Influence of transition metals added during sporulation on heat resistance of Clostridium botulinum 113B spores

Sporulation of Clostridium botulinum 113B in a complex medium supplemented with certain transition metals (Fe, Mn, Cu, or Zn) at 0.01 to 1.0 mM gave spores that were increased two to sevenfold in their contents of the added metals. The contents of calcium, magnesium, and other metals in the purified spores were relatively unchanged. Inclusion of sodium citrate (3 g/liter) in the medium enhanced metal accumulation and gave consistency in the transition metal contents of independent spore crops. In citrate-supplemented media, C. botulinum formed spores with very high contents of Zn (approximately 1% of the dry weight). Spores containing an increased content of Fe (0.1 to 0.2%) were more susceptible to thermal killing than were native spores or spores containing increased Zn or Mn. The spores formed with added Fe or Cu also appeared less able to repair heat-induced injuries than the spores with added Mn or Zn. Fe-increased spores appeared to germinate and outgrow at a higher frequency than did native and Mn-increased spores. This study shows that C. botulinum spores can be sensitized to increased thermal destruction by incorporation of Fe in the spores.     

Aerobic growth and toxigenicity ofClostridium botulinum types A and B

Clostridium botulinum types A and B cultured in association with avian skin flora, had similar growth patterns under both aerobic and anaerobic conditions. The selective “C. botulinum isolation” (CBI) medium was found to be especially useful for the recovery and quantitation of small numbers of type A or type B organisms from the mixed cultures. Enzyme immunoassay in conjunction with conventional mouse biossay provided a practical means for the quantitation of toxigenicity ofC. botulinum in avian skin cultures. The amount of toxin produced by type A was always higher than that produced by type B strains. The aerobically incubated type A or type B cultures appeared to be less toxigenic than cultures incubated anaerobically.     

Zinc stimulates sporulation inClostridium botulinum 113B

The presence of 0.5–1.0 mM zinc (Zn) in a complex sporulation medium stimulated spore formation in certain strains ofClostridium botulinum. Zinc increased both the titer of free refractile spores (spores per liter) and the percentage conversion of vegetative cells to spores. Certain other transition metals including iron (Fe) and manganese (Mn) also improved sporulation, but not so effectively as zinc. Sporulation was drastically decreased by the addition to the medium of 0.5–1.0 mM copper (Cu). Copper was shown to compete with the acquisition of zinc by the sporulating cells. Spores were separated from their progenitor vegetative cells to 98% homogeneity by incorporation of a density-separation step in the extensive washing procedure. Analysis of the metal contents of the purified spores showed that zinc levels in spores were reduced considerably in culture media containing excess copper. The results imply that either the availability of zinc or the limitation of copper stimulates sporulation inC. botulinum. In addition toC. botulinum 113B, zinc also increased sporulation in several type A, B, and E strains and one proteolytic type F strain ofC. botulinum.     

Influence of transition metals added during sporulation on heat resistance of Clostridium botulinum 113B spores.

Sporulation of Clostridium botulinum 113B in a complex medium supplemented with certain transition metals (Fe, Mn, Cu, or Zn) at 0.01 to 1.0 mM gave spores that were increased two to sevenfold in their contents of the added metals. The contents of calcium, magnesium, and other metals in the purified spores were relatively unchanged. Inclusion of sodium citrate (3 g/liter) in the medium enhanced metal accumulation and gave consistency in the transition metal contents of independent spore crops. In citrate-supplemented media, C. botulinum formed spores with very high contents of Zn (approximately 1% of the dry weight). Spores containing an increased content of Fe (0.1 to 0.2%) were more susceptible to thermal killing than were native spores or spores containing increased Zn or Mn. The spores formed with added Fe or Cu also appeared less able to repair heat-induced injuries than the spores with added Mn or Zn. Fe-increased spores appeared to germinate and outgrow at a higher frequency than did native and Mn-increased spores. This study shows that C. botulinum spores can be sensitized to increased thermal destruction by incorporation of Fe in the spores.     

Heterogeneity in the cellular protein profiles ofClostridium botulinum types A and B

Summary Profiles of cellular proteins from 11 type A and 9 type B strains ofClostridium botulinum were examined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Cellular protein profiles exhibited considerable heterogeneity among strains of the same biotype, as well as among strains of different biotypes. This study also demonstrated the reliability and usefulness of this rapid and inexpensive procedure to determine the variation which may occur amongC. botulinum and related species.References to brand or firm names do not constitute endorsement by the U.S. Department of Agriculture over others of a similar nature not mentioned.     

