Synthesis of teichoic acids. VI. The formation of multiple wall polymers in Bacillus subtilis W-23

Control of Morphological Differentiation of Streptomyces coelicolor A3(2) by Phosphorylation of MreC and PBP2

During morphological differentiation of Streptomyces coelicolor A3(2), the sporogenic aerial hyphae are transformed into a chain of more than fifty spores in a highly coordinated manner. Synthesis of the thickened spore envelope is directed by the Streptomyces spore wall synthesizing complex SSSC which resembles the elongasome of rod-shaped bacteria. The SSSC includes the eukaryotic type serine/threonine protein kinase (eSTPK) PkaI, encoded within a cluster of five independently transcribed eSTPK genes (SCO4775-4779). To understand the role of PkaI in spore wall synthesis, we screened a S. coelicolor genomic library for PkaI interaction partners by bacterial two-hybrid analyses and identified several proteins with a documented role in sporulation. We inactivated pkaI and deleted the complete SCO4775-4779 cluster. Deletion of pkaI alone delayed sporulation and produced some aberrant spores. The five-fold mutant NLΔ4775-4779 had a more severe defect and produced 18% aberrant spores affected in the integrity of the spore envelope. Moreover, overbalancing phosphorylation activity by expressing a second copy of any of these kinases caused a similar defect. Following co-expression of pkaI with either mreC or pbp2 in E. coli, phosphorylation of MreC and PBP2 was demonstrated and multiple phosphosites were identified by LC-MS/MS. Our data suggest that elaborate protein phosphorylation controls activity of the SSSC to ensure proper sporulation by suppressing premature cross-wall synthesis.

Wall teichoic acids of gram-positive bacteria

The peptidoglycan layers of many gram-positive bacteria are densely functionalized with anionic glycopolymers known as wall teichoic acids (WTAs). These polymers play crucial roles in cell shape determination, regulation of cell division, and other fundamental aspects of gram-positive bacterial physiology. Additionally, WTAs are important in pathogenesis and play key roles in antibiotic resistance. We provide an overview of WTA structure and biosynthesis, review recent studies on the biological roles of these polymers, and highlight remaining questions. We also discuss prospects for exploiting WTA biosynthesis as a target for new therapies to overcome resistant infections.

Methicillin resistance in Staphylococcus aureus requires glycosylated wall teichoic acids

Staphylococcus aureus peptidoglycan (PG) is densely functionalized with anionic polymers called wall teichoic acids (WTAs). These polymers contain three tailoring modifications: d-alanylation, α-O-GlcNAcylation, and β-O-GlcNAcylation. Here we describe the discovery and biochemical characterization of a unique glycosyltransferase, TarS, that attaches β-O-GlcNAc (β-O-N-acetyl-D-glucosamine) residues to S. aureus WTAs. We report that methicillin resistant S. aureus (MRSA) is sensitized to β-lactams upon tarS deletion. Unlike strains completely lacking WTAs, which are also sensitive to β-lactams, ΔtarS strains have no growth or cell division defects. Because neither α-O-GlcNAc nor β-O-Glucose modifications can confer resistance, the resistance phenotype requires a highly specific chemical modification of the WTA backbone, β-O-GlcNAc residues. These data suggest β-O-GlcNAcylated WTAs scaffold factors required for MRSA resistance. The β-O-GlcNAc transferase identified here, TarS, is a unique target for antimicrobials that sensitize MRSA to β-lactams.

The origins of 168, W23, and other Bacillus subtilis legacy strains

Bacillus subtilis is both a model organism for basic research and an industrial workhorse, yet there are major gaps in our understanding of the genomic heritage and provenance of many widely used strains. We analyzed 17 legacy strains dating to the early years of B. subtilis genetics. For three--NCIB 3610T, PY79, and SMY--we performed comparative genome sequencing. For the remainder, we used conventional sequencing to sample genomic regions expected to show sequence heterogeneity. Sequence comparisons showed that 168, its siblings (122, 160, and 166), and the type strains NCIB 3610 and ATCC 6051 are highly similar and are likely descendants of the original Marburg strain, although the 168 lineage shows genetic evidence of early domestication. Strains 23, W23, and W23SR are identical in sequence to each other but only 94.6% identical to the Marburg group in the sequenced regions. Strain 23, the probable W23 parent, likely arose from a contaminant in the mutagenesis experiments that produced 168. The remaining strains are all genomic hybrids, showing one or more "W23 islands" in a 168 genomic backbone. Each traces its origin to transformations of 168 derivatives with DNA from 23 or W23. The common prototrophic lab strain PY79 possesses substantial W23 islands at its trp and sac loci, along with large deletions that have reduced its genome 4.3%. SMY, reputed to be the parent of 168, is actually a 168-W23 hybrid that likely shares a recent ancestor with PY79. These data provide greater insight into the genomic history of these B. subtilis legacy strains.

