Curing of plasmid pXO1 from Bacillus anthracis using plasmid incompatibility

The large plasmid pXO1 encoding the anthrax toxin is important for the virulence of Bacillus anthracis. It is essential to cure pXO1 from B. anthracis to evaluate its role in the pathogenesis of anthrax infection. Because conventional methods for curing plasmids (e.g., curing agents or growth at elevated temperatures) can induce mutations in the host chromosomal DNA, we developed a specific and reliable method to eliminate pXO1 from B. anthracis using plasmid incompatibility. Three putative replication origins of pXO1 were inserted into a temperature-sensitive plasmid to generate three incompatible plasmids. One of the three plasmids successfully eliminated the large plasmid pXO1 from B. anthracis vaccine strain A16R and wild type strain A16. These findings provided additional information about the replication/partitioning of pXO1 and demonstrated that introducing a small incompatible plasmid can generate plasmid-cured strains of B. anthracis without inducing spontaneous mutations in the host chromosome.     

BslA, a pXO1-encoded adhesin of Bacillus anthracis

The Gram-positive pathogen Bacillus anthracis causes anthrax, a fulminant and lethal infection of mammals. Two large virulence plasmids, pXO1 and pXO2, harbour genes required for anthrax pathogenesis and encode secreted toxins or provide for the poly γ- d -glutamic acid capsule. In addition to capsule, B. anthracis harbours additional cell wall envelope structures, including the surface layer (S-layer), which is composed of crystalline protein arrays. We sought to identify the B. anthracis envelope factor that mediates adherence of vegetative forms to human cells and isolated BslA ( B . anthracis S - l ayer protein A ). Its structural gene, bslA , is located on the pXO1 pathogenicity island (pXO1-90) and bslA expression is both necessary and sufficient for adherence of vegetative forms to host cells. BslA assembly into S-layers and surface exposure is presumably mediated by three N-terminal SLH domains. Twenty-three B. anthracis genes, whose products harbour similar SLH domains, may provide additional surface molecules that allow bacilli to engage cells or tissues of specific hosts during anthrax pathogenesis.     

A novel FtsZ-like protein is involved in replication of the anthrax toxin-encoding pXO1 plasmid in Bacillus anthracis

Plasmid pXO1 encodes the tripartite anthrax toxin, which is the major virulence factor of Bacillus anthracis. In spite of the important role of pXO1 in anthrax pathogenesis, very little is known about its replication and maintenance in B. anthracis. We cloned a 5-kb region of the pXO1 plasmid into an Escherichia coli vector and showed that this plasmid can replicate when introduced into B. anthracis. Mutational analysis showed that open reading frame 45 (repX) of pXO1 was required for the replication of the miniplasmid in B. anthracis. Interestingly, repX showed limited homology to bacterial FtsZ proteins that are involved in cell division. A mutation in the predicted GTP binding domain of RepX abolished its replication activity. Genes almost identical to repX are contained on several megaplasmids in members of the Bacillus cereus group, including a B. cereus strain that causes an anthrax-like disease. Our results identify a novel group of FtsZ-related initiator proteins that are required for the replication of virulence plasmids in B. anthracis and possibly in related organisms. Such replication proteins may provide novel drug targets for the elimination of plasmids encoding the anthrax toxin and other virulence factors.     

Contribution of determinants, located in Bacillus anthracis chromosomes, in realizing the pathogenic properties of the pathogen

Comparative study of virulence of B. anthracis strains harbouring pXO1 and pXO2 plasmids in mice and guinea pigs showed that among six B. anthracis strains, three were 100-1000 times less virulent for guinea pigs. Genetic construction of B. anthracis strains using transduction and conjugation transfer of resident plasmids permitted us to rule out the effects of modified pXO1 and pXO2 replicons and to prove the existence of nonidentified chromosome locuses responsible for the development of an infectious process in anthrax, along with plasmid determinants of virulence.     

