炭疽毒素及其细胞受体的研究进展

炭疽毒素由 3种蛋白组成 :保护性抗原 (protectiveantigen ,PA)、致死因子 (lethalfactor,LF)和水肿因子 (edemafactor ,EF) .综述炭疽毒素研究的最新进展 .主要介绍炭疽毒素的关键致病因子———LF的结构与功能 ,炭疽毒素膜转运成分PA的结构及其受体 (anthraxtoxinreceptor ,ATR)和其cDNA克隆的结构 ,并讨论了在炭疽的治疗、预防和毒素在肿瘤治疗中的可能应用 .     

Asp 187 and Phe 190 residues in lethal factor are required for the expression of anthrax lethal toxin activity

Anthrax toxin consists of three proteins, protective antigen, lethal factor, and edema factor. Protective antigen translocates lethal factor and edema factor to the cytosol of mammalian cells. The amino-termini of lethal factor and edema factor have several homologous stretches. These regions are presumably involved in binding to protective antigen. In the present study we have determined the role of one such homologous stretch in lethal factor. Residues 187AspLeuLeuPhe190 were replaced by alanine. Asp187Ala and Phe190Ala were found to be non-toxic in combination with protective antigen. Their protective antigen-binding ability was drastically reduced. We propose that Asp187 and Phe190 are crucial for the expression of anthrax lethal toxin activity.     

Hydrophobic residues Phe552, Phe554, Ile562, Leu566, and Ile574 are required for oligomerization of anthrax protective antigen

Anthrax protective antigen (PA) plays a central role in facilitating the entry of active toxin components, namely, lethal factor and edema factor, into the cells. PA is also the main immunogen of both human and veterinary vaccine against anthrax. During host cell intoxication, protective antigen binds to the receptors on cell surface, gets proteolytically activated, oligomerizes to form a heptamer and binds to lethal factor or edema factor. The complex, formed by binding of lethal factor or edema factor to oligomerized PA, is internalized by receptor-mediated endocytosis. Acidification of the endosome results in the insertion of the heptamer into the membrane, thereby forming a pore through which lethal factor or edema factor can translocate into the cytosol. In this study we have identified hydrophobic residues, Phe552, Phe554, Ile562, Leu566, and Ile574, which are required for oligomerization of anthrax protective antigen. Mutation of these conserved residues to alanine impaired the oligomerization of protective antigen. Consequently, these mutants became nontoxic in combination with lethal factor and edema factor. Therapeutic importance of these mutants and their potential as vaccine candidates is discussed.     

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.     

Special features of immune response to the lethal toxin of Bacillus anthracis

We and other authors have recently shown that the pattern of the immune response to components of anthrax, the Bacillus anthracis lethal toxin, is complex. In addition to the neutralizing antibodies, the antitoxin antibody pool contains antibodies enhancing the toxin lethal action. We mapped the epitopes in the protective antigen that are responsible for the induction of both antibody types. In this study, we obtained new data on the cytotoxicity of the B. anthracis lethal toxin toward the J774 A.1 cell line in the presence of monoclonal antibodies to various domains of the protective antigen and the lethal factor. The role of the Fc fragment of immunoglobulins in enhancing the lethal toxin action was shown. These results may serve as a basis for the development of a new generation vaccine for anthrax.     

A viral nanoparticle with dual function as an anthrax antitoxin and vaccine

The recent use of Bacillus anthracis as a bioweapon has stimulated the search for novel antitoxins and vaccines that act rapidly and with minimal adverse effects. B. anthracis produces an AB-type toxin composed of the receptor-binding moiety protective antigen (PA) and the enzymatic moieties edema factor and lethal factor. PA is a key target for both antitoxin and vaccine development. We used the icosahedral insect virus Flock House virus as a platform to display 180 copies of the high affinity, PA-binding von Willebrand A domain of the ANTXR2 cellular receptor. The chimeric virus-like particles (VLPs) correctly displayed the receptor von Willebrand A domain on their surface and inhibited lethal toxin action in in vitro and in vivo models of anthrax intoxication. Moreover, VLPs complexed with PA elicited a potent toxin-neutralizing antibody response that protected rats from anthrax lethal toxin challenge after a single immunization without adjuvant. This recombinant VLP platform represents a novel and highly effective, dually-acting reagent for treatment and protection against anthrax.     

