The nucleotide sequence of the rodC operon of Bacillus subtilis

The sweet tooth of bacteria: common themes in bacterial glycoconjugates

Humans have been increasingly recognized as being superorganisms, living in close contact with a microbiota on all their mucosal surfaces. However, most studies on the human microbiota have focused on gaining comprehensive insights into the composition of the microbiota under different health conditions (e.g., enterotypes), while there is also a need for detailed knowledge of the different molecules that mediate interactions with the host. Glycoconjugates are an interesting class of molecules for detailed studies, as they form a strain-specific barcode on the surface of bacteria, mediating specific interactions with the host. Strikingly, most glycoconjugates are synthesized by similar biosynthesis mechanisms. Bacteria can produce their major glycoconjugates by using a sequential or an en bloc mechanism, with both mechanistic options coexisting in many species for different macromolecules. In this review, these common themes are conceptualized and illustrated for all major classes of known bacterial glycoconjugates, with a special focus on the rather recently emergent field of glycosylated proteins. We describe the biosynthesis and importance of glycoconjugates in both pathogenic and beneficial bacteria and in both Gram-positive and -negative organisms. The focus lies on microorganisms important for human physiology. In addition, the potential for a better knowledge of bacterial glycoconjugates in the emerging field of glycoengineering and other perspectives is discussed.

Membrane Translocation and Assembly of Sugar Polymer Precursors

Bacterial polysaccharides play an essential role in cell viability, virulence, and evasion of host defenses. Although the polysaccharides themselves are highly diverse, the pathways by which bacteria synthesize these essential polymers are conserved in both Gram-negative and Gram-positive organisms. By utilizing a lipid linker, a series of glycosyltransferases and integral membrane proteins act in concert to synthesize capsular polysaccharide, teichoic acid, and teichuronic acid. The pathways used to produce these molecules are the Wzx/Wzy-dependent, the ABC-transporter-dependent, and the synthase-dependent pathways. This chapter will cover the initiation, synthesis of the various polysaccharides on the cytoplasmic face of the membrane using nucleotide sugar precursors, and export of the nascent chain from the cytoplasm to the extracellular milieu. As microbial glycobiology is an emerging field in Gram-positive bacteria research, parallels will be drawn to the more widely studied polysaccharide biosynthesis systems in Gram-negative species in order to provide greater understanding of these biologically significant molecules.

Pathways and roles of wall teichoic acid glycosylation in Staphylococcus aureus

The thick peptidoglycan layers of Gram-positive bacteria are connected to polyanionic glycopolymers called wall teichoic acids (WTA). Pathogens such as Staphylococcus aureus, Listeria monocytogenes, or Enterococcus faecalis produce WTA with diverse, usually strain-specific structure. Extensive studies on S. aureus WTA mutants revealed important functions of WTA in cell division, growth, morphogenesis, resistance to antimicrobials, and interaction with host or phages. While most of the S. aureus WTA-biosynthetic genes have been identified it remained unclear for long how and why S. aureus glycosylates WTA with α- or β-linked N-acetylglucosamine (GlcNAc). Only recently the discovery of two WTA glycosyltransferases, TarM and TarS, yielded fundamental insights into the roles of S. aureus WTA glycosylation. Mutants lacking WTA GlcNAc are resistant towards most of the S. aureus phages and, surprisingly, TarS-mediated WTA β-O-GlcNAc modification is essential for β-lactam resistance in methicillin-resistant S. aureus. Notably, S. aureus WTA GlcNAc residues are major antigens and activate the complement system contributing to opsonophagocytosis. WTA glycosylation with a variety of sugars and corresponding glycosyltransferases were also identified in other Gram-positive bacteria, which paves the way for detailed investigations on the diverse roles of WTA modification with sugar residues.

Taking aim at wall teichoic acid synthesis: new biology and new leads for antibiotics

Wall teichoic acids are a major and integral component of the Gram-positive cell wall. These structures are present across all species of Gram-positive bacteria and constitute roughly half of the cell wall. Despite decades of careful investigation, a definitive physiological function for wall teichoic acids remains elusive. Advances in the genetics and biochemistry of wall teichoic acid synthesis have led to a new understanding of the complexity of cell wall synthesis in Gram-positive bacteria. Indeed, these innovations have provided new molecular tools available to probe the synthesis and function of these cell wall structures. Among recent discoveries are unexpected roles for wall teichoic acid in cell division, coordination of peptidoglycan synthesis and β-lactam resistance in methicillin-resistant Staphylococcus aureus (MRSA). Notably, wall teichoic acid biogenesis has emerged as a bona fide drug target in S. aureus, where remarkable synthetic-viable interactions among biosynthetic genes have been leveraged for the discovery and characterization of novel inhibitors of the pathway.