HtrA is a major virulence determinant of Bacillus anthracis

We demonstrate that disruption of the htrA (high temperature requirement A) gene in either the virulent Bacillus anthracis Vollum (pXO1(+) , pXO2(+) ), or in the ΔVollum (pXO1(-), pXO2(-), nontoxinogenic and noncapsular) strains, affect significantly the ability of the resulting mutants to withstand heat, oxidative, ethanol and osmotic stress. The ΔhtrA mutants manifest altered secretion of several proteins, as well as complete silencing of the abundant extracellular starvation-associated neutral protease A (NprA). VollumΔhtrA bacteria exhibit delayed proliferation in a macrophage infection assay, and despite their ability to synthesize the major B. anthracis toxins LT (lethal toxin) and ET (oedema toxin) as well as the capsule, show a decrease of over six orders of magnitude in virulence (lethal dose 50% = 3 × 10(8) spores, in the guinea pig model of anthrax), as compared with the parental wild-type strain. This unprecedented extent of loss of virulence in B. anthracis, as a consequence of deletion of a single gene, as well as all other phenotypic defects associated with htrA mutation, are restored in their corresponding trans-complemented strains. It is suggested that the loss of virulence is due to increased susceptibility of the ΔhtrA bacteria to stress insults encountered in the host. On a practical note, it is demonstrated that the attenuated Vollum ΔhtrA is highly efficacious in protecting guinea pigs against a lethal anthrax challenge.     

A Bacillus anthracis strain deleted for six proteases serves as an effective host for production of recombinant proteins

Bacillus anthracis produces a number of extracellular proteases that impact the integrity and yield of other proteins in the B. anthracis secretome. In this study we show that anthrolysin O (ALO) and the three anthrax toxin proteins, protective antigen (PA), lethal factor (LF), and edema factor (EF), produced from the B. anthracis Ames 35 strain (pXO1?, pXO2?), are completely degraded at the onset of stationary phase due to the action of proteases. An improved Cre-loxP gene knockout system was used to sequentially delete the genes encoding six proteases (InhA1, InhA2, camelysin, TasA, NprB, and MmpZ). The role of each protease in degradation of the B. anthracis toxin components and ALO was demonstrated. Levels of the anthrax toxin components and ALO in the supernatant of the sporulation defective, pXO1? A35HMS mutant strain deleted for the six proteases were significantly increased and remained stable over 24 h. A pXO1-free variant of this six-protease mutant strain, designated BH460, provides an improved host strain for the preparation of recombinant proteins. As an example, BH460 was used to produce recombinant EF, which previously has been difficult to obtain from B. anthracis. The EF protein produced from BH460 had the highest in vivo potency of any EF previously purified from B. anthracis or Escherichia coli hosts. BH460 is recommended as an effective host strain for recombinant protein production, typically yielding greater than 10mg pure protein per liter of culture.     

Early Bacillus anthracis-macrophage interactions: intracellular survival survival and escape

This study describes early intracellular events occurring during the establishment phase of Bacillus anthracis infections. Anthrax infections are initiated by dormant endospores gaining access to the mammalian host and becoming engulfed by regional macrophages (Mφ). During systemic anthrax, late stage events include vegetative growth in the blood to very high titres and the synthesis of the anthrax exotoxin complex, which causes disease symptoms and death. Experiments focus on the early events occurring during the first few hours of the B. anthracis infectious cycle, from endospore germination up to and including release of the vegetative cell from phagocytes. We found that newly vegetative bacilli escape from the phagocytic vesicles of cultured Mφ and replicate within the cytoplasm of these cells. Release from the Mφ occurs 4–6 h after endospore phagocytosis, timing that correlates with anthrax infection of test animals. Genetic analysis from this study indicates that the toxin plasmid pXO1 is required for release from the Mφ, whereas the capsule plasmid pXO2 is not. The transactivator atxA , located on pXO1, is also found to be essential for release, but the toxin genes themselves are not required. This suggests that Mφ release of anthrax bacilli is atxA regulated. The putative 'escape' genes may be located on the chromosome and/or on pXO1.     

Two independent replicons can support replication of the anthrax toxin-encoding plasmid pXO1 of Bacillus anthracis

The large pXO1 plasmid (181.6kb) of Bacillus anthracis encodes the anthrax toxin proteins. Previous studies have shown that two separate regions of pXO1 can support replication of pXO1 miniplasmids when introduced into plasmid-less strains of this organism. No information is currently available on the ability of the above two replicons, termed RepX and ORFs 14/16 replicons, to support replication of the full-length pXO1 plasmid. We generated mutants of the full-length pXO1 plasmid in which either the RepX or the ORFs 14/16 replicon was inactivated by TargeTron insertional mutagenesis. Plasmid pXO1 derivatives containing only the RepX or the ORFs 14/16 replicon were able to replicate when introduced into a plasmid-less B. anthracis strain. Plasmid copy number analysis showed that the ORFs 14/16 replicon is more efficient than the RepX replicon. Our studies demonstrate that both the RepX and ORFs 14/16 replicons can independently support the replication of the full-length pXO1 plasmid.     

