Sortase C-mediated anchoring of BasI to the cell wall envelope of Bacillus anthracis

Vegetative forms of Bacillus anthracis replicate in tissues of an infected host and precipitate lethal anthrax disease. Upon host death, bacilli form dormant spores that contaminate the environment, thereby gaining entry into new hosts where spores germinate and once again replicate as vegetative forms. We show here that sortase C, an enzyme that is required for the formation of infectious spores, anchors BasI polypeptide to the envelope of predivisional sporulating bacilli. BasI anchoring to the cell wall requires the active site cysteine of sortase C and an LPNTA motif sorting signal at the C-terminal end of the BasI precursor. The LPNTA motif of BasI is cleaved between the threonine (T) and the alanine (A) residue; the C-terminal carboxyl group of threonine is subsequently amide linked to the side chain amino group of diaminopimelic acid within the wall peptides of B. anthracis peptidoglycan.     

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.     

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.     

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.     

Targeting of Bacillus anthracis interaction factors for human macrophages using two-dimensional gel electrophoresis

Bacillus anthracis, a gram-positive, endospore-forming, aerobic rod-shaped bacterium, interacts with macrophages at various stages of the disease. Spore germination and the outgrowth of vegetative bacilli are crucial steps enabling the bacteria to proliferate actively and to synthesize the virulence factors leading to a massive septicemia. In this study, we performed a proteomic analysis and MALDI-TOF/MS were carried out to identify proteins using human macrophages infected with the spores of B. anthracis live-Sterne or inactivated-Sterne. We identified 21 proteins which are related to the infection of B. anthracis spores on human macrophages at the early stage events. These proteins function in processes such as cytoskeleton regulation, apoptosis, cell division, and protein degradation. Proteins such as PAK 2 revealed a relationship to apoptosis in human macrophages. These proteins play an important role in the macrophage survival and death on human macrophages with infected B. anthracis spores.     

Interferon-inducible CXC chemokines directly contribute to host defense against inhalational anthrax in a murine model of infection

Chemokines have been found to exert direct, defensin-like antimicrobial activity in vitro, suggesting that, in addition to orchestrating cellular accumulation and activation, chemokines may contribute directly to the innate host response against infection. No observations have been made, however, demonstrating direct chemokine-mediated promotion of host defense in vivo. Here, we show that the murine interferon-inducible CXC chemokines CXCL9, CXCL10, and CXCL11 each exert direct antimicrobial effects in vitro against Bacillus anthracis Sterne strain spores and bacilli including disruptions in spore germination and marked reductions in spore and bacilli viability as assessed using CFU determination and a fluorometric assay of metabolic activity. Similar chemokine-mediated antimicrobial activity was also observed against fully virulent Ames strain spores and encapsulated bacilli. Moreover, antibody-mediated neutralization of these CXC chemokines in vivo was found to significantly increase host susceptibility to pulmonary B. anthracis infection in a murine model of inhalational anthrax with disease progression characterized by systemic bacterial dissemination, toxemia, and host death. Neutralization of the shared chemokine receptor CXCR3, responsible for mediating cellular recruitment in response to CXCL9, CXCL10, and CXCL11, was not found to increase host susceptibility to inhalational anthrax. Taken together, our data demonstrate a novel, receptor-independent antimicrobial role for the interferon-inducible CXC chemokines in pulmonary innate immunity in vivo. These data also support an immunomodulatory approach for effectively treating and/or preventing pulmonary B. anthracis infection, as well as infections caused by pathogenic and potentially, multi-drug resistant bacteria including other spore-forming organisms.     

Protective effect of Bacillus anthracis surface protein EA1 against anthrax in mice

Bacillus anthracis spores germinate to vegetative forms in host cells, and produced fatal toxins. A toxin-targeting prophylaxis blocks the effect of toxin, but may allow to grow vegetative cells which create subsequent toxemia. In this study, we examined protective effect of extractable antigen 1 (EA1), a major S-layer component of B. anthracis, against anthrax. Mice were intranasally immunized with recombinant EA1, followed by a lethal challenge of B. anthracis spores. Mucosal immunization with EA1 resulted in a significant level of anti-EA1 antibodies in feces, saliva and serum. It also delayed the onset of anthrax and remarkably decreased the mortality rate. In addition, the combination of EA1 and protective antigen (PA) protected all immunized mice from a lethal challenge with B. anthracis spores. The numbers of bacteria in tissues of EA1-immunized mice were significantly decreased compared to those in the control and PA alone-immunized mice. Immunity to EA1 might contribute to protection at the early phase of infection, i.e., before massive multiplication and toxin production by vegetative cells. These results suggest that EA1 is a novel candidate for anthrax vaccine and provides a more effective protection when used in combination with PA.     

