Clostridium botulinum Strain Af84 Contains Three Neurotoxin Gene Clusters: Bont/A2, bont/F4 and bont/F5

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.     

Analysis of the neurotoxin complex genes in Clostridium botulinum A1-A4 and B1 strains: BoNT/A3, /Ba4 and /B1 clusters are located within plasmids

Background

Clostridium botulinum and related clostridial species express extremely potent neurotoxins known as botulinum neurotoxins (BoNTs) that cause long-lasting, potentially fatal intoxications in humans and other mammals. The amino acid variation within the BoNT is used to categorize the species into seven immunologically distinct BoNT serotypes (A–G) which are further divided into subtypes. The BoNTs are located within two generally conserved gene arrangements known as botulinum progenitor complexes which encode toxin-associated proteins involved in toxin stability and expression.

Methodology/Principal Findings

Because serotype A and B strains are responsible for the vast majority of human botulism cases worldwide, the location, arrangement and sequences of genes from eight different toxin complexes representing four different BoNT/A subtypes (BoNT/A1-Ba4) and one BoNT/B1 strain were examined. The bivalent Ba4 strain contained both the BoNT/A4 and BoNT/bvB toxin clusters. The arrangements of the BoNT/A3 and BoNT/A4 subtypes differed from the BoNT/A1 strains and were similar to those of BoNT/A2. However, unlike the BoNT/A2 subtype, the toxin complex genes of BoNT/A3 and BoNT/A4 were found within large plasmids and not within the chromosome. In the Ba4 strain, both BoNT toxin clusters (A4 and bivalent B) were located within the same 270 kb plasmid, separated by 97 kb. Complete genomic sequencing of the BoNT/B1 strain also revealed that its toxin complex genes were located within a 149 kb plasmid and the BoNT/A3 complex is within a 267 kb plasmid.

Conclusions/Significance

Despite their size differences and the BoNT genes they contain, the three plasmids containing these toxin cluster genes share significant sequence identity. The presence of partial insertion sequence (IS) elements, evidence of recombination/gene duplication events, and the discovery of the BoNT/A3, BoNT/Ba4 and BoNT/B1 toxin complex genes within plasmids illustrate the different mechanisms by which these genes move among diverse genetic backgrounds of C. botulinum.     

