Biomimetic Micromotor Enables Active Delivery of Antigens for Oral Vaccination.

Vaccination represents one of the most effective means of preventing infectious disease. In order to maximize the utility of vaccines, highly potent formulations that are easy to administer and promote high patient compliance are desired. In the present work, a biomimetic self-propelling micromotor formulation is developed for use as an oral antivirulence vaccine. The propulsion is provided by a magnesium-based core, and a biomimetic cell membrane coating is used to detain and neutralize a toxic antigenic payload. The resulting motor toxoids leverage their propulsion properties in order to more effectively elicit mucosal immune responses. After demonstrating the successful fabrication of the motor toxoids, their uptake properties are shown in vitro. When delivered to mice via an oral route, it is then confirmed that the propulsion greatly improves retention and uptake of the antigenic material in the small intestine in vivo. Ultimately, this translates into markedly elevated generation of antibody titers against a model toxin. This work provides a proof-of-concept highlighting the benefits of active oral delivery for vaccine development, opening the door for a new set of applications, in which biomimetic motor technology can provide significant benefits.

Large-scale preparation of Shiga toxin 2 in Escherichia coli for toxoid vaccine antigen production.

Enterohemorrhagic Escherichia coli (EHEC) causes hemorrhagic colitis, and in more severe cases, a serious clinical complication called hemolytic uremic syndrome (HUS). Shiga toxin (Stx)is one of the factors that cause HUS. Serotypes of Stx produced by EHEC include Stx1 and Stx2. Although some genetically mutated toxoids of Stx have been developed, large-scale preparation of Stx that is practical for vaccine development has not been reported. Therefore, overexpression methods for Stx2 and mutant Stx2 (mStx2) in E. coli were developed. The expression plasmid pBSK-Stx2(His) was constructed by inserting the full-length Stx2 gene, in which a six-histidine tag gene was fused at the end of the B subunit into the lacZα fragment gene of the pBluescript II SK(+) vector. An E. coli MV1184 strain transformed with pBSK-Stx2(His) overexpressed histidine-tagged Stx2 (Stx2-His) in cells cultured in CAYE broth in the presence of lincomycin. Stx2-His was purified using TALON metal affinity resin followed by hydroxyapatite chromatography. From 1 L of culture, 68.8 mg of Stx2-His and 61.1 mg of mStx2-His, which was generated by site-directed mutagenesis, were obtained. Stx2-His had a cytotoxic effect on HeLa cells and was lethal to mice. However, the toxicity of mStx2-His was approximately 1000-fold lower than that of Stx2-His. Mice immunized with mStx2-His produced specific antibodies that neutralized the toxicity of Stx2 in HeLa cells. Moreover, these mice survived challenge with high doses of Stx2-His. Therefore, the lincomycin-inducible overexpression method is suitable for large-scale preparation of Stx2 vaccine antigens.

Production and characterization of Clostridium perfringens recombinant ß toxoid.

In this work, we produced and evaluated a vaccine based on a ß toxoid of Clostridium perfringens type C produced in Escherichia coli (rBT). The non-toxic rBT was innocuous for mice and induced 14 IU mL(-1) of ß antitoxin in rabbits, complying with the European Pharmacopeia and CFR9 - USDA guidelines.

An improved method for development of toxoid vaccines and antitoxins.

Botulinum neurotoxins are the most potent toxins known and causative agents of human botulism. Treatment comprises of administering purified polyclonal antitoxin or the prophylactic use of a vaccine containing formaldehyde inactivated toxoid. Whilst formaldehyde inhibits toxin activity, it induces so many structural changes in the molecule that immunisation often results in low levels of neutralising antibodies. We describe here for the first time a simple, less time consuming, novel method for producing a non-toxic toxoid that is structurally and antigenically more similar to the native toxin. Toxin is chemically inactivated by alkylation with iodoacetamide in the presence of reversibly denaturing conditions. This reduces neurotoxic activity by at least 7-orders of magnitude to undetectable levels. Following immunisation, in vivo neutralising antibody levels were 600-times higher than those produced with formaldehyde toxoid, despite generating equivalent ELISA antitoxin binding titres. These studies demonstrate that the new toxoid retains more of the native toxins structure and critical epitopes responsible for inducing life-saving neutralising antibody. Toxoid produced by the new method should substantially improve both antitoxin and vaccine production and be applicable to other toxins and immunogens.

