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.

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.

Characterization of pertussis toxoid by two-dimensional liquid chromatography-tandem mass spectrometry.

Pertussis toxoid, an acellular pertussis vaccine prepared by hydrogen peroxide treatment in the presence of Fe(3+), has not been well characterized. Because the toxoid has been a part of the DTaP vaccine for infants, it is of interest and significance to have a clear understanding of its structure. The five subunits of pertussis toxin (PT) have a combined molecular weight of approximately 95,000Da. The peroxide treatment in toxoid formation introduces additional complexity into the protein sequence. To maximize sequence coverage, a two-dimensional liquid chromatography-tandem mass spectrometry (2D LC-MS/MS) approach was used to analyze the tryptic digest of toxoid as a whole. An analytical-scale high-performance liquid chromatography (HPLC) instrument using a pentafluorophenyl (PFP) column was used as the first-dimensional LC for fraction collection. The fractions were then analyzed by nanoLC-MS/MS using a C18 column to acquire collision-activated dissociation (CAD) spectra of the tryptic peptides. It is shown that a PFP column has a different peptide retention specificity from a C18 column. A combination of a PFP column and a C18 column is a viable approach for dispersing peptides in a complex mixture. From the structures of 65 peptides that represented approximately 50% of its sequence, PT was found to have sustained heavy oxidative damages during toxoid preparation. Nearly all methionine, cysteine, and (likely) tryptophan residues were oxidized. Evidence of histidine and tyrosine oxidation was also observed. In addition, a large percentage of asparagine was found hydrolyzed to aspartic acid. These findings corrrelate well with the reduction of PT toxicity by peroxide treatment.

Production of secondary metabolites by freshwater cyanobacteria.

Freshwater cyanobacteria produce lethal toxins such as microcystins and anatoxins. During the purification of microcystins in bloom samples we found that a toxic cyanobacterium produced not only microcystins but also other types-peptides in early 1990. Since then we have isolated approximately thirty peptides from freshwater cyanobacteria. In this manuscript we focused on the following topics concerning the isolated peptides: 1) how to isolate desired compounds and to determine their structures, 2) structural classification of isolated compounds, 3) isolation of similar peptides from laboratory strains and bloom materials, 4) structurally related peptides from freshwater and marine origins, 5) beta-amino acid containing peptides from cyanobacteria, 6) comprehensive analysis system for the biosynthetic study of peptides produced by cyanobacteria, 7) biological activities of isolated compounds.

The reaction of bacterial toxins with formaldehyde and its use for antigen stabilization.

Since the discovery of diphtheria toxin inactivation in the early 1920s, formaldehyde has been used to inactivate bacterial toxins and viruses used as vaccine antigens. More recently, formaldehyde was used to inactivate pertussis toxin (PT), a component of the newly developed diphtheria-tetanus-acellular pertussis (DTaP) vaccine. This application however illustrated the complexity of the reaction. To eliminate the need for inactivation, the mutant PT-9K/129G was developed. This toxin analogue is irreversibly devoid of toxicity and is a more immunogenic antigen than chemically detoxified PT. Native antigens however proved less stable than detoxified antigens upon storage or heating. We investigated the use of low concentrations of formaldehyde as a stabilizing agent for PT-9K/129G. Under the conditions selected, its antigenic characteristics were retained. Enhanced immunogenicity compared to detoxified preparations was demonstrated in clinical trials in infants where DTaP vaccines containing formalin-stabilized PT-9K/129G were compared to other DTaP vaccines containing detoxified wild type PT. Additional studies with filamentous haemagglutinin (FHA), another component of acellular pertussis vaccines, showed how high formaldehyde concentrations could depress the presentation of epitopes to T-cells by limiting the antigen processing. In conclusion, mild formaldehyde treatment can be applied to stabilize vaccine antigens while retaining optimum antigenic activity.