Sequence Diversity of Genes Encoding Botulinum Neurotoxin Type F

Botulism due to type F botulinum neurotoxin (BoNT/F) is rare (<1% of cases), and only a limited number of clostridial strains producing this toxin type have been isolated. As a result, analysis of the diversity of genes encoding BoNT/F has been challenging. In this study, the entire bont/F nucleotide sequences were determined from 33 type F botulinum toxin-producing clostridial strains isolated from environmental sources and botulism outbreak investigations. We examined proteolytic and nonproteolytic Clostridium botulinum type F strains, bivalent strains, including Bf and Af, and Clostridium baratii type F strains. Phylogenetic analysis revealed that the bont/F genes examined formed 7 subtypes (F1 to F7) and that the nucleotide sequence identities of these subtypes differed by up to 25%. The genes from proteolytic (group I) C. botulinum strains formed subtypes F1 through F5, while the genes from nonproteolytic (group II) C. botulinum strains formed subtype F6. Subtype F7 was composed exclusively of bont/F genes from C. baratii strains. The region of the bont/F5 gene encoding the neurotoxin light chain was found to be highly divergent compared to the other subtypes. Although the bont/F5 nucleotide sequences were found to be identical in strains harboring this gene, the gene located directly upstream (ntnh/F) demonstrated sequence variation among representative strains of this subtype. These results demonstrate that extensive nucleotide diversity exists among genes encoding type F neurotoxins from strains with different phylogenetic backgrounds and from various geographical sources.Botulism is a potentially fatal disease caused solely by the action of serologically distinct neurotoxins (BoNT/A, -B, -C, -D, -E, -F, or -G) which prevent acetylcholine release at neuromuscular junctions, resulting in paralysis. Food-borne botulism may result from the ingestion of a preformed toxin that is produced in inadequately preserved food. Under certain conditions, botulinum neurotoxin-producing Clostridium sp. may colonize and produce toxin in wounds (wound botulism) or in the intestine (infant botulism or adult colonization). Globally, human botulism cases are associated with botulinum neurotoxin serotypes A, B, E, and rarely F. The Centers for Disease Control and Prevention (CDC) maintains active surveillance for botulism cases in the United States. Of 1,269 U.S. cases of botulism reported to the CDC between 1981 and 2002, approximately 1% were due to type F toxin (13). An additional 10 cases of type F botulism were reported to the CDC from 2003 to 2007 (http://www.cdc.gov/nationalsurveillance/botulism_surveillance.html).Type F botulism was first described in 1960 following an outbreak occurring in Denmark involving liver paste (30). The organism isolated in this outbreak metabolically resembled proteolytic Clostridium botulinum strains of types A and B. In a subsequent outbreak, type F toxin was found to be produced by a nonproteolytic C. botulinum strain isolated from venison jerky (29). Bivalent toxin-producing strains have been described, including Bf strains isolated from infants in the United States and England (1, 16, 17, 35) and an Af strain isolated from individuals in Argentina with food-borne botulism (11). Bivalent strains may produce higher titers of one toxin type, which are denoted with a capital letter. The only reported organism isolated from infants with botulism due to type F toxin alone (i.e., not associated with additional serotypes as in bivalent strains) is Clostridium baratii (2, 14, 24). In addition, C. baratii type F has been isolated from adults with botulism (28) as well as suspect foods associated with botulism cases (15; CDC, unpublished data).Botulinum neurotoxin genes (bont) are typically found within toxin gene clusters that include other genes encoding components of the toxin complex (ha70, ha17, ha33, ntnh), regulatory proteins (botR), or proteins with unknown functions (p47, orfX1, orfX2, orfX3). Two general toxin gene cluster arrangements have been described, including the orfX cluster (orfX3-orfX2-orfX1-botR-p47-ntnh-bont) and the ha cluster (ha70-ha17-ha33-botR-ntnh-bont) (21, 22). The bont/F genes of type F and type Bf strains examined by Hill et al. (21) were found in an orfX cluster.The amino acid sequence identities of the BoNT serotypes A to G range from approximately 35 to 70% (36). In addition, within nearly all toxin serotypes, various levels of amino acid sequence variation have been observed, resulting in the identification of toxin subtypes (20, 36, 37).Although a limited number of genes encoding type F botulinum neurotoxin have been sequenced, a comparison of sequences available in public databases indicates that significant diversity exists within this serotype. The nucleotide sequence identity of the type F neurotoxin gene from the proteolytic strain Langeland differs from that of the gene in the nonproteolytic strain 202F by 7%. The type F gene from C. baratii strain ATCC 43756 differs from those of Langeland and 202F by 18% and 20%, respectively. Although the bivalent (Bf) strain CDC3281 is phenotypically proteolytic, the toxin gene shows greater similarity to those from nonproteolytic strains (34). In addition to metabolic differences observed between proteolytic and nonproteolytic C. botulinum strains as well as C. baratii, these organisms are phylogenetically distinct based on differences among their 16S rRNA sequences (5, 20).In order to define the degree of genetic diversity among strains encoding botulinum neurotoxin type F, we sequenced the bont/F gene and partially characterized the toxin gene cluster by using a panel of 33 strains with diverse origins. These strains were selected from those available in the CDC culture collection as well as several isolated in Argentina. The only reported Af strains have been isolated in Argentina. Among 68 outbreaks of serotype-confirmed food-borne botulism in Argentina between 1922 and 2007, type F was isolated in two outbreaks, and type Af was isolated in one outbreak. In addition, Lúquez et al. (26) reported isolation of type F and Af strains from Argentine soils.Here, we report that analysis of the bont/F genes from the strains examined in this study revealed a high degree of nucleotide sequence heterogeneity and the identification of seven type F subtypes (F1 to F7). In addition, the nucleotide sequence of one subtype (F5) has not been previously reported and contains evidence of recombination compared to the other subtypes.     

Sequencing the botulinum neurotoxin gene and related genes in Clostridium botulinum type E strains reveals orfx3 and a novel type E neurotoxin subtype

Three Clostridium botulinum type E strains were sequenced for the botulinum neurotoxin (BoNT) gene cluster, and 11 type E strains, representing a wide biodiversity, were sequenced for the bont/E gene. The total length of the BoNT/E gene cluster was 12,908 bp, and a novel gene (partial) designated orfx3, together with the complete orfx2 gene, was identified in the three type E strains for the first time. Apart from orfx3, the structure and organization of the neurotoxin gene cluster of the three strains were identical to those of previously published ones. Only minor differences (≤3%) in the nucleotide sequences of the gene cluster components were observed among the three strains and the published BoNT/E-producing clostridia. The orfx3, orfx2, orfx1, and p47 gene sequences of the three type E strains shared homologies of 81%, 67 to 76%, 78 to 79%, and 79 to 85%, respectively, with published sequences for type A1 and A2 C. botulinum. Analysis of bont/E from the 14 type E strains and 19 previously published BoNT/E-producing clostridia revealed six neurotoxin subtypes, with a new distinct subtype consisting of three Finnish isolates alone. The amino acid sequence of the subtype E6 neurotoxin differed 3 to 6% from the other subtypes, suggesting that these subtype E6 neurotoxins may possess specific antigenic or functional properties.     

