammalian β4-GalT, although it catalyzes a similar reaction.Lipopolysaccharides (LPSs) consist of O-polysaccharide (O-antigenic) side chains covalently linked to a core polysaccharide and lipid A. LPSs are found in the outer membranes of Gram-negative bacteria, where they contribute to the structural integrity of the membrane and interact with the external environment (9, 10, 15). In the complex and dynamic microbial ecosystem of the human intestine, the communication between microorganisms and the gastrointestinal (GI) epithelium involves O-antigen and LPS binding molecules. Thus, the elimination of the O antigen may reduce virulence (2, 16, 21). Shigella is a genus of highly adapted bacterial pathogens that cause gastrointestinal disease, such as bacillary dysentery or shigellosis. A recent survey showed that shigellosis causes approximately 165 million cases of severe dysentery and more than 1 million deaths per year, mostly in children from developing countries (10). Shigella strains are categorized into four groups: S. boydii, S. dysenteriae, S. flexneri, and S. sonnei, each containing multiple subgroups of different serotypes, based on structural variations in their O antigens.O antigens consist of repeating units of oligosaccharides that are assembled individually, followed by the polymerization of units to form O antigens of different lengths. The glycosyltransferases involved in the biosynthesis of O antigens play a critical role in determining O-antigen structural diversity. The pentasaccharide repeating unit of S. boydii type 14 (B14) has the structure [→6-d-Galpα1→4-d-GlcpAβ1→6-d-Galpβ1→4-d-Galpβ1→4-d-GlcpNAcβ1→]n (12), suggesting the existence of five specific glycosyltransferases: a GlcNAc-phosphotransferase (WecA), three Gal-transferases, and a glucuronosyltransferase.Three distinct processes for the synthesis and translocation of O antigens have been described: the Wzx/Wzy-dependent pathway, the ATP binding cassette transporter-dependent process, and the synthase-dependent process (20, 25, 26). The biosynthesis of the S. boydii B14 O antigen that contains a variety of different sugar residues is expected to utilize the Wzy/Wzx-dependent pathway, where the synthesis of the repeating unit is initiated by WecA, catalyzing the transfer of sugar-phosphate (GlcNAcα-phosphate) from nucleotide sugar (UDP-GlcNAc) to a lipid carrier, undecaprenol-phosphate (Und-P), at the cytoplasmic side of the inner membrane. The wecA gene is present in the S. boydii B14 genome but outside the O-antigen gene cluster (1). The wecA gene is also involved in the synthesis of bacterial polysaccharides other than the O antigen. The extension of the chain is then mediated by specific glycosyltransferases that utilize nucleotide sugar donor substrates and are thought to be loosely associated with the inner membrane. In contrast, mammalian glycosyltransferases are usually membrane-bound proteins. Bacterial and mammalian glycosyltransferases, although they may have similar substrate specificities and form the same linkage, show significantly different amino acid sequences (4). Completed repeating units are then flipped across the membrane to the periplasmic side (by the flippase Wzx) and are polymerized (by Wzy) to form the O antigen under the control of a chain length regulator (Wzz). The repeating units are initially linked to the lipid carrier through GlcNAcα-phosphate. However, the S. boydii B14 O antigen has GlcNAc in the β linkage; thus, upon the polymerization of the completed repeating units, the linkage may be inverted, probably through the specific action of the polymerase Wzy. The entire polymer is then ligated to an outer core sugar based on lipid A. Upon completion, the LPS is extruded from the inner membrane and translocated to the outer membrane (19, 26). The latter-acting enzymes have multiple transmembrane regions that integrate them into the bacterial membranes.Genes involved in O-antigen biosynthesis are normally clustered between galF and gnd in Escherichia coli and Shigella and are classified into three different groups: (i) nucleotide sugar synthesis genes involved in the synthesis of donor substrates, (ii) glycosyltransferase genes, and (iii) O-antigen-processing genes, such as the flippase gene wzx and the polymerase gene wzy. The O-antigen gene cluster of B14 has been sequenced and analyzed (10). Four putative glycosyltransferase genes found in the B14 O-antigen synthesis gene cluster are wfeA, wfeB, wfeD, and wfeE. WfeD shares 38% identity and 57% similarity to the putative glycosyltransferase Orf9, which is involved in the synthesis of the E. coli O136 O antigen (our unpublished data). Since the O antigens of B14 and E. coli O136 share only one common linkage, d-Galpβ1→4-d-GlcpNAc (12, 23), wfeD was proposed to encode the galactosyltransferase (GalT) that transfers Gal to GlcNAcα-PP-Und in the β1-4 linkage, which is the second step in the biosynthetic pathway of the B14 O-antigen repeating unit.We have used biochemical approaches to assay the WfeD enzyme activity and to characterize this enzyme. The lipid carrier analog GlcNAcα-PO₃-PO₃-(CH₂)₁₁-O-phenyl [GlcNAc-PP-(CH₂)₁₁-OPh] has previously been used as a defined synthetic acceptor substrate for the characterization of glycosyltransferases from E. coli serotypes O7 (β1,3-GalT WbbD), O56 (β1,3-Glc-transferase WfaP), and O152 (β1,3-Glc-transferase WfgD) (6, 17). In this work, we showed that GlcNAc-PP-(CH₂)₁₁-OPh could also serve as an exogenous substrate for WfeD from B14. We were therefore able to prove that wfeD encodes a novel β1,4-GalT.     

