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Botulinum neurotoxins (BoNTs) are valuable tools to unveil molecular mechanisms of exocytosis in neuronal and non-neuronal cells due to their peptidase activity on exocytic isoforms of SNARE proteins. They are produced by Clostridia as single-chain polypeptides that are proteolytically cleaved into light, catalytic domains covalently linked via disulfide bonds to heavy, targeting domains. This format of two subunits linked by disulfide bonds is required for the full neurotoxicity of BoNTs. We have generated a recombinant version of BoNT/B that consists of the light chain of the toxin fused to the protein transduction domain of the human immunodeficiency virus-1 (TAT peptide) and a hexahistidine tag. His6-TAT-BoNT/B-LC, expressed in Escherichia coli and purified by affinity chromatography, penetrated membranes and exhibited strong enzymatic activity, as evidenced by cleavage of the SNARE synaptobrevin from rat brain synaptosomes and human sperm cells. Proteolytic attack of synaptobrevin hindered exocytosis triggered by a calcium ionophore in the latter. The novel tool reported herein disrupts the function of a SNARE protein within minutes in cells that may or may not express the receptors for the BoNT/B heavy chain, and without the need for transient transfection or permeabilization.

Botulinum neurotoxins (BoNTs) are the most potent natural toxins known. The effects of BoNT serotype A (BoNT/A) can last several months, whereas the effects of BoNT serotype E (BoNT/E), which shares the same synaptic target, synaptosomal-associated protein 25 (SNAP25), last only several weeks. The long-lasting effects or persistence of BoNT/A, although desirable for therapeutic applications, presents a challenge for medical treatment of BoNT intoxication. Although the mechanisms for BoNT toxicity are well known, little is known about the mechanisms that govern the persistence of the toxins. We show that the recombinant catalytic light chain (LC) of BoNT/E is ubiquitylated and rapidly degraded in cells. In contrast, BoNT/A LC is considerably more stable. Differential susceptibility of the catalytic LCs to ubiquitin-dependent proteolysis therefore might explain the differential persistence of BoNT serotypes. In this regard we show that TRAF2, a RING finger protein implicated in ubiquitylation, selectively associates with BoNT/E LC and promotes its proteasomal degradation. Given these data, we asked whether BoNT/A LC could be targeted for rapid proteasomal degradation by redirecting it to characterized ubiquitin ligase domains. We describe chimeric SNAP25-based ubiquitin ligases that target BoNT/A LC for degradation, reducing its duration in a cellular model for toxin persistence.

Sanger and shotgun sequencing of Clostridium botulinum strain Af84 type Af and its botulinum neurotoxin gene (bont) clusters identified the presence of three bont gene clusters rather than the expected two. The three toxin gene clusters consisted of bont subtypes A2, F4 and F5. The bont/A2 and bont/F4 gene clusters were located within the chromosome (the latter in a novel location), while the bont/F5 toxin gene cluster was located within a large 246 kb plasmid. These findings are the first identification of a C. botulinum strain that contains three botulinum neurotoxin gene clusters.

Botulinum neurotoxins are known to have seven serotypes (BoNT/A–G). Here we report a new BoNT serotype, tentatively named BoNT/X, which has the lowest sequence identity with other BoNTs and is not recognized by antisera against known BoNTs. Similar to BoNT/B/D/F/G, BoNT/X cleaves vesicle-associated membrane proteins (VAMP) 1, 2 and 3, but at a novel site (Arg66-Ala67 in VAMP2). Remarkably, BoNT/X is the only toxin that also cleaves non-canonical substrates VAMP4, VAMP5 and Ykt6. To validate its activity, a small amount of full-length BoNT/X was assembled by linking two non-toxic fragments using a transpeptidase (sortase). Assembled BoNT/X cleaves VAMP2 and VAMP4 in cultured neurons and causes flaccid paralysis in mice. Thus, BoNT/X is a novel BoNT with a unique substrate profile. Its discovery posts a challenge to develop effective countermeasures, provides a novel tool for studying intracellular membrane trafficking, and presents a new potential therapeutic toxin for modulating secretions in cells. There are seven well-established types of Botulinum neurotoxins (BoNTs). Here the authors report the identification and characterization of a new type of BoNT—BoNT/X—which cleaves a different site on canonical BoNTs substrates and targets SNARE family members not cleaved by known BoNTs.

