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.     

Characterization of Clostridium perfringens spores that lack SpoVA proteins and dipicolinic acid

Spores of Clostridium perfringens possess high heat resistance, and when these spores germinate and return to active growth, they can cause gastrointestinal disease. Work with Bacillus subtilis has shown that the spore's dipicolinic acid (DPA) level can markedly influence both spore germination and resistance and that the proteins encoded by the spoVA operon are essential for DPA uptake by the developing spore during sporulation. We now find that proteins encoded by the spoVA operon are also essential for the uptake of Ca(2+) and DPA into the developing spore during C. perfringens sporulation. Spores of a spoVA mutant had little, if any, Ca(2+) and DPA, and their core water content was approximately twofold higher than that of wild-type spores. These DPA-less spores did not germinate spontaneously, as DPA-less B. subtilis spores do. Indeed, wild-type and spoVA C. perfringens spores germinated similarly with a mixture of l-asparagine and KCl (AK), KCl alone, or a 1:1 chelate of Ca(2+) and DPA (Ca-DPA). However, the viability of C. perfringens spoVA spores was 20-fold lower than the viability of wild-type spores. Decoated wild-type and spoVA spores exhibited little, if any, germination with AK, KCl, or exogenous Ca-DPA, and their colony-forming efficiency was 10(3)- to 10(4)-fold lower than that of intact spores. However, lysozyme treatment rescued these decoated spores. Although the levels of DNA-protective alpha/beta-type, small, acid-soluble spore proteins in spoVA spores were similar to those in wild-type spores, spoVA spores exhibited markedly lower resistance to moist heat, formaldehyde, HCl, hydrogen peroxide, nitrous acid, and UV radiation than wild-type spores did. In sum, these results suggest the following. (i) SpoVA proteins are essential for Ca-DPA uptake by developing spores during C. perfringens sporulation. (ii) SpoVA proteins and Ca-DPA release are not required for C. perfringens spore germination. (iii) A low spore core water content is essential for full resistance of C. perfringens spores to moist heat, UV radiation, and chemicals.     

Antisense-RNA-mediated decreased synthesis of small, acid-soluble spore proteins leads to decreased resistance of clostridium perfringens spores to moist heat and UV radiation

Previous work has suggested that a group of alpha/beta-type small, acid-soluble spore proteins (SASP) is involved in the resistance of Clostridium perfringens spores to moist heat. However, this suggestion is based on the analysis of C. perfringens spores lacking only one of the three genes encoding alpha/beta-type SASP in this organism. We have now used antisense RNA to decrease levels of alpha/beta-type SASP in C. perfringens spores by approximately 90%. These spores had significantly reduced resistance to both moist heat and UV radiation but not to dry heat. These results clearly demonstrate the important role of alpha/beta-type SASP in the resistance of C. perfringens spores.     

Requirement for and Sensitivity to Lysozyme by Clostridium perfringens Spores Heated at Ultrahigh Temperatures

The requirement of ultrahigh temperature (UHT)-treated Clostridium perfringens spores for lysozyme and the sensitivity of heated and unheated spores to lysozyme were studied. The UHT-treated spores requiring lysozyme for germination and colony formation originated from only a small portion of the non-UHT-treated spore population. This raised a question of whether the requirement for lysozyme was natural to the spores or was induced by the UHT treatments. However, these spores did not require lysozyme for germination before UHT treatment, which confirmed that the requirement for lysozyme had been induced by the UHT treatment. Only 1 to 2% of the spores were naturally sensitive to lysozyme; therefore, the mere addition of lysozyme to the plating medium did not permit the enumeration of all survivors. Treatment of UHT-treated spores with ethylenediaminetetraacetate (EDTA) sensitized the spores to lysozyme and increased by 10- to 100-fold the number of survivors that were detected on a medium containing lysozyme. Under the heating conditions used, spores that were naturally sensitive to lysozyme and spores that required EDTA treatment were equally heat resistant.     

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 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.     

