Influence of pH on the Heat Inactivation of Staphylococcal Enterotoxin A as Determined by Monkey Feeding and Serological Assay

The effect of pH on the thermal inactivation of staphylococcal enterotoxin A was investigated. Analysis of heated toxin by immunodiffusion in gel indicated that enterotoxin A in beef bouillon was inactivated faster at pH 5.3 than at pH 6.2. The z values (slopes) for the heat inactivation curves at pH 6.2 and 5.3 were 49.5 and 55 F (about 27 and 30 C), respectively. Enterotoxin produced and heated in dialyzed Casamino Acids medium and assayed by monkey feeding was more easily inactivated by heat at pH 5.3 than at pH 7.8. Thermal inactivation curves for enterotoxin A in beef bouillon (5 mug/ml, pH 5.3) were determined by two methods, monkey feeding and serological assay. The z values for the curves obtained by these two methods were both 55 F, although loss of biological or toxic activity of the enterotoxin occurred before loss of serological activity.     

Establishment of a heat inactivation curve for Clostridium botulinum 62A toxin in beef broth.

A procedure is described for establishing a heat inactivation curve for the toxin of Clostridium botulinum 62A in beef broth. The effect of toxin titer, pH, and the type of acid employed for pH adjustment on the heat stability of the toxin is described.     

Establishment of a heat inactivation curve for Clostridium botulinum 62A toxin in beef broth.

A procedure is described for establishing a heat inactivation curve for the toxin of Clostridium botulinum 62A in beef broth. The effect of toxin titer, pH, and the type of acid employed for pH adjustment on the heat stability of the toxin is described.     

Production of Escherichia coli Heat-labile Enterotoxin in Fermenter Dialysis Culture

Production of Escherichia coli heat-labile enterotoxin was investigated with one porcine and one human strain in three different media under different cultivation conditions. Cultivation in aerated fermenters at pH 7·0 yielded 10–20 times more enterotoxin/ml of culture fluid than cultivation in shake flasks. A trypton-yeast extract medium was optimal in fermenter cultures. Comparatively good yields of enterotoxin in fermenters were also obtained in a glucose-salts medium. Continuous feeding of glucose and salts during fermenter cultivation resulted in a lower production of enterotoxin/mg of bacterial cells. Since this decrease in specific yield could be reversed by using dialysis culture, it was concluded that inhibition of toxin formation was due to the accumulation of extracellular low molecular weight metabolites. The highest yield of enterotoxin in dialysis culture was 80 ED₅₀ ml⁻¹ (rabbit jejunal loop test) which is at least eight times more toxin than in ordinary fermenter culture and 80 times more toxin than in shake flask cultures.     

Regulation of Staphylococcal Enterotoxin B

Several factors influenced the formation of enterotoxin B by Staphylococcus aureus strain S-6. In the standard casein hydrolysate medium, toxin was not produced in detectable quantities during exponential growth; it was produced during the post-exponential phase when total protein synthesis was arithmetic. The rate of toxin synthesis was much greater than the rate of total protein synthesis. The appearance of enterotoxin was inhibited by chloramphenicol; thus, the presence of toxin was dependent on de novo protein synthesis. When low concentrations of glucose (<0.30%) were added to the casein hydrolysate medium, growth was diauxic; glucose was completely metabolized during the first growth period. During the second growth period, enterotoxin was synthesized. In unbuffered casein hydrolysate medium containing excess glucose, toxin synthesis was completely repressed. The absence of toxin production under such conditions might be explained by the low (4.6) pH resulting from the acid end products of glucose metabolism. At pH <5.0, little or no toxin was produced. Toxin synthesis was initiated in the presence of glucose when the medium were buffered at any pH above 5.6. In such media, the differential rates of toxin synthesis, with respect to the rates of total protein synthesis, were lower than the differential rates in casein hydrolysate medium alone. Addition of glucose to a culture synthesizing toxin resulted in an immediate decrease in the differential rate without any change in pH. Thus, toxin synthesis appeared to be regulated by catabolite repression.     

