Purified,recombinant TagF protein from Bacillus subtilis 168 catalyzes the polymerization of glycerol phosphate onto a membrane acceptor in vitro

We report the first characterization of a recombinant protein involved in the polymerization of wall teichoic acid. Previously, a study of the teichoic acid polymerase activity associated with membranes from Bacillus subtilis 168 strains bearing thermosensitive mutations in tagB, tagD, and tagF implicated TagF as the poly(glycerol phosphate) polymerase (Pooley, H. M., Abellan, F. X., and Karamata, D. (1992) J. Bacteriol. 174, 646-649). In the work reported here, we have demonstrated an unequivocal role for tagF in the thermosensitivity of one such mutant (tagF1) by conditional complementation at the restrictive temperature with tagF under control of the xylose promoter at the amyE locus. We have overexpressed and purified recombinant B. subtilis TagF protein, and we provide direct biochemical evidence that this enzyme is responsible for polymerization of poly(glycerol phosphate) teichoic acid in B. subtilis 168. Recombinant hexahistidine-tagged TagF protein was purified from Escherichia coli and was used to develop a novel membrane pelleting assay to monitor poly(glycerol phosphate) polymerase activity. Purified TagF was shown to incorporate radioactivity from its substrate CDP-[(14)C]glycerol into a membrane fraction in vitro. This activity showed a saturable dependence on the concentration of CDP-glycerol (K(m) of 340 microm) and the membrane acceptor (half-maximal activity at 650 microg of protein/ml of purified B. subtilis membranes). High pressure liquid chromatography analysis confirmed the polymeric nature of the reaction product, approximately 35 glycerol phosphate units in length.     

Synthesis of polyglycerol phosphate by Bacillus stearothermophilus.

A particulate enzyme preparation from Bacillus stearothermophilus synthesized 1,3-poly(glycerol phosphage) from CDPglycerol at an optimum pH of 8.0 and the reaction was stimulated by divalent cations. Km for CDPglycerol was 0.18 mM. The synthesis was inhibited by CMP, CDP, and CTP and by concentrations of CDP-glycerol above 0.49 mM. The reaction was irreversible, The product had an average chain length of 8 glycerol units. About two thirds of the polymers were synthesized in entirety while the ramainder were attached to some acceptor by their phosphate end. The enzome was able to synthesize only a limited amount of polymer.     

Structure and functions of linkage unit intermediates in the biosynthesis of ribitol teichoic acids in Staphylococcus aureus H and Bacillus subtilis W23

The stepwise formation and characterization of linkage unit intermediates and their functions in ribitol teichoic acid biosynthesis were studied with membranes obtained from Staphylococcus aureus H and Bacillus subtilis W23. The formation of labeled polymer from CDP-[14C]ribitol and CDP-glycerol in each membrane system was markedly stimulated by the addition of N-acetylmannosaminyl(beta 1----4)N-acetylglucosamine (ManNAc-GlcNAc) linked to pyrophosphorylyisoprenol. Whereas incubation of S. aureus membranes with CDP-glycerol and ManNAc-[14C]GlcNAc-PP-prenol led to synthesis of (glycerol phosphate) 1-3-ManNAc-[14C]GlcNAc-PP-prenol, incubation of B. subtilis membranes with the same substrates yielded (glycerol phosphate)1-2-ManNAc-[14C]GlcNAc-PP-prenol. In S. aureus membranes, (glycerol phosphate)2-ManNAc-[14C]GlcNAc-PP-prenol as well as (glycerol phosphate)3-ManNAc-[14C]GlcNAc-PP-prenol served as an acceptor for ribitol phosphate units, but (glycerol phosphate)-ManNAc-[14C]GlcNAc-PP-prenol did not. In B. subtilis W23 membranes, (glycerol phosphate)-ManNAc-[14C]GlcNAc-PP-prenol served as a better acceptor for ribitol phosphate units than (glycerol phosphate)2-ManNAc-[14C]GlcNAc-PP-prenol. In this membrane system (ribitol phosphate)-(glycerol phosphate)-ManNAc-[14C]GlcNAc-PP-prenol was formed from ManNAc-[14C]GlcNAc-PP-prenol, CDP-glycerol and CDP-ribitol. The results indicate that (glycerol phosphate)1-3-ManNAc-GlcNAc-PP-prenol and (glycerol phosphate)1-2-ManNac-GlcNAc-PP-prenol are involved in the pathway for the synthesis of wall ribitol teichoic acids in S. aureus H and B. subtilis W23 respectively.     

