Role of PBP1 in cell division of Staphylococcus aureus.

We constructed a conditional mutant of pbpA in which transcription of the gene was placed under the control of an IPTG (isopropyl-beta-D-thiogalactopyranoside)-inducible promoter in order to explore the role of PBP1 in growth, cell wall structure, and cell division. A methicillin-resistant strain and an isogenic methicillin-susceptible strain, each carrying the pbpA mutation, were unable to grow in the absence of the inducer. Conditional mutants of pbpA transferred into IPTG-free medium underwent a four- to fivefold increase in cell mass, which was not accompanied by a proportional increase in viable titer. Examination of thin sections of such cells by transmission electron microscopy or fluorescence microscopy of intact cells with Nile red-stained membranes showed a morphologically heterogeneous population of bacteria with abnormally increased sizes, distorted axial ratios, and a deficit in the number of cells with completed septa. Immunofluorescence with an antibody specific for PBP1 localized the protein to sites of cell division. No alteration in the composition of peptidoglycan was detectable in pbpA conditional mutants grown in the presence of a suboptimal concentration of IPTG, which severely restricted the rate of growth, and the essential function of PBP1 could not be replaced by PBP2A present in methicillin-resistant cells. These observations suggest that PBP1 is not a major contributor to the cross-linking of peptidoglycan and that its essential function must be intimately integrated into the mechanism of cell division.

Requirement for the cell division protein DivIB in polar cell division and engulfment during sporulation in Bacillus subtilis.

During spore formation in Bacillus subtilis, cell division occurs at the cell pole and is believed to require essentially the same division machinery as vegetative division. Intriguingly, although the cell division protein DivIB is not required for vegetative division at low temperatures, it is essential for efficient sporulation under these conditions. We show here that at low temperatures in the absence of DivIB, formation of the polar septum during sporulation is delayed and less efficient. Furthermore, the polar septa that are complete are abnormally thick, containing more peptidoglycan than a normal polar septum. These results show that DivIB is specifically required for the efficient and correct formation of a polar septum. This suggests that DivIB is required for the modification of sporulation septal peptidoglycan, raising the possibility that DivIB either regulates hydrolysis of polar septal peptidoglycan or is a hydrolase itself. We also show that, despite the significant number of completed polar septa that form in this mutant, it is unable to undergo engulfment. Instead, hydrolysis of the peptidoglycan within the polar septum, which occurs during the early stages of engulfment, is incomplete, producing a similar phenotype to that of mutants defective in the production of sporulation-specific septal peptidoglycan hydrolases. We propose a role for DivIB in sporulation-specific peptidoglycan remodelling or its regulation during polar septation and engulfment.

Forespore-specific transcription of the lonB gene during sporulation in Bacillus subtilis.

The Bacillus subtilis genome encodes two members of the Lon family of prokaryotic ATP-dependent proteases. One, LonA, is produced in response to temperature, osmotic, and oxidative stress and has also been implicated in preventing sigma(G) activity under nonsporulation conditions. The second is encoded by the lonB gene, which resides immediately upstream from lonA. Here we report that transcription of lonB occurs during sporulation under sigma(F) control and thus is restricted to the prespore compartment of sporulating cells. First, expression of a lonB-lacZ transcriptional fusion was abolished in strains unable to produce sigma(F) but remained unaffected upon disruption of the genes encoding the early and late mother cell regulators sigma(E) and sigma(K) or the late forespore regulator sigma(G). Second, the fluorescence of strains harboring a lonB-gfp fusion was confined to the prespore compartment and depended on sigma(F) production. Last, primer extension analysis of the lonB transcript revealed -10 and -35 sequences resembling the consensus sequence recognized by sigma(F)-containing RNA polymerase. We further show that the lonB message accumulated as a single monocistronic transcript during sporulation, synthesis of which required sigma(F) activity. Disruption of the lonB gene did not confer any discernible sporulation phenotype to otherwise wild-type cells, nor did expression of lonB from a multicopy plasmid. In contrast, expression of a fusion of the lonB promoter to the lonA gene severely reduced expression of the sigma(G)-dependent sspE gene and the frequency of sporulation. In confirmation of earlier observations, we found elevated levels of sigma(F)-dependent activity in a spoIIIE47 mutant, in which the lonB region of the chromosome is not translocated into the prespore. Expression of either lonB or the P(lonB)-lonA fusion from a plasmid in the spoIIIE47 mutant reduced sigma(F) -dependent activity to wild-type levels. The results suggest that both LonA and LonB can prevent abnormally high sigma(F) activity but that only LonA can negatively regulate sigma(G).