Stimulation of neutrophil leukocyte chemotaxis by a cloned cytolytic enterotoxin of Aeromonas hydrophila

A cytolytic enterotoxin produced by Aeromonas hydrophila, isolate SSU, has been cloned in our laboratory. This enterotoxin lysed rabbit red blood cells, destroyed Chinese hamster ovary cells, caused fluid secretion in rat ligated ileal loops, inhibited the phagocytic function of mouse phagocytes, and was lethal to mice when injected intravenously. In this study, the effect of this cytolytic enterotoxin on the chemotaxis of human leukocytes (cell line RPMI 1788) was examined. This toxin, at concentrations from 92.5 to 370 ng/ml, significantly stimulated the chemotactic activity of human leukocytes in a dose-dependent fashion. The stimulation of leukocyte chemotaxis elicited by cytolytic enterotoxin was abolished when the toxin was neutralized, heated, or exposed to low pH values. This stimulatory effect also was inhibited by various concentrations of pertussis toxin. These results demonstrated that cytolytic enterotoxin may stimulate increased chemotaxis of human leukocytes, and suggest that human leukocytes may possess cytolytic enterotoxin receptors which may be coupled to pertussis toxin-sensitive G-protein.     

Cloning of genes that encode a new heat-labile enterotoxin of Escherichia coli.

The genes for a new enterotoxin were cloned from Escherichia coli SA53. The new toxin was heat labile and activated adenylate cyclase but was not neutralized by antisera against cholera toxin or E. coli heat-labile enterotoxin. Subcloning and minicell experiments indicated that the toxin is composed of two polypeptide subunits that are encoded by two genes. The two toxin subunits exhibited mobilities on polyacrylamide gels that are similar to those of cholera toxin and E. coli heat-labile enterotoxin subunits. A 0.8-kilobase DNA probe for the new enterotoxin failed to hybridize with the cloned structural genes for E. coli heat-labile enterotoxin.     

Factors Affecting the Secretion of Staphylococcal Enterotoxin A

The biosynthesis of enterotoxin A by replicating and nonreplicating cells was investigated. Unlike enterotoxin B, a secondary metabolite, enterotoxin A secretion resembled that of a primary metabolite by being secreted during the exponential phase of growth. The amount of toxin produced per unit of growth was not influenced by NaCl, NaNO(2), or NaNO(3). Several surfactants increased toxin secretion. Toxin secretion by nonreplicating cells was inhibited by chloramphenicol and 2, 4-dinitrophenol but not by streptomycin or penicillin G. The optimal pH for enterotoxin A production was 6.5 to 7.0. The findings suggest a number of possible reasons for the higher incidence of food poisonings caused by enterotoxin A as compared to enterotoxin B.     

Studies on the irradiation of toxins of Clostridium botulinum and Staphylococcus aureus

The effects of irradiation of Clostridium botulinum neurotoxin type A (BNTA) and staphylococcal enterotoxin A (SEA) in gelatin phosphate buffer and cooked mince beef slurries were investigated. Estimation of toxins by immunoassays showed that in buffer, toxins were destroyed by irradiation at 8.0 kGy; in mince slurries however, 45% of BTNA and 27–34% of SEA remained after this level of irradiation. At 23.7 kGy, over twice the dose of irradiation proposed for legal acceptance in the UK, 15% of BNTA and 16–26% of SEA still remained. Increasing concentrations of mince conferred increased protection against the effect of irradiation on both toxins. The biological activity of BNTA was more sensitive to irradiation than the immunological activity. Staphylococcal enterotoxin was more resistant to irradiation than BNTA. Irradiation should therefore only be used in conjunction with good manufacturing practices to prevent microbial proliferation and toxin production prior to irradiation.     

Studies on the irradiation of toxins of Clostridium botulinum and Staphylococcus aureus

The effects of irradiation of Clostridium botulinum neurotoxin type A (BNTA) and staphylococcal enterotoxin A (SEA) in gelatin phosphate buffer and cooked mince beef slurries were investigated. Estimation of toxins by immunoassays showed that in buffer, toxins were destroyed by irradiation at 8.0 kGy; in mince slurries however, 45% of BTNA and 27-34% of SEA remained after this level of irradiation. At 23.7 kGy, over twice the dose of irradiation proposed for legal acceptance in the UK, 15% of BNTA and 16-26% of SEA still remained. Increasing concentrations of mince conferred increased protection against the effect of irradiation on both toxins. The biological activity of BNTA was more sensitive to irradiation than the immunological activity. Staphylococcal enterotoxin was more resistant to irradiation than BNTA. Irradiation should therefore only be used in conjunction with good manufacturing practices to prevent microbial proliferation and toxin production prior to irradiation.     

