Surface-layer (S-layer) proteins sap and EA1 govern the binding of the S-layer-associated protein BslO at the cell septa of Bacillus anthracis

The Gram-positive pathogen Bacillus anthracis contains 24 genes whose products harbor the structurally conserved surface-layer (S-layer) homology (SLH) domain. Proteins endowed with the SLH domain associate with the secondary cell wall polysaccharide (SCWP) following secretion. Two such proteins, Sap and EA1, have the unique ability to self-assemble into a paracrystalline layer on the surface of bacilli and form S layers. Other SLH domain proteins can also be found within the S layer and have been designated Bacillus S-layer-associated protein (BSLs). While both S-layer proteins and BSLs bind the same SCWP, their deposition on the cell surface is not random. For example, BslO is targeted to septal peptidoglycan zones, where it catalyzes the separation of daughter cells. Here we show that an insertional lesion in the sap structural gene results in elongated chains of bacilli, as observed with a bslO mutant. The chain length of the sap mutant can be reduced by the addition of purified BslO in the culture medium. This complementation in trans can be explained by an increased deposition of BslO onto the surface of sap mutant bacilli that extends beyond chain septa. Using fluorescence microscopy, we observed that the Sap S layer does not overlap the EA1 S layer and slowly yields to the EA1 S layer in a growth-phase-dependent manner. Although present all over bacilli, Sap S-layer patches are not observed at septa. Thus, we propose that the dynamic Sap/EA1 S-layer coverage of the envelope restricts the deposition of BslO to the SCWP at septal rings.     

Bacillus anthracis surface: capsule and S-layer

Two abundant surface proteins, EA1 and Sap, are components of the Bacillus anthracis surface layer (S-layer). Their corresponding genes have been cloned, shown to be clustered on the chromosome and sequenced. EA1 and Sap each possess three 'S-layer homology' motifs. Single and double disrupted mutants were constructed. EA1 and Sap were co-localized at the cell surface of both the non-capsulated and capsulated bacilli. When present, the capsule is exterior to, and completely covers, the S-layer proteins, which form an array beneath it. Nevertheless, the presence of these proteins is not required for normal capsulation of the bacilli. Thus both structures are compatible, and yet neither is required for the correct formation of the other. Bacillus anthracis has, therefore, a very complex cell wall organization for a gram-positive bacterium.     

Distinct affinity of binding sites for S-layer homologous domains in Clostridium thermocellum and Bacillus anthracis cell envelopes

Binding parameters were determined for the SLH (S-layer homologous) domains from the Clostridium thermocellum outer layer protein OlpB, from the C. thermocellum S-layer protein SlpA, and from the Bacillus anthracis S-layer proteins EA1 and Sap, using cell walls from C. thermocellum and B. anthracis. Each SLH domain bound to C. thermocellum and B. anthracis cell walls with a different KD, ranging between 7.1 x 10(-7) and 1.8 x 10(-8) M. Cell wall binding sites for SLH domains displayed different binding specificities in C. thermocellum and B. anthracis. SLH-binding sites were not detected in cell walls of Bacillus subtilis. Cell walls of C. thermocellum lost their affinity for SLH domains after treatment with 48% hydrofluoric acid but not after treatment with formamide or dilute acid. A soluble component, extracted from C. thermocellum cells by sodium dodecyl sulfate treatment, bound the SLH domains from C. thermocellum but not those from B. anthracis proteins. A corresponding component was not found in B. anthracis.     

Role of the components of the S-layer in immunogenicity of Bacillus anthracis

The immunogenicity of proteins Sap and EA1, contained in B. anthracis S-layer, was evaluated in experiments on laboratory animals. These proteins were found to produce protective effect and could be regarded as additional immunogenic factors. The use of the newly constructed isogenic pair Sap+ and Sap- of B. anthracis strains made it possible to study the influence of Sap- mutation on the immunological properties of the causative agent of anthrax.     

