Biosynthesis of type 3 capsular polysaccharide in Streptococcus pneumoniae. Enzymatic chain release by an abortive translocation process

The type 3 polysaccharide synthase from Streptococcus pneumoniae catalyzes sugar transfer from UDP-Glc and UDP-glucuronic acid (GlcUA) to a polymer with the repeating disaccharide unit of [3)-beta-d-GlcUA-(1-->4)-beta-d-Glc-(1-->]. Evidence is presented that release of the polysaccharide chains from S. pneumoniae membranes is time-, temperature-, and pH-dependent and saturable with respect to specific catalytic metabolites. In these studies, the membrane-bound synthase was shown to catalyze a rapid release of enzyme-bound polysaccharide when either UDP-Glc or UDP-GlcUA alone was present in the reaction. Only a slow release of polysaccharide occurred when both UDP sugars were present or when both UDP sugars were absent. Chain size was not a specific determinant in polymer release. The release reaction was saturable with increasing concentrations of UDP-Glc or UDP-GlcUA, with respective apparent K(m) values of 880 and 0.004 micrometer. The apparent V(max) was 48-fold greater with UDP-Glc compared with UDP-GlcUA. The UDP-Glc-actuated reaction was inhibited by UDP-GlcUA with an approximate K(i) of 2 micrometer, and UDP-GlcUA-actuated release was inhibited by UDP-Glc with an approximate K(i) of 5 micrometer. In conjunction with kinetic data regarding the polymerization reaction, these data indicate that UDP-Glc and UDP-GlcUA bind to the same synthase sites in both the biosynthetic reaction and the chain release reaction and that polymer release is catalyzed when one binding site is filled and the concentration of the conjugate UDP-precursor is insufficient to fill the other binding site. The approximate energy of activation values of the biosynthetic and release reactions indicate that release of the polysaccharide occurs by an abortive translocation process. These results are the first to demonstrate a specific enzymatic mechanism for the termination and release of a polysaccharide.     

Expression of the Streptococcus pneumoniae type 3 synthase in Escherichia coli. Assembly of type 3 polysaccharide on a lipid primer.

Synthesis of the type 3 capsular polysaccharide of Streptococcus pneumoniae is catalyzed by the membrane-localized type 3 synthase, which utilizes UDP-Glc and UDP-GlcUA to form high molecular mass [3-beta-d-GlcUA-(1-->4)-beta-d-Glc-(1-->](n). Expression of the synthase in Escherichia coli resulted in synthesis of a 40-kDa protein that was reactive with antibody directed against the C terminus of the synthase and was the same size as the native enzyme. Membranes isolated from E. coli contained active synthase, as demonstrated by the ability to incorporate Glc and GlcUA into a high molecular mass polymer that could be degraded by type 3 polysaccharide-specific depolymerase. As in S. pneumoniae, the membrane-bound synthase from E. coli catalyzed a rapid release of enzyme-bound polysaccharide when incubated with either UDP-Glc or UDP-GlcUA alone. The recombinant enzyme expressed in E. coli was capable of releasing all of the polysaccharide from the enzyme, although the chains remained associated with the membrane. The recombinant enzyme was also able to reinitiate polysaccharide synthesis following polymer release by utilizing a lipid primer present in the membranes. At low concentrations of UDP-Glc and UDP-GlcUA (1 microm in the presence of Mg(2+) and 0.2 microm in Mn(2+)), novel glycolipids composed of repeating disaccharides with linkages consistent with type 3 polysaccharide were synthesized. As the concentration of the UDP-sugars was increased, there was a marked transition from glycolipid to polymer formation. At UDP-sugar concentrations of either 5 microm (with Mg(2+)) or 1.5 microm (with Mn(2+)), 80% of the incorporated sugar was in polymer form, and the size of the polymer increased dramatically as the concentration of UDP-sugars was increased. These results suggest a cooperative interaction between the UDP-precursor-binding site(s) and the nascent polysaccharide-binding site, resulting in a non-processive addition of sugars at the lower UDP-sugar concentrations and a processive reaction as the substrate concentrations increase.     