SpoVID guides SafA to the spore coat in Bacillus subtilis.

Bacteria assemble complex structures by targeting proteins to specific subcellular locations. The protein coat that encases Bacillus subtilis spores is an example of a structure that requires coordinated targeting and assembly of more than 24 polypeptides. The earliest stages of coat assembly require the action of three morphogenetic proteins: SpoIVA, CotE, and SpoVID. In the first steps, a basement layer of SpoIVA forms around the surface of the forespore, guiding the subsequent positioning of a ring of CotE protein about 75 nm from the forespore surface. SpoVID localizes near the forespore membrane where it functions to maintain the integrity of the CotE ring and to anchor the nascent coat to the underlying spore structures. However, it is not known which spore coat proteins interact directly with SpoVID. In this study we examined the interaction between SpoVID and another spore coat protein, SafA, in vivo using the yeast two-hybrid system and in vitro. We found evidence that SpoVID and SafA directly interact and that SafA interacts with itself. Immunofluorescence microscopy showed that SafA localized around the forespore early during coat assembly and that this localization of SafA was dependent on SpoVID. Moreover, targeting of SafA to the forespore was also dependent on SpoIVA, as was targeting of SpoVID to the forespore. We suggest that the localization of SafA to the spore coat requires direct interaction with SpoVID.

Alternative translation initiation produces a short form of a spore coat protein in Bacillus subtilis.

During endospore formation in Bacillus subtilis, over two dozen polypeptides are localized to the developing spore and coordinately assembled into a thick multilayered structure called the spore coat. Assembly of the coat is initiated by the expression of morphogenetic proteins SpoIVA, CotE, and SpoVID. These morphogenetic proteins appear to guide the assembly of other proteins into the spore coat. For example, SpoVID forms a complex with the SafA protein, which is incorporated into the coat during the early stages of development. At least two forms of SafA are found in the mature spore coat: a full-length form and a shorter form (SafA-C(30)) that begins with a methionine encoded by codon 164 of safA. In this study, we present evidence that the expression of SafA-C(30) arises from translation initiation at codon 164. We found only a single transcript driving expression of SafA. A stop codon engineered just upstream of a predicted ribosome-binding site near codon M164 abolished formation of full-length SafA, but not SafA-C(30). The same effect was observed with an alanine substitution at codon 1 of SafA. Accumulation of SafA-C(30) was blocked by substitution of an alanine codon at codon 164, but not by a substitution at a nearby methionine at codon 161. We found that overproduction of SafA-C(30) interfered with the activation of late mother cell-specific transcription and caused a strong sporulation block.

Morphogenetic proteins SpoVID and SafA form a complex during assembly of the Bacillus subtilis spore coat.

During endospore formation in Bacillus subtilis, over two dozen polypeptides are assembled into a multilayered structure known as the spore coat, which protects the cortex peptidoglycan (PG) and permits efficient germination. In the initial stages of coat assembly a protein known as CotE forms a ring around the forespore. A second morphogenetic protein, SpoVID, is required for maintenance of the CotE ring during the later stages, when most of proteins are assembled into the coat. Here, we report on a protein that appears to associate with SpoVID during the early stage of coat assembly. This protein, which we call SafA for SpoVID-associated factor A, is encoded by a locus previously known as yrbA. We confirmed the results of a previous study that showed safA mutant spores have defective coats which are missing several proteins. We have extended these studies with the finding that SafA and SpoVID were coimmunoprecipitated by anti-SafA or anti-SpoVID antiserum from whole-cell extracts 3 and 4 h after the onset of sporulation. Therefore, SafA may associate with SpoVID during the early stage of coat assembly. We used immunogold electron microscopy to localize SafA and found it in the cortex, near the interface with the coat in mature spores. SafA appears to have a modular design. The C-terminal region of SafA is similar to those of several inner spore coat proteins. The N-terminal region contains a sequence that is conserved among proteins that associate with the cell wall. This motif in the N-terminal region may target SafA to the PG-containing regions of the developing spore.

Structure and assembly of the bacterial endospore coat.