Identification of a second Listeria secA gene associated with protein secretion and the rough phenotype

We describe the identification and characterization of a second secA gene in Listeria monocytogenes. This gene, termed secA2, is involved in smooth-rough phenotypic variation and secA2 expression contributes to bacterial virulence. Spontaneous rough (R-) variants of L. monocytogenes grow in chains and form rough colonies on solid media. A subset of R-variants, classified here as type I, also shows reduced secretion of an autolysin, p60. We find that disruptions and in frame deletions in secA2 confer phenotypes identical to those of spontaneous type I R-variants. Additionally, the secA2 genes from two spontaneous type I R-variants encoded truncated SecA2 proteins. Mutations were not found in the secA2 genes from the remaining five independent R-variants, four of which showed a distinct (type II) rough morphology and secreted wild-type levels of p60. Expression of an epitope-tagged SecA2 in the DeltasecA2 strain and a spontaneous R-variant restored normal cell septation and smooth colony morphology. These data suggest that mutations in both secA2 and other genes contribute to smooth-rough phase variation in L. monocytogenes. Expression of the full-length SecA2 also promotes secretion of p60 and a set of additional L. monocytogenes proteins. We hypothesize that SecA2-dependent protein secretion plays a role in the colonization of environmental and host surfaces.     

Characterisation of the immune response to the UK human anthrax vaccine

The UK human anthrax vaccine consists of the alum-precipitated culture supernatant of Bacillus anthracis Sterne. In addition to protective antigen (PA), the key immunogen, the vaccine also contains a number of other bacteria- and media-derived proteins. These proteins may contribute to the transient side effects experienced by some individuals and could influence the development of the PA-specific immune response. Bacterial cell-wall components have been shown to be potent immunomodulators. B. anthracis expresses two S-layer proteins, EA1 and Sap, which have been demonstrated to be immunogenic in animal studies. These are also immunogenic in man so that convalescent and post-immunisation sera contain specific antibodies to Ea1, and to a lesser extent, to Sap. To determine if these proteins are capable of modifying the protective immune response to PA, A/J mice were immunised with equivalent amounts of recombinant PA and S-layer proteins in the presence of alhydrogel. IgG isotype profiles were determined and the animals were subsequently challenged with spores of B. anthracis STI. The results suggest that there was no significant shift in IgG isotype profile and that the presence of the S-layer proteins did not adversely affect the protective immune response induced by PA.     

SecA2 is distinct from SecA in immunogenic specificity, subcellular distribution and requirement for membrane anchoring in Streptococcus parasanguis

A secA2 gene is present in the genomes of a wide variety of Gram-positive bacteria. In Streptococcus parasanguis, a primary colonizer of the tooth surface, secA2 is involved in the secretion of a small group of proteins including the fimbrial adhesin, Fap1. Although the substrate specificity is different, SecA2 is predicted to be similar to SecA in structure and function based on the homology between these two proteins. In this study, polyclonal antibodies against SecA2 and SecA did not cross-react with each other, indicating that these two proteins possessed distinct immunogenic epitopes. Fractionation analysis demonstrated that SecA2 was not evenly distributed between the cytoplasmic membrane and the cytoplasm as was noted for SecA. SecA2 was associated with the membrane in the wild type and in secA2 mutants with different regions deleted. The subcellular distribution of SecA2 was not dependent on secY2, suggesting that the membrane association is not through SecY2. These data suggested that SecA2 is distinct from SecA in many respects such as substrate specificity, immunogenic specificity, subcellular distribution and requirement for membrane anchoring.     

Molecular characterization of the Bacillus anthracis main S-layer component: evidence that it is the major cell-associated antigen

Bacillus anthracis, the aetiological agent of anthrax, is a Gram-positive spore-forming bacterium. The cell wall of vegetative cells of B. anthracis is surrounded by an S-layer. An array remained when sap, a gene described as encoding an S-layer component, was deleted. The remaining S-layer component, termed EA1, is chromosomally encoded. The gene encoding EA1 (eag) was obtained on two overlapping fragments in Escherichia coli and shown to be contiguous to the sap gene. The EA1 amino acid sequence, deduced from the eag nucleotide sequence, shows classical S-layer protein features (no cysteine, only 0.1% methionine, 10% lysine, and a weakly acidic pi). Similar to Sap and other Gram-positive surface proteins, EA1 has three 'S-layer-homology’motifs immediately downstream from a signal peptide. Single- and double-disrupted mutants were constructed. EA1 and Sap were co-localized at the cell surface of the wild-type bacilli. However, EA1 was more tightly bound than Sap to the bacteria. Electron microscopy studies and in vivo experiments with the constructed mutants showed that EA1 constitutes the main lattice of the B. anthracis S-layer, and is the major cell-associated antigen.     