Capsule biosynthesis and basic metabolism in Streptococcus pneumoniae are linked through the cellular phosphoglucomutase

Synthesis of the type 3 capsular polysaccharide of Streptococcus pneumoniae requires UDP-glucose (UDP-Glc) and UDP-glucuronic acid (UDP-GlcUA) for production of the [3)-beta-D-GlcUA-(1-->4)-beta-D-Glc-(1-->](n) polymer. The generation of UDP-Glc proceeds by conversion of Glc-6-P to Glc-1-P to UDP-Glc and is mediated by a phosphoglucomutase (PGM) and a Glc-1-P uridylyltransferase, respectively. Genes encoding both a Glc-1-P uridylyltransferase (cps3U) and a PGM homologue (cps3M) are present in the type 3 capsule locus, but these genes are not essential for capsule production. In this study, we characterized a mutant that produces fourfold less capsule than the type 3 parent. The spontaneous mutation resulting in this phenotype was not contained in the type 3 capsule locus but was instead located in a distant gene (pgm) encoding a second PGM homologue. The function of this gene product as a PGM was demonstrated through enzymatic and complementation studies. Insertional inactivation of pgm reduced capsule production to less than 10% of the parental level. The loss of PGM activity in the insertion mutants also caused growth defects and a strong selection for isolates containing second-site suppressor mutations. These results demonstrate that most of the PGM activity required for type 3 capsule biosynthesis is derived from the cellular PGM.     

Evidence for a UDP-Glucose Transporter in Golgi Apparatus-Derived Vesicles from Pea and Its Possible Role in Polysaccharide Biosynthesis

The Golgi apparatus in plant cells is involved in hemicellulose and pectin biosynthesis. While it is known that glucan synthase I is responsible for the formation of [beta]-l-4-linked glucose (Glc) polymers and uses UDP-Glc as a substrate, very little is known about the topography of reactions leading to the biosynthesis of polysaccharides in this organelle. We isolated from pea (Pisum sativum) stems a fraction highly enriched in Golgi apparatus-derived vesicles that are sealed and have the same topographical orientation that the membranes have in vivo. Using these vesicles and UDP-Glc, we reconstituted polysaccharide biosynthesis in vitro and found evidence for a luminal location of the active site of glucan synthase I. In addition, we identified a UDP-Glc transport activity, which is likely to be involved in supplying substrate for glucan synthase I. We found that UDP-Glc transport is protein mediated. Moreover, our results suggest that UDP-Glc transport is coupled to the exit of a luminal uridine-containing nucleotide via an antiporter mechanism. We suggest that UDP-Glc is transported into the lumen of Golgi and that Glc is transferred to a polysaccharide chain, whereas the nucleotide moiety leaves the vesicle by an antiporter mechanism.     

Role of the carbohydrate binding site of the Streptococcus pneumoniae capsular polysaccharide type 3 synthase in the transition from oligosaccharide to polysaccharide synthesis

The type 3 synthase catalyzes the formation of the Streptococcus pneumoniae type 3 capsular polysaccharide [-3)-beta-D-GlcUA-(1, 4)-beta-D-Glc-(1-]n. Synthesis is comprised of two distinct catalytic phases separated by a transition step whereby an oligosaccharylphosphatidylglycerol primer becomes tightly bound to the carbohydrate acceptor recognition site of the synthase. Using the recombinant synthase in Escherichia coli membranes, we determined that a critical oligosaccharide length of approximately 8 monosaccharides was required for recognition of the growing chain by the synthase. Upon binding of the oligosaccharide-lipid to the carbohydrate recognition site, the polymerization reaction entered a highly processive phase to produce polymer of high molecular weight. The initial oligosaccharide-synthetic phase also appeared to be processive, the duration of which was enhanced by the concentration of UDP-GlcUA and diminished by an increase in temperature. The overall reaction approached a steady state equilibrium between the polymer- and oligosaccharide-forming phases that was shifted toward the former by higher UDP-GlcUA levels or lower temperatures and toward the latter by lower concentrations of UDP-GlcUA or higher temperatures. The transition step between the two enzymatic phases demonstrated cooperative kinetics, which is predicted to reflect a possible reorientation of the oligosaccharide-lipid in conjunction with the formation of a tight binding complex.     

