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°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°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.     

Comparative Effects of Osmotic, Sodium Nitrite-Induced, and pH-Induced Stress on Growth and Survival of Clostridium perfringens Type A Isolates Carrying Chromosomal or Plasmid-Borne Enterotoxin Genes

About 1 to 2% of Clostridium perfringens isolates carry the enterotoxin gene (cpe) necessary for causing C. perfringens type A food poisoning. While the cpe gene can be either chromosomal or plasmid borne, food poisoning isolates usually carry a chromosomal cpe gene. Previous studies have linked this association between chromosomal cpe isolates (i.e., C-cpe isolates) and food poisoning, at least in part, to both the spores and vegetative cells of C-cpe isolates being particularly resistant to high and low temperatures. The current study now reveals that the resistance phenotype of C-cpe isolates extends beyond temperature resistance to also include, for both vegetative cells and spores, enhanced resistance to osmotic stress (from NaCl) and nitrites. However, by omitting one outlier isolate, no significant differences in pH sensitivity were detected between the spores or vegetative cells of C-cpe isolates versus isolates carrying a plasmid-borne cpe gene. These results indicate that both vegetative cells and spores of C-cpe isolates are unusually resistant to several food preservation approaches in addition to temperature extremes. The broad-spectrum nature of the C-cpe resistance phenotype suggests these bacteria may employ multiple mechanisms to persist and grow in foods prior to their transmission to humans.     

Prevalence and Characterization of Enterotoxin Gene-Carrying Clostridium perfringens Isolates from Retail Meat Products in Japan

Clostridium perfringens is an important anaerobic pathogen causing food-borne gastrointestinal (GI) diseases in humans and animals. It is thought that C. perfringens food poisoning isolates typically carry the enterotoxin gene (cpe) on their chromosome, while isolates from other GI diseases, such as antibiotic-associated diarrhea, carry cpe on a transferable plasmid. However, food-borne GI disease outbreaks associated with C. perfringens isolates carrying plasmid-borne cpe (plasmid cpe isolates) were recently reported in Japan and Europe. To investigate whether retail food can be a reservoir for food poisoning generally, we evaluated Japanese retail meat products for the presence of two genotypes of enterotoxigenic C. perfringens. Our results demonstrated that approximately 70% of the Japanese retail raw meat samples tested were contaminated with low numbers of C. perfringens bacteria and 4% were contaminated with cpe-positive C. perfringens. Most of the cpe-positive C. perfringens isolates obtained from Japanese retail meat carried cpe on a plasmid. The plasmid cpe isolates exhibited lower spore heat resistance than did chromosomal cpe isolates. Collectively, these plasmid cpe isolates might be causative agents of food poisoning when foods are contaminated with these isolates from equipment and/or the environment after cooking, or they may survive in food that has not been cooked at a high enough temperature.     

Further comparison of temperature effects on growth and survival of Clostridium perfringens type A isolates carrying a chromosomal or plasmid-borne enterotoxin gene

Clostridium perfringens type A isolates can carry the enterotoxin gene (cpe) on either their chromosome or a plasmid, but food poisoning isolates usually have a chromosomal cpe gene. This linkage between chromosomal cpe isolates and food poisoning has previously been attributed, at least in part, to better high-temperature survival of chromosomal cpe isolates than of plasmid cpe isolates. In the current study we assessed whether vegetative cells and spores of chromosomal cpe isolates also survive better than vegetative cells and spores of plasmid cpe isolates survive when the vegetative cells and spores are subjected to low temperatures. Vegetative cells of chromosomal cpe isolates exhibited about eightfold-higher decimal reduction values (D values) at 4 degrees C and threefold-higher D values at -20 degrees C than vegetative cells of plasmid cpe isolates exhibited. After 6 months of incubation at 4 degrees C and -20 degrees C, the average log reductions in viability for spores of plasmid cpe isolates were about fourfold and about threefold greater, respectively, than the average log reductions in viability for spores from chromosomal cpe isolates. C. perfringens type A isolates carrying a chromosomal cpe gene also grew significantly faster than plasmid cpe isolates grew at 25 degrees C, 37 degrees C, or 43 degrees C. In addition, chromosomal cpe isolates grew at higher maximum and lower minimum temperatures than plasmid cpe isolates grew. Collectively, these results suggest that chromosomal cpe isolates are commonly involved in food poisoning because of their greater resistance to low (as well as high) temperatures for both survival and growth. They also indicate the importance of proper low-temperature storage conditions, as well as heating, for prevention of C. perfringens type A food poisoning.     

