Monoclonal antibodies to B.anthracis protective antigen are capable to neutralize and to enhance the anthrax lethal toxin action in vitro

Anthrax belongs to highly dangerous infections of man and animals. No effective treatment methods for pulmonary types of the disease have been yet developed. The existing anthrax vaccines were designed decades ago and need improvement to fit the large-scale vaccination of population. At the same time, the immunological properties of the anthrax vaccine main component, i.e. of the protective agent, have been poorly studied. We obtained, within the present case study, a panel of mouse monoclonal antibodies to the protective agent and investigated the properties of the highest-affine panel representatives. An unusual phenomenon was detected, which is related with enhancement of the anthrax toxin action on the mouse macrophage-like cell-line in presence of the 1F2 monoclonal antibody. The remaining analyzed antibodies, i.e. 6G8 and 6G7, were found to neutralize effectively the toxin action. The enhancing and neutralizing antibodies were proven to be specific to different domains of the protective antigen and to recognize epitopes in its composition. The antibody-mediated enhancement of the anthrax lethal action is a convincing argument for further development of a new-generation anthrax vaccine. Definition of the linear antigen determinants for neutralizing antibodies in the protective antigens is an important step in the development of the next-generation anthrax vaccine.     

Antigen delivery by attenuated Bacillus anthracis: new prospects in veterinary vaccines

This report summarizes the recent investigations on the use of Bacillus anthracis as a live vector for delivery of antigens. Recombinant strains were constructed by engineering the current live Sterne vaccine. This vaccine, used to prevent anthrax in cattle, causes side-effects due to anthrax toxin activities. Bacteria producing a genetically detoxified toxin factor were devoid of lethal effects and were as protective as the Sterne strain against experimental anthrax. Moreover, B. anthracis expressing a foreign antigen controlled by an in vivo inducible promoter were able to generate either antibody or cellular protective responses against heterologous diseases.     

Expression of anthrax lethal factor gene by osmolyte induction

The anthrax toxin consists of protective antigen (PA), lethal factor (LF) and edema factor (EF). PA mediates the entry of LF and EF to the cytosol where they exert their effects. Although PA is the major component of the vaccines against anthrax, LF has also been found to play an important role in enhancing protective immunity. We have developed an osmolyte-inducible LF expression system. The protein expression system contributed no additional amino acids to the recombinant LF making it suitable for the human vaccine trials.     

Nasal immunization with the mixture of PA63, LF, and a PGA conjugate induced strong antibody responses against all three antigens

A new generation anthrax vaccine is expected to target not only the anthrax protective antigen (PA) protein, but also other virulent factors of Bacillus anthracis. It is also expected to be amenable for rapid mass immunization of a large number of people. This study aimed to address these needs by designing a prototypic triantigen nasal anthrax vaccine candidate that contained a truncated PA (rPA63), the anthrax lethal factor (LF), and the capsular poly-gamma-D-glutamic acid (gammaDPGA) as the antigens and a synthetic double-stranded RNA (dsRNA), polyriboinosinic-polyribocytodylic acid (poly(I:C)) as the adjuvant. This study identified the optimal dose of nasal poly(I:C) in mice, demonstrated that nasal immunization of mice with the LF was capable of inducing functional anti-LF antibodies (Abs), and showed that nasal immunization of mice with the prototypic triantigen vaccine candidate induced strong immune responses against all three antigens. The immune responses protected macrophages against an anthrax lethal toxin challenge in vitro and enabled the immunized mice to survive a lethal dose of anthrax lethal toxin challenge in vivo. The anti-PGA Abs were shown to have complement-mediated bacteriolytic activity. After further optimization, this triantigen nasal vaccine candidate is expected to become one of the newer generation anthrax vaccines.     

Anthrax vaccination strategies

The biological attack conducted through the US postal system in 2001 broadened the threat posed by anthrax from one pertinent mainly to soldiers on the battlefield to one understood to exist throughout our society. The expansion of the threatened population placed greater emphasis on the reexamination of how we vaccinate against Bacillus anthracis. The currently-licensed Anthrax Vaccine, Adsorbed (AVA) and Anthrax Vaccine, Precipitated (AVP) are capable of generating a protective immune response but are hampered by shortcomings that make their widespread use undesirable or infeasible. Efforts to gain US Food and Drug Administration (FDA) approval for licensure of a second generation recombinant protective antigen (rPA)-based anthrax vaccine are ongoing. However, this vaccine’s reliance on the generation of a humoral immune response against a single virulence factor has led a number of scientists to conclude that the vaccine is likely not the final solution to optimal anthrax vaccine design. Other vaccine approaches, which seek a more comprehensive immune response targeted at multiple components of the B. anthracis organism, are under active investigation. This review seeks to summarize work that has been done to build on the current PA-based vaccine methodology and to evaluate the search for future anthrax prophylaxis strategies.     

