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.     

The stability of toxigenicity in Clostridium botulinum types C and D.

Several type C and D strains of Clostridium botulinum, which had been converted to the toxgenic state by phages, were serially transferred through cooked meat medium with and without specific anti-phage serum. Most of the converted strains lost their toxigenicity even during transfer without antiserum, and the non-toxigenic variants that appeared were resistant to lysis and conversion by the original phage. However, in some combinations of phage and host bacteria toxigenicity was stable after ten transfers, though it showed a transient decrease, and the non-toxigenic variants that arose remained sensitive to lysis and conversion. When converted strains were transferred in medium containing anti-phage serum, toxigenicity was lost more rapidly than in the absence of serum and the non-toxigenic variants that appeared remained sensitive to lysis and conversion by the parent phage. Filtrates of the supernatants of culture fluids of strains transferred without anti-phase serum converted non-toxigenic strains to toxigenicity at varying rates.     

The cell wall receptor for bacteriophage Mu G(−) in Erwinia and Escherichia coli C

Abstract Adsorption of bacteriophage Mu with its invertible DNA segment in the G(−) orientation requires a terminal glucose residue for binding to the core lipopolysaccharide (LPS) of Gram-negative bacteria. Analysis of a Mu-resistant mutant shows that the receptor for Mu G(−) in Erwinia B374 is a Glc-β1,6-Glc disaccharide. A spontaneously occurring host-range mutant, Mu G(−)h101, grows on Escherichia coli C. The loss of the terminal β1,3-linked glucose from the LPS of E. coli C leads to resistance to the phage Mu. These mutants are also resistant to phage P1 and D108 which have largely homologous G segments. This shows that Mu G(+) and G(−) phage particles differ with respect to their cell-wall receptors in the type of glycosidic linkage of a terminal glucose residue: α1, 2 for G(+) and β1,6 for G(−).     

Potential Significance of Lysogeny to Bacteriophage Production and Bacterial Mortality in Coastal Waters of the Gulf of Mexico

The potential effect that induction of lysogenic bacteria has on bacteriophage production and bacterial mortality in coastal waters was investigated, and we present estimates for the percentage of lysogenic cells in a natural aquatic bacterial community. Various concentrations of mitomycin C and exposure times to UV C radiation (UV-C) (wavelength of 254 nm) were used to induce the lytic cycle in lysogenic cells of natural communities of marine bacteria. UV-C treatment occasionally resulted in phage production, but phage production induced by UV-C was always less than that caused by the addition of mitomycin C. There was no evidence that high growth rates of bacteria resulted in lysogenic phage production. The burst size of cells induced by mitomycin C was determined by transmission electron microscopy and ranged from 11 to 45. Dividing the induced phage production by the burst size provided an estimate of the number of lysogenic bacterial cells, which ranged from 0.07 to 4.4% (average, 1.5%) of the total bacterial population. The percentages of lysogenic bacteria that were induced by mitomycin C were similar for samples collected nearshore from the pier of the Marine Science Institute (chlorophyll a, 1.6 to 2.9 (mu)g liter(sup-1)) and in relatively oligotrophic water (chlorophyll a, 0.2 to 0.9 (mu)g liter(sup-1)) collected 25 to 100 km offshore. By using a steady-state model, if all lysogenic bacteria were induced simultaneously, 0.14 to 8.8% (average, 3.0%) of the total bacterial mortality would result from induction of lysogenic cells. If mitomycin C induces all or the majority of lysogenized cells, our results imply that lysogenic phage production is generally not an important source of phage production or bacterial mortality in the coastal waters of the western Gulf of Mexico.     

Bacteriophage association of streptococcal pyrogenic exotoxin type C.

A gene encoding streptococcal pyrogenic exotoxin type C (SPE C) was isolated from bacteriophage DNA derived from Streptococcus pyogenes CS112. The gene, designated speC2, was shown to reside near the phage attachment site of phage CS112. A restriction endonuclease map of the CS112 phage was generated, and the location and orientation of the speC2 gene were determined. Hybridization analyses of eight SPE C-producing strains revealed restriction fragment length polymorphism of the speC gene-containing DNA fragments and further showed that each speC was linked to a common CS112 phage-derived DNA fragment.     