Real-time PCR detection of the nontoxic nonhemagglutinin gene as a rapid screening method for bacterial isolates harboring the botulinum neurotoxin (A–G) gene complex

Botulinum neurotoxin (BoNT) producing clostridia contain genes encoding a specific neurotoxin serotype (A–G) and nontoxic associated proteins that form the toxin complex. The nontoxic nonhemagglutinin (NTNH) is a conserved component of the toxin complex in all seven toxin types. A real-time PCR assay that utilizes a locked nucleic acid hydrolysis probe to target the NTNH gene was developed to detect bacterial strains harboring the botulinum neurotoxin gene cluster. The specificity of the assay for Clostridium botulinum types A–G, Clostridium butyricum type E and Clostridium baratii type F was demonstrated using a panel of 73 BoNT producing clostridia representing all seven toxin serotypes. In addition, exclusivity of the assay was demonstrated using non-botulinum toxin producing clostridia (7 strains) and various enteric bacterial strains (n = 27). Using purified DNA, the assay had a sensitivity of 4–95 genome equivalents. C. botulinum type A was detected directly in spiked stool samples at 10²–10³ CFU/ml. Stool spiked with 1 CFU/ml was detected when the sample was inoculated into enrichment broth and incubated for 24 h. These results indicate that the NTNH real-time PCR assay can be used to screen enrichment cultures of primary specimens at earlier time points (24 h) than by toxin detection of unknown culture supernatants (up to 5 days).     

Genetic Characterization and Comparison of Clostridium botulinum Isolates from Botulism Cases in Japan between 2006 and 2011

Genetic characterization was performed for 10 group I Clostridium botulinum strains isolated from botulism cases in Japan between 2006 and 2011. Of these, 1 was type A, 2 were type B, and 7 were type A(B) {carrying a silent bont/B [bont/(B)] gene} serotype strains, based on botulinum neurotoxin (BoNT) production. The type A strain harbored the subtype A1 BoNT gene (bont/A1), which is associated with the ha gene cluster. The type B strains carried bont/B5 or bont/B6 subtype genes. The type A(B) strains carried bont/A1 identical to that of type A(B) strain NCTC2916. However, bont/(B) genes in these strains showed single-nucleotide polymorphisms (SNPs) among strains. SNPs at 2 nucleotide positions of bont/(B) enabled classification of the type A(B) strains into 3 groups. Pulsed-field gel electrophoresis (PFGE) and multiple-locus variable-number tandem-repeat analysis (MLVA) also provided consistent separation results. In addition, the type A(B) strains were separated into 2 lineages based on their plasmid profiles. One lineage carried a small plasmid (5.9 kb), and another harbored 21-kb plasmids. To obtain more detailed genetic information about the 10 strains, we sequenced their genomes and compared them with 13 group I C. botulinum genomes in a database using whole-genome SNP analysis. This analysis provided high-resolution strain discrimination and enabled us to generate a refined phylogenetic tree that provides effective traceability of botulism cases, as well as bioterrorism materials. In the phylogenetic tree, the subtype B6 strains, Okayama2011 and Osaka05, were distantly separated from the other strains, indicating genomic divergence of subtype B6 strains among group I strains.     

Differentiation of Clostridium botulinum Serotype A Strains by Multiple-Locus Variable-Number Tandem-Repeat Analysis

Ten variable-number tandem-repeat (VNTR) regions identified within the complete genomic sequence of Clostridium botulinum strain ATCC 3502 were used to characterize 59 C. botulinum strains of the botulism neurotoxin A1 (BoNT/A1) to BoNT/A4 (BoNT/A1-A4) subtypes to determine their ability to discriminate among the serotype A strains. Two strains representing each of the C. botulinum serotypes B to G, including five bivalent strains, and two strains of the closely related species Clostridium sporogenes were also tested. Amplified fragment length polymorphism analyses revealed the genetic diversity among the serotypes and the high degree of similarity among many of the BoNT/A1 strains. The 10 VNTR markers amplified fragments within all of the serotype A strains but were less successful with strains of other serotypes. The composite multiple-locus VNTR analysis of the 59 BoNT/A1-A4 strains and 3 bivalent B strains identified 38 different genotypes. Thirty genotypes were identified among the 53 BoNT/A1 and BoNT/A1(B) strains, demonstrating discrimination below the subtype level. Contaminating DNA within crude toxin preparations of three BoNT/A subtypes (BoNT/A1 to BoNT/A3) also supported amplification of all of the VNTR regions. These markers provide clinical and forensics laboratories with a rapid, highly discriminatory tool to distinguish among C. botulinum BoNT/A1 strains for investigations of botulism outbreaks.     