Genetic Characterization of Type A Enterotoxigenic Clostridium perfringens Strains

Clostridium perfringens type A, is both a ubiquitous environmental bacterium and a major cause of human gastrointestinal disease, which usually involves strains producing C. perfringens enterotoxin (CPE). The gene (cpe) encoding this toxin can be carried on the chromosome or a large plasmid. Interestingly, strains carrying cpe on the chromosome and strains carrying cpe on a plasmid often exhibit different biological characteristics, such as resistance properties against heat. In this study, we investigated the genetic properties of C. perfringens by PCR-surveying 21 housekeeping genes and genes on representative plasmids and then confirmed those results by Southern blot assay (SB) of five genes. Furthermore, sequencing analysis of eight housekeeping genes and multilocus sequence typing (MLST) analysis were also performed. Fifty-eight C. perfringens strains were examined, including isolates from: food poisoning cases, human gastrointestinal disease cases, foods in Japan or the USA, or feces of healthy humans. In the PCR survey, eight of eleven housekeeping genes amplified positive reactions in all strains tested. However, by PCR survey and SB assay, one representative virulence gene, pfoA, was not detected in any strains carrying cpe on the chromosome. Genes involved in conjugative transfer of the cpe plasmid were also absent from almost all chromosomal cpe strains. MLST showed that, regardless of their geographic origin, date of isolation, or isolation source, chromosomal cpe isolates, i) assemble into one definitive cluster ii) lack pfoA and iii) lack a plasmid related to the cpe plasmid. Similarly, independent of their origin, strains carrying a cpe plasmid also appear to be related, but are more variable than chromosomal cpe strains, possibly because of the instability of cpe-borne plasmid(s) and/or the conjugative transfer of cpe-plasmid(s) into unrelated C. perfringens strains.     

Further Characterization of Clostridium perfringens Small Acid Soluble Protein-4 (Ssp4) Properties and Expression

Background

Clostridium perfringens type A food poisoning (FP) is usually caused by C. perfringens type A strains that carry a chromosomal enterotoxin gene (cpe) and produce spores with exceptional resistance against heat and nitrites. Previous studies showed that the extreme resistance of spores made by most FP strains is mediated, in large part, by a variant of small acid soluble protein 4 (Ssp4) that has Asp at residue 36; in contrast, the sensitive spores made by other C. perfringens type A isolates contain an Ssp4 variant with Gly at residue 36.

Methodology/Principal Findings

The current study has further characterized Ssp4 properties and expression. Spores made by cpe-positive type C and D strains were found to contain the Ssp4 variant with Gly at residue 36 and were shown to be heat- and nitrite-sensitive; this finding may help to explain why cpe-positive type C and D isolates rarely cause food poisoning. Saturation mutagenesis indicated that both amino acid size and charge at Ssp4 residue 36 are important for DNA binding and for spore resistance. C. perfringens Ssp2 was shown to bind preferentially to GC-rich DNA on gel-shift assays, while Ssp4 preferred binding to AT-rich DNA sequences. Maximal spore heat and nitrite resistance required production of all four C. perfringens Ssps, indicating that these Ssps act cooperatively to protect the spore''s DNA, perhaps by binding to different chromosomal sequences. The Ssp4 variant with Asp at residue 36 was also shown to facilitate exceptional spore survival at freezer and refrigerator temperatures. Finally, Ssp4 expression was shown to be dependent upon Spo0A, a master regulator.

Conclusions/Significance

Collectively, these results provide additional support for the importance of Ssps, particularly the Ssp4 variant with Asp at residue 36, for the extreme spore resistance phenotype that likely contributes to C. perfringens type A food poisoning transmission.     