Cell wall teichoic acid glycosylation in Listeria monocytogenes serotype 4b requires gtcA, a novel, serogroup-specific gene

We have identified a novel gene, gtcA, involved in the decoration of cell wall teichoic acid of Listeria monocytogenes serotype 4b with galactose and glucose. Insertional inactivation of gtcA brought about loss of reactivity with the serotype 4b-specific monoclonal antibody c74.22 and was accompanied by a complete lack of galactose and a marked reduction in the amounts of glucose on teichoic acid. Interestingly, the composition of membrane-associated lipoteichoic acid was not affected. Complementation of the mutants with the cloned gtcA in trans restored galactose and glucose on teichoic acid to wild-type levels. The complemented strains also recovered reactivity with c74.22. Within L. monocytogenes, sequences homologous to gtcA were found in all serogroup 4 isolates but not in strains of any other serotypes. In serotype 4b, gtcA appears to be the first member of a bicistronic operon which includes a gene with homology to Bacillus subtilis rpmE, encoding ribosomal protein L31. In contrast to gtcA, the latter gene appears conserved among all screened serotypes of L. monocytogenes.

Pseudo-allelic relationship between non-homologous genes concerned with biosynthesis of polyglycerol phosphate and polyribitol phosphate teichoic acids in Bacillus subtilis strains 168 and W23

A 60 kbp region of the Bacillus subtilis chromosome encompassing the genes concerned with teichoic acid biosynthesis has been subjected to physical analysis. No homology was detected by Southern hybridization between DNA segments encoding the tag genes of strain 168, concerned with polyglycerol phosphate (poly(groP)) biosynthesis, and the tar genes of strain W23, concerned with polyribitol phosphate (poly-(rboP)) biosynthesis. Analysis of 168/W23 interstrain hybrids that incorporate poly(rboP) instead of poly-(groP) into their cell walls revealed that, in every case, integral substitution of the W23 tar genes for the 168 tag genes had occurred. Interstrain hybrids of the 'W23-like' type have inherited larger segments of W23 DNA than interstrain hybrids of the 'mixed' type. The tag and tar genes are located at equivalent positions on the chromosomes of strains 168 and W23, behaving, in genetic crosses, like an allelic pair. They provide the first example of a pseudo-allelic relationship between non-homologous genes in B. subtilis.

Function of alpha-D-glucosyl monophosphorylpolyprenol in biosynthesis of cell wall teichoic acids in Bacillus coagulans

D-[alpha-14C]]glucosyl phosphorylpolyprenol ([ 14C]Glc-P-prenol) was formed from UDP-D-[14C]glucose in each of the membrane systems obtained from Bacillus coagulans AHU 1631 and AHU 1634 and two Bacillus megaterium strains. Membranes of these B. coagulans strains, which possess beta-D-glucosyl branches on the repeating units in their major cell wall teichoic acids, were shown to catalyze the transfer of the glucose residue from [14C]Glc-P-prenol to endogenous polymer. On the other hand, membranes of B. coagulans AHU 1366, which has no glucose substituents in the cell wall teichoic acid, exhibited neither [14C]Glc-P-prenol synthetase activity nor the activity of transferring glucose from [14C]Glc-P-prenol to endogenous acceptor. The enzyme which catalyzes the polymer glycosylation in the former two B. coagulans strains was most active at pH 5.5 and in the presence of the Mg2+ ion. The apparent Km for [14C]Glc-P-prenol was 0.6 microM. Hydrogen fluoride hydrolysis of the [14C]glucose-linked polymer product yielded a major fragment identical to D-galactosyl-alpha(1----2)(D-glucosyl-beta(1----1/3)) glycerol, the dephosphorylated repeating unit in the major cell wall teichoic acids of these B. coagulans strains. This result, together with the behavior of the radioactive polymer in chromatography on Sepharose CL-6B, DEAE-Sephacel, and Octyl-Sepharose CL-4B, led to the conclusion that [14C]Glc-P-prenol serves as an intermediate in the formation of beta-D-glucosyl branches on the polymer chains of cell wall teichoic acids in B. coagulans.

