A new growth and in vitro sporulation medium for Clostridium perfringens

Growth and in vitro sporulation capabilities of three related Clostridium perfringens strains (NCTC 8798, 8-6 and R3) were followed in a new sporulation medium (NSM), with notable changes from a maintenance medium originally designed for strictly anaerobic bacteria. Compared with thioglycollate (FTG) medium, the new sporulation medium promoted growth of Cl. perfringens with a shorter lag phase and a 20% higher biomass production. The age of inoculum did not change Cl. perfringens growth kinetics. When compared with reference conditions, in vitro spore production kinetics were different in the new sporulation medium, but both conditions led routinely to 100% sporulation and spore counts of approximately 10(8) ml-1. The ease of preparation of the NSM, and the use of the same culture medium for good growth, high sporulation yields and spore production, represent an attractive alternative to the complex media routinely used for in vitro studies of Cl. perfringens physiology.     

Chemically Defined Medium for Growth and Sporulation of Clostridium perfringens

A chemically defined medium was developed that could support sporulation and growth of Clostridium perfringens strains ATCC 12916 and H9. This medium consisted of a modification of the basal medium of Boyd et al. plus 0.1% sodium thioglycolate and 0.5% monosodium glutamate. Five other strains grew, but did not sporulate, in this medium. With the addition of more vatamins into the medium, two more strains grew but did not sporulate. The effects of glucose, monosodium glutamate, ammonium glutamate, and sodium thioglycolate on growth and sporulation of C. perfringens ATCC 12916 in the defined medium was investigated.     

Characteristics of a sporulation stimulating factor from Clostridium perfringens type A

A product in the culture supernatant fluid of Clostridium perfringens NCTC 8239 stimulated the sporulation of a test strain, NCTC 8679, of the same organism. The responsible factor, termed sporulation factor (SF), was present in seven cultures of Cl. perfringens grown in either a defined or complex medium. The SF reversed glucose-mediated catabolite repression of sporulation by this organism. Preliminary characterization of the SF demonstrated a resistance to elevated temperatures and proteases and a molecular weight of less than 500 Da. The known association of Cl. perfringens enterotoxin with sporulation highlights the importance of interactions between strains of this organism as may occur in the human intestine during foodborne illness.     

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).     

Effect of purine derivatives, papaverine hydrochloride, and imidazole on enterotoxin formation by Clostridium perfringens type A

The percentage sporulation and enterotoxin specific activity were improved for all of five Clostridium perfringens strains, and numbers of heat-resistant spores were improved for four of five strains by replacing proteose peptone with peptone in Duncan-Strong (DS) medium. When raffinose replaced starch in DS, peptone was superior to proteose peptone in increasing percentage sporulation, numbers of heat-resistant spores, and enterotoxin formation for four of five strains. Enterotoxin levels for a strain varied when different lots of the same peptone were used. Additional experiments were conducted with three C. perfringens strains grown in DS medium with peptone. Enterotoxin specific activity was increased for three strains by adding papaverine (hydrochloride crystalline), for two strains by adding each of caffeine and 3-isobutyl-l-methylxanthine, for one strain by adding each of theophylline, 6-mercaptopurine, and 2-amino-6-mercaptopurine, and for none of the strains by adding imidazole. When enterotoxin formation was improved for a strain by one of the compounds, percentage sporulation increased, but growth decreased. Effective compounds also increased numbers of heat-resistant spores for strains H6 and R42, but slightly or not at all for strain E13. The action of these compounds was concentration dependent, with the optimal concentration differing between compounds and between strains grown in the presence of the same compound.     

Alternative medium for Clostridium perfringens sporulation.

A medium containing 0.50 g of thiotone peptone, 0.30 g of soluble starch, 0.02 g of MgSO4 X 7H2O, 0.90 g of Na2HPO4 X 2H2O, 100.00 ml of distilled water, and optionally , 166 micrograms of dichloridric thiamine supported sporulation of 138 out of 141 Clostridium perfringens strains. Comparatively this medium gave a greater percentage of sporulation than five other media described previously.     

Sporulation and enterotoxin production by Clostridium perfringens type A at 37 and 43 degrees C.

Enterotoxin-positive strains of Clostridium perfringens were grown in Duncan-Strong sporulation medium in the presence of 0.4% (7.9 mM) raffinose at 37 and 43 degrees C. Enterotoxin- and heat-resistant spores were produced at similar concentrations but sooner at 43 degrees C than at 37 degrees C. There was a direct relationship between spore heat resistance and sporulation temperature (32, 37, and 43 degrees C).     

Sporulation and enterotoxin production by Clostridium perfringens type A at 37 and 43 degrees C.

Enterotoxin-positive strains of Clostridium perfringens were grown in Duncan-Strong sporulation medium in the presence of 0.4% (7.9 mM) raffinose at 37 and 43 degrees C. Enterotoxin- and heat-resistant spores were produced at similar concentrations but sooner at 43 degrees C than at 37 degrees C. There was a direct relationship between spore heat resistance and sporulation temperature (32, 37, and 43 degrees C).     

Pathogenesis of Hobbs' heat-sensitive spore forming Clostridium perfringens type A strain.