Anthrax biosensor, protective antigen ion channel asymmetric blockade

The significant threat posed by biological agents (e.g. anthrax, tetanus, botulinum, and diphtheria toxins) (Inglesby, T. V., O'Toole, T., Henderson, D. A., Bartlett, J. G., Ascher, M. S., Eitzen, E., Friedlander, A. M., Gerberding, J., Hauer, J., Hughes, J., McDade, J., Osterholm, M. T., Parker, G., Perl, T. M., Russell, P. K., and Tonat, K. (2002) J. Am. Med. Assoc. 287, 2236-2252) requires innovative technologies and approaches to understand the mechanisms of toxin action and to develop better therapies. Anthrax toxins are formed from three proteins secreted by fully virulent Bacillus anthracis, protective antigen (PA, 83 kDa), lethal factor (LF, 90 kDa), and edema factor (EF, 89 kDa). Here we present electrophysiological measurements demonstrating that full-length LF and EF convert the current-voltage relationship of the heptameric PA63 ion channel from slightly nonlinear to highly rectifying and diode-like at pH 6.6. This effect provides a novel method for characterizing functional toxin interactions. The method confirms that a previously well characterized PA63 monoclonal antibody, which neutralizes anthrax lethal toxin in animals in vivo and in vitro, prevents the binding of LF to the PA63 pore. The technique can also detect the presence of anthrax lethal toxin complex from plasma of infected animals. The latter two results suggest the potential application of PA63 nanopore-based biosensors in anthrax therapeutics and diagnostics.     

重组炭疽水肿因子的表达与生物活性分析

炭疽毒素包括3种蛋白因子,即保护性抗原（PA）、致死因子（LF）和水肿因子（EF）。EF是钙调蛋白依耐的腺苷酸环化酶,可使细胞cAMP浓度升高,导致宿主防御能力下降。为深入研究炭疽毒素的作用机理,构建了原核表达质粒,在大肠杆菌中表达出重组EF（rEF）。经鉴定,rEF以可溶形式表达于细菌胞质中。经过金属螯和层析、阳离子交换层析和凝胶层析,每升诱导培养物可获得约5mg 重组蛋白。用重组蛋白免疫家兔获得了兔多抗,能够在细胞试验中中和rEF,体外细胞试验显示rEF具有很好的生物活性,在J774A.1和CHO细胞试验中,能与LF共同竞争和PA的结合位点,相互抑制。上述工作为深入研究炭疽毒素的作用机理,开发针对EF的毒素抑制剂打下基础     

A deleted variant of Bacillus anthracis protective antigen is non-toxic and blocks anthrax toxin action in vivo

Anthrax toxin is the only protein secreted by Bacillus anthracis that contributes to the virulence of this bacterium. An obligatory step in the action of anthrax toxin on eukaryotic cells is cleavage of the receptor-bound protective antigen (PA) protein (83 kilodaltons) to produce a 63-kilodalton, receptor-bound COOH-terminal fragment. A similar fragment can be obtained by limited treatment with trypsin. This proteolytic processing event exposes a site with high affinity for the other two anthrax toxin proteins, lethal factor and edema factor. Terminal sequencing of the purified fragment showed that the activating cleavage occurred in the sequence Arg164-Lys165-Lys166-Arg167. The gene encoding PA was mutagenized to delete residues 163-168, and the deleted PA was purified from a Bacillus subtilis host. The deleted PA was not cleaved by either trypsin or the cell-surface protease, and was non-toxic when administered with lethal factor. Purified, deleted PA protected rats when administered 90 min before injection of 20 minimum lethal doses of toxin. This mutant PA may be useful as a replacement for the PA that is the major active ingredient in the current human anthrax vaccine, because deleted PA is expected to have normal immunogenicity, but would not combine with trace amounts of LF and EF to cause toxicity.     