The TagB protein in Bacillus subtilis 168 is an intracellular peripheral membrane protein that can incorporate glycerol phosphate onto a membrane-bound acceptor in vitro

Genes involved in the synthesis of poly(glycerol phosphate) wall teichoic acid have been identified in the tag locus of the model Gram-positive organism Bacillus subtilis 168. The functions of most of these gene products are predictable from sequence similarity to characterized proteins and have provided limited insight into the intracellular synthesis and translocation of wall teichoic acid. Nevertheless, critical steps of poly(glycerol phosphate) teichoic acid polymerization continue to be a puzzle. TagB and TagF, encoded in the tag locus, do not show sequence similarity to characterized proteins. We recently showed that recombinant TagF could catalyze glycerol phosphate polymerization in vitro. Based largely on homology to TagF, the TagB protein has been proposed to catalyze either an intracellular glycerophosphotransfer reaction or the extracellular teichoic acid/peptidoglycan ligation reaction. Here we have taken steps to characterize TagB, particularly through in vivo localization studies and in vitro biochemical assay, in order to make a case for either role in teichoic acid biogenesis. We have shown that TagB associates peripherally with the intracellular face of the cell membrane in vivo. We have also produced recombinant TagB and used it to demonstrate the enzymatic incorporation of labeled glycerol phosphate onto a membrane-bound acceptor. The data collected from this and the accompanying study are strongly supportive of a role for TagB in B. subtilis 168 teichoic acid biogenesis as the CDP-glycerol:N-acetyl-beta-d-mannosaminyl-1,4-N-acetyl-d-glucosaminyldiphosphoundecaprenyl glycerophosphotransferase. Here we use the trivial name "Tag primase."     

Studies on glucosyltransferase and endogenous glucosyl acceptor in Bacillus cereus AHU 1030 membranes

A glucosyltransferase, extracted from the membranes of Bacillus cereus AHU 1030 with Tris-HCl buffer containing 0.1% Triton X-100 at pH 9.5, was separated from an endogenous glucosyl acceptor by chromatography on DEAE-Sepharose CL-6B subsequent to chromatography on Sepharose 6B. Structural analysis data showed that the glucosyl acceptor was a glycerol phosphate polymer linked to beta-gentiobiosyl diglyceride. The enzyme catalyzed the transfer of glucosyl residues from UDP-glucose to C-2 of the glycerol residues of repeating units of the acceptor. On the other hand, a lipoteichoic acid which contained 0.3 D-alanine residue per phosphorus was isolated from the cells by phenol treatment at pH 4.6. Except for the presence of D-alanine, this lipoteichoic acid had the same structure as the glucosyl acceptor. The rate of glucosylation observed with the D-alanine-containing lipoteichoic acid as the substrate was less than 40% of that observed with the D-alanine-free lipoteichoic acid, indicating that the ester-linked D-alanine in the lipoteichoic acid interferes with the action of the glucosyltransferase. The enzyme also catalyzed glucosylation of poly(glycerol phosphate) which was synthesized in the reaction of a separate enzyme fraction with CDP-glycerol. Thus, it is likely that the glucosyltransferase functions in the synthesis of cell wall teichoic acid.     