Identification of the protein encoded by rodC, a cell division gene from Bacillus subtilis

The rodC1 mutation of Bacillus subtilis is a temperature-sensitive marker which affects the orientation of the plane of cell division. We have cloned the rodC gene and have localized the site of the rodC1 lesion. To identify the rodC gene product, we have subjected several plasmid clones containing B. subtilis chromosomal DNA from the rodC region to maxicell analysis in Escherichia coli. A 68 kiloDalton protein has been identified as the rodC gene product. This is the initial cloning of a cell division gene and the identification of its product from B. subtilis. The rodC gene has also been implicated as being directly associated with the synthesis of glycerol teichoic acid.

The functions of autolysins in the growth and division of Bacillus subtilis

Some bacteria, such as streptococci, exhibit growth from discrete and well-defined zones. In Streptococcus faecalis, growth zones can be observed in the electron microscope, and the position of the zone can be used as a marker for cell cycle events. Growth of the cell surface of Bacillus subtilis appears to be by a much different mechanism from that of streptococci. Cell elongation takes place by the insertion at many sites in the cell cylinder of peptidoglycan components. The insertion occurs on the inner face of the wall, and upon cross linking, the new wall material becomes stress bearing and older wall is pushed to the surface. When old wall reaches the surface, it becomes susceptible to excision by autolysins, resulting in wall turnover; cell elongation, due to the stretching of the cross-linked peptidoglycan, therefore, accompanies turnover and does not require a specialized growth zone.

Structure of the linkage units between ribitol teichoic acids and peptidoglycan

The structure of the linkage regions between ribitol teichoic acids and peptidoglycan in the cell walls of Staphylococcus aureus H and 209P and Bacillus subtilis W23 and AHU 1390 was studied. Teichoic acid-linked saccharide preparations obtained from the cell walls by heating at pH 2.5 contained mannosamine and glycerol in small amounts. On mild alkali treatment, each teichoic acid-linked saccharide preparation was split into a disaccharide identified as N-acetylmannosaminyl beta(1----4)N-acetylglucosamine and the ribitol teichoic acid moiety that contained glycerol residues. The Smith degradation of reduced samples of the teichoic acid-linked saccharide preparations from S. aureus and B. subtilis gave fragments characterized as 1,2-ethylenediol phosphate-(glycerolphosphate)3-N-acetylmannosaminyl beta(1----4)N- -acetylxylosaminitol and 1,2-ethylenediolphosphate-(glycerol phosphate)2-N-acetylmannosaminyl beta(1----4)N-acetylxylosaminitol, respectively. The binding of the disaccharide unit to peptidoglycan was confirmed by the analysis of linkage-unit-bound glycopeptides obtained from NaIO4 oxidation of teichoic acid-glycopeptide complexes. Mild alkali treatment of the linkage-unit-bound glycopeptides yielded disaccharide-linked glycopeptides, which gave the disaccharide and phosphorylated glycopeptides on mild acid treatment. Thus, it is concluded that the ribitol teichoic acid chains in the cell walls of the strains of S. aureus and B. subtilis are linked to peptidoglycan through linkage units, (glycerol phosphate)3-N-acetylmannosaminyl beta(1----4)N-acetylglucosamine and (glycerol phosphate)2-N-acetylmannosaminyl beta(1----4)N-acetylglucosamine, respectively.

Synthesis of teichoic acid by Bacillus subtilis protoplasts

Protoplasts of Bacillus subtilis W23 readily synthesized ribitol teichoic acid from nucleotide precursors in the surrounding medium. With cytidine diphosphate-ribitol they made poly(ribitol phosphate), presumably attached to lipoteichoic acid carrier; when cytidine diphosphate-glycerol and uridine diphosphate-N-acetylglucosamine were also present a 10-fold increase in the rate of polymer synthesis occurred, and the product contained both the main chain and the linkage unit. Synthesis was inhibited by trypsin or p-chloromercuribenzenesulfonate in the medium, and we concluded that it occurred at the outer surface of the membrane. During synthesis, which was also achieved readily by whole cells after a brief period of wall lysis, the cytidine phosphate portion of the nucleotide precursors did not pass through the membrane. No evidence could be obtained for a transphosphorylation mechanism for the translocation process. It is suggested that reaction with exogenous substrates was due to temporary exposure of a protein component of the enzyme complex at the outer surface of the membrane during the normal biosynthetic cycle.

