Identification and grouping of Clostridium botulinum strains by numerical analysis of their electrophoretic protein patterns

Strains of Clostridium botulinum type A, type E and both non-proteolytic and proteolytic types B and F were characterized by their electrophoretic protein patterns. As the protein pattern changes during sporulation, special attention was paid to the prevention of sporulation by selecting an appropriate medium (Strasdine's medium plus 1% w/v glucose) and a scheme of repeated subculturing. Ribosomal proteins, evolutionarily conservative and hence relatively similar in all types of bacteria, were removed to optimize the resolving power of the electrophoretic technique. Protein patterns were compared by computing correlation coefficients of normalized densitometric tracings. The method is highly reproducible and its resolving power is high: all protein patterns found were specific. The strains tested fall into two main groups: the proteolytic and the non-proteolytic cluster. Type A strains form a separate subgroup within the proteolytic cluster, the same applies to type E strains within the non-proteolytic group. Although time-consuming for spore-forming bacteria, this method is, to our knowledge, the only technique that recognizes individual strains of Cl. botulinum . For non-spore-forming micro-organisms the method is certainly much simpler and hence even more valuable.     

Identification of Clostridium botulinum with API 20 A, Rapid ID 32 A and RapID ANA II

Three commercially available test systems for the identification of anaerobic bacteria were evaluated for the identification of 18 proteolytic group I and 69 non-proteolytic group II Clostridium botulinum, four Clostridium sporogenes and 18 non-toxigenic group II C. botulinum-like strains. All proteolytic C. botulinum strains were misidentified by the Rapid ID 32 A and RapID ANA II, while 14 strains and all C. sporogenes strains were identified as C. botulinum or C. sporogenes by the API 20 A. Reversely, all non-proteolytic C. botulinum strains were misidentified by the API 20 A while the Rapid ID 32 A recognized 67 and RapID ANA II 68 strains. All C. sporogenes strains were recognized by the RapID ANA II, while the Rapid ID 32 A recognized one strain. All non-proteolytic non-toxigenic strains were identified as C. botulinum group II by the Rapid ID 32 A, 17 strains by the RapID ANA II, and one strain by the API 20 A. The results show that these test systems do not provide a reliable method for identification of C. botulinum.     

Growth and toxin production by non-proteolytic and proteolytic Clostridium botulinum in cooked vegetables

Growth and toxin production by proteolytic and non-proteolytic strains of Clostridium botulinum have been followed in 28 cooked puréed vegetables prepared under strict anaerobic conditions and incubated at 30°C for up to 60 d. Toxin production was confirmed in 25 of the cooked vegetables inoculated with a suspension of spores of proteolytic strains of types A and B, and in 13 inoculated with a suspension of spores of non-proteolytic strains of types B, E and F. For both proteolytic and non-proteolytic strains, a trend was identified correlating growth and toxin production with the pH of the cooked puréed vegetables.     

A Pyrolysis Gas-liquid Chromatography Study of Clostridium botulinum and Related Organisms

Low resolution pyrolysis gas-liquid chromatography could differentiate the following groups of Clostridium botulinum and related organisms: (1) Cl. botulinum type A. proteolytic types B and F and Cl. sporogenes ; (2) Cl. botulinum types C and D. and (3) Cl. botulinum type E and non-proteolytic types B and F. Toxin types A and B could be distinguished from type E and from type F.     

The metabolism of pyrimidines by proteolytic clostridia.

Uracil was used by growing cultures of Clostridium sporogenes, and by proteolytic strains of C. botulinum types A and B. Uracil was not used by C. bifermentans; C. botulinum, type B (non-proteolytic); C. botulinum, type F (non-proteolytic); C. botulinum, type E; C. butyricum; C. cochlearium; C. difficile; C. histolyticum; C. oedematiens, type A; C. paraputrificum; C. scatologenes; C. specticum; C. sordellii; C. sticklandii; C. tertium; C. tetani; C. tetanomorphum; C. welchii, types A, B, C, E and 4 untyped strains. The growth of C. sporogenes was not increased by uracil; it was reduced to dihydrouracil. Experiments with washed cells of C. sporogenes showed that the uracil-reducing system was inducible. Washed cell suspensions incubated under hydrogen with uracil, thymine, iso-barbituric acid, 5-amino uracil and cytosine consumed 1 mole H2/mole pyrimidine. The reduction product of cytosine was dihydrouracil indicating that it was deaminated before reduction. The reduction products of the remaining pyrimidines were the corresponding dihydro derivatives. Extracts of C. sporogenes reduced uracil in the presence of NADPH2 but not NADH2.     