Molecular cloning and characterization of chondroitin polymerase from Escherichia coli strain K4

Escherichia coli strain K4 produces the K4 antigen, a capsule polysaccharide consisting of a chondroitin backbone (GlcUA beta(1-3)-GalNAc beta(1-4))(n) to which beta-fructose is linked at position C-3 of the GlcUA residue. We molecularly cloned region 2 of the K4 capsular gene cluster essential for biosynthesis of the polysaccharide, and we further identified a gene encoding a bifunctional glycosyltransferase that polymerizes the chondroitin backbone. The enzyme, containing two conserved glycosyltransferase sites, showed 59 and 61% identity at the amino acid level to class 2 hyaluronan synthase and chondroitin synthase from Pasteurella multocida, respectively. The soluble enzyme expressed in a bacterial expression system transferred GalNAc and GlcUA residues alternately, and polymerized the chondroitin chain up to a molecular mass of 20 kDa when chondroitin sulfate hexasaccharide was used as an acceptor. The enzyme exhibited apparent K(m) values for UDP-GlcUA and UDP-GalNAc of 3.44 and 31.6 microm, respectively, and absolutely required acceptors of chondroitin sulfate polymers and oligosaccharides at least longer than a tetrasaccharide. In addition, chondroitin polymers and oligosaccharides and hyaluronan polymers and oligosaccharides served as acceptors for chondroitin polymerization, but dermatan sulfate and heparin did not. These results may lead to elucidation of the mechanism for chondroitin chain synthesis in both microorganisms and mammals.     

Characterization of the Lipid Linkage Region and Chain Length of the Cellubiuronic Acid Capsule of Streptococcus pneumoniae

