Induction of autophagy by anthrax lethal toxin

Autophagy is an evolutionary conserved intracellular process whereby cells break down long-lived proteins and organelles. Accumulating evidences suggest increasing physiological significance of autophagy in pathogenesis of infectious diseases. Anthrax lethal toxin (LT) exerts its influence on numerous cells and herein, we report a novel effect of LT-induced autophagy on mammalian cells. Several autophagy biochemical markers including LC3-II conversion, increased punctuate distribution of GFP-LC3 and development of acidic vesicular organelles (AVO) were detected in cells treated with LT. Analysis of individual LT component revealed a moderate increase in LC3-II conversion for protective antigen-treated cells, whereas the LC3-II level in lethal factor-treated cells remained unchanged. In addition, our preliminary findings suggest a protective role of autophagy in LT intoxication as autophagy inhibition resulted in accelerated cell death. This study presents a hitherto undescribed effect of LT-induced autophagy on cells and provides the groundwork for future studies on the implication of autophagy in anthrax pathogenesis.     

Crystallographic studies of the anthrax lethal toxin

Anthrax lethal toxin comprises two proteins: protective antigen (PA; MW 83 kDa) and lethal factor (LF; MW 87 kDa). We have recently determined the crystal structure of the 735-residue PA in its monomeric and heptameric forms ( Petosa et al . 1997 ). It bears no resemblance to other bacterial toxins of known three-dimensional structure, and defines a new structural class which includes homologous toxins from other Gram-positive bacteria. We have proposed a model of membrane insertion in which the water-soluble heptamer undergoes a substantial pH-induced conformational change involving the creation of a 14-stranded β-barrel. Recent work by Collier's group ( Benson et al . 1998 ) lends strong support to our model of membrane insertion. 'Lethal factor' is the catalytic component of anthrax lethal toxin. It binds to the surface of the cell-bound PA heptamer and, following endocytosis and acidification of the endosome, translocates to the cytosol. We have made substantial progress towards an atomic resolution crystal structure of LF. Progress towards a structure of the 7:7 translocation complex between the PA heptamer and LF will also be discussed.     

Cellular and systemic effects of anthrax lethal toxin and edema toxin

Anthrax lethal toxin (LT) and edema toxin (ET) are the major virulence factors of anthrax and can replicate the lethality and symptoms associated with the disease. This review provides an overview of our current understanding of anthrax toxin effects in animal models and the cytotoxicity (necrosis and apoptosis) induced by LT in different cells. A brief reexamination of early historic findings on toxin in vivo effects in the context of our current knowledge is also presented.     

Validation of the anthrax lethal toxin neutralization assay.

A validation of the performance characteristics of a toxin neutralization assay is presented. This in vitro assay measures the functional ability of antisera, containing antibodies to anthrax lethal toxin, to specifically protect J774A.1 cells against Bacillus anthracis lethal toxin cytotoxicity. This colormetric assay is based upon the reduction of MTT by living cells. Human and rabbit antisera produced against anthrax vaccine absorbed (AVA) were used to validate the assay. Results showed a high level of repeatability and reproducibility, particularly for a bio-assay. Inter-assay variability in absorbance values was the most prominent negative finding however, an acceptable level was demonstrated with a ratio [neutralization ratio (NR)] of the test serum 50% effective dose (ED(50)) to the reference standard ED(50). Accuracy was maintained, even in samples with minimal neutralizing capacity, and linearity was noted when sample dilutions resulted in accurate prediction of the Y(max)and Y(min). Specificity tests demonstrated that normal sera did not have an observable effect on the ability of the reference standard to neutralize toxin. The assay remained stable against time, temperature, and freeze/thaw effects on the reference standards, but not on the toxin. The assay also remained stable against media and solution storage effects. Cell passage number and cell plating density were two critical parameters identified during the robustness studies that may be responsible for inter-assay variability in absorbance values. The work was performed in accordance with the FDA's Bioanalytical Method Validation Guidance for Industry and the FDA's Good Laboratory Practice for Nonclinical Laboratory Studies (21 CFR Part 58).     