The combined effect of incubation temperature, pH and sorbic acid on the probability of growth of non-proteolytic, type B Clostridium botulinum

It has been reported that non-proteolytic strains of Clostridium botulinum will grow at 3.3 degrees C, and they are therefore of concern in relation to certain chilled foods. The effects of combinations of inhibitory factors may be used to reduce the risk of growth of these bacteria in foods. The combined effect of pH values between 4.8 and 7.0, temperatures between 6 degrees and 30 degrees C, and sorbic acid concentrations up to 2270 mg/l on the probability of growth from a single spore of non-proteolytic, type B strains in a culture medium has been determined. A mathematical model has been developed that enables the effect of varying combinations of these factors on the probability of growth of non-proteolytic, type B Cl. botulinum to be predicted.     

Diversity of proteolytic Clostridium botulinum strains, determined by a pulsed-field gel electrophoresis approach

Pulsed-field gel electrophoresis (PFGE) was applied to the study of the similarity of 55 strains of proteolytic Clostridium botulinum (C. botulinum group I) types A, AB, B, and F. Rare-cutting restriction enzymes ApaI, AscI, MluI, NruI, PmeI, RsrII, SacII, SmaI, and XhoI were tested for their suitability for the cleavage of DNA of five proteolytic C. botulinum strains. Of these enzymes, SacII, followed by SmaI and XhoI, produced the most convenient number of fragments for genetic typing and were selected for analysis of the 55 strains. The proteolytic C. botulinum species was found to be heterogeneous. In the majority of cases, PFGE enabled discrimination between individual strains of proteolytic C. botulinum types A and B. The different toxin types were discriminated at an 86% similarity level with both SacII and SmaI and at an 83% similarity level with XhoI. Despite the high heterogeneity, three clusters at a 95% similarity level consisting of more than three strains of different origin were noted. The strains of types A and B showed higher diversity than the type F organisms which formed a single cluster. According to this survey, PFGE is to be considered a useful tool for molecular epidemiological analysis of proteolytic C. botulinum types A and B. However, epidemiological conclusions based on PFGE data only should be made with discretion, since highly similar PFGE patterns were noticed, especially within the type B strains.     

The combined effect of incubation temperature, pH and sorbic acid on the probability of growth of non-proteolytic, type B Clostridium botulinum

L und , B.M., G raham , A.F., G eorge , S.M. & B rown , D. 1990. The combined effect of incubation temperature, pH and sorbic acid on the probability of growth of non-proteolytic, type B Clostridium botulinum. Journal of Applied Bacteriology 69 , 481–492.
It has been reported that non-proteolytic strains of Clostridium botulinum will grow at 3.3°C, and they are therefore of concern in relation to certain chilled foods. The effects of combinations of inhibitory factors may be used to reduce the risk of growth of these bacteria in foods. The combined effect of pH values between 4.8 and 7.0, temperatures between 6° and 30°C, and sorbic acid concentrations up to 2270 mg/1 on the probability of growth from a single spore of non-proteolytic, type B strains in a culture medium has been determined. A mathematical model has been developed that enables the effect of varying combinations of these factors on the probability of growth of non-proteolytic, type B Cl. botulinum to be predicted.     