Bacillus anthracis toxins inhibit human neutrophil NADPH oxidase activity

Bacillus anthracis, the causative agent of anthrax, is a Gram-positive, spore-forming bacterium. B. anthracis virulence is ascribed mainly to a secreted tripartite AB-type toxin composed of three proteins designated protective Ag (PA), lethal factor, and edema factor. PA assembles with the enzymatic portions of the toxin, the metalloprotease lethal factor, and/or the adenylate cyclase edema factor, to generate lethal toxin (LTx) and edema toxin (ETx), respectively. These toxins enter cells through the interaction of PA with specific cell surface receptors. The anthrax toxins act to suppress innate immune responses and, given the importance of human neutrophils in innate immunity, they are likely relevant targets of the anthrax toxin. We have investigated in detail the effects of B. anthracis toxin on superoxide production by primary human neutrophils. Both LTx and ETx exhibit distinct inhibitory effects on fMLP (and C5a) receptor-mediated superoxide production, but have no effect on PMA nonreceptor-dependent superoxide production. These inhibitory effects cannot be accounted for by induction of neutrophil death, or by changes in stimulatory receptor levels. Analysis of NADPH oxidase regulation using whole cell and cell-free systems suggests that the toxins do not exert direct effects on NADPH oxidase components, but rather act via their respective effects, inhibition of MAPK signaling (LTx), and elevation of intracellular cAMP (ETx), to inhibit upstream signaling components mediating NADPH oxidase assembly and/or activation. Our results demonstrate that anthrax toxins effectively suppress human neutrophil-mediated innate immunity by inhibiting their ability to generate superoxide for bacterial killing.     

Delivery of nucleic acid into mammalian cells by anthrax toxin

Gene delivery vehicles based on receptor-mediated endocytosis offer an attractive long-term solution as they might overcome the limitations of toxicity and cargo capacity inherent to many viral gene delivery systems. The protective antigen component of anthrax toxin bind to specific receptors and deliver lethal factor or edema factor into the cytosol of mammalian cells. The N-terminal 254 amino acids of LF (LF(1-254)) binds to PA and, when fused to heterologous proteins, delivers such proteins into the cytosol. However, so far no attempt has been made to use the anthrax toxin system for the intracellular delivery of DNA. In the present study, LF(1-254) of anthrax toxin was fused to the DNA-binding domain of GAL4 protein. The fusion protein (LF(254)-GAL4DBD) showed both PA binding as well as DNA-binding activity in solution. The complex of fusion protein with plasmid DNA containing a reporter gene (luciferase or green fluorescent protein) along with PA delivered plasmid DNA into the cytosol of COS-1 cells. These results suggest that anthrax toxin components can be used as a non-viral system for the efficient delivery of DNA into the cytosol of mammalian cells.     

LRP5 and LRP6 are not required for protective antigen-mediated internalization or lethality of anthrax lethal toxin

Anthrax toxin (AnTx) plays a key role in the pathogenesis of anthrax. AnTx is composed of three proteins: protective antigen (PA), edema factor, and lethal factor (LF). PA is not toxic but serves to bind cells and translocate the toxic edema factor or LF moieties to the cytosol. Recently, the low-density lipoprotein receptor-related protein LRP6 has been reported to mediate internalization and lethality of AnTx. Based on its similarity to LRP6, we hypothesized that LRP5 may also play a role in cellular uptake of AnTx. We assayed PA-dependent uptake of anthrax LF or a cytotoxic LF fusion protein (FP59) in cells and mice harboring targeted deletions of Lrp5 or Lrp6. Unexpectedly, we observed that uptake was unaltered in the presence or absence of either Lrp5 or Lrp6 expression. Moreover, we observed efficient PA-mediated uptake into anthrax toxin receptor (ANTXR)-deficient Chinese hamster ovary cells (PR230) that had been stably engineered to express either human ANTXR1 or human ANTXR2 in the presence or absence of siRNA specific for LRP5 or LRP6. Our results demonstrate that neither LRP5 nor LRP6 is necessary for PA-mediated internalization or lethality of anthrax lethal toxin.     

