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.     

Lethal factor of anthrax toxin binds monomeric form of protective antigen

Anthrax toxin consists of three components: the enzymatic moieties edema factor (EF) and the lethal factor (LF) and the receptor-binding moiety protective antigen (PA). These toxin components are released from Bacillus anthracis as unassociated proteins and form complexes on the surface of host cells after proteolytic processing of PA into PA20 and PA63. The sequential order of PA heptamerization and ligand binding, as well as the exact mechanism of anthrax toxin entry into cells, are still unclear. In the present study, we provide direct evidence that PA63 monomers are sufficient for binding to the full length LF or its LF-N domain, though with lower affinity with the latter. Therefore, PA oligomerization is not a necessary condition for LF/PA complex formation. In addition, we demonstrated that the PA20 directly interacts with the LF-N domain. Our data points to an alternative process of self-assembly of anthrax toxin on the surface of host 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.     

Functional characterization of protease-treated Bacillus anthracis protective antigen.

Characterization of the functional domains of Bacillus anthracis protective antigen (PA, 83-kDa), the common cellular binding molecule for both anthrax edema toxin and anthrax lethal toxin, is important for understanding the mechanism of entry and action of the anthrax toxins. In this study, we generated both biologically active (facilitates killing of J774A.1 cells in combination with lethal factor, LF) and inactive preparations of PA by protease treatment. Limited proteolytic digestion of PA in vitro with trypsin generated a 20-kDa fragment and a biologically active 63-kDa fragment. In contrast, limited digestion of PA with chymotrypsin yielded a preparation containing 37- and 47-kDa fragments defective for biological activity. Treatment with both chymotrypsin and trypsin generated three major fragments, 20, "17," and 47 kDa as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. This PA preparation was also biologically inactive. To investigate the nature of the defect resulting from chymotrypsin treatment, we assayed PA preparations for the ability to bind to the cellular receptor and to bind and internalize 125I-LF. All radiolabeled PA preparations bound with specificity to J774A.1 cells and exhibited affinities similar to native 83-kDa PA. Once bound to the cell surface receptor, both trypsin-treated PA and chymotrypsin/trypsin-treated PA specifically bound 125I-LF with high affinity. Finally, these PA preparations delivered 125I-LF to a Pronase-resistant cellular compartment in a time- and temperature-dependent fashion. Thus, the biological defect exhibited by chymotrypsin-treated PA is not at the level of cell binding or internalization but at a step later, such as toxin routing or processing by J774A.1 cells. These protease-treated preparations of PA should prove useful in both elucidating the intracellular processing of anthrax lethal toxin and determining the structure-function relationship of PA and LF.     

Cell surface tumor endothelium marker 8 cytoplasmic tail-independent anthrax toxin binding,proteolytic processing,oligomer formation,and internalization

The interaction of anthrax toxin protective antigen (PA) and target cells was assessed, and the importance of the cytosolic domain of tumor endothelium marker 8 (TEM8) in its function as a cellular receptor for PA was evaluated. PA binding and proteolytic processing on the Chinese hamster ovary cell surface occurred rapidly, with both processes nearly reaching steady state in 5 min. Remarkably, the resulting PA63 fragment was present on the cell surface only as an oligomer, and furthermore, the oligomer was the only PA species internalized, suggesting that oligomerization of PA63 triggers receptor-mediated endocytosis. Following internalization, the PA63 oligomer was rapidly and irreversibly transformed to an SDS/heat-resistant form, in a process requiring an acidic compartment. This conformational change was functionally correlated with membrane insertion, channel formation, and translocation of lethal factor into the cytosol. To explore the role of the TEM8 cytosolic tail, a series of truncated TEM8 mutants was transfected into a PA receptor-deficient Chinese hamster ovary cell line. Interestingly, all of the cytosolic tail truncated TEM8 mutants functioned as PA receptors, as determined by PA binding, processing, oligomer formation, and translocation of an lethal factor fusion toxin into the cytosol. Moreover, cells transfected with a TEM8 construct truncated before the predicted transmembrane domain failed to bind PA, demonstrating that residues 321-343 are needed for cell surface anchoring. Further evidence that the cytosolic domain plays no essential role in anthrax toxin action was obtained by showing that TEM8 anchored by a glycosylphosphatidylinositol tail also functioned as a PA receptor.     