Factors affecting growth from heat-treated spores of non-proteolytic Clostridium botulinum

Heat treatment of spores of non-proteolytic Clostridium botulinum at 85°C for 120 min followed by enumeration of survivors on a medium containing lysozyme resulted in a 4.1 and 4.8 decimal reduction in numbers of spores of strains 17B (type B) and Beluga (type E), respectively. Only a small proportion of heated spores formed colonies on medium containing lysozyme; this proportion could be increased by treatments designed to increase the permeability of heated spores. The results indicate that the germination system in spores of non-proteolytic Cl. botulinum was destroyed by heating, that lysozyme could replace this germination system, and that treatments that increased the permeability of the spore coat could increase the proportion of heated spores that germinated on medium containing lysozyme. These results are important in relation to the assessment of heat-treatments required to reduce the risk of survival and growth of non-proteolytic Clostridium botulinum in processed (pasteurized) refrigerated foods for extended storage.     

Interactions between proteolytic and non-proteolytic Pseudomonas fluorescens affect protein degradation in a model community

The metabolic interactions between proteinase-producing bacteria and other members of bacterial communities are poorly investigated, although they are important for the understanding of structure-function relationships in complex ecosystems. We constructed simple model communities consisting of proteolytic and non-proteolytic Pseudomonas fluorescens strains to identify relevant interactions and to assess their specific significance during the mobilization of protein for growth. The proteolytic or non-proteolytic model communities were established by co-inoculating proteolytic or proteinase-deficient Tn5-mutants of P. fluorescens strain ON2 with the non-proteolytic reporter strain DF57-N3 that expresses bioluminescence in response to nitrogen limitation. The growth medium was composed such that growth would be nitrogen limited in the absence of proteolytic activity. In the proteolytic communities data on growth and nitrogen availability showed that the protein hydrolysates were available to both the proteolytic and the non-proteolytic strain. Competition between these strains profoundly affected both growth and proteinase production. Hence, the mobilization of protein was closely coupled to the competitive success of the proteolytic strain. These findings provide new insight into the metabolic interactions that occur when protein is degraded in mixed bacterial communities.     

Differentiation of Clostridium botulinum Types A, B, and E by Pyrolysis-Gas-Liquid Chromatography

Vegetative cells and spores of 10 strains of Clostridium botulinum representing types A, B, and E were grown in Trypticase-peptone-sucrose-yeast extract (TPSY) medium. Five type E strains were also grown in Multipeptone-sucrose-Nutramino acids (MSN) medium. Lyophilized samples were subjected to pyrolysis-gas-liquid chromatography (PGLC) analysis, and the resulting pyrograms were examined for variations in elution patterns between spores and vegetative cells of types A, B, and E grown in the TPSY medium and spores and vegetative cells of type E grown in the TPSY medium and spores and vegetative cells of type E grown in TPSY and MSN media. Growth and toxin production of all 10 strains of C. botulinum were investigated by using a modified dialysis sac culture technique. The dialysate supernatant fluid (DSF) obtained after centrifugation of the 5-day-old cultures from the dialysate was also subjected to PGLC analysis. Control samples consisting of (i) noninoculated DSF, (ii) noninoculated DSF plus partially purified toxin, and (iii) 1.0 mg of partially purified toxin were also analyzed by PGLC. Differences between pyrograms of cultures were suitable for positive identification at the type level but not at the strain level. Pyrograms permitting differentiation were also obtained between spores and vegetative cells as well as between the same cultures grown in different media. The dialysis sac technique was useful in detecting growth but not toxin production of C. botulinum.     

The effect of recovery medium on the estimated heat-inactivation of spores of non-proteolytic Clostridium botulinum

Heating spores of non-proteolytic strains of Clostridium botulinum at 85°C, followed by enumeration of survivors on a highly nutrient medium indicated a 5 decimal kill in less than 2 min. The inclusion of lysozyme or egg yolk emulsion in the recovery medium substantially increased apparent spore heat-resistance, with as little as 0.1 μg lysozyme/ml sufficient to give an increase in the number of survivors. After heating at 85°C for 2 min between 0.1% and 1% of the spores of 11 strains (5 type B, 4 type E, 2 type F) formed colonies on medium containing 10 μg lysozyme/ml. Enumeration of survivors on a medium containing lysozyme showed that heating at 85°C for 5 min resulted in an estimated 2.6 decimal kill of spores of strain 17B (type B). These findings are important in the assessment of heat-treatments required to ensure the safety with respect to non-proteolytic Clostridium botulinum of processed (pasteurized) refrigerated foods for extended storage such as sous-vide foods.     