Comparative Genomic Hybridization Analysis Shows Different Epidemiology of Chromosomal and Plasmid-Borne cpe-Carrying Clostridium perfringens Type A

Clostridium perfringens, one of the most common causes of food poisonings, can carry the enterotoxin gene, cpe, in its chromosome or on a plasmid. C. perfringens food poisonings are more frequently caused by the chromosomal cpe-carrying strains, while the plasmid-borne cpe-positive genotypes are more commonly found in the human feces and environmental samples. Different tolerance to food processing conditions by the plasmid-borne and chromosomal cpe-carrying strains has been reported, but the reservoirs and contamination routes of enterotoxin-producing C. perfringens remain unknown. A comparative genomic hybridization (CGH) analysis with a DNA microarray based on three C. perfringens type A genomes was conducted to shed light on the epidemiology of C. perfringens food poisonings caused by plasmid-borne and chromosomal cpe-carrying strains by comparing chromosomal and plasmid-borne cpe-positive and cpe-negative C. perfringens isolates from human, animal, environmental, and food samples. The chromosomal and plasmid-borne cpe-positive C. perfringens genotypes formed two distinct clusters. Variable genes were involved with myo-inositol, ethanolamine and cellobiose metabolism, suggesting a new epidemiological model for C. perfringens food poisonings. The CGH results were complemented with growth studies, which demonstrated different myo-inositol, ethanolamine, and cellobiose metabolism between the chromosomal and plasmid-borne cpe-carrying strains. These findings support a ubiquitous occurrence of the plasmid-borne cpe-positive strains and their adaptation to the mammalian intestine, whereas the chromosomal cpe-positive strains appear to have a narrow niche in environments containing degrading plant material. Thus the epidemiology of the food poisonings caused by two populations appears different, the plasmid-borne cpe-positive strains probably contaminating foods via humans and the chromosomal strains being connected to plant material.     

Inorganic Phosphate and Sodium Ions Are Cogerminants for Spores of Clostridium perfringens Type A Food Poisoning-Related Isolates