Lactobacillus plantarum possesses the capability for wall teichoic acid backbone alditol switching

Background

Specific strains of Lactobacillus plantarum are marketed as health-promoting probiotics. The role and interplay of cell-wall compounds like wall- and lipo-teichoic acids (WTA and LTA) in bacterial physiology and probiotic-host interactions remain obscure. L. plantarum WCFS1 harbors the genetic potential to switch WTA backbone alditol, providing an opportunity to study the impact of WTA backbone modifications in an isogenic background.

Results

Through genome mining and mutagenesis we constructed derivatives that synthesize alternative WTA variants. The mutants were shown to completely lack WTA, or produce WTA and LTA that lack D-Ala substitution, or ribitol-backbone WTA instead of the wild-type glycerol-containing backbone. DNA micro-array experiments established that the tarIJKL gene cluster is required for the biosynthesis of this alternative WTA backbone, and suggest ribose and arabinose are precursors thereof. Increased tarIJKL expression was not observed in any of our previously performed DNA microarray experiments, nor in qRT-PCR analyses of L. plantarum grown on various carbon sources, leaving the natural conditions leading to WTA backbone alditol switching, if any, to be identified. Human embryonic kidney NF-κB reporter cells expressing Toll like receptor (TLR)-2/6 were exposed to purified WTAs and/or the TA mutants, indicating that WTA is not directly involved in TLR-2/6 signaling, but attenuates this signaling in a backbone independent manner, likely by affecting the release and exposure of immunomodulatory compounds such as LTA. Moreover, human dendritic cells did not secrete any cytokines when purified WTAs were applied, whereas they secreted drastically decreased levels of the pro-inflammatory cytokines IL-12p70 and TNF-α after stimulation with the WTA mutants as compared to the wild-type.

Conclusions

The study presented here correlates structural differences in WTA to their functional characteristics, thereby providing important information aiding to improve our understanding of molecular host-microbe interactions and probiotic functionality.

Studies of the genetics, function, and kinetic mechanism of TagE, the wall teichoic acid glycosyltransferase in Bacillus subtilis 168

The biosynthetic enzymes involved in wall teichoic acid biogenesis in gram-positive bacteria have been the subject of renewed investigation in recent years with the benefit of modern tools of biochemistry and genetics. Nevertheless, there have been only limited investigations into the enzymes that glycosylate wall teichoic acid. Decades-old experiments in the model gram-positive bacterium, Bacillus subtilis 168, using phage-resistant mutants implicated tagE (also called gtaA and rodD) as the gene coding for the wall teichoic acid glycosyltransferase. This study and others have provided only indirect evidence to support a role for TagE in wall teichoic acid glycosylation. In this work, we showed that deletion of tagE resulted in the loss of α-glucose at the C-2 position of glycerol in the poly(glycerol phosphate) polymer backbone. We also reported the first kinetic characterization of pure, recombinant wall teichoic acid glycosyltransferase using clean synthetic substrates. We investigated the substrate specificity of TagE using a wide variety of acceptor substrates and found that the enzyme had a strong kinetic preference for the transfer of glucose from UDP-glucose to glycerol phosphate in polymeric form. Further, we showed that the enzyme recognized its polymeric (and repetitive) substrate with a sequential kinetic mechanism. This work provides direct evidence that TagE is the wall teichoic acid glycosyltransferase in B. subtilis 168 and provides a strong basis for further studies of the mechanism of wall teichoic acid glycosylation, a largely uncharted aspect of wall teichoic acid biogenesis.

Structure of the bacterial teichoic acid polymerase TagF provides insights into membrane association and catalysis

Teichoic acid polymers are composed of polyol-phosphate units and form a major component of Gram-positive bacterial cell walls. These anionic compounds perform a multitude of important roles in bacteria and are synthesized by monotopic membrane proteins of the TagF polymerase family. We have determined the structure of Staphylococcus epidermidis TagF to 2.7-A resolution from a construct that includes both the membrane-targeting region and the glycerol-phosphate polymerase domains. TagF possesses a helical region for interaction with the lipid bilayer, placing the active site at a suitable distance for access to the membrane-bound substrate. Characterization of active-site residue variants and analysis of a CDP-glycerol substrate complex suggest a mechanism for polymer synthesis. With the importance of teichoic acid in Gram-positive physiology, this elucidation of the molecular details of TagF function provides a critical new target in the development of novel anti-infectives.