Outgrowth and sporulation studies on Clostridium botulinum type E: influence of isoleucine.

A defined medium (CDM) is described which supported growth and sporulation of type E strains of Clostridium botulinum, but not sporulation of other serotypes of C. botulinum or C. sporogenes. As compared to growth in complex medium, spore outgrowth was delayed and both the growth rate and the cell yield was reduced. However, efficiency of sporulation of the type E MSpt strain in a chemically defined medium (CDM) was the same as that in complex medium and, in fact, sporulation was nearly synchronous and completed within 3 h of the first appearance of phase-bright endospores, compared with completion in 9 h in TPGY. Growth studies with CDM, from which single amino acids were omitted, showed that isoleucine was essential for outgrowth of heat-activated spores of the MSp+ strain, whereas valine was required for that of the Ts-25 mutant. Radioactive isoleucine was incorporated by germinating MSp+ spores at an earlier stage and at a more rapid rate than labelled methionine or mixed amino acids. Uptake studies showed that isoleucine accumulated in a prominent acid-soluble pool during outgrowth, a period when its incorporation into protein was not evident. The results suggest that the isoleucine may be required for a purpose other than protein synthesis during outgrowth.     

Use of a novel method to characterize the response of spores of non-proteolytic Clostridium botulinum types B, E and F to a wide range of germinants and conditions

AIMS: Limited information is available on the germination triggers for spores of non-proteolytic Clostridium botulinum. An automated system was used to study the effect of a large number of potential germinants, of temperature and pH, and aerobic and anaerobic conditions, on germination of spores of non-proteolytic Cl. botulinum types B, E and F. METHODS AND RESULTS: A Bioscreen analyser was used to measure germination by decrease in optical density. Results were confirmed by phase-contrast light microscopy. Spores of strains producing type B, E and F toxin gave similar results. Optimum germination occurred in L-alanine/L-lactate, L-cysteine/L-lactate and L-serine/L-lactate (50 mmol l(-1) of each). A further 12 combinations of factors induced germination. Sodium bicarbonate, sodium thioglycollate and heat shock each enhanced germination, but were not essential. Germination was similar in aerobic and anaerobic conditions. The optimum pH range was 5.5-8.0, germination occurred at 1-40 degrees C, but not at 50 degrees C, and was optimal at 20-25 degrees C. CONCLUSIONS: The automated system enabled a systematic study of germination requirements, and provided an insight into germination in spores of non-proteolytic Cl. botulinum. SIGNIFICANCE AND IMPACT OF THE STUDY: The results extend understanding of germination of non-proteolytic Cl. botulinum spores, and provide a basis for improving detection of viable spores.     

Antigenic Relationships Among the Proteolytic and Nonproteolytic Strains of Clostridium botulinum

Relationships of the somatic antigens among Clostridium botulinum strains have been investigated by tube agglutination and agglutinin absorption tests. Results revealed a relationship by which strains of C. botulinum are grouped by their proteolytic capacity rather than by the type of specific toxin produced. Thus, C. botulinum type E and its nontoxigenic variants, which are nonproteolytic, share common somatic antigens with the nonproteolytic strains of types B and F. Absorption of antiserum of a strain of any one type with antigen of any of the others removes the antibody to all three types. In the same manner, C. botulinum type A shares somatic antigens with the proteolytic strains of types B and F, and absorption of any one antiserum with an antigen of either of the other two types removes the antibody to all three types. Partial cross-agglutination of C. sporogenes, C. tetani, and C. histolyticum with the somatic antisera of the proteolytic group was also observed.     

Toxin production by Clostridium botulinum in grass.