Teichoic acid synthesis in Bacillus stearothermophilus

1. Particulate enzyme preparations obtained from Bacillus stearothermophilus B65 by digestion with lysozyme were shown to catalyse teichoic acid synthesis. With CDP-glycerol as sole substrate the preparations synthesized 1,3-poly(glycerol phosphate). It was characterized by alkaline hydrolysis, by glucosylation to the alkali-stable 2-glucosyl-1,3-poly(glycerol phosphate) with excess of UDP-glucose and a Bacillus subtilis Marburg enzyme system, by degradation of this latter product with 60%HF and periodate oxidation of the resulting glucosylglycerol. The specificity of the B. subtilis system previously reported (Glaser & Burger, 1964), was confirmed in the present work. 2. Pulse-labelling experiments, followed by periodate oxidation of the product and isolation of formaldehyde from the glycerol terminus of the polymer, showed that the B. stearothermophilus enzyme system transferred glycerol phosphate units to the glycerol end of the chain. The transfer reaction was irreversible. It was not determined if these poly(glycerol phosphate) chains were synthesized de novo, but it was shown that the newly synthesized oligomers were bound to much larger molecules. 3. When the B. stearothermophilus enzyme system was supplied with both CDP-glycerol and UDP-glucose, 1-glucosyl-2,3-poly(glycerol phosphate) was synthesized in addition to the 1,3-isomer. The former polymer was characterized by acid and alkaline hydrolysis, degradation with HF and periodate oxidation of the resulting glucosylglycerol, and periodate oxidation of the intact polymer followed by mild acid hydrolysis. This latter procedure removed the glucose substituents without disrupting the poly(glycerol phosphate) chain. 4. The poly(glycerol phosphate) isomers were distinguished by glucosylation with the B. subtilis enzymes and alkaline hydrolysis, the 2,3-isomer remaining alkali-labile. The proportion of 2,3-poly(glycerol phosphate) in the product increased with increasing amounts of UDP-glucose in the incubation mixture, but the total glycerol phosphate incorporated into products remained constant. It is suggested that the synthetic pathways of the two poly(glycerol phosphate) species may share a rate-limiting step.     

Biosynthesis of poly(galactosylglycerol phosphate) in Bacillus coagulans

The pathway for the de novo synthesis of a teichoic acid, poly(galactosylglycerol phosphate), in Bacillus coagulans AHU 1366 was studied by means of characterization and stepwise conversion of lipid-linked intermediates. Incubation of membranes with UDP-N-acetylglucosamine and UDP-glucose yielded a disaccharide-linked polyprenylpyrophosphate, whose sugar moiety was characterized as glucosyl(beta 1----4)N-acetylglucosamine (Glc-GlcNAc). By incubation with membranes and CDP-glycerol, Glc-GlcNAc-PP-prenol was converted to a series of glycolipids characterized as (Gro-P)1-6-Glc-GlcNAc-PP-prenol (Gro = glycerol). Glc-[14C]GlcNAc-PP-prenol was converted to polymer by incubation with membranes, CDP-glycerol and UDP-galactose. Smith degradation of the polymer gave two radioactive fragments corresponding to (Gro-P)3-Glc-GlcNAc and (Gro-P)4-Glc-GlcNAc. These results, together with data on gel chromatography of radioactive polymer synthesized from UDP-[3H]galactose, CDP-glycerol and Glc-[14C]GlcNAc-PP-prenol, led to the conclusion that in this strain poly(galactosylglycerol phosphate) is probably synthesized through the following pathway: GlcNAc-PP-prenol----Glc-GlcNAc-PP-prenol----(Gro-P)3-4 -Glc-GlcNAc-PP-prenol----(Gro-P-Gal)n- (Gro-P)3-4-Glc-GlcNAc-PP-prenol----(Gro-P-Gal)n- (Gro-P)3-4-Glc-GlcNAc-P-peptidoglycan complex.     