Effects of anthrax lethal toxin on human primary keratinocytes

Aims: To investigate the effects of anthrax lethal toxin (LeTx) on human primary keratinocytes. Methods and Results: We show here that human primary keratinocytes are resistant to LeTx‐triggered cytotoxicity. All but one of the MEKs (mitogen‐activated protein kinase kinases) are cleaved within 3 h, and the cleavage of MEKs in keratinocytes leads to their subsequent proteasome‐mediated degradation at different rates. Moreover, LeTx reduced the concentration of several cytokines except RANTES in culture. Conclusions: Our results indicate that primary keratinocytes are resistant to LeTx cytotoxicity, and MEK cleavage does not correlate with LeTx cytotoxicity. Although LeTx is considered as an anti‐inflammatory agent, it upregulates RANTES. Significance and Impact of the Study: According to a current view, the action of LeTx results in downregulation of the inflammatory response, as evidenced by diminished expression of several inflammatory biomarkers. Paradoxically, LeTx has been reported to attract neutrophils to cutaneous infection sites. This paper, which shows that RANTES, a chemoattractant for immune cells, is upregulated after exposure of keratinocytes to LeTx, although a number of other markers of the inflammatory response are downregulated. Our results might explain why the exposure of keratinocytes to LeTx results in the recruitment of neutrophils to cutaneous infection sites, while the expression of several inflammatory biomarkers is diminished.     

Binding and cell intoxication studies of anthrax lethal toxin

Anthrax lethal toxin (LT) is a major virulence factor of Bacillus anthracis. The vast majority of the anthrax toxin-related literature describes the assembly of LT as a cell-dependent process. However, some reports have provided evidence for the existence of a fully assembled LT, either in vitro or in the bloodstream of anthrax-infected animals. To follow up on this work, we present studies on fully-assembled LT. We first demonstrate facile and cell-free assembly and purification of LT. We then show that fully assembled LT binds an anthrax toxin receptor with almost 100-fold higher affinity than the protective antigen (PA) alone. Quantitative cell intoxication assays were used to determine the LD₅₀ (lethal dose 50) for LT. The cell-binding studies revealed that LT binds mammalian cells using a different mode from PA. Even when PA-specific receptors were blocked, fully assembled LT was able to bind the cell surface. Our studies support the existing evidence that LT fully assembles in the blood stream and can bind and intoxicate mammalian cells with very high affinity and efficacy. More importantly, the data presented here invoke the possibility that LT may bind cells in a receptor-independent fashion, or recognize receptors that do not interact with PA. Hence, blood borne LT may emerge as a novel therapeutic target for combating anthrax.     

Deletion mutants of protective antigen that inhibit anthrax toxin both in vitro and in vivo

The anthrax toxin complex is primarily responsible for most of the symptoms of anthrax. This complex is composed of three proteins, anthrax protective antigen, anthrax edema factor, and anthrax lethal factor. The three proteins act in binary combination of protective antigen plus edema factor (edema toxin) and protective antigen plus lethal factor (lethal toxin) that paralyze the host defenses and eventually kill the host. Both edema factor and lethal factor are intracellularly acting proteins that require protective antigen for their delivery into the host cell. In this study, we show that deletion of certain residues of protective antigen results in variants of protective antigen that inhibit the action of anthrax toxin both in vitro and in vivo. These mutants protected mice against both lethal toxin and edema toxin challenge, even when injected at a 1:8 ratio relative to the wild-type protein. Thus, these mutant proteins are promising candidates that may be used to neutralize the action of anthrax toxin.     