Toxicity assessment of Clostridium difficile toxins in rodent models and protection of vaccination.

Clostridium difficile is the leading cause of hospital-acquired diarrhea, also known as C. difficile associated diarrhea. The two major toxins, toxin A and toxin B are produced by most C. difficile bacteria, but some strains, such as BI/NAP1/027 isolates, produce a third toxin called binary toxin. The precise biological role of binary toxin is not clear but it has been shown to be a cytotoxin for Vero cells. We evaluated the toxicity of these toxins in mice and hamsters and found that binary toxin causes death in both animals similar to toxins A and B. Furthermore, immunization of mice with mutant toxoids of all three toxins provided protection upon challenge with native toxins. These results support the concept that binary toxin contributes to the pathogenicity of C. difficile and provide a method for monitoring the toxicity of binary toxin components in vaccines.

Detecting and preventing reversion to toxicity for a formaldehyde-treated C. difficile toxin B mutant.

The toxicity of Clostridium difficile large clostridial toxin B (TcdB) can be reduced by many orders of magnitude by a combination of targeted point mutations. However, a TcdB mutant with five point mutations (referred to herein as mTcdB) still has residual toxicity that can be detected in cell-based assays and in-vivo mouse toxicity assays. This residual toxicity can be effectively removed by treatment with formaldehyde in solution. Storage of the formaldehyde-treated mTcdB as a liquid can result in reversion over time back to the mTcdB level of toxicity, with the rate of reversion dependent on the storage temperature. We found that for both the "forward" mTcdB detoxification reaction with formaldehyde, and the "reverse" reversion to toxicity reaction, mouse toxicity correlated with several biochemical assays including anion exchange chromatography retention time and appearance on SDS-PAGE. Maintenance of a low concentration of formaldehyde prevents reversion to toxicity in liquid formulations. However, when samples with 0.016% (v/v) formaldehyde were lyophilized and stored at 37 °C, formaldehyde continued to react with and modify the mTcdB in the lyophilized state. Lyophilization alone effectively prevented reversion to toxicity for formaldehyde-treated, formaldehyde-removed mTcdB samples stored at 37 °C for 6 months. Formaldehyde-treated, formaldehyde-removed lyophilized mTcdB showed no evidence of reversion to toxicity, appeared stable by several assays, and was immunogenic in mice, even after storage for 6 months at 37 °C.

Use of rats to compare atrophic rhinitis vaccines for protection against effects of heat-labile protein toxin produced by Pasteurella multocida serogroup D.

Four bacterin-toxoid and three bacterin commercial vaccines against atrophic rhinitis were tested in rats for their capacity to immunize against the lethal and systemic effects of purified heat-labile protein toxin (D-toxin) produced by Pasteurella multocida serogroup D. Only one bacterin-toxoid vaccine stimulated sufficient immunity to prevent the death of all rats challenged with D-toxin. None of the vaccines prevented weight loss, leukocytosis or increases in serum complement titers in rats challenged with D-toxin. Rats provide an inexpensive animal model for testing the capacity of vaccines to generate antitoxic immunity against the lethal and systemic effects of D-toxin.

Dermatonecrotic lesions in rabbits caused by neuraminidase.

In an attempt to study the role of neuraminidase in cholera vibrio pathogenesis, the dermatonecrotic effect of a purified neuraminidase preparation was studied in rabbits. The experiments demonstrated that dermatonecrotic lesions resulted from intracutaneous injection of a purified neuraminidase preparation (0.5 specific human dose or 1 NU) as well as significant doses of cholera toxoid containing the enzyme (4,12,18 specific human doses).

Toxoid preparation from venom of Bothrops colombiensis (Central and South American snake).

A new technique is described for the preparation of Bothrops venom and their different fractions toxoid. This method preserves a high degree of immunogenicity but eliminates lethal effects. All the animals vaccinated with Bothrops crude venom toxoid survived when they were injected with crude venom.