Biosynthesis of wall teichoic acids in Staphylococcus aureus H, Micrococcus varians and Bacillus subtilis W23. Involvement of lipid intermediates containing the disaccharide N-acetylmannosaminyl N-acetylglucosamine

The precursors for linkage unit (LU) synthesis in Staphylococcus aureus H were UDP-GlcNAc, UDP-N-acetylmannosamine (ManNAc) and CDP-glycerol and synthesis was stimulated by ATP. Moraprenol-PP-GlcNAc-ManNAc-(glycerol phosphate)1-3 was formed from chemically synthesised moraprenol-PP-GlcNAc, UDP-ManNAc and CDP-glycerol in the presence of Triton X-100. LU intermediates formed under both conditions served as acceptors for ribitol phosphate residues, from CDP-ribitol, which comprise the main chain. The initial transfer of GlcNAc-1-phosphate from UDP-GlcNAc was very sensitive to tunicamycin whereas the subsequent transfer of ManNAc from UDP-ManNAc was not. Poly(GlcNAc-1-phosphate) and LU synthesis in Micrococcus varians, with endogenous lipid acceptor, UDP-GlcNAc and CDP-glycerol, was stimulated by UDP-ManNAc. Synthesis of LU on exogenous moraprenol-PP-GlcNAc, with Triton X-100, was dependent on UDP-ManNAc and CDP-glycerol and the intermediates formed served as substrates for polymer synthesis. Membranes from Bacillus subtilis W23 had much lower levels of LU synthesis, but UDP-ManNAc was again required for optimal synthesis in the presence of UDP-GlcNAc and CDP-glycerol. Conditions for LU synthesis on exogenous moraprenol-PP-GlcNAc were not found in this organism. LU synthesis on endogenous acceptor in the absence of UDP-ManNAc was explained by contamination of membranes with UDP-GlcNAc 2-epimerase. Under appropriate conditions, low levels of this enzyme were sufficient to convert UDP-GlcNAc into a mixture of UDP-Glc-NAc and UDP-ManNAc and account for LU synthesis. The results indicate the formation of prenol-PP-GlcNAc-ManNAc-(glycerol phosphate)1-3 which is involved in the synthesis of wall teichoic acids in S. aureus H, M. varians and B. subtilis W23 and their attachment to peptidoglycan.     

In vitro synthesis of the unit that links teichoic acid to peptidoglycan.

The role of cytidine diphosphate (CDP)-glycerol in gram-positive bacteria whose walls lack poly(glycerol phosphate) was investigated. Membrane preparations from Staphylococcus aureus H, Bacillus subtilis W23, and Micrococcus sp. 2102 catalyzed the incorporation of glycerol phosphate residues from radioactive CDP-glycerol into a water-soluble polymer. In toluenized cells of Micrococcus sp. 2102, some of this product became linked to the wall. In each case, maximum incorporation of glycerol phosphate residues required the presence of the nucleotide precursors of wall teichoic acid and of uridine diphosphate-N-acetylglucosamine. In membrane preparations capable of synthesizing peptidoglycan, vancomycin caused a decrease in the incorporation of isotope from CDP-glycerol into polymer. Synthesis of the poly (glycerol phosphate) unit thus depended at an early stage on the concomitant synthesis of wall teichoic acid and later on the synthesis of peptidoglycan. It is concluded that CDP-glycerol is the biosynthetic precursor of the tri(glycerol phosphate) linkage unit between teichoic acid and peptidoglycan that has recently been characterized in S. aureus H.     

Biosynthesis of the wall teichoic acid in Bacillus licheniformis

1. The biosynthesis of the wall teichoic acid, poly(glycerol phosphate glucose), has been studied with a particulate membrane preparation from Bacillus licheniformis A.T.C.C. 9945. The precursor CDP-glycerol supplies glycerol phosphate residues, whereas UDP-glucose supplies only glucose to the repeating structure of the polymer. 2. Synthesis proceeds through polyprenol phosphate derivatives, and chemical studies and pulse-labelling techniques show that the first intermediate is the phosphodiester, glucose polyprenol monophosphate. CDP-glycerol donates a glycerol phosphate residue to this to give a second intermediate, (glycerol phosphate glucose phosphate) polyprenol. 3. The glucose residue in the lipid intermediates has the beta configuration, and chain extension in the synthesis of polymer occurs by transglycosylation with inversion of anomeric configuration at two stages.     

