Improved Medium for Sporulation of Clostridium perfringens

An improved sporulation medium has been developed in which all five strains of Clostridium perfringens tested exhibited a 100- to 10,000-fold increase in numbers of spores when compared with spore yields in SEC medium under comparable conditions. In addition, three of five strains produced a 100- to 1,000-fold increase, with the remaining two strains yielding approximately the same numbers of spores, when compared with strains cultured in Ellner medium. At the 40-hr sampling time, 18 of 27 strains produced a 10- to 100-fold increase in numbers of spores in our medium, when compared to spore production obtained in a medium recently reported by Kim et al. The new medium contained yeast extract, 0.4%; proteose peptone, 1.5%; soluble starch, 0.4%; sodium thioglycolate, 0.1%; and Na(2)HPO(4). 7H(2)O, 1.0%. In some cases, the spore yield could be increased by the addition of activated carbon to the new medium. The inclusion of activated carbon in the medium resulted in spores with slightly greater heat resistance than spores produced in the new medium without added carbon or in SEC or in Ellner medium. The major differences in heat resistance of the various strains appeared to be genetically determined rather than reflections of a particular sporulation medium. A definite heat-shock requirement was shown for four of four strains, with the optimal temperature ranging from 60 C for a heat-sensitive strain to 80 C for a heat-resistant strain. Heating for 20 min at the optimal temperature resulted in a 100-fold increase over the viable count obtained after heating for 20 min at 50 C.     

Relationship of sporulation, enterotoxin formation, and spoilage during growth of Clostridium perfringens type A in cooked chicken

Sporulation and enterotoxin formation were determined for 17 strains of Clostridium perfringens type A in autoclaved chicken dark meat and in Duncan-Strong sporulation medium. The mean numbers of heat-resistant spores detected after 24 h at 37 degrees C were log10 1.13 to log10 7.64/ml in Duncan-Strong medium and log10 4.93 to log10 6.59/g in chicken. Of 17 strains, 7 formed enterotoxin in Duncan-Strong culture supernatant (1.0 to 60 microgram/ml) and 8 produced enterotoxin in chicken (0.21 to 24 microgram/g). Additional studies with chicken were conducted with C. perfringens NCTC 8239. With an inoculum of 10(6) cells per g, greater than log10 7.99 vegetative cells per g were detected by 4 h in chicken at 37 degrees C. Heat-resistant spores occurred by 4 and 6 h and enterotoxin occurred by 8 and 6 h in autoclaved chicken dark meat and barbecued chicken drumsticks, respectively. Enterotoxin was detected in autoclaved dark meat after incubation at 45 degrees C for 1.5 h followed by 37 degrees C for 4.5 h, but not after incubation at 45 degrees C for 1.5 to 8 h. With an inoculum of 10(2) cells per g in oven-cooked or autoclaved chicken, greater than log10 8.00 vegetative cells per g were detected by 6 to 8 h at 37 degrees C, heat-resistant spores were detected by 8 h, and enterotoxin was detected by 12 h. A statistical analysis of odor determinants of chicken after growth of C. perfringens indicated that, at the 95% confidence level, the product was considered spoiled (off or unwholesome odor) by the time spores or enterotoxin were formed.     

Relationship of sporulation, enterotoxin formation, and spoilage during growth of Clostridium perfringens type A in cooked chicken.

