Assembly and disassembly kinetics of anthrax toxin complexes

Proteolytic activation of the protective antigen (PA) component of anthrax toxin allows it to self-associate into a ring-shaped homoheptamer, [PA(63)](7), which can bind the enzymatic components lethal factor (LF) and edema factor (EF). [PA(63)](7) is a pore-precursor (prepore), and under the low-pH conditions of the endosome, it forms a transmembrane pore that allows LF and EF to enter the cytosol. PA was labeled with donor and acceptor fluorescent dyes, and F?rster resonance energy transfer was used to measure the assembly and disassembly kinetics of the prepore complex in solution. The dissociation rate constant for [PA(63)](7) was 1 x 10(-)(6) s(-)(1) (t(1/2) approximately 7 days). In contrast, a ternary complex containing the PA-binding domain of LF (LF(N)) bound to a PA(63) dimer composed of two nonoligomerizing mutants dissociated rapidly (t(1/2) approximately 1 min). Thus, the substantial decrease in the rate of disassembly of [PA(63)](7) relative to the ternary complex is due to the cooperative interactions among neighboring subunits in the heptameric ring. Low concentrations of LF(N) promoted assembly of the prepore from proteolytically activated PA, whereas high concentrations inhibited assembly of both the prepore and the ternary complex. A self-assembly scheme of anthrax toxin complexes is proposed.     

Domain 4 of the anthrax protective antigen maintains structure and binding to the host receptor CMG2 at low pH

Domain 4 of the anthrax protective antigen (PA) plays a key role in cellular receptor recognition as well as in pH-dependent pore formation. We present here the 1.95 Å crystal structure of domain 4, which adopts a fold that is identical to that observed in the full-length protein. We have also investigated the structural properties of the isolated domain 4 as a function of pH, as well as the pH-dependence on binding to the von Willebrand factor A domain of capillary morphogenesis protein 2 (CMG2). Our results provide evidence that the isolated domain 4 maintains structure and interactions with CMG2 at pH 5, a pH that is known to cause release of the receptor on conversion of the heptameric prepore (PA₆₃)₇ to a membrane-spanning pore. Our results suggest that receptor release is not driven solely by a pH-induced unfolding of domain 4.     

Whole-cell voltage clamp measurements of anthrax toxin pore current

Protective antigen (PA) of anthrax toxin binds cellular receptors and forms pores in target cell membranes, through which catalytic lethal factor (LF) and edema factor (EF) are believed to translocate to the cytoplasm. Using patch clamp electrophysiological techniques, we assayed pore formation by PA in real time on the surface of cultured cells. The membranes of CHO-K1 cells treated with activated PA had little to no electrical conductivity at neutral pH (7.3) but exhibited robust mixed ionic currents in response to voltage stimuli at pH 5.3. Pore formation depended on specific cellular receptors and exhibited voltage-dependent inactivation at large potentials (>60 mV). The pH requirement for pore formation was receptor-specific as membrane insertion occurs at significantly different pH values when measured in cells specifically expressing tumor endothelial marker 8 (TEM8) or capillary morphogenesis protein 2 (CMG2), the two known cellular receptors for anthrax toxin. Pores were inhibited by an N-terminal fragment of LF and by micromolar concentrations of tetrabutylammonium ions. These studies demonstrated basic biophysical properties of PA pores in cell membranes and served as a foundation for the study of LF and EF translocation in vivo.     

A Novel Mechanism for Antibody-based Anthrax Toxin Neutralization: INHIBITION OF PREPORE-TO-PORE CONVERSION

Protective antigen (PA), a key component of anthrax toxin, mediates the entry of lethal factor (LF) or edema factor (EF) through a membranal pore into target cells. We have previously reported the isolation and chimerization of cAb29, an anti-PA monoclonal antibody that effectively neutralizes anthrax toxin in an unknown mechanism. The aim of this study was to elucidate the neutralizing mechanism of this antibody in vitro and to test its ability to confer post-exposure protection against anthrax in vivo. By systematic evaluation of the steps taking place during the PA-based intoxication process, we found that cAb29 did not interfere with the initial steps of intoxication, namely its ability to bind to the anthrax receptor, the consecutive proteolytic cleavage to PA₆₃, oligomerization, prepore formation, or LF binding. However, the binding of cAb29 to the prepore prevented its pH-triggered transition to the transmembranal pore, thus preventing the last step of intoxication, i.e. the translocation of LF/EF into the cell. Epitope mapping, using a phage display peptide library, revealed that cAb29 binds the 2α₁ loop in domain 2 of PA, a loop that undergoes major conformational changes during pore formation. In vivo, we found that 100% of anthrax-infected rabbits survived when treated with cAb29 12 h after exposure. In conclusion, these experiments demonstrate that cAb29 exerts its potent neutralizing activity in a unique manner by blocking the prepore-to-pore conversion process.     