The biosynthesis of the wall teichoic acid in Staphylococcus lactis I3

1. The biosynthesis of the wall teichoic acid in Staphylococcus lactis I3 was studied. Cell-free particulate enzyme preparations, probably representing fragmented membrane, were isolated and used for the synthesis of polymer. 2. By using appropriately labelled CDP-glycerol and UDP-N-acetylglucosamine it was shown that the former contributes a glycerol phosphate residue and the latter contributes an N-acetylglucosamine 1-phosphate residue to the repeating unit. 3. No polymer was synthesized unless both nucleotides were present, and no other substrates were required. 4. The properties of the enzyme system were studied. 5. Although attempts to fractionate the system failed, the biosynthesis is believed to be complex and its mechanism is considered.     

Two conserved histidine residues are critical to the function of the TagF-like family of enzymes

The TagF protein from Bacillus subtilis 168 is the poly(glycerol phosphate) polymerase responsible for the synthesis of wall teichoic acid and is the prototype member of a poorly understood family of similar teichoic acid synthetic enzymes. Here we describe in vitro and in vivo characterization of TagF, which localizes the active site to the carboxyl terminus of the protein and identifies residues that are critical for catalysis. We also establish the first mechanistic link among TagF and similar proteins by demonstrating that the identified residues are also critical in the function of TagB, a homologous enzyme implicated as the glycerophosphotransferase responsible for priming poly(glycerol phosphate) synthesis. We investigated the dependence of TagF activity on pH and showed that deprotonation of a residue with a pK(a) near neutral is critical for proper function. Alteration of histidine residues 474 and 612 by site-directed mutagenesis abolished TagF activity in vitro (5000-fold reduction in k(cat)/K(m)) while variants in four other conserved acidic residues showed minimal loss of activity. Complementation using H474A and H612A mutant alleles failed to suppress a lethal temperature-sensitive tagF defect in vivo despite confirmation of robust expression by Western blot. When corresponding mutations were made to the homologous tagB gene, these alleles were unable to suppress a tagB temperature-sensitive lethal phenotype. These results extend the mechanistic observations for TagF across a wider family of enzymes and provide the first biochemical evidence for the relatedness of these two enzymes.     

The mechanism of wall synthesis in bacteria. The organization of enzymes and isoprenoid phosphates in the membrane

1. The synthesis of peptidoglycan and teichoic acids by cell-free preparations from Bacillus licheniformis A.T.C.C. 9945 and Bacillus subtilis N.C.T.C. 3610 has been studied under a variety of conditions. 2. It was shown that poly(glycerol phosphate) is synthesized through a lipid intermediate, and it is concluded from this and other work that all major bacterial wall polymers are formed in a similar manner through such intermediates. 3. Close interrelation between the synthesis of peptidoglycan and teichoic acids was demonstrated, and inhibition studies confirm that the polyprenol phosphate molecules participating in the synthesis of peptidoglycan are shared with the systems that synthesize teichoic acids. 4. Nucleotides for the synthesis of one polymer are inhibitory towards synthesis of the other, and these effects can be enhanced or diminished by preincubation of the enzyme system with appropriate nucleotide precursors. 5. It is concluded that the return of undecaprenol phosphate to a common pool occurs only after the completion of polymer chains, and not after each cycle in the attachment of individual repeating units. This and other observations support a model for bacterial wall synthesis in which the multi-enzyme systems for each polymer are closely aligned in the membrane, with a molecule of undecaprenol phosphate located between them in a manner that enables it to be shared. The general mechanisms of wall synthesis and its control are discussed.     

