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.     

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.     

Identification of self-transmissible plasmids in four Bacillus thuringiensis subspecies.

The transfer of plasmids by mating from four Bacillus thuringiensis subspecies to Bacillus anthracis and Bacillus cereus recipients was monitored by selecting transcipients which acquired plasmid pBC16 (Tcr). Transcipients also inherited a specific large plasmid from each B. thuringiensis donor at a high frequency along with a random array of smaller plasmids. The large plasmids (ca. 50 to 120 megadaltons), pXO13, pXO14, pXO15, and pXO16, originating from B. thuringiensis subsp. morrisoni, B. thuringiensis subsp. toumanoffi, B. thuringiensis subsp. alesti, and B. thuringiensis subsp. israelensis, respectively, were demonstrated to be responsible for plasmid mobilization. Transcipients containing any of the above plasmids had donor capability, while B. thuringiensis strains cured of each of them were not fertile, indicating that the plasmids confer conjugation functions. Confirmation that pXO13, pXO14, and pXO16 were self-transmissible was obtained by the isolation of fertile B. anthracis and B. cereus transcipients that contained only pBC16 and one of these plasmids. pXO14 was efficient in mobilizing the toxin and capsule plasmids, pXO1 and pXO2, respectively, from B. anthracis transcipients to plasmid-cured B. anthracis or B. cereus recipients. DNA-DNA hybridization experiments suggested that DNA homology exists among pXO13, pXO14, and the B. thuringiensis subsp. thuringiensis conjugative plasmids pXO11 and pXO12. Matings performed between strains which each contained the same conjugative plasmid demonstrated reduced efficiency of pBC16 transfer. However, in many instances when donor and recipient strains contained different conjugative plasmids, the efficiency of pBC16 transfer appeared to be enhanced.     

Transduction and conjugation transfer of the pXO2 plasmid in Bacillus anthracis

The plasmid pXO2 determining the capsule synthesis has been shown to be transfered into the cells of different strains of Bacillus anthracis (STI-1, Sterne, KM33, KM35) by the transducing bacteriophage CP54ant and by mobilization by pAM beta 1 replicon with the frequencies, consequently, n.10(-8) and n.10(-7). The optimal parameters for the selection of clones having acquired the pXO2 plasmid have been defined. Mobilization for conjugational transfer has been demonstrated for the plasmid pXO1 coding for the production of Bacillus anthracis toxin. The dramatic increase of virulence for white mice has been registered for Bacillus anthracis strains having acquired the pXO2 plasmid replicon.     

Involvement of Tn4430 in transfer of Bacillus anthracis plasmids mediated by Bacillus thuringiensis plasmid pXO12.

The self-transmissible plasmid pXO12 (112.5 kilobases [kb]), originally isolated from strain 4042A of Bacillus thuringiensis subsp. thuringiensis, codes for production of the insecticidal crystal protein (Cry+). The mechanism of pXO12-mediated plasmid transfer was investigated by monitoring the cotransfer of the tetracycline resistance plasmid pBC16 (4.2 kb) and the Bacillus anthracis toxin and capsule plasmids, pXO1 (168 kb) and pXO2 (85.6 kb), respectively. In matings of B. anthracis donors with B. anthracis and Bacillus cereus recipients, the number of Tcr transcipients ranged from 4.8 x 10(4) to 3.9 x 10(6)/ml (frequencies ranged from 1.6 x 10(-4) to 7.1 x 10(-2), and 0.3 to 0.4% of them simultaneously inherited pXO1 or pXO2. Physical analysis of the transferred plasmids suggested that pBC16 was transferred by the process of donation and that the large B. anthracis plasmids were transferred by the process of conduction. The transfer of pXO1 and pXO2 involved the transposition of Tn4430 from pXO12 onto these plasmids. DNA-DNA hybridization experiments demonstrated that Tn4430 was located on a 16.0-kb AvaI fragment of pXO12. Examination of Tra- and Cry- derivatives of pXO12 showed that this fragment also harbored information involved in crystal formation and was adjacent to a restriction fragment containing DNA sequences carrying information required for conjugal transfer.     

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.     