Glycosylation of wall teichoic acid in Staphylococcus aureus by TarM

Wall teichoic acid (WTA) glycopolymers are major constituents of cell envelopes in Staphylococcus aureus and related gram-positive bacteria with important roles in cell wall maintenance, susceptibility to antimicrobial molecules, biofilm formation, and host interaction. Most S. aureus strains express polyribitol phosphate WTA substituted with D-alanine and N-acetylglucosamine (GlcNAc). WTA sugar modifications are highly variable and have been implicated in bacteriophage susceptibility and immunogenicity, but the pathway and enzymes of staphylococcal WTA glycosylation have remained unknown. Revisiting the structure of S. aureus RN4220 WTA by NMR analysis revealed the presence of canonical polyribitol phosphate WTA bearing only alpha-linked GlcNAc substituents. A RN4220 transposon mutant resistant to WTA-dependent phages was identified and shown to produce altered WTA, which exhibited faster electrophoretic migration and lacked completely the WTA alpha-GlcNAc residues. Disruption of a gene of unknown function, renamed tarM, was responsible for this phenotype. Recombinant TarM was capable of glycosylating WTA in vitro in a UDP-GlcNAc-dependent manner, thereby confirming its WTA GlcNAc-transferase activity. Deletion of the last seven amino acids from the C terminus abolished the activity of TarM. tarM-related genes were found in the genomes of several WTA-producing bacteria, suggesting that TarM-mediated WTA glycosylation is a general pathway in gram-positive bacteria. Our study represents a basis for dissecting the biosynthesis and function of glycosylated WTA in S. aureus and other bacteria.

The extracellular biology of the lactobacilli

Lactobacilli belong to the lactic acid bacteria, which play a key role in industrial and artisan food raw-material fermentation, including a large variety of fermented dairy products. Next to their role in fermentation processes, specific strains of Lactobacillus are currently marketed as health-promoting cultures or probiotics. The last decade has witnessed the completion of a large number of Lactobacillus genome sequences, including the genome sequences of some of the probiotic species and strains. This development opens avenues to unravel the Lactobacillus-associated health-promoting activity at the molecular level. It is generally considered likely that an important part of the Lactobacillus effector molecules that participate in the proposed health-promoting interactions with the host (intestinal) system resides in the bacterial cell envelope. For this reason, it is important to accurately predict the Lactobacillus exoproteomes. Extensive annotation of these exoproteomes, combined with comparative analysis of species- or strain-specific exoproteomes, may identify candidate effector molecules, which may support specific effects on host physiology associated with particular Lactobacillus strains. Candidate health-promoting effector molecules of lactobacilli can then be validated via mutant approaches, which will allow for improved strain selection procedures, improved product quality control criteria and molecular science-based health claims.

Bacterial cell wall synthesis: new insights from localization studies

In order to maintain shape and withstand intracellular pressure, most bacteria are surrounded by a cell wall that consists mainly of the cross-linked polymer peptidoglycan (PG). The importance of PG for the maintenance of bacterial cell shape is underscored by the fact that, for various bacteria, several mutations affecting PG synthesis are associated with cell shape defects. In recent years, the application of fluorescence microscopy to the field of PG synthesis has led to an enormous increase in data on the relationship between cell wall synthesis and bacterial cell shape. First, a novel staining method enabled the visualization of PG precursor incorporation in live cells. Second, penicillin-binding proteins (PBPs), which mediate the final stages of PG synthesis, have been localized in various model organisms by means of immunofluorescence microscopy or green fluorescent protein fusions. In this review, we integrate the knowledge on the last stages of PG synthesis obtained in previous studies with the new data available on localization of PG synthesis and PBPs, in both rod-shaped and coccoid cells. We discuss a model in which, at least for a subset of PBPs, the presence of substrate is a major factor in determining PBP localization.

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.

Bacillus subtilis alpha-phosphoglucomutase is required for normal cell morphology and biofilm formation

Mutations designated gtaC and gtaE that affect alpha-phosphoglucomutase activity required for interconversion of glucose 6-phosphate and alpha-glucose 1-phosphate were mapped to the Bacillus subtilis pgcA (yhxB) gene. Backcrossing of the two mutations into the 168 reference strain was accompanied by impaired alpha-phosphoglucomutase activity in the soluble cell extract fraction, altered colony and cell morphology, and resistance to phages phi29 and rho11. Altered cell morphology, reversible by additional magnesium ions, may be correlated with a deficiency in the membrane glycolipid. The deficiency in biofilm formation in gtaC and gtaE mutants may be attributed to an inability to synthesize UDP-glucose, an important intermediate in a number of cell envelope biosynthetic processes.

A continuum of anionic charge: structures and functions of D-alanyl-teichoic acids in gram-positive bacteria

Teichoic acids (TAs) are major wall and membrane components of most gram-positive bacteria. With few exceptions, they are polymers of glycerol-phosphate or ribitol-phosphate to which are attached glycosyl and D-alanyl ester residues. Wall TA is attached to peptidoglycan via a linkage unit, whereas lipoteichoic acid is attached to glycolipid intercalated in the membrane. Together with peptidoglycan, these polymers make up a polyanionic matrix that functions in (i) cation homeostasis; (ii) trafficking of ions, nutrients, proteins, and antibiotics; (iii) regulation of autolysins; and (iv) presentation of envelope proteins. The esterification of TAs with D-alanyl esters provides a means of modulating the net anionic charge, determining the cationic binding capacity, and displaying cations in the wall. This review addresses the structures and functions of D-alanyl-TAs, the D-alanylation system encoded by the dlt operon, and the roles of TAs in cell growth. The importance of dlt in the physiology of many organisms is illustrated by the variety of mutant phenotypes. In addition, advances in our understanding of D-alanyl ester function in virulence and host-mediated responses have been made possible through targeted mutagenesis of dlt. Studies of the mechanism of D-alanylation have identified two potential targets of antibacterial action and provided possible screening reactions for designing novel agents targeted to D-alanyl-TA synthesis.