The Structure of Tumor Endothelial Marker 8 (TEM8) Extracellular Domain and Implications for Its Receptor Function for Recognizing Anthrax Toxin

Anthrax toxin, which is released from the Gram-positive bacterium Bacillus anthracis, is composed of three proteins: protective antigen (PA), lethal factor (LF), and edema factor (EF). PA binds a receptor on the surface of the target cell and further assembles into a homo-heptameric pore through which EF and LF translocate into the cytosol. Two distinct cellular receptors for anthrax toxin, TEM8/ANTXR1 and CMG2/ANTXR2, have been identified, and it is known that their extracellular domains bind PA with low and high affinities, respectively. Here, we report the crystal structure of the TEM8 extracellular vWA domain at 1.7 Å resolution. The overall structure has a typical integrin fold and is similar to that of the previously published CMG2 structure. In addition, using structure-based mutagenesis, we demonstrate that the putative interface region of TEM8 with PA (consisting of residues 56, 57, and 154–160) is responsible for the PA-binding affinity differences between the two receptors. In particular, Leu56 was shown to be a key factor for the lower affinity of TEM8 towards PA compared with CMG2. Because of its high affinity for PA and low expression in normal tissues, an isolated extracellular vWA domain of the L56A TEM8 variant may serve as a potent antitoxin and a potential therapeutic treatment for anthrax infection. Moreover, as TEM8 is often over-expressed in tumor cells, our TEM8 crystal structure may provide new insights into how to design PA mutants that preferentially target tumor cells.     

Mechanism of membrane translocation by anthrax toxin: insertion and pore formation by protective antigen

Proteolytic activation of receptor-bound protective antigen (PA) at the cell surface removes PA₂₀, allowing PA₆₃ to oligomerize and form a ring-shaped heptameric prepore. The prepore binds edema factor (EF) and lethal factor (LF) and, after endocytosis and trafficking of the complex to an acidic, vesicular compartment, it undergoes membrane insertion and mediates translocation of EF/LF to the cytosol. Data from membrane conductance experiments support a model of membrane insertion in which the 2β2–2β3 loop of PA, which is disordered in native PA and the prepore, forms a 14-stranded transmembrane β-barrel. Recent studies on the process of prepore-to-pore conversion and our current understanding of the mechanism of pH-dependent translocation will be described.     

Acid-induced unfolding of the amino-terminal domains of the lethal and edema factors of anthrax toxin

The two enzymatic components of anthrax toxin, lethal factor (LF) and edema factor (EF), are transported to the cytosol of mammalian cells by the third component, protective antigen (PA). A heptameric form of PA binds LF and/or EF and, under the acidic conditions encountered in endosomes, generates a membrane-spanning pore that is thought to serve as a passageway for these enzymes to enter the cytosol. The pore contains a 14-stranded transmembrane beta-barrel that is too narrow to accommodate a fully folded protein, necessitating that LF and EF unfold, at least partly, in order to pass. Here, we describe the pH-dependence of the unfolding of LF(N) and EF(N), the 30kDa N-terminal PA-binding domains, and minimal translocatable units, of LF and EF. Equilibrium chemical denaturation studies using fluorescence and circular dichroism spectroscopy show that each protein unfolds via a four-state mechanism: N<-->I<-->J<-->U. The acid-induced N-->I transition occurs within the pH range of the endosome (pH 5-6). The I state predominates at lower pH values, and the J and U states are populated significantly only in the presence of denaturant. The I state is compact and has characteristics of a molten globule, as shown by its retention of significant secondary structure and its ability to bind an apolar fluorophore. The N-->I transition leads to an overall 60% increase in buried surface area exposure. The J state is expanded significantly and has diminished secondary structure content. We analyze the different protonation states of LF(N) and EF(N) in terms of a linked equilibrium proton binding model and discuss the implications of our findings for the mechanism of acidic pH-induced translocation of anthrax toxin. Finally, analysis of the structure of the transmembrane beta-barrel of PA shows that it can accommodate alpha-helix, and we suggest that the steric constraints and composition of the lumen may promote alpha-helix formation.     