Food poisoning in man due to heat-sensitive strains of Cl. perfringens type A appeared to be mediated through enterotoxin synthesized in vivo during sporulation. A minimum of 2.0 X 10(5) vegetative cells suspended in sporulation medium was sufficient to elicit gut-loop response in rabbits. The functional disturbance in the gut as well as the structural changes were progressive and proportional to the size of the inoculum up to a dose limit of 2.0 X 10(7) vegetative cells and beyond this the changes remained steady.     

Sporulation-promoting ability of Clostridium perfringens culture fluids.

The culture supernatant fluids (CSFs) of 12 strains of Clostridium perfringens types A, B, C, and D stimulated sporulation of test strains NCTC 8238 and NCTC 8449 of this organism. The sporulation-promoting ability was present in vegetative and sporulating CSFs of both enterotoxin-positive (Ent+) and Ent- strains. The sporulation factor possessed a molecular weight between 1,000 and 5,000 and was heat and acid stable. This study suggests a potential role for Ent- strains in food-borne disease outbreaks caused by Ent+ strains of C. perfringens type A.     

Nutritional Requirements for Growth and Sporulation of Clostridium perfringens

Two strains of Clostridium perfringens grew in a chemically defined medium consisting of L-tryptophan, L-arginine, L-glutamic acid, L-histidine HCl, L-leucine, DL-threonine, DL-phenylalanine, DL-tryrosine, DL-valine, L-cystine, ascorbic acid, Ca d -pantothenate, pyridoxine, biotin, adenine HCl, glucose, salts and mercaptoacetic acid. Alanine, aspartic acid and methionine were highly stimulatory but not essential for growth. Growth did not occur in the absence of glucose, but other fermentable carbohydrates were not tested. Acetone, isopropyl alcohol, succinic acid, acetic acid, butanol, butyric acid, lactic acid, pyruvic acid, oxaloacetic acid or acetaldehyde did not eliminate the requirement for glucose. Methionine was required for sporulation; one strain also required riboflavin, isoleucine, serine and lysine. Butanol increased the degree of sporulation in a complex thioglycolate medium. Failure of Cl. perfringens to sporulate in inadequately buffered media containing glucose was shown to be caused by the high H-ion concentration developing in the culture medium. In addition, some possible end-products of glucose metabolism such as lactic acid, oxaloacetic acid and acetaldehyde, reduced sporulation in one strain appreciably.     

Clostridium perfringens: I. Sporulation in a Biphasic Glucose-Ion-Exchange Resin Medium

A biphasic culture medium suitable for cultivation and sporulation of Clostridium perfringens, C. botulinum, and C. sporogenes was devised. The medium designed for use in a disposable, compartmented, plastic film container contained peptones, yeast extract, minerals, an anion exchange resin, and glucose in 4% agar as the solid phase and (NH(4))(2)SO(4) and 0.1% agar as the liquid phase. With the biphasic system, it was not necessary to use active cultures as inocula. Growth was at least equal to that obtained in conventional media, and spore production of 9 out of 12 strains of C. perfringens equalled or usually exceeded that of conventional media.     

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.     

Increased spore yields of Clostridium perfringens in the presence of methylxanthines.

The methylxanthines caffeine, theophylline, and isobutylmethylxanthine greatly increased spore yields of Clostridium perfringens strains FD-1, PS52, and PS49 when grown on Duncan-Strong medium or on a new casein-digest medium. Four other strains (KA3, and National Collection of Type Cultures strains 8798, 8238, and 10240) failed to show any significant increase when tested under similar conditions. The degree of sporulation increase was influenced by the carbohydrate energy source in some strains but not in others. Strain PS52 showed a large increase in spore yield when dextrin was the energy source but only a slight increase when raffinose served as the energy source. Strain FD-1 showed similar increases in spore yield with either dextrin or raffinose.     

Phospholipid fatty acid and lipopolysaccharide fatty acid signature lipids in methane-utilizing bacteria

The effect of human bile juice and bile salts (sodium cholate, sodium taurocholate, sodium glycochenodeoxycholate and sodium chenodeoxycholate) on growth, sporulation and enterotoxin production by enterotoxin-positive and enterotoxin-negative strains of Clostridium perfringens was determined. Each bile salt inhibited growth to a different degree. A mixture of bile salts completely inhibited the growth of enterotoxin-positive strains of this organism. Human bile juice completely inhibited the growth of all the strains at a dilution of 1:320. A distinct stimulatory effect of the bile salts on sporulation was observed in the case of C. perfringens strains NCTC 8239 and NCTC 8679. The salts also increased enterotoxin concentrations in the cell extracts of the enterotoxin-positive strains tested. No effect on enterotoxin production was detected when an enterotoxin-negative strain was examined.     

Increased spore yields of Clostridium perfringens in the presence of methylxanthines.

The methylxanthines caffeine, theophylline, and isobutylmethylxanthine greatly increased spore yields of Clostridium perfringens strains FD-1, PS52, and PS49 when grown on Duncan-Strong medium or on a new casein-digest medium. Four other strains (KA3, and National Collection of Type Cultures strains 8798, 8238, and 10240) failed to show any significant increase when tested under similar conditions. The degree of sporulation increase was influenced by the carbohydrate energy source in some strains but not in others. Strain PS52 showed a large increase in spore yield when dextrin was the energy source but only a slight increase when raffinose served as the energy source. Strain FD-1 showed similar increases in spore yield with either dextrin or raffinose.     

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.     

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.