Comparative analysis of C3 and botulinal neurotoxin genes and their environment in Clostridium botulinum types C and D.

The C3 exoenzyme gene is located on a bacteriophage in Clostridium botulinum types C and D (M. R. Popoff, D. Hauser, P. Boquet, M. W. Eklund, and D. M. Gill, Infect. Immun. 59:3673-3679, 1991). A derivative CN phage from phage C of C. botulinum Stockholm (C-St) (K. Oguma, H. Iida, and K. Inoue, Jpn. J. Microbiol. 19:167-172, 1975), isolated as neurotoxin negative, also does not produce exoenzyme C3. The botulinal neurotoxin C1 gene is present on the CN phage but contains a stop mutation in the DNA region encoding the N-terminal part of the heavy chain (codon 553). The putative truncated botulinal neurotoxin C1 protein was not recovered in a C. botulinum strain harboring the CN phage. We found that the C3 gene is localized on a 21.5-kbp DNA fragment flanked by the core motif 5'-AAGGAG-3' in DNAs of phage C of C. botulinum 468 (C-468), C-St phage, and phage D of C. botulinum 1873 (D-1873). The 21.5-kbp DNA fragment is deleted in CN phage DNA, and the motif 5'-AAGGAG-3' is present only in one copy at the deletion junction, but the deletion in the CN phage could be nonspecific, since this phage was obtained by nitrosoguanidine treatment. These findings could indicate that the C3 gene is localized on a 21.5-kbp mobile element. C. botulinum type C strain 003-9 produces a C3 exoenzyme (Y. Nemoto, T. Namba, S. Kozaki, and S. Narumiya, J. Biol. Chem. 266:19312-19319, 1991), and Staphylococcus aureus E1 produces a related C3 enzyme which is named epidernmal cell differentiation inhibitor (S. Inoue, M. Sugai, Y. Murooka, S. Y. Paik, Y. M. Hong, H. Oghai, and H. Suginaka, Biochem. Biophys. Res. Comm. 174:459-464, 1991) and which shares 80.6 and 56.6% similarity, respectively with the C3 enzymes from C-468 or C-St and D-1873 phages athe amino acid level. The features of the putative 21.5-kbp transposon were not found in C. botulinum 003-9 and S. aureus E1, as determined by analysis of the C3 and epidermal cell differentiation inhibitor gene-flanking DNA regions. These data suggest a common ancestral origin and divergent evolution of the C3 genes in these three groups of bacterial strains and dissemination of a 21.5-kbp element carrying the C3 gene C-468, C-St, and D-1873 phages.     

Screening and identification of human ZnT8-specific single-chain variable fragment (scFv) from type 1 diabetes phage display library

Zinc transporter 8(ZnT8) is a major autoantigen and a predictive marker in type 1 diabetes(T1D). To investigate ZnT8-specific antibodies, a phage display library from T1 D was constructed and single-chain antibodies against ZnT 8 were screened and identified. Human T1 D single-chain variable fragment(sc Fv) phage display library consists of approximately 1í10~8 clones. After four rounds of bio-panning, seven unique clones were positive by phage ELISA. Among them, C27 and C22, which demonstrated the highest affinity to ZnT8, were expressed in Escherichia coli Top10F' and then purified by affinity chromatography. C27 and C22 specifically bound ZnT8 N/C fusion protein and ZnT8 C terminal dimer with one Arg325 Trp mutation. The specificity to human islet cells of these sc Fvs were further confirmed by immunohistochemistry. In conclusion, we have successfully constructed a T1 D phage display antibody library and identified two ZnT8-specific sc Fv clones, C27 and C22. These ZnT8-specific sc Fvs are potential agents in immunodiagnostic and immunotherapy of T1 D.     

Generation of scFv phages specific to Staphylococcus enterotoxin C1 by panning on related antigens

A method for generation of highly specific miniantibodies within the phage particle has been developed, and used to produce antibodies against Staphylococcus enterotoxin type C1. Under successive panning of the non-immune phage miniantibody (scFv) library with enterotoxins SE (types A, B, C1, D, E, G, and I) adsorbed on the plate surface, we generated 11 individual phage clones to Staphylococcus enterotoxin type C1. Five of them interacted specifically only with SEC1 and had no cross-reactions with the other enterotoxins.     