Heat Inactivation of Enterotoxin A from Staphylococcus aureus in Veronal Buffer

Serological tests were used to determine the slope of the thermal inactivation curve of crude enterotoxin A in Veronal buffer (pH 7.2), and the resulting z value was 27.8 C. (50 F). Serological assays also showed that the heat inactivation at each time-temperature depended on the original concentration of enterotoxin A. The usefulness of the Oudin tube serological test for determining end points of inactivation of naturally produced enterotoxin A (not concentrated) is discussed. We concluded that this test cannot be used to determine end points of heat inactivation for enterotoxin A in the minute quantities naturally produced in foods.     

Regulation of Staphylococcal Enterotoxin B: Effect of Thiamine Starvation

During the transition between the exponential and stationary phases of growth, there was a rapid accumulation of both cell-associated and extracellular enterotoxin B. Extracellular enterotoxin was synthesized until the cells entered the stationary phase during which cell-bound toxin was not detected. The differential rate of toxin synthesis relative to that of total protein synthesis was greater at pH 7.7 than at 6.0. Addition of glucose decreased the differential rate of toxin synthesis. This decrease was greater at pH 7.7 than at 6.0. Addition of pyruvate decreased the differential rate at pH 7.7 but not at 6.0. Analysis of the nongaseous end products of glucose and pyruvate metabolism showed that conditions which favor the oxidative decarboxylation of pyruvate also favor the repression of toxin synthesis. Elimination of thiamine from the medium prevented the oxidative decarboxylation of pyruvate by Staphylococcus aureus S-6 and partially or completely reversed the repression of toxin synthesis by glucose and pyruvate. In the absence of an added energy source, thiamine starvation caused a decrease in protein synthesis but an increased differential rate of toxin synthesis which was greater at pH 7.7 than at 6.0. In the absence of thiamine, pyruvate was not metabolized but caused a decrease in the rate of protein synthesis. This resulted in a twofold increase in the differential rate of toxin synthesis. Thus, conditions which altered the oxidative decarboxylation of pyruvate or decreased the rate of protein synthesis increased the rate of enterotoxin B synthesis.     

Inhibition of enterotoxin production by, and growth of enteropathogens in a lactic acid-fermenting cereal gruel

Growth and enterotoxin production of three strains of Campylobacter jejuni or Escherichia coli known to produce heat labile enterotoxins were evaluated when added into a lactic acid-fermenting cereal gruel, togwa. A single strain of each of the enteropathogens was simultaneously inoculated with a lactic acid starter culture (sc) to reach a level of about 107 c.f.u./ml and was left to ferment for 48h. Gruels without sc (control gruel), pure cholera toxin in fermenting or control gruel and the test bacteria inoculated into nutrient broth were used as positive toxin controls; gruel without inoculated test bacteria was the toxin-negative control. Viable colonies were counted by spread plating 0.1ml of gruel subsamples collected at intervals during the fermentation period onto different selective media and the heat labile enterotoxin production was evaluated using an assay on Chinese hamster ovary (CHO) cells. In the fermenting gruels, no viable cells of the C. jejuni and E. coli strains were detected after 8 and 24h incubation, respectively, but inocula increased in number or remained at the initial level in the control gruel and in the nutrient broth. After 24h incubation, all supernatants of control gruels with inoculated bacteria showed enterotoxicity to the CHO cells (indicated by elongation of 20–50% of the cells). No toxin activity was observed in the fermenting gruels with or without added bacteria or in control gruel alone. Pure cholera toxin added to control gruel caused the enterotoxigenic effect in 70–100% of the CHO cells, but no activity was detected when it was added to the fermenting gruel. The CHO cells were affected instead by a low pH level but were not elongated. Adjusting the pH of fermented gruels to approximately neutral levels restored the toxin effect when cholera toxin was added but not in the presence of added test bacteria. We conclude that lactic acid fermented cereal gruels with pH 4 have a high potential to inhibit the growth of enteropathogenic bacteria of the genera C. jejuni and E. coli and to inhibit production of heat labile enterotoxins. Regular consumption of fermented cereal weaning foods will therefore reduce transmission of enterotoxin-producing bacteria, and ingestion of enterotoxins.     