Roles of DacB and spm proteins in clostridium perfringens spore resistance to moist heat, chemicals, and UV radiation

Clostridium perfringens food poisoning is caused mainly by enterotoxigenic type A isolates that typically possess high spore heat resistance. Previous studies have shown that alpha/beta-type small, acid-soluble proteins (SASP) play a major role in the resistance of Bacillus subtilis and C. perfringens spores to moist heat, UV radiation, and some chemicals. Additional major factors in B. subtilis spore resistance are the spore's core water content and cortex peptidoglycan (PG) structure, with the latter properties modulated by the spm and dacB gene products and the sporulation temperature. In the current work, we have shown that the spm and dacB genes are expressed only during C. perfringens sporulation and have examined the effects of spm and dacB mutations and sporulation temperature on spore core water content and spore resistance to moist heat, UV radiation, and a number of chemicals. The results of these analyses indicate that for C. perfringens SM101 (i) core water content and, probably, cortex PG structure have little if any role in spore resistance to UV and formaldehyde, presumably because these spores' DNA is saturated with alpha/beta-type SASP; (ii) spore resistance to moist heat and nitrous acid is determined to a large extent by core water content and, probably, cortex structure; (iii) core water content and cortex PG cross-linking play little or no role in spore resistance to hydrogen peroxide; (iv) spore core water content decreases with higher sporulation temperatures, resulting in spores that are more resistant to moist heat; and (v) factors in addition to SpmAB, DacB, and sporulation temperature play roles in determining spore core water content and thus, spore resistance to moist heat.     

Dying of Gamma-Irradiated Escherichia coli Studied by the Use of Prophage

Loss of the biological activity of deoxyribonucleic acid in gamma-irradiated Escherichia coli cells was studied. The study is based on two sets of experimental data: (i) post-irradiation heat inducibility of the cells whose chromosomes were "labeled" with the thermoinducible lambdacI857ind prophage, and (ii) post-irradiation capacity of nonlysogenic cells to promote growth of the unirradiated lambdacI857ind phage. The results show that, at the beginning of incubation after irradiation, the number of plaques formed upon heat induction of lysogenic cells was much higher than the viable cell count of the nonheated culture. This high resistance of the heat inducibility gradually decreased during post-irradiation incubation. Finally, after a period of 4 h, there was no difference in sensitivity between the heat inducibility and the colony-forming ability of gamma-irradiated cells. The capacity of gamma-irradiated bacteria to support growth of unirradiated lambdacI857ind is radioresistant; this resistance, in contrast to that of heat inducibility, is much less affected during post-irradiation incubation. A continuous decrease in radioresistance of heat inducibility without a corresponding decrease in radioresistance of the capacity suggests that functional failure of initially undamaged and/or repaired parts of the chromosome gradually develops after irradiation. From the fact that after 4 h all colony formers are capable of being induced by heat, whereas no chromosomal activity can be detected in nonviable cells, two conclusions may be drawn: (i) gamma-irradiated E. coli cells destined to die reach their biological end point within 4 h of post-irradiation incubation; (ii) in most cells, functional failure of the whole chromosome is the immediate cause of death.     

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.     

Comparative experiments to examine the effects of heating on vegetative cells and spores of Clostridium perfringens isolates carrying plasmid genes versus chromosomal enterotoxin genes