Genetic Diversity among Clostridium botulinum Strains Harboring bont/A2 and bont/A3 Genes

Clostridium botulinum type A strains are known to be genetically diverse and widespread throughout the world. Genetic diversity studies have focused mainly on strains harboring one type A botulinum toxin gene, bont/A1, although all reported bont/A gene variants have been associated with botulism cases. Our study provides insight into the genetic diversity of C. botulinum type A strains, which contain bont/A2 (n = 42) and bont/A3 (n = 4) genes, isolated from diverse samples and geographic origins. Genetic diversity was assessed by using bont nucleotide sequencing, content analysis of the bont gene clusters, multilocus sequence typing (MLST), and pulsed-field gel electrophoresis (PFGE). Sequences of bont genes obtained in this study showed 99.9 to 100% identity with other bont/A2 or bont/A3 gene sequences available in public databases. The neurotoxin gene clusters of the subtype A2 and A3 strains analyzed in this study were similar in gene content. C. botulinum strains harboring bont/A2 and bont/A3 genes were divided into six and two MLST profiles, respectively. Four groups of strains shared a similarity of at least 95% by PFGE; the largest group included 21 out of 46 strains. The strains analyzed in this study showed relatively limited genetic diversity using either MLST or PFGE.     

Whole-Genome Single-Nucleotide-Polymorphism Analysis for Discrimination of Clostridium botulinum Group I Strains

Clostridium botulinum is a genetically diverse Gram-positive bacterium producing extremely potent neurotoxins (botulinum neurotoxins A through G [BoNT/A-G]). The complete genome sequences of three strains harboring only the BoNT/A1 nucleotide sequence are publicly available. Although these strains contain a toxin cluster (HA⁺ OrfX⁻) associated with hemagglutinin genes, little is known about the genomes of subtype A1 strains (termed HA⁻ OrfX⁺) that lack hemagglutinin genes in the toxin gene cluster. We sequenced the genomes of three BoNT/A1-producing C. botulinum strains: two strains with the HA⁺ OrfX⁻ cluster (69A and 32A) and one strain with the HA⁻ OrfX⁺ cluster (CDC297). Whole-genome phylogenic single-nucleotide-polymorphism (SNP) analysis of these strains along with other publicly available C. botulinum group I strains revealed five distinct lineages. Strains 69A and 32A clustered with the C. botulinum type A1 Hall group, and strain CDC297 clustered with the C. botulinum type Ba4 strain 657. This study reports the use of whole-genome SNP sequence analysis for discrimination of C. botulinum group I strains and demonstrates the utility of this analysis in quickly differentiating C. botulinum strains harboring identical toxin gene subtypes. This analysis further supports previous work showing that strains CDC297 and 657 likely evolved from a common ancestor and independently acquired separate BoNT/A1 toxin gene clusters at distinct genomic locations.     

Arrangement of the Clostridium baratii F7 Toxin Gene Cluster with Identification of a σ Factor That Recognizes the Botulinum Toxin Gene Cluster Promoters

Botulinum neurotoxin (BoNT) is the most poisonous substances known and its eight toxin types (A to H) are distinguished by the inability of polyclonal antibodies that neutralize one toxin type to neutralize any of the other seven toxin types. Infant botulism, an intestinal toxemia orphan disease, is the most common form of human botulism in the United States. It results from swallowed spores of Clostridium botulinum (or rarely, neurotoxigenic Clostridium butyricum or Clostridium baratii) that germinate and temporarily colonize the lumen of the large intestine, where, as vegetative cells, they produce botulinum toxin. Botulinum neurotoxin is encoded by the bont gene that is part of a toxin gene cluster that includes several accessory genes. We sequenced for the first time the complete botulinum neurotoxin gene cluster of nonproteolytic C. baratii type F7. Like the type E and the nonproteolytic type F6 botulinum toxin gene clusters, the C. baratii type F7 had an orfX toxin gene cluster that lacked the regulatory botR gene which is found in proteolytic C. botulinum strains and codes for an alternative σ factor. In the absence of botR, we identified a putative alternative regulatory gene located upstream of the C. baratii type F7 toxin gene cluster. This putative regulatory gene codes for a predicted σ factor that contains DNA-binding-domain homologues to the DNA-binding domains both of BotR and of other members of the TcdR-related group 5 of the σ⁷⁰ family that are involved in the regulation of toxin gene expression in clostridia. We showed that this TcdR-related protein in association with RNA polymerase core enzyme specifically binds to the C. baratii type F7 botulinum toxin gene cluster promoters. This TcdR-related protein may therefore be involved in regulating the expression of the genes of the botulinum toxin gene cluster in neurotoxigenic C. baratii.     