Effect of 2-fluorohistidine labeling of the anthrax protective antigen on stability, pore formation, and translocation

The action of anthrax toxin relies in part upon the ability of the protective antigen (PA) moiety to form a heptameric pore in the endosomal membrane, providing a portal for entry of the enzymic moieties of the toxin into the cytosol. Pore formation is dependent on a conformational change in the heptameric prepore that occurs in the neutral to mildly acidic pH range, and it has been hypothesized that protonation of one or more histidine residues triggers this transition. To test this hypothesis, we used biosynthetic methods to incorporate the unnatural amino acid analogue 2-fluorohistidine (2-FHis) into PA. 2-FHis is isosteric with histidine but resists protonation at physiological pH values due to a dramatically reduced side-chain pKa ( approximately 1). We found that 2-FHis-labeled PA was biologically inactive, as judged by its inability to deliver a model intracellular effector, LFN-DTA, to the cytosol of CHO-K1 cells. However, whereas 2-FHis blocked a conformational transition in the full-length PA83 protein in the pH 5-6 range, the pH dependence of prepore-to-pore conversion of (PA63)7 was unchanged from the wild-type protein, implying that this conversion is not dependent on His protonation. Consistent with this result, the labeled, trypsin-activated PA was able to permeabilize liposomes to K+ and retained pore-forming activity in planar phospholipid bilayers. The pores in planar bilayers were incapable, however, of translocating a model ligand in response to a transmembrane pH gradient or elevated voltage. The results indicate that protonation of residues other than His, presumably Glu and/or Asp side chains, triggers pore formation in vitro, but His residues are nonetheless important for PA functioning in vivo.     

Solubilization and characterization of the anthrax toxin pore in detergent micelles

Proteolytically activated Protective Antigen (PA) moiety of anthrax toxin self‐associates to form a heptameric ring‐shaped oligomer (the prepore). Acidic pH within the endosome converts the prepore to a pore that serves as a passageway for the toxin's enzymatic moieties to cross the endosomal membrane. Prepore is stable in solution under mildly basic conditions, and lowering the pH promotes a conformational transition to an insoluble pore‐like state. N‐tetradecylphosphocholine (FOS14) was the only detergent among 110 tested that prevented aggregation without dissociating the multimer into its constituent subunits. FOS14 maintained the heptamers as monodisperse, insertion‐competent 440‐kDa particles, which formed channels in planar phospholipid bilayers with the same unitary conductance and ability to translocate a model substrate protein as channels formed in the absence of detergent. Electron paramagnetic resonance analysis detected pore‐like conformational changes within PA on solubilization with FOS14, and electron micrograph images of FOS14‐solubilized pore showed an extended, mushroom‐shaped structure. Circular dichroïsm measurements revealed an increase in α helix and a decrease in β structure in pore formation. Spectral changes caused by a deletion mutation support the hypothesis that the 2β2‐2β3 loop transforms into the transmembrane segment of the β‐barrel stem of the pore. Changes caused by selected point mutations indicate that the transition to α structure is dependent on residues of the luminal 2β11‐2β12 loop that are known to affect pore formation. Stabilizing the PA pore in solution with FOS14 may facilitate further structural analysis and a more detailed understanding of the folding pathway by which the pore is formed.     

Onset of anthrax toxin pore formation

Protective antigen (PA) is the anthrax toxin protein recognized by capillary morphogenesis gene 2 (CMG2), a transmembrane cellular receptor. Upon activation, seven ligand-receptor units self-assemble into a heptameric ring-like complex that becomes endocytozed by the host cell. A critical step in the subsequent intoxication process is the formation and insertion of a pore into the endosome membrane by PA. The pore conversion requires a change in binding between PA and its receptor in the acidified endosome environment. Molecular dynamics simulations totaling approximately 136 ns on systems of over 92,000 atoms were performed. The simulations revealed how the PA-CMG2 complex, stable at neutral conditions, becomes transformed at low pH upon protonation of His-121 and Glu-122, two conserved amino acids of the receptor. The protonation disrupts a salt bridge important for the binding stability and leads to the detachment of PA domain II, which weakens the stability of the PA-CMG2 complex significantly, and subsequently releases a PA segment needed for pore formation. The simulations also explain the great strength of the PA-CMG2 complex achieves through extraordinary coordination of a divalent cation.     

