Sensitization of Clostridium perfringens spores to heat by gamma radiation.

Spores of Clostridium perfringens, type A, were given separate or sequential treatments of gamma radiation (0 to 0.7 Mrad) and/or high temperature (93 to 103 degrees C). Prior heating, sufficient to inactivate 40 to 99% of the viable spores, had no effect on the subsequent radiation inactivation rate. Prior irradiation had a sensitizing effect on subsequently heated spores. The degree of sensitization to heat, as measured by thermal inactivation rate, increased with increased radiation pretreatment dose.     

Sensitization by ethylenediaminetetraacetate of Clostridium perfringens type A spores to germination by lysozyme

Clostridium perfringens spores (three strains) were normally resistant to germination by lysozyme. In the absence of disulfide bond-breaking reagents, tetrasodium ethylenediaminetetraacetate rapidly sensitized the spores to lysozyme.     

Reversal of radiation-dependent heat sensitization of Clostridium perfringens spores.

The effect of solute concentration on the sensitization of Clostridium perfringens spores to heat by ionizing radiation was investigated. As we have shown previously, spores of C. perfringens treated with gamma radiation are now sensitive to subsequent heat treatments than are spores that receive no radiation treatment. When gamma-irradiated spores were heated in the presence of increasing concentrations of glycerol or sucrose, the heat sensitivity induced by irradiation was progressively decreased. The magnitude of the increase in heat resistance induced by extracellular solutes was greater in gamma-irradiated spores than in nonirradiated spores. Based on these observations, it is proposed that the induction of heat sensitivity in spores by radiation is related to the loss of osmoregulatory or dehydrating mechanisms in irradiated spores.     

Reversal of radiation-dependent heat sensitization of Clostridium perfringens spores

The effect of solute concentration on the sensitization of Clostridium perfringens spores to heat by ionizing radiation was investigated. As we have shown previously, spores of C. perfringens treated with gamma radiation are now sensitive to subsequent heat treatments than are spores that receive no radiation treatment. When gamma-irradiated spores were heated in the presence of increasing concentrations of glycerol or sucrose, the heat sensitivity induced by irradiation was progressively decreased. The magnitude of the increase in heat resistance induced by extracellular solutes was greater in gamma-irradiated spores than in nonirradiated spores. Based on these observations, it is proposed that the induction of heat sensitivity in spores by radiation is related to the loss of osmoregulatory or dehydrating mechanisms in irradiated spores.     

Activation and injury of Clostridium perfringens spores by alcohols.

The activation properties of Clostridium perfringens NCTC 8679 spores were demonstrated by increases in CFU after heating in water or aqueous alcohols. The temperature range for maximum activation, which was 70 to 80 degrees C in water, was lowered by the addition of alcohols. The response at a given temperature was dependent on the time of exposure and the alcohol concentration. The monohydric alcohols and some, but not all, of the polyhydric alcohols could activate spores at 37 degrees C. The concentration of a monohydric alcohol that produced optimal spore activation was inversely related to its lipophilic character. Spore injury, which was manifested as a dependence on lysozyme for germination and colony formation, occurred under some conditions of alcohol treatment that exceeded those for optimal spore activation. Treatment with aqueous solutions of monohydric alcohols effectively activated C. perfringens spores and suggests a hydrophobic site for spore activation.     

Changes in the hydrophobic characteristics of Clostridium perfringens spores and spore coats by heat

The hydrophobic characteristics of Clostridium perfringens NCTC 8679 spores were demonstrated by adherence to toluene in a toluene-aqueous partition system. Spores and spore coat preparations were hydrophobic. Vegetative cells and spores extracted with a dithiothreitol-sodium dodecyl sulfate treatment known to remove spore coats were not hydrophobic. A heat activation treatment (75 degrees C for 20 min) which promotes more rapid spore germination increased the hydrophobicity of intact spores and decreased that of isolated spore coats. The hydrophobic changes were reversed by washing and stabilized by 0.5% glutaraldehyde. Heat-induced hydrophobic changes were observed in spore coats prepared from spores that were preheated and washed before rupturing in a buffer containing glutaraldehyde. These results suggest the occurrence of a heat-induced change in the spore coat (possibly in the conformation of a macromolecule) which was stable only within the architectural confines of the intact spore.     

