Monoclonal antibodies for use in detection of Bacillus and Clostridium spores.

Five monoclonal antibodies against bacterial spores of Bacillus cereus T and Clostridium sporogenes PA3679 were developed. Two antibodies (B48 and B183) were selected for their reactivity with B. cereus T spores, two (C33 and C225) were selected for their reactivity with C. sporogenes spores, and one (D89) was selected for its reactivity with both B. cereus and C sporogenes spores. The isotypes of the antibodies were determined to be immunoglobulin G2a (IgG2a) (B48), IgG1 (B183), and IgM (C33, C225, and D89). The antibodies reacted with spores of B. cereus T, Bacillus subtilis subsp. globigii, Bacillus megaterium, Bacillus stearothermophilus, C. sporogenes, Clostridium perfringens, and Desulfotomaculum nigrificans. Antibody D89 also reacted with vegetative cells of B. cereus and C. sporogenes. Analysis of B. cereus spore extracts showed that two of the antigens with which the anti-Bacillus antibodies reacted had molecular masses of 76 kDa and approximately 250 kDa. Immunocytochemical localization indicated that antigens with which B48, B183, and D89 react are on the exosporium of the B. cereus T spore. Antibody D89 reacted with the exosporium and outer cortex of C. sporogenes spores in immunocytochemical localization studies but did not react with extracts of C. sporogenes or B. cereus spores in Western blotting. Some C. sporogenes antigens were not stable during long-term storage at -20 degrees C. Antibodies B48, B183, and D89 should prove to be useful tools for developing immunological methods for the detection of bacterial spores.     

Effect of Temperature on Germination of Spores from Some Bacillus and Clostridium Species

The effect of temperature on germination of spores of Bacillus subyilis, B. megaterium. B. cereus, Clostridium sporogenes, Cl. butyricum and Cl. bifermentans was studied. At lower temperatures (+5°C to +10°C) the three Glostridium species germinated to a less extent than the three Bacillus. species. The optimum temperature for germination of the six species varied between +35°C and +45°C. The Clostridium species were more tolerant to heat than the Bacillus species.     

The effect of transition metal ions on the resistance of bacterial spores to hydrogen peroxide and to heat.

The presence of 10 microM-Cu2+ increased the lethal effect of hydrogen peroxide on spores of Clostridium bifermentans but not on those of Clostridium sporogenes PA 3679, Clostridium perfringens, Bacillus cereus or Bacillus subtilis var. niger. Cu2+ at 100 muM also increased the lethal effect of heat on spores of C. bifermentans but not on those of B. sutilis var. niger. The rate and extent of Cu2+ uptake by spores of C. bifermentans and B. subtilis var. niger were similar, but examination of unstained sections of spores by electron microscopy suggested that Cu2+ is bound by the protoplasts of spores of C. bifermentans but not of B. subtilis var. niger.     

Note: Occurrence and persistence of culturable clostridial spores on the leaves of horticultural plants

Clostridial spores were found in numbers from less than 1 to over 50 colony-forming units cm^-2 on mature leaves of 19 species of horticultural plants under commercial cultivation in five localities in Apulia (SE Italy). Of 1828 clostridial isolates, 87% were identified phenotypically and ascribed to Clostridium pasteurianum, Cl. sporogenes, Cl. butyricum, Cl. roseum, Cl. perfringens, Cl. felsineum and Cl. acetobutylicum , in decreasing order of frequency. When spore suspensions of Cl. pasteurianum, Cl. perfringens, Cl. roseum and Cl. sporogenes were inoculated onto the leaves of basil, leaf-beet, lettuce, rocket-salad, spinach and tomato in the greenhouse, spore counts at first invariably declined shortly after inoculation, then rose again significantly for Cl. pasteurianum and Cl. perfringens on basil and for Cl. sporogenes on tomato in summer.     

Multiple modes of inhibition of spore germination and outgrowth by reduced pH and sorbate

Germination and outgrowth of three strains of Clostridium botulinum in PYEG medium were measured by phase contrast microscopy. Reduction in pH from 7 to 5·5 completely inhibited germination of strain 12885A, reduced the extent of germination of strain 62A and had no effect on the extent of germination of strain 53B. At pH 5·5, 225 mg/1 of undissociated sorbic acid had no effect on the germination of strain 53B, while at pH 6·5, 225 mg/1 of undissociated sorbic acid completely inhibited germination of strains 62A and 12885A. Outgrowth of germinated spores of strains 62A and 53B was not inhibited at pH 5·5, but the addition of sorbate (225 mg/1 undissociated sorbic acid) completely inhibited outgrowth. Sorbate inhibited germination of Cl. botulinum and Bacillus cereus spores triggered to germinate by amino acids. Inhibition occurred after germinant binding, as measured by commitment to germinate.     