alpha-Glucan synthesis on a protein primer, uridine diphosphoglucose: protein transglucosylase I. Separation from starch synthetase and phosphorylase and a study of its properties

It was found that the DEAE-cellulose-treated UDP-Glc:protein transglucosylase I catalyzing the first step (reaction 1) in the formation of alpha-glucan bound to protein in potato tuber is not only specific for the glucosyl donor but also for the endogenous acceptor. A single radioactive 38-kDa macromolecular component appeared during denaturing polyacrylamide gel electrophoresis of reaction 1 product. The labeled component is probably the polypeptide subunit of the endogenous acceptor which is being glucosylated. The radioactivity incorporated in reaction 1 product was isolated from a protease digest as a low-molecular-mass glucopeptide fraction. A beta-elimination reaction carried out in the presence of a reducing agent demonstrated that only one glucosyl moiety is transferred from UDP-Glc to the aminoacyl residue, thus forming an O-glucosidic linkage. 3H-labeled sodium borohydride showed that serine and threonine are involved in the peptide bond to glucose. Ion-exchange chromatography on DEAE-cellulose, affinity chromatography on concanavalin-A--Sepharose, gel filtration on Sephacryl S-300 and sucrose density gradient centrifugation failed to separate the enzyme catalyzing reaction 1 from the endogenous acceptor.     

Regulation of Triacylglucose Fatty Acid Composition (Uridine Diphosphate Glucose:Fatty Acid Glucosyltransferases with Overlapping Chain-Length Specificity)

UDP-glucose (UDP-Glc):fatty acid glucosyltransferases catalyze the UDP-Glc-dependent activation of fatty acids as 1-O-acyl-[beta]-glucoses. 1-O-Acyl-[beta]-glucoses act as acyl donors in the biosynthesis of 2,3,4-tri-O-acylglucoses secreted by wild tomato (Lycopersicon pennellii) glandular trichomes. The acyl composition of L. pennellii 2,3,4-tri-O-acylglucoses is dominated by branched short-chain acids (4:0 and 5:0; approximately 65%) and straight and branched medium-chain-length fatty acids (10:0 and 12:0; approximately 35%). Two operationally soluble UDP-Glc:fatty acid glucosyltransferases (I and II) were separated and partially purified from L. pennellii (LA1376) leaves by polyethylene glycol precipitation followed by DEAE-Sepharose and Cibacron Blue 3GA-agarose chromatography. Whereas both transferases possessed similar affinity for UDP-Glc, glucosyltransferase I showed higher specificity toward short-chain fatty acids (4:0) and glucosyltransferase II showed higher specificity toward medium-chain fatty acids (8:0 and 12:0). The overlapping specificity of UDP-Glc:fatty acid glucosyltransferases for 4:0 to 12:0 fatty acid chain lengths suggests that the mechanism of 6:0 to 9:0 exclusion from acyl substituents of 2,3,4-tri-O-acylglucoses is unlikely to be controlled at the level of fatty acid activation. UDP-Glc:fatty acid glucosyltransferases are also present in cultivated tomato (Lycopersicon esculentum), and activities toward 4:0, 8:0, and 12:0 fatty acids do not appear to be primarily epidermal when assayed in interspecific periclinal chimeras.     