Two Novel Toxin Variants Revealed by Whole-Genome Sequencing of 175 Clostridium botulinum Type E Strains

We sequenced 175 Clostridium botulinum type E strains isolated from food, clinical, and environmental sources from northern Canada and analyzed their botulinum neurotoxin (bont) coding sequences (CDSs). In addition to bont/E1 and bont/E3 variant types, neurotoxin sequence analysis identified two novel BoNT type E variants termed E10 and E11. Strains producing type E10 were found along the eastern coastlines of Hudson Bay and the shores of Ungava Bay, while strains producing type E11 were only found in the Koksoak River region of Nunavik. Strains producing BoNT/E3 were widespread throughout northern Canada, with the exception of the coast of eastern Hudson Bay.     

Genetic Analysis of Type E Botulinum Toxin-Producing Clostridium butyricum Strains

Type E botulinum toxin (BoNT/E)-producing Clostridium butyricum strains isolated from botulism cases or soil specimens in Italy and China were analyzed by using nucleotide sequencing of the bont/E gene, random amplified polymorphic DNA (RAPD) assay, pulsed-field gel electrophoresis (PFGE), and Southern blot hybridization for the bont/E gene. Nucleotide sequences of the bont/E genes of 11 Chinese isolates and of the Italian strain BL 6340 were determined. The nucleotide sequences of the bont/E genes of 11 C. butyricum isolates from China were identical. The deduced amino acid sequence of BoNT/E from the Chinese isolates showed 95.0 and 96.9% identity with those of BoNT/E from C. butyricum BL 6340 and Clostridium botulinum type E, respectively. The BoNT/E-producing C. butyricum strains were divided into the following three clusters based on the results of RAPD assay, PFGE profiles of genomic DNA digested with SmaI or XhoI, and Southern blot hybridization: strains associated with infant botulism in Italy, strains associated with food-borne botulism in China, and isolates from soil specimens of the Weishan lake area in China. A DNA probe for the bont/E gene hybridized with the nondigested chromosomal DNA of all toxigenic strains tested, indicating chromosomal localization of the bont/E gene in C. butyricum. The present results suggest that BoNT/E-producing C. butyricum is clonally distributed over a vast area.     

Immunoprecipitation of Native Botulinum Neurotoxin Complexes from Clostridium botulinum Subtype A Strains

Botulinum neurotoxins (BoNTs) naturally exist as components of protein complexes containing nontoxic proteins. The nontoxic proteins impart stability of BoNTs in the gastrointestinal tract and during purification and handling. The two primary neurotoxin complexes (TCs) are (i) TC1, consisting of BoNT, nontoxin-nonhemagglutinin (NTNH), and hemagglutinins (HAs), and (ii) TC2, consisting of BoNT and NTNH (and possibly OrfX proteins). In this study, BoNT/A subtypes A1, A2, A3, and A5 were examined for the compositions of their TCs in culture extracts using immunoprecipitation (IP). IP analyses showed that BoNT/A1 and BoNT/A5 form TC1s, while BoNT/A2 and BoNT/A3 form TC2s. A Clostridium botulinum host strain expressing recombinant BoNT/A4 (normally present as a TC2) from an extrachromosomal plasmid formed a TC1 with complexing proteins from the host strain, indicating that the HAs and NTNH encoded on the chromosome associated with the plasmid-encoded BoNT/A4. Strain NCTC 2916 (A1/silent B1), which carries both an ha silent bont/b cluster and an orfX bont/a1 cluster, was also examined. IP analysis revealed that NCTC 2916 formed only a TC2 containing BoNT/A1 and its associated NTNH. No association between BoNT/A1 and the nontoxic proteins from the silent bont/b cluster was detected, although the HAs were expressed as determined by Western blotting analysis. Additionally, NTNH and HAs from the silent bont/b cluster did not form a complex in NCTC 2916. The stabilities of the two types of TC differed at various pHs and with addition of KCl and NaCl. TC1 complexes were more stable than TC2 complexes. Mouse serum stabilized TC2, while TC1 was unaffected.     