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.     

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.     

Identification of structural genes for Clostridium botulinum type C neurotoxin-converting phage particles

The structural genes for strain C-Stockholm (c-st) phage particles, a representative type C toxin-converting phage of Clostridium botulinum, have been determined. First, by determining the N-terminal amino acid sequences of sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) bands of c-st phage particles, it became clear that four proteins, 14, 25, 32 and 42 kDa, are the products of the ORFs, cst166, cst165, cst160 and cst164, respectively, of the c-st phage genome. The Western blot analyses reacting these phage bands with an antiphage serum prepared previously indicated that the products of cst165 and cst160 are the main proteins of the phage particles. Then, six candidates for the phage structural proteins, including cst165 and cst160 gene products, were prepared as recombinant proteins. Also, the protein corresponding to the cst164 gene product was excised from SDS-PAGE gels. The antibodies against these seven proteins were prepared in rabbits, and finally, the reaction of these antibodies to the c-st phage particles was analyzed by electron microscopy. It was concluded that a sheath protein and a head protein of the c-st phage are the products of genes cst160 and cst165, respectively, and that these two proteins are conserved in the other three converting phages, but not in the nonconverting phage.     

Production and purification of Clostridium botulinum type C and D neurotoxin

Neurotoxins of Clostridium botulinum are needed in basic neurologic research, but as therapeutic agent for certain neuromuscular disorders like strabism as well. A method for the production and purification of botulinum neurotoxins C and D is reported using a two-step hollow-fiber cross flow filtration and a newly developed chromatographic purification procedure. Hollow-fiber filtration proved to be a rapid and safe concentration and pre-purification step, which can easily be scaled up. The chromatographic purification included hydrophobic interaction, anion exchange and size exclusion chromatography runs. Botulinum neurotoxins C and D could be recovered with an overall yield of 12.6% and 10.6%, respectively. A specific toxicity of 1.86 x 10(7) minimal lethal dose mg(-1) (type C) and 5.26 x 10(7) minimal lethal dose mg(-1) (type D) was determined in the mouse bioassay.     

Generation of scFv phages specific to Staphylococcus enterotoxin C1 by panning on related antigens

A method for generation of highly specific miniantibodies within the phage particle has been developed and used to produce antibodies against Staphylococcus enterotoxin type C1. Under successive panning of the non-immune phage miniantibody (scFv) library with enterotoxins SE (types A, B, C1, D, E, G and I) adsorbed on the plate surface, we generated 11 individual phage clones to Staphylococcus enterotoxin type C1. Five of them interacted specifically only with SEC1 and had no cross-reactions with the other enterotoxins.Key words: scFv, phage display, antibody specificity, Staphylococcus aureus enterotoxins     

EFFECT OF SODIUM SULFATE ON THE PHAGE-BACTERIUM REACTION

Bacteriophagy taking place in the presence of M/8 Na₂SO₄ has the following pronounced characteristics: A. Time of lysis is considerably prolonged. B. The bacteria take up less than the normal amount of phage. C. Phage production occurs at one-third the customary rate. D. It takes four times as much phage to lyse a Na₂SO₄-treated bacterium than a normal one. E. Bacterial growth is not affected by Na₂SO₄. The lag phase and the lowered rate of phage production can be attributed to the Na₂SO₄ effect on the cell surface. Less phage is taken up by the cells and contact of phage with the bacterium''s precursor-producing mechanism is impeded.     