Monoclonal antibodies directed against protective antigen of Bacillus anthracis enhance lethal toxin activity in vivo

Protective antigen (PA) from Bacillus anthracis binds to cellular receptors, combines with lethal factor (LF) forming lethal toxin (LeTx), and facilitates the translocation of LF into the cytosol. LeTx is cytotoxic for J774A.1 cells, a murine macrophage cell line, and causes death of Fisher 344 rats when injected intravenously. PA is also the major protective component in anthrax vaccines. Antibody-dependent enhancement has been reported for several viral diseases, a bacterial infection, and for B. anthracis LeTx in vitro cytotoxicity. Further screening of our 73 PA monoclonal antibodies (mAbs) identified a total of 17 PA mAbs that enhanced in vitro cytotoxicity at suboptimal concentrations of LeTx. A competitive binding enzyme-linked immunosorbent assay showed that these 17 PA mAbs identified eight different antigenic regions on PA. Eight of the 17 PA mAbs that enhanced LeTx in vitro cytoxicity were examined for their activity in vivo. Of the eight mAbs that were injected intravenously with a sublethal concentration of LeTx into male Fisher 344 rats, four mAbs enhanced the lethality of LeTx and resulted in the death of animals, whereas control animals did not succumb to intoxication. This is the first demonstration that PA mAbs can enhance LeTx intoxication in vivo.     

Proteolytic stability of beta-peptide bonds probed using quenched fluorescent substrates incorporating a hemoglobin cleavage site

Anthrax lethal toxin is a binary bacterial toxin consisting of two proteins, protective antigen (PA) and lethal factor (LF), that self-assemble on receptor-bearing eukaryotic cells to form toxic, non-covalent complexes. PA₆₃, a proteolytically activated form of PA, spontaneously oligomerizes to form ring-shaped heptamers that bind LF and translocate it into the cell. Site-directed mutagenesis was used to substitute cysteine for each of three residues (N209, E614 and E733) at various levels on the lateral face of the PA₆₃ heptamer and for one residue (E126) on LF_N, the 30 kDa N-terminal PA binding domain of LF. Cysteine residues in PA were labeled with IAEDANS and that in LF_N was labeled with Alexa 488 maleimide. The mutagenesis and labeling did not significantly affect function. Time-resolved fluorescence methods were used to study fluorescence resonance energy transfer (FRET) between the AEDANS and Alexa 488 probes after the complex assembled in solution. The results clearly indicate energy transfer between AEDANS labeled at residue N209C on PA and the Alexa 488-labeled LF_N, whereas transfer from residue E614C on PA was slight, and none was observed from residue E733C. These results support a model in which LF_N binds near the top of the ring-shaped (PA₆₃)₇ heptamer.     

Proton-coupled protein transport through the anthrax toxin channel

Anthrax toxin consists of three proteins (approx. 90kDa each): lethal factor (LF); oedema factor (OF); and protective antigen (PA). The former two are enzymes that act when they reach the cytosol of a targeted cell. To enter the cytosol, however, which they do after being endocytosed into an acidic vesicle compartment, they require the third component, PA. PA (or rather its proteolytically generated fragment PA63) forms at low pH a heptameric beta-barrel channel, (PA63)7, through which LF and OF are transported--a phenomenon we have demonstrated in planar phospholipid bilayers. It might appear that (PA63)7 simply forms a large hole through which LF and OF diffuse. However, LF and OF are folded proteins, much too large to fit through the approximately 15A diameter (PA63)7 beta-barrel. This paper discusses how the (PA63)7 channel both participates in the unfolding of LF and OF and functions in their translocation as a proton-protein symporter.     

A quantitative study of the interactions of Bacillus anthracis edema factor and lethal factor with activated protective antigen

Bacillus anthracis secretes three proteins, which associate in binary combinations to form toxic complexes at the surface of mammalian cells. Receptor-bound protective antigen (PA) is proteolytically activated, yielding a 63 kDa fragment (PA(63)). PA(63) oligomerizes into heptamers, which bind edema factor (EF) or lethal factor (LF) to form the toxic complexes. We undertook a quantitative analysis of the interactions of EF with PA(63) by means of surface plasmon resonance (SPR) measurements. Heptameric PA(63) was covalently bound by amine coupling to an SPR chip, or noncovalently bound via a C-terminal hexahistidine tag on the protein to Ni(2+)nitrilotriacetate groups on the chip. Values of k(on) and k(off) for EF at 23 degrees C were approximately 3 x 10(5) M(-)(1) s(-)(1) and (3-5) x 10(-)(4) s(-)(1), respectively, giving a calculated K(d) of (1-2) x 10(-)(9) M. A similar value of K(d) (7 x 10(-)(10) M) was obtained when we measured the binding of radiolabeled EF to receptor-bound PA(63) on the surface of L6 cells (at 4 degrees C). Each of these analyses was also performed with LF and LF(N) (the N-terminal 255 residues of LF), and values obtained were comparable to those for EF. The similarity in the dissociation constants determined by SPR and by measurements on the cell surface suggests that the presence of the receptor does not play a large role in the interaction between PA(63) and EF/LF.     

