Development of an o-pthalaldehyde (OPA) assay to measure protein content in Ricin Vaccine E. coli (RVEc™).

A recombinant ricin vaccine from E. coli (RVEc™), was developed at the US Army Medical Research Institute of Infectious Diseases (USAMRIID) and assessed in an FDA sponsored Phase 1a clinical trial. At the maximum dosage, two of the study participants developed physiological responses that were elevated to the level of severe adverse reactions. To stay within safe dosing guidelines, the FDA recommended that an assay be developed to accurately quantify the recombinant protein content in the vaccine. The RVEc™ vaccine Final Drug Product (FDP) contains the adjuvant Alhydrogel®, which by its colloidal nature interferes with most conventional protein assay methods. We decided to develop an assay measuring RVEc™ FDP using o-pthalaldehyde (OPA) reagent. The OPA reagent reacts to the primary amines and lysine side chains of proteins in the presence of a thiol under alkaline conditions with a quantifiable fluorescent signature, but does not react with Alhydrogel®. Protein content in the RVEc™ FDP can be determined by comparing the fluorescence of the test sample to the fluorescence of a standard curve of defined concentration. Each phase of the assay was tested to optimize and simplify the assay procedure. The accuracy, specificity, reproducibility, and stability of the assay were evaluated. Results indicated that the optimized and modified OPA assay was simple and able to quantify antigen concentration from a standard curve in the 25 µg/mL-600 µg/mL range. The assay accuracy and coefficient of variation (CV) was 95% and less than 8%, respectively, when determining the ricin protein content in the 200 µg/mL vialed RVEc™ FDP. The assay was simple to perform and used conventional laboratory equipment. This assay could be adapted to measure the protein content in the FDP of other vaccines, but with the proviso that each step of the assay would need to be optimized for each antigen.

Ex vivo inhibition of Clostridium botulinum neurotoxin types B, C, E, and F by small molecular weight inhibitors.

Two small molecular weight inhibitors, compounds CB7969312 and CB7967495, that displayed inhibition of botulinum neurotoxin serotype A in a previous study, were evaluated for inhibition of botulinum neurotoxin serotypes B, C, E, and F. The small molecular weight inhibitors were assessed by molecular modeling, UPLC-based peptide cleavage assay; and an ex vivo assay, the mouse phrenic nerve - hemidiaphragm assay (MPNHDA). While both compounds were inhibitors of botulinum neurotoxin (BoNT) serotypes B, C, and F in the MPNHDA, compound CB7969312 was effective at lower molar concentrations than compound CB7967495. However, compound CB7967495 was significantly more effective at preventing BoNTE intoxication than compound CB7969312. In the UPLC-based peptide cleavage assay, CB7969312 was also more effective against LcC. Both compounds inhibited BoNTE, but not BoNTF, LcE, or LcF in the UPLC-based peptide cleavage assay. Molecular modeling studies predicted that both compounds would be effective inhibitors of BoNTs B, C, E, and F. But CB7967495 was predicted to be a more effective inhibitor of the four serotypes (B, C, E, and F) than CB7969312. This is the first report of a small molecular weight compound that inhibits serotypes B, C, E, and F in the ex vivo assay.

Diagnostic and possible therapeutic application of a monoclonal antibody (14G8) directed against botulinum type C neurotoxin.

A monoclonal antibody, designated 14G8, detected Clostridium botulinum type C neurotoxin in immunoassays requiring native confirmation of the analyte. 14G8 bound to the light chain of the type C neurotoxin, which is conserved between strains of C. botulinum type C and C/d mosaic neurotoxins. 14G8 did not react to any other serotypes of C. botulinum neurotoxins. In mouse phrenic nerve-hemidiaphragm assays, 14G8, when combined with a second antibody (5D9-H9-A9, which reacts to epitopes on the carboxy terminus of the heavy chain), was able to protect the mouse myoneural junction from intoxication with C. botulinum type C neurotoxin. When used individually, both 14G8 and 5D9-H9-G9 antibodies slowed the loss of twitch tension in the mouse phrenic nerve-hemidiaphragm assays, but did not completely protect the phrenic nerve from paralysis. In in vivo mouse botulinum neurotoxin type C challenge studies, the combination of 14G8 and 5D9-H9-A9 significantly increased mean time-to-death and survival when compared to toxin controls and mice receiving only one of the monoclonal antibodies. These results suggest that the 14G8 monoclonal antibody could have useful therapeutic applications.