Caulobacter crescentus synthesizes an S-layer-editing metalloprotease possessing a domain sharing sequence similarity with its paracrystalline S-layer protein

Strains of Caulobacter crescentus elaborate an S-layer, a two-dimensional protein latticework which covers the cell surface. The S-layer protein (RsaA) is secreted by a type I mechanism (relying on a C-terminal signal) and is unusual among type I secreted proteins because high levels of protein are produced continuously. In efforts to adapt the S-layer for display of foreign peptides and proteins, we noted a proteolytic activity that affected S-layer monomers with foreign inserts. The cleavage was precise, resulting in fragments with an unambiguous N-terminal sequence. We developed an assay to screen for loss of this activity (i.e., presentation of foreign peptides without degradation), using transposon and traditional mutagenesis. A metalloprotease gene designated sap (S-layer-associated protease) was identified which could complement the protease-negative mutants. The N-terminal half of Sap possessed significant similarity to other type I secreted proteases (e.g., alkaline protease of Pseudomonas aeruginosa), including the characteristic RTX repeat sequences, but the C-terminal half which normally includes the type I secretion signal exhibited no such similarity. Instead, there was a region of significant similarity to the N-terminal region of RsaA. We hypothesize that Sap evolved by combining the catalytic portion of a type I secreted protease with an S-layer-like protein, perhaps to associate with nascent S-layer monomers to "scan" for modifications.     

SecA2 functions in the secretion of superoxide dismutase A and in the virulence of Mycobacterium tuberculosis

Tuberculosis remains a severe worldwide health threat. A thorough understanding of Mycobacterium tuberculosis pathogenesis will facilitate the development of new treatments for tuberculosis. Numerous bacterial pathogens possess specialized protein secretion systems that are dedicated to the export of virulence factors. Mycobacterium tuberculosis is part of a developing group of pathogenic bacteria that share the uncommon property of possessing two secA genes (secA1 and secA2). In mycobacteria, SecA1 is the essential 'housekeeping' SecA protein whereas SecA2 is an accessory secretion factor. Here we demonstrate that SecA2 contributes to the pathogenesis of M. tuberculosis. A deletion of the secA2 gene in M. tuberculosis attenuates the virulence of the organism in mice. By comparing the profile of proteins secreted by wild-type M. tuberculosis and the DeltasecA2 mutant, we identified superoxide dismutase A (SodA) as a protein dependent on SecA2 for secretion. SodA lacks a classical signal sequence for protein export. Our data suggests that SecA2-dependent export is a new type of secretion pathway that is part of a virulence mechanism of M. tuberculosis to elude the oxidative attack of macrophages.     

Structural analysis and evidence for dynamic emergence of Bacillus anthracis S-layer networks

Surface layers (S-layers), which form the outermost layers of many Bacteria and Archaea, consist of protein molecules arranged in two-dimensional crystalline arrays. Bacillus anthracis, a gram-positive, spore-forming bacterium, responsible for anthrax, synthesizes two abundant surface proteins: Sap and EA1. Regulatory studies showed that EA1 and Sap appear sequentially at the surface of the parental strain. Sap and EA1 can form arrays. The structural parameters of S-layers from mutant strains (EA1(-) and Sap(-)) were determined by computer image processing of electron micrographs of negatively stained regular S-layer fragments or deflated whole bacteria. Sap and EA1 projection maps were calculated on a p1 symmetry basis. The unit cell parameters of EA1 were a = 69 A, b = 83 A, and gamma = 106 degrees, while those of Sap were a = 184 A, b = 81 A, and gamma = 84 degrees. Freeze-etching experiments and the analysis of the peripheral regions of the cell suggested that the two S-layers have different settings. We characterized the settings of each network at different growth phases. Our data indicated that the scattered emergence of EA1 destabilizes the Sap S-layer.     