The processive reaction mechanisms of β-glycosyl-polymerases are poorly understood. The cellubiuronan synthase of Streptococcus pneumoniae catalyzes the synthesis of the type 3 capsular polysaccharide through the alternate additions of β-1,3-Glc and β-1,4-GlcUA. The processive multistep reaction involves the sequential binding of two nucleotide sugar donors in coordination with the extension of a polysaccharide chain associated with the carbohydrate acceptor recognition site. Degradation analysis using cellubiuronan-specific depolymerase demonstrated that the oligosaccharide-lipid and polysaccharide-lipid products synthesized in vitro with recombinant cellubiuronan synthase had a similar oligosaccharyl-lipid at their reducing termini, providing definitive evidence for a precursor-product relationship and also confirming that growth occurred at the nonreducing end following initiation on phosphatidylglycerol. The presence of a lipid marker at the reducing end allowed the quantitative determination of cellubiuronic acid polysaccharide chain lengths. As the UDP-GlcUA concentration was increased from 1 to 11.5 μm, the level of synthase in the transitory processive state decreased, with the predominant oligosaccharide-lipid product containing 3 uronic acid residues, whereas the proportion of synthase in the fully processive state increased and the polysaccharide chain length increased from 320 to 6700 monosaccharide units. In conjunction with other kinetic data, these results suggest that the formation of a complex between a tetrauronosyl oligomer and the carbohydrate acceptor recognition site plays a central role in coordinating the repetitive interaction of the synthase with the nucleotide sugar donors and modulating the chain length of cellubiuronan polysaccharide.Cellubiuronic acid, the capsular polysaccharide of type 3 Streptococcus pneumoniae, is composed of the repeating disaccharide cellobiuronic acid (-3)-β-d-GlcUA²-(1,4)-β-d-Glc-(1-) (1) and is synthesized by a processive mechanism similar to that for cellulose, chitin, hyaluronic acid, and other related β-glycans (2). This group of polysaccharides is synthesized by inverting GT-2A polymerases that are located in the plasma membrane with their active sites on the cytoplasmic face, and following chain initiation, the synthases are thought to be involved in the extrusion of the nascent chains to the external membrane face (3–8). The overall processive elaboration of these polysaccharides remains poorly understood at the molecular level. In particular, there is relatively little information concerning the initiation process, the facilitation of chain extrusion, the mechanism of translocation, and the regulation of the final chain length during the assembly of these polymers. Recent investigations in this laboratory have begun to unravel some of the details of both the early and later stages of the biosynthesis of cellubiuronan.Unlike most S. pneumoniae capsules, whose elaboration requires multiple glycosyltransferases, a polymerase, and an additional transport system (9), the assembly and transport of cellubiuronic acid in type 3 strains is carried out by the single enzyme cellubiuronan synthase (Cps3S) (3, 10, 11). Studies of the synthase in S. pneumoniae and recombinant Escherichia coli membranes have shown that assembly of the polysaccharide involves two distinct kinetic phases: 1) a transitory processive state wherein the chain is thought to be initiated by the formation of an oligosaccharide-lipid that is loosely associated with the synthase, and 2) a fully processive state in which the polysaccharide is tightly bound to the carbohydrate substrate recognition site, except for a brief period during the translocation stage of each catalytic cycle (5, 12). Each catalytic cycle in the extrusion mode provides for chain extension by the addition of a repeating disaccharide and requires the alternate association of the synthase with UDP-Glc and UDP-GlcUA, the formation of the glycosidic linkages of the respective sugars, and the release, translocation, and reattachment of the elongating chain at the synthase carbohydrate recognition site. Transition from the transitory mode to the fully processive extrusion mode correlates with the attainment of a threshold-length oligosaccharide of ∼8 sugars (12). Nod factor chito-oligosaccharides from rhizobia are synthesized by a related group of synthases that apparently are not capable of organizing into an extrusion mode (13). Significantly, the maximum length of any reported Nod-factor oligosaccharide is 6 sugars (14).Based on β-glucosidase sensitivity of singly added [¹⁴C]Glc to the terminal end of high molecular weight cellubiuronan, it was deduced that the polysaccharide grows by repetitive β-1,3-Glc and β-1,4-GlcUA additions to the nonreducing terminus (2). Oligosaccharide-lipid assembly is thought to initiate on phosphatidylglycerol (15). To date, however, there has been no quantitative demonstration of polysaccharide-lipid conjugate, and the similarity of the distal sugar-lipid linkages in the polysaccharide- and oligosaccharide-lipid products has not been verified.Cellubiuronan depolymerase is a Bacillus circulans β-endoglucuronidase that specifically cleaves cellubiuronic acid chains at GlcUA-β1,4-Glc linkages (16, 17). The polysaccharide is successively cleaved at random internal linkages, which upon completion of hydrolysis yields a series of oligosaccharide end products containing 1–4 Glc-β1,3-GlcUA disaccharide units, with the most abundant oligomer being a tetrasaccharide. The high degree of specificity of this depolymerase has provided a sensitive analytical tool to further characterize cellubiuronan oligosaccharide- and polysaccharide-lipids, and even more importantly, it has provided a means for determining the chain length of these polysaccharides. Both in vivo (18) and in vitro studies (12) indicate that the processivity of cellubiuronan synthase is modulated by the concentration of UDP-GlcUA. However, lacking well defined cellubiuronan polysaccharide size standards, there has been no way to clearly establish the actual length of the polymer synthesized under different reaction conditions. The methodology described in this article has allowed a clear demonstration of the relationship between the polysaccharide size and the UDP-GlcUA substrate concentration and in turn has led to the development of a kinetic model (38), which provides both for UDP-sugar modulation of polysaccharide chain length and for the assembly by a single-site synthase of a polysaccharide composed of a repeating heterodisaccharide.     

Initiation and synthesis of the Streptococcus pneumoniae type 3 capsule on a phosphatidylglycerol membrane anchor