Background. Clostridium botulinum strain IBCA10-7060, isolated from a patient with infant botulism, produced botulinum neurotoxin type B (BoNT/B) and another BoNT that, by use of the standard mouse bioassay, could not be neutralized by any of the Centers for Disease Control and Prevention-provided monovalent polyclonal botulinum antitoxins raised against BoNT types A-G. Methods and Results. The combining of antitoxins to neutralize the toxicity of known bivalent C. botulinum strains Ab, Ba, Af, and Bf also failed to neutralize the second BoNT. Analysis of culture filtrate by double immunodiffusion yielded a single line of immunoprecipitate with anti-A, anti-B, and anti-F botulinum antitoxins but not with anti-E antitoxin. A heptavalent F(ab')₂ botulinum antitoxin A-G obtained from the US Army also did not neutralize the second BoNT. An antitoxin raised against IBCA10-7060 toxoid protected mice against BoNT/B (Okra) and against the second BoNT but did not protect mice against BoNT/A (Hall) or BoNT/F (Langeland). Conclusion. The second BoNT thus fulfilled classic criteria for being designated BoNT/H. IBCA10-7060 is the first C. botulinum type Bh strain to be identified. BoNT/H is the first new botulinum toxin type to be recognized in >40 years, and its recognition could not have been accomplished without the availability of the mouse bioassay.

We sequenced the 2 botulinum toxin gene clusters of Clostridium botulinum strain IBCA10-7060 type Bh. The sequence of bont/H differed substantially from the sequences of the 7 known bont genes for toxin types A-G. The 5' one-third terminus of bont/H that codes for the botulinum toxin light chain differed markedly from the light chain coding sequences of toxin types A-G. The 3' two-thirds terminus of bont/H that codes for the botulinum toxin heavy chain contained a novel Hn translocation domain coding sequence and a nonneutralizing type A-like Hc binding domain coding sequence. bont/H was part of an orfX toxin gene cluster that was located at a unique chromosomal site distant from those used by other botulinum toxin gene clusters. The bont/B sequence was similar to that of subtype bont/B2 and was located within its ha toxin gene cluster at the oppA/brnQ site. Our findings further establish that C. botulinum IBCA10-7060 produces novel BoNT/H.

Botulinum neurotoxins (BoNTs) are produced by Clostridium botulinum and cause the fatal disease botulism, a flaccid paralysis of the muscle. BoNTs are released together with several auxiliary proteins as progenitor toxin complexes (PTCs) to become highly potent oral poisons. Here, we report the structure of a ∼760 kDa 14-subunit large PTC of serotype A (L-PTC/A) and reveal insight into its absorption mechanism. Using a combination of X-ray crystallography, electron microscopy, and functional studies, we found that L-PTC/A consists of two structurally and functionally independent sub-complexes. A hetero-dimeric 290 kDa complex protects BoNT, while a hetero-dodecameric 470 kDa complex facilitates its absorption in the harsh environment of the gastrointestinal tract. BoNT absorption is mediated by nine glycan-binding sites on the dodecameric sub-complex that forms multivalent interactions with carbohydrate receptors on intestinal epithelial cells. We identified monosaccharides that blocked oral BoNT intoxication in mice, which suggests a new strategy for the development of preventive countermeasures for BoNTs based on carbohydrate receptor mimicry.

Clostridium botulinum Group I and Clostridium sporogenes are closely related bacteria responsible for foodborne, infant and wound botulism. A comparative genomic study with 556 highly diverse strains of C. botulinum Group I and C. sporogenes (including 417 newly sequenced strains) has been carried out to characterise the genetic diversity and spread of these bacteria and their neurotoxin genes. Core genome single-nucleotide polymorphism (SNP) analysis revealed two major lineages; C. botulinum Group I (most strains possessed botulinum neurotoxin gene(s) of types A, B and/or F) and C. sporogenes (some strains possessed a type B botulinum neurotoxin gene). Both lineages contained strains responsible for foodborne, infant and wound botulism. A new C. sporogenes cluster was identified that included five strains with a gene encoding botulinum neurotoxin sub-type B1. There was significant evidence of horizontal transfer of botulinum neurotoxin genes between distantly related bacteria. Population structure/diversity have been characterised, and novel associations discovered between whole genome lineage, botulinum neurotoxin sub-type variant, epidemiological links to foodborne, infant and wound botulism, and geographic origin. The impact of genomic and physiological variability on the botulism risk has been assessed. The genome sequences are a valuable resource for future research (e.g., pathogen biology, evolution of C. botulinum and its neurotoxin genes, improved pathogen detection and discrimination), and support enhanced risk assessments and the prevention of botulism.