Clostridium perfringens enterotoxin (CPE) is an important virulence factor for both C. perfringens type A food poisoning and several non-food-borne human gastrointestinal diseases. Recent studies have indicated that C. perfringens isolates associated with food poisoning carry a chromosomal cpe gene, while non-food-borne human gastrointestinal disease isolates carry a plasmid cpe gene. However, no explanation has been provided for the strong associations between certain cpe genotypes and particular CPE-associated diseases. Since C. perfringens food poisoning usually involves cooked meat products, we hypothesized that chromosomal cpe isolates are so strongly associated with food poisoning because (i) they are more heat resistant than plasmid cpe isolates, (ii) heating induces loss of the cpe plasmid, or (iii) heating induces migration of the plasmid cpe gene to the chromosome. When we tested these hypotheses, vegetative cells of chromosomal cpe isolates were found to exhibit, on average approximately twofold-higher decimal reduction values (D values) at 55 degrees C than vegetative cells of plasmid cpe isolates exhibited. Furthermore, the spores of chromosomal cpe isolates had, on average, approximately 60-fold-higher D values at 100 degrees C than the spores of plasmid cpe isolates had. Southern hybridization and CPE Western blot analyses demonstrated that all survivors of heating retained their cpe gene in its original plasmid or chromosomal location and could still express CPE. These results suggest that chromosomal cpe isolates are strongly associated with food poisoning, at least in part, because their cells and spores possess a high degree of heat resistance, which should enhance their survival in incompletely cooked or inadequately warmed foods.     

Clostridium perfringens spore germination: characterization of germinants and their receptors

Clostridium perfringens food poisoning is caused by type A isolates carrying a chromosomal enterotoxin (cpe) gene (C-cpe), while C. perfringens-associated non-food-borne gastrointestinal (GI) diseases are caused by isolates carrying a plasmid-borne cpe gene (P-cpe). C. perfringens spores are thought to be the important infectious cell morphotype, and after inoculation into a suitable host, these spores must germinate and return to active growth to cause GI disease. We have found differences in the germination of spores of C-cpe and P-cpe isolates in that (i) while a mixture of L-asparagine and KCl was a good germinant for spores of C-cpe and P-cpe isolates, KCl and, to a lesser extent, L-asparagine triggered spore germination in C-cpe isolates only; and (ii) L-alanine or L-valine induced significant germination of spores of P-cpe but not C-cpe isolates. Spores of a gerK mutant of a C-cpe isolate in which two of the proteins of a spore nutrient germinant receptor were absent germinated slower than wild-type spores with KCl, did not germinate with L-asparagine, and germinated poorly compared to wild-type spores with the nonnutrient germinants dodecylamine and a 1:1 chelate of Ca2+ and dipicolinic acid. In contrast, spores of a gerAA mutant of a C-cpe isolate that lacked another component of a nutrient germinant receptor germinated at the same rate as that of wild-type spores with high concentrations of KCl, although they germinated slightly slower with a lower KCl concentration, suggesting an auxiliary role for GerAA in C. perfringens spore germination. In sum, this study identified nutrient germinants for spores of both C-cpe and P-cpe isolates of C. perfringens and provided evidence that proteins encoded by the gerK operon are required for both nutrient-induced and non-nutrient-induced spore germination.     

Clostridium perfringens type A: certain characters of epidemiologic significance.

Survival of spores of Cl. perfringens type A was significantly greater than that of vegetative cells in acid pH (pH 1.2). Survival of spores in soil varied from strain to strain. Time required for 5 million spores to be reduced to 500 per gram of soil varied from 2 to 8 months with an average of 4.5+/-2.3 months. Quantitative and qualitative heat resistance studies revealed that a majority of the Indian and all the American strains tested were heat-sensitive. These characters of Cl. perfringens have an important bearing on the epidemiology of food poisoning due to this agent.     

Biochemical differentiation between enterotoxigenic heat-sensitive and heat-resistant Clostridium perfringens strains

Some biochemical characteristics of 37 enterotoxigenic Clostridium perfringens strains isolated from human feces, ground beef, and soil samples by heat-selection methods and of two NCTC strains were studied. Two different biochemical patterns closely related to the heat resistance of the strains were found. The strains placed into group 1 were trehalose, inositol, and sorbitol negative and synthesized heat-resistant spores, while those placed into group 2 were trehalose and inositol positive and synthesized heat-sensitive spores. Sorbitol fermentation was variable among the strains of this last group. The strains of group 1 were more cellobiose, melibiose, and salicin fermentative than those of group 2. Only the strains placed into group 2 synthesized toxins of sufficient levels for typing. In spite of having been isolated by mild heat treatment of the specimens, two strains showed the same biochemical and toxigenic characteristics of the strains of group 1. The heating of these two strains did not modify their characteristics. We conclude that enterotoxigenic C. perfringens strains showing the two different toxigenic and biochemical patterns are present in the human gut, ground beef, and, probably, in soil. These strains may be differentiated on the basis of their capacity to produce acid from trehalose, inositol, and sorbitol, heat resistance of the spores and grade of toxigenicity. The heat-selection methods used for isolation of C. perfringens strains from different sources exerted a selection of strains from one or another group, but had no influence on their toxigenic and biochemical properties.     