Induction of L-form-like cell shape change of Bacillus subtilis under microculture conditions

A remarkable cell shape change was observed in Bacillus subtilis strain 168 under microculture conditions on CI agar medium (Spizizen's minimal medium supplemented with a trace amount of yeast extract and Casamino acids). Cells cultured under a cover glass changed in form from rod-shaped to spherical, large and irregular shapes that closely resembled L-form cells. The cell shape change was observed only with CI medium, not with Spizizen's minimum medium alone or other rich media. The whole-cell protein profile of cells grown under cover glass and cells grown on CI agar plates differed in several respects. Tandem mass analysis of nine gel bands which differed in protein expression between the two conditions showed that proteins related to nitrate respiration and fermentation were expressed in the shape-changed cells grown under cover glass. The cell shape change of CI cultures was repressed when excess KNO3 was added to the medium. Whole-cell protein analysis of the normal rod-shaped cells grown with 0.1% KNO3 and the shape-changed cells grown without KNO3 revealed that the expression of the branched-chain alpha-keto acid dehydrogenase complex (coded by the bfmB gene locus) was elevated in the shape-changed cells. Inactivation of the bfmB locus resulted in the repression of cell shape change, and cells in which bfmB expression was induced by IPTG did show changes in shape. Transmission electron microscopy of ultrathin sections demonstrated that the shape-changed cells had thin walls, and plasmolysis of cells fixed with a solution including 0.1 M sucrose was observed. Clarifying the mechanism of thinning of the cell wall may lead to the development of a new type of cell wall biosynthetic inhibitor.

Essential nature of the mreC determinant of Bacillus subtilis

The mre genes of Escherichia coli and Bacillus subtilis are cell shape determination genes. Mutants affected in mre function are spheres instead of the normal rods. Although the mre determinants are not required for viability in E. coli, the mreB determinant is an essential gene in B. subtilis. Conflicting results have been reported as to whether the two membrane-associated proteins MreC and MreD are essential proteins. Furthermore, although the MreB protein has been studied in some detail, the roles of the MreC and MreD proteins in cell shape determination are unknown. We constructed a strain of B. subtilis in which expression of the mreC determinant is dependent upon the addition of isopropyl-beta-D-thiogalactopyranoside to the culture medium. Utilizing this conditional strain, it was shown that mreC is an essential gene in B. subtilis. Furthermore, it was shown that cells lacking sufficient quantities of MreC undergo morphological changes, namely, swelling and twisting of the cells, which is followed by cell lysis. Electron microscopy was utilized to demonstrate that a polymeric material accumulated at one side of the division septum of the cells and that the presence of this material correlated with the bending of the cell. The best explanation for the results is that the MreC protein is involved in the control of septal versus long-axis peptidoglycan synthesis, that cells lacking MreC perform aberrant septal peptidoglycan synthesis, and that lysis results from a deficiency in long-axis peptidoglycan synthesis.

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.

tagO is involved in the synthesis of all anionic cell-wall polymers in Bacillus subtilis 168

Sequence homologies suggest that the Bacillus subtilis 168 tagO gene encodes UDP-N-acetylglucosamine:undecaprenyl-P N-acetylglucosaminyl 1-P transferase, the enzyme responsible for catalysing the first step in the synthesis of the teichoic acid linkage unit, i.e. the formation of undecaprenyl-PP-N-acetylglucosamine. Inhibition of tagO expression mediated by an IPTG-inducible P(spac) promoter led to the development of a coccoid cell morphology, a feature characteristic of mutants blocked in teichoic acid synthesis. Indeed, analyses of the cell-wall phosphate content, as well as the incorporation of radioactively labelled precursors, revealed that the synthesis of poly(glycerol phosphate) and poly(glucosyl N-acetylgalactosamine 1-phosphate), the two strain 168 teichoic acids known to share the same linkage unit, was affected. Surprisingly, under phosphate limitation, deficiency of TagO precludes the synthesis of teichuronic acid, which is normally induced under these conditions. The regulatory region of tagO, containing two partly overlapping sigma(A)-controlled promoters, is similar to that of sigA, the gene encoding the major sigma factor responsible for growth. Here, the authors discuss the possibility that TagO may represent a pivotal element in the multi-enzyme complexes responsible for the synthesis of anionic cell-wall polymers, and that it may play one of the key roles in balanced cell growth.