Murine splenocytes produce inflammatory cytokines in a MyD88-dependent response to Bacillus anthracis spores

Bacillus anthracis is a sporulating Gram-positive bacterium that causes the disease anthrax. The highly stable spore is the infectious form of the bacterium that first interacts with the prospective host, and thus the interaction between the host and spore is vital to the development of disease. We focused our study on the response of murine splenocytes to the B. anthracis spore by using paraformaldehyde-inactivated spores (FIS), a treatment that prevents germination and production of products associated with vegetative bacilli. We found that murine splenocytes produce IL-12 and IFN-gamma in response to FIS. The IL-12 was secreted by CD11b cells, which functioned to induce the production of IFN-gamma by CD49b (DX5) NK cells. The production of these cytokines by splenocytes was not dependent on TLR2, TLR4, TLR9, Nod1, or Nod2; however, it was dependent on the signalling adapter protein MyD88. Unlike splenocytes, Nod1- and Nod2-transfected HEK cells were activated by FIS. Both IL-12 and IFN-gamma secretion were inhibited by treatment with B. anthracis lethal toxin. These observations suggest that the innate immune system recognizes spores with a MyD88-dependent receptor (or receptors) and responds by secreting inflammatory cytokines, which may ultimately aid in resisting infection.     

Human neutrophils kill Bacillus anthracis

Bacillus anthracis spores cause natural infections and are used as biological weapons. Inhalation infection with B. anthracis, the etiological agent of anthrax, is almost always lethal, yet cutaneous infections usually remain localized and resolve spontaneously. Neutrophils are typically recruited to cutaneous but seldom to other forms of anthrax infections, raising the possibility that neutrophils kill B. anthracis. In this study we infected human neutrophils with either spores or vegetative bacteria of a wild-type strain, or strains, expressing only one of the two major virulence factors. The human neutrophils engulfed B. anthracis spores, which germinated intracellularly and were then efficiently killed. Interestingly, neutrophil killing was independent of reactive oxygen species production. We fractionated a human neutrophil granule extract by high-performance liquid chromatography and identified alpha-defensins as the component responsible for B. anthracis killing. These data suggest that the timely recruitment of neutrophils can control cutaneous infections and possibly other forms of B. anthracis infections, and that alpha-defensins play an important role in the potent anti-B. anthracis activity of neutrophils.     

Surface protein IsdC and Sortase B are required for heme-iron scavenging of Bacillus anthracis

Bacillus anthracis, the spore-forming agent of anthrax, requires iron for growth and is capable of scavenging heme-iron during infection. We show here that the B. anthracis iron-regulated surface determinants (isd) locus encompasses isdC, specifying a heme-iron binding surface protein. Anchoring of IsdC to the cell wall envelopes of vegetative bacilli requires srtB, which encodes sortase B. Purified sortase B cleaves IsdC between the threonine and the glycine of its NPKTG motif sorting signal. B. anthracis variants lacking either isdC or srtB display defects in heme-iron scavenging, suggesting that IsdC binding to heme-iron in the cell wall envelope contributes to bacterial uptake of heme.     

In vivo protective role of human group IIa phospholipase A2 against experimental anthrax

Anthrax is an acute disease caused by Bacillus anthracis. Some animal species are relatively resistant to anthrax infection. This trait has been correlated to the extent of the local inflammatory reaction, suggesting innate immunity to be the first line of defense against B. anthracis infection in nonimmunized hosts. Group IIA secreted phospholipase A2 (sPLA2-IIA) is produced in particular by macrophages and possesses potent antibacterial activity especially against Gram-positive bacteria. We have previously shown in vitro that sPLA2-IIA kills both germinated B. anthracis spores and encapsulated bacilli. Here we show that sPLA2-IIA plays in vivo a protective role against experimental anthrax. Transgenic mice expressing human sPLA2-IIA are resistant to B. anthracis infection. In addition, in vivo administration of recombinant human sPLA2-IIA protects mice against B. anthracis infection. The protective effect was observed both with a highly virulent encapsulated nontoxinogenic strain and a wild-type encapsulated toxinogenic strain, showing that toxemia did not hinder the sPLA2-IIA-afforded protection. sPLA2-IIA, a natural component of the immune system, may thus be considered a novel therapeutic agent to be used in adjunct with current therapy for treating anthrax. Its anthracidal activity would be effective even against strains resistant to multiple antibiotics.     