Proteome analysis of mouse macrophages treated with anthrax lethal toxin

Anthrax toxin produced by Bacillus anthracis is a tripartite toxin comprising of protective antigen (PA), lethal factor (LF) and edema factor (EF). PA is the receptor-binding component, which facilitates the entry of LF or EF into the cytosol. EF is a calmodulin-dependent adenylate cyclase that causes edema whereas LF is a zinc metalloprotease and leads to necrosis of macrophages. It is also important to note that the exact mechanism of LF action is still unclear. With this view in mind, in the present study, we investigated a proteome wide effect of anthrax lethal toxin (LT) on mouse macrophage cells (J774A.1). Proteome analysis of LT-treated and control macrophages revealed 41 differentially expressed protein spots, among which phosphoglycerate kinase I, enolase I, ATP synthase (beta subunit), tubulin beta2, gamma-actin, Hsp70, 14-3-3 zeta protein and tyrosine/tryptophan-3-monooxygenase were found to be down-regulated, while T-complex protein-1, vimentin, ERp29 and GRP78 were found to be up-regulated in the LT-treated macrophages. Analysis of up- and down-regulated proteins revealed that primarily the stress response and energy generation proteins play an important role in the LT-mediated macrophage cell death.     

Guanidinylated 2,5-dideoxystreptamine derivatives as anthrax lethal factor inhibitors

Anthrax lethal factor is a Zn(2+)-dependent metalloprotease and the key virulence factor of tripartite anthrax toxin secreted by Bacillus anthracis, the causative agent of anthrax. A series of guanidinylated 2,5-dideoxystreptamine derivatives were designed and synthesized as inhibitors of lethal factor, some of which show strong inhibitory activity against lethal factor in an in vitro FRET assay. Preparation and structure-activity relationships of these compounds are presented.     

Macrophages are sensitive to anthrax lethal toxin through an acid-dependent process

Anthrax lethal toxin, which consists of two proteins, protective antigen and lethal factor, is lethal for experimental animals. This study describes the first in vitro system demonstrating lethality of the toxin. Mouse peritoneal macrophages are killed within 1 h of exposure to the toxin. Neither protein component alone shows any toxic activity. The minimal effective concentration of protective antigen and lethal factor was approximately equal to 10(-2) and approximately equal to 10(-3) micrograms/ml, respectively. None of the several established cell lines examined was killed. Cells could be completely protected from the toxin by pretreatment with agents, such as amines or monensin, which dissipate intracellular proton gradients and raise the pH of intracellular vesicles. This protection was reversible and could be overcome by lowering the intravesicular pH. Antitoxin added after preincubation with amines was unable to protect cells subsequently exposed to low pH treatment. These results suggest that anthrax lethal toxin requires passage through an acidic endocytic vesicle in order to exert its toxic effect within the cytosol.     

Functional mapping of anthrax toxin lethal factor by in-frame insertion mutagenesis

Linker insertion mutagenesis was employed to create structural disruptions of the lethal factor (LF) protein of anthrax toxin to map functional domains. A dodecameric linker was inserted at 17 blunt end restriction enzyme sites throughout the gene. Paired MluI restriction sites within the linker allowed the inserts to be reduced from four to two amino acids. Shuttle vectors containing the mutated genes were transformed into the avirulent Bacillus anthracis UM23C1-1 for expression and secretion of the gene products. Mutations at five sites in the central one-third of the sequence made the protein unstable, and purified protein could not be obtained. Mutated LF proteins with insertions at the other sites were purified and assessed for toxic activity in a macrophage lysis assay and for their ability to bind to the protective antigen (PA) component of anthrax toxin, the receptor binding moiety. Most insertions located in the NH2-terminal one-third of the LF protein eliminated both toxicity and binding to PA, while all four insertions in the COOH-terminal one-third of the protein eliminated toxicity without affecting binding to PA. These data support the hypothesis that the NH2-terminal domain contains the structures required for binding to PA and the COOH-terminal domain contains the putative catalytic domain of LF.     