Application of the multiplex PCR and PCR-RFLP method in the identification of the Bacillus anthracis

The aim of this study was to apply the multiplex PCR and PCR-RFLP method for the identification of the B. anthracis strains and to distinguish those bacteria from other members of the Bacillus cereus group. The multiplex PCR method enables to detect the virulence factors, i.e. the toxin and the capsule in B. anthracis strains. To do that, the authors have used 5 primer pairs specific for the fragments of lef, cya, pag genes which are present in the pXO1 plasmid and encode the toxin, the cap gene, which is present in the pXO2 plasmid and encodes the capsule, and the Ba813 chromosomal sequence. Among the four B. anthracis strains examined, three contained two plasmids and the Ba813 chromosomal sequence, while the fourth one contained the pXO1 plasmid only, together and the Ba813 chromosomal sequence. Other bacterial species, belonging to the B. cereus group, were also examined: 6 strains of B. cereus, 4 strains of B. thuringiensis and one strain of B. mycoides. The presence of Ba813 chromosomal sequence has been detected in two B. cereus strains. Neither plasmids nor Ba813 chromosomal sequence have been discovered in other B. cereus, B. thuringiensis and B. mycoides strains. The results of the survey indicate that the Ba813 chromosomal sequence does not occur solely in B. anthracis strains. The PCR-RFLP method with the use of SG-749f and SG-749r primers enabled to demonstrate the presence of DNA sequence (SG-749) in B. anthracis, B. cereus, B. thuringiensis and B. mycoides strains. Restriction analysis with enzyme AluI of the SG-749 sequence, has shown the presence of two DNA fragments at the size of about 90 and 660 bp in all B. anthracis strains. The restriction profile obtained was characteristic for B. anthracis strains and it did not occur in other investigated bacterial species belonging to the B. cereus group. It was not observed even in such B. cereus strains in which the presence of Ba813 sequence was discovered and it enabled to differentiate between B. anthracis strains and other closely related species of the B. cereus group.     

Characterization of Bacillus anthracis-like bacteria isolated from wild great apes from Cote d'Ivoire and Cameroon

We present the microbiological and molecular characterization of bacteria isolated from four chimpanzees and one gorilla thought to have died of an anthrax-like disease in C?te d'Ivoire and Cameroon. These isolates differed significantly from classic Bacillus anthracis by the following criteria: motility, resistance to the gamma phage, and, for isolates from Cameroon, resistance to penicillin G. A capsule was expressed not only after induction by CO(2) and bicarbonate but also under normal growth conditions. Subcultivation resulted in beta-hemolytic activity and gamma phage susceptibility in some subclones, suggesting differences in gene regulation compared to classic B. anthracis. The isolates from C?te d'Ivoire and Cameroon showed slight differences in their biochemical characteristics and MICs of different antibiotics but were identical in all molecular features and sequences analyzed. PCR and Southern blot analyses confirmed the presence of both the toxin and the capsule plasmid, with sizes corresponding to the B. anthracis virulence plasmids pXO1 and pXO2. Protective antigen was expressed and secreted into the culture supernatant. The isolates possessed variants of the Ba813 marker and the SG-749 fragment differing from that of classic B. anthracis strains. Multilocus sequence typing revealed a close relationship of our atypical isolates with both classic B. anthracis strains and two uncommonly virulent Bacillus cereus and Bacillus thuringiensis isolates. We propose that the newly discovered atypical B. anthracis strains share a common ancestor with classic B. anthracis or that they emerged recently by transfer of the B. anthracis plasmids to a strain of the B. cereus group.     

Virulotypes of Bacillus anthracis strains isolated in Poland

Bacillus anthracis--the causative agent of anthrax--possesses several virulence genes located in the chromosome as well as in two B. anthracis virulence plasmids: pXO1 and pXO2. In the presented study, we determined occurrence of six virulence markers located in the virulence plasmids (capA, capB, capC, pagA, lef and cya) for capsule and toxin production together with virulence-associated gene gerXA and chromosomal gene sap, which are responsible for germination and S-layer biosynthesis respectively. Fourteen strains of B. anthracis isolated in Poland and belonging to five different MLVA genotypes were analyzed by PCR for presence of the aforementioned genes. Two virulotypes were found in tested strains. The only variation was absence of capA, capB and capC due to a lack of pXO2.     

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.     

