Evidence for plasmid-mediated toxin and bacteriocin production in Clostridium botulinum type G

A single 81-megadalton plasmid was previously isolated from each of six toxigenic strains of Clostridium botulinum type G (M. S. Strom, M. W. Eklund, and F. T. Poysky, Appl. Environ. Microbiol. 48:956-963, 1984). In this study, nontoxigenic derivatives isolated from each of the toxigenic strains following consecutive daily transfers in Trypticase (BBL Microbiology Systems, Cockeysville, Md.)-yeast extract-glucose broth at 44 degrees C simultaneously ceased to produce type G neurotoxin and to harbor the resident 81-megadalton plasmid. The nontoxigenic derivatives also ceased to produce bacteriocin and lost their immunity to the bacteriocin produced by the toxigenic strains. In contrast, all of the toxigenic isolates continued to carry the resident plasmid and to produce both bacteriocin and type G neurotoxin. This is the first evidence suggesting that the production of neurotoxin and bacteriocin by C. botulinum is mediated by a plasmid.     

Transfer of neurotoxigenicity from Clostridium butyricum to a nontoxigenic Clostridium botulinum type E-like strain.

Two Clostridium butyricum strains from infant botulism cases produce a toxic molecule very similar to C. botulinum type E neurotoxin. Chromosomal, plasmid, and bacteriophage DNAs of toxigenic and nontoxigenic strains of C. butyricum and C. botulinum type E were probed with (i) a synthesized 30-mer oligonucleotide encoding part of the L chain of type E botulinum toxin and (ii) the DNA of phages lysogenizing these cultures. The toxin gene probe hybridized to the chromosomal DNA of toxigenic strains but not to their plasmid DNA. All toxigenic and most nontoxigenic strains tested were lysogenized by a prophage on the chromosome. Prophages of toxigenic strains, irrespective of species, had related or identical DNAs which differed from the DNAs of prophages in nontoxigenic strains. The prophage of toxigenic strains was adjacent or close to the toxin gene on the chromosome. Phage DNAs purified from toxigenic strains did not hybridize with the toxin gene probe but could act as the template of the polymerase chain reaction to amplify the toxin gene. The toxin gene was not transferred between C. botulinum and C. butyricum (either direction) when different pairs of a possible gene donor and a recipient strain were grown as mixed cultures. Nontoxigenic C. butyricum or C. botulinum type E-like strains did not become toxigenic when grown in broth containing the phage induced from a toxigenic strain of the other species.(ABSTRACT TRUNCATED AT 250 WORDS)     

Plasmids in Clostridium botulinum and related Clostridium species.

Toxigenic Clostridium botulinum and nontoxigenic C. sporogenes, C. subterminale, and C. botulinum-like organisms from a variety of sources were screened for plasmids. Of the 68 toxigenic C. botulinum isolates, 56% carried one or more plasmids, ranging in mass from 2.1 to 81 megadaltons. Within individual groups (based on the type of neurotoxin produced), many strains showed identical plasmid banding patterns on agarose gels. Of the 15 nontoxigenic strains tested, 40% also carried one or more plasmids ranging from 1.7 to 25.0 megadaltons, with both unique and common banding patterns represented. A total of 67 plasmids from both toxigenic and nontoxigenic strains were detected. At this time, no phenotypic functions have been assessed for these plasmids, and they must therefore be considered cryptic. A variety of lysing and extraction techniques were necessary to detect plasmids in the different C. botulinum groups.     

Interconversion of Type C and D Strains of Clostridium botulinum by Specific Bacteriophages

These studies show that Clostridium botulinum types C and D cultures can be cured of their prophages and converted to either type C or D depending on the specific phage used. Strains of types C and D were cured of their prophages and simultaneously ceased to produce their dominant toxins designated as C(1) and D, respectively. Cured nontoxigenic cultures derived from type C strain 162 were sensitive to the phages from the toxigenic type C strain 162 and type D strain South African. When cured nontoxigenic cultures derived from strain 162 were infected with the tox(+) phages from the 162 strain of type C and the South African strain of type D, they then produced toxin neutralized by types C and D antisera, respectively. Cured nontoxigenic cultures isolated from the type D South African strain were only sensitive to the parent phage, and, when reinfected with the tox(+) phage, they produced toxin neutralized by type D antiserum. Type C strain 153 and type D strain 1873, when cured of their respective prophages, also ceased to produce toxins C(1) and D, but, unlike strain 162 and the South African strain, they continued to produce a toxin designated as C(2). When the cured cultures from strains 153 and 1873 were infected with the tox(+) phage from type D strain 1873, the cultures simultaneously produced toxin that was neutralized by type D antiserum. When these cured cultures were infected with the tox(+) phage from type C strain 153, the cultures produced toxin that was neutralized by type C antiserum. These studies with the four strains of C. botulinum confirm that the toxigenicity of types C and D strains requires the continued participation of tox(+) phages. Evidence is presented that types C and D cultures may arise from a common nontoxigenic strain.     