Sporulation and enterotoxin formation were determined for 17 strains of Clostridium perfringens type A in autoclaved chicken dark meat and in Duncan-Strong sporulation medium. The mean numbers of heat-resistant spores detected after 24 h at 37 degrees C were log10 1.13 to log10 7.64/ml in Duncan-Strong medium and log10 4.93 to log10 6.59/g in chicken. Of 17 strains, 7 formed enterotoxin in Duncan-Strong culture supernatant (1.0 to 60 microgram/ml) and 8 produced enterotoxin in chicken (0.21 to 24 microgram/g). Additional studies with chicken were conducted with C. perfringens NCTC 8239. With an inoculum of 10(6) cells per g, greater than log10 7.99 vegetative cells per g were detected by 4 h in chicken at 37 degrees C. Heat-resistant spores occurred by 4 and 6 h and enterotoxin occurred by 8 and 6 h in autoclaved chicken dark meat and barbecued chicken drumsticks, respectively. Enterotoxin was detected in autoclaved dark meat after incubation at 45 degrees C for 1.5 h followed by 37 degrees C for 4.5 h, but not after incubation at 45 degrees C for 1.5 to 8 h. With an inoculum of 10(2) cells per g in oven-cooked or autoclaved chicken, greater than log10 8.00 vegetative cells per g were detected by 6 to 8 h at 37 degrees C, heat-resistant spores were detected by 8 h, and enterotoxin was detected by 12 h. A statistical analysis of odor determinants of chicken after growth of C. perfringens indicated that, at the 95% confidence level, the product was considered spoiled (off or unwholesome odor) by the time spores or enterotoxin were formed.     

Time of Enterotoxin Formation and Release During Sporulation of Clostridium perfringens Type A

Clostridium perfringens enterotoxin was detected intracellularly about 3 hr after the inoculation of vegetative cells into sporulation medium. The subsequent increase in intracellular enterotoxin concentration roughly paralleled but followed by 2.5 to 5 hr the increase in number of heat-resistant spores. The increase in biologically active toxin coincided with the increase in enterotoxin antigen. Enterotoxin was released from the sporangium with its lysis, concomitantly with the mature spore release.     

Enterotoxin formation by Clostridium perfringens type A studied by the use of fluorescent antibody.

Fluorescein isothiocyanate-conjugated antibody to purified enterotoxin of Clostridium perfringens was used to study the intracellular formation of enterotoxin by this organism. Enterotoxin was detected at 4 h of growth at the end of the cell containing forespore. With the development of the spore, enterotoxin accumulation continued and involved the entire length of the cell until its lysis with the release of enterotoxin and mature spore. The spores did not contain demonstrable enterotoxin. Only a certain number of the sporulated cells of the enterotoxigenic strains studied produced this toxin. The amount of enterotoxin produced varied with sporulation percentage, and between strains and individual cells.     

Influence of carbohydrates on growth and sporulation of Clostridium perfringens in a defined medium with or without guanosine.

Clostridium perfringens strains NCTC 8238, NCTC 8798, NCTC 8679, 8-6, FD-1, and PS52 formed high levels of heat-resistant spores in a defined medium (D) with various sugars as energy sources. Strain PS49 formed high levels of heat-resistant spores when grown with dextrin and methylxanthines. The experiments showed the possibility of carrying out experiments on the sporulation of certain C. perfringens strains in a completely defined medium, without using the ill-defined polysaccharide dextrin. The addition of guanosine and sucrose to D medium generally suppressed sporulation in most strains and made it possible to prepare overnight cultures consisting mainly of vegetative cells. These cultures could be used to inoculate D medium directly, eliminating both the need to wash cells and the lag which normally occurs when cells have been grown in a different medium. Except for strains PS52 and NCTC 8238, guanosine generally increased growth rates and reduced sporulation for all strains when grown on simple sugars. Methylxanthines decreased growth rates and increased sporulation of NCTC 8679 and PS49 when present in D medium with dextrin. In the absence of guanosine, strains NCTC 8798 and 8-6 grew much slower on glucose than on disaccharides. Strain PS52 grew on lactose only after a prolonged lag. For strains requiring dextrin for good sporulation, a commercial dextrin (Difco Laboratories) was found to be readily filter sterilized, making it possible to prepare large amounts of media for use in the production of spores (or enterotoxin).     