PA63 channel of anthrax toxin: an extended beta-barrel

Anthrax toxin consists of three protein components: protective antigen (PA), lethal factor (LF), and edema factor (EF). PA(63), generated by protease "nicking" of whole PA, is responsible for delivering the toxin's catalytic fragments (LF and EF) to the target cell's cytosol. In planar bilayer membranes, trypsin-nicked PA makes cation-selective voltage-gated channels with a pore diameter of > or =12 A. The channels are presumed to be heptameric "mushrooms", with an extracellular "cap" region and a membrane-inserted, beta-barrel "stem". Although the crystal structure of the water-soluble monomeric form has been resolved to 2.1 A and that of the heptameric "prepore" to 4.5 A, the structure for the membrane-bound channel (pore) has not been determined. We have engineered mutant channels that are cysteine-substituted in residues in the putative beta-barrel, and identified the residues lining the channel lumen by their accessibility to a water-soluble sulfhydryl-specific reagent. The reaction with lumen-exposed cysteinyl side chains causes a drop in channel conductance, which we used to map the residues that line the pore. Our results indicate that the beta-barrel structure extends beyond the bilayer and involves residues that are buried in the monomer. The implication is that major rearrangement of domains in the prepore cap region is required for membrane insertion of the beta-barrel stem.     

Insertion of anthrax protective antigen into liposomal membranes: effects of a receptor

Protective antigen (PA), the receptor-binding component of anthrax toxin, heptamerizes and inserts into the endosomal membrane at acidic pH, forming a pore that mediates translocation of the enzymic components of the toxin to the cytosol. When the heptameric pre-insertion form of PA (the prepore) is acidified in solution, it rapidly loses the ability to insert into membranes. To maximize insertion into model membranes, we examined two ways to bind the protein to large unilamellar vesicles (LUV). One involved attaching a His tag to the von Willebrand factor A domain of one of the PA receptors, ANTXR2, and using this protein as a bridge to bind PA to LUV containing a nickel-chelating lipid. The other involved using a His tag fused to the C terminus of PA to bind the protein directly to LUV containing the same lipid. Both ways enhanced pore formation at pH 5.0 strongly and about equally, as measured by the release of K+. Controls showed that pore formation in this system faithfully reproduced that in vivo. We also showed that binding unmodified ANTXR2 von Willebrand factor A to the prepore in solution enhanced its pore forming activity by slowing its inactivation at acidic pH. These findings indicate that an important role of PA receptors is to promote partitioning of PA into the bilayer by maintaining the prepore close to the target membrane and presumably in the optimal orientation as it undergoes the acidic pH-dependent conformational transition to the pore.     

Anthrax toxins

Bacillus anthracis, the etiological agent of anthrax, secretes three polypeptides that assemble into toxic complexes on the cell surfaces of the host it infects. One of these polypeptides, protective antigen (PA), binds to the integrin-like domains of ubiquitously expressed membrane proteins of mammalian cells. PA is then cleaved by membrane endoproteases of the furin family. Cleaved PA molecules assemble into heptamers, which can then associate with the two other secreted polypeptides: edema factor (EF) and/or lethal factor (LF). The heptamers of PA are relocalized to lipid rafts where they are quickly endocytosed and routed to an acidic compartment. The low pH triggers a conformational change in the heptamers, resulting in the formation of cation-specific channels and the translocation of EF/LF. EF is a calcium- and calmodulin-dependent adenylate cyclase that dramatically raises the intracellular concentration of cyclic adenosine monophosphate (cAMP). LF is a zinc-dependent endoprotease that cleaves the amino terminus of mitogen-activated protein kinase kinases (Meks). Cleaved Meks cannot bind to their substrates and have reduced kinase activity, resulting in alterations of the signaling pathways they govern. The structures of PA, PA heptamer, EF, and LF have been solved and much is now known about the molecular details of the intoxication mechanism. The in vivo action of the toxins, on the other hand, is still poorly understood and hotly debated. A better understanding of the toxins will help in the design of much-needed anti-toxin drugs and the development of new toxin-based medical applications.Abbreviations CMG2 Capillary morphogenesis protein 2 - DTA Diphtheria toxin A chain - EF Edema factor - EFn N-terminal fragment of EF - ETx Edema toxin - GR Glucocorticoid receptors - GSK3 Glycogen synthase kinase 3 - I domain Integrin-like domain - iNOS Inducible nitric oxide synthase - LF Lethal factor - LFn N-terminal fragment of LF - LTx Lethal toxin - MAPK Mitogen-activated protein kinase - Mek MAPK kinases - PA Protective antigen - PA₂₀ 20-kDa N-terminal fragment of PA - PA₆₃ 63-kDa C-terminal fragment of PA - TEM8 Tumor endothelial marker 8     