Serological Studies of Clostridium botulinum Type E and Related Organisms II. Serology of Spores

Pure spore antigens for the immunization of rabbits were prepared by enzymic digestion of vegetative components and separation of the cleaned spores in polyethylene glycol. Spore antisera were prepared to strains representative of toxigenic Clostridium botulinum type E; nontoxigenic boticin E-producing variants; nontoxigenic nonproducers of boticin E; nontoxigenic "atypical" strains, which differ somewhat from C. botulinum type E in their physiology; C. botulinum types A and B; and C. bifermentans. They were tested against these and additional strains representative of the above groups, other types of C. botulinum, and other Clostridium species. There was no evidence of agglutination of flagellar or somatic antigens of vegetative cells by these antisera. Agglutination and agglutinin absorption tests showed common antigens among toxigenic type E strains and nontoxigenic variants, both producers and nonproducers of boticin E. Some nontoxigenic "atypical" strains varied in their ability to be agglutinated by type E antisera, and others did not agglutinate at all. Of those atypical strains that were not agglutinated, one was agglutinated by C. bifermentans antiserum. Antisera prepared against C. botulinum types A and B and C. bifermentans did not agglutinate the spores of type E or its variants nor share antigens common to each other. Similarly, antisera to type E, its nontoxigenic variants, and nontoxigenic atypical strains did not agglutinate other C. botulinum types or any other Clostridium species investigated.     

Serological Studies of Clostridium botulinum Type E and Related Organisms

Clostridium botulinum type E antigens prepared from washed cells by either Formalin treatment or heating at 100 C were used for immunizing rabbits. Agglutination tests showed that high levels of antibody were produced by both types of preparations. Flagellar antigens were highly strain-specific, whereas the somatic antigens were sufficiently similar to produce complete cross-agglutination. One toxigenic strain produced toxigenic and nontoxigenic progeny which were physiologically and antigenically identical in all other respects. Other nontoxigenic strains whose growth, physiological, and morphological characters were identical to type E and strains which had some physiological differences completely cross-agglutinated with type E strains via the somatic antigen. Neither type of antiserum agglutinated other clostridia against which they were tested except for C. acetobutylicum. This reaction seems to be due to a nonspecific anamnestic response and does not appear to be related to the immunizing strains. The nontoxigenic strains studied seem to have no greater antigenic differences from type E strains than the type E strains have from each other.     

Apparent Involvement of a Plasmid in Phaseotoxin Production by Pseudomonas phaseolicola

Three naturally occurring toxigenic strains (HB-36, G-50, and HB-33), one nontoxigenic strain (HB-20), and one ultraviolet light-induced toxinless mutant (G-50 Tox⁻) of Pseudomonas phaseolicola were examined by dye-buoyant density equilibrium centrifugation for the presence of plasmid deoxyribonucleic acid. All strains contained plasmid deoxyribonucleic acid. Comparison of the plasmid deoxyribonucleic acid of different strains by agarose gel electrophoresis showed that strain G-50 harbored three plasmids, whereas the rest of the strains contained two plasmids each. Irrespective of their toxigenicity, all strains shared the large-sized first plasmid band, but differed with respect to other plasmids. Restriction endonuclease analyses of the plasmids indicated that a 22.50-megadalton plasmid was common to two of the toxigenic strains (HB-36 and G-50). However, strain HB-33, which is also toxigenic, contained a much smaller plasmid (4.23 megadaltons). It is hypothesized that this small plasmid may have arisen by a recombination event from a larger plasmid.     

