Lethal Factor Antigen Research Articles

Development of a novel chimeric PA-LF antigen of Bacillus anthracis, its immunological characterization and evaluation as a future vaccine candidate in mouse model

Tremendous efforts are being made to develop an anthrax vaccine with long term protection. The main component of traditional anthrax vaccine is protective antigen (PA) with the trace amount of other proteins and bacterial components. In this study, we developed a recombinant PA-LF chimera antigen of Bacillus anthracis by fusing the PA domain 2-4 with lethal factor (LF) domain 1 and evaluated its protective potential against B. anthracis in mouse model. The anti-PA-LF chimera serum reacted with both PA and LF antigen, individually. The chimera elicited a strong antibody titer in mice with predominance of IgG1 isotype followed by IgG2b, IgG2a and IgG3. Cytokines were assessed in splenocytes of immunized mice and a significant up-regulation in the expression of IL-4, IL-10, IFN-γ and TNF-α was observed. The PA-LF chimera immunized mice exhibited 80% survival after challenge with virulent spores of B. anthracis. Pathological studies showed normal architecture in vital organs (spleen, lung, liver and kidney) of recovered immunized mice on 20 DPI after spore challenge. These findings suggested that PA-LF chimera of B. anthracis elicited good humoral as well as cell mediated immune response in mice, and thus, can be a potent vaccine candidate against anthrax.

Generation of a novel chimeric PALFn antigen of Bacillus anthracis and its immunological characterization in mouse model.

Bacillus anthracis chimeric molecule PALFn, comprising the immunodominant domains of protective antigen (PA) and lethal factor (LF), has been developed in the past and has been shown to confer enhanced protection against anthrax in mouse model when challenged with anthrax lethal toxin (LeTx). However, the immunological correlates for this chimeric antigen, both in terms of humoral as well as cell-mediated immune responses, have not been described in detail. To address this gap, we have determined the immunological responses both at humoral as well as cellular levels for the protection conferred by the novel chimeric antigen PALFn constructed in our laboratory in comparison to PA antigen. The biological functionality of the chimeric antigen was ascertained by the trypsin digestion assay. The trypsin cleavage activated the functionality of PALFn and rendered it to interact and bind with the LF molecule. Similarly, the LFn component in the chimera could independently interact and bind to the trypsin-activated wild-type PA. Further, it was observed that the PALFn-immunized mice sera could readily react to both PA and LF antigens while PA-immunized mice sera showed reaction to PA and PALFn alone and not to the individual LF antigen. The in vitro toxin neutralizing ability of PALFn antisera on macrophage cell line J774.1 was robust but with 1.3-fold lesser titer than PA-immunized antisera. PALFn-immunized mouse splenocytes showed a significant lymphocyte proliferation when stimulated with PALFn. There was a remarkable increase in the level of interleukin-2 (IL-2), interleukin-4 (IL-4), interleukin 10 (IL-10), interferon-γ (IFN- γ), and tumor necrosis factor α (TNFα) from PALFn- and PA-stimulated splenocytes. In addition, there was a significant increase in antigen-specific CD4+ and CD8+ T-cell counts from both PALFn- and PA-immunized mouse splenocytes. The results clearly demonstrate the ability of chimeric molecule PALFn in eliciting robust humoral and cell-mediated immune responses in mouse model that is parallel to the wild-type PA but has additional anti-LF antibody response. Considering the enhanced protection offered by the chimera PALFn, we can conclude that it can be a better alternative to the wild-type PA-based recombinant vaccine against anthrax.