Tailing of survivor curves of clostridial spores heated in edible oils

Tailing of survivor curves was observed for Clostridium sporogenes PA 3679 and Cl. botulinum 62A spores heated whilst suspended in edible oils, but not for the same spores suspended in buffer (pH 7˙2) or mineral oil or for Bacillus cereus F4165/75 spores suspended in buffer or oils. The tailing cannot be ascribed to a genetic or developmental heterogeneity in the resistance of the spore population or to a heterogeneity of the treatment severity during heating. Heat adaptation due to the release of protective factor(s), to the selection for resistant spores or to the diffusion of oil constituents inside the spore protoplast to protect key molecules from heat denaturation was also ruled out. The tailing can be ascribed to spore clumping during the course of heating or to a heterogeneity in heat resistance of germination system(s) within spores, concurrently with the activation of a dormant germination system. It is probably caused by some oleic acid containing triglycerides.     

Effect of Various Gas Atmospheres on Destruction of Microorganisms in Dry Heat

The heat resistance of dry bacterial spores was tested in various gases at temperatures ranging from 121.1 to 160 C (250 to 320 F). Spores of Clostridium sporogenes (PA 3679) were heated in air, carbon dioxide, and helium; spores of Bacillus subtilis 5230 were heated in these gases and also in oxygen and in nitrogen. The surrounding gas influenced the heat resistance, but the differences among gases were small. D values were about 7 min at 148.9 C (300 F); z values were about 18.3 C (33 F) for B. subtilis, and about 21.7 C (39 F) for C. sporogenes. The resistance of B. subtilis in carbon dioxide was about the same as in air, but lower than in all other gases; resistance in helium and nitrogen was about the same, and was higher than in all other gases. C. sporogenes had the least resistance in air; the resistance was about the same in carbon dioxide and helium. For B. subtilis, the gases in order of increasing heat resistance were carbon dioxide, air, oxygen, helium, and nitrogen, and for C. sporogenes, air, carbon dioxide, and helium. Neither oxygen content nor molecular weight of the gas appeared to have a marked influence on dry-heat resistance of the spores, whereas the more inert gases seemed to yield larger D values.     

Multiple modes of inhibition of spore germination and outgrowth by reduced pH and sorbate

Germination and outgrowth of three strains of Clostridium botulinum in PYEG medium were measured by phase contrast microscopy. Reduction in pH from 7 to 5.5 completely inhibited germination of strain 12885A, reduced the extent of germination of strain 62A and had no effect on the extent of germination of strain 53B. At pH 5.5, 225 mg/l of undissociated sorbic acid had no effect on the germination of strain 53B, while at pH 6.5, 225 mg/l of undissociated sorbic acid completely inhibited germination of strains 62A and 12885A. Outgrowth of germinated spores of strains 62A and 53B was not inhibited at pH 5.5, but the addition of sorbate (225 mg/l undissociated sorbic acid) completely inhibited outgrowth. Sorbate inhibited germination of Cl. botulinum and Bacillus cereus spores triggered to germinate by amino acids. Inhibition occurred after germinant binding, as measured by commitment to germinate.     

Application of the 'Inoculated Pack Test' method for the determination of the heat resistance of Clostridium sporogenes PA3679 spores in acidified mushrooms

The effect of pH in the range 5.2–6.7 on the thermal destruction of Clostridium sporogenes PA3679 spores suspended in mushrooms in brine acidified with citric acid was examined by the 'inoculated pack test' method. The results indicated that increasing acidity is accompanied by decreasing decimal reduction times at 121.1°C: D _121.1 at pH 6.0 and 5.2 was, respectively, 64% and 17.5% of that at pH 6.7, the pH of natural mushrooms ( D _121.1= 2.22 min). A linear model ( r = 0.988, α= 0.05) was developed where the D _121.1 value was a function of the pH over the range studied. The inoculated pack test seems to be the only method to evaluate the actual microbial heat resistance, whether of spore or of vegetative forms, in order to estimate within reasonably close limits a suitable process time required to eliminate health hazards and to prevent spoilage losses in a given food product.     

Tailing of survivor curves of clostridial spores heated in edible oils

Tailing of survivor curves was observed for Clostridium sporogenes PA 3679 and Cl. botulinum 62A spores heated whilst suspended in edible oils, but not for the same spores suspended in buffer (pH 7.2) or mineral oil or for Bacillus cereus F4165/75 spores suspended in buffer or oils. The tailing cannot be ascribed to a genetic or developmental heterogeneity in the resistance of the spore population or to a heterogeneity of the treatment severity during heating. Heat adaptation due to the release of protective factor(s), to the selection for resistant spores or to the diffusion of oil constituents inside the spore protoplast to protect key molecules from heat denaturation was also ruled out. The tailing can be ascribed to spore clumping during the course of heating or to a heterogeneity in heat resistance of germination system(s) within spores, concurrently with the activation of a dormant germination system. It is probably caused by some oleic acid containing triglycerides.     