Sequences of the botulinal neurotoxin E derived from Clostridium botulinum type E (strain Beluga) and Clostridium butyricum (strains ATCC 43181 and ATCC 43755).

Recently, it has been shown that two Clostridium butyricum strains (ATCC 43181 and ATCC 43755), isolated from cases of infant botulism, produce a botulinal neurotoxin type E (BoNT/E). Here we have determined the nucleotide sequences of the BoNT/E genes of these two C. butyricum strains and from C. botulinum E strain Beluga. We show that the sequences of the BoNT/E genes from the two C. butyricum strains are identical and differ in only 64 positions resulting in 39 amino acid changes (97% identity at the amino acid level) from that derived from C. botulinum. Our data suggest a transfer of the BoNT/E gene from C. botulinum to the originally nontoxigenic C. butyricum strains.     

Plasmid localization of a type E botulinal neurotoxin gene homologue in toxigenic Clostridium butyricum strains, and absence of this gene in non-toxigenic C. butyricum strains

It has been shown recently that two Clostridium butyricum strains (ATCC 43181 and ATCC 43755) contain a botulinal neurotoxin type E (BoNT/E) gene closely related to that of C. botulinum type E. In this study, we show that this gene is located on a large plasmid in the two toxigenic C. butyricum strains and is absent in 18 non-toxigenic C. butyricum and C. beijerinckii strains. Interestingly, the 230 bp upstream and the 1260 bp downstream of the neurotoxin coding sequence are not present in either the non-toxigenic C. butyricum or C. beijerinckii strains. Our data suggest a BoNT/E gene transfer from C. botulinum E to originally non-toxigenic C. butyricum strains.     

Detection of the genes encoding botulinum neurotoxin types A to E by the polymerase chain reaction.

The polymerase chain reaction (PCR) was used as the basis for the development of highly sensitive and specific diagnostic tests for organisms harboring botulinum neurotoxin type A through E genes. Synthetic DNA primers were selected from nucleic acid sequence data for Clostridium botulinum neurotoxins. Individual components of the PCR for each serotype (serotypes A through E) were adjusted for optimal amplification of the target fragment. Each PCR assay was tested with organisms expressing each of the botulinum neurotoxin types (types A through G), Clostridium tetani, genetically related nontoxigenic organisms, and unrelated strains. Each assay was specific for the intended target. The PCR reliably identified multiple strains having the same neurotoxin type. The sensitivity of the test was determined with different concentrations of genomic DNA from strains producing each toxin type. As little as 10 fg of DNA (approximately three clostridial cells) was detected. C. botulinum neurotoxin types A, B, and E, which are most commonly associated with human botulism, could be amplified from crude DNA extracts, from vegetative cells, and from spore preparations. This suggests that there is great potential for the PCR in the identification and detection of botulinum neurotoxin-producing strains.     

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.     

Proteolytic mutants obtained from Clostridium botulinum type E.

Proteolytic mutants were isolated from toxigenic strains of Clostridium botulinum type E after several transfers. When these cultures were plated on blood agar, almost all of the colonies obtained were proteolytic, and there were fewer toxigenic colonies than nontoxigenic colonies. The proteolytic mutants and nonproteolytic original strains were different in their biological properties.     

Cloning, nucleotide sequence, and expression of the gene encoding the bacteriocin boticin B from Clostridium botulinum strain 213B

Boticin B is a heat-stable bacteriocin produced by Clostridium botulinum strain 213B that has inhibitory activity against various strains of C. botulinum and related clostridia. The gene encoding the bacteriocin was localized to a 3.0-kb HindIII fragment of an 18. 8-kb plasmid, cloned, and sequenced. DNA sequencing revealed the boticin B structural gene, btcB, to be an open reading frame encoding 50 amino acids. A C. botulinum strain 62A transconjugant containing the HindIII fragment inserted into a clostridial shuttle vector expressed boticin B, although at much lower levels than those observed in C. botulinum 213B. To our knowledge, this is the first demonstration and characterization of a bacteriocin from toxigenic group I C. botulinum.     

Conjugal transfer and characterization of bacteriocin plasmids in group N (lactic acid) streptococci.