Poly-γ-d-glutamic acid and protective antigen conjugate vaccines induce functional antibodies against the protective antigen and capsule of Bacillus anthracis in guinea-pigs and rabbits

Anthrax is a lethal infectious disease caused by the spore-forming Bacillus anthracis . The two major virulence factors of B. anthracis are exotoxin and the poly-γ- d -glutamic acid (PGA) capsule. The three components of the exotoxin, protective antigen (PA), lethal factor and edema factor act in a binary combination, which results in massive edema and organ failure in the progress of anthrax disease. The antiphagocytic PGA capsule disguises the bacilli from immune surveillance and allows unimpeded growth of bacilli in the host. Because PA can elicit a protective immune response, it has been a target of the anthrax vaccine. In addition to PA, efforts have been made to include PGA as a component of the anthrax vaccine. In this study, we report that PA–PGA conjugates induce expressions of anti-PA, anti-PGA and toxin-neutralizing antibodies in guinea-pigs and completely protect guinea-pigs against a 50 × LD₅₀ challenge with fully virulent B. anthracis spores. Polyclonal rabbit antisera produced against either PA or ovalbumin conjugated to a PGA-15mer offer a partial passive protection to guinea-pigs against B. anthracis infection, indicating that anti-PGA antibodies play a protective role. Our results demonstrate that PA–PGA conjugate vaccines are effective in the guinea-pig model, in addition to the previously reported mouse model.     

Monoclonal antibodies against spore antigens of Bacillus anthracis

Abstract A murine monoclonal antibody produced against heat inactivated spores of Bacillus anthracis Ames, reacted with live or inactivated spores of several anthrax strains in indirect immunofluorescence (IF) tests. The reactive anthrax strain gave only a moderate degree of reaction. No staining of anthrax vegetative cells was observed. The monoclonal did not react with spores of non-anthrax Bacillus strains that gave cross reactions with mouse hyperimmune antiserum raised against Ames spores. The staining of individual spores in B. anthracis preparations was more heterogeneous with the monoclonal antibody than with the hyperimmune serum. Evidence is produced that the epitope for this monoclonal is not stable during long-term storage of inactivated spore preparations, and is not fully available for reaction with antibody until late in spore maturation. The monoclonal did not react by immunoblotting (Western blotting) of spore extracts.     

炭疽芽胞杆菌疫苗研究进展

炭疽芽胞杆菌引起的炭疽病死亡率非常高 ,当前的疫苗具有效力不稳定、对吸入性炭疽的保护率低、免疫程序繁琐、存在副作用等缺点。近年来人们在改造传统疫苗的同时又有一些新的发现 ,如保护性抗原 (PA)的抗体在体内可杀死芽胞 ;通过粘膜免疫能够诱导机体分泌IgA抗体 ;抗多聚谷氨酸 (γ D PGA)抗体可以同炭疽杆菌的繁殖体作用 ,从而杀死繁殖体 ;寻找到新的免疫原。DNA疫苗、活载体疫苗的出现为新一代安全、免疫程序简单、具更高保护率的疫苗奠定了基础     

Monoclonal antibodies against spore antigens of Bacillus anthracis

A murine monoclonal antibody produced against heat inactivated spores of Bacillus anthracis Ames, reacted with live or inactivated spores of several anthrax strains in indirect immunofluorescence (IF) tests. The reactive anthrax strain gave only a moderate degree of reaction. No staining of anthrax vegetative cells was observed. The monoclonal did not react with spores of non-anthrax Bacillus strains that gave cross reactions with mouse hyperimmune antiserum raised against Ames spores. The staining of individual spores in B. anthracis preparations was more heterogeneous with the monoclonal antibody than with the hyperimmune serum. Evidence is produced that the epitope for this monoclonal is not stable during long-term storage of inactivated spore preparations, and is not fully available for reaction with antibody until late in spore maturation. The monoclonal did not react by immunoblotting (Western blotting) of spore extracts. A monoclonal antibody produced against Ames spore extracts reacted with about 1% of Ames spores in IF tests, but not reproducible reactions with other anthrax strains were recorded. This monoclonal interacted with three bands in Western blots of anthrax spore extracts.     

BslA,the S‐layer adhesin of B. anthracis,is a virulence factor for anthrax pathogenesis

Microbial pathogens use adhesive surface proteins to bind to and interact with host tissues, events that are universal for the pathogenesis of infectious diseases. A surface adhesin of Bacillus anthracis, the causative agent of anthrax, required to mediate these steps has not been discovered. Previous work identified BslA, an S‐layer protein, to be necessary and sufficient for adhesion of the anthrax vaccine strain, Bacillus anthracis Sterne, to host cells. Here we asked whether encapsulated bacilli require BslA for anthrax pathogenesis in guinea pigs. Compared with the highly virulent parent strain B. anthracis Ames, bslA mutants displayed a dramatic increase in the lethal dose and in mean time‐to‐death. Whereas all tissues of animals infected with B. anthracis Ames contained high numbers of bacilli, only few vegetative forms could be recovered from internal organs of animals infected with the bslA mutant. Surface display of BslA occurred at the poles of encapsulated bacilli and enabled the binding of vegetative forms to host cells. Together these results suggest that BslA functions as the surface adhesin of the anthrax pathogen B. anthracis strain Ames.     