A medium for the isolation, enumeration and rapid presumptive identification of injured Clostridium perfringens and Bacillus cereus

A blood-free egg yolk medium (BCP) containing pyruvate, inositol, mannitol and a bromocresol purple indicator in a nutrient agar base has been developed to initiate the growth of Clostridium perfringens . It is comparable to blood agar for the growth of normal, chilled stored vegetative cells and heat-injured spores of Cl. perfringens and Bacillus cereus . It has the advantage over blood agar in exhibiting presumptive evidence of Cl. perfringens (production of lecithinase and inositol fermentation) after an overnight incubation at 43°C-45°C. Pyruvate, catalase and other hydrogen peroxide degraders were found to remove toxins rapidly formed in media exposed to air and light. Free radical scavengers of superoxide, hydroxyl ions and singlet oxygen were ineffective. Without scavengers the formation of 10–20 μg/ml hydrogen peroxide in the exposed medium was indicated and found lethal to injured Cl. perfringens .
The BCP medium has been used successfully for the rapid identification and enumeration of Cl. perfringens in foods and faeces from food poisoning outbreaks and cases of suspected infectious diarrhoea. Greater recovery of severely injured vegetative Cl. perfringens could be obtained by pre-incubation at 37°C of inoculated media for 2–4 h followed by overnight incubation at 43°C-45°C. Tryptose-sulphite-cyclo-serine and Shahidi-Ferguson-perfringens agar base were found to inhibit the growth of several strains of injured vegetative Cl. perfringens . This was not completely overcome by the addition of pyruvate. The inclusion of mannitol also allows the medium to be used for the presumptive identification of B. cereus . Growth and lecithinase activity are profuse on BCP. Heat-injured spores are recovered equally well on BCP and blood agar. A scheme for the identification of some other clos-tridia on BCP is presented.     

Effect of High Concentrations of Carbon Dioxide on Growth Rate of Pseudomonas fragi, Bacillus cereus and Streptococcus cremoris

The maximum specific growth rates of Pseudomonas fragi, Bacillus cereus and Streptococcus cremoris were studied over a wide range of carbon dioxide concentrations. The growth rate compared with a control was reduced to 50% in Ps. fragi at 0–5 atm CO₂, in B. cereus at 1—3 atm and in Strep, cremoris at 8–6 atm. B. cereus and Strep, cremoris were completely inhibited at 3 and 11 atm CO₂, respectively. The growth rate of the aerobic Ps. fragi at 0–99 atm CO₂ (0–01 atm oxygen) was reduced to about 20% of that in air. The growth rate of Ps. fragi was decreased at oxygen concentrations lower than 0–01 atm.
When Ps. fragi was grown at oxygen limitation (0.0025 atm oxygen) and exposed to 0.99 atm CO₂, the inhibiting effect of the CO₂ was added to that of the oxygen limitation. No indications of a synergistic effect between CO₂ inhibition and oxygen limitation were noted.
B. cereus and Strep, cremoris were tested under anaerobic conditions.     

Mechanisms of sorbate inhibition of Bacillus cereus T and Clostridium botulinum 62A spore germination.

The mechanism by which potassium sorbate inhibits Bacillus cereus T and Clostridium botulinum 62A spore germination was investigated. Spores of B. cereus T were germinated at 35 degrees C in 0.08 M sodium-potassium phosphate buffers (pH 5.7 and 6.7) containing various germinants (L-alanine, L-alpha-NH2-n-butyric acid, and inosine) and potassium sorbate. Spores of C. botulinum 62A were germinated in the same buffers but with 10 mM L-lactic acid, 20 mM sodium bicarbonate, L-alanine or L-cysteine, and potassium sorbate. Spore germination was monitored by optical density measurements at 600 nm and phase-contrast microscopy. Inhibition of B. cereus T spore germination was observed when 3,900 micrograms of potassium sorbate per ml was added at various time intervals during the first 2 min of spore exposure to the pH 5.7 germination medium. C. botulinum 62A spore germination was inhibited when 5,200 micrograms of potassium sorbate per ml was added during the first 30 min of spore exposure to the pH 5.7 medium. Potassium sorbate inhibition of germination was reversible for both B. cereus T and C. botulinum 62A spores. Potassium sorbate inhibition of B. cereus T spore germination induced by L-alanine and L-alpha-NH2-n-butyric acid was shown to be competitive in nature. Potassium sorbate was also a competitive inhibitor of L-alanine- and L-cysteine-induced germination of C. botulinum 62A spores.     