An accessory sec locus of Streptococcus gordonii is required for export of the surface protein GspB and for normal levels of binding to human platelets

The translocation of proteins across the bacterial cell membrane is carried out by highly conserved components of the Sec system. Most bacterial species have a single copy of the genes encoding SecA and SecY, which are essential for viability. However, Streptococcus gordonii strain M99 encodes SecA and SecY homologues that are not required for viability or for the translocation of most exported proteins. The genes (secA2 and secY2) reside in a region of the chromosome required for the export of GspB, a 286 kDa cell wall-anchored protein. Loss of GspB surface expression is associated with a significant reduction in the binding of M99 to human platelets, suggesting that it may be an adhesin. Genetic analyses indicate that M99 has a second, canonical SecA homologue that is essential for viability. At least two other Gram-positive species, Streptococcus pneumoniae and Staphylococcus aureus, encode two sets of SecA and SecY homologues. One set is more similar to SecA and SecY of Escherichia coli, whereas the other set is more similar to SecA2 and SecY2 of strain M99. The conserved organization of genes in the secY2-secA2 loci suggests that, in each of these Gram-positive species, SecA2 and SecY2 may constitute a specialized system for the transport of a very large serine-rich repeat protein.

Comparison of ribitol and glycerol teichoic acid genes in Bacillus subtilis W23 and 168: identical function, similar divergent organization, but different regulation

The tar genes directing the synthesis of poly(ribitol phosphate), the main teichoic acid in Bacillus subtilis strain W23, were sequenced. They are organized in two divergently transcribed operons, tarABIJKL and tarDF, as are the tag genes specifying poly(glycerol phosphate) synthesis in B. subtilis 168. The features of the tar genes as well as the putative participation of their products in the proposed biosynthesis pathway of poly(ribitol phosphate) are presented. The tarA and tarD genes, which are most likely involved in the synthesis of the linkage unit (the entity coupling teichoic acid to peptidoglycan), are separated by 508 nt. Sequences of the outer segments of this regulatory region are similar to the two divergent promoter regions identified upstream of the tagA and tagD genes in strain 168. However, in W23, these regions, which also included functional promoters, are separated by an additional DNA segment of about 100 nt, on which two new mRNA starts, one in each direction, were identified. The regulatory regions of teichoic acid divergons of Bacillus globigii, Bacillus licheniformis and eight strains of B. subtilis were cloned and sequenced. In four B. subtilis strains and in B. globigii, their length and sequence are similar to the regulatory region of W23. In the others, including B. licheniformis, they are of the 168-type. Analysis of nucleotide sequences of a non-coding grey hole, present in the tag region of strain 168, revealed higher similarities to tar than to tag entities. This suggests that at least part of the tag genes specifying the synthesis of glucosylated poly(glycerol phosphate) in strain 168 was introduced by horizontal gene transfer into a strain originally synthesizing a ribitol-phosphate-containing teichoic acid.

Control of cell shape in bacteria: helical, actin-like filaments in Bacillus subtilis

In the absence of an overt cytoskeleton, the external cell wall of bacteria has traditionally been assumed to be the primary determinant of cell shape. In the Gram-positive bacterium Bacillus subtilis, two related genes, mreB and mbl, were shown to be required for different aspects of cell morphogenesis. Subcellular localization of the MreB and Mbl proteins revealed that each forms a distinct kind of filamentous helical structure lying close to the cell surface. The distribution of the proteins in different species of bacteria, and the similarity of their sequence to eukaryotic actins, suggest that the MreB-like proteins have a cytoskeletal, actin-like role in bacterial cell morphogenesis.

Molecular analysis of the tagF gene, encoding CDP-Glycerol:Poly(glycerophosphate) glycerophosphotransferase of Staphylococcus epidermidis ATCC 14990

Staphylococcus epidermidis ATCC 14990 produces a wall-associated glycerol teichoic acid which is chemically identical to the major wall-associated teichoic acid of Bacillus subtilis 168. The S. epidermidis tagF gene was cloned from genomic DNA and sequenced. When introduced on a plasmid vector into B. subtilis 1A486 carrying the conditionally lethal temperature-sensitive mutation tagF1 (rodC1), it expressed an 85-kDa protein which allowed colonies to grow at the restrictive temperature. This showed that the cloned S. epidermidis gene encodes a functional CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase. An amino acid substitution at residue 616 in the recombinant TagF protein eliminated complementation. Unlike B. subtilis, where the tagF gene is part of the tagDEF operon, the tagF gene of S. epidermidis is not linked to any other tag genes. We attempted to disrupt the chromosomal tagF gene in S. epidermidis TU3298 by directed integration of a temperature-sensitive plasmid but this failed, whereas a control plasmid containing the 5' end of tagF on a similarly sized DNA fragment was able to integrate. This suggests that the tagF gene is essential and that the TagF and other enzymes involved in teichoic acid biosynthesis could be targets for new antistaphylococcal drugs.