Novel Chimpanzee/Human Monoclonal Antibodies That Neutralize Anthrax Lethal Factor, and Evidence for Possible Synergy with Anti-Protective Antigen Antibody

Three chimpanzee Fabs reactive with lethal factor (LF) of anthrax toxin were isolated and converted into complete monoclonal antibodies (MAbs) with human gamma1 heavy-chain constant regions. In a macrophage toxicity assay, two of the MAbs, LF10E and LF11H, neutralized lethal toxin (LT), a complex of LF and anthrax protective antigen (PA). LF10E has the highest reported affinity for a neutralizing MAb against LF (dissociation constant of 0.69 nM). This antibody also efficiently neutralized LT in vitro, with a 50% effective concentration (EC(50)) of 0.1 nM, and provided 100% protection of rats against toxin challenge with a 0.5 submolar ratio relative to LT. LF11H, on the other hand, had a slightly lower binding affinity to LF (dissociation constant of 7.4 nM) and poor neutralization of LT in vitro (EC(50) of 400 nM) and offered complete protection in vivo only at an equimolar or higher ratio to toxin. Despite this, LF11H, but not LF10E, provided robust synergistic protection when combined with MAb W1, which neutralizes PA. Epitope mapping and binding assays indicated that both LF10E and LF11H recognize domain I of LF (amino acids 1 to 254). Although domain I is responsible for binding to PA, neither MAb prevented LF from binding to activated PA. Although two unique MAbs could protect against anthrax when used alone, even more efficient and broader protection should be gained by combining them with anti-PA MAbs.

Human α-Defensins Inhibit Clostridium difficile Toxin B

Clostridium difficile toxins A and B are major virulence factors implicated in pseudomembranous colitis and antibiotic-associated diarrhea. The toxins are glucosyltransferases, which inactivate Rho proteins involved in cellular signaling. Human alpha-defensins as part of the innate immune system inactivate various microbial pathogens as well as specific bacterial exotoxins. Here, we studied the effects of alpha-defensins human neutrophil protein (HNP)-1, HNP-3, and enteric human defensin (HD)-5 on the activity of C difficile toxins A and B. Inactivation of C difficile toxins by alpha-defensins in vivo was monitored by microscopy, determination of the transepithelial resistance of CaCo-2 cell monolayers, and analysis of the glucosylation of Rac1 in toxin-treated cells. In vitro glucosylation was used to determine K(m) and median inhibitory concentration (IC(50)) values. Formation of defensin-toxin complexes was analyzed by precipitation and turbidity studies. Treatment of cells with human alpha-defensins caused loss of cytotoxicity of toxin B, but not of toxin A. Only alpha-defensins, but not beta-defensin-1 or cathelicidin LL-37, inhibited toxin B-catalyzed in vitro glucosylation of Rho guanosine triphosphatases in a competitive manner, increasing K(m) values for uridine 5'-diphosphate-glucose up to 10-fold. The IC(50) values for inhibition of toxin B-catalyzed glucosylation by the alpha-defensins were 0.6-1.5 micromol/L. At high concentrations, defensins (HNP-1 > or = 2 micromol/L) caused high-molecular-mass aggregates, comparable to Bacillus anthracis protective antigen and lethal factor. Our data indicate that toxin B interacts with high affinity with alpha-defensins and suggest that defensins may provide a defense mechanism against some types of clostridial glucosylating cytotoxins.

Qualification and performance characteristics of a quantitative enzyme-linked immunosorbent assay for human lgG antibodies to anthrax lethal factor antigen

The contribution of Bacillus anthracis lethal factor (LF)-specific immune responses to protection against anthrax disease in humans remains incompletely defined due, in part, to a paucity of qualified reagents and a lack of standardized serological assays. Toward this end, we have identified and characterized suitable positive quality control and standard reference sera and developed, optimized, and qualified an enzyme-linked immunosorbent assay (ELISA) to measure LF-binding IgG. Herein we describe the performance characteristics of this ELISA and propose criteria for its use in the detection and quantification of anti-LF IgG in human serum.

