The solute-binding component of a putative Mn(II) ABC transporter (MntA) is a novel Bacillus anthracis virulence determinant.

Here we describe the characterization of a lipoprotein previously proposed as a potential Bacillus anthracis virulence determinant and vaccine candidate. This protein, designated MntA, is the solute-binding component of a manganese ion ATP-binding cassette transporter. Coupled proteomic-serological screen of a fully virulent wild-type B. anthracis Vollum strain, confirmed that MntA is expressed both in vitro and during infection. Expression of MntA is shown to be independent of the virulence plasmids pXO1 and pXO2. An mntA deletion, generated by allelic replacement, results in complete loss of MntA expression and its phenotypic analysis revealed: (i) impaired growth in rich media, alleviated by manganese supplementation; (ii) increased sensitivity to oxidative stress; and (iii) delayed release from cultured macrophages. The DeltamntA mutant expresses the anthrax-associated classical virulence factors, lethal toxin and capsule, in vitro as well as in vivo, and yet the mutation resulted in severe attenuation; a 10(4)-fold drop in LD(50) in a guinea pig model. MntA expressed in trans allowed to restore, almost completely, the virulence of the DeltamntA B. anthracis strain. We propose that MntA is a novel B. anthracis virulence determinant essential for the development of anthrax disease, and that B. anthracisDeltamntA strains have the potential to serve as platform for future live attenuated vaccines.

Construction of a rhamnose mutation in Bacillus anthracis affects adherence to macrophages but not virulence in guinea pigs.

Carbohydrate analyses of whole-spore extracts have confirmed the presence of rhamnose in the spore of the fully virulent Ames strain of Bacillus anthracis. A gene cluster containing loci with high homology to the rhamnose biosynthetic genes, rmlACBD, was identified within the B. anthracis chromosome. The first gene of this cluster, rmlA, was inactivated by forming a merodiploid cointegrate using an internal fragment of the gene within the Ames strain of B. anthracis to construct the mutant strain Ames-JAB1. Carbohydrate analysis of spores from this mutant demonstrated the loss of rhamnose. When assaying for spore infection of macrophages, we detected a significant decrease in the recovery with the Ames-JAB1 strain compared to the recovery with the Ames wild-type strain. When pre-treating macrophages with cytochalasin-D, spores of the mutant were further hindered in recovery, indicating that the spores were not able to bind as well to the macrophages. However, in guinea pigs challenge experiments, no difference in virulence was observed between the mutant and wild-type strains. These results suggest that the incorporation of rhamnose into the spore coat of B. anthracis is required for optimal interaction with macrophages but is not required for full virulence in this animal model.

The NheA component of the non-hemolytic enterotoxin of Bacillus cereus is produced by Bacillus anthracis but is not required for virulence.

A non-hemolytic enterotoxin (NHE) is one of the two enterotoxins thought to cause diarrhea produced by Bacillus cereus. We identified genes in Bacillus anthracis homologous to the B. cereus nheAB genes encoding proteins of the NHE complex. The NheA component was detected immunologically in culture supernatants from B. anthracis but not from a NheA(-) mutant, suggesting that B. anthracis produces and secretes the NheA subunit of NHE. A NheA deletion mutant was not attenuated in the guinea pig suggesting that NheA is not absolutely required for virulence.