Anthrax protective antigen: efficiency of translocation is independent of the number of ligands bound to the prepore

Heptameric anthrax protective antigen (termed prepore), which assembles at the mammalian cell surface, competitively binds edema factor (EF) and/or lethal factor (LF). It then transports them to an acidic intracellular compartment and mediates their translocation across the membrane to the cytosol. Steric constraints limit to three the number of molecules of EF and/or LF that can bind simultaneously to prepore. To determine whether the number of ligand molecules bound per heptamer affects the efficiency of translocation, we measured the low-pH-triggered translocation of the radiolabeled protective antigen (PA(63))-binding domain of LF ((35)S-LF(N)) across the plasma membrane of CHO-K1 cells as a function of the degree of saturation of the prepore. The fraction translocated remained constant at approximately 0.4 as (35)S-LF(N) was varied from nil through saturating concentrations. The same constant value was observed when we held (35)S-LF(N) at a saturating concentration and varied the number of functional ligand sites per prepore by changing the ratio of wild-type PA to a ligand-binding mutant. Thus, prepore containing only a single ligand-binding site is capable of translocating its cargo as efficiently as one containing multiple binding sites. The results as a whole imply that heptamers with one, two, or three ligands bound translocate their ligands with the same efficiency, indicating that each ligand molecule is translocated independently from the others.     

Anthrax protective antigen: prepore-to-pore conversion.

PA(63), the active 63 kDa form of anthrax protective antigen, forms a heptameric ring-shaped oligomer that is believed to represent a precursor of the membrane pore formed by this protein. When maintained at pH >/=8.0, this "prepore" dissociated to monomeric subunits upon treatment with SDS at room temperature, but treatment at pH 相似文献   

Trp 346 and Leu 352 residues in protective antigen are required for the expression of anthrax lethal toxin activity

The three separate proteins that make up anthrax toxin-protective antigen (PA), edema factor (EF) and lethal factor (LF) act in binary combinations to produce two distinct reactions in experimental animals: edema (PA+EF) and death (PA+LF). PA is believed to interact with a membrane receptor and, after proteolytic processing, to mediate endocytosis and subsequent translocation of EF or LF into the cytosol. Residues W346, M350, and L352 in loop 3 of domain 2 have been implicated to induce a conformational change when the pH is lowered from 7.4 to 6.5. Modification of the residues Trp (346), Met (350), and Leu (352) to alanine individually and all the three residues together to alanine residues resulted in the loss of cytotoxic activity in combination with LF. The mutant proteins were able to bind to the cell surface receptor, become cleaved by trypsin, bind LF, and oligomerize. These residues might play an important role in the membrane insertion of PA and/or translocation of LF/EF into the cytosol.     

Probing the pH-dependent prepore to pore transition of Bacillus anthracis protective antigen with differential oxidative protein footprinting

The protective antigen (PA) component of the anthrax toxin (ATx) plays an essential role in the pathogenesis of the bioterrorism bacterium Bacillus anthracis. After oligomerization on the cell surface and docking of lethal factor and/or edema factor, PA is internalized and undergoes a conformational change when exposed to the low pH of the endosome to form a membrane-penetrating pore. While the structure of the PA prepore has been determined, precise structural information regarding the pore state remains lacking. Oxidative protein footprinting (OPF) can provide dynamic structural information about a protein complex through analysis of amino acid oxidation both before and after a conformational change. In this study, PA at pH 7.5 and 5.5 was exposed to hydroxyl radicals generated by ionizing radiation. Mass spectrometry was then used to both identify and quantitate the extent of oxidation of differentially modified residues. Several residues were found to be more readily oxidized at pH 7.5, most of which clustered toward the bottom plane of the prepore heptamer. Two amino acids had greater oxidation rates at pH 5.5, both found on the outer periphery of the prepore. When the OPF results were mapped to a current computational model of the pore, the accessibilities of some residues were consistent with their modeled positions in the pore (i.e., Y688 and V619/I620), while data for other residues (W346 and M350) appeared to conflict with the model. The results from this study illustrate the utility of OPF in generating empirical structural information for yet undetermined structures and offering opportunities for refinement for models thereof.     