Fluorescent analogs of UDP-glucose and their use in characterizing substrate binding by toxin A from Clostridium difficile.

Uridine-5'-diphospho-1-alpha-d-glucose (UDP-Glc) is a common substrate used by glucosyltransferases, including certain bacterial toxins such as Toxins A and B from Clostridium difficile. Fluorescent analogs of UDP-Glc have been prepared for use in our studies of the clostridial toxins. These compounds are related to the methylanthraniloyl-ATP compounds commonly used to probe the chemistry of ATP-dependent enzymes. The reaction of excess methylisatoic anhydride with UDP-Glc in aqueous solution yields primarily the 2' and 3' isomers of methylanthraniloyl-UDP-Glc (MUG). As the 2' and 3' isomers readily interconvert, this isomeric mixture was copurified by HPLC away from the other isomeric products, and was characterized by a combination of NMR, fluorescence and mass spectrometric methods. TcdA binds MUG competitively with respect to UDP-Glc with an affinity of 15 +/- 2 microm in the absence of Mg2+. There is currently no evidence that the fluorescent substrate analog is turned over by the toxin in either glucosyltransferase or glucosylhydrolase reactions. Using a competition assay, the affinity of UDP-Glc was determined to be 45+/-10 microm in the absence of Mg2+. The binding of UDP-Glc and Mg2+ are highly coupled with Mg2+ affinities in the range of 90-600 microm, depending on the experimental conditions. These results imply that one of the significant roles of the metal ion might be to stabilize the enzyme-substrate complex prior to initiation of the transferase chemistry.     

Non-Michaelian kinetics of rabbit muscle uridine diphosphoglucose pyrophosphorylase

The kinetic properties of rabbit muscle uridine diphosphoglucose (UDP-Glc) pyrophosphorylase have been studied, in both directions, with respect to substrate saturation, product inhibition, and cation requirement for activity. The results demonstrate that UDP-Glc pyrophosphorylase is a non-Michaelian enzyme: the synthetic reaction is characterized by a marked inhibition by glucose-1-phosphate (at concentrations higher than 0.3 mM) and by an hyperbolic saturation for UTP. In the reverse reaction, instead, the saturation function for UDP-Glc is hyperbolic and that for inorganic pyrophosphate is sigmoid, with a high Hill coefficient of (nH) 2.5. The study of the metal requirement indicates a distinctive ability of cations to stimulate the reactions of synthesis and degradation of the sugar nucleotide and a different stoichiometry of the metal chelates involved. The reaction mechanism is of the ordered-sequential type and the data of product inhibition allowed the identification of glucose-1-phosphate as the first substrate bound and UDP-Glc as the last product released. The inhibition pattern by UDP-Glc gives evidence for cooperativity also in the binding of this molecule.     