Immunoproteomically identified GBAA_0345, alkyl hydroperoxide reductase subunit C is a potential target for multivalent anthrax vaccine

Anthrax is caused by the spore‐forming bacterium Bacillus anthracis, which has been used as a weapon for bioterrorism. Although current vaccines are effective, they involve prolonged dose regimens and often cause adverse reactions. High rates of mortality associated with anthrax have made the development of an improved vaccine a top priority. To identify novel vaccine candidates, we applied an immunoproteomics approach. Using sera from convalescent guinea pigs or from human patients with anthrax, we identified 34 immunogenic proteins from the virulent B. anthracis H9401. To evaluate vaccine candidates, six were expressed as recombinant proteins and tested in vivo. Two proteins, rGBAA_0345 (alkyl hydroperoxide reductase subunit C) and rGBAA_3990 (malonyl CoA‐acyl carrier protein transacylase), have afforded guinea pigs partial protection from a subsequent virulent‐spore challenge. Moreover, combined vaccination with rGBAA_0345 and rPA (protective antigen) exhibited an enhanced ability to protect against anthrax mortality. Finally, we demonstrated that GBAA_0345 localizes to anthrax spores and bacilli. Our results indicate that rGBAA_0345 may be a potential component of a multivalent anthrax vaccine, as it enhances the efficacy of rPA vaccination. This is the first time that sera from patients with anthrax have been used to interrogate the proteome of virulent B. anthracis vegetative cells.     

A Single-Dose PLGA Encapsulated Protective Antigen Domain 4 Nanoformulation Protects Mice against Bacillus anthracis Spore Challenge

Bacillus anthracis, the etiological agent of anthrax, is a major bioterror agent. Vaccination is the most effective prophylactic measure available against anthrax. Currently available anthrax vaccines have issues of the multiple booster dose requirement, adjuvant-associated side effects and stability. Use of biocompatible and biodegradable nanoparticles to deliver the antigens to immune cells could solve the issues associated with anthrax vaccines. We hypothesized that the delivery of a stable immunogenic domain 4 of protective antigen (PAD4) of Bacillus anthracis encapsulated in a poly (lactide-co-glycolide) (PLGA) - an FDA approved biocompatible and biodegradable material, may alleviate the problems of booster dose, adjuvant toxicity and stability associated with anthrax vaccines. We made a PLGA based protective antigen domain 4 nanoparticle (PAD4-NP) formulation using water/oil/water solvent evaporation method. Nanoparticles were characterized for antigen content, morphology, size, polydispersity and zeta potential. The immune correlates and protective efficacy of the nanoparticle formulation was evaluated in Swiss Webster outbred mice. Mice were immunized with single dose of PAD4-NP or recombinant PAD4. The PAD4-NP elicited a robust IgG response with mixed IgG1 and IgG2a subtypes, whereas the control PAD4 immunized mice elicited low IgG response with predominant IgG1 subtype. The PAD4-NP generated mixed Th1/Th2 response, whereas PAD4 elicited predominantly Th2 response. When we compared the efficacy of this single-dose vaccine nanoformulation PAD4-NP with that of the recombinant PAD4 in providing protective immunity against a lethal challenge with Bacillus anthracis spores, the median survival of PAD4-NP immunized mice was 6 days as compared to 1 day for PAD4 immunized mice (p<0.001). Thus, we demonstrate, for the first time, the possibility of the development of a single-dose and adjuvant-free protective antigen based anthrax vaccine in the form of PAD4-NP. Further work in this direction may produce a better and safer candidate anthrax vaccine.     