Molecular dynamics simulations of complexes between wild-type and mutant anthrax protective antigen variants and a model anthrax toxin receptor

Bacillus anthracis, a spore-forming infectious bacterium, produces a toxin consisting of three proteins: lethal factor (LF), edema factor (EF), and protective antigen (PA). LF and EF possess intracellular enzymatic functions, the net effect of which is to severely compromise host innate immunity. During an anthrax infection PA plays the critical role of facilitating entry of both EF and LF toxins into host cell cytoplasm. Crystal structures of all three of the anthrax toxins have been determined, as well as the crystal structure of the (human) von Willebrand factor A (integrin VWA/I domain) -- an anthrax toxin receptor. A theoretical structure of the complex between VWA/I and PA has also been reported. Here we report on the results of 1,000 psec molecular dynamics (MD) simulations carried out on complexes between the Anthrax Protective Antigen Domain 4 (PA-D4) and the von Willebrand Factor A (VWA/I). MD simulations (using Insight II software) were carried out for complexes containing wild-type (WT) PA-D4, as well as for complexes containing three different mutants of PA-D4, one containing three substitutions in the PA-D4 "small loop" (residues 679-693) (D683A/L685E/Y688C), one containing a single substitution at a key site at the PA-D4 -- receptor interface (K679A) and another containing a deletion of eleven residues at the C-terminus of PA (Delta724-735). All three sets of PA mutations have been shown experimentally to result in serious deficiencies in PA function. Our MD results are consistent with these findings. Major disruptions in interactions were observed between the mutant PA-D4 domains and the anthrax receptor during the MD simulations. Many secondary structural features in PA-D4 are also severely compromised when VWA complexes with mutant variants of PA-D4 are subjected to MD simulations. These MD simulation results clearly indicate the importance of the mutated PA-D4 residues in both the "small loop" and at the carboxyl terminus in maintaining a PA conformation that is capable of effective interaction with the anthrax toxin receptor.     

Role of the Protective Antigen Octamer in the Molecular Mechanism of Anthrax Lethal Toxin Stabilization in Plasma

Anthrax is caused by strains of Bacillus anthracis that produce two key virulence factors, anthrax toxin (Atx) and a poly-γ-D-glutamic acid capsule. Atx is comprised of three proteins: protective antigen (PA) and two enzymes, lethal factor (LF) and edema factor (EF). To disrupt cell function, these components must assemble into holotoxin complexes, which contain either a ring-shaped homooctameric or homoheptameric PA oligomer bound to multiple copies of LF and/or EF, producing lethal toxin (LT), edema toxin, or mixtures thereof. Once a host cell endocytoses these complexes, PA converts into a membrane-inserted channel that translocates LF and EF into the cytosol. LT can assemble on host cell surfaces or extracellularly in plasma. We show that, under physiological conditions in bovine plasma, LT complexes containing heptameric PA aggregate and inactivate more readily than LT complexes containing octameric PA. LT complexes containing octameric PA possess enhanced stability, channel-forming activity, and macrophage cytotoxicity relative to those containing heptameric PA. Under physiological conditions, multiple biophysical probes reveal that heptameric PA can prematurely adopt the channel conformation, but octameric PA complexes remain in their soluble prechannel configuration, which allows them to resist aggregation and inactivation. We conclude that PA may form an octameric oligomeric state as a means to produce a more stable and active LT complex that could circulate freely in the blood.     