Thirteen bacteriocin-producing strains of group N (lactic acid) streptococci were screened for their potential to transfer this property by conjugation to Streptococcus lactis subsp. diacetylactis Bu2-60. Bacteriocin production in three strains was plasmid encoded as shown by conjugal transfer and by analysis of cured, bacteriocin-negative derivatives of the donor strains and the transconjugants. With Streptococcus cremoris strains 9B4 and 4G6 and S. lactis subsp. diacetylactis 6F7 as donors, bacteriocin-producing transconjugants were isolated with frequencies ranging from ca. 2 X 10(-2) to 2 X 10(-1) per recipient cell. Bacteriocin-producing transconjugants had acquired a 39.6-megadalton plasmid from the donor strains 9B4 and 4G6, and a 75-megadalton plasmid from the donor strain 6F7. As shown by restriction endonuclease analysis, the plasmids from strains 9B4 and 4G6 were almost identical. The plasmid from strain 6F7 yielded some additional fragments not present in the two other plasmids. In hybridization experiments any of the three plasmids strongly hybridized with each other and with some other bacteriocin but nontransmissible plasmids from other S. cremoris strains. Homology was also detected to a variety of cryptic plasmids in lactic acid streptococci.     

Isolation and some properties of nontoxigenic derivatives of a strain of Clostridium tetani.

Nontoxigenic derivatives of a toxigenic strain of Clostridium tetani were isolated gy treatment with acridine orange, N-methyl-N'-nitro-soguanidine, rifampicin or ultraviolet light. The frequency of appearance fo non-toxigenic derivatives on these treatments was 0.8 to 3.2 per cent. The nontoxigenic derivatives peoduced all the same extracellular antigenic and protein components as the toxigenic parent strain, except the toxin and materials cross-reacting with the toxin. The nontoxigenic strains, like the toxigenic parent strain, were lyzed by trratment with mitomycin C. Bacteriophage was detected in the lysates of all the nontoxigenic derivatives produced with mitomycin C, and this bacteriophage was morphologically indistinguishable from that obtained from the toxigenic parent strain. The genetic factor controlling tetanus toxin production is discussed.     

Properties of F′ Factor Deoxyribonucleic Acid Transferred from Ultraviolet-Irradiated Donors: Photoreactivation in the Recipient and the Influence of recA, recB, recC, and uvr Genes

The bacteriocin, boticin E, was produced by only a few strains of those clostridia which are nontoxigenic but otherwise identical to Clostridium botulinum type E. Boticin preparations from four different strains had identical spectra against indicator cultures. Experiments with bacterial lawns showed boticin to be sporostatic for all tested nonproteolytic C. botulinum (types B, E, and F) and nontoxigenic type E-related strains which included the producing strains as well as those different from type E in the fermentation of one to three carbohydrates. Boticin had no detectable effect on vegetative cells of boticinogenic strains but killed those of all other strains whose spores were sensitive. Cultures that were growing in an agar medium were more sensitive to the bacteriocin than those growing in broth. Vegetative cells of indicator strains adsorbed boticin, but cells of a boticin-resistant mutant did not. Boticin did not lyse suspensions of vegetative cells which had been killed previously by exposure to air but lysed actively growing protoplasts and L-forms of a strain whose normal vegetative cells are susceptible to lysis. Sporostasis resulted from inhibition of germination rather than of outgrowth. Proteolytic strains of C. botulinum (types A, B, and F) were resistant to boticin E.     

Isolation of Clostridium botulinum type G from Swiss soil specimens by using sequential steps in an identification scheme.

After Clostridium botulinum type G organisms and toxin were identified in necropsy specimens in cases of unexplained death in adults and infants (O. Sonnabend, W. Sonnabend, R. Heinzle, T. Sigrist, R Dirnhofer, and U. Krech, J. Infect. Dis. 143:22-27, 1981), extensive research to detect C. botulinum type G in soil samples from Switzerland was done. A total of 41 specimens from virgin soil and from cultivated land were examined for the presence of C. botulinum type G and other toxin types. Because of the lack of the lipase marker in type G, the detection of C. botulinum type G was based on the demonstration of type G organisms in enrichment cultures by a type G-specific enzyme-linked immunosorbent assay to detect both the type G toxin and antigen; enrichment cultures in which type G toxin or antigen was identified by enzyme-linked immunosorbent assay were then tested by a type G-specific gel immunodiffusion agar procedure. This method not only isolated strains of type G but also strains of Clostridium subterminale, a nontoxigenic variant of C. botulinum type G. As a consequence of the observed cross-reactions caused by strains of C. subterminale within this test system, all isolates of type G had to be definitively confirmed by mouse bioassay. The sequential steps of these methods seem to be very useful for detecting C. botulinum type G organisms. C. botulinum type G strains were isolated in five soil samples from different locations in close association with cultivated land.(ABSTRACT TRUNCATED AT 250 WORDS)     