A glycosyltransferase-enriched reconstituted membrane system for the synthesis of branched O-linked glycans in vitro

Mimicking the biochemical reactions that take place in cell organelles is becoming one of the most important challenges in biological chemistry. In particular, reproducing the Golgi glycosylation system in vitro would allow the synthesis of bioactive glycan polymers and glycoconjugates for many future applications including treatments of numerous pathologies. In the present study, we reconstituted a membrane system enriched in glycosyltransferases obtained by combining the properties of the wheat germ lectin with the dialysable detergent n-octylglucoside. When applied to cells engineered to express the O-glycan branching enzyme core2 beta (1,6)-N-acetylglucosaminyltransferase (C2GnT-I), this combination led to the reconstitution of lipid vesicles exhibiting an enzyme activity 11 times higher than that found in microsomal membranes. The enzyme also showed a slightly higher affinity than its soluble counterpart toward the acceptor substrate. Moreover, the use of either the detergent re-solubilization, glycoprotein substrates or N-glycanase digestion suggests that most of the reconstituted glycosyltransferases have their catalytic domains in an extravesicular orientation. Using the disaccharide substrate Galβ1-3GalNAc-O-p-nitrophenyl as a primer, we performed sequential glycosylation reactions and compared the recovered oligosaccharides to those synthesized by cultured parental cells. After three successive glycosylation reactions using a single batch of the reconstituted vesicles and without changing the buffer, the acceptor was transformed into an O-glycan with chromatographic properties similar to glycans produced by C2GnT-I-expressing cells. Therefore, this new and efficient approach would greatly improve the synthesis of bioactive carbohydrates and glycoconjugates in vitro and could be easily adapted for the study of other reactions naturally occurring in the Golgi apparatus such as N-glycosylation or sulfation.     

In vitro system for the synthesis of teichoic acid linked to peptidoglycan.

A crude cell wall preparation from Staphylococcus aureus H prepared by the method of Mirelman and Sharon (1972) was shown to catalyze the synthesis of polyribitol phosphate linked to the cell wall peptidoglycan. The reaction used cytidine diphosphate (CDP)-ribitol as a substrate and in addition required the presence of CDP-glycerol, uridine diphosphate (UDP)-N-acetyl-D-glucosamine, and adenosine triphosphate. Incubation of radioactive CDP-glycerol with the crude cell wall preparation resulted in the transfer of glycerol phosphate residues to the cell wall; this reaction was greatly stimulated by the presence of UDP-N-acetylglucosamine. These data suggest that polyribitol phosphate is linked to the cell wall peptidoglycan by an oligomer contaning N-acetyl-D-glucosamine and glycerol phosphate.     

Concomitant synthesis and attachment of cell wall polymers by a membrane preparation from Micrococcus varians ATCC 29750

Membranes from Micrococcus varians catalyse the de novo synthesis of poly(N-acetylglucosamine 1-phosphate) attached to noncrosslinked peptidoglycan through a linkage unit of N-acetylglucosamine phosphate-tri(glycerol phosphate). The absence of CDP-glycerol, one of the precursors of linkage unit, precludes the attachment of the sugar 1-phosphate polymer. This report is the first of such polymer attachment performed by membranes which are completely free of cell walls.     

Chain length analysis of ADP-ribose polymers generated by poly(ADP-ribose) polymerase (PARP) as a function of beta-NAD+ and enzyme concentrations

Bireactant autopoly(ADP-ribosyl)ation of poly(ADP-ribose) polymerase (PARP) (EC 2.4.2.30) was carried out by using either increasing concentrations of beta-NAD+ (donor substrate) at a fixed protein concentration or increasing concentrations of PARP (acceptor substrate) at a fixed beta-NAD+ concentration. The [32P]ADP-ribose polymers synthesized were chemically detached from PARP by alkaline hydrolysis of the monoester bond between the carboxylate moiety of Glu and the polymer. Nucleic acid-like polymers were then analyzed by high-resolution polyacrylamide gel electrophoresis and autoradiography. The ADP-ribose chain lengths observed displayed substrate concentration-dependent elongation from 0.2 microM to 2 mM beta-NAD+. Similar results were observed at fixed concentrations of 4.5, 9, 18, 27, and 36 nM PARP. Therefore, we conclude that the concentration of the ADP-ribose donor substrate determines the average chain length of the polymer synthesized. In contrast, the polymer size was unaltered when the concentration of PARP was varied from 4.5 to 18 nM at a fixed beta-NAD+ concentration. However, when PARP concentrations > 18 nM were used, the total amount of monomeric ADP-ribose produced was noticeably less. Therefore, we conclude that high concentrations of PARP lead to acceptor substrate inhibition at the level of the ADP-ribose chain initiation reaction.     