Complete genome sequence of Bacillus anthracis H9401, an isolate from a Korean patient with anthrax

Bacillus anthracis H9401 (NCCP 12889) is an isolate from a Korean patient with gastrointestinal anthrax. The whole genome of H9401 was sequenced. It is a circular chromosome containing 5,480 open reading frames (ORFs) and two plasmids, pXO1 containing 202 ORFs and pXO2 containing 110 ORFs. H9401 shows high pathogenicity and genome sequence similarity to Ames Ancestor.     

Sensitive and rapid quantitative detection of anthrax spores isolated from soil samples by real-time PCR

Quantitative analysis of anthrax spores from environmental samples is essential for accurate detection and risk assessment since Bacillus anthracis spores have been shown to be one of the most effective biological weapons. Using TaqMan real-time PCR, specific primers and probes were designed for the identification of pathogenic B. anthracis strains from pag gene and cap gene on two plasmids, pXO1 and pXO2, as well as a sap gene encoded on the S-layer. To select the appropriate lysis method of anthrax spore from environmental samples, several heat treatments and germination methods were evaluated with multiplex-PCR. Among them, heat treatment of samples suspended with sucrose plus non-ionic detergent was considered an effective spore disruption method because it detected up to 10(5) spores/g soil by multiplex-PCR. Serial dilutions of B. anthracis DNA and spore were detected up to a level of 0.1 ng/ microliters and 10 spores/ml, respectively, at the correlation coefficient of 0.99 by real-time PCR. Quantitative analysis of anthrax spore could be obtained from the comparison between C(T) value and serial dilutions of soil sample at the correlation coefficient of 0.99. Additionally, spores added to soil samples were detected up to 10(4) spores/g soil within 3 hr by real-time PCR. As a consequence, we established a rapid and accurate detection system for environmental anthrax spores using real-time PCR, avoiding time and labor-consuming preparation steps such as enrichment culturing and DNA preparation.     

A simple and sensitive detection system for Bacillus anthracis in meat and tissue

AIMS: To detect and isolate Bacillus anthracis from meat and tissue by rapid and simple procedures. METHODS AND RESULTS: Bacillus anthracis Pasteur II cells were added to 1 g lymph node and pig meat, which were then cut into small pieces and suspended in PBS. Aliquots were spread on Bacillus cereus selective agar (BCA) plates to isolate B. anthracis cells, and incubated in trypticase soy broth. The enrichment culture was used for nested PCR with B. anthracis specific primers, which were to confirm the presence of B. anthracis chromosomal DNA and the pXO1/pXO2 plasmids. CONCLUSION: One cell of B. anthracis was detected by nested PCR from 1 g of the samples, and was also isolated on BCA plates according to colony morphology within two days. SIGNIFICANCE AND IMPACT OF THE STUDY: These results could be useful for detecting animals with latent anthrax, and meat contaminated with B. anthracis, rapidly and simply.     

Anthrax: early steps of the intracellular stage of infection development

It was shown that spore germination of different Bacillus anthracis strains in macrophage-like cells J774A.1 depended on the genotype of the strains. The virulent B. anthracis strains contain plasmids pXO1 and pX02 responsible for the synthesis of a toxin and a capsule, respectively. The loss of one of the plasmids results in the reduction of strain virulence. It was shown that effective survival of germinating spores in macrophages occurred in the presence of plasmid pXO1 only. The spores of the B. anthracis strains ?Ames and STI-Rif deprived of plasmid pXO1 were least adapted to passing through the intracellular stage. The B. anthracis strains 81/1 and 71/12 (carrying plasmids pXO1 and pXO2 and synthesizing the toxin and capsule) less effectively survived in the cytoplasm of macrophages than the strain STI-1 which has only the plasmid pXO1. It was found that the rate of synthesis of the capsule consisting of polymer gamma-D-glutamic acid depended on the ability of bacterial cells to escape from macrophages. In the B. anthracis strains carrying plasmid pXO2, capsule synthesis by vegetative cells was activated within macrophages that promoted a rapid escape of the vegetative cells from the macrophages. On the contrary, most of capsule-free cells of the vaccine strain STI-1 remained inside macrophages during the whole period of observation. Thus, integrated regulation of two processes, namely synthesis of the toxin components participating in the transition of the germinating cell from phagosome into cytoplasm, and synthesis of the capsule whose presence promotes rapid escape of bacterial cells from macrophages by presently unknown mechanism play the key role in anthrax development at early stages.     