Clostridium perfringens type A isolates carrying a chromosomal copy of the enterotoxin (cpe) gene are involved in the majority of food poisoning (FP) outbreaks, while type A isolates carrying a plasmid-borne cpe gene are involved in C. perfringens-associated non-food-borne (NFB) gastrointestinal diseases. To cause diseases, C. perfringens spores must germinate and return to active growth. Previously, we showed that only spores of FP isolates were able to germinate with K⁺ ions. We now found that the spores of the majority of FP isolates, but none of the NFB isolates, germinated with the cogerminants Na⁺ and inorganic phosphate (NaP_i) at a pH of ∼6.0. Spores of gerKA-KC and gerAA mutants germinated to a lesser extent and released less dipicolinic acid (DPA) than did wild-type spores with NaP_i. Although gerKB spores germinated to a similar extent as wild-type spores with NaP_i, their rate of germination was lower. Similarly, gerO and gerO gerQ mutant spores germinated slower and released less DPA than did wild-type spores with NaP_i. In contrast, gerQ spores germinated to a slightly lesser extent than wild-type spores but released all of their DPA during NaP_i germination. In sum, this study identified NaP_i as a novel nutrient germinant for spores of most FP isolates and provided evidence that proteins encoded by the gerKA-KC operon, gerAA, and gerO are required for NaP_i-induced spore germination.Clostridium perfringens is a gram-positive, anaerobic, spore-forming, pathogenic bacterium that causes a wide array of gastrointestinal (GI) diseases in both animals and humans (14, 15). However, Clostridium perfringens type A food poisoning (FP) is the most common C. perfringens-associated illness among humans and is currently ranked as the third most commonly reported food-borne disease (14). Mostly type A isolates that produce the C. perfringens enterotoxin have been associated with C. perfringens-related GI illnesses (14). C. perfringens cpe-positive isolates can carry the cpe gene on either the chromosome or a plasmid (3, 4). Interestingly, the majority of C. perfringens type A FP isolates carry a chromosomal copy of the cpe gene, while all non-food-borne (NFB) GI disease isolates carry a plasmid copy of cpe (3, 4, 11, 29). The genetic differences involved in the pathogenesis differences between C. perfringens FP and NFB isolates seem to involve more factors than the simple location of the cpe gene. For example, spores of FP isolates are strikingly more resistant than spores of NFB isolates to heat (100°C) (27), cold (4°C), and freezing (−20°C) temperatures (12) and to chemicals used in food industry settings (13), making FP spores more suited for FP environments. Under favorable environmental conditions, these dormant spores germinate to return to active growth, proliferate to high numbers, and then produce toxins to cause disease (14).Bacterial spores germinate when they sense the presence of nutrients (termed germinants) in the environment through their cognate receptors located in the spore inner membrane (18). For C. perfringens, some nutrients that initiate germination include l-asparagine, KCl, a mixture of l-asparagine and KCl, and a 1:1 chelate of Ca²⁺ and dipicolinic acid (DPA) (Ca-DPA) (20). The main receptor(s) involved in sensing these compounds is the GerKA and/or GerKC receptor(s), which is required for l-asparagine and Ca-DPA and only partially required for KCl and an l-asparagine-KCl mixture (20, 21). Upon binding of the germinant to its cognate receptor, a variety of biophysical events take place, including the release of monovalent ions (i.e., Na⁺, K⁺, and Li⁺) followed by the release of the spore''s large depot of Ca-DPA (28). In Bacillus subtilis, release of Ca-DPA acts as a signal for activation of the cortex-lytic enzyme CwlJ (17). In contrast, Ca-DPA release from the spore core has no role in triggering cortex hydrolysis during C. perfringens spore germination (19, 22, 23); instead, Ca-DPA induces germination via the GerKA and/or GerKC receptor(s) (20, 21). Degradation of the cortex in both species leads to hydration of the spore core up to levels found in growing bacteria, allowing resumption of enzymatic activity and metabolism, and consequently outgrowth (22, 28).The ability of bacterial spores to sense different nutrients appears to be tightly regulated by their adaptation to different environmental niches. For example, spores of FP isolates, but not NFB isolates, are capable of germinating with KCl (20), an intrinsic mineral of meats that are most commonly associated with FP, suggesting an adaptation of FP isolates to FP environments. In addition, the level of inorganic phosphate (P_i) is also significant in meat products (42 to 60 mM) (USDA [http://fnic.nal.usda.gov/nal_display/index.php?info_center=4&tax_level=1&tax_subject=242]). Similarly, sodium ions are also present in meats (∼30 mM), especially in processed meat products (∼300 to 400 mM) (USDA). Consequently, in this study we found that Na⁺ and P_i at ∼100 mM and pH 6.0 are unique cogerminants for spores of C. perfringens type A FP isolates, act through the GerKA and/or GerKC and GerAA receptors, and also require the presence of the putative Na⁺/K⁺-H⁺ antiporter, GerO, for normal germination.     

Organization of the cpe Locus in CPE-Positive Clostridium perfringens Type C and D Isolates

Clostridium perfringens enterotoxin (encoded by the cpe gene) contributes to several important human, and possibly veterinary, enteric diseases. The current study investigated whether cpe locus organization in type C or D isolates resembles one of the three (one chromosomal and two plasmid-borne) cpe loci commonly found amongst type A isolates. Multiplex PCR assays capable of detecting sequences in those type A cpe loci failed to amplify products from cpe-positive type C and D isolates, indicating these isolates possess different cpe locus arrangements. Therefore, restriction fragments containing the cpe gene were cloned and sequenced from two type C isolates and one type D isolate. The obtained cpe locus sequences were then used to construct an overlapping PCR assay to assess cpe locus diversity amongst other cpe-positive type C and D isolates. All seven surveyed cpe-positive type C isolates had a plasmid-borne cpe locus partially resembling the cpe locus of type A isolates carrying a chromosomal cpe gene. In contrast, all eight type D isolates shared the same plasmid-borne cpe locus, which differed substantially from the cpe locus present in other C. perfringens by containing two copies of an ORF with 67% identity to a transposase gene (COG4644) found in Tn1546, but not previously associated with the cpe gene. These results identify greater diversity amongst cpe locus organization than previously appreciated, providing new insights into cpe locus evolution. Finally, evidence for cpe gene mobilization was found for both type C and D isolates, which could explain their cpe plasmid diversity.     