Reconstitution of turkey erythrocyte beta-adrenergic receptors into human erythrocyte acceptor membranes. Demonstration of guanine nucleotide regulation of agonist affinity

Digitonin-solubilized turkey erythrocyte beta-adrenergic receptors were reconstituted by dialysis into human erythrocyte acceptor membranes which lack beta receptors. Incorporation of turkey beta receptors into acceptor membranes was directly proportional to the quantity of soluble protein added to the reconstitution system. Reconstituted beta receptors demonstrate saturable [125I]iodohydroxybenzylpindolol binding (Bmax = 11.1 +/- 0.8 fmol/mg, K = 77.8 +/- 8.6 pM) and stereospecificity ((-)-propranolol, K = 11.0 nM; (+)-propranolol, K = 2000 nM; (-)-isoproterenol, K = 250 nM; (+)-isoproterenol, K = 82 micro M). Reconstituted beta receptors appear to be incorporated into acceptor membranes as integral proteins. Reconstituted beta receptors cannot be extracted by high salt or pH (3 to 11); detergent is required for resolubilization of reconstituted beta receptors. Adenylate cyclase stimulation was not obtained in reconstituted membranes since acceptor membranes lack a catalytic subunit. However, guanine nucleotide regulation of agonist affinity was observed indicating a functional reconstitution. GTP (100 micro M) produces a 5-fold decrease in the affinity of isoproterenol for reconstituted beta receptors. Experiments with sulfhydryl reagents indicate that the reconstituted beta receptor couples with the guanine nucleotide regulatory protein of the acceptor membranes. These data describe the successful reconstitution of a beta receptor and indicate that the reconstituted beta receptor can interact with the GTP binding protein of human erythrocyte acceptor membranes.     

The Wall Teichoic Acid Polymerase TagF Is Non-processive in Vitro and Amenable to Study Using Steady State Kinetic Analysis