Modulation of cytokine production and enhancement of cell viability by TLR7 and TLR9 ligands during anthrax infection of macrophages

Inhalation of Bacillus anthracis, a bioterrorism agent, results in a high mortality rate despite appropriate antibiotic therapy. Macrophages appear to be a key factor in B. anthracis pathogenesis. The burst of pro-inflammatory cytokines from macrophages could be a major cause of death in anthrax. However, preactivation of Toll-like receptors (TLRs) could modify the host response. TLR ligands stimulate the release of activating cytokines but may also down-modulate the subsequent deleterious cytokine response to pathogens. We developed a cell culture model to measure macrophage responses to B. anthracis spores and bacilli. We found that germination from spores to bacilli produced a substantial stimulus for the secretion of the cytokines IL-6, TNF-alpha, IL-10, and IL-12 p40. Our studies showed that pretreatment of mouse macrophages with the TLR9 ligand ISS-1018, or the TLR7 ligands R-848 and IT-37, results in a substantial decrease in the subsequent secretion of IL-6 and TNF-alpha in response to B. anthracis infection of macrophages. Furthermore, the TLR7 and TLR9 ligands significantly decreased anthrax-induced cytotoxicity in the macrophages. These findings suggest that TLR ligands may contribute to the enhancement of innate immunity in B. anthracis infection by suppressing potentially deleterious pro-inflammatory cytokine responses and by improving macrophage viability.     

Anthrax toxin receptor 2 mediates Bacillus anthracis killing of macrophages following spore challenge

Initiation of inhalation anthrax is believed to involve phagocytosis of Bacillus anthracis spores by alveolar macrophages, followed by spore germination within the phagolysosome. In order to establish a systemic infection, it is predicted that bacilli then escape from the macrophage and replicate extracellularly. Mechanisms utilized by B. anthracis to escape from the macrophage are not well characterized, but a role for anthrax toxin has been proposed. Here we report the isolation of an anthrax toxin-resistant cell line (R3D) following chemical mutagenesis of toxin-sensitive RAW 264.7 murine macrophage cells. Both R3D and RAW 264.7 cells phagocytize spores of a B. anthracis Sterne strain. However, RAW 264.7 cells are killed following spore challenge, whereas R3D cells survive. Resistance to toxin and spore challenge correlates with loss of expression of anthrax toxin receptor 2 (ANTXR2/CMG-2). When R3D cells are complemented with cDNA encoding either murine ANTXR2 or human anthrax toxin receptor 1 (ANTXR1/TEM-8), toxin and spore challenge susceptibility are restored, indicating that over-expression of either ANTXR can confer susceptibility to anthrax spore challenge. Taken together, these results indicate that anthrax toxin expression by the germinated spore enables B. anthracis killing of the macrophage from within.     

炭疽杆菌检测方法的研究现状与展望

炭疽是严重威胁人类健康的烈性传染病,其病原体为炭疽芽孢杆菌。炭疽芽孢杆菌在我国公布的《人间传染的病原微生物名录》中被列为第二类病原微生物(高致病性病原微生物),其芽孢可作为生物战剂和生物恐怖的原材料,因此,发展灵敏、高效的炭疽杆菌检测方法十分重要和紧迫。按检测的靶标分类,针对炭疽杆菌的检测方法主要有四大类:针对炭疽杆菌芽孢的检测方法,针对细菌繁殖体的检测方法,针对炭疽杆菌基因的检测方法和针对炭疽毒素蛋白的检测方法。其中,针对炭疽杆菌芽孢和细菌繁殖体的检测已经有比较成熟的方法,但其在特异性以及临床的实用性方面难以令人满意;针对炭疽杆菌基因的检测技术在特异性和灵敏度上有较大的提高,但在临床诊断等方面还有欠缺;而针对炭疽毒素蛋白的检测技术的发展,使得直接对炭疽杆菌的主要致病因子的检测成为可能,这对于临床诊断以及流行病学研究具有重要意义。本文对当前炭疽杆菌检测方法的最新进展做了简要的归纳,关注了不同检测方法的适用范围和检测能力,并展望了相关领域的发展趋势,希望能为从事炭疽杆菌检测方法研究的同行提供参考和帮助。