AbstractBotulinum neurotoxins (BoNTs), the causative agents of botulism, are proteins consisting of an N-terminal catalytic Light Chain (LC) and a C-terminal Heavy Chain (HC), which comprises a LC-translocation domain (HC N) and a receptor binding domain (HC C). There are seven BoNT serotypes (A-G) and multiple subtypes. Currently, there is no approved vaccine against botulism available for human use. Several studies have investigated BoNT domains, multi-domains, or mutated holotoxins as candidate BoNT vaccines. However, residual toxicity has been observed in mutated full-length BoNTs and multi-domain (LCHC N) vaccines. In this study, six-individual point substitutions (6M) were introduced into the substrate binding and cleavage sites, zinc binding motif, and LC translocation region of LCHC N/A1 and LCHC N/B1, which possessed no detectable toxicity in mice at 200 μg, being >40-million-fold less toxic than full-length BoNT. IP immunization of mice with 6MLCHC N/A1 or 6MLCHC N/B1 elicited a strong IgG response that protected against high dose challenge with BoNT/A1 or BoNT/B1, respectively. 4MBoNT/B1 and 7MBoNT/B1 were also engineered and found to elicit strong IgG responses that protected against high dose challenge with BoNT/B1. Thus, multi-domain inactivation may yield potent and safe vaccines against other BoNT-serotypes and BoNT-like proteins. The strategy of systematic inactivation of multiple functional domains by targeted single amino acid substitutions to decrease toxicity, combined with investigations of the most immunogenic and protective domains, provides a robust platform for protein toxin vaccines for humans and animals.

Toxin production and sporulation are key determinants of pathogenesis in Clostridia. Clostridium botulinum produces the most potent toxin known, the botulinum neurotoxin (BoNT), which blocks neurotransmission and causes a life-threatening paralysis called botulism. BoNT production and sporulation share a common regulator Spo0A, which suggests coordination of the two traits. Describing the relationship between toxin production and sporulation is fundamental toward understanding the evolutionary and mechanistic logic and further control of clostridial pathogenesis. Here, we provide the first single-cell resolution analysis of BoNT production and sporulation in C. botulinum type E cultures by using a fluorescent reporter to follow the activation of the BoNT gene promoter. BoNT was expressed by a subpopulation of cells and was released through Spo0A-mediated autolysis of vegetative cells or upon release of mature spores. All possible combinations of toxin production and sporulation resided in wild-type C. botulinum type E cultures, indicating neither tight co-regulation nor strict independence of the two traits. The population structure and the degree of overall heterogeneity were affected by growth phase and environmental conditions, with cold temperature inducing large diversity and cultural stability, in line with adaptation to fluctuating temperatures that C. botulinum type E strains likely encounter in nature. We also observed Spo0A-independent BoNT production by a small cell subpopulation of the spo0A -null strain. Our observation of toxin gene activation in the forespore invites speculation on possible alternative biological roles for toxin production by vegetative and sporulating cells and reflection on the evolutionary rationale of toxin production with respect to the ecology of spore-forming pathogens. Toxin production and sporulation are key determinants of pathogenesis in Clostridia . Toxins cause the clinical manifestation of clostridial diseases, including diarrhea and colitis, tissue damage, and systemic effects on the nervous system. Spores ensure long-term survival and persistence in the environment, act as infectious agents, and initiate the host tissue colonization leading to infection. Understanding the interplay between toxin production and sporulation and their coordination in bacterial cells and cultures provides novel intervention points for controlling the public health and food safety risks caused by clostridial diseases. We demonstrate environmentally driven cellular heterogeneity in botulinum neurotoxin and spore production in Clostridium botulinum type E populations and discuss the biological rationale of toxin and spore production in the pathogenicity and ecology of C. botulinum . The results invite to reassess the epidemiology of botulism and may have important implications in the risk assessment and risk management strategies in food processing and human and animal health.