An improved method for detecting cytostatic toxin (emetic toxin) of Bacillus cereus and its application to food samples

Abstract We developed an improved HEp-2 cell assay method for the detection of Bacillus cereus toxin, which affects the proliferation of HEp-2 cells. The cytostatic toxin was stable upon exposure to heat, pH 2, pH 11 and trypsin, which suggests it is an emetic. Using the HEp-2 cell assay, we examined the distribution and contamination of B. cereus strains that produced an emetic toxin in various foods. Although there were 228 enterotoxin producers among 310 B. cereus strains obtained from foods, 16 of them produced the cytostatic type (emetic toxin). All of the strains that produced the cytostatic toxin were of the H.1 serotype.     

Factors influencing Clostridium botulinum spore germination, outgrowth, and toxin formation in acidified media

Clostridium botulinum type A spores were inoculated at a level of 10(7) spores per ml into sterile beef media with protein concentrations of 1, 2, 3, 4, or 6% and acidified to pH values of 2.01 to 4.75 with hydrochloric acid or 4.19 to 4.60 with citric acid. All experimental manipulations, including blending, acidification, inoculation, incubation (30 degrees C), and analyses, were conducted in an anaerobic chamber-incubator in which atmospheric oxygen levels were maintained below 2 ppm (2 microliters/liter). Under these strict anaerobic conditions (oxidation-reduction values in media ranging from -370 to -391 mV), C. botulinum spores were consistently found to germinate, grow, and produce toxin below pH 4.6. The boundary between toxic and atoxic samples in HC1-acidified beef media was mediated by titratable acidity, pH, and protein concentration. A limiting acidity was not established for the citrate-acidified samples; all blends tested (1, 2, 3, and 4% protein and titratable acidities of 0.091 to 0.453%) became toxic within 5 weeks. At the same pH and protein concentration, citric acid was less effective than HC1 in preventing the germination of C. botulinum spores. Higher levels of cell proliferation in the beef protein, as well as enhanced gas production and putrefactive degradation, indicated that beef was a better substrate than soy for C. botulinum spores under these conditions. Reducing the inoculum to 10(4) delayed but did not prevent spore outgrowth and toxin release at pH levels below 4.6.     

Factors influencing Clostridium botulinum spore germination, outgrowth, and toxin formation in acidified media.

Clostridium botulinum type A spores were inoculated at a level of 10(7) spores per ml into sterile beef media with protein concentrations of 1, 2, 3, 4, or 6% and acidified to pH values of 2.01 to 4.75 with hydrochloric acid or 4.19 to 4.60 with citric acid. All experimental manipulations, including blending, acidification, inoculation, incubation (30 degrees C), and analyses, were conducted in an anaerobic chamber-incubator in which atmospheric oxygen levels were maintained below 2 ppm (2 microliters/liter). Under these strict anaerobic conditions (oxidation-reduction values in media ranging from -370 to -391 mV), C. botulinum spores were consistently found to germinate, grow, and produce toxin below pH 4.6. The boundary between toxic and atoxic samples in HC1-acidified beef media was mediated by titratable acidity, pH, and protein concentration. A limiting acidity was not established for the citrate-acidified samples; all blends tested (1, 2, 3, and 4% protein and titratable acidities of 0.091 to 0.453%) became toxic within 5 weeks. At the same pH and protein concentration, citric acid was less effective than HC1 in preventing the germination of C. botulinum spores. Higher levels of cell proliferation in the beef protein, as well as enhanced gas production and putrefactive degradation, indicated that beef was a better substrate than soy for C. botulinum spores under these conditions. Reducing the inoculum to 10(4) delayed but did not prevent spore outgrowth and toxin release at pH levels below 4.6.     