Wall teichoic acids are a chemically diverse group of anionic polymers that constitute up to 50% of the Gram-positive cell wall. These polymers play a pivotal role in virulence and have been implicated in a diverse range of physiological functions. The TagF-like family of enzymes has been shown to be responsible for wall teichoic acid priming and polymerization events. Although many such enzymes are well validated therapeutic targets, a mechanistic understanding of this enzyme family has remained elusive. TagF is the prototypical teichoic acid polymerase and uses CDP-glycerol to catalyze synthesis of the linear (1,3)-linked poly(glycerol phosphate) teichoic acid in Bacillus subtilis 168. Here we used a synthetic soluble analog of the natural substrate of the enzyme, Lipid ϕ, to conduct the first detailed mechanistic investigation of teichoic acid polymerization. Through the use of a new high pressure liquid chromatography-based assay to monitor single glycerol phosphate incorporations into the Lipid ϕ analog, we conducted a detailed analysis of reaction product formation patterns and unequivocally showed TagF to be non-processive in vitro. Furthermore by monitoring the kinetics of polymerization, we showed that Lipid ϕ analog species varying in size have the same K_m value of 2.6 μm and validated use of Bi Bi velocity expressions to model the TagF enzyme system. Initial rate analysis showed that TagF catalyzes a sequential Bi Bi mechanism where both substrates are added to the enzyme prior to product release consistent with a single displacement chemical mechanism.Wall teichoic acids are a group of phosphate-containing anionic carbohydrate polymers that constitute up to 50% of the dry weight of the Gram-positive cell wall (1). Teichoic acids play a pivotal role in virulence and have been implicated in a diverse range of physiological functions including cation homeostasis, nutrient trafficking, binding of envelope proteins, and regulation of autolysins (2–4). Our knowledge of wall teichoic acid synthesis largely stems from studies conducted in the model bacterium Bacillus subtilis 168, which expresses a linear (1,3)-linked poly(glycerol phosphate) teichoic acid (5–7). Through these studies, our group and others have identified the genetic requirements for poly(glycerol phosphate) synthesis; however, until recently, a biochemical understanding of priming and polymerization events have been confounded by the interfacial localization of these enzymatic steps (8, 9). Indeed interfacial localization has hindered the understanding of the synthesis of many other important cell wall components such as O-antigen, polysialic acid, lipoarabinomannan, oligomers for N-linked glycosylation, and others (10–13). A breakthrough in our ability to study the enzymes involved in the lipid-linked steps of wall teichoic acid synthesis was made by Ginsberg et al. (14) with the development of synthetic substrate analogs of lipid-linked wall teichoic acid intermediates. These substrate analogs have since facilitated the detailed mechanistic study of uncharacterized teichoic acid enzymes and were used to reconstitute all intracellular steps in Staphylococcus aureus wall teichoic acid synthesis in vitro (15, 16).Genetic and biochemical studies have given rise to a model for the synthesis of poly(glycerol phosphate) wall teichoic acid in B. subtilis 168 in which polymer synthesis is carried out on the intracellular surface of the cytoplasmic membrane by stepwise additions of sugars to an undecaprenol phosphate lipid carrier via the tag (teichoic acid glycerol) gene products (7, 17). Polymer synthesis is initiated by TagO, which catalyzes the transfer of N-acetylglucosamine-1-phosphate from UDP-GlcNAc to undecaprenol phosphate to create Lipid α (18) (the new nomenclature for lipid-linked teichoic acid intermediates proposed by Pereira and Brown (17) is summarized in 2 is transferred to Lipid α from UDP-ManNAc by TagA, producing Lipid β that is “primed” with sn-glycerol-3-phosphate by TagB to create the polymerization substrate Lipid ϕ.1 (9, 14, 16). Some 30–50 glycerol phosphate residues are subsequently added to Lipid ϕ.1 by TagF, and the intracellular steps of teichoic acid synthesis are completed via polymer glucosylation by TagE (6, 8). Intracellular teichoic acid is then exported to the outer leaflet of the cytoplasmic membrane by the TagG/H ATP-binding cassette transport system and transferred to peptidoglycan by a currently unknown enzyme (19).

TABLE 1

Recently proposed nomenclature for wall teichoic acid intermediatesShown is the nomenclature proposed for wall teichoic acid biosynthetic intermediates (17). Intermediates were named according to the enzyme utilizing the molecule as a substrate. Lipid α is the substrate for TagA, Lipid β is the substrate for TagB. Lipid ϕ.n species are substrates for TagF where n indicates the number of glycerol phosphate residues in the molecule. For example, Lipid ϕ.1 is the product of the TagB-catalyzed priming reaction where a single glycerol phosphate residue is added. und, undecaprenol; P, phosphate; GroP, sn-glycerol-3-phosphate.

CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase, which is involved in the synthesis of the major wall teichoic acid in Bacillus subtilis 168, is encoded by tagF (rodC).

Assays of CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase (CGPTase) (EC 2.7.8.12) in membranes isolated from Bacillus subtilis 168 wild type and 11 strains bearing conditional lethal thermosensitive mutations in tagB, tagD, or tagF revealed that CGPTase deficiency was associated only with mutant tagF alleles. In vitro, thermosensitivity of CGPTase strongly suggests that the structural gene for this enzyme is tagF. We discuss apparent discrepancies between biochemical evidence favoring a membrane location for TagF and a previous report that suggested a cytoplasmic location based on sequence analysis.