Capsule synthesis by Bacillus anthracis is required for dissemination in murine inhalation anthrax

Bacillus anthracis, the agent of anthrax, produces a poly-D-glutamic acid capsule that has been implicated in virulence. Many strains missing pXO2 (96 kb), which harbors the capsule biosynthetic operon capBCAD, but carrying pXO1 (182 kb) that harbors the anthrax toxin genes, are attenuated in animal models. Also, noncapsulated strains are readily phagocytosed by macrophage cell lines, whereas capsulated strains are resistant to phagocytosis. We show that a strain carrying both virulence plasmids but deleted specifically for capBCAD is highly attenuated in a mouse model for inhalation anthrax. The parent strain and capsule mutant initiated germination in the lungs, but the capsule mutant did not disseminate to the spleen. A mutant harboring capBCAD but deleted for the cap regulators acpA and acpB was also significantly attenuated, in agreement with the capsule-negative phenotype during in vitro growth. Surprisingly, an acpB mutant, but not an acpA mutant, displayed an elevated LD(50) and reduced ability to disseminate, indicating that acpA and acpB are not true functional homologs and that acpB may play a larger role in virulence than originally suspected.     

Markers for species-specific detection of bacteria from Bacillus cereus group

rpoB and gyr genes (and their fragments) of chromosomal DNA of bacteria from Bacillus cereus group - B. anthracis, B. cereus, and B. thuringiensis - which are the potential markers for their genotyping were sequenced and phylogenetic trees were constructed. Sets of primers for species-specific detection of B. anthracis, B. cereus, and B. thuringiensis by multiplex polymerase chain reaction were designed. Also primers sets, which allow to differentiate strains of B. anthracis with various plasmid profiles (containing both plasmids (pXO1+, pXO2+), and without one (pXO1+, pXO2- or pXO1-, pXO2+) or both plasmids (pXO1-, pXO2-), determining pathogenic characteristics of the strains, were developed. For multiplex PCR primer sets were optimized on the annealing temperature of primers and amplicon length. Itwas shown that phylogenetic tree can be applied as an indicator of reliability and accuracy of taxonomical classification of microorganisms' species and subspecies. Comparison of pXO1 and pXO2 plasmid sequences of B. anthracis showed that these plasmids contain 18 and 4 palindrome sequences respectively which can potentially form thermodynamically stable hairpin-loop structures.     

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 sequence analysis of novel plasmids from emetic and periodontal Bacillus cereus isolates reveals a common evolutionary history among the B. cereus-group plasmids, including Bacillus anthracis pXO1

The plasmids of the members of the Bacillus cereus sensu lato group of organisms are essential in defining the phenotypic traits associated with pathogenesis and ecology. For example, Bacillus anthracis contains two plasmids, pXO1 and pXO2, encoding toxin production and encapsulation, respectively, that define this species pathogenic potential, whereas the presence of a Bt toxin-encoding plasmid defines Bacillus thuringiensis isolates. In this study the plasmids from B. cereus isolates that produce emetic toxin or are linked to periodontal disease were sequenced and analyzed. Two periodontal isolates examined contained almost identical approximately 272-kb plasmids, named pPER272. The emetic toxin-producing isolate contained one approximately 270-kb plasmid, named pCER270, encoding the cereulide biosynthesis gene cluster. Comparative sequence analyses of these B. cereus plasmids revealed a high degree of sequence similarity to the B. anthracis pXO1 plasmid, especially in a putative replication region. These plasmids form a newly defined group of pXO1-like plasmids. However, these novel plasmids do not contain the pXO1 pathogenicity island, which in each instance is replaced by plasmid specific DNA. Plasmids pCER270 and pPER272 share regions that are not found in any other pXO1-like plasmids. Evolutionary studies suggest that these plasmids are more closely related to each other than to other identified B. cereus plasmids. Screening of a population of B. cereus group isolates revealed that pXO1-like plasmids are more often found in association with clinical isolates. This study demonstrates that the pXO1-like plasmids may define pathogenic B. cereus isolates in the same way that pXO1 and pXO2 define the B. anthracis species.     

Mating system for transfer of plasmids among Bacillus anthracis, Bacillus cereus, and Bacillus thuringiensis.