Analysis of the Botulinum Neurotoxin Type F Gene Clusters in Proteolytic and Nonproteolytic Clostridium botulinum and Clostridium barati

Comparison of genes encoding type F botulinum neurotoxin progenitor complex in strains of proteolytic Clostridium botulinum strain Langeland, nonproteolytic Clostridium botulinum strain 202F, and Clostridium barati strain ATCC 43256 reveals an identical organization of genes encoding a protein of molecular mass of approx. 47 kDa (P-47), nontoxic-nonhemagglutinin (NTNH) and botulinum toxin (BoNT). Although homology between the protein components of the complexes encoded by these different species all producing botulinum neurotoxin type F is considerable (approx. 69–88% identity), exceptionally high homology is observed between the C-termini of the P-47s (approx. 96% identity) and the NTNHs (approx. 94% identity) encoded by Clostridium botulinum type F strain Langeland and Clostridium botulinum type A strain Kyoto. Such a region of extremely high sequence identity is strongly indicative of recombination in these strains synthesizing botulinum neurotoxins of different antigenic types. Received: 13 April 1998 / Accepted: 9 May 1998     

Holotoxin Activity of Botulinum Neurotoxin Subtype A4 Originating from a Nontoxigenic Clostridium botulinum Expression System

Clostridium botulinum subtype A4 neurotoxin (BoNT/A4) is naturally expressed in the dual-toxin-producing C. botulinum strain 657Ba at 100× lower titers than BoNT/B. In this study, we describe purification of recombinant BoNT/A4 (rBoNT/A4) expressed in a nonsporulating and nontoxigenic C. botulinum expression host strain. The rBoNT/A4 copurified with nontoxic toxin complex components provided in trans by the expression host and was proteolytically cleaved to the active dichain form. Activity of the recombinant BoNT/A4 in mice and in human neuronal cells was about 1,000-fold lower than that of BoNT/A1, and the recombinant BoNT/A4 was effectively neutralized by botulism heptavalent antitoxin. A previous report using recombinant truncated BoNT/A4 light chain (LC) expressed in Escherichia coli has indicated reduced stability and activity of BoNT/A4 LC compared to BoNT/A1 LC, which was surmounted by introduction of a single-amino-acid substitution, I264R. In order to determine whether this mutation would also affect the holotoxin activity of BoNT/A4, a recombinant full-length BoNT/A4 carrying this mutation as well as a second mutation predicted to increase solubility (L260F) was produced in the clostridial expression system. Comparative analyses of the in vitro, cellular, and in vivo activities of rBoNT/A4 and rBoNT/A4-L260F I264R showed 1,000-fold-lower activity than BoNT/A1 in both the mutated and nonmutated BoNT/A4. This indicates that these mutations do not alter the activity of BoNT/A4 holotoxin. In summary, a recombinant BoNT from a dual-toxin-producing strain was expressed and purified in an endogenous clostridial expression system, allowing analysis of this toxin.     