Monitoring anthrax toxin receptor dissociation from the protective antigen by NMR

The binding of the Bacillus anthracis protective antigen (PA) to the host cell receptor is the first step toward the formation of the anthrax toxin, a tripartite set of proteins that include the enzymatic moieties edema factor (EF), and lethal factor (LF). PA is cleaved by a furin‐like protease on the cell surface followed by the formation of a donut‐shaped heptameric prepore. The prepore undergoes a major structural transition at acidic pH that results in the formation of a membrane spanning pore, an event which is dictated by interactions with the receptor and necessary for entry of EF and LF into the cell. We provide direct evidence using 1‐dimensional ¹³C‐edited ¹H NMR that low pH induces dissociation of the Von‐Willebrand factor A domain of the receptor capillary morphogenesis protein 2 (CMG2) from the prepore, but not the monomeric full length PA. Receptor dissociation is also observed using a carbon‐13 labeled, 2‐fluorohistidine labeled CMG2, consistent with studies showing that protonation of His‐121 in CMG2 is not a mechanism for receptor release. Dissociation is likely caused by the structural transition upon formation of a pore from the prepore state rather than protonation of residues at the receptor PA or prepore interface.     

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.     

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.     

A dominant negative mutant of Bacillus anthracis protective antigen inhibits anthrax toxin action in vivo

PA63, a proteolytically activated 63-kDa form of anthrax protective antigen (PA), forms heptameric oligomers and has the ability to bind and translocate the catalytic moieties, lethal factor (LF), and edema factor (EF) into the cytosol of mammalian cells. Acidic pH triggers oligomerization and membrane insertion by PA63. A disordered amphipathic loop in domain II of PA (2beta2-2beta3 loop) is involved in membrane insertion by PA63. Because conditions required for membrane insertion coincide with those for oligomerization of PA63 in mammalian cells, residues constituting the 2beta2-2beta3 loop were replaced with the residues of the amphipathic membrane-inserting loop of its homologue iota-b toxin secreted by Clostridium perfringens. It was hypothesized that such a molecule might assemble into hetero-heptameric structures with wild-type PA ultimately leading to the inhibition of cellular intoxication. The mutation blocked the ability of PA to mediate membrane insertion and translocation of LF into the cytosol but had no effect on proteolytic activation, oligomerization, or binding LF. Moreover, an equimolar mixture of purified mutant PA (PA-I) and wild-type PA showed complete inhibition of toxin activity both in vitro on J774A.1 cells and in vivo in Fischer 344 rats thereby exhibiting a dominant negative effect. In addition, PA-I inhibited the channel-forming ability of wild-type PA on the plasma membrane of CHO-K1 cells thereby indicating protein-protein interactions between the two proteins resulting in the formation of mixed oligomers with defective functional activity. Our findings provide a basis for understanding the mechanism of translocation and exploring the possibility of the use of this PA molecule as a therapeutic agent against anthrax toxin action in vivo.     

Membrane type-1 matrix metalloproteinase (MT1-MMP) protects malignant cells from tumoricidal activity of re-engineered anthrax lethal toxin

Protective antigen (PA) and lethal factor (LF) are the two components of anthrax lethal toxin. PA is responsible for interacting with cell receptors and for the subsequent translocation of LF inside the cell compartment. A re-engineered toxin comprised of PA and a fusion chimera LF/Pseudomonas exotoxin (FP59) is a promising choice for tumor cell surface targeting. We demonstrated, however, that in vitro in cell-free system and in cultured human colon carcinoma LoVo, fibrosarcoma HT1080 and glioma U251 cells membrane type-1 matrix metalloproteinase (MT1-MMP) cleaves both the PA83 precursor and the PA63 mature protein. Exhaustive MT1-MMP cleavage of PA83 in vitro generates several major degradation fragments with an N-terminus at Glu40, Leu48, and Gln512. In cultured cells, MT1-MMP-dependent cleavage releases the cell-bound PA83 and PA63 species from the cell surface. As a result, MT1-MMP expressing cells have less PA63 to internalize. In agreement, our observations demonstrate that MT1-MMP proteolysis of PA makes the MT1-MMP-expressing aggressive invasive cells resistant to the cytotoxic effect of a bipartite PA/FP59 toxin. We infer from our studies that synthetic inhibitors of MMPs are likely to increase the therapeutic anti-cancer effect of anthrax toxin. In addition, our study supports a unique role of furin in the activation of PA, thereby suggesting that furin inhibitors are the likely specific drugs for short-term therapy of anthrax infection.     

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.     

The carboxyl-terminal end of protective antigen is required for receptor binding and anthrax toxin activity.