acs1 of Haemophilus influenzae type a capsulation locus region II encodes a bifunctional ribulose 5-phosphate reductase- CDP-ribitol pyrophosphorylase

The serotype-specific, 5.9-kb region II of the Haemophilus influenzae type a capsulation locus was sequenced and found to contain four open reading frames termed acs1 to acs4. Acs1 was 96% identical to H. influenzae type b Orf1, previously shown to have CDP-ribitol pyrophosphorylase activity (J. Van Eldere, L. Brophy, B. Loynds, P. Celis, I. Hancock, S. Carman, J. S. Kroll, and E. R. Moxon, Mol. Microbiol. 15:107-118, 1995). Low but significant homology to other pyrophosphorylases was only detected in the N-terminal part of Acs1, whereas the C-terminal part was homologous to several short-chain dehydrogenases/reductases, suggesting that Acs1 might be a bifunctional enzyme. To test this hypothesis, acs1 was cloned in an expression vector and overexpressed in Escherichia coli. Cells expressing this protein displayed both ribitol 5-phosphate dehydrogenase and CDP-ribitol pyrophosphorylase activities, whereas these activities were not detectable in control cells. Acs1 was purified to near homogeneity and found to copurify with ribitol 5-phosphate dehydrogenase and CDP-ribitol pyrophosphorylase activities. These had superimposable elution profiles from DEAE-Sepharose and Blue-Sepharose columns. The dehydrogenase activity was specific for ribulose 5-phosphate and NADPH in one direction and for ribitol 5-phosphate and NADP+ in the other direction and was markedly stimulated by CTP. The pyrophosphorylase showed activity with CTP and ribitol 5-phosphate or arabitol 5-phosphate. We conclude that acs1 encodes a bifunctional enzyme that converts ribulose 5-phosphate into ribitol 5-phosphate and further into CDP-ribitol, which is the activated precursor form for incorporation of ribitol 5-phosphate into the H. influenzae type a capsular polysaccharide.

Teichuronic acid operon of Bacillus subtilis 168

Sequence analysis reveals that the Bacillus subtilis 168 tuaABCDEFGH operon encodes enzymes required for the polymerization of teichuronic acid as well as for the synthesis of one of its precursors, the UDP-glucuronate. Mutants deficient in any of the tua genes, grown in batch cultures under conditions of phosphate limitation, were characterized by reduced amounts of uronate in their cell walls. The teichuronic acid operon belongs to the Pho regulon, as phosphate limitation induces its transcription. Placing the tuaABCDEFGH operon under the control of the inducible Pspac promoter allowed its constitutive expression independently of the phosphate concentration in the medium; the level of uronic acid in cell walls was dependent on the concentration of the inducer. Apparently, owing to an interdependence between teichoic and teichuronic acid incorporation into the cell wall, in examined growth conditions, the balance between the two polymers is maintained in order to insure a constant level of the wall negative charge.

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.

A novel resistance mechanism against beta-lactams in Streptococcus pneumoniae involves CpoA, a putative glycosyltransferase

Piperacillin resistance in Streptococcus pneumoniae was mediated by mutations in a novel gene, cpoA, that also confer transformation deficiency and a decrease in penicillin-binding protein la. cpoA is part of an operon located downstream of the primary sigma factor of S. pneumoniae. The deduced protein, CpoA, and the peptide encoded by the adjacent 3' open reading frame contained domains homologous to glycosyltransferases of procaryotes and eucaryotes that act on membrane-associated substrates, such as enzymes functioning in lipopolysaccharide core biosynthesis of gram-negative bacteria, RodD of Bacillus subtilis, which is involved in teichoic acid biosynthesis, and the human PIG-A protein, which is required for early steps of glycosylphosphatidylinositol anchor biosynthesis. This suggests that the cpo operon has a similar function related to cell surface components.

The divIVA minicell locus of Bacillus subtilis

The Bacillus subtilis divIVA1 mutation causes misplacement of the septum during cell division, resulting in the formation of small, circular, anucleate minicells. This study reports the cloning and sequence analysis of 2.4 kb of the B. subtilis chromosome including the divIVA locus. Three open reading frames were identified: orf, whose function is unknown; divIVA; and isoleucyl tRNA synthetase (ileS). We identified the point mutation in the divIVA1 mutant allele. Inactivation of divIVA produces a minicell phenotype, whereas overproduction of DivIVA results in a filamentation phenotype. Mutants with mutations at both of the minicell loci of B. subtilis, divIVA and divIVB, possess a minicell phenotype identical to that of the DivIVB- mutant. The DivIVA-mutants, but not the DivIVB- mutants, show a decrease in sporulation efficiency and a delay in the kinetics of endospore formation. The data support a model in which divIVA encodes the topological specificity subunit of the minCD system. The model suggests that DivIVA acts as a pilot protein, directing minCD to the polar septation sites. DivIVA also appears to be the interface between a sporulation component and MinCD, freeing up the polar septation sites for use during the asymmetric septation event of the sporulation process.