Galactosylation of endogenous proteins from human platelets

Human platelets have been shown to contain the enzyme glycoprotein:galactosyltransferase that catalyzes the transfer of galactose to an endogenous protein acceptor present in the platelet. Galactosylation of added ovalbumin also occurs. The activity was extracted with 30 mM Tris buffer (pH 7.5). The endogenous activity was enriched 1.4-fold (compared with the crude homogenate) in the fraction, 105,000 g pellet, and the exogenous enzyme was retained in the respective supernatant. The two galactosyltransferase activities showed proportionality to time, protein, and substrate concentration, and were identical in pH dependence and Mn+2 requirement. The effect of Triton X-100 (range 0-1.5%) in the assay system appeared to be different for both activities: with the optimum concentration of detergent (0.15%) the endogenous activity increased by 50% whereas the exogenous activity was augmented 5-fold. From a number of sugar nucleotides tested as glycosyl donor into the endogenous proteins, the optimum substrate was UDP-Glc (100%), followed by UDP-Gal (80%), GDP-Man (24%), UDP-Glc-NAc (21%), UDP-Xyl (19%), and ADP-Glc (5%). An appropriate exogenous acceptor for UDP-Glc as donor was not found. The different solubilization of galactosyl- and glucosyltransferase activities by Triton X-100 suggests that they are distinct enzymes. In addition, the exogenous galactosyltransferase activity achieved after the treatment was much higher (940%) than the endogenous (26%). It is suggested that these differences on both galactosyltransferases could reflect changes in the accessibility of the exogenous substrate to the enzyme.     

The structure of sucrose phosphate synthase from Halothermothrix orenii reveals its mechanism of action and binding mode

Sucrose phosphate synthase (SPS) catalyzes the transfer of a glycosyl group from an activated donor sugar, such as uridine diphosphate glucose (UDP-Glc), to a saccharide acceptor D-fructose 6-phosphate (F6P), resulting in the formation of UDP and D-sucrose-6'-phosphate (S6P). This is a central regulatory process in the production of sucrose in plants, cyanobacteria, and proteobacteria. Here, we report the crystal structure of SPS from the nonphotosynthetic bacterium Halothermothrix orenii and its complexes with the substrate F6P and the product S6P. SPS has two distinct Rossmann-fold domains with a large substrate binding cleft at the interdomain interface. Structures of two complexes show that both the substrate F6P and the product S6P bind to the A-domain of SPS. Based on comparative analysis of the SPS structure with other related enzymes, the donor substrate, nucleotide diphosphate glucose, binds to the B-domain of SPS. Furthermore, we propose a mechanism of catalysis by H. orenii SPS. Our findings indicate that SPS from H. orenii may represent a valid model for the catalytic domain of plant SPSs and thus may provide useful insight into the reaction mechanism of the plant enzyme.     

Synthesis of nucleotide-activated disaccharides with recombinant β3-galactosidase C from Bacillus circulans

Nucleotide-activated di- and oligosaccharides represent a novel class of glycoconjugates. They are components of human milk with still unknown biological function. Synthetic access to a wide range of nucleotide di- and oligosaccharides would also facilitate their utilization as donor substrates or inhibitors of Leloir-glycosyltransferases. We here present for the first time the synthesis of β1-3-linked nucleotide activated disaccharides by recombinant β3-galactosidase C from Bacillus circulans. UDP-Glc, UDP-GlcNAc, and UDP-GalNAc reacted as acceptor substrates in the transglycosylation reaction with p-nitrophenyl-β-galactoside as donor substrate. In an attempt to optimise the transglycosylation reaction, focused microwave irradiation was investigated. In comparison to conventional thermal heating product compositions and product yields were affected by microwave irradiation and depended on the used acceptor substrate. Microwave irradiation was advantageous for syntheses with UDP-GlcNAc as preferred acceptor substrate of β3-galactosidase C. The β1,3 linked UDP-disaccharide was the main product with minor fractions of UDP-tri- and UDP-tetrasaccharide. In summary, access to important UDP-disaccharides such as UDP-LacNAc type 1 and UDP-Thomsen-Friedenreich(T)-antigen was accomplished for further studies of their role as donor substrates or inhibitors of glycosyltransferases.