Mechanism of chemical manipulation of the heat resistance of Clostridium perfringens spores

The mechanism(s) of chemical manipulation of the heat resistance of Clostridium perfringens type A spores was studied. Spores were converted to various ionic forms by base-exchange technique and these spores were heated at 95°C. Of the four ionic forms, i.e. Ca²⁺, Na⁺, H⁺ and native, only hydrogen spores appeared to have been rapidly inactivated at this temperature, when survivors were enumerated on the ordinary plating medium. However, the recovery of the survivors was improved when the plating medium was supplemented with lysozyme, and more dramatically when the heated spores were pretreated with alkali followed by plating in the medium containing lysozyme. In contrast to crucial damage to germination, in particular to spore lytic enzyme, no appreciable amount of DPA was released from the heat-damaged H-spores. These results suggest that a germination system is involved in the thermal inactivation of the ionic forms of spores, and that exchangeable cation load plays a role in protection from thermal damage of the germination system within the spore. An enhancement of thermal stability of spore lytic enzyme in the presence of a high concentration of NaCl was consistent with the hypothesis.     

Activation and injury of Clostridium perfringens spores by alcohols

The activation properties of Clostridium perfringens NCTC 8679 spores were demonstrated by increases in CFU after heating in water or aqueous alcohols. The temperature range for maximum activation, which was 70 to 80 degrees C in water, was lowered by the addition of alcohols. The response at a given temperature was dependent on the time of exposure and the alcohol concentration. The monohydric alcohols and some, but not all, of the polyhydric alcohols could activate spores at 37 degrees C. The concentration of a monohydric alcohol that produced optimal spore activation was inversely related to its lipophilic character. Spore injury, which was manifested as a dependence on lysozyme for germination and colony formation, occurred under some conditions of alcohol treatment that exceeded those for optimal spore activation. Treatment with aqueous solutions of monohydric alcohols effectively activated C. perfringens spores and suggests a hydrophobic site for spore activation.     

Extraction of Clostridium perfringens spores from bottom sediment samples.

Two extraction-separation procedures were developed and evaluated for use in conjunction with the mCP membrane filter method for the enumeration of Clostridium perfringens spores in bottom sediments. In the more facile of the two procedures, a distilled-water suspension of the sediment sample is pulse sonicated for 10 s and allowed to settle. Portions of the supernatant are then removed for membrane filtration. This procedure is recommended for general use. The more complicated procedure is recommended for situations in which the presence of high levels of toxic materials is suspected or in which relatively low spore densities are present in fine silts. In this procedure, sonication is followed by a distilled water wash. The centrifuged sediment is resuspended in distilled water and mixed with the components of a two-phase separation system (50% polyethylene glycol in distilled water and 25% sucrose in 3 M phosphate buffer [pH 7.1]). After equilibration of the system and low-speed centrifugation, the top phase and interphase are removed, mixed, and membrane filtered. The recoveries of C. perfringens spores by the two procedures, when used in conjunction with the mCP method, were comparable to each other and significantly greater than those by the British most-probable-number method. It was estimated that more than 85% of the spores were recovered by the procedures. The precision of the sonicate-and-settle-mCP procedure was markedly better than that obtained theoretically by the most-probable-number method and approached that theoretically attributable to counting an average of 85 colonies on each of two plates.     