Influence of resistance-factors on the phage types ofSalmonella Panama

The resistance to antibiotics which has been increasingly observed in naturally occurringSalmonella panama, is due to an R-factor. A relationship was found between phage pattern and the presence of this R-factor. All strains belonging to phage types A, C and E are sensitive to all antibiotics and are indicated in phage-typing by wild-type phage 47 or host-range mutants of phage 47. All strains belonging to phage types B, D and F possess an R-factor and are indicated by host-modified variants of phage 47. Phage type G, indicated by a host-range mutant, and group Z contain strains with, as well as without an R-factor. Spontaneous drug-sensitive segregants of type B, D and F strains have the phage pattern A, C and E respectively. Conversely, the phage pattern of A, C and E type strains change into B, D and F respectively after infection with the R-factor ofS. panama. The theory can be advanced that type B type A+R-factor, D — C+R-factor and F = E+R-factor. This change in phage type can be considered to be due to the fact that the R-factor exerts restriction and modification of the phage which indicates theS. panama strain without the R-factor.Many of the antibiotic-resistantEscherichia coli strains found in nature possess an R-factor which can be transferred toS. panama in vitro. Relatively few of these R-factors were found to possess also the restriction marker. Thus up to the present the number ofE. coli strains possessing an R-factor which is able to create a dependable combination of phage type and drug resistance inS. panama is relatively small.     

1H, 15N and 13C resonance assignments of PpdD,a type IV pilin from enterohemorrhagic Escherichia coli

Bacterial type 4 pili (T4P) are long flexible fibers involved in adhesion, DNA uptake, phage transduction, aggregation and a flagella-independent movement called “twitching motility”. T4P comprise thousands of copies of the major pilin subunit, which is initially inserted in the plasma membrane, processed and assembled into dynamic helical filaments. T4P are crucial for host colonization and virulence of many Gram-negative bacteria. In enterohemorrhagic Escherichia coli the T4P, called hemorrhagic coli pili (HCP) promote cell adhesion, motility, biofilm formation and signaling. To understand the mechanism of HCP assembly and function, we analyzed the structure of the major subunit prepilin peptidase-dependent protein D (PpdD) (also called HcpA), a 15 kDa pilin with two potential disulfide bonds. Here we present the ¹H, ¹⁵N and ¹³C backbone and side chain resonance assignments of the C-terminal globular domain of PpdD as a first step to its structural determination.     

In vitro evaluation methods for Clostridium botulinum type C and D vaccines

Reagents were prepared for use in ELISAs to determine the concentration of the antigenic components of Clostridium botulinum type C and D. The results obtained were compared with the L+dose assay and a good correlation was found between the two assays for measurement of the C and D neurotoxin concentration. These ELISAs were also used to determine the concentration of the neurotoxins in toxoid form. The relationship between the C neurotoxin dose, in toxoid form, and the immune response in guinea pigs could be deduced from the data obtained. The relationship for the D neurotoxin was not that clear, as the same concentration of the antigen resulted in variable potency values. However, these ELISAs can be used to formulate the concentration of the C and D components in the final bivalent vaccine. Replacement of the preliminary potency assay on the monovalent components after production with the in vitro assays will shorten the total production time of the vaccine by about 60 days. The economical and ethical implications are the reduction in the use of animals to evaluate the vaccine.     

Observations on Nonconverting Phage,c-n71, Obtained from a Nontoxigenic Strain of Clostridium botulinum Type C

A nontoxigenic mutant (C-N71) obtained from a toxigenic strain of Clostridium botulinum type C, Stockholm, with nitrosoguanidine treatment was found to be lysogenic by the lysis test. Although the filtrate of a passaged lysate of this nontoxigenic but lysogenic strain, C-N71, lysed cells of the nontoxigenic strain C-AO2 equally as well as the converting phage c-st obtained from the strain C-Stockholm, it did not convert C-AO2 to the toxigenic state. The lysis spectrum of this filtrate was the same as that of the c-st phage. The ability of the filtrate to lyse the indicator cells, C-AO2, was destroyed neither by trypsin nor DNase but was inactivated by heat treatment at 80 C for 10 min. This suggested that the agent which caused lysis was not boticin but probably a phage. An electron micrograph of the complete phage, c-n71, which was similar in morphology to that of the c-st phage was obtained from the filtrate of strain C-N71. Anti-c-n71 phage rabbit serum neutralized both the lytic and the converting activities of the c-st phage. These findings strongly suggest that the c-n71 phage is a mutant of the c-st phage which lacks the gene controlling production of botulinum type C toxin.