Neurotoxin Gene Clusters in Clostridium botulinum Type Ab Strains

There is limited knowledge of the neurotoxin gene diversity among Clostridium botulinum type Ab strains. Only the sequences of the bont/A and bont/B genes in C. botulinum type Ab strain CDC1436 and the sequence of the bont/B gene in C. botulinum type Ab strain CDC588 have been reported. In this study, we sequenced the entire bont/A- and bont/B-associated neurotoxin gene clusters of C. botulinum type Ab strain {"type":"entrez-protein","attrs":{"text":"CDC41370","term_id":"524503451","term_text":"CDC41370"}}CDC41370 and the bont/A gene of strain CDC588. In addition, we analyzed the organization of the neurotoxin gene clusters in strains CDC588 and CDC1436. The bont/A nucleotide sequence of strain {"type":"entrez-protein","attrs":{"text":"CDC41370","term_id":"524503451","term_text":"CDC41370"}}CDC41370 differed from those of the known bont/A subtypes A1 to A4 by 2 to 7%, and the predicted amino acid sequence differed by 4% to 14%. The bont/B nucleotide sequence in strain {"type":"entrez-protein","attrs":{"text":"CDC41370","term_id":"524503451","term_text":"CDC41370"}}CDC41370 showed 99.7% identity to the sequence of subtype B1. The bont/A nucleotide sequence of strain CDC588 was 99.9% identical to that of subtype A1. Although all of the C. botulinum type Ab strains analyzed contained the two sets of neurotoxin clusters, similar to what has been found in other bivalent strains, the intergenic spacing of p21-orfX1 and orfX2-orfX3 varied among these strains. The type Ab strains examined in this study had differences in their toxin gene cluster compositions and bont/A and bont/B nucleotide sequences, suggesting that they may have arisen from separate recombination events.Clostridium botulinum is a gram-positive anaerobic bacterium that produces an extremely potent toxin, the botulinum neurotoxin (BoNT). There are seven serologically distinct types of BoNT (serotypes A through G). Although most strains of C. botulinum express a single toxin serotype, some isolates have been shown to produce more than one, namely, Ab, Af, Ba, and Bf (11). In addition, many strains designated type A by mouse bioassay harbor nucleotide sequences for both type A and B toxins (6). These strains have been designated A(B) to indicate the presence of the bont/B gene without type B-specific toxicity.Based on phylogenetic analysis of the neurotoxin gene sequences, four subtypes have been identified within serotype A and five subtypes within serotype B (12). The neurotoxin gene nucleotide sequences of these subtypes differ by up to 8%, and the predicted amino acid sequences differ by up to 16%. In addition, the genes encoding components of the toxin complexes are arranged in clusters that differ in composition and organization (14) (Fig. ​(Fig.1).1). The toxin gene cluster of subtype A1 (termed ha cluster) includes the gene encoding the nontoxic nonhemagglutinin (ntnh), a regulatory gene (botR), and an operon encoding three hemagglutinins (ha70, ha33, and ha17). The toxin gene clusters containing bont/A2 or bont/A3 (termed orfX cluster) include the ntnh and p21 (analogous to botR) genes and several genes of unknown function (orfX1, orfX2, orfX3, and p47). Type Ba and A(B) strains contain two sets of neurotoxin cluster genes in which ha70, ha33, and ha17 are associated with the bont/B gene, and orfX1, orfX2, orfX3, and p47 are associated with the bont/A gene. In addition, some A1 strains contain a neurotoxin gene cluster that is similar to those in A2 and A3, but the bont/A nucleotide sequence is 99.9% identical to that in other A1 strains. These strains have been designated HA⁻ Orfx⁺ A1 (14). The neurotoxin gene cluster in type B strains includes the ntnh, botR, ha70, ha33, and ha17 genes. Notably, no differences in the neurotoxin gene cluster arrangements among the subtypes within serotype B have been reported.Open in a separate windowFIG. 1.Toxin gene cluster arrangements for BoNT type A-producing strains, including Ab, A(B), and Ba strains.Although several studies have described the organization and the nucleotide sequences of the neurotoxin gene cluster components among type A and B strains [including type Ba and A(B) strains], there is limited information regarding the diversity of the neurotoxin cluster genes among C. botulinum type Ab strains. The nucleotide sequences of the bont/A and bont/B genes in C. botulinum type Ab strain CDC1436 and the sequence of the bont/B gene of C. botulinum type Ab strain CDC588 have been previously reported; strain CDC1436 harbors a bont/A2 gene, and both strains CDC1436 and CDC588 harbor a bont/bvB gene (12, 15). Four additional type Ab strains from Italy have been analyzed by a restriction fragment length polymorphism method to determine the bont/A and bont/B subtypes (7, 9). To the best of our knowledge, the complete nucleotide sequences of the neurotoxin gene clusters in C. botulinum type Ab strains have not been reported. Thus, the objective of this study was to analyze the neurotoxin gene cluster composition in three C. botulinum type Ab strains ({"type":"entrez-protein","attrs":{"text":"CDC41370","term_id":"524503451","term_text":"CDC41370"}}CDC41370, CDC588, and CDC1436) available in the CDC strain collection. We report differences in bont/A gene sequence among type Ab strains, including the identification of a novel bont/A nucleotide sequence in strain {"type":"entrez-protein","attrs":{"text":"CDC41370","term_id":"524503451","term_text":"CDC41370"}}CDC41370, and describe differences in the organization of the neurotoxin gene clusters among these strains.     