Compilation and analysis of Bacillus subtilis sigma A-dependent promoter sequences: evidence for extended contact between RNA polymerase and upstream promoter DNA

Sequence analysis of 236 promoters recognized by the Bacillus subtilis sigma A-RNA polymerase reveals an extended promoter structure. The most highly conserved bases include the -35 and -10 hexanucleotide core elements and a TG dinucleotide at position -15, -14. In addition, several weakly conserved A and T residues are present upstream of the -35 region. Analysis of dinucleotide composition reveals A2- and T2-rich sequences in the upstream promoter region (-36 to -70) which are phased with the DNA helix: An tracts are common near -43, -54 and -65; Tn tracts predominate at the intervening positions. When compared with larger regions of the genome, upstream promoter regions have an excess of An and Tn sequences for n > 4. These data indicate that an RNA polymerase binding site affects DNA sequence as far upstream as -70. This sequence conservation is discussed in light of recent evidence that the alpha subunits of the polymerase core bind DNA and that the promoter may wrap around RNA polymerase.

The tagGH operon of Bacillus subtilis 168 encodes a two-component ABC transporter involved in the metabolism of two wall teichoic acids

We report the nucleotide sequence and the characterization of the Bacillus subtilis tagGH operon. The latter is controlled by a sigma A-dependent promoter and situated in the 308 degrees chromosomal region which contains genes involved in teichoic acid biosynthesis. TagG is a hydrophobic 32.2 kDa protein which resembles integral membrane proteins belonging to polymer-export systems of Gram-negative bacteria. Gene tagH encodes a 59.9 kDa protein whose N-moiety contains the ATP-binding motif and shares extensive homology with a number of ATP-binding proteins, particularly with those associated with the transport of capsular polysaccharides and O-antigens. That the tagGH operon is essential for cell growth was established by the failure to inactivate tagG and the 5'-moiety of tagH by insertional mutagenesis. During limited tagGH expression, cells exhibited a cocoid morphology while their walls contained reduced amounts of phosphate as well as galactosamine. These observations, revealing impaired metabolism of both wall teichoic acids of B. subtilis 168, i.e. poly(glycerol phosphate), and poly(glucose galactosamine phosphate), combined with sequence homologies, suggest that TagG and TagH are involved in the translocation through the cytoplasmic membrane of the latter teichoic acids or their precursors.

Bacillus subtilis possesses a second determinant with extensive sequence similarity to the Escherichia coli mreB morphogene

A gene with substantial sequence similarity to the mreB morphogene of Bacillus subtilis has been identified at 302 degrees on the chromosomal map by A. Decatur, B. Kunkel, and R. Losick (Harvard University; personal communication). Our characterization has revealed that the protein product of this determinant (termed mbl for mreB-like) is 55 and 53% identical in sequence to the MreB proteins of B. subtilis and Escherichia coli, respectively. The protein is 86% identical to a protein identified as MreB from Bacillus cereus, suggesting that the B. cereus protein is actually Mbl. Insertional inactivation of mbl indicated that this gene is not essential for cell viability or sporulation. Cells bearing mutant mbl alleles display a decreased growth rate and an altered cellular morphology. The cells appear bloated and are frequently twisted. Intergenic suppressor mutations which restore the growth rate to an approximately normal level arise within the mutant population. A second site mutation, designated som-1, was mapped to the hisA-mbl region of the chromosome by transduction.

Changes in wall teichoic acid during the rod-sphere transition of Bacillus subtilis 168

Wall teichoic acid (WTA) is essential for the growth of Bacillus subtilis 168. To clarify the function of this polymer, the WTAs of strains 168, 104 rodB1, and 113 tagF1 (rodC1) grown at 32 and 42 degrees C were characterized. At the restrictive temperature, the rodB1 and tagF1 (rodC1) mutants undergo a rod-to-sphere transition that is correlated with changes in the WTA content of the cell wall. The amount of WTA decreased 33% in strain 104 rodB1 and 84% in strain 113 tagF1 (rodC1) when they were grown at the restrictive temperature. The extent of alpha-D-glucosylation (0.84) was not affected by growth at the higher temperature in these strains. The degree of D-alanylation decreased from 0.22 to 0.10 in the rodB1 mutant but remained constant (0.12) in the tagF1 (rodC1) mutant at both temperatures. Under these conditions, the degree of D-alanylation in the parent strain decreased from 0.27 to 0.21. The chain lengths of WTA in strains 168 and 104 rodB1 grown at both temperatures were approximately 53 residues, with a range of 45 to 60. In contrast, although the chain length of WTA from the tagF1 (rodC1) mutant at 32 degrees C was similar to that of strains 168 and 104 rodB1, it was approximately eight residues at the restrictive temperature. The results suggested that the rodB1 mutant is partially deficient in completed poly(glycerophosphate) chains. The precise biochemical defect in this mutant remains to be determined. The results for strain 113 tagF1(rodC1) are consistent with the temperature-sensitive defect in the CDP-glycerol:poly(glycerophosphate) glycerophosphotransferase (H. M. Pooley, F.-X. Abellan, and D. Karamata, J. Bacteriol. 174:646-649, 1992).