[Isolation of different variants of Pseudomonas aeruginosa anatoxin and their characteristics]. / Poluchenie razlichnykh variantov anatoksina Pseudomonas aeruginosa i ikh kharakteristiki.

The conditions for the detoxification of the crude preparations of P. aeruginosa exotoxin A, obtained by the cultivation of strain PA-7 in Martin's broth, have been studied, and the schemes for obtaining nontoxic, stable, specifically antigenic preparations of toxoid from exotoxins A with different degrees of purification have been developed. Toxoid obtained by formalin treatment on the level of a crude preparation with its subsequent purification and additional detoxification with formalin in the presence of lysin has been shown to possess high immunogenic potency. The preparation has been found to induce immune response and to ensure the protection of experimental animals challenged not only with the lethal dose of exotoxin A, but also with P. aeruginosa toxigenic and protease-producing strains.

Binding and cleavage (BINACLE) assay for the functional in vitro detection of tetanus toxin: applicability as alternative method for the safety testing of tetanus toxoids during vaccine production.

Tetanus toxoids (i.e. chemically inactivated preparations of tetanus neurotoxin) are used for the production of tetanus vaccines. In order to exclude the risk of residual toxicity or of a "reversion to toxicity", each batch of tetanus toxoid is subject to strict safety testing. Up to now, these prescribed safety tests have to be performed as in vivo toxicity tests in guinea pigs. However, as animal tests are generally slow, costly and ethically disputable, a replacement by an in vitro method would be desirable. A suitable alternative method would have to be able to sensitively detect already low concentrations of active tetanus neurotoxin in matrices containing large amounts of inactivated toxoid molecules. We have developed a method which detects active tetanus neurotoxin molecules based on their specific receptor-binding capacity as well as their proteolytic activity. By taking into account two relevant functional characteristics, this combined "BINding And CLEavage" (BINACLE) assay more reliably discriminates between toxic and detoxified molecules than other in vitro assays which solely rely on one single toxin function (e.g. endopeptidase assays). Data from an in-house validation show that the BINACLE assay is able to detect active tetanus neurotoxin with a detection limit comparable to the in vivo test. The sensitive detection of active toxin which has been spiked into toxoid samples from different manufacturers could also be demonstrated. Specificity and precision of the method have been shown to be satisfactory. The presented data indicate that for toxoid batches from some of the most relevant European vaccine manufacturers, the BINACLE assay may represent a potential alternative to the prescribed animal safety tests. In addition, this novel method may also provide a convenient tool for monitoring batch-to-batch consistency during toxoid production.

Toxicity and immunogenicity of Enterotoxigenic Escherichia coli heat-labile and heat-stable toxoid fusion 3xSTa(A14Q)-LT(S63K/R192G/L211A) in a murine model.

Diarrhea is the second leading cause of death to young children. Enterotoxigenic Escherichia coli (ETEC) are the most common bacteria causing diarrhea. Adhesins and enterotoxins are the virulence determinants in ETEC diarrhea. Adhesins mediate bacterial attachment and colonization, and enterotoxins including heat-labile (LT) and heat-stable type Ib toxin (STa) disrupt fluid homeostasis in host cells that leads to fluid hyper-secretion and diarrhea. Thus, adhesins and enterotoxins have been primarily targeted in ETEC vaccine development. A recent study reported toxoid fusions with STa toxoid (STa(P13F)) fused at the N- or C-terminus, or inside the A subunit of LT(R192G) elicited neutralizing antitoxin antibodies, and suggested application of toxoid fusions in ETEC vaccine development (Liu et al., Infect. Immun. 79:4002-4009, 2011). In this study, we generated a different STa toxoid (STa(A14Q)) and a triple-mutant LT toxoid (LT(S63K/R192G/L211A), tmLT), constructed a toxoid fusion (3xSTa(A14Q)-tmLT) that carried 3 copies of STa(A14Q) for further facilitation of anti-STa immunogenicity, and assessed antigen safety and immunogenicity in a murine model to explore its potential for ETEC vaccine development. Mice immunized with this fusion antigen showed no adverse effects, and developed antitoxin antibodies particularly through the IP route. Anti-LT antibodies were detected and were shown neutralizing against CT in vitro. Anti-STa antibodies were also detected in the immunized mice, and serum from the IP immunized mice neutralized STa toxin in vitro. Data from this study indicated that toxoid fusion 3xSTa(A14Q)-tmLT is safe and can induce neutralizing antitoxin antibodies, and provided helpful information for vaccine development against ETEC diarrhea.