The type 3 synthase from Streptococcus pneumoniae is a processive beta-glycosyltransferase that assembles the type 3 polysaccharide [3)-beta-D-GlcUA-(1-->4)-beta-D-Glc-(1-->] by a multicatalytic process. Polymer synthesis occurs via alternate additions of Glc and GlcUA onto the nonreducing end of the growing polysaccharide chain. In the presence of a single nucleotide sugar substrate, the type 3 synthase ejects its nascent polymer and also adds a single sugar onto a lipid acceptor. Following single sugar incorporation from either UDP-[(14)C]Glc or UDP-[(14)C]GlcUA, we found that phospholipase D digestion of the Glc-labeled lipid yielded a product larger than a monosaccharide, while digestion of the GlcUA-labeled lipid resulted in a product larger than a disaccharide. These data indicated that the lipid acceptor contained a headgroup and that the order of addition to the lipid acceptor was Glc followed by GlcUA. Higher-molecular-weight product synthesized in vitro was also sensitive to phospholipase D digestion, suggesting that the same lipid acceptor was being used for single sugar additions and for polymer formation. Mass spectral analysis of the anionic lipids of a type 3 S. pneumoniae strain demonstrated the presence of glycosylated phosphatidylglycerol. This lipid was also observed in Escherichia coli strains expressing the recombinant type 3 synthase. The presence of the lipid primer in S. pneumoniae membranes explained both the ability of the synthase to reinitiate polysaccharide synthesis following ejection of its nascent chain and the association of newly synthesized polymer with the membrane. Unlike most S. pneumoniae capsular polysaccharides, the type 3 capsule is not covalently linked to the cell wall. The present data indicate that phosphatidylglycerol may anchor the type 3 polysaccharide to the cell membrane.     

Structure and mechanism of human UDP-glucose 6-dehydrogenase

Elevated production of the matrix glycosaminoglycan hyaluronan is strongly implicated in epithelial tumor progression. Inhibition of synthesis of the hyaluronan precursor UDP-glucuronic acid (UDP-GlcUA) therefore presents an emerging target for cancer therapy. Human UDP-glucose 6-dehydrogenase (hUGDH) catalyzes, in two NAD(+)-dependent steps without release of intermediate aldehyde, the biosynthetic oxidation of UDP-glucose (UDP-Glc) to UDP-GlcUA. Here, we present a structural characterization of the hUGDH reaction coordinate using crystal structures of the apoenzyme and ternary complexes of the enzyme bound with UDP-Glc/NADH and UDP-GlcUA/NAD(+). The quaternary structure of hUGDH is a disc-shaped trimer of homodimers whose subunits consist of two discrete α/β domains with the active site located in the interdomain cleft. Ternary complex formation is accompanied by rigid-body and restrained movement of the N-terminal NAD(+) binding domain, sequestering substrate and coenzyme in their reactive positions through interdomain closure. By alternating between conformations in and out of the active site during domain motion, Tyr(14), Glu(161), and Glu(165) participate in control of coenzyme binding and release during 2-fold oxidation. The proposed mechanism of hUGDH involves formation and breakdown of thiohemiacetal and thioester intermediates whereby Cys(276) functions as the catalytic nucleophile. Stopped-flow kinetic data capture the essential deprotonation of Cys(276) in the course of the first oxidation step, allowing the thiolate side chain to act as a trap of the incipient aldehyde. Because thiohemiacetal intermediate accumulates at steady state under physiological reaction conditions, hUGDH inhibition might best explore ligand binding to the NAD(+) binding domain.     

Identification and molecular cloning of a heparosan synthase from Pasteurella multocida type D.

Pasteurella multocida Type D, a causative agent of atrophic rhinitis in swine and pasteurellosis in other domestic animals, produces an extracellular polysaccharide capsule that is a putative virulence factor. It was reported previously that the capsule was removed by treating microbes with heparin lyase III. We molecularly cloned a 617-residue enzyme, pmHS, which is a heparosan (nonsulfated, unepimerized heparin) synthase. Recombinant Escherichia coli-derived pmHS catalyzes the polymerization of the monosaccharides from UDP-GlcNAc and UDP-GlcUA. Other structurally related sugar nucleotides did not substitute. Synthase activity was stimulated about 7-25-fold by the addition of an exogenous polymer acceptor. Molecules composed of approximately 500-3,000 sugar residues were produced in vitro. The polysaccharide was sensitive to the action of heparin lyase III but resistant to hyaluronan lyase. The sequence of the pmHS enzyme is not very similar to the vertebrate heparin/heparan sulfate glycosyltransferases, EXT1 and 2, or to other Pasteurella glycosaminoglycan synthases that produce hyaluronan or chondroitin. The pmHS enzyme is the first microbial dual-action glycosyltransferase to be described that forms a polysaccharide composed of beta4GlcUA-alpha4GlcNAc disaccharide repeats. In contrast, heparosan biosynthesis in E. coli K5 requires at least two separate polypeptides, KfiA and KfiC, to catalyze the same polymerization reaction.     