Teichoic and teichuronic acids: biosynthesis, assembly, and location

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Bacteriophage resistance in Bacillus subtilis 168, W23, and interstrain transformants

Strains of Bacillus subtilis 168 deficient in glucosylated teichoic acid vary in their resistance to bacteriophage infection. Although glucosylated teichoic acid is important for bacteriophage attachment, the results demonstrate that alternate receptor sites exist. Non-glucosylated cell wall mutants could be assigned to specific classes (gtaA, gtaB, gtaC) by their pattern of resistance to three closely related bacteriophages (phi25, phie, SP82). In addition to glucosylation, the type of teichoic acid was also important for bacteriophage attachment. B. subtilis strains 168 and W23 have different teichoic acids in their cell walls and have varied susceptibilities to bacteriophage infection. Transfer of bacteriophage resistance from strain W23 into a derivative of strain 168 was accomplished. The resistant bacteria obtained were imparied in their ability to adsorb bacteriophage and in their capacity to be transfected by bacteriophage deoxyribonucleic acid.

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.

Bacteriophages of Bacillus subtilis

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Studies on polysaccharide C of Staphylococcus epidermidis. 1. Isolation and chemical characterization

Polysaccharide C (poly C) has been isolated from two strains of S. epidermidis and characterized chemically. The results suggest that poly C is a wall N-acetylglucosaminylglycerol teichoic acid, linked through 1:3-phosphodiester linkages. One poly C preparation contained only beta-linked N-acetyglucosamine, the other traces of alpha-linked sugar in addition. The degree of substitution of sugar in the poly C preparations from the two strains was about 50 and 25 per cent.

The teichuronic acid of cell walls of Bacillus subtilis W23 grown in a chemostat under phosphate limitation

Cell walls of Bacillus subtilis W23 contain teichuronic acid when grown in a chemostat under phosphate limitation at a low dilution rate, but teichoic acid at a higher dilution rate. The teichuronic acid was purified and shown to be a polymer of glucuronic acid and N-acetylgalactosamine.

Immunological properties of teichoic acids

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An acceptor-dependent polyglycerolphosphate polymerase

A method for the extraction of polyglycerolphosphate polymerase from Bacillus subtilis membranes is described. Further purification by ion-exchange chromatography yields an enzyme fraction totally dependent on the addition of a heat-stable factor for activity. This factor was isolated from cell membranes and acts as an acceptor of glycerolphosphate units. The acceptor contains glycerolphosphate, glucosamine, and fatty acids, but its precise chemical structure has not yet been elucidated.

Teichoic acid hydrolase activity in soil bacteria (Bacillus subtilis-sporulation-phosphodiesterase-polyamines-concanavalin A)

Bacterial phosphodiesterases have been found that are capable of cleaving the backbone of teichoic acid. Such enzymes have not been reported previously. An aerobic, gram-negative, rod-shaped bacterium producing this activity was detected and isolated by autoradiography of soil suspensions growing on minimal medium containing (32)P-labeled Bacillus subtilis ATCC 6051 cell walls as the sole phosphorus source. Broken-cell preparations are capable of depolymerizing teichoic acids in media of low ionic strength at near-neutral pH values. An active teichoicase is also present in B. subtilis, ATCC 6051 (the Marburg strain), especially in sporulating cultures.

The wall teichoic acids of Lactobacillus plantarum N.I.R.D.C106. Location of the phosphodiester groups and separation of the chains

1. The identities of the component glycerol glucosides of the wall teichoic acids of Lactobacillus plantarum N.I.R.D. C106 have been confirmed by methylation analysis. These glucosides are alpha-d-glucopyranosyl-(1-->1)-l-glycerol, alpha-d-glucopyranosyl-(1-->2)-alpha-d-glucopyranosyl-(1-->1)-l-glycerol and alpha-d-glucopyranosyl-(1-->3)-alpha-d-glucopyranosyl-(1-->1)-l-glycerol. 2. These units are connected by phosphodiester groups attached to the 3(l)-hydroxyl group of glycerol and the 6-hydroxyl group of the non-reducing terminal glucose residues in the adjacent unit. 3. Concanavalin A forms a precipitate with the teichoic acid and the material so precipitated contains only the alpha-d-glucopyranosyl-(1-->2)-alpha-d-glucopyranosyl -(1-->1)-l-glycerol component. This unit is therefore present in a homogeneous polymer so that the teichoic acid is a mixture of this and of other possibly homogeneous chains containing the other two components.