A prl Mutation in SecY Suppresses Secretion and Virulence Defects of Listeria monocytogenes secA2 Mutants

The bulk of bacterial protein secretion occurs through the conserved SecY translocation channel that is powered by SecA-dependent ATP hydrolysis. Many Gram-positive bacteria, including the human pathogen Listeria monocytogenes, possess an additional nonessential specialized ATPase, SecA2. SecA2-dependent secretion is required for normal cell morphology and virulence in L. monocytogenes; however, the mechanism of export via this pathway is poorly understood. L. monocytogenes secA2 mutants form rough colonies, have septation defects, are impaired for swarming motility, and form small plaques in tissue culture cells. In this study, 70 spontaneous mutants were isolated that restored swarming motility to L. monocytogenes secA2 mutants. Most of the mutants had smooth colony morphology and septated normally, but all were lysozyme sensitive. Five representative mutants were subjected to whole-genome sequencing. Four of the five had mutations in proteins encoded by the lmo2769 operon that conferred lysozyme sensitivity and increased swarming but did not rescue virulence defects. A point mutation in secY was identified that conferred smooth colony morphology to secA2 mutants, restored wild-type plaque formation, and increased virulence in mice. This secY mutation resembled a prl suppressor known to expand the repertoire of proteins secreted through the SecY translocation complex. Accordingly, the ΔsecA2prlA1 mutant showed wild-type secretion levels of P60, an established SecA2-dependent secreted autolysin. Although the prl mutation largely suppressed almost all of the measurable SecA2-dependent traits, the ΔsecA2prlA1 mutant was still less virulent in vivo than the wild-type strain, suggesting that SecA2 function was still required for pathogenesis.     

Regulation of the Escherichia coli secA gene by protein secretion defects: analysis of secA, secB, secD, and secY mutants.

SecA protein synthesis levels were elevated 10- to 20-fold when protein secretion was blocked in secA, secD, and secY mutants or in a malE-lacZ fusion-containing strain but not in a secB null mutant. An active secB gene product was not required to derepress secA, since SecA levels were elevated during protein export blocks in secB secY and secB malE-lacZ double mutants.     

Clostridium difficile has two parallel and essential Sec secretion systems

Protein translocation across the cytoplasmic membrane is an essential process in all bacteria. The Sec system, comprising at its core an ATPase, SecA, and a membrane channel, SecYEG, is responsible for the majority of this protein transport. Recently, a second parallel Sec system has been described in a number of gram-positive species. This accessory Sec system is characterized by the presence of a second copy of the energizing ATPase, SecA2; where it has been studied, SecA2 is responsible for the translocation of a subset of Sec substrates. In common with many pathogenic gram-positive species, Clostridium difficile possesses two copies of SecA. Here, we describe the first characterization of the C. difficile accessory Sec system and the identification of its major substrates. Using inducible antisense RNA expression and dominant-negative alleles of secA1 and secA2, we demonstrate that export of the S-layer proteins (SLPs) and an additional cell wall protein (CwpV) is dependent on SecA2. Accumulation of the cytoplasmic precursor of the SLPs SlpA and other cell wall proteins was observed in cells expressing dominant-negative secA1 or secA2 alleles, concomitant with a decrease in the levels of mature SLPs in the cell wall. Furthermore, expression of either dominant-negative allele or antisense RNA knockdown of SecA1 or SecA2 dramatically impaired growth, indicating that both Sec systems are essential in C. difficile.     