Beta-cyclodextrin derivatives that inhibit anthrax lethal toxin

Recently, we demonstrated that simultaneous blocking of bacterial growth by antibiotics and inhibition of anthrax toxin action with antibodies against protective antigen were beneficial for the treatment of anthrax. The present study examined the hypothesis that blocking the pore formed by protective antigen can inhibit the action of anthrax toxin. The potential inhibitors were chosen by a structure-based design using beta-cyclodextrin as the starting molecule. Several beta-cyclodextrin derivatives were evaluated for their ability to protect RAW 264.7 cells from the action of anthrax lethal toxin. Per-substituted aminoalkyl derivatives displayed inhibitory activity and were protective against anthrax lethal toxin action at low micromolar concentrations. These results provide the basis for a structure-based drug discovery program, with the goal of identifying new drug candidates for anthrax treatment.     

Cross-reactivity of anthrax and C2 toxin: protective antigen promotes the uptake of botulinum C2I toxin into human endothelial cells

Binary toxins are among the most potent bacterial protein toxins performing a cooperative mode of translocation and exhibit fatal enzymatic activities in eukaryotic cells. Anthrax and C2 toxin are the most prominent examples for the AB(7/8) type of toxins. The B subunits bind both host cell receptors and the enzymatic A polypeptides to trigger their internalization and translocation into the host cell cytosol. C2 toxin is composed of an actin ADP-ribosyltransferase (C2I) and C2II binding subunits. Anthrax toxin is composed of adenylate cyclase (EF) and MAPKK protease (LF) enzymatic components associated to protective antigen (PA) binding subunit. The binding and translocation components anthrax protective antigen (PA(63)) and C2II of C2 toxin share a sequence homology of about 35%, suggesting that they might substitute for each other. Here we show by conducting in vitro measurements that PA(63) binds C2I and that C2II can bind both EF and LF. Anthrax edema factor (EF) and lethal factor (LF) have higher affinities to bind to channels formed by C2II than C2 toxin's C2I binds to anthrax protective antigen (PA(63)). Furthermore, we could demonstrate that PA in high concentration has the ability to transport the enzymatic moiety C2I into target cells, causing actin modification and cell rounding. In contrast, C2II does not show significant capacity to promote cell intoxication by EF and LF. Together, our data unveiled the remarkable flexibility of PA in promoting C2I heterologous polypeptide translocation into cells.     

A Bacillus anthracis strain deleted for six proteases serves as an effective host for production of recombinant proteins

Bacillus anthracis produces a number of extracellular proteases that impact the integrity and yield of other proteins in the B. anthracis secretome. In this study we show that anthrolysin O (ALO) and the three anthrax toxin proteins, protective antigen (PA), lethal factor (LF), and edema factor (EF), produced from the B. anthracis Ames 35 strain (pXO1?, pXO2?), are completely degraded at the onset of stationary phase due to the action of proteases. An improved Cre-loxP gene knockout system was used to sequentially delete the genes encoding six proteases (InhA1, InhA2, camelysin, TasA, NprB, and MmpZ). The role of each protease in degradation of the B. anthracis toxin components and ALO was demonstrated. Levels of the anthrax toxin components and ALO in the supernatant of the sporulation defective, pXO1? A35HMS mutant strain deleted for the six proteases were significantly increased and remained stable over 24 h. A pXO1-free variant of this six-protease mutant strain, designated BH460, provides an improved host strain for the preparation of recombinant proteins. As an example, BH460 was used to produce recombinant EF, which previously has been difficult to obtain from B. anthracis. The EF protein produced from BH460 had the highest in vivo potency of any EF previously purified from B. anthracis or Escherichia coli hosts. BH460 is recommended as an effective host strain for recombinant protein production, typically yielding greater than 10mg pure protein per liter of culture.     