Identification and Typing of Clostridia in Raw Milk in Egypt

S ummary : Three spp. of clostridia were isolated from samples of raw cow and buffalo milk obtained near Cairo. Of 150 isolates of anaerobes, 108 were Clostridium perfringens , 30 were Cl. butyricum , and 12 were Cl. sporogenes. The Cl. perfringens isolates comprised 100 nonhaemolytic and 8 pathogenic haemolytic strains. The latter strains typed by neutralization tests, were of type A. Fifteen of the nonhaemolytic strains were also of type A; of these, 6 strains produced heat resistant spores and 9 strains produced heat susceptible spores. Feeding mice with these 15 nonhaemolytic strains caused marked reduction in intestinal passage time.     

Salt extends the upper temperature limit for growth of food-poisoning bacteria

Inclusion of NaCl into the growth medium raised the upper temperature limit of growth of the following organisms: Staphylococcus aureus (two strains), Salmonella senftenberg, S. typhimurium, Escherichia coli, Streptococcus faecalis, Bacillus cereus, Clostridium sporogenes, C. perfringens (two strains). The magnitude of the response varied with the culture, the largest being 3.5 degrees with B. cereus cells. The spores of B. cereus were not protected by salt but clostridial spores behaved as the vegetative cells (response of 2.5 degrees). The optimal salt concentration for the protective effect varied with the organism ranging from 0.2 M for the Gram-negative organisms to 1.0 M for S. aureus.     

Efficient inhibition of germination of coat-deficient bacterial spores by multivalent metal cations, including terbium (Tb³+)

Release of dipicolinic acid (DPA) and its fluorescence with terbium (Tb(3+)) allow rapid measurement of the germination and viability of spores of Bacillus and Clostridium species. However, germination of coat-deficient Bacillus spores was strongly inhibited by Tb(3+) and some other multivalent cations. Tb(3+) also inhibited germination of coat-deficient Clostridium perfringens spores.     

The Effect of Carbon Dioxide on Spore Germination in Some Clostridia

S ummary . The rate and extent of spore germination in 3 cultures of clostridia have been investigated under controlled gas environment conditions. Germination in each of them was markedly stimulated by carbon dioxide in a variety of media. Quantitative measurements on 2 of the cultures indicated that while Clostridium bifermentans gave rapid and complete germination with as little as 3 mM bicarbonate, Cl. sporogenes PA 3679/S₂ required higher concentrations for maximal response.     

Growth energetics of Clostridium sporogenes NCIB 8053: modulation by CO2

The effects of the partial pressure of carbon dioxide on the growth energetics of Clostridium sporogenes NCIB 8053 grown in chemostat culture were investigated in defined minimal media. Both the 'maintenance' requirements and the growth yield coefficients were dependent upon the partial pressure of carbon dioxide in otherwise glucose-limited cultures. Since growth yield coefficients decreased along with the apparent 'maintenance' requirements in essential amino acid/fatty acid medium when the partial pressure of carbon dioxide was increased above 0.5 atm, the occurrence of some type of metabolic uncoupling seemed likely. By contrast, when the organism was grown in amino acid complete medium both the maintenance requirements and the growth yield coefficients were increased when the partial pressure of carbon dioxide was raised above 0.5 atm partial pressure of carbon dioxide, suggesting an increased efficiency of growth. A futile cycle involving carbon dioxide is proposed as a factor contributing to the variable extent of free energy dissipation within this organism.     

Stimulation of germination of unactivated Bacillus cereus spores by ammonia

Inclusion of ammonia in germinant mixtures containing L-alanine and inosine stimulated germination of unactivated Bacillus cereus spores at rates equal to those obtained using heat-activated spores without ammonia. D-Alanine had little effect on germination of heat-activated spores, but severely inhibited germination of unactivated spores in the presence of ammonia. Ammonia did not replace the requirement for either L-alanine or inosine: all three compounds were required for rapid germination. Kinetic analysis suggested that the functions of ammonia and L-alanine were more closely related than the functions of ammonia and inosine. With rate-saturating concentrations of L-alanine and inosine, germination rates showed saturation kinetics for ammonia with a Km for NH4Cl of 5 mM. Comparisons of the effects of salts, amines and pH on germination rates suggested that NH4OH rather than NH+4 was the rate-limiting form of ammonia. In comparisons of various strains of B. cereus, stimulation of germination by ammonia occurred in all cases, although spores of most soil isolates germinated more rapidly than B. cereus T spores in the absence of ammonia.