Detection of Type A, B, E, and F Clostridium botulinum Neurotoxins in Foods by Using an Amplified Enzyme-Linked Immunosorbent Assay with Digoxigenin-Labeled Antibodies

An amplified enzyme-linked immunosorbent assay (ELISA) for the detection of Clostridium botulinum complex neurotoxins was evaluated for its ability to detect these toxins in food. The assay was found to be suitable for detecting type A, B, E, and F botulinum neurotoxins in a variety of food matrices representing liquids, solid, and semisolid food. Specific foods included broccoli, orange juice, bottled water, cola soft drinks, vanilla extract, oregano, potato salad, apple juice, meat products, and dairy foods. The detection sensitivity of the test for these botulinum complex serotypes was found to be 60 pg/ml (1.9 50% lethal dose [LD₅₀]) for botulinum neurotoxin type A (BoNT/A), 176 pg/ml (1.58 LD₅₀) for BoNT/B, 163 pg/ml for BoNT/E (4.5 LD₅₀), and 117 pg/ml for BoNT/F (less than 1 LD₅₀) in casein buffer. The test could also readily detect 2 ng/ml of neurotoxins type A, B, E, and F in a variety of food samples. For specificity studies, the assay was also used to test a large panel of type A C. botulinum, a smaller panel of proteolytic and nonproteolytic type B, E, and F neurotoxin-producing Clostridia, and nontoxigenic organisms using an overnight incubation of toxin production medium. The assay appears to be an effective tool for large-scale screening of the food supply in the event of a botulinum neurotoxin contamination event.     

Conserved structure of genes encoding components of botulinum neurotoxin complex M and the sequence of the gene coding for the nontoxic component in nonproteolyticClostridium botulinum type F

For investigation of the genes of proteins associated in vivo with botulinum neurotoxin (BoNT), polymerase chain reaction (PCR) experiments were carried out with oligonucleotide primers designed to regions of the nontoxic-nonhemagglutinin (NTNH) gene ofClostridium botulinum type C. The primers were used to amplify a DNA fragment from genomic DNA ofC. botulinum types A, B, E, F, G and toxigenic strains ofClostridium barati andClostridium butyricum. The amplified product from all of these strains hybridized with an internal oligonucleotide probe, whereas all nontoxigenic clostridia tested gave no PCR product and showed no reaction with the probe. TheNTNH gene was shown to be located upstream of the gene encoding BoNT, thereby revealing a conserved structure for genes encoding the proteins of the M complex of the progenitor botulinum toxin in these organisms. The sequence of theNTNH gene of nonproteolyticC. botulinum type F was determined by PCR amplification and sequencing of overlapping cloned fragments. NTNH/F showed 71% and 61% identity with NTNH ofC. botulinum type E and type C respectively.     

Rapid, Quantitative PCR Monitoring of Growth of Clostridium botulinum Type E in Modified-Atmosphere-Packaged Fish

A rapid, quantitative PCR assay (TaqMan assay) which quantifies Clostridium botulinum type E by amplifying a 280-bp sequence from the botulinum neurotoxin type E (BoNT/E) gene is described. With this method, which uses the hydrolysis of an internal fluoregenic probe and monitors in real time the increase in the intensity of fluorescence during PCR by using the ABI Prism 7700 sequence detection system, it was possible to perform accurate and reproducible quantification of the C. botulinum type E toxin gene. The sensitivity and specificity of the assay were verified by using 6 strains of C. botulinum type E and 18 genera of 42 non-C. botulinum type E strains, including strains of C. botulinum types A, B, C, D, F, and G. In both pure cultures and modified-atmosphere-packaged fish samples (jack mackerel), the increase in amounts of C. botulinum DNA could be monitored (the quantifiable range was 10² to 10⁸ CFU/ml or g) much earlier than toxin could be detected by mouse assay. The method was applied to a variety of seafood samples with a DNA extraction protocol using guanidine isothiocyanate. Overall, an efficient recovery of C. botulinum cells was obtained from all of the samples tested. These results suggested that quantification of BoNT/E DNA by the rapid, quantitative PCR method was a good method for the sensitive assessment of botulinal risk in the seafood samples tested.     

Clostridium botulinum Group II Isolate Phylogenomic Profiling Using Whole-Genome Sequence Data

Clostridium botulinum group II isolates (n = 163) from different geographic regions, outbreaks, and neurotoxin types and subtypes were characterized in silico using whole-genome sequence data. Two clusters representing a variety of botulinum neurotoxin (BoNT) types and subtypes were identified by multilocus sequence typing (MLST) and core single nucleotide polymorphism (SNP) analysis. While one cluster included BoNT/B4/F6/E9 and nontoxigenic members, the other comprised a wide variety of different BoNT/E subtype isolates and a nontoxigenic strain. In silico MLST and core SNP methods were consistent in terms of clade-level isolate classification; however, core SNP analysis showed higher resolution capability. Furthermore, core SNP analysis correctly distinguished isolates by outbreak and location. This study illustrated the utility of next-generation sequence-based typing approaches for isolate characterization and source attribution and identified discrete SNP loci and MLST alleles for isolate comparison.