Influence of carbohydrates on growth and sporulation of Clostridium perfringens in a defined medium with or without guanosine

Clostridium perfringens strains NCTC 8238, NCTC 8798, NCTC 8679, 8-6, FD-1, and PS52 formed high levels of heat-resistant spores in a defined medium (D) with various sugars as energy sources. Strain PS49 formed high levels of heat-resistant spores when grown with dextrin and methylxanthines. The experiments showed the possibility of carrying out experiments on the sporulation of certain C. perfringens strains in a completely defined medium, without using the ill-defined polysaccharide dextrin. The addition of guanosine and sucrose to D medium generally suppressed sporulation in most strains and made it possible to prepare overnight cultures consisting mainly of vegetative cells. These cultures could be used to inoculate D medium directly, eliminating both the need to wash cells and the lag which normally occurs when cells have been grown in a different medium. Except for strains PS52 and NCTC 8238, guanosine generally increased growth rates and reduced sporulation for all strains when grown on simple sugars. Methylxanthines decreased growth rates and increased sporulation of NCTC 8679 and PS49 when present in D medium with dextrin. In the absence of guanosine, strains NCTC 8798 and 8-6 grew much slower on glucose than on disaccharides. Strain PS52 grew on lactose only after a prolonged lag. For strains requiring dextrin for good sporulation, a commercial dextrin (Difco Laboratories) was found to be readily filter sterilized, making it possible to prepare large amounts of media for use in the production of spores (or enterotoxin).     

Sporulation of Clostridium perfringens in a Modified Medium and Selected Foods

A modified sporulation medium for Clostridium perfringens was formulated in which a larger number of spores were produced than in SEC broth and in which spores of greater heat resistance were produced than in Ellner's medium when it was also used as the suspending medium. This modified medium consisted of 1.5% peptone; 3.0% Trypticase; 0.4% starch; 0.5% NaCl; and 0.02% MgSO(4). The addition of 0.1% sodium thioglycolate and 0.0001% thiamine hydrochloride was optional. The optimal temperature for sporulation of five strains was 37 C in comparison with 5, 22, and 46 C. Sporulation had occurred by 6 hr and was essentially complete after 20 hr at 37 C. Noyes veal broth without glucose also supported the formation of heat-resistant spores but in smaller numbers than did the modified medium. Very low numbers of spores, or none, were produced under the same conditions in pea or tuna slurries.     

Incidence of Enterotoxigenic Clostridium perfringens in Healthy Humans in relation to the Enhancement of Enterotoxin Production by Heat Treatment

Enterotoxin production was greatly enhanced in two of five food poisoning strains of Clostridium perfringens subjected to heat treatment prior to incubation in Duncan and Strong sporulation medium. Heating was carried out on three successive cultures of each strain, the optimum temperature for treatment being 85 °C for one strain and 95 °C for another: on each occasion cultures were heated for 20 min. The triple heat treatment procedure was used in testing strains of Cl. perfringens isolated from faeces of healthy human subjects for production of enterotoxin. Eleven of 35 (31%) individuals were found to be carriers of enterotoxigenic strains, the isolates producing more than 0·1 μ/ml of enterotoxin. Six of the 11 enterotoxigenic strains were killed by heating at 95 °C but one isolate produced more enterotoxin following treatment at this temperature than after heating at 75 °C.     

Influence of Carbohydrates on Growth and Sporulation of Clostridium perfringens Type A

Growth and sporulation of Clostridium perfringens type A in Duncan and Strong (DS) sporulation medium was investigated. A biphasic growth response was found to be dependent on starch concentration. Maximal levels of heat-resistant spores were formed at a starch concentration of 0.40%. Addition of glucose, maltose, or maltotriose to a sporulating culture resulted in an immediate turbidity increase, indicating that biphasic growth in DS medium may be due to such starch degradation products. Amylose and, to a lesser extent, amylopectin resulted in biphasic growth when each replaced starch in the sporulation medium. A levels of heat-resistant spores approximately equal to the control was produced with amylopectin but not amylose as the added carbohydrate. Addition of glucose or maltose to a DS medium without starch at stage II or III of sporulation did not alter the level of heat-resistant spores as compared with the level obtained in DS medium with starch. Omission of starch or glucose or maltose resulted in an approximately 100-fold decrease in the number of heat-resistant spores, although the percentage of sporulation (90%) was unaffected. The role of starch and amylopectin in the formation of heat-resistant spores probably involves the amyloytic production of utilizable short-chain glucose polymers that provide an energy source for the completion of sporulation.     