Germination response of spores of the pathogenic bacterium Clostridium perfringens and Clostridium difficile to cultured human epithelial cells

Spores of pathogenic Clostridium perfringens and Clostridium difficile must germinate in the food vehicle and/or host's intestinal tract to cause disease. In this work, we examined the germination response of spores of C. perfringens and C. difficile upon incubation with cultured human epithelial cell lines (Caco-2, HeLa and HT-29). C. perfringens spores of various sources were able to germinate to different extents; while spores of a non-food-borne isolate germinated very well, spores of food-borne and animal isolates germinated poorly in human epithelial cells. In contrast, no detectable spore germination (i.e., loss of spore heat resistance) was observed upon incubation of C. difficile spores with epithelial cells; instead, there was a significant (p?相似文献   

Inactivation of Cryptosporidium parvum oocysts and Clostridium perfringens spores by a mixed-oxidant disinfectant and by free chlorine.

Cryptosporidium parvum oocysts and Clostridium perfringens spores are very resistant to chlorine and other drinking-water disinfectants. Clostridium perfringens spores have been suggested as a surrogate indicator of disinfectant activity against Cryptosporidium parvum and other hardy pathogens in water. In this study, an alternative disinfectant system consisting of an electrochemically produced mixed-oxidant solution (MIOX; LATA Inc.) was evaluated for inactivation of both Cryptosporidium parvum oocysts and Clostridium perfringens spores. The disinfection efficacy of the mixed-oxidant solution was compared to that of free chlorine on the basis of equal weight per volume concentrations of total oxidants. Batch inactivation experiments were done on purified oocysts and spores in buffered, oxidant demand-free water at pH 7 an 25 degrees C by using a disinfectant dose of 5 mg/liter and contact times of up to 24 h. The mixed-oxidant solution was considerably more effective than free chlorine in activating both microorganisms. A 5-mg/liter dose of mixed oxidants produced a > 3-log10-unit (> 99.9%) inactivation of Cryptosporidium parvum oocysts and Clostridium perfringens spores in 4 h. Free chlorine produce no measurable inactivation of Cryptosporidium parvum oocysts by 4 or 24 h, although Clostridium perfringens spores were inactivated by 1.4 log10 units after 4 h. The on-site generation of mixed oxidants may be a practical and cost-effective system of drinking water disinfection protecting against even the most resistant pathogens, including Cryptosporidium oocysts.     

Resistance of Bacillus Spores to Combined Sporicidal Treatments

S ummary . Moist heat at 82° (100° for Bacillus stearothermophilus ) and solutions of 0.2% w/v chlorocresol or 0.01% w/v benzalkonium chloride at 24° separately showed no sporicidal activity against B. pumilis, B. stearothermophilus, B. subtilis and B. subtilis var. niger . Spores of the last organism were the most sensitive to γ radiation, the D value being 0.16 Mrad. Prior irradiation with a dose of 0.16 Mrad brought about only a slight increase in the sensitivity of the spores to moist heat. The presence of bactericide during irradiation did not affect radiation resistance. Inactivation rates were greater when the spores were heated in the presence of a bactericide than in aqueous suspension and benzalkonium chloride was more active than chlorocresol. Chlorocresol enhanced the heat activation of B. stearothermophilus at 100°. Irradiation in the presence of 0.2% w/v chlorocresol or 0.01% w/v benzalkonium chloride had no effect on the subsequent resistance of the spores when heated in the presence of these bactericides. It is concluded that it is unlikely that combinations of moist heat, radiation and bactericides, each less severe than when used in an accepted sterilization process, will lead to an alternative process which, while less damaging to the materials being sterilized, would still maintain the accepted standards of freedom from contamination.     