Enterotoxin Production by Lecithinase-positive and Lecithinase-negative Clostridium perfringens Isolated from Food Poisoning Outbreaks and other sources

Strains of Clostridium perfringens from a variety of sources were examined for their ability to produce enterotoxin in vitro. Fifty-six of 65 (86%) strains isolated from separate outbreaks of food poisoning were found to be enterotoxigenic, only two of 174 strains from other sources produced enterotoxin. The ability to produce this toxin was not confined to particular serotypes: types frequently encountered as the cause of outbreaks were also isolated as enterotoxin-negative strains from faeces, minced beef and meat carcasses. Loss of toxigenicity was also observed in different serotypes. Five strains of lecithinase-negative Cl. perfringens produced high levels of enterotoxin. Four strains of Clostridium plagarum failed to produce enterotoxin although they were serologically typable with the Cl. perfringens antisera.     

Detection of staphylococcal enterotoxin in foods.

A method has been developed for the detection of staphylococcal enterotoxin A in the boiled rice extract. The procedure utilized was the batch adsorption of enterotoxin from the cell-free culture supernatant by CG-50 ion exchange resin at pH 5.6. The enterotoxin was eluted by various concentrations of elution solution with different pH values. The lyophilized eluate was dissolved in Phosphate Buffer Saline (PBS) solution and analyzed with a quantitative double diffusion method. The desorption of enterotoxin from ion exchange resin appeared to be less effective by increasing the concentration of elution solution than by elevating the pH value of elution solution. The pH below 6.2 seemed to lose the ability to elute the enterotoxin from ion exchanger but enough to elimate non-specific extra proteins. The quantitative double diffusion method was able to detect enterotoxin in food with approximation in quantitation.     

Simplified Method for Purification of Clostridium perfringens Type A Enterotoxin

Purification of Clostridium perfringens type A enterotoxin from sporulated cells was simplified. The method consisted of precipitation of the enterotoxin from the extract of sonically treated cells at 40% saturation of ammonium sulfate at pH 7, differential solubilization in 0.02 M phosphate buffer, pH 6.7, and repeated gel filtration on Sephadex G-200. The purified enterotoxin was at least 98% pure in ultracentrifugation, polyacrylamide gel electrophoresis, and agar gel double diffusion. Recovery was over 74% from the sporulated cell extract. The toxin had biological activities of at least 4,700 mouse intravenous minimal lethal doses/mg of N, 3,900 capillary permeability-increasing U/mg of N in the guinea pig skin, and 210 rabbit intestinal loop distension U/mg of N. The toxin, containing no hexose, lipid, or nucleic acid, appeared to be identical in sedimentation constant, isoelectric point, and ultraviolet absorption spectrum to the toxin purified previously by different procedures.     

Effect of beef broth protein on the thermal inactivation of staphylococcal enterotoxin B1.

Enterotoxin B produced by Staphylococus aureus 243 in brain heart infusion broth was concentrated by dialysis against 40% polyethylene glycol (20 M), partially purified on a Sephadex G-100 column and heated at 110 degrees C in thermal death time cans. Various heating menstrua included 0.04 M Veronal buffer (pH 7.4), beef broth, and fractions of beef broth obtained by ultrafiltration or precipitation with ammonium sulfate. The toxin was assayed serologically using the microslide gel double-diffusion method. The time requiring for 90% inactivation at 110 degrees C (D110 value) obtained in buffer and in beef broth was 18 and 60 min, respectively. When the concentration of beef broth was increased fivefold, the D110 increased to 78 min. The apparent protective effect or protein was further investigated using beef broth protein obtained by precipitation with (NH4)2SO4. The D110 values were 51 and 70 min when the protein concentration in the heating menstruum was 3.8 and 7.7 mg/ml, respectively. However, when the beef broth protein was dialyzed against buffer before use as a heating menstrum, the D110 was only 39 or 41 min at comparable protein concentrations. Results indicated a dialyzable factor, whose protective effect was partially destroyed by trypsin and chymotrypsin but did not by disodium ethylenediaminetetraacetate, was involved in the protection of enterotoxin B during heating.