炭疽活疫苗家兔免疫力与血清抗芽胞IgG关系的研究

炭疽疫苗是预防炭疽流行和炭疽生物恐怖的重要手段。已有动物实验表明,炭疽活疫苗的保护力优于以保护性抗原为主要成份的无细胞疫苗,但两类现行疫苗都有待重新评价和改进。炭疽疫苗的效力必须用适当的实验室方法进行检测与分析才能了解其性质和细节。试验中力图探寻炭疽活疫苗家兔免疫力与血清抗芽胞抗体水平的关系。用“皮上划痕人用炭疽活疫苗”免疫家兔,以特定制备的炭疽芽胞抗原用ELISA法检测血清抗炭疽芽胞IgG抗体水平,并用强毒炭疽杆菌攻击进行效力试验。免疫家兔血清几何平均抗芽胞IgG滴度在免疫后一个月内持续升高,14d达到206,28d时达到776,这时其抵抗20MLD毒菌攻击的保护率为80％,符合中国生物制品规程要求的保护力。一个月后抗体水平开始下降,42d时滴度降至223。实验所揭示的炭疽减毒活疫苗诱导的家兔抗芽胞IgG抗体与抗炭疽保护力之间的关系,既为评价现行疫苗提供了资料,也为研制新型疫苗建立了参考性指标。     

Assessment of immunity and allergy after vaccination with dry combined anthrax vaccine

Study of humoral immune response and allergy in recipients of dry combined anthrax vaccine was performed. Immune response was assessed by antibody titers to protective antigen and by index of preventive properties of blood serum (PPS) of recipients. Relation of index of PPS and antibody titers in blood serum of the donors was established. Distribution of erythrocyte antigens in recipients of live dry and combined anthraxvaccines depending on blood group, Rh-factor, and age was studied. It has been shown that 80% of recipients of dry combined anthrax vaccine formed potent immunity with its high level lasted for 8 months. Study of allergenic properties of the combined anthrax vaccine using registration of neutrophils chemiluminescence in vivo showed low level of sensitization of vacinees.     

Recent progress in the development of anthrax vaccines

Bacillus anthracis is the etiological agent of anthrax. Although anthrax is primarily an epizootic disease; humans are at risk for contracting anthrax. The potential use of B. anthracis spores as biowarfare agent has led to immense attention. Prolonged vaccination schedule of current anthrax vaccine and variable protection conferred; often leading to failure of therapy. This highlights the need for alternative anthrax countermeasures. A number of approaches are being investigated to substitute or supplement the existing anthrax vaccines. These relied on expression of Protective antigen (PA), the key protective immunogen; in bacterial or plant systems; or utilization of attenuated strains of B. anthracis for immunization. Few studies have established potential of domain IV of PA for immunization. Other targets including the spore, capsule, S-layer and anthrax toxin components have been investigated for imparting protective immunity. It has been shown that co-immunization of PA with domain I of lethal factor that binds PA resulted in higher antibody responses. Of the epitope based vaccines, the loop neutralizing determinant, in particular; elicited robust neutralizing antibody response and conferred 97% protection upon challenge. DNA vaccination resulted in varying degree of protection and seems a promising approach. Additionally, the applicability of monoclonal and therapeutic antibodies in the treatment of anthrax has also been demonstrated. The recent progress in the direction of anthrax prophylaxis has been evaluated in this review.     

A study of the physiology of Bacillus anthracis Sterne during manufacture of the UK acellular anthrax vaccine

AIM: To analyse the growth of Bacillus anthracis during simulations of the UK anthrax vaccine manufacturing process. METHODS AND RESULTS: Simulated vaccine production runs were performed using the toxigenic, acapsulate Sterne 34F(2) strain of B. anthracis in semi-defined medium. After rising during the logarithmic growth phase, the pH of the culture starts to fall at about 18 h from pH 8.7 to reach <7.6 at 26 h, coincident with consumption of glucose and optimal production of protective antigen (PA; 7.89 g ml(-1), SD 1.0) and lethal factor (LF; 1.85 g ml(-1), SD 0.29). No increased breakdown of toxin antigens was seen over the 26-32 h period. When glucose was exhausted, amino acids (principally serine) were utilized as an alternative carbon source. Sporulation was not observed during the 32 h. CONCLUSIONS: PA and LF, the principal constituents in the UK anthrax vaccine, undergo little degradation during vaccine fermentation. The vaccine manufacturing process is robust and reproducible. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first detailed analysis of the manufacturing process used for the UK acellular anthrax vaccine; insight gained into the process will support continued and safe vaccine manufacture.     

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.     