Protein expression pattern of murine macrophages treated with anthrax lethal toxin

Anthrax lethal toxin (LeTx; a combination of protective antigen and lethal factor) secreted by the vegetative cells of Bacillus anthracis is cytotoxic for certain macrophage cell lines. The role of LeTx in mediating these effects is complicated largely due to the difficulty in identifying and assigning functions to the affected proteins. To analyze the protein profile of murine macrophages treated with LeTx, we employed two-dimensional polyacrylamide gel electrophoresis and MALDI-TOF MS, and interpreted the peptide mass fingerprint data relying on the ProFound database. Among the differentially expressed spots, cleaved mitogen-activated protein kinase kinase 1 acting as a negative element in the signal transduction pathway, and glucose-6-phosphate dehydrogenase playing a role in the protection of cells from hyperproduction of active oxygen were up-regulated in the LeTx-treated macrophages.     

Stop the killer: how to inhibit the anthrax lethal factor metalloprotease

Inhalation of anthrax spores rapidly develops into a deadly bacteraemia and toxaemia. Anthrax toxins include the lethal factor (LF), a mitogen-activated protein kinase (MAPK)-kinase-specific metalloprotease, which acts in the cell cytosol and plays a major part in anthrax pathogenesis. Recently, screening methods have led to the discovery of LF inhibitors that are membrane permeable. This will pave the way for design of novel anthrax therapeutics that are capable of inhibiting the metalloprotease activity of LF in vivo.     

Matrix metalloproteinase-activated anthrax lethal toxin demonstrates high potency in targeting tumor vasculature

Anthrax lethal toxin (LT), a virulence factor secreted by Bacillus anthracis, is selectively toxic to human melanomas with the BRAF V600E activating mutation because of its proteolytic activities toward the mitogen-activated protein kinase kinases (MEKs). To develop LT variants with lower in vivo toxicity and high tumor specificity, and therefore greater potential for clinical use, we generated a mutated LT that requires activation by matrix metalloproteinases (MMPs). This engineered toxin was less toxic than wild-type LT to mice because of the limited expression of MMPs by normal cells. Moreover, the systemically administered toxin produced greater anti-tumor effects than wild-type LT toward human xenografted tumors. This was shown to result from its greater bioavailability, a consequence of the limited uptake and clearance of the modified toxin by normal cells. Furthermore, the MMP-activated LT had very potent anti-tumor activity not only to human melanomas containing the BRAF mutation but also to other tumor types, including lung and colon carcinomas regardless of their BRAF status. Tumor histology and in vivo angiogenesis assays showed that this anti-tumor activity is due largely to the indirect targeting of tumor vasculature and angiogenic processes. Thus, even tumors genetically deficient in anthrax toxin receptors were still susceptible to the toxin therapy in vivo. Moreover, the modified toxin also displayed lower immunogenicity compared with the wild-type toxin. All these properties suggest that this MMP-activated anti-tumor toxin has potential for use in cancer therapy.     

Sublethal doses of anthrax lethal toxin on the suppression of macrophage phagocytosis

Background

Lethal toxin (LT), the major virulence factor produced by Bacillus anthracis, has been shown to suppress the immune system, which is beneficial to the establishment of B. anthracis infections. It has been suggested that the suppression of MEK/MAPK signaling pathways of leukocytes contributes to LT-mediated immunosuppressive effects. However, the involvement of MAPK independent pathways has not been clearly elucidated; nor has the crucial role played by LT in the early stages of infection. Determining whether LT exerts any pathological effects before being enriched to an MEK inhibitory level is an important next step in the furtherance of this field.

Methodology/Principal Findings

Using a cell culture model, we determined that low doses of LT inhibited phagocytosis of macrophages, without influencing MAPK pathways. Consistent low doses of LT significantly suppressed bacterial clearance and enhanced the mortality of mice with bacteremia, without suppressing the MEK1 of splenic and peripheral blood mononuclear cells.

Conclusion/Significance

These results suggest that LT suppresses the phagocytes in a dose range lower than that required to suppress MEK1 in the early stages of infection.     