The SLH-domain protein BslO is a determinant of Bacillus anthracis chain length

The Gram-positive pathogen Bacillus anthracis grows in characteristic chains of individual, rod-shaped cells. Here, we report the cell-separating activity of BslO, a putative N-acetylglucosaminidase bearing three N-terminal S-layer homology (SLH) domains for association with the secondary cell wall polysaccharide (SCWP). Mutants with an insertional lesion in the bslO gene exhibit exaggerated chain lengths, although individual cell dimensions are unchanged. Purified BslO complements this phenotype in trans, effectively dispersing chains of bslO-deficient bacilli without lysis and localizing to the septa of vegetative cells. Compared with the extremely long chain lengths of csaB bacilli, which are incapable of binding proteins with SLH-domains to SCWP, bslO mutants demonstrate a chaining phenotype that is intermediate between wild-type and csaB. Computational simulation suggests that BslO effects a non-random distribution of B. anthracis chain lengths, implying that all septa are not equal candidates for separation.     

Two Nonredundant SecA Homologues Function in Mycobacteria

The proper extracytoplasmic localization of proteins is an important aspect of mycobacterial physiology and the pathogenesis of Mycobacterium tuberculosis. The protein export systems of mycobacteria have remained unexplored. The Sec-dependent protein export pathway has been well characterized in Escherichia coli and is responsible for transport across the cytoplasmic membrane of proteins containing signal sequences at their amino termini. SecA is a central component of this pathway, and it is highly conserved throughout bacteria. Here we report on an unusual property of mycobacterial protein export--the presence of two homologues of SecA (SecA1 and SecA2). Using an allelic-exchange strategy in Mycobacterium smegmatis, we demonstrate that secA1 is an essential gene. In contrast, secA2 can be deleted and is the first example of a nonessential secA homologue. The essential nature of secA1, which is consistent with the conserved Sec pathway, leads us to believe that secA1 represents the equivalent of E. coli secA. The results of a phenotypic analysis of a Delta secA2 mutant of M. smegmatis are presented here and also indicate a role for SecA2 in protein export. Based on our study, it appears that SecA2 can assist SecA1 in the export of some proteins via the Sec pathway. However, SecA2 is not the functional equivalent of SecA1. This finding, in combination with the fact that SecA2 is highly conserved throughout mycobacteria, suggests a second role for SecA2. The possibility exists that another role for SecA2 is to export a specific subset of proteins.     

Escherichia coli SecA helicase activity is not required in vivo for efficient protein translocation or autogenous regulation

SecA is an essential ATP-driven motor protein that binds to preproteins and the translocon to promote protein translocation across the eubacterial plasma membrane. Escherichia coli SecA contains seven conserved motifs characteristic of superfamily II of DNA and RNA helicases, and it has been shown previously to possess RNA helicase activity. SecA has also been shown to be an autogenous repressor that binds to its translation initiation region on secM-secA mRNA, thereby blocking and dissociating 30 S ribosomal subunits. Here we show that SecA is an ATP-dependent helicase that unwinds a mimic of the repressor helix of secM-secA mRNA. Mutational analysis of the seven conserved helicase motifs in SecA allowed us to identify mutants that uncouple SecA-dependent protein translocation activity from its helicase activity. Helicase-defective secA mutants displayed normal protein translocation activity and autogenous repression of secA in vivo. Our studies indicate that SecA helicase activity is nonessential and does not appear to be necessary for efficient protein secretion and secA autoregulation.     

Tyr-326 plays a critical role in controlling SecA-preprotein interaction

SecA is an essential ATP-dependent motor protein that interacts with the preprotein and translocon to drive protein translocation across the eubacterial plasma membrane. A region containing residues 267-340 has been proposed to comprise the preprotein binding site of Escherichia coli SecA. To elucidate the function of this region further, we isolated mutants using a combination of region-specific polymerase chain reaction (PCR) mutagenesis and a genetic and biochemical screening procedure. Although this region displayed considerable plasticity based on phylogenetic and genetic analysis, Tyr-326 was found to be critical for SecA function. secA mutants with non-conservative substitutions at Tyr-326 showed strong protein secretion defects in vivo and were completely defective for SecA-dependent translocation ATPase activity in vitro. The SecA-Y326 mutant proteins were normal in their membrane, SecYE and nucleotide-binding properties. However, they exhibited a reduced affinity for preprotein and were defective in preprotein release, as assessed by several biochemical assays. Our results indicate that the region containing Tyr-326 functions as a conformational response element to regulate the preprotein binding and release cycle of SecA.