Bacillus anthracis

About: Bacillus anthracis is a research topic. Over the lifetime, 3994 publications have been published within this topic receiving 128122 citations.

Treatment of experimental anthrax with recombinant capsule depolymerase.

Abstract: Bacillus anthracis produces an antiphagocytic gamma-linked poly-D-glutamic acid capsule that is required for virulence. Capsule depolymerase (CapD) is a membrane-associated poly-gamma-glutamate-specific depolymerase encoded on the B. anthracis capsule plasmid, pX02, that is reported to contribute to virulence by anchoring the capsule to the peptidoglycan and partially degrading high-molecular-weight capsule from the bacterial surface. We previously demonstrated that treatment with CapD effectively removes the capsule from anthrax bacilli, rendering them susceptible to phagocytic killing in vitro. Here we report that CapD promoted in vivo phagocytic killing of B. anthracis bacilli by mouse peritoneal neutrophils and that parenteral administration of CapD protected mice in two models of anthrax infection. CapD conferred significant protection compared with controls when coinjected with encapsulated bacilli from fully virulent B. anthracis Ames or the nontoxigenic encapsulated strain Delta Ames and when injected 10 min after infection with encapsulated bacilli from B. anthracis Ames. Protection was also observed when CapD was administered 30 h after infection with B. anthracis Delta Ames spores, while significant protection could not be demonstrated following challenge with B. anthracis Ames spores. These data support the proposed role of capsule in B. anthracis virulence and suggest that strategies to target anthrax bacilli for neutrophil killing may lead to novel postexposure therapies.

Ultrasensitive, direct detection of a specific DNA sequence of Bacillus anthracis in solution.

Abstract: A very fast and ultrasensitive method has been developed for the detection and quantitation of specific nucleic and sequences of bacterial origin in solution. The method is based on a two-color, single fluorescent molecule detection technique developed in our laboratory. The technique was applied to the detection of Bacillus anthracis DNA in solution.

Anthrax toxin fusion proteins for intracellular delivery of macromolecules

Abstract: The dominant role played by the anthrax toxin in Bacillus anthracis pathogenesis shows that the toxin has evolved to be an efficient system for delivering its two catalytic protein components, oedema factor and lethal factor (LF), into the cytosol of host cells. This system involves binding of the protective antigen (PA) toxin component to a ubiquitous (and still unidentified) receptor, proteolytic activation at the cell surface, internalization by endocytosis and translocation through an early endosome membrane to the cytosol ( Leppla 1995). We and colleagues showed that the system can be exploited to deliver heterologous polypeptides to the cytosol ( Arora et al. 1992 ; Milne et al. 1995 ). This work used the catalytic domains of other toxins which are normally translocated across membranes ( Arora & Leppla 1994) . Immunity to intracellular pathogens depends on the cytosolic processing of antigens to produce peptides that are presented on the cell surface bound to MHC Class I molecules. The anthrax toxin delivery system provides a way to mimic this process. We made a fusion protein containing the (non-catalytic) amino terminal domain of LF and the gp120 envelope glycoprotein of HIV-1. Administration of this recombinant protein along with PA to antigen-presenting cells sensitized them to cytolysis by cytotoxic T-cells specific to gp120 peptides ( Goletz et al. 1997 ). Further exploitation of the anthrax toxin system as a cell-targeting reagent would be facilitated by achieving cell type specificity. The recent determination of the PA structure ( Petosa et al. 1997 ) allows rational engineering to modify or replace the receptor-binding domain with specific ligand structures. A model system was produced by fusing a c-Myc peptide to the carboxyl terminus of PA so as to target hybridoma cells expressing cell surface antibodies to this peptide. Killing of the hybridoma cells was shown to be specific by competition with the peptide and with non-toxic mutants of PA ( Varughese et al. 1998 ).

Potential dissemination of Bacillus anthracis utilizing human lung epithelial cells

Abstract: Dissemination of Bacillus anthracis spores from the lung is a critical early event in the establishment of inhalational anthrax. We recently reported that B. anthracis could adhere to and be internalized by cultured intestinal epithelial and fibroblast cells. Here, using gentamicin protection assays and/or electron microscopy, we found that Sterne strain 7702 spores were able to adhere to and subsequently be internalized by polarized A549 cells and primary human small airway epithelial cells. We showed for the first time that internalized spores were able to survive and that spores could translocate across an A549 cell barrier from the apical side to the basolateral side without disrupting the barrier integrity, suggesting a transcellular route. In addition, dormant spores of fully virulent Ames and UT500 strains were able to adhere to A549 cells at a frequency similar to that of 7702, whereas the capsule in germinated Ames and UT500 spores prevented adherence. Fluorescence microscopy also revealed that dormant Ames spores were internalized at a frequency similar to that of 7702. These findings highlight the possibility of a novel route of dissemination in which B. anthracis utilizes epithelial cells of the lung. The implications of these results to B. anthracis pathogenesis are discussed.