Spores of microorganisms

The addition of different cysteine or thioproline concentrations (1–5×10^?4M) to the culture at the outset of the formation ofBacillus cereus prespores, i.e. before the commencement of dipicolinic acid synthesis, led to the death of some of the cells and injured the thermoprotection mechanism of the surviving spores. In control spores with a high dipicolinic acid content, inactivation by heating at 85°C was preceded by a lag phase, while in cysteine- and thioproline-treated spores this lag phase was completely absent and the death rate of most of the spores (D-value=17) was actually higher than the final death rate of the control spores (D-value=33). A small proportion of the spores in inhibited cultures (less than 10%) displayed almost the same heat resistance as untreated spores. The heat sensitivity of treated spores was greater than might have been anticipated from their dipicolinic acid content. Their resistance to X-rays was not lowered, but was actually slightly raised. The results are discussed with reference to the differentiation of a possible “basal” and “additional” spore thermoprotection mechanism and to differentiation of the nature of heat and radiation resistance in bacterial spores.     

Effect of a small, acid-soluble spore protein from Clostridium perfringens on the resistance properties of Bacillus subtilis spores

Alpha/beta-type small, acid-soluble spore proteins (SASP) are essential for the resistance of DNA in spores of Bacillus species to damage. An alpha/beta-type SASP, Ssp2, from Clostridium perfringens was expressed at significant levels in B. subtilis spores lacking one or both major alpha/beta-type SASP (alpha- and alpha- beta- strains, respectively). Ssp2 restored some of the resistance of alpha- beta- spores to UV and nitrous acid and of alpha- spores to dry heat. Ssp2 also restored much of the resistance of alpha- spores to nitrous acid and restored full resistance of alpha- spores to UV and moist heat. These results further indicate the interchangeability of alpha/beta-type SASP in DNA protection in spores.     

A novel small acid soluble protein variant is important for spore resistance of most Clostridium perfringens food poisoning isolates

Clostridium perfringens is a major cause of food poisoning (FP) in developed countries. C. perfringens isolates usually induce the gastrointestinal symptoms of this FP by producing an enterotoxin that is encoded by a chromosomal (cpe) gene. Those typical FP strains also produce spores that are extremely resistant to food preservation approaches such as heating and chemical preservatives. This resistance favors their survival and subsequent germination in improperly cooked, prepared, or stored foods. The current study identified a novel alpha/beta-type small acid soluble protein, now named Ssp4, and showed that sporulating cultures of FP isolates producing resistant spores consistently express a variant Ssp4 with an Asp substitution at residue 36. In contrast, Gly was detected at Ssp4 residue 36 in C. perfringens strains producing sensitive spores. Studies with isogenic mutants and complementing strains demonstrated the importance of the Asp 36 Ssp4 variant for the exceptional heat and sodium nitrite resistance of spores made by most FP strains carrying a chromosomal cpe gene. Electrophoretic mobility shift assays and DNA binding studies showed that Ssp4 variants with an Asp at residue 36 bind more efficiently and tightly to DNA than do Ssp4 variants with Gly at residue 36. Besides suggesting one possible mechanistic explanation for the highly resistant spore phenotype of most FP strains carrying a chromosomal cpe gene, these findings may facilitate eventual development of targeted strategies to increase killing of the resistant spores in foods. They also provide the first indication that SASP variants can be important contributors to intra-species (and perhaps inter-species) variations in bacterial spore resistance phenotypes. Finally, Ssp4 may contribute to spore resistance properties throughout the genus Clostridium since ssp4 genes also exist in the genomes of other clostridial 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.