Enterotoxic strains of Clostridium perfringens and sporulation

Clostridium perfringens strains of A type capable of enterotoxin (CPE) synthesis may be a potential source of food-poisoning. Suitability of methods for CPE detection on the protein level is limited by difficulties in inducing sporulation in vitro. A number of unknown facts concerning coregulation the sporulation processes and CPE synthesis are recognised. The goal of the work was to determine the level of correlation between CPE synthesis and spores formation. Enterotoxin and cpe gen were detected by RPLA after sporulation induction test and by methods based on amplification on the DNA and mRNA levels. Sixty-four C. perfringens strains of A type isolated from patients with food poisoning symptoms and from food samples were analysed. Collection of isolates was differentiated as not enterotoxic, enterotoxic, and potentially enterotoxic strains based on appropriate strain profile: plc(+), cpe(-), CPE(-); plc(+), cpe(+), CPE(+); and plc(+), cpe(-), CPE(-), respectively. No significant difference between expression of cpe mRNA in vegetative and sporulation phase was found. The obtained results indicate that sporulation is not an essential factor for cpe gene expression.     

Raffinose increases sporulation and enterotoxin production by Clostridium perfringens type A.

Replacement of starch with raffinose in Duncan and Strong sporulation medium improved percent sporulation in six of eight strains tested. Enterotoxin concentration in cell extracts was increased in the case of four of five known enterotoxin-positive strains. With strain NCTC 10240, levels of 0.3, 0.4, and 0.5% raffinose produced the highest enterotoxin concentration 300 to 320 micrograms of enterotoxin per mg of cell extract protein. At a level of 0.4% raffinose the highest enterotoxin concentration in cell extracts of NCTC 10240 occurred after 8 h of growth in Duncan and Strong medium. Enterotoxin produced in the presence of starch or raffinose by three separate strains all migrated at similar Rm by polyacrylamide gel electrophoresis.     

Raffinose increases sporulation and enterotoxin production by Clostridium perfringens type A.

Replacement of starch with raffinose in Duncan and Strong sporulation medium improved percent sporulation in six of eight strains tested. Enterotoxin concentration in cell extracts was increased in the case of four of five known enterotoxin-positive strains. With strain NCTC 10240, levels of 0.3, 0.4, and 0.5% raffinose produced the highest enterotoxin concentration 300 to 320 micrograms of enterotoxin per mg of cell extract protein. At a level of 0.4% raffinose the highest enterotoxin concentration in cell extracts of NCTC 10240 occurred after 8 h of growth in Duncan and Strong medium. Enterotoxin produced in the presence of starch or raffinose by three separate strains all migrated at similar Rm by polyacrylamide gel electrophoresis.     

The suitability of Tórtora's medium for the production of enterotoxin in Clostridium perfringens strains

Examination of 200 samples from soil and the same number of samples from healthy human feces yielded 49 (24.5%) and 105 (52.5%) strains of heat-resistant Clostridium perfringens respectively. Fourteen (7.0%) strains isolated from soil and 37 (18.5%) from feces synthesized enterotoxin, as demonstrated by Tórtora's method, at sufficient levels to permit its detection by mouse lethality, microslide double gel diffusion or counterimmunoelectrophoresis tests. By using the Duncan-Strong (DS) method, only four (2%) enterotoxigenic strains from soil and 14 (7.0%) from feces were obtained. The supernatant fluid from two enterotoxigenic-negative strains grown in DS medium gave a false-positive reaction when they were injected intravenously into mice. Tórtora's medium was preferable because a larger number of isolated strains produced spores and enterotoxin to permit their recognition as enterotoxigenic strains.     

Enterotoxin synthesis by nonsporulating cultures of Clostridium perfringens

Chemostat-cultured Clostridium perfringens ATCC 3624 and NCTC 10240, and a nonsporulating mutant strain, 8-5, produced enterotoxin in the absence of sporulation when cultured in a chemically defined medium at a 0.084-h-1 dilution rate at 37 degrees C. The enterotoxin was detected by serological and biological assays. Examination of the chemostat cultures by electron microscopy did not reveal sporulation at any stage. The culture maintained enterotoxigenicity throughout cultivation in a continuous system. The enterotoxin was detected in batch cultures of each strain cultivated in fluid thioglycolate medium and a chemically defined medium. No heat-resistant or light-refractile spores were detected in batch cultures during the exponential growth.     