Tailing of thermal inactivation curve of Aspergillus niger spores.

The nonlinear thermal inactivation of Aspergillus niger spores in phosphate-citrate buffer was studied. The thermal inactivation pattern of the spore consisted of a shoulder, an accelerated decline, and a tail at various constant temperatures around 60 degrees C. The pattern fitted a thermotolerant subpopulation model. In the model, we postulated that some spores in the initial population had become thermotolerant at a certain ratio during heating. The model parameters including the rate coefficients, the time lag, and the existence ratio of thermotolerant cells were analyzed at various temperatures. The tailing was not observed at an initial concentration below 10(3) cells per ml. Cells cultured from thermotolerant cells showed an inactivation pattern similar to that of the original cells. Also, cells at the second heating showed the same thermotolerance as or were slightly more thermosensitive than the original cells. Intermittent heating was found to be effective to inactivate cells at a high concentration.     

Comparative dose-survival curves of representative Clostridium botulinum type F spores with type A and B spores.

Radiation survival data of proteolytic (Walls 8G-F) and non-proteolytic (Eklund 83F) type F spores of Clostridium botulinum were compared with dose-response data of radiation-resistant type A (33A) and B (40B) spores. Strain Eklund 83F was as resistant as strain 33A, whereas strain Walls 8G-F was the most sensitive of the four strains tested. The methods suggested for computing both an initial shoulder and a D value for the dose-survival curves yielded results comparable to the graphic techniques used to obtain these two parameters.     

Comparative dose-survival curves of representative Clostridium botulinum type F spores with type A and B spores.

Radiation survival data of proteolytic (Walls 8G-F) and non-proteolytic (Eklund 83F) type F spores of Clostridium botulinum were compared with dose-response data of radiation-resistant type A (33A) and B (40B) spores. Strain Eklund 83F was as resistant as strain 33A, whereas strain Walls 8G-F was the most sensitive of the four strains tested. The methods suggested for computing both an initial shoulder and a D value for the dose-survival curves yielded results comparable to the graphic techniques used to obtain these two parameters.     

Temperature dependence of thermal inactivation rate constants of bacterial spores in a glassy state

Summary Differential scanning calorimetry data obtained from corn embryos is consistent with the hypothesis of their glassy state. This work extends that hypothesis to explain the speculation about the high heat resistance of bacterial spores. By considering the protoplast to be in a glassy solid-state, it can be assumed that the configurational rearrangements of the key life dependent polymer chain backbones (DNA, etc.) are extremely slow, thereby ceasing thermal motions. It is assumed that at the glass transition temperature, the spore protoplast undergoes a discontinuity in the thermal expansion coefficient, and above this critical temperature, the rate of thermal inactivation of spores is free volume dependent and can be described adequately by the William, Landel and Ferry (WLF) equation. Glass transition temperatures forBacillus stearothermophilus andClostridium botulinum spores, obtained by fitting the inactivation rate data to the WLF equation, indicate a decrease in the inactivation rates with increasing glass-transition temperatures.     

High gas pressure: an innovative method for the inactivation of dried bacterial spores

In this article, an original non-thermal process to inactivate dehydrated bacterial spores is described. The use of gases such as nitrogen or argon as transmission media under high isostatic pressure led to an inactivation of over 2 logs CFU/g of Bacillus subtilis spores at 430 MPa, room temperature, for a 1 min treatment. A major requirement for the effectiveness of the process resided in the highly dehydrated state of the spores. Only a water activity below 0.3 led to substantial inactivation. The solubility of the gas in the lipid components of the spore and its diffusion properties was essential to inactivation. The main phenomenon involved seems to be the sorption of the gas under pressure by the spores' structures such as residual pores and plasma membranes, followed by a sudden drop in pressure. Observation by phase-contrast microscopy suggests that internal structures have been affected by the treatment. Some parallels with polymer permeability to gas and rigidity at various water activities offer a few clues about the behavior of the outer layers of spores in response to this parameter and provide a good explanation for the sensitivity of spores to high gas pressure discharge at low hydration levels. Specificity of microorganisms such as size, organization, and composition could help in understanding the differences between spores and yeast regarding the parameters required for inactivation, such as pressure or maintenance time.     