Identification of two genes, kpsM and kpsT, in region 3 of the polysialic acid gene cluster of Escherichia coli K1.

The polysialic acid capsule of Escherichia coli K1, a causative agent of neonatal septicemia and meningitis, is an essential virulence determinant. The 17-kb kps gene cluster, which is divided into three functionally distinct regions, encodes proteins necessary for polymer synthesis and expression at the cell surface. The central region, 2, encodes products required for synthesis, activation, and polymerization of sialic acid, while flanking regions, 1 and 3, are thought to be involved in polymer assembly and transport. In this study, we identified two genes in region 3, kpsM and kpsT, which encode proteins with predicted sizes of 29.6 and 24.9 kDa, respectively. The hydrophobicity profile of KpsM suggests that it is an integral membrane protein, while KpsT contains a consensus ATP-binding domain. KpsM and KpsT belong to a family of prokaryotic and eukaryotic proteins involved with a variety of biological processes, including membrane transport. A previously described kpsT chromosomal mutant that accumulates intracellular polysialic acid was characterized and could be complemented in trans. Results of site-directed mutagenesis of the putative ATP-binding domain of KpsT are consistent with the view that KpsT is a nucleotide-binding protein. KpsM and KpsT have significant similarity to BexB and BexA, two proteins that are essential for polysaccharide capsule expression in Haemophilus influenzae type b. We propose that KpsM and KpsT constitute a system for transport of polysialic acid across the cytoplasmic membrane.     

Comamonas testosteronan synthase, a bifunctional glycosyltransferase that produces a unique heparosan polysaccharide analog

Glycosaminoglycans (GAGs) are linear hexosamine-containing polysaccharides. These polysaccharides are synthesized by some pathogenic bacteria to form an extracellular coating or capsule. This strategy forms the basis of molecular camouflage since vertebrates possess naturally occurring GAGs that are essential for life. A recent sequence database search identified a putative protein from the opportunistic pathogen Comamonas testosteroni that exhibits similarity with the Pasteurella multocida GAG synthase PmHS1, which is responsible for the synthesis of a heparosan polysaccharide capsule. Initial supportive evidence included glucuronic acid (GlcUA)-containing polysaccharides extracted from C. testosteroni KF-1. We describe here the cloning and analysis of a novel Comamonas GAG synthase, CtTS. The GAG produced by CtTS in vitro consists of the sugars d-GlcUA and N-acetyl-D-glucosamine, but is insensitive to digestion by GAG digesting enzymes, thus has distinct glycosidic linkages from vertebrate GAGs. The backbone structure of the polysaccharide product [-4-D-GlcUA-α1,4-D-GlcNAc-α1-](n) was confirmed by nuclear magnetic resonance. Therefore, this novel GAG, testosteronan, consists of the same sugars as the biomedically relevant GAGs heparosan (N-acetyl-heparosan) and hyaluronan but may have distinct properties useful for future medical applications.     

Identification and molecular cloning of a chondroitin synthase from Pasteurella multocida type F

Pasteurella multocida Type F, the minor fowl cholera pathogen, produces an extracellular polysaccharide capsule that is a putative virulence factor. It was reported that the capsule was removed by treating microbes with chondroitin AC lyase. We found by acid hydrolysis that the polysaccharide contained galactosamine and glucuronic acid. We molecularly cloned a Type F polysaccharide synthase and characterized its enzymatic activity. The 965-residue enzyme, called P. multocida chondroitin synthase (pmCS), is 87% identical at the nucleotide and the amino acid level to the hyaluronan synthase, pmHAS, from P. multocida Type A. A recombinant Escherichia coli-derived truncated, soluble version of pmCS (residues 1-704) was shown to catalyze the repetitive addition of sugars from UDP-GalNAc and UDP-GlcUA to chondroitin oligosaccharide acceptors in vitro. Other structurally related sugar nucleotide precursors did not substitute in the elongation reaction. Polymer molecules composed of approximately 10(3) sugar residues were produced, as measured by gel filtration chromatography. The polysaccharide synthesized in vitro was sensitive to the action of chondroitin AC lyase but resistant to the action of hyaluronan lyase. This is the first report identifying a glycosyltransferase that forms a polysaccharide composed of chondroitin disaccharide repeats, [beta(1,4)GlcUA-beta(1,3)GalNAc](n). In analogy to known hyaluronan synthases, a single polypeptide species, pmCS, possesses both transferase activities.     