Enterotoxin synthesis by nonsporulating cultures of Clostridium perfringens.

Chemostat-cultured Clostridium perfringens ATCC 3624 and NCTC 10240, and a nonsporulating mutant strain, 8-5, produced enterotoxin in the absence of sporulation when cultured in a chemically defined medium at a 0.084-h-1 dilution rate at 37 degrees C. The enterotoxin was detected by serological and biological assays. Examination of the chemostat cultures by electron microscopy did not reveal sporulation at any stage. The culture maintained enterotoxigenicity throughout cultivation in a continuous system. The enterotoxin was detected in batch cultures of each strain cultivated in fluid thioglycolate medium and a chemically defined medium. No heat-resistant or light-refractile spores were detected in batch cultures during the exponential growth.     

Heat resistance, spore germination, and enterotoxigenicity of Clostridium perfringens

Heat resistance at 95 C, heat activation at 75 C, and germination response were determined for spores of 10 serotype strains of Clostridium perfringens type A, including five heat-resistant and five heat-sensitive strains. The D95-values ranged from 17.6 to 63.0 and from 1.3 to 2.8 for the heat-resistant and the heat-sensitive strains, respectively. The heat-activation values, the ratios between the heated and unheated viable counts of spore suspensions, ranged from 0.0035 to 0.65 and from 6.5 to 60.0 for the heat-sensitive and the heat-resistant strains, respectively. Spores of these strains were divided into two distinct germination types on the basis of their germination response; spores of the heat-resistant strains germinated in KC1 medium after heat activation (K-type), and spores of the heat-sensitive strains germinated in a mixture of L-alanine, inosine, and CaCl2 in the presence of CO2 without heat activation (A-type). The strains were tested for enterotoxigenicity by a reversed passive latex-agglutination (RPLA) test. All the heat-resistant strains were RPLA-positive, whereas the heat-sensitive strains were all RPLA-negative. A total of 37 strains of the organism isolated from food-poisoning outbreaks were tested for spore germination and enterotoxin formation. All of the 20 heat-resistant strains showed K-type spore germination and, except for three strains, were RPLA-positive, whereas all of the 17 heat-sensitive strains showed A-type spore germination and, except for only one strain, were RPLA-negative.     

Enterotoxin formation by Clostridium perfringens type A in a defined medium

Enterotoxin was produced by 9 of 10 strains of Clostridium perfringens type A when grown in a defined medium. Additional dextrin increased the amount of enterotoxin in extracts of sporulating cells of strain NCTC 10239.     

Enterotoxin formation by Clostridium perfringens type A in a defined medium.

Enterotoxin was produced by 9 of 10 strains of Clostridium perfringens type A when grown in a defined medium. Additional dextrin increased the amount of enterotoxin in extracts of sporulating cells of strain NCTC 10239.     

Acid exposure enhances sporulation of certain strains of Clostridium perfringens

A gastroenteritis results when Clostridium perfringens is ingested in high numbers and sporulates releasing enterotoxin in the intestines. Since the organism must pass through the stomach, its ability to form spores may be affected by the acidic environment. Five strains of C. perfringens were exposed to acidic conditions and then assessed for survival and their ability to form spores. An acidic pH environment kills the bacteria over time but surviving cells are able to recover and form spores. Two of the five strains demonstrated enhanced sporulation following a 30-min exposure to a pH 2 environment. For four of the strains tested, enterotoxin concentrations were higher from acid-exposed cells than from untreated cells. Exposure to a pH 3.5 environment did not affect sporulation when compared to an untreated control. Bacteria in the stationary phase of growth were the most able to resist the acid and sporulate. The results indicate that some strains will produce more spores and enterotoxin following exposure to an acidic environment.