Many biological processes are mediated through the action of multiprotein complexes, often assembled at specific cellular locations. Bacterial endospores for example, are encased in a proteinaceous coat, which confers resistance to lysozyme and harsh chemicals and influences the spore response to germinants. In Bacillus subtilis, the coat is composed of more than 20 polypeptides, organized into three main layers: an amorphous undercoat; a lamellar, lightly staining inner structure; and closely apposed to it, a striated electron-dense outer coat. Synthesis of the coat proteins is temporally and spatially governed by a cascade of four mother cell-specific transcription factors. However, the order of assembly and final destination of the coat structural components may rely mainly on specific protein-protein interactions, as well as on the action of accessory morphogenetic proteins. Proteolytic events, protein-protein crosslinking, and protein glycosylation also play a role in the assembly process. These modifications are carried out by enzymes that may themselves be targeted to the coat layers. Coat genes have been identified by reverse genetics or, more recently, by screens for mother cell-specific promoters or for peptide sequences able to interact with certain bait proteins. A role for a given locus in coat assembly is established by a combination of regulatory, functional, morphological, and topological criteria. Because of the amenability of B. subtilis to genetic analysis (now facilitated by the knowledge of its genome sequence), coat formation has become an attractive model for the assembly of complex macromolecular structures during development.

A Bacillus subtilis secreted protein with a role in endospore coat assembly and function.

Bacterial endospores are encased in a complex protein coat, which confers protection against noxious chemicals and influences the germination response. In Bacillus subtilis, over 20 polypeptides are organized into an amorphous undercoat, a lamellar lightly staining inner structure, and an electron-dense outer coat. Here we report on the identification of a polypeptide of about 30 kDa required for proper coat assembly, which was extracted from spores of a gerE mutant. The N-terminal sequence of this polypeptide matched the deduced product of the tasA gene, after removal of a putative 27-residue signal peptide, and TasA was immunologically detected in material extracted from purified spores. Remarkably, deletion of tasA results in the production of asymmetric spores that accumulate misassembled material in one pole and have a greatly expanded undercoat and an altered outer coat structure. Moreover, we found that tasA and gerE mutations act synergistically to decrease the efficiency of spore germination. We show that tasA is the most distal member of a three-gene operon, which also encodes the type I signal peptidase SipW. Expression of the tasA operon is enhanced 2 h after the onset of sporulation, under the control of sigmaH. When tasA transcription is uncoupled from sipW expression, a presumptive TasA precursor accumulates, suggesting that its maturation depends on SipW. Mature TasA is found in supernatants of sporulating cultures and intracellularly from 2 h of sporulation onward. We suggest that, at an early stage of sporulation, TasA is secreted to the septal compartment. Later, after engulfment of the prespore by the mother cell, TasA acts from the septal-proximal pole of the spore membranes to nucleate the organization of the undercoat region. TasA is the first example of a polypeptide involved in coat assembly whose production is not mother cell specific but rather precedes its formation. Our results implicate secretion as a mechanism to target individual proteins to specific cellular locations during the assembly of the bacterial endospore coat.

Assembly requirements and role of CotH during spore coat formation in Bacillus subtilis.

We report Western blot data showing that the 42.8-kDa product of the previously characterized cotH locus (8) is a structural component of the Bacillus subtilis spore coat. We show that the assembly of CotH requires both CotE and GerE. In agreement with these observations, the ultrastructural analysis of purified spores suggests that CotH is needed for proper formation of both inner and outer layers of the coat.

Control of cell shape and elongation by the rodA gene in Bacillus subtilis.

The Escherichia coli rodA and ftsW genes and the spoVE gene of Bacillus subtilis encode membrane proteins that control peptidoglycan synthesis during cellular elongation, division and sporulation respectively. While rodA and ftsW are essential genes in E. coli, the B. subtilis spoVE gene is dispensable for growth and is only required for the synthesis of the spore cortex peptidoglycan. In this work, we report on the characterization of a B. subtilis gene, designated rodA, encoding a homologue of E. coli RodA. We found that the growth of a B. subtilis strain carrying a fusion of rodA to the IPTG-inducible Pspac promoter is inducer dependent. Limiting concentrations of inducer caused the formation of spherical cells, which eventually lysed. An increase in the level of IPTG induced a sphere-to-short rod transition that re-established viability. Higher levels of inducer restored normal cell length. Staining of the septal or polar cap peptidoglycan by a fluorescent lectin was unaffected during growth of the mutant under restrictive conditions. Our results suggest that rodA functions in maintaining the rod shape of the cell and that this function is essential for viability. In addition, RodA has an irreplaceable role in the extension of the lateral walls of the cell. Electron microscopy observations support these conclusions. The ultrastructural analysis further suggests that the growth arrest that accompanies loss of the rod shape is caused by the cell's inability to construct a division septum capable of spanning the enlarged cell. RodA is similar over its entire length to members of a large protein family (SEDS, for shape, elongation, division and sporulation). Members of the SEDS family are probably present in all eubacteria that synthesize peptidoglycan as part of their cell envelope.