Bacillus anthracis but not always anthrax.

Gram-positive bacilli isolated during epidemiological investigations which, on the basis of conventional tests, resemble Bacillus anthracis but which fail to produce the capsule or to induce anthrax in test animals have long been dismissed in clinical and veterinary laboratories as B. cereus or simply as unidentified Bacillus spp. and thereupon discarded as inconsequential. In this study, the application of newly available DNA probe, polymerase chain reaction and specific toxin antigen detection technology has revealed that a proportion of such strains are B. anthracis which lack the plasmid carrying the capsule gene (pXO2). While these techniques cannot, of course, be used to confirm the identities of strains resembling B. anthracis but which also lack the plasmid carrying the toxin genes (pXO1), the likelihood that these also are bona fide B. anthracis becomes more acceptable. (As yet no naturally occurring pXO1-/2+ strains have been found.) At this point, the significance of the presence of such avirulent forms of B. anthracis in specimens can only be a subject for speculation, but the possibility that they may be indicators of virulent parents somewhere in the system being examined must be considered.     

Molecular evolution and diversity in Bacillus anthracis as detected by amplified fragment length polymorphism markers.

Bacillus anthracis causes anthrax and represents one of the most molecularly monomorphic bacteria known. We have used AFLP (amplified fragment length polymorphism) DNA markers to analyze 78 B. anthracis isolates and six related Bacillus species for molecular variation. AFLP markers are extremely sensitive to even small sequence variation, using PCR and high-resolution electrophoresis to examine restriction fragments. Using this approach, we examined ca. 6.3% of the Bacillus genome for length mutations and ca. 0.36% for point mutations. Extensive variation was observed among taxa, and both cladistic and phenetic analyses were used to construct a phylogeny of B. anthracis and its closest relatives. This genome-wide analysis of 357 AFLP characters (polymorphic fragments) indicates that B. cereus and B. thuringiensis are the closest taxa to B. anthracis, with B. mycoides slightly more distant. B. subtilis, B. polymyxa, and B. stearothermophilus shared few AFLP markers with B. anthracis and were used as outgroups to root the analysis. In contrast to the variation among taxa, only rare AFLP marker variation was observed within B. anthracis, which may be the most genetically uniform bacterial species known. However, AFLP markers did establish the presence or absence of the pXO1 and pXO2 plasmids and detected 31 polymorphic chromosomal regions among the 79 B. anthracis isolates. Cluster analysis identified two very distinct genetic lineages among the B. anthracis isolates. The level of variation and its geographic distribution are consistent with a historically recent African origin for this pathogenic organism. Based on AFLP marker similarity, the ongoing anthrax epidemic in Canada and the northern United States is due to a single strain introduction that has remained stable over at least 30 years and a 1,000-mile distribution.     

Synthesis of lipoteichoic acids in Bacillus anthracis

Lipoteichoic acid (LTA), a glycerol phosphate polymer, is a component of the envelope of Gram-positive bacteria that has hitherto not been identified in Bacillus anthracis, the causative agent of anthrax. LTA synthesis in Staphylococcus aureus and other microbes is catalyzed by the product of the ltaS gene, a membrane protein that polymerizes polyglycerol phosphate from phosphatidyl glycerol. Here we identified four ltaS homologues, designated ltaS1 to -4, in the genome of Bacillus anthracis. Polyglycerol phosphate-specific monoclonal antibodies were used to detect LTA in the envelope of B. anthracis strain Sterne (pXO1(+) pXO2(-)) vegetative forms. B. anthracis mutants lacking ltaS1, ltaS2, ltaS3, or ltaS4 did not display defects in growth or LTA synthesis. In contrast, B. anthracis strains lacking both ltaS1 and ltaS2 were unable to synthesize LTA and exhibited reduced viability, altered envelope morphology, aberrant separation of vegetative forms, and decreased sporulation efficiency. Expression of ltaS1 or ltaS2 alone in B. anthracis as well as in other microbes was sufficient for polyglycerol phosphate synthesis. Thus, similar to S. aureus, B. anthracis employs LtaS enzymes to synthesize LTA, an envelope component that promotes bacterial growth and cell division.     