Effective mucosal immunity to anthrax: neutralizing antibodies and Th cell responses following nasal immunization with protective antigen

Mucosal, but not parenteral, immunization induces immune responses in both systemic and secretory immune compartments. Thus, despite the reports that Abs to the protective Ag of anthrax (PA) have both anti-toxin and anti-spore activities, a vaccine administered parenterally, such as the aluminum-adsorbed anthrax vaccine, will most likely not induce the needed mucosal immunity to efficiently protect the initial site of infection with inhaled anthrax spores. We therefore took a nasal anthrax vaccine approach to attempt to induce protective immunity both at mucosal surfaces and in the peripheral immune compartment. Mice nasally immunized with recombinant PA (rPA) and cholera toxin (CT) as mucosal adjuvant developed high plasma PA-specific IgG Ab responses. Plasma IgA Abs as well as secretory IgA anti-PA Abs in saliva, nasal washes, and fecal extracts were also induced when a higher dose of rPA was used. The anti-PA IgG subclass responses to nasal rPA plus CT consisted of IgG1 and IgG2b Abs. A more balanced profile of IgG subclasses with IgG1, IgG2a, and IgG2b Abs was seen when rPA was given with a CpG oligodeoxynucleotide as adjuvant, suggesting a role for the adjuvants in the nasal rPA-induced immunity. The PA-specific CD4(+) T cells from mice nasally immunized with rPA and CT as adjuvant secreted low levels of CD4(+) Th1-type cytokines in vitro, but exhibited elevated IL-4, IL-5, IL-6, and IL-10 responses. The functional significance of the anti-PA Ab responses was established in an in vitro macrophage toxicity assay in which both plasma and mucosal secretions neutralized the lethal effects of Bacillus anthracis toxin.     

Characterization of the human immune response to the UK anthrax vaccine

The anthrax bipartite lethal toxin (protective antigen (PA) and lethal factor (LF))-specific antibody responses of humans receiving the UK licensed anthrax vaccine were determined. The PA-specific IgG response peaked two weeks post immunization and fell back to pre-boost levels by week 12. The heterogeneity of the host population modulated the extent of the PA-specific antibody response. Significantly lower levels of LF-specific antibodies were also detected. Vaccinated individuals recognized the same PA epitope as the protective mouse lethal toxin neutralizing monoclonal 2D3 suggesting that this may also be a target for human protection.     

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.     

Human immune responses to the UK human anthrax vaccine

The IgG anti-protective antigen subclass antibody response of individuals who had been infected with anthrax was compared with that of healthy individuals immunized with the UK licensed anthrax vaccine. The predominant subclass in both groups was IgG1. In addition, IgG3 was seen in convalescent serum while vaccinees produced IgG2, IgG3 and IgG4 subclass. The significance of these results is discussed. Further work is required to determine the role of antibodies in mediating protective immunity in man.     

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

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

重组炭疽保护性抗原的表达、纯化与生物活性分析

构建分泌型表达质粒 ,在大肠杆菌中实现了重组炭疽保护性抗原 (rPA)的分泌型表达。重组蛋白位于细菌外周质 ,表达量约占菌体总蛋白的 10 %。以离子交换、疏水层析和凝胶过滤为基础 ,建立了rPA的纯化工艺 ,每升培养物可获得约 15mgrPA ,纯度可达 95 %以上。体外细胞毒性试验显示rPA具有较好的生物学活性。用rPA免疫家兔产生的抗血清在体外可抑制炭疽致死毒素的活性 ,表明rPA可诱导机体产生保护性免疫。以上结果为今后发展新一代炭疽疫苗打下基础     

Expression of protective antigen in transgenic plants: a step towards edible vaccine against anthrax

Protective antigen (PA) is the most potent molecule for vaccination against anthrax. In the present study, we have successfully integrated protective antigen gene in nuclear genome of tobacco plants by Agrobacterium mediated leaf-disc transformation method. Expression of protective antigen gene was detected by immunoblot analysis using antisera raised against purified PA. A distinct band of approximately 83kDa lighted up in the protein extracted from transformed plants while there was no such band in untransformed plants. The plant expressed PA showed biological activity just like native PA, which was demonstrated by cytolytic assay on macrophage like cell lines with lethal factor. This study establishes for the first time expression of PA gene in a plant system and thus marks the first milestone towards developing edible vaccine against 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.