Isolation of Clostridium botulinum type G from Swiss soil specimens by using sequential steps in an identification scheme

After Clostridium botulinum type G organisms and toxin were identified in necropsy specimens in cases of unexplained death in adults and infants (O. Sonnabend, W. Sonnabend, R. Heinzle, T. Sigrist, R Dirnhofer, and U. Krech, J. Infect. Dis. 143:22-27, 1981), extensive research to detect C. botulinum type G in soil samples from Switzerland was done. A total of 41 specimens from virgin soil and from cultivated land were examined for the presence of C. botulinum type G and other toxin types. Because of the lack of the lipase marker in type G, the detection of C. botulinum type G was based on the demonstration of type G organisms in enrichment cultures by a type G-specific enzyme-linked immunosorbent assay to detect both the type G toxin and antigen; enrichment cultures in which type G toxin or antigen was identified by enzyme-linked immunosorbent assay were then tested by a type G-specific gel immunodiffusion agar procedure. This method not only isolated strains of type G but also strains of Clostridium subterminale, a nontoxigenic variant of C. botulinum type G. As a consequence of the observed cross-reactions caused by strains of C. subterminale within this test system, all isolates of type G had to be definitively confirmed by mouse bioassay. The sequential steps of these methods seem to be very useful for detecting C. botulinum type G organisms. C. botulinum type G strains were isolated in five soil samples from different locations in close association with cultivated land.(ABSTRACT TRUNCATED AT 250 WORDS)     

Simple Method for Detection of Clostridium botulinum Type A to F Neurotoxin Genes by Ploymerase Chain Reaction

A polymerase chain reaction (PCR)-based method was established to detect each type of neurotoxin genes of Clostridium botulinum types A to F by employing the oligonucleotide primer sets corresponding to special regions of the light chains of the neurotoxins. In this procedure, the PCR products were easily confirmed by restriction enzyme digestion profiles, and as little as 2.5 pg of template DNAs from toxigenic strains could be detected. The specific PCR products were obtained from toxigenic C. botulinum types A to F, a type E toxin-producing C. butyricum strain, and a type F toxin-producing C. baratii strain, but no PCR product was detected in nontoxigenic strains of C. botulinum and other clostridial species. The neurotoxin genes were also detected in food products of a seasoned dry salmon and a fermented fish (Izushi) which had caused type E outbreaks of botulism. Therefore, it is concluded that this PCR-based detection method can be used for the rapid diagnosis of botulism.     

Observations on bacteriophages of Clostridium botulinum type C isolates from different sources and the role of certain phages in toxigenicity.

Twenty strains of Clostridium botulinum type C, including 12 isolates from avian sources with varying toxigenic properties, were examined by electron microscope for the presence of bacteriophages. All toxigenic strains were infected with one or two types of phages. Three types of phages designated large, small, and intermediate were observed. Most of the strains carried the large and small phage, with the large phage being present in much greater numbers. Since there is evidence that highly toxigenic strains of C. botulinum type C are responsible for large outbreaks of botulism in wild birds, the phenomenon of toxigenic variation among the type C strains was investigated. Experiments were carried out employing a broth medium on a phagefree nontoxigenic strain for elucidating the role of bacteriophages in toxigenicity. All phage suspensions contained large phages, with the exception of one that caused conversion. The exception was a preparation containing an intermediate type of phage. Phages from different strains produced cultures of varying toxigenic characteristics. By employing a tube-lytic test and an agar-overlay-phage assay technique, it was determined that whenever the phage-bacterium relationship resulted in an initial high degree of lysis, the potency of toxin in the culture was weak. It appeared that in highly toxigenic strains, the phage-bacterium relationship is characterized by a stable lysogenic type of association. It was also found that in a highly toxigenic converted culture the percentage of toxigenic cells was 100, whereas in hypotoxigenic culture the percentage was only 20.