Evaluation of critical structural elements of UDP-sugar substrates and certain cysteine residues of a vertebrate hyaluronan synthase

The hyaluronan (HA) synthases catalyze the addition of two different monosaccharides from UDP-sugar substrates to the linear heteropolysaccharide chain. To accomplish this task, the HA synthases must be able to bind and to transfer from both UDP-sugar substrates. Until now, it has been impossible to distinguish between these two abilities. We have created a mutant of xlHAS1, a HA synthase from Xenopus laevis, that allows for the examination of the enzyme's ability to bind substrate only. The ability of different compounds to protect the xlHAS1(C337S) mutant enzyme from loss of activity due to treatment with N-ethylmaleimide, a cysteine-modifying reagent, yields information on the relative affinity of a variety of nucleotides and nucleotide-sugars. We have observed that the substrate binding selectivity is more relaxed than the specificity of catalytic transfer. The only attribute that appears to be absolutely required for binding is a nucleotide containing two phosphates complexed with magnesium ion. The role of certain cysteine residues in catalysis was also evaluated. Cys307 of xlHAS1 may play a role in catalysis or in maintaining structure. Mutation of Cys337 raises the UDP-GlcUA Michaelis constant (K(m)), suggesting that this residue participates in UDP-GlcUA substrate binding or in catalytic complex formation.     

A membrane transporter mediates access of uridine 5'-diphosphoglucuronic acid from the cytosol into the endoplasmic reticulum of rat hepatocytes: implications for glucuronidation reactions

Hepatic glucuronidation of a wide variety of substrates is catalyzed by the membrane-bound UDP-glucuronosyltransferases. Uridine 5'-diphosphoglucuronic acid (UDP-GlcUA) is the essential cosubstrate for all UDP-glucuronosyltransferase-mediated reactions. The mechanism by which this bulky, hydrophilic nucleotide-sugar is transported from the cytosol (where it is synthesized) to its binding site(s) on the enzyme is unknown. To determine whether a membrane carrier mediates the access of UDP-GlcUA into the endoplasmic reticulum, the transport of uridine 5'-diphospho-D-[U-14C]glucuronic acid into vesicles of rough and smooth endoplasmic reticulum isolated from rat liver was investigated at 38 degrees C using a rapid filtration technique. Uptake of UDP-GlcUA by both rough and smooth vesicles was extremely rapid (linear for only 10-20 s) and temperature-dependent (negligible at 4 degrees C). UDP-GlcUA uptake was saturable, and similar kinetic parameters were obtained for rough and smooth vesicles (Km 1.9 microM, Vmax 443 pmol/mg protein per min, and Km 1.3 microM, Vmax 503 pmol/mg protein per min, respectively). The uptake of UDP-GlcUA also exhibited a high degree of specificity, since many related compounds, including UMP, UDP and UDP-Glc, did not influence uptake. In addition, the non-penetrating inhibitors of anion transport, 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid (SITS), 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS), and probenecid, markedly inhibited UDP-GlcUA uptake. Finally, osmotic modulation of the intravesicular volume did not affect total uptake of UDP-GlcUA by membrane vesicles at equilibrium, indicating that this nucleotide-sugar is transported into the membrane rather than the intravesicular space. Collectively, these data provide direct evidence for a specific, carrier-mediated uptake process, which transports UDP-GlcUA from the cytosol into the endoplasmic reticulum of hepatocytes. This UDP-GlcUA transporter may be involved in the regulation of hepatic glucuronidation reactions.     