Molecular Dynamics Simulations of Complexes Between Wild-Type and Mutant Anthrax Protective Antigen Variants and a Model Anthrax Toxin Receptor

Abstract

Bacillus anthracis, a spore-forming infectious bacterium, produces a toxin consisting of three proteins: lethal factor (LF), edema factor (EF), and protective antigen (PA). LF and EF possess intracellular enzymatic functions, the net effect of which is to severely compromise host innate immunity. During an anthrax infection PA plays the critical role of facilitating entry of both EF and LF toxins into host cell cytoplasm. Crystal structures of all three of the anthrax toxins have been determined, as well as the crystal structure of the (human) von Willebrand factor A (integrin VWA/I domain)—an anthrax toxin receptor. A theoretical structure of the complex between VWA/I and PA has also been reported. Here we report on the results of 1,000 psec molecular dynamics (MD) simulations carried out on complexes between the Anthrax Protective Antigen Domain 4 (PA-D4) and the von Willebrand Factor A (VWA/I). MD simulations (using Insight II software) were carried out for complexes containing wildtype (WT) PA-D4, as well as for complexes containing three different mutants of PA-D4, one containing three substitutions in the PA-D4 “small loop” (residues 679–693) (D683A/L685E/Y688C), one containing a single substitution at a key site at the PA-D4—receptor interface (K679A) and another containing a deletion of eleven residues at the C-terminus of PA (A724–735). All three sets of PA mutations have been shown experimentally to result in serious deficiencies in PA function. Our MD results are consistent with these findings. Major disruptions in interactions were observed between the mutant PA-D4 domains and the anthrax receptor during the MD simulations. Many secondary structural features in PA-D4 are also severely compromised when VWA complexes with mutant variants of PA-D4 are subjected to MD simulations. These MD simulation results clearly indicate the importance of the mutated PA-D4 residues in both the “small loop” and at the carboxyl terminus in maintaining a PA conformation that is capable of effective interaction with the anthrax toxin receptor.     

Scalable purification of Bacillus anthracis protective antigen from Escherichia coli

The anthrax toxin consists of three proteins, protective antigen (PA), lethal factor, and edema factor that are produced by the Gram-positive bacterium, Bacillus anthracis. Current vaccines against anthrax use PA as their primary component. In this study, we developed a scalable process to produce and purify multi-gram quantities of highly pure, recombinant PA (rPA) from Escherichia coli. The rPA protein was produced in a 50-L fermentor and purified to >99% purity using anion-exchange, hydrophobic interaction, and hydroxyapatite chromatography. The final yield of purified rPA from medium cell density fermentations resulted in approximately 2.7 g of rPA per kg of cell paste (approximately 270 mg/L) of highly pure, biologically active rPA protein. The results presented here exhibit the ability to generate multi-gram quantities of rPA from E. coli that may be used for the development of new anthrax vaccines and anthrax therapeutics.     

The early humoral immune response to Bacillus anthracis toxins in patients infected with cutaneous anthrax

Bacillus anthracis, the causative agent of anthrax, produces a tripartite toxin composed of two enzymatically active subunits, lethal factor (LF) and edema factor (EF), which, when associated with a cell-binding component, protective antigen (PA), form lethal toxin and edema toxin, respectively. In this preliminary study, we characterized the toxin-specific antibody responses observed in 17 individuals infected with cutaneous anthrax. The majority of the toxin-specific antibody responses observed following infection were directed against LF, with immunoglobulin G (IgG) detected as early as 4 days after the onset of symptoms in contrast to the later and lower EF- and PA-specific IgG responses. Unlike the case with infection, the predominant toxin-specific antibody response of those immunized with the US anthrax vaccine absorbed and UK anthrax vaccine precipitated licensed anthrax vaccines was directed against PA. We observed that the LF-specific human antibodies were, like anti-PA antibodies, able to neutralize toxin activity, suggesting the possibility that they may contribute to protection. We conclude that an antibody response to LF might be a more sensitive diagnostic marker of anthrax than to PA. The ability of human LF-specific antibodies to neutralize toxin activity supports the possible inclusion of LF in future anthrax vaccines.