Involvement of superoxide dismutase in spore coat assembly in Bacillus subtilis.

Endospores of Bacillus subtilis are enclosed in a proteinaceous coat which can be differentiated into a thick, striated outer layer and a thinner, lamellar inner layer. We found that the N-terminal sequence of a 25-kDa protein present in a preparation of spore coat proteins matched that of the Mn-dependent superoxide dismutase (SOD) encoded by the sod4 locus. sod4 is transcribed throughout the growth and sporulation of a wild-type strain and is responsible for the SOD activity detected in total cell extracts prepared from B. subtilis. Disruption of the sod4 locus produced a mutant that lacked any detectable SOD activity during vegetative growth and sporulation. The sodA mutant was not impaired in the ability to form heat- or lysozyme-resistant spores. However, examination of the coat layers of sodA mutant spores revealed increased extractability of the tyrosine-rich outer coat protein CotG. We showed that this condition was not accompanied by augmented transcription of the cotG gene in sporulating cells of the sodA mutant. We conclude that SodA is required for the assembly of CotG into the insoluble matrix of the spore and suggest that CotG is covalently cross-linked into the insoluble matrix by an oxidative reaction dependent on SodA. Ultrastructural analysis revealed that the inner coat formed by a sodA mutant was incomplete. Moreover, the outer coat lacked the characteristic striated appearance of wild-type spores, a pattern that was accentuated in a cotG mutant. These observations suggest that the SodA-dependent formation of the insoluble matrix containing CotG is largely responsible for the striated appearance of this coat layer.

Assembly and interactions of cotJ-encoded proteins, constituents of the inner layers of the Bacillus subtilis spore coat.

During Bacillus subtilis endospore formation, a complex protein coat is assembled around the maturing spore. The coat is made up of more than two dozen proteins that form an outer layer, which provides chemical resistance, and an inner layer, which may play a role in the activation of germination. A third, amorphous layer of the coat occupies the space between the inner coat and the cortex, and is referred to as the undercoat. Although several coat proteins have been characterized, little is known about their interactions during assembly of the coat. We show here that at least two open reading frames of the cotJ operon (cotJA and cotJC) encode spore coat proteins. We suggest that CotJC is a component of the undercoat, since we found that its assembly onto the forespore is not prevented by mutations that block both inner and outer coat assembly, and because CotJC is more accessible to antibody staining in spores lacking both of these coat layers. Assembly of CotJC into the coat is dependent upon expression of cotJA. Conversely, CotJA is not detected in the coats of a cotJC insertional mutant. Co-immunoprecipitation was used to demonstrate the formation of complexes containing CotJA and CotJC 6 h after the onset of sporulation. Experiments with the yeast two-hybrid system indicate that CotJC may interact with itself and with CotJA. We suggest that interaction of CotJA with CotJC is required for the assembly of both CotJA and CotJC into the spore coat.

CotM of Bacillus subtilis, a member of the alpha-crystallin family of stress proteins, is induced during development and participates in spore outer coat formation.

We cloned and characterized a gene, cotM, that resides in the 173 degrees region of the Bacillus subtilis chromosome and is involved in spore outer coat assembly. We found that expression of the cotM gene is induced during development under sigma K control and is negatively regulated by the GerE transcription factor. Disruption of the cotM gene resulted in spores with an abnormal pattern of coat proteins. Electron microscopy revealed that the outer coat in cotM mutant spores had lost its multilayered type of organization, presenting a diffuse appearance. In particular, significant amounts of material were absent from the outer coat layers, which in some areas had a lamellar structure more typical of the inner coat. Occasionally, a pattern of closely spaced ridges protruding from its surface was observed. No deficiency associated with the inner coat or any other spore structure was found. CotM is related to the alpha-crystallin family of low-molecular-weight heat shock proteins, members of which can be substrates for transglutaminase-mediated protein cross-linking. CotM was not detected among the extractable spore coat proteins. These observations are consistent with a model according to which CotM is part of a cross-linked insoluble skeleton that surrounds the spore, serves as a matrix for the assembly of additional outer coat material, and confers structural stability to the final structure.

cse15, cse60, and csk22 are new members of mother-cell-specific sporulation regulons in Bacillus subtilis.