The wall content and composition of Bacillus substilis var. niger grown in a chemostat

Bacillus subtilis var. niger was grown in a chemostat with various growth limitations and at various growth rates. The wall content and composition of the organism grown under these conditions were determined. The wall content, expressed as a percentage of the dry weight of organisms, varied with the growth rate. Analysis of wall samples showed that their composition also varied, particularly with respect to the phosphorus content. Wall samples extracted with trichloroacetic acid under carefully controlled conditions were found to contain various amounts of phosphorus, this being present as a glycerol phosphate polymer containing hexose (glucose and in some cases galactose), i.e. a teichoic aid. Teichoic acids were present in the walls of organisms grown under all conditions except when phosphorus limited growth. Then a different anionic polymer, composed of glucuronic acid and N-acetylgalactosamine (a teichuronic acid), was present. Under the specific growth conditions at pH7.0 and 35 degrees C in a chemostat, teichoic acid and teichuronic acid appeared to be mutually exclusive.

The mechanism of biosynthesis and direction of chain extension of a poly-(N-acetylglucosamine 1-phosphate) from the walls of Staphylococcus lactis N.C.T.C. 2102

1. The synthesis of a polymer of N-acetylglucosamine 1-phosphate, occurring in the walls of Staphylococcus lactis N.C.T.C. 2102, was examined by using cell-free enzyme preparations. The enzyme system was particulate, and probably represents fragmented cytoplasmic membrane. 2. Uridine diphosphate N-acetylglucosamine was the only substrate required for polymer synthesis and labelled substrate was used to show that N-acetylglucosamine 1-phosphate is transferred as an intact unit from substrate to polymer. 3. The properties of the enzyme system were studied. A high concentration of Mg(2+) or Mn(2+) was required for optimum activity, and the pH optimum was about 8.5. 4. End-group analysis during synthesis in vitro showed that newly formed chains contain up to about 15 repeating units. Pulse-labelling indicated that chain extension occurs by transfer from the nucleotide to the ;sugar-end' of the chain, i.e. to the end that is not attached to peptidoglycan in the wall.

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.

The cell wall of Bacillus licheniformis N.C.T.C. 6346. Isolation of low-molecular-weight fragments from the soluble mucopeptide

1. Soluble mucopeptide was prepared by lysozyme treatment of acid-extracted walls of Bacillus licheniformis N.C.T.C. 6346 and separated into fractions differing in molecular size by chromatography on Sephadex G-25 and G-50. 2. About 16% of the weight of soluble mucopeptide has a weight-average molecular weight in excess of 20000. About one half has a weight-average molecular weight of less than 2000 and the balance of soluble mucopeptide is of intermediate size. 3. In the mucopeptide fractions isolated from Sephadex there is a correlation between the weight-average molecular weight, the number of non-reducing muramic acid residues and the proportion of diaminopimelic acid residues recovered after treatment with 1-fluoro-2,4-dinitrobenzene. 4. The extent of cross-linking between peptide side chains is relatively low, even in mucopeptide material of the large molecular size. 5. The small amount of residual phosphorus present in preparations of B. licheniformis soluble mucopeptide remains associated mainly with mucopeptide material of large molecular size. 6. The mucopeptide components of lowest molecular weight are not produced as artifacts during the preparation of soluble mucopeptide, but are apparently incorporated in the insoluble mucopeptide present in walls of exponentially growing cells. 7. Soluble mucopeptide isolated in a complex with acidic polymers after lysozyme treatment of walls of B. licheniformis N.C.T.C. 6346 and Bacillus subtilis W23 retains a high molecular weight when the covalent bonds between mucopeptide and the acidic polymers are broken. 8. Pure fragments were isolated from B. licheniformis soluble mucopeptide. A major component, C1, of the material of smallest size is made up of one residue each of N-acetylglucosamine, N-acetylmuramic acid, l-alanine, glutamic acid and diaminopimelic acid. The N-acetylglucosamine is in beta-glycosidic linkage with a reducing N-acetylmuramic acid residue. The peptide unit is probably amidated. A quantitatively minor component, C2, has amino acid and amino sugar composition identical with that of component C1, but probably lacks an amide group. Another fragment, B1, is made up of two molecules of component C1 or C2 that are joined together through a molecule of d-alanine.