To facilitate the analysis of genetic determinants carried by large resident plasmids of Bacillus anthracis, a mating system was developed which promotes plasmid transfer among strains of B. anthracis, B. cereus, and B. thuringiensis. Transfer of the selectable tetracycline resistance plasmid pBC16 and other plasmids from B. thuringiensis to B. anthracis and B. cereus recipients occurred during mixed incubation in broth. Two plasmids, pXO11 and pXO12, found in B. thuringiensis were responsible for plasmid mobilization. B. anthracis and B. cereus transcipients inheriting either pXO11 or pXO12 were, in turn, effective donors. Transcipients harboring pXO12 were more efficient donors than those harboring pXO11; transfer frequencies ranged from 10(-4) to 10(-1) and from 10(-8) to 10(-5), respectively. Cell-to-cell contact was necessary for plasmid transfer, and the addition of DNase had no effect. The high frequencies of transfer, along with the fact that cell-free filtrates of donor cultures were ineffective, suggested that transfer was not phage mediated. B. anthracis and B. cereus transcipients which inherited pXO12 also acquired the ability to produce parasporal crystals (Cry+) resembling those produced by B. thuringiensis, indicating that pXO12 carries a gene(s) involved in crystal formation. Transcipients which inherited pXO11 were Cry-. This mating system provides an efficient method for interspecies transfer of a large range of Bacillus plasmids by a conjugation-like process.     

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.     

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.     

Phenotypic and genetic features of cultural-morphologic variants of Bacillus anthracis

Comparative analysis of MVLA-genotypes of 6 Bacillus anthracis strains and 40 their variants differing on capsule- and toxin synthesis, hemolytic, proteolytic and lecitinase activity, nutritional requirements, susceptibility to anthrax bacteriophages, virulence, immunogenicity, and presence of genes for capsule and toxin synthesis was performed. Results of phylogenetic analysis of 5 chromosome locuses and plasmid locus pXO1aat which are variable for this sample of B. anthracis cultures showed that all strains divided on 2 main clusters - A and B. Cluster A consisted of 5 genotypes whereas cluster B - of 1 genotype. All highly virulent original strains and variants with characteristic phenotype Cap(CO2)(+)(O2)(-)Tox(+)ProtA(+)Hly(+) Lec(-)Trp(+) had identical genotype in 4 groups and in 5th group differences were present only in vrrA locus. All original strains and variants with the most atypical complex of phenotypic characteristics Cap (CO2)(+)(O2)(+)Tox(-)ProtA(-)Hly(-)Lec(-)Trp(-) also had the same genotype belonging to cluster B and diverged on characteristic of 5 chromosomal VNTR locuses and pXO1aat locus from typical strains. Absence of toxin production in vitro was not related to loss of genetic determinants of toxin components. Cultures with typical characteristics, one of which was ability to produce toxin in vitro, had larger sizes of amplicons of pXO1aat locus (135 and 132 nbp), whereas atoxigenic original strains and variants with complex of atypical characteristics and identical chromosome genotype had the smallest sizes (123 bnp). All original cultures were isolated in Russia, their genotypes are described for the first time.     

TnXO1, a germination-associated class II transposon from Bacillus anthracis

Bacillus anthracis harbours two virulence plasmids, pXO1 (182 kb) and pXO2 (95 kb). Whereas pXO2 harbours the cap operon coding for the capsule, pXO1 contains the pag, lef, and cya genes coding for protective antigen, lethal, and oedema factors, respectively, as well as the atxA regulatory gene. These genes are located within a 44.8 kb long pathogenicity island flanked by insertion sequences. Here, we describe the presence in the same plasmid region of an 8679 bp genetic element displaying the structural features of a class II cointegrative transposon. This element, named TnXO1, bears a transposase and a site-specific recombinase and is delineated by 38 bp terminal inverted repeats sequences similar to those of other members of this group of transposons. A putative res site has been identified in the 200 bp region between these genes. Interestingly, TnXO1 also contains the gerX operon involved in the germination of B. anthracis spores within phagocytic cells. Such close association of a mobile DNA structure with known virulence determinants in a pathogen further prompted us to look for the presence of this transposable element in other members of the Bacillus cereus sensu lato group. No instance of TnXO1 was detected outside of B. anthracis in PCR experiments, although it was found to be present in the genome sequence draft of one strain of B. cereus which has recently been shown to harbour a plasmid almost identical to pXO1.     

Purification and physical analysis of Bacillus anthracis plasmids pXO1 and pXO2

Virulent strains of Bacillus anthracis contain two large plasmids. pXO1 encodes the three component protein exotoxin and pXO2 is necessary for synthesis of the poly-D-glutamic acid capsule. A procedure for the isolation of these plasmids which yields high quantities of pure DNA is described. Restriction endonuclease analysis of these plasmids shows that they are not related. pXO1 is 174 kilobase pairs and pXO2 is 95 kilobase pairs. From their bouyant densities and melting temperatures we also determined their GC contents. pXO1 contains 31.1% GC base pairs and pXO2 is 31.4% GC. Both of these values are close to the GC content of B. anthracis genomic DNA which is 32.2%.