Survival of Clostridium perfringens During Baking and Holding of Turkey Stuffing

Vegetative cells of three strains of Clostridium perfringens were used as inoculum for bread and onion stuffing for eight lightweight and eight heavyweight turkeys. When stuffed turkeys were refrigerated (5 ± 1 C for 24 ± 2 hr), a mean count of 580 vegetative cells of C. perfringens per gram of stuffing was reduced to undetectable levels (<6 per gram) in six of the eight. An inoculum of spores of the three strains used in a second series survived refrigerated holding with no change in numbers. During cooking of the stuffed turkeys in an oven at 94 C, numbers of vegetative cells fell steadily and numbers of spores remained constant or increased slightly (2 of 16 stuffings), until the temperature of the stuffing rose above that permitting growth. Viable C. perfringens cells were recovered from the stuffings at the end of cooking plus 1 hr for the group inoculated with the spore suspension. Storage of these stuffings resulted in marked reductions in numbers after 6 days at 5 ± 1 C and in increases after 24 ± 2 hr at 23 ± 1 C. Cells of a strain which produces spores not considered heat-resistant survived in stuffing in birds cooked to doneness in ovens at 94, 163, and 232 C. In accepted methods of cooking stuffed turkeys, C. perfringens contaminants may survive and create a hazard if subsequent storage is in a temperature range which permits their multiplication.     

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.     

Enterotoxigenicity and Genetic Relatedness of Clostridium perfringens Isolates from Retail Foods in the United States

Clostridium perfringens is a leading cause of bacterial food-borne illness in countries where consumption of meat and poultry is high. For example, each year in the United States, this organism is the second or third most common cause of confirmed cases of food-borne illness. Surveys of the incidence of this organism in retail foods were done in the 1960s without regard to whether isolates were enterotoxigenic. It is now known that not all strains of this organism possess the enterotoxin gene responsible for illness. We examined the incidence of this organism in 131 food samples from retail food stores in an area of the northeastern United States. Forty isolates were obtained by using the iron milk method at 45°C, with confirmation by use of motility nitrate and lactose gelatin media. The presence of the C. perfringens enterotoxin (cpe) and alpha toxin (cpa) genes was determined by PCR using previously published primer sequences. All isolates possessed cpa. None of the isolates were identified as carrying the cpe gene by this method or by another method using a digoxigenin-labeled gene probe. Consistent with these results, none of the sporulating-cell extracts contained enterotoxin as determined by reverse passive latex hemagglutination. Pulsed-field gel electrophoresis was used to determine the genetic relatedness of the isolates. About 5% of the isolates were considered to be closely related (2- to 3-band difference). The others were considered to be unrelated to one another. The results demonstrate the rarity of cpe⁺ strains in retail foods and the genetic diversity among nonoutbreak strains.     

Comparison of the Levels of Heat Resistance of Wild-Type, cpe Knockout, and cpe Plasmid-Cured Clostridium perfringens Type A Strains

An enterotoxin (cpe) plasmid was cured from a Clostridium perfringens non-food-borne gastrointestinal disease (NFBGID) isolate, and the heat resistance levels of wild-type, cpe knockout, and cpe plasmid-cured strains were compared. Our results demonstrated that (i) wild-type cpe has no influence in mediating high-level heat resistance in C. perfringens and (ii) the cpe plasmid does not confer heat sensitivity on NFBGID isolates.     