65. Protective Immunity Against Anthrax Lethal Toxin in Mice Immunized with an Ad-Based Vaccine Vector Expressing Lethal Factor

Top of pageAbstract Dissemination of anthrax spores in a terrorism event could result in inhalational anthrax, an infection that resulted in 45% mortality in the recent US anthrax attacks. The focus of this study is to use adenovirus gene transfer vectors as a rapidly-acting highly-defined anthrax vaccine. Bacillus anthracis, the etiologic agent of anthrax, produces two exotoxins that are associated with the fatal pathophysiology of the disease, the most important of which is lethal toxin, composed of protective antigen (PA) and lethal factor (LF). Although PA has been the focus of prior vaccine development with Ad vectors and a variety of delivery systems, there is evidence suggesting that LF may also be an excellent target for an anti-anthrax vaccine. In this context, we have developed two LF-based anti-anthrax vaccines, one using Ad5 to express wild type LF (AdsechLF) and the second using Ad5 to express a mutant form of LF that is not toxic due to modification of the active site (AdsechLFmut). Both vectors were designed to secrete the LF antigen, and in both, the LF sequence was modified with codons optimized for mammalian expression. The LF-specific immune responses in mice immunized with these vectors were analyzed and compared to the PA-specific immune responses elicited in mice immunized with AdsechPA, an Ad-based anti-anthrax vaccine expressing PA. Groups of 5 BALB/c mice were immunized intramuscularly with 109 particle units (pu) AdsechLF, AdsechLFmut or AdsechPA. As negative controls, one group of mice was immunized with AdNull, an isogenic vector with no transgene, and one group of mice was naive. Serum IgG titers were measured by ELISA. Maximal anti-LF IgG titers were reached at wk 4 in both groups receiving LF-based vectors (AdsechLF 3400, AdsechLFmut 12,400). No anti-LF IgG titers were detectable in AdsechPA, AdNull-immunized mice or in naive mice. Consistent with the vectors stimulating antigen-specific IgG titers, the immunization also protected mice against a fatal challenge with lethal toxin. In contrast to AdNull-immunized mice and naive mice, which did not survive the challenge, immunization with all Ad-based vaccine vectors resulted in significant protection (AdsechLF 90%, AdsechLFmut, 100%, AdsechPA 100%). These observations demonstrate that lethal factor is an excellent candidate for an adenovirus-based vaccine against anthrax infection. Interestingly, a form of lethal factor that has been rendered non-functional as a toxin functions equally well as an anti-anthrax toxin immunogen as lethal factor, suggesting that the AdsechLFmut may be the best candidate as a safe, effective anthrax vaccine.

Protection against anthrax lethal toxin challenge by genetic immunization with a plasmid encoding the lethal factor protein.

The ability of genetic vaccination to protect against a lethal challenge of anthrax toxin was evaluated. BALB/c mice were immunized via gene gun inoculation with eucaryotic expression vector plasmids encoding either a fragment of the protective antigen (PA) or a fragment of lethal factor (LF). Plasmid pCLF4 contains the N-terminal region (amino acids [aa] 10 to 254) of Bacillus anthracis LF cloned into the pCI expression plasmid. Plasmid pCPA contains a biologically active portion (aa 175 to 764) of B. anthracis PA cloned into the pCI expression vector. One-micrometer-diameter gold particles were coated with plasmid pCLF4 or pCPA or a 1:1 mixture of both and injected into mice via gene gun (1 microg of plasmid DNA/injection) three times at 2-week intervals. Sera were collected and analyzed for antibody titer as well as antibody isotype. Significantly, titers of antibody to both PA and LF from mice immunized with the combination of pCPA and pCLF4 were four to five times greater than titers from mice immunized with either gene alone. Two weeks following the third and final plasmid DNA boost, all mice were challenged with 5 50% lethal doses of lethal toxin (PA plus LF) injected intravenously into the tail vein. All mice immunized with pCLF4, pCPA, or the combination of both survived the challenge, whereas all unimmunized mice did not survive. These results demonstrate that DNA-based immunization alone can provide protection against a lethal toxin challenge and that DNA immunization against the LF antigen alone provides complete protection.