Dissociation and reconstitution of 12-S toxin of Clostridium botulinum type E

Molecular assembly of botulinum neurotoxin progenitor complexes

Botulinum neurotoxin (BoNT) is produced by Clostridium botulinum and associates with nontoxic neurotoxin-associated proteins to form high-molecular weight progenitor complexes (PCs). The PCs are required for the oral toxicity of BoNT in the context of food-borne botulism and are thought to protect BoNT from destruction in the gastrointestinal tract and aid in absorption from the gut lumen. The PC can differ in size and protein content depending on the C. botulinum strain. The oral toxicity of the BoNT PC increases as the size of the PC increases, but the molecular architecture of these large complexes and how they contribute to BoNT toxicity have not been elucidated. We have generated 2D images of PCs from strains producing BoNT serotypes A1, B, and E using negative stain electron microscopy and single-particle averaging. The BoNT/A1 and BoNT/B PCs were observed as ovoid-shaped bodies with three appendages, whereas the BoNT/E PC was observed as an ovoid body. Both the BoNT/A1 and BoNT/B PCs showed significant flexibility, and the BoNT/B PC was documented as a heterogeneous population of assembly/disassembly intermediates. We have also determined 3D structures for each serotype using the random conical tilt approach. Crystal structures of the individual proteins were placed into the BoNT/A1 and BoNT/B PC electron density maps to generate unique detailed models of the BoNT PCs. The structures highlight an effective platform that can be engineered for the development of mucosal vaccines and the intestinal absorption of oral biologics.

Vaccination against type F botulinum toxin using attenuated Salmonella enterica var Typhimurium strains expressing the BoNT/F H(C) fragment

The utility of the htrA, pagC and nirB promoters to direct the expression of the carboxy-terminal (H(C)) fragment of botulinum toxin F (FH(C)) in Salmonella enterica var Typhimurium has been evaluated. Only low levels of serum antibody were induced after immunisation, and some protection against botulinum toxin type F was demonstrated after oral immunisation of mice with two doses of any of these recombinant Salmonella. Immunisation with two doses of recombinant Salmonella expressing FH(C) from the htrA promoter gave the greatest protection, against up to 10,000 mouse lethal doses of botulinum toxin type F. These results demonstrate the feasibility of an orally delivered vaccine against botulinum toxin type F.

Identification of RNA species in the RNA-toxin complex and structure of the complex in Clostridium botulinum type E

Clostridium botulinum type E toxin was isolated in the form of a complex with RNA(s) from bacterial cells. Characterization of the complexed RNA remains to be elucidated. The RNA is identified here as ribosomal RNA (rRNA) having 23S and 16S components. The RNA-toxin complexes were found to be made up of three types with different molecular sizes. The three types of RNA-toxin complex are toxin bound to both the 23S and 16S rRNA, toxin bound to the 16S rRNA and a small amount of 23S rRNA, and toxin bound only to the 16S rRNA.

Involvement of phospholipids in the intoxication mechanism of botulinum neurotoxin

Phospholipids were examined for their potential to interact with botulinum neurotoxin by an in vivo toxin-inactivation assay and a direct binding assay on a thin layer plate. Type E neurotoxin was inactivated by negatively charged phospholipids, phosphatidylserine (PS) and phosphatidylinositol (PI). The toxicity of the neurotoxin was not affected by phosphatidylcholine (PC) without an electric charge or phosphatidylethanolamine (PE) with a positive electric charge. The neurotoxin bound directly to PS and PI but not to PC or PE. These results suggest that the negatively charged phospholipids in the cell membranes are involved in the intoxication mechanism of botulinum neurotoxin. The phospholipids PS and PI were tested for their potential to interact within three domains [L, H-1, and H-2] which compose the neurotoxin. All three domains bound to PS; whereas, PI specifically accepted the binding of the H-1 domain relative to the penetration of the neurotoxin into the lipid membrane. In this paper, we discuss the interaction between the neurotoxin and the lipid membrane in the intoxication mechanism.

Purification and characterization of the ganglioside-binding fragment of Clostridium botulinum type E neurotoxin

A way of fragmentation of Clostridium botulinum neurotoxin was carried out to elucidate the structure-function relationship of neurotoxin. The hitherto only plausible fragment was isolated from the trypsin-treated heavy chain of botulinum type E neurotoxin. In the presence of 4 M urea, one protein peak emerged from QAE-Sephadex column loaded with the heavy chain mildly treated with trypsin by elution with 0.1 M sodium chloride. Although many protein bands were detected in SDS-PAGE of the treated heavy chain, the eluted protein migrated in a single band to the position of 41,000 Da. The recovery of the 41,000-Da fragment was 28.6%, but with a 2 M urea-containing buffer as eluant, the recovery was less than 12%. The 41,000-Da fragment bound to gangliosides GD1a, GT1b, and GQ1b, to which neurotoxin and the heavy chain bound. The 41,000-Da fragment partially interfered with the binding of 125I-labeled neurotoxin to mouse brain synaptosomes. We have proposed a three-fragment structure (L.H-1.H-2) for botulinum type E neurotoxin. The characters of the 41,000-Da fragment described in this paper seem to substantiated our proposal that type E neurotoxin consists of three fragments, L.H-1.H-2, and that the ganglioside-binding fragment is H-2.

Evidence that botulinum C2 toxin has two dissimilar components

Botulinum C2 toxin produced by most toxigenic and nontoxigenic strains of Clostridium botulinum types C and D contains two distinct protein components, and these were separated by ion-exchange chromatography and gel filtration. Neither of these components manifested the original toxicity, but the original toxicity was restored when the two components were mixed together and trypsinized. This indicates that C2 toxin consists of two dissimilar protein components and that the cooperation of the two is required to elicit toxicity.

Comparison of progenitor toxins of nonproteolytic with those of proteolytic Clostridium botulinum Type B

A nonproteolytic strain of Clostridium botulinum type B produces two toxins of different molecular weight (16S and 12S) that are indistinguishable from the corresponding toxins of a proteolytic strain in molecular weight and construction but differ in potential toxicity, activation ratio, and hemagglutinability. Successful hybridization between the toxic and nontoxic components (both7S) of 12S toxins of biologically heterologous type B strains confirmed the physico-chemical similarity between the toxic as well as the nontoxic components.

Electron microscopy of the toxin and hemagglutinin of type A Clostridium botulinum

Electron micrographs of the toxin and the hemagglutinin of type A Clostridium botulinum showed the toxin to be either round or disclike particles of 4 to 4.5 nm. These particles could also be seen as arranged in long strands or tubules of 9 nm in width. The hemagglutinin appeared as a crystalloid monolayer of stacked particles of 9 nm forming regularly arranged structures of 20 nm. Seen in cross section, these structures appeared as tubules with a lumen of 9 nm. The regularity of the angle of 83 degrees to the long axis of the structure in which the individual particles were arranged suggested that the hemagglutinins formed a helix with sufficient space within its coil to admit the strands of the toxins. A model of the possible arrangement of the toxin and the hemagglutinin in the native state is proposed.