Toxigenic Strains of Bacillus licheniformis Related to Food Poisoning

Toxin-producing isolates of Bacillus licheniformis were obtained from foods involved in food poisoning incidents, from raw milk, and from industrially produced baby food. The toxin detection method, based on the inhibition of boar spermatozoan motility, has been shown previously to be a sensitive assay for the emetic toxin of Bacillus cereus, cereulide. Cell extracts of the toxigenic B. licheniformis isolates inhibited sperm motility, damaged cell membrane integrity, depleted cellular ATP, and swelled the acrosome, but no mitochondrial damage was observed. The responsible agent from the B. licheniformis isolates was partially purified. It showed physicochemical properties similar to those of cereulide, despite having very different biological activity. The toxic agent was nonproteinaceous; soluble in 50 and 100% methanol; and insensitive to heat, protease, and acid or alkali and of a molecular mass smaller than 10,000 g mol⁻¹. The toxic B. licheniformis isolates inhibited growth of Corynebacterium renale DSM 20688^T, but not all inhibitory isolates were sperm toxic. The food poisoning-related isolates were beta-hemolytic, grew anaerobically and at 55°C but not at 10°C, and were nondistinguishable from the type strain of B. licheniformis, DSM 13^T, by a broad spectrum of biochemical tests. Ribotyping revealed more diversity; the toxin producers were divided among four ribotypes when cut with PvuII and among six when cut with EcoRI, but many of the ribotypes also contained nontoxigenic isolates. When ribotyped with PvuII, most toxin-producing isolates shared bands at 2.8 ± 0.2, 4.9 ± 0.3, and 11.7 ± 0.5 or 13.1 ± 0.8 kb.     

Investigating the role of small, acid-soluble spore proteins (SASPs) in the resistance of Clostridium perfringens spores to heat

Background  

Clostridium perfringens type A food poisoning is caused by enterotoxigenic C. perfringens type A isolates that typically possess high spore heat-resistance. The molecular basis for C. perfringens spore heat-resistance remains unknown. In the current study, we investigated the role of small, acid-soluble spore proteins (SASPs) in heat-resistance of spores produced by C. perfringens food poisoning isolates.     

Bacillus thermoamylovorans Spores with Very-High-Level Heat Resistance Germinate Poorly in Rich Medium despite the Presence of ger Clusters but Efficiently upon Exposure to Calcium-Dipicolinic Acid

High-level heat resistance of spores of Bacillus thermoamylovorans poses challenges to the food industry, as industrial sterilization processes may not inactivate such spores, resulting in food spoilage upon germination and outgrowth. In this study, the germination and heat resistance properties of spores of four food-spoiling isolates were determined. Flow cytometry counts of spores were much higher than their counts on rich medium (maximum, 5%). Microscopic analysis revealed inefficient nutrient-induced germination of spores of all four isolates despite the presence of most known germination-related genes, including two operons encoding nutrient germinant receptors (GRs), in their genomes. In contrast, exposure to nonnutrient germinant calcium-dipicolinic acid (Ca-DPA) resulted in efficient (50 to 98%) spore germination. All four strains harbored cwlJ and gerQ genes, which are known to be essential for Ca-DPA-induced germination in Bacillus subtilis. When determining spore survival upon heating, low viable counts can be due to spore inactivation and an inability to germinate. To dissect these two phenomena, the recoveries of spores upon heat treatment were determined on plates with and without preexposure to Ca-DPA. The high-level heat resistance of spores as observed in this study (D_120°C, 1.9 ± 0.2 and 1.3 ± 0.1 min; z value, 12.2 ± 1.8°C) is in line with survival of sterilization processes in the food industry. The recovery of B. thermoamylovorans spores can be improved via nonnutrient germination, thereby avoiding gross underestimation of their levels in food ingredients.     

Molecular Epidemiology of Clostridium perfringens Related to Food-Borne Outbreaks of Disease in Finland from 1984 to 1999

From 1975 to 1999, Clostridium perfringens caused 238 food-borne disease outbreaks in Finland, which is 20% of all such reported outbreaks during these years. The fact that C. perfringens is commonly found in human and animal stools and that it is also widespread in the environment is a disadvantage when one is searching for the specific cause of a food-borne infection by traditional methods. In order to strengthen the evidence-based diagnostics of food poisonings suspected to be caused by C. perfringens, we retrospectively investigated 47 C. perfringens isolates by PCR for the cpe gene, which encodes enterotoxin; by reversed passive latex agglutination to detect the enterotoxin production; and by pulsed-field gel electrophoresis (PFGE) to compare their genotypes after restriction of DNA by the enzymes SmaI and ApaI. The strains were isolated during 1984 to 1999 from nine food-borne outbreaks of disease originally reported as having been caused by C. perfringens. In seven of the nine outbreaks our results supported the fact that the cause was C. perfringens. Our findings emphasize the importance of a more detailed characterization of C. perfringens isolates than mere identification to the species level in order to verify the cause of an outbreak. Also, to increase the probability of finding the significant cpe-positive C. perfringens strains, it is very important to isolate and investigate more than one colony from the fecal culture of a patient and screen all these isolates for the presence of the cpe gene before further laboratory work is done.     