Crystal Structure of the Engineered Neutralizing Antibody M18 Complexed to Domain 4 of the Anthrax Protective Antigen

The virulence of Bacillus anthracis is critically dependent on the cytotoxic components of the anthrax toxin, lethal factor (LF) and edema factor (EF). LF and EF gain entry into host cells through interactions with the protective antigen (PA), which binds to host cellular receptors such as CMG2. Antibodies that neutralize PA have been shown to confer protection in animal models and are undergoing intense clinical development. A murine monoclonal antibody, 14B7, has been reported to interact with domain 4 of PA (PAD4) and block its binding to CMG2. More recently, the 14B7 antibody was used as the platform for the selection of very high affinity, single-chain antibodies that have tremendous potential as a combination anthrax prophylactic and treatment. Here, we report the high-resolution X-ray structures of three high-affinity, single-chain antibodies in the 14B7 family; 14B7 and two high-affinity variants 1H and M18. In addition, we present the first neutralizing antibody-PA structure, M18 in complex with PAD4 at 3.8 Å resolution. These structures provide insights into the mechanism of neutralization, and the effect of various mutations on antibody affinity, and enable a comparison between the binding of the M18 antibody and CMG2 with PAD4.     

Stability of domain 4 of the anthrax toxin protective antigen and the effect of the VWA domain of CMG2 on stability

The major immunogenic component of the current anthrax vaccine, anthrax vaccine adsorbed (AVA) is protective antigen (PA). We have shown recently that the thermodynamic stability of PA can be significantly improved by binding to the Von‐Willebrand factor A (VWA) domain of capillary morphogenesis protein 2 (CMG2), and improvements in thermodynamic stability may improve storage and long‐term stability of PA for use as a vaccine. In order to understand the origin of this increase in stability, we have isolated the receptor binding domain of PA, domain 4 (D4), and have studied the effect of the addition of CMG2 on thermodynamic stability. We are able to determine a binding affinity between D4 and CMG2 (～300 nM), which is significantly weaker than that between full‐length PA and CMG2 (170–300 pM). Unlike full‐length PA, we observe very little change in stability of D4 on binding to CMG2, using either fluorescence or ¹⁹F‐NMR experiments. Because in previous experiments we could observe a stabilization of both domain 4 and domain 2, the mechanism of stabilization of PA by CMG2 is likely to involve a mutual stabilization of these two domains.     

Purified Bacillus anthracis lethal toxin complex formed in vitro and during infection exhibits functional and biological activity

Anthrax protective antigen (PA, 83 kDa), a pore-forming protein, upon protease activation to 63 kDa (PA(63)), translocates lethal factor (LF) and edema factor (EF) from endosomes into the cytosol of the cell. The relatively small size of the heptameric PA(63) pore (approximately 12 angstroms) raises questions as to how large molecules such as LF and EF can move through the pore. In addition, the reported high binding affinity between PA and EF/LF suggests that EF/LF may not dissociate but remain complexed with activated PA(63). In this study, we found that purified (PA(63))(7)-LF complex exhibited biological and functional activities similar to the free LF. Purified LF complexed with PA(63) heptamer was able to cleave both a synthetic peptide substrate and endogenous mitogen-activated protein kinase kinase substrates and kill susceptible macrophage cells. Electrophysiological studies of the complex showed strong rectification of the ionic current at positive voltages, an effect similar to that observed if LF is added to the channels formed by heptameric PA(63) pore. Complexes of (PA(63))(7)-LF found in the plasma of infected animals showed functional activity. Identifying active complex in the blood of infected animals has important implications for therapeutic design, especially those directed against PA and LF. Our studies suggest that the individual toxin components and the complex must be considered as critical targets for anthrax therapeutics.