Identification and biochemical characterization of small-molecule inhibitors of Clostridium botulinum neurotoxin serotype A.

An integrated strategy that combined in silico screening and tiered biochemical assays (enzymatic, in vitro, and ex vivo) was used to identify and characterize effective small-molecule inhibitors of Clostridium botulinum neurotoxin serotype A (BoNT/A). Virtual screening was initially performed by computationally docking compounds of the National Cancer Institute (NCI) database into the active site of BoNT/A light chain (LC). A total of 100 high-scoring compounds were evaluated in a high-performance liquid chromatography (HPLC)-based protease assay using recombinant full-length BoNT/A LC. Seven compounds that significantly inhibited the BoNT/A protease activity were selected. Database search queries of the best candidate hit [7-((4-nitro-anilino)(phenyl)methyl)-8-quinolinol (NSC 1010)] were performed to mine its nontoxic analogs. Fifty-five analogs of NSC 1010 were synthesized and examined by the HPLC-based assay. Of these, five quinolinol derivatives that potently inhibited both full-length BoNT/A LC and truncated BoNT/A LC (residues 1 to 425) were selected for further inhibition studies in neuroblastoma (N2a) cell-based and tissue-based mouse phrenic nerve hemidiaphragm assays. Consistent with enzymatic assays, in vitro and ex vivo studies revealed that these five quinolinol-based analogs effectively neutralized BoNT/A toxicity, with CB 7969312 exhibiting ex vivo protection at 0.5 microM. To date, this is the most potent BoNT/A small-molecule inhibitor that showed activity in an ex vivo assay. The reduced toxicity and high potency demonstrated by these five compounds at the biochemical, cellular, and tissue levels are distinctive among the BoNT/A small-molecule inhibitors reported thus far. This study demonstrates the utility of a multidisciplinary approach (in silico screening coupled with biochemical testing) for identifying promising small-molecule BoNT/A inhibitors.

Protection with recombinant Clostridium botulinum C1 and D binding domain subunit (Hc) vaccines against C and D neurotoxins.

Recombinant botulinum Hc (rBoNT Hc) vaccines for serotypes C1 and D were produced in the yeast Pichia pastoris and used to determine protection against four distinct BoNT C and D toxin subtypes. Mice were vaccinated with rBoNT/C1 Hc, rBoNT/D Hc, or with a combination of both vaccines and challenged with BoNT C1, D, C/D, or D/C toxin. Mice receiving monovalent vaccinations were partially or completely protected against homologous toxin and not protected against heterologous toxin. Bivalent vaccine candidates completely survived challenges from all toxins except D/C toxin. These results indicate the recombinant C1 and D Hc vaccines are not only effective in a monovalent formula but offer complete protection against both parental and C/D mosaic toxin and partial protection against D/C mosaic toxin when delivered as a bivalent vaccine.

Roads from vaccines to therapies.

Over the past decade, we have demonstrated that various recombinant fragments of botulinum neurotoxin are highly immunogenic, stimulating notable levels of protective antibodies in mice, guinea pigs, and nonhuman primates. One of the fragments evaluated, the fragment C, is a potential next-generation vaccine candidate to replace the current pentavalent botulinum toxoid vaccine. Synthetic genes encoding the carboxyl-terminal regions (approximately 50 kDa) of toxin types A, B, C1, E, and F were expressed in Pichia pastoris, and manufacturing processes were developed for producing highly purified vaccines. These vaccines were shown to be safe, highly efficacious, stable, and amenable to high-level industrial production. Recombinant vaccines are now being produced in accordance with current Good Manufacturing Practices for use in future clinical trials. As our discovery-based program on vaccine development is diminishing, it is concurrently being replaced with a program focused on developing therapeutic interventions to botulism. Synthetic genes encoding the light chains of botulinum toxin have been expressed in Escherichia coli, and purified. These proteolytically active light chains are being used in high-throughput assays to screen for inhibitors of its catalytic activity. Other resources developed as part of the vaccine initiative, likewise, are finding utility in the quest to develop therapies for botulism.