We report on the characterization of three new transcription units expressed during sporulation in Bacillus subtilis. Two of the units, cse15 and cse60, were mapped at about 123 degrees and 62 degrees on the genetic map, respectively. Their transcription commenced around h 2 of sporulation and showed an absolute requirement for sigmaE. Maximal expression of both cse15 and cse60 further depended on the DNA-binding protein SpoIIID. Primer extension results revealed -10 and -35 sequences upstream of the cse15 and cse60 coding sequences very similar to those utilized by sigmaE-containing RNA polymerase. Alignment of these and other regulatory regions led to a revised consensus sequence for sigmaE-dependent promoters. A third transcriptional unit, designated csk22, was localized at approximately 173 degrees on the chromosome. Transcription of csk22 was activated at h 4 of sporulation, required the late mother-cell regulator sigmaK, and was repressed by the GerE protein. Sequences in the csk22 promoter region were similar to those of other sigmaK-dependent promoters. The cse60 locus was deduced to encode an acidic product of only 60 residues. A 37.6-kDa protein apparently encoded by cse15 was weakly related to the heavy chain of myosins, as well as to other myosin-like proteins, and is predicted to contain a central, 100 residue-long coiled-coil domain. Finally, csk22 is inferred to encode a 18.2-kDa hydrophobic product with five possible membrane-spanning helices, which could function as a transporter.

Characterization of cotJ, a sigma E-controlled operon affecting the polypeptide composition of the coat of Bacillus subtilis spores.

The outermost protective structure found in endospores of Bacillus subtilis is a thick protein shell known as the coat, which makes a key contribution to the resistance properties of the mature spore and also plays a role in its interaction with compounds able to trigger germination. The coat is organized as a lamellar inner layer and an electron-dense outer layer and has a complex polypeptide composition. Here we report the cloning and characterization of an operon, cotJ, located at about 62 degrees on the B. subtilis genetic map, whose inactivation results in the production of spores with an altered pattern of coat polypeptides. The cotJ operon was identified by screening a random library of lacZ transcriptional fusions for a conditional (inducer-dependent) Lac+ phenotype in cells of a strain in which the structural gene (spoIIGB) for the early-acting, mother-cell-specific transcriptional factor sigma E was placed under the control of the IPTG (isopropyl-beta-D-thiogalactopyranoside)-inducible Pspac promoter. Sequence analysis of cloned DNA from the cotJ region complemented by genetic experiments revealed a tricistronic operon preceded by a strong sigma E-like promoter. Expression of an SP beta-borne cotJ-lacZ fusion commences at around h 2 of sporulation, as does expression of other sigma E-dependent genes, and shows an absolute requirement for sigma E. Studies with double-reporter strains bearing a cotJ-gusA fusion and lacZ fusions to other cot genes confirmed that expression of cotJ is initiated during sporulation prior to activation of genes known to encode coat structural proteins (with the sole exception of cotE). An in vitro-constructed insertion-deletion mutation in cotJ resulted in the formation of spores with no detectable morphological or resistance deficiency. However, examination of the profile of electrophoretically separated spore coat proteins from the null mutant revealed a pattern that was essentially identical to that of a wild-type strain in the range of 12 to 65 kDa, except for polypeptides of 17 and 24 kDa, the putative products of the second (cotJB) and third (cotJC) cistrons of the operon, that were missing or reduced in amount in the coat of the mutant. Polypeptides of the same apparent sizes are detected in spores of a cotE null mutant, on which basis we infer that the products of the cotJ operon are required for the normal formation of the inner layers of the coat or are themselves structural components of the coat. Because the onset of cotJ transcription is temporally coincident with the appearance of active sigma E, we speculate that the cotJ-encoded products may be involved in an early state of coat assembly.

A Bacillus subtilis morphogene cluster that includes spoVE is homologous to the mra region of Escherichia coli.

It is known that there is a strong similarity in amino acid sequence between the products of the Escherichia coli morphogenes ftsW (mra region at 2 min) and rodA (mrd region at 14 min) and the Bacillus subtilis SpoVE protein which is required for spore cortex formation. We show here that the predicted amino acid sequences coded for by the genes flanking spoVE are homologous to the products of the E coli genes murD and murG, which flank ftsW, and are involved in peptidoglycan biosynthesis. During vegetative growth and early stationary phase spoVE is cotranscribed with murD and murG in the form of very long polycistronic messages originating upstream of murD. However, this transcriptional activity is shut-off soon (approximately 1 h) after the cells enter stationary phase, and spoVE is then transcribed at two times during sporulation from its own promoter(s). Insertional in vitro mutagenesis of the region revealed that although murD and murG are essential for normal vegetative growth, spoVE is only required for sporulation: spoVE null mutants display a sporulation stage V phenotype indistinguishable by light microscopy from the phenotype conferred by the spoVE85 and spoVE153 alleles that originally defined the locus.