Exploiting the combined effects of high pressure and moderate heat with nisin on inactivation of Clostridium botulinum spores

In the present work, we studied the combined effects of pressure (300.0-700.0 MPa), temperature (30-70 degrees C) and the presence of nisin (0-333 IU/ml) on the inactivation of Clostridium botulinum 33A spores at various pressure holding times (7.5-17.5 min). Moreover, response surface methodology (RSM) was employed and a quadratic equation for HPP and nisin-induced inactivation was built with RSM. By analyzing the response surface plots and their corresponding contour plots as well as solving the quadratic equation, the experimental values were shown to be significantly in good agreement with predicted values because the adjusted determination coefficient (R(Adj)(2)) was 0.9261 and the level of significance was P<0.0001. The optimum process parameters for a six-log cycle reduction of C. botulinum spores were obtained as: pressure, 545.0 MPa; temperature, 51 degrees C; pressure holding time, 13.3 min; and nisin concentration, 129 IU/ml. The adequacy of the model equation for predicting the optimum response values was verified effectively for 10 test points. Compared to conventional high pressure processing (HPP) techniques, the main process advantages of HPP-nisin combination sterilization in the UHT milk are, lower pressure, natural preservative (nisin), and temperature in a shorter treatment time.     

Thermal inactivation of nonproteolytic Clostridium botulinum type E spores in model fish media and in vacuum-packaged hot-smoked fish products

Thermal inactivation of nonproteolytic Clostridium botulinum type E spores was investigated in rainbow trout and whitefish media at 75 to 93 degrees C. Lysozyme was applied in the recovery of spores, yielding biphasic thermal destruction curves. Approximately 0.1% of the spores were permeable to lysozyme, showing an increased measured heat resistance. Decimal reduction times for the heat-resistant spore fraction in rainbow trout medium were 255, 98, and 4.2 min at 75, 85, and 93 degrees C, respectively, and those in whitefish medium were 55 and 7.1 min at 81 and 90 degrees C, respectively. The z values were 10.4 degrees C in trout medium and 10.1 degrees C in whitefish medium. Commercial hot-smoking processes employed in five Finnish fish-smoking companies provided reduction in the numbers of spores of nonproteolytic C. botulinum of less than 10(3). An inoculated-pack study revealed that a time-temperature combination of 42 min at 85 degrees C (fish surface temperature) with >70% relative humidity (RH) prevented growth from 10(6) spores in vacuum-packaged hot-smoked rainbow trout fillets and whole whitefish stored for 5 weeks at 8 degrees C. In Finland it is recommended that hot-smoked fish be stored at or below 3 degrees C, further extending product safety. However, heating whitefish for 44 min at 85 degrees C with 10% RH resulted in growth and toxicity in 5 weeks at 8 degrees C. Moist heat thus enhanced spore thermal inactivation and is essential to an effective process. The sensory qualities of safely processed and more lightly processed whitefish were similar, while differences between the sensory qualities of safely processed and lightly processed rainbow trout were observed.     

Thermal destruction of Clostridium botulinum spores suspended in tomato juice in aluminum thermal death time tubes.

The heat destruction characteristics of Clostridium botulinum spores suspended in tomato juice and phosphate buffer were determined by the survivor curve method with aluminum thermal death time tubes. Two type A strains of C. botulinum and a type B strain were evaluated. Strains A16037 and B15580 were implicated in outbreaks of botulism involving home-canned tomato products. Strain A16037 had a higher heat resistance than either 62A or B15580. The mean thermal resistance (D-values) for A16037 in tomato juice (pH 4.2) were: 115.6 degrees C, 0.4 min; 110.0 degrees C, 1.6 min; and 104.4 degrees C, 6.0 min. The mean D-values for A16037 in Sorensen 0.067 M phosphate buffer (pH 7) were: 115.6 degrees C, 1.3 min; 110.0 degrees C, 4.4 min; and 104.4 degrees C, 17.6 min. At each test temperature, the D-values were approximately three times higher in buffer than in tomato juice. The z-value for C. botulinum A16037 spores in tomato juice was 9.4 degrees C, and in buffer the z-value was 9.9 degrees C. The use of aluminum thermal death time tubes in a miniature retort system makes it possible to determine survivor curves for C. botulinum spores at 121.1 degrees C. This is possible because the lag correction factor for the aluminum tubes is only about 0.2 min, making possible heating times as short as 0.5 min.     

Validation of a polynomial regression model: the thermal inactivation of Bacillus subtilis spores in milk

AIMS: The predicted survival of Bacillus subtilis 168 spores from a polynomial regression equation was validated in milk. METHODS AND RESULTS: Bias factor suggested as an index of model performance was used to validate the polynomial