Analysis of the polymerization initiation and activity of Pasteurella multocida heparosan synthase PmHS2, an enzyme with glycosyltransferase and UDP-sugar hydrolase activity

Heparosan synthase catalyzes the polymerization of heparosan (-4GlcUAβ1-4GlcNAcα1-)(n) by transferring alternatively the monosaccharide units from UDP-GlcUA and UDP-GlcNAc to an acceptor molecule. Details on the heparosan chain initiation by Pasteurella multocida heparosan synthase PmHS2 and its influence on the polymerization process have not been reported yet. By site-directed mutagenesis of PmHS2, the single action transferases PmHS2-GlcUA(+) and PmHS2-GlcNAc(+) were obtained. When incubated together in the standard polymerization conditions, the PmHS2-GlcUA(+)/PmHS2-GlcNAc(+) showed comparable polymerization properties as determined for PmHS2. We investigated the first step occurring in heparosan chain initiation by the use of the single action transferases and by studying the PmHS2 polymerization process in the presence of heparosan templates and various UDP-sugar concentrations. We observed that PmHS2 favored the initiation of the heparosan chains when incubated in the presence of an excess of UDP-GlcNAc. It resulted in a higher number of heparosan chains with a lower average molecular weight or in the synthesis of two distinct groups of heparosan chain length, in the absence or in the presence of heparosan templates, respectively. These data suggest that PmHS2 transfers GlcUA from UDP-GlcUA moiety to a UDP-GlcNAc acceptor molecule to initiate the heparosan polymerization; as a consequence, not only the UDP-sugar concentration but also the amount of each UDP-sugar is influencing the PmHS2 polymerization process. In addition, it was shown that PmHS2 hydrolyzes the UDP-sugars, UDP-GlcUA being more degraded than UDP-GlcNAc. However, PmHS2 incubated in the presence of both UDP-sugars favors the synthesis of heparosan polymers over the hydrolysis of UDP-sugars.     

The catalytic efficiency of trehalose-6-phosphate synthase is effected by the N-loop at low temperatures

The enzyme OtsA (trehalose-6-phosphate synthase) is ubiquitous in both prokaryotic and eukaryotic organisms, where it plays a critical role in stress resistance and glucose metabolism. Here, we cloned the otsA gene from Arthrobacter sp. Cjts, and expressed and then purified the recombinant proteins. Enzyme activity analysis indicated that the high catalytic efficiency of OtsA from Arthrobacter sp. Cjts resulted from the high affinity of the enzyme for uridine 5′-diphosphoglucose (UDP-Glc) at low temperatures. We also confirmed that the N-loop sequence of OtsA has a large effect on its affinity for UDP-Glc. Sequence analysis indicated that the flexibility of the N-loop may be directly related to the catalytic efficiency of OtsA at low temperatures.     

Polyacrylamide gel electrophoresis of the capsular polysaccharides of Escherichia coli K1 and other bacteria.

Methods were developed for the polyacrylamide gel electrophoretic analysis of capsular polysaccharides of bacteria with Escherichia coli K1 as a model. Conditions were determined for the rapid and gentle extraction of the K1 polysaccharide by incubation of the bacteria in a volatile buffer and for the subsequent removal of the putative phospholipid moiety attached to the reducing end of the polysaccharide. Detection of the polysaccharides after gel electrophoresis was carried out by fluorography of samples labeled by sodium borotritiide reduction or by combined alcian blue and silver staining. The smallest components could be detected only by fluorography, owing to diffusion during staining. Components of the E. coli K1 polysialic acid capsule ranging from monomers to 80 sialic-acid-unit-containing polymers could be separated as distinct bands in a ladderlike pattern. A maximum chain length of 160 to 230 sialyl residues was estimated for the bulk of the K1 polysaccharide from the nearly linear reciprocal relationship between the logarithm of the molecular size and the distance of migration. Gel electrophoresis of capsular polysaccharides of other bacterial species revealed different electrophoretic mobilities for each polysaccharide, with a ladderlike pattern displayed by the fastest-moving components. There are many potential applications of this facile method for the determination of the sizes of molecules present in a polydisperse polysaccharide sample. When combined with the simple method for the isolation of the capsule, as in the case of the K1 capsule, it provides an efficient tool for the characterization and comparison of the capsular polysaccharides of bacteria.