Live Cell Imaging of Germination and Outgrowth of Individual Bacillus subtilis Spores; the Effect of Heat Stress Quantitatively Analyzed with SporeTracker

Spore-forming bacteria are a special problem for the food industry as some of them are able to survive preservation processes. Bacillus spp. spores can remain in a dormant, stress resistant state for a long period of time. Vegetative cells are formed by germination of spores followed by a more extended outgrowth phase. Spore germination and outgrowth progression are often very heterogeneous and therefore, predictions of microbial stability of food products are exceedingly difficult. Mechanistic details of the cause of this heterogeneity are necessary. In order to examine spore heterogeneity we made a novel closed air-containing chamber for live imaging. This chamber was used to analyze Bacillus subtilis spore germination, outgrowth, as well as subsequent vegetative growth. Typically, we examined around 90 starting spores/cells for ≥4 hours per experiment. Image analysis with the purposely built program “SporeTracker” allows for automated data processing from germination to outgrowth and vegetative doubling. In order to check the efficiency of the chamber, growth and division of B. subtilis vegetative cells were monitored. The observed generation times of vegetative cells were comparable to those obtained in well-aerated shake flask cultures. The influence of a heat stress of 85°C for 10 min on germination, outgrowth, and subsequent vegetative growth was investigated in detail. Compared to control samples fewer spores germinated (41.1% less) and fewer grew out (48.4% less) after the treatment. The heat treatment had a significant influence on the average time to the start of germination (increased) and the distribution and average of the duration of germination itself (increased). However, the distribution and the mean outgrowth time and the generation time of vegetative cells, emerging from untreated and thermally injured spores, were similar.     

Survival of Desulfotomaculum spores from estuarine sediments after serial autoclaving and high-temperature exposure

Bacterial spores are widespread in marine sediments, including those of thermophilic, sulphate-reducing bacteria, which have a high minimum growth temperature making it unlikely that they grow in situ. These Desulfotomaculum spp. are thought to be from hot environments and are distributed by ocean currents. Their cells and spores upper temperature limit for survival is unknown, as is whether they can survive repeated high-temperature exposure that might occur in hydrothermal systems. This was investigated by incubating estuarine sediments significantly above (40–80 °C) maximum in situ temperatures (∼23 °C), and with and without prior triple autoclaving. Sulphate reduction occurred at 40–60 °C and at 60 °C was unaffected by autoclaving. Desulfotomaculum sp. C1A60 was isolated and was most closely related to the thermophilic D. kuznetsovii^T (∼96% 16S rRNA gene sequence identity). Cultures of Desulfotomaculum sp. C1A60, D. kuznetsovii^Tand D. geothermicum B2T survived triple autoclaving while other related Desulfotomaculum spp. did not, although they did survive pasteurisation. Desulfotomaculum sp. C1A60 and D. kuznetsovii cultures also survived more extreme autoclaving (C1A60, 130 °C for 15 min; D. kuznetsovii, 135 °C for 15 min, maximum of 154 °C reached) and high-temperature conditions in an oil bath (C1A60, 130° for 30 min, D. kuznetsovii 140 °C for 15 min). Desulfotomaculum sp. C1A60 with either spores or predominantly vegetative cells demonstrated that surviving triple autoclaving was due to spores. Spores also had very high culturability compared with vegetative cells (∼30 × higher). Combined extreme temperature survival and high culturability of some thermophilic Desulfotomaculum spp. make them very effective colonisers of hot environments, which is consistent with their presence in subsurface geothermal waters and petroleum reservoirs.