A receptor-based switch that regulates anthrax toxin pore formation

Cellular receptors can act as molecular switches, regulating the sensitivity of microbial proteins to conformational changes that promote cellular entry. The activities of these receptor-based switches are only partially understood. In this paper, we sought to understand the mechanism that underlies the activity of the ANTXR2 anthrax toxin receptor-based switch that binds to domains 2 and 4 of the protective antigen (PA) toxin subunit. Receptor-binding restricts structural changes within the heptameric PA prepore that are required for pore conversion to an acidic endosomal compartment. The transfer cross-saturation (TCS) NMR approach was used to monitor changes in the heptameric PA-receptor contacts at different steps during prepore-to-pore conversion. These studies demonstrated that receptor contact with PA domain 2 is weakened prior to pore conversion, defining a novel intermediate in this pathway. Importantly, ANTXR2 remained bound to PA domain 4 following pore conversion, suggesting that the bound receptor might influence the structure and/or function of the newly formed pore. These studies provide new insights into the function of a receptor-based molecular switch that controls anthrax toxin entry into cells.     

Knock-on effect of anthrax lethal toxin on macrophages potentiates cytotoxicity to endothelial cells

Herein we report the knock-on cytotoxic effect of lethal toxin (LeTx) on human umbilical vascular endothelial cells (HUVECs). HUVECs were treated either directly with LeTx or indirectly with LeTx conditioned medium (LeTxCM) prepared from RAW264.7 macrophage cells. Cytotoxicity assays were done on HUVECs and A549 cells using LeTx. HUVECs were more susceptible to LeTx (61-74% survivals) as compared to A549 cells (83-94% survivals, P < 0.005). However, LeTxCM from RAW264.7 further potentiated killing of HUVECs (37% survival) compared to the LeTxCM from A549 cells (up to 70-100% survivals). LeTxCM challenge induced an apoptotic cell death in HUVECs, and this was confirmed by reduction of BCL-2 levels to 54%. Protective antigen (PA) binding to macrophage cell line RAW264.7 > HUVECs > A549 cells. Thus, we postulate that after the initial prodormal phase of pulmonary entry, LeTx causes not only significant direct damage to macrophages and endothelial cells, but also mediates additional indirect damage to endothelial cells mediated by a knock-on effect of LeTx on macrophages that causes apoptotic cell death in endothelial cells.     

Role of macrophage oxidative burst in the action of anthrax lethal toxin.

BACKGROUND: Major symptoms and death from systemic Bacillus anthracis infections are mediated by the action of the pathogen's lethal toxin on host macrophages. High levels of the toxin are cytolytic to macrophages, whereas low levels stimulate these cells to produce cytokines (interleukin-1 beta and tumor necrosis factor-alpha), which induce systemic shock and death. MATERIALS AND METHODS: Experiments were performed to assess the possibility that the oxidative burst may be involved in one or both of lethal toxin's effects on macrophages. Toximediated cell lysis, superoxide anion and cytokine production were measured. Effects of antioxidants and macrophage mutations were examined. RESULTS: RAW264.7 murine macrophages treated with high levels of toxin released large amounts of superoxide anion, beginning at about 1 hr, which correlates with the onset of cytolysis. Cytolysis could be blocked with various exogenous antioxidants or with N-acetyl-L-cysteine and methionine, which promote production of the endogenous antioxidant, glutathione. Mutant murine macrophage lines deficient in production of reactive oxygen intermediates (ROIs) were relatively insensitive to the lytic effects of the toxin, whereas a line with increased oxidative burst potential showed elevated sensitivity. Also, cultured blood monocyte-derived macrophages from a patient with Chronic Granulomatous Disease, a disorder in which the phagocyte's oxidative burst is disabled, were totally resistant to toxin, in contrast to control monocytes. CONCLUSIONS: These results imply that the cytolytic effect of the toxin is mediated by ROIs. Additionally, cytokine production and consequent pathologies showed partial dependence on macrophage ROIs. Antioxidants moderately inhibited toxin-induced cytokine production in vitro, and BALB/c mice pretreated with N-acetyl-L-cysteine or mepacrine showed partial protection against lethal toxin. Thus ROIs are involved in both the cytolytic action of anthrax lethal toxin and the overall pathologic process in vivo.