Coat and enterotoxin-related proteins in Clostridium perfringens spores

Coat proteins from mature spores of two enterotoxin-positive (Ent+) and two enterotoxin-negative (Ent-) strains of Clostridium perfringens were solubilized using 50 mM-dithiothreitol and 1% sodium dodecyl sulphate at pH 9.7, and alkylated using 110 mM-iodoacetamide to prevent aggregation. The coat proteins and C. perfringens type A enterotoxin (CPE) were separated by SDS-PAGE and analysed by Western blotting using anti-CPE antibody. As previously reported, CPE aggregated in the presence of SDS, but no aggregation occurred at concentrations below 15 micrograms CPE ml-1. Two CPE-related proteins (34 and 48 kDa) were found in the solubilized spore coat protein of Ent+ strains while only the 48 kDa CPE-related protein was found in the spore coat fraction of Ent- strains. CPE-related proteins comprised 2.7% and 0.8% of the total solubilized coat protein of Ent+ and Ent- strains respectively. CPE-related proteins could be extracted from the spores with 1% SDS alone. They could also be released by disruption of whole spores, indicating that the CPE-related proteins may be in the spore core or trapped between the core and coat layers. The results suggest that CPE is not a major structural component of the coat fraction of C. perfringens spores.     

Spore lytic enzyme released from Clostridium perfringens spores during germination.

The exudate of fully germinated spores of Clostridium perfringens was found to contain a large amount of a spore lytic enzyme which acted directly on alkali-treated spores of the organism to cause germination. Although no detectable amount of the enzyme was found in dormant spores during germination in a KCl medium, the enzyme was produced rapidly and released into the medium. The optimal conditions for enzyme activity were pH 6.0 and 45 degrees C. Maximum activity occurred in the presence of various univalent cations at a concentration of 50 mM. The enzyme was readily inactivated by several sulfhydryl reagents. A strong reducing condition was generated in the ionic germination of the spores, a minimum Eh level of -350 mV being reached 30 min after initiation of germination. Furthermore, adenosine triphosphate-dependent pyruvate:ferredoxin oxidoreductase (EC 1.2.7.1) was identified in both dorman and germinated spores. The relationship between the release of active enzyme and the generation of reducing conditions during germination is discussed.     

Energy-dependent activation of spore-lytic enzyme precursor by germinated spores of Clostridium perfringens

A precursor of the spore-lytic enzyme of Clostridium perfringens was extracted with alkali from dormant spores of the organism. The enzyme precursor was activated by incubating it with germinated spores which had been treated with alkali. The activation was greatly enhanced by the addition of 3-phosphoglycerate, suggesting that the conversion of precursor to active enzyme depends on endogenous energy-producing metabolism during germination.     

Sensitivity of chemically treated spores of Clostridium perfringens type A to an initiation protein.

Extraction of Clostridium perfringens type A spores with dithiothreitol (DTT), DTT plus sodium dodecyl sulphate (DTT-SDS), urea-mercaptoethanol (UME), or alkali, solubilized from 18.6 to 46.5 of the total dry weight of spores. The initiation of germination and lysis of such treated spores with lysozyme and an initiation protein (IP) from the culture supernatant fluid of sporulating cells of C. perfringens was studied under various conditions. The ability of lysozyme and the crude IP to induce germination and lysis of extracted spores was concentration dependent up to 0.5 microgram/ml and 5.6 mg/ml respectively. IP showed an optimum of activity between pH 7 and 8 for DTT-SDS and DTT extracted spores, and between pH 6 and 9 for UME extracted spores. The optimum temperature of activity for IP was 55 degrees C. Dissimilarities in the extent to which lysozyme and the IP initiated germination and lysis of spores extracted by various methods may have been a reflection of the differences in amounts of protein solubilized by each treatment.     

Factors contributing to heat resistance of Clostridium perfringens endospores

The endospores formed by strains of type A Clostridium perfringens that produce the C. perfringens enterotoxin (CPE) are known to be more resistant to heat and cold than strains that do not produce this toxin. The high heat resistance of these spores allows them to survive the cooking process, leading to a large number of food-poisoning cases each year. The relative importance of factors contributing to the establishment of heat resistance in this species is currently unknown. The present study examines the spores formed by both CPE(+) and CPE(-) strains for factors known to affect heat resistance in other species. We have found that the concentrations of DPA and metal ions, the size of the spore core, and the protoplast-to-sporoplast ratio are determining factors affecting heat resistance in these strains. While the overall thickness of the spore peptidoglycan was found to be consistent in all strains, the relative amounts of cortex and germ cell wall peptidoglycan also appear to play a role in the heat resistance of these strains.     