Investigations on farms where botulism has occurred in cows showed that proteolytic Clostridium botulinum type B was present in newly made grass silages. Experiments were undertaken to study growth and toxin production of C. botulinum in grass. Of the strains tested only proteolytic strains of C. botulinum types A and B were able to produce toxin with grass as a substrate. Proteolytic strains of type B produced both medium (12S) and large (16S) toxin forms. The minimal water activity (aw) for toxin production at pH 6.5 and 5.8 was 0.94. At pH 5.3, toxin was produced at an aw of 0.985. These results indicate that proteolytic strains of C. botulinum (if present) may multiply and produce toxin in wilted grass silages.     

Toxin production by Clostridium botulinum in grass.

Investigations on farms where botulism has occurred in cows showed that proteolytic Clostridium botulinum type B was present in newly made grass silages. Experiments were undertaken to study growth and toxin production of C. botulinum in grass. Of the strains tested only proteolytic strains of C. botulinum types A and B were able to produce toxin with grass as a substrate. Proteolytic strains of type B produced both medium (12S) and large (16S) toxin forms. The minimal water activity (aw) for toxin production at pH 6.5 and 5.8 was 0.94. At pH 5.3, toxin was produced at an aw of 0.985. These results indicate that proteolytic strains of C. botulinum (if present) may multiply and produce toxin in wilted grass silages.     

Proteases produced by a proteolytic mutant of Clostridium botulinum type E.

A proteolytic mutant from Clostridium botulinum type E produced extracellular proteases after the end of exponential growth coinciding with the period of sporulation. Proteases were separated into four fractions by chromatography on a DEAE-cellulose column. One was a sulphydryl-dependent protease that also apparently required a divalent cation for enzyme activity since it was inhibited by EDTA. This enzyme hydrolysed synthetic amide and ester compounds containing an arginine residue, and showed some activity towards L-lysine methyl ester. It appeared that two of the other proteases were serine proteases and the fourth was a metal protease. These last three proteases did not require a thiol agent and did not hydrolyse any of the synthetic amides or esters examined. Only the sulphydryl-dependent protease could activate C. botulinum type B, E and F toxins. The ability of this enzyme to activate type B and E toxins was markedly lower than that of trypsin. The susceptibility of type B toxin to this protease was lower than that of type E toxin. C2 toxin was not activated by this enzyme. It is suggested that the sulphydryl-dependent protease in this proteolytic mutant of C. botulinum type E has properties similar to those of proteases from C. botulinum types B and F.     

Efficient DNA fingerprinting of Clostridium botulinum types A, B, E, and F by amplified fragment length polymorphism analysis

Amplified fragment length polymorphism (AFLP) analysis was applied to characterize 33 group I and 37 group II Clostridium botulinum strains. Four restriction enzyme and 30 primer combinations were screened to tailor the AFLP technique for optimal characterization of C. botulinum. The enzyme combination HindIII and HpyCH4IV, with primers having one selective nucleotide apiece (Hind-C and Hpy-A), was selected. AFLP clearly differentiated between C. botulinum groups I and II; group-specific clusters showed <10% similarity between proteolytic and nonproteolytic C. botulinum strains. In addition, group-specific fragments were detected in both groups. All strains studied were typeable by AFLP, and a total of 42 AFLP types were identified. Extensive diversity was observed among strains of C. botulinum type E, whereas group I had lower genetic biodiversity. These results indicate that AFLP is a fast, highly discriminating, and reproducible DNA fingerprinting method with excellent typeability, which, in addition to its suitability for typing at strain level, can be used for C. botulinum group identification.     

Patterns in the formation of proteolytic enzymes by different strains of C1. botulinum type F]

The authors studied regularities attending the accumulation of proteolytic enzyme and toxin by C1. botulinum, type F, strains in the medium. Strains No. 470, 200, 76, 55 proved to possess caseinolytic capacity, whereas strains Eklund and Craig were "nonproteolytic". C1. botulinum strain, type F, medium and growing conditions providing a high yield of proteolytic enzymes were selected. Some properties of proteolytic enzyme of strain No. 470 were studied.