A conformational change of C fragment of tetanus neurotoxin reduces its ganglioside-binding activity but does not destroy its immunogenicity.

The C fragment of tetanus neurotoxin (TeNT-Hc) with different conformations was observed due to the four cysteine residues within it which could form different intramolecular disulfide bonds. In this study, we prepared and compared three types of monomeric TeNT-Hc with different conformational components: free sulfhydryls (50 kDa), bound sulfhydryls (44 kDa), and a mixture of the two conformational proteins (half 50 kDa and half 44 kDa). TeNT-Hc with bound sulfhydryls reduced its binding activity to ganglioside G(T1b) and neuronal PC-12 cells compared to what was seen for TeNT-Hc with free sulfhydryls. However, there was no significant difference among their immunogenicities in mice, including induction of antitetanus toxoid IgG titers, antibody types, and protective capacities against tetanus neurotoxin challenge. Our results showed that the conformational changes of TeNT-Hc resulting from disulfide bond formation reduced its ganglioside-binding activity but did not destroy its immunogenicity, and the protein still retained continuous B cell and T cell epitopes; that is, the presence of the ganglioside-binding site within TeNT-Hc may be not essential for the induction of a fully protective antitetanus response. TeNT-Hc with bound sulfhydryls may be developed into an ideal human vaccine with a lower potential for side effects.

Effects of heating on the immunogenicity and biological toxicity of Deinagkistrodon acutus venom and its fractions.

To improve toxoid preparation, the effects of selective heat denaturation were assessed on Deinagkistrodon acutus venom. The venom and its fractions (peak 1 and peak 2 separated by gel filtration chromatography) were heated to various temperatures (45-70 degrees C) for 30 min, after which protein concentration, immunoreactivity, lethality, myotoxicity and hemorrhagic and membrane lysis activities of the samples were determined. In addition, the synergistic effects of the venom fractions were evaluated by separate or simultaneous intramuscular injection in mice. The results showed that the peak 1 fraction consisted primarily of proteins in the range of 18 to 105 kDa, while the peak 2 fraction consisted primarily of proteins smaller than 21 kDa. The hemorrhagic activity, immunoreactivity, and protein concentration of heated samples were gradually reduced as the temperature increased from 25 degrees C to 70 degrees C. Bioactivities significantly decreased but immunoreactivity was retained when the crude venom, peak 1 fraction, or peak 2 fraction were heated to the critical temperatures of 60 degrees C, 55 degrees C, or 60 degrees C, respectively. Synergistic effects of two kinds of heated fractions were observed in toxicity and antibody production after the peak 1 and peak 2 injected simultaneously or respectively. The results suggest that venom fractions heated and injected separately could significantly reduce their toxicity and enhance the neutralization of antiserum induced by them.

Immune modulation by chondroitin sulfate and its degraded disaccharide product in the development of an experimental model of multiple sclerosis.

Clinical symptoms in MOG-induced EAE mice significantly exacerbated following chondroitin sulfate A (CS-A) injection, whereas administration of a degraded product, CSPG-DS, caused dramatic inhibition of EAE development. Also, administration of CSPG-DS but not CS-A, after the onset of clinical symptoms of EAE, was able to suppress the disease. Further studies demonstrated that CS-A up-regulated STAT4 expression and thus, induced IFN-gamma production and Th1 CD4 T cell differentiation. CS-A also up-regulated STAT3 and IL-23 expression and thus increased IL-17 producing T cells. CSPG-DS treatment both in vivo and in vitro decreased TNFalpha production from splenocytes. In vitro and in vivo studies indicated that CSPG-DS treatment in EAE mice significantly blocked migration of lymphocytes, whereas CS-A treatment increased lymphocyte infiltration in the brain.