DNA sequence of a gene in Escherichia coli encoding a putative tripartite transcription factor with receiver, ATPase and DNA binding domains

We have sequenced downstream of the last previously sequenced gene of the glucitol operon (gutABDMRQ) in E. coli and have found that gutQ is the last gene of this operon. Downstream of the gutQ gene is found a palindromic unit (PU or REP sequence), followed by a large open reading frame of 1515 (or possibly 1590) bps transcribed in the direction opposite to that of the gut operon. This open reading frame encodes a protein of 504 (or possibly 529) amino acids with a tripartite structure. The N-terminal "receiver" domain of 187 (or possibly 212) residues is homologous to the FhlA protein of E. coli, a transcriptional activator of formate hydrogen lyase. It may possess a short domain at its extreme N-terminus exhibiting sequence similarity to carbohydrate binding proteins. The central ATPase domain (236 residues) exhibits greatest sequence similarity to the HydG protein of E. coli, a transcriptional activator of labile hydrogenase. The C-terminal DNA binding domain (81 residues) is homologous to NtrX of Azorhizobium caulinodans, a protein involved in transcriptional regulation of nitrogen fixation. Sequence comparisons with well-characterized transcription factors suggest that ORF504 encodes a protein that hydrolyzes ATP to generate the open transcriptional initiation complex of sigma 54-dependent promoters, possibly in response to redox conditions and/or ligand binding. We propose that this tripartite transcription factor arose by fusion of gene fragments encoding its three constituent modules.

Amplification of the Bacillus subtilis maf gene results in arrested septum formation

The Bacillus subtilis homolog of the Escherichia coli morphogene orfE (of the mre operon) has been identified. The determinant is located on the chromosome immediately upstream of the mreBCD-minCD (divIVB) operon. The Maf protein shares substantial amino acid sequence identity with the E. coli OrfE protein. Introduction of the B. subtilis maf determinant on a multicopy plasmid into B. subtilis cells results in an inhibition of septation, which leads to extensive filamentation and loss of viability in the transformed cell population. Insertional inactivation of maf indicated that this gene is not essential for cell division.

The divIVB region of the Bacillus subtilis chromosome encodes homologs of Escherichia coli septum placement (minCD) and cell shape (mreBCD) determinants

Mutation of the divIVB locus in Bacillus subtilis causes frequent misplacement of the division septum, resulting in circular minicells, short rods, and filaments of various sizes. The divIVB1 mutant allele maps to a region of the chromosome also known to encode sporulation (spo0B, spoIVF, spoIIB) and cell shape (rodB) determinants. This study reports the cloning and sequence analysis of 4.4 kb of the B. subtilis chromosome encompassing the divIVB locus. This region contains five open reading frames (ORFs) arranged in two functionally distinct gene clusters (mre and min) and transcribed colinearly with the direction of replication. Although sequence analysis reveals potential promoters preceding each gene cluster, studies with integrational plasmids suggest that all five ORFs are part of a single transcription unit. The first gene cluster contains three ORFs (mreBCD) homologous to the mre genes of Escherichia coli. We show that rodB1 is allelic to mreD and identify the rodB1 mutation. The second gene cluster contains two ORFs (minCD) homologous to minC and minD of E. coli but lacks a minE homolog. We show that divIVB1 is allelic to minD and identify two mutations in the divIVB1 allele. Insertional inactivation of either minC or minD or the presence of the divIVB region on plasmids produces a severe minicell phenotype in wild-type cells. Moreover, E. coli cells carrying the divIVB region on a low-copy-number plasmid produce minicells, suggesting that a product of this locus may retain some function across species boundaries.

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.

Role and expression of the Bacillus subtilis rodC operon

The role of the rodC operon in Bacillus subtilis was investigated. The operon encodes two genes (rodD and rodC) necessary for the synthesis of the cell wall teichoic acid. Transcription of this operon is responsive to levels of phosphate and to concentrations of magnesium ions in the growth medium. This regulation of mRNA production corresponds to conditions that dictate the type of polymer that will be synthesized for the cell wall, i.e., teichoic or teichuronic acid. While the introduction of multiple copies of rodC was tolerated by the cells, multiple copies of rodD appeared to be lethal. The lethality of the rodD fragment was not exhibited if multiple copies of rodC were also present.