Anthrax toxin consists of three separate proteins produced by Bacillus anthracis: protective antigen (PA), lethal factor (LF), and edema factor (EF). Previous work showed that the process by which these proteins damage eukaryotic cells begins with binding of PA (83 kDa) to cell surface receptors. PA is then cleaved by a cell surface protease so as to expose a high-affinity binding site for LF or EF on the COOH-terminal, receptor-bound, 63-kilodalton fragment. In this report we more closely define a region of PA involved in receptor binding. The gene encoding PA was mutagenized so as to delete 3, 5, 7, 12, or 14 amino acids from the carboxyl terminus of the protein, and the truncated PA variants were purified from Bacillus subtilis or Escherichia coli. Deletion of 3, 5, or 7 amino acids reduced the binding of PA to cells and the subsequent toxicity of the PA.LF complex to J774A.1 cells and also the ability to cause EF binding to cells. Deletion of 12 or 14 amino acids completely eliminated all these activities. These results show that the carboxy terminus comprises or is part of the receptor-binding domain of PA.     

Anthrax toxin receptor drives protective antigen oligomerization and stabilizes the heptameric and octameric oligomer by a similar mechanism

Background

Anthrax toxin is comprised of protective antigen (PA), lethal factor (LF), and edema factor (EF). These proteins are individually nontoxic; however, when PA assembles with LF and EF, it produces lethal toxin and edema toxin, respectively. Assembly occurs either on cell surfaces or in plasma. In each milieu, PA assembles into a mixture of heptameric and octameric complexes that bind LF and EF. While octameric PA is the predominant form identified in plasma under physiological conditions (pH 7.4, 37°C), heptameric PA is more prevalent on cell surfaces. The difference between these two environments is that the anthrax toxin receptor (ANTXR) binds to PA on cell surfaces. It is known that the extracellular ANTXR domain serves to stabilize toxin complexes containing the PA heptamer by preventing premature PA channel formation—a process that inactivates the toxin. The role of ANTXR in PA oligomerization and in the stabilization of toxin complexes containing octameric PA are not understood.

Methodology

Using a fluorescence assembly assay, we show that the extracellular ANTXR domain drives PA oligomerization. Moreover, a dimeric ANTXR construct increases the extent of and accelerates the rate of PA assembly relative to a monomeric ANTXR construct. Mass spectrometry analysis shows that heptameric and octameric PA oligomers bind a full stoichiometric complement of ANTXR domains. Electron microscopy and circular dichroism studies reveal that the two different PA oligomers are equally stabilized by ANTXR interactions.

Conclusions

We propose that PA oligomerization is driven by dimeric ANTXR complexes on cell surfaces. Through their interaction with the ANTXR, toxin complexes containing heptameric and octameric PA oligomers are similarly stabilized. Considering both the relative instability of the PA heptamer and extracellular assembly pathway identified in plasma, we propose a means to regulate the development of toxin gradients around sites of infection during anthrax pathogenesis.     

Both PA63 and PA83 are endocytosed within an anthrax protective antigen mixed heptamer: a putative mechanism to overcome a furin deficiency

Anthrax toxin consists of protective antigen (PA), and lethal (LF) and edema (EF) factors. A 83 kDa PA monomer (PA83) precursor binds to the cell receptor. Furin-like proprotein convertases (PCs) cleave PA83 to generate cell-bound 63 kDa protein (PA63). PA63 oligomerizes to form a ring-shaped heptamer that binds LF-EF and facilitates their entry into the cells. Several additional PCs, as opposed to furin alone, are capable of processing PA83. Following the incomplete processing of the available pool of PA83, the functional heptamer includes both PA83 and PA63. The available structures of the receptor-PA complex imply that the presence of either one or two molecules of PA83 will not impose structural limitations on the formation of the heptamer and the association of either the (PA83)(1)(PA63)(6) or (PA83)(2)(PA63)(5) heteroheptamer with LF-EF. Our data point to the intriguing mechanism of anthrax that appears to facilitate entry of the toxin into the cells which express limiting amounts of PCs and an incompletely processed PA83 pool.     

Anthrax toxin complexes: heptameric protective antigen can bind lethal factor and edema factor simultaneously

The 83 kDa protective antigen (PA(83)) component of anthrax toxin, after proteolytic activation, self-associates to form ring-shaped heptamers ([PA(63)](7)) that bind and aid delivery of the Edema Factor (EF) and Lethal Factor (LF) components to the cytosol. Here we show using fluorescence (F?rster) resonance energy transfer that a molecule of [PA(63)](7) can bind EF and LF simultaneously. We labeled EF and LF with an appropriate donor/acceptor pair and found quenching of the donor and an increase in sensitized emission of the acceptor when, and only when, a mixture of the labeled proteins was combined with [PA(63)](7). Addition of unlabeled PA(63)-binding domain of LF to the mixture competitively displaced labeled EF and LF, causing a loss of energy transfer. In view of the known maximum occupancy of 3 ligand molecules per [PA(63)](7), these findings indicate that PA, EF, and LF can form mixtures of liganded toxin complexes containing both EF and LF.