Interactions between Clostridium perfringens spores and Raw 264.7 macrophages

Clostridium perfringens is the causative agent of a variety of histotoxic infections in humans and animals. Studies on the early events of C. perfringens infections have been largely focused on the interactions between their vegetative cells and macrophages. Consequently, in the current study we have examined the interactions between C. perfringens spores and Raw 264.7 macrophages. Raw 264.7 cells were able to interact and phagocytose Clostridium perfringens spores of a food poisoning isolate, strain SM101, and a non-food borne isolate, strain F4969, albeit to different extents. Phagocytosis and to a lesser extent, association, of C. perfringens spores by Raw 2647 macrophages was completely inhibited in presence of cytochalasin D. Complement increased association and phagocytosis of C. perfringens spores by Raw 264.7 macrophages. Survival of C. perfringens spores during macrophage infection seems to depend on the ability of spore germination during infection as: (i) F4969 spores germinated during infection with Raw 264.7 macrophages and subsequently killed by macrophages; and (ii) SM101 spores remained dormant inside Raw 264.7 macrophages and thus survived up to 24 h of infection. The in vitro spore-resistance factors, α/β-type SASP, SpmA/B proteins and spore's core water content, seems to play no role in mediating SM101 spore-resistance to macrophages. Collectively, these results might well have implications in understanding the initial stages of infections by C. perfringens spores.     

The effect of hydrogen peroxide on spores of Clostridium perfringens

Dithiothreitol (DTT)-treated spores of Clostridium perfringens were much more sensitive to lysis by H₂O₂ in the presence of Cu²⁺ than untreated spores. Lysis was greatly inhibited by hydroxyl radical (.OH) scavengers such as thiourea, dimethylthiourea and dimethylsulfoxide, suggesting that lysis of spores by H₂O₂ involves formation of OH by Cu²⁺-catalysed decomposition of the peroxide. DTT-treated spores took up Cu²⁺ at almost the same rate and extent as did isolated cortical fragments. Hydrogen peroxide caused both the decrease in optical density and the hexosamine solubilization of cortical fragments which bound Cu²⁺.     

Heterogeneity of enterotoxin-like protein extracted from spores fo Clostridium perfringens type A.

Enterotoxin-like protein was extracted from spores of three enterotoxin-positive and three enterotoxin-negative strains of Clostridium perfringens type A by urea/mercaptoethanol, alkaline mercaptoethanol and alkaline dithiothreitol. Disc immunoelectrophoresis demonstrated that three distinct enterotoxin-like proteins could be extracted. In 7% acrylamide gels, type I, type II, and type III enterotoxinlike proteins had relative mobilities of 0.52, 0.63, and 0.73 respectively. In contrast to disc immunoelectrophoresis, immunoelectrophoresis in agar gel demonstrated identical electrophoretic properties for the various entertoxin-like proteins. Immunoelectrofocusing experiments gave isoelectric points of 4.43, 4.43, 4.36, and 4.52 for purified entertoxin and type I, type II, and type III enterotoxin-like proteins respectively. Ferguson plots (i.e., log relative mobility versus acrylamide concentration) yielded nonparallel lines which intersected at a nonsieving concentration of acrylamide indicating that the various species of enterotoxin-like protein differed in size. Estimation of the molecular weight of purified enterotoxin and the three species of enterotoxin-like protein was done by comparing the slopes obtained in Ferguson plots with those obtained using proteins of a known molecular weight. Molecular weights of 38000, 36500, 23000, and 15400 were obtained for purified enterotoxin, type I, type II, and type III enterotoxin-like protein respectively. Collectively, the evidence indicates that fractionation of the different species of enterotoxin-like protein was due primarily to differences in their size, and that different forms of enterotoxin-like protein can be extracted from spores of different strains of C. perfringens type A.