Rapid genotypic detection of Bacillus anthracis and the Bacillus cereus group by multiplex real-time PCR melting curve analysis

Bacillus anthracis has four plasmid possible virulence genotypes: pXO1+/pXO2+, pXO1+/pXO2-, pXO1-/pXO2+ or pXO1-/pXO2-. Due to the lack of a specific chromosomal marker for B. anthracis, differentiation of the pXO1-/pXO2- form of B. anthracis from closely related Bacillus cereus group species is difficult. In this study, we evaluate the ability of sspE, pXO1 and pXO2 primers to discriminate individual B. anthracis and the B. cereus group genotypes using multiplex real-time PCR and melting curve analysis. Optimal conditions for successful multiplex assays have been established. Purified DNAs from 38 bacterial strains including 11 strains of B. anthracis and 18 B. cereus group strains were analyzed. Nine of the B. cereus group near-neighbor strains were shown by multilocus sequence typing to be phylogenetically proximate to the B. anthracis clade. We have demonstrated that the four plasmid genotypes of B. anthracis and B. cereus group near-neighbors were differentially and simultaneously discriminated by this assay.     

Bacillus anthracis but not always anthrax

Gram-positive bacilli isolated during epidemiological investigations which, on the basis of conventional tests, resemble Bacillus anthracis but which fail to produce the capsule or to induce anthrax in test animals have long been dismissed in clinical and veterinary laboratories as B. cereus or simply as unidentified Bacillus spp. and thereupon discarded as inconsequential. In this study, the application of newly available DNA probe, polymerase chain reaction and specific toxin antigen detection technology has revealed that a proportion of such strains are B. anthracis which lack the plasmid carrying the capsule gene (pXO2). While these techniques cannot, of course, be used to confirm the identities of strains resembling B. anthracis but which also lack the plasmid carrying the toxin genes (pXO1), the likelihood that these also are bonajide B. anthracis becomes more acceptable. (As yet no naturally occurring pXOl^-/2⁺ strains have been found.) At this point, the significance of the presence of such avirulent forms of B. anthracis in specimens can only be a subject for speculation, but the possibility that they may be indicators of virulent parents somewhere in the system being examined must be considered.     

Identification of chromosomally encoded membranal polypeptides of Bacillus anthracis by a proteomic analysis: prevalence of proteins containing S-layer homology domains

Bacillus anthracis is the causative agent of anthrax disease. Improvement of existing anthrax vaccines, which are currently based on the administration of Protective Antigen (the highly immunogenic nontoxic subunit of the bacterial toxin) may entail other bacterial immunogenic elements, part of which are predicted to reside on the surface of bacterial cells. In the present study, membranal proteins extracted from a stationary-phase culture of a nonvirulent B. anthracis strain, devoid of the native virulence plasmids pXO1 and pXO2, were separated by two-dimensional electrophoresis (2-DE) and a characteristic protein map was defined. The proteomic analysis allowed matrix-assisted laser desorption/ionization-time of flight mass spectrometry-assisted identification of 86 protein spots which represent the product of 30 individual open reading frames (ORF). Among these, a prevalent class of proteins was the S-layer proteins (which were found to represent more than 75% of the B. anthracis membranal fraction) and proteins containing S-layer homology (SLH)-membranal localization domains. Five novel SLH proteins, previously inferred only from bioinformatic ORF analysis (draft genome sequence), were identified and one was shown to be a highly abundant membranal protein. Western blots of the 2-DE gels were probed with sera from convalescent rabbits and guinea pigs infected with virulent B. anthracis (Vollum strain). This analysis revealed that B. anthracis immune animals exhibit antibodies against at least 14 distinct membranal proteins present in the 2-DE map, establishing that these proteins are expressed in vivo and are able to elicit an immune response. The identification of the protein components of the B. anthracis membranal fraction, as well as the establishment of their potential immunogenicity, underscore the strength of the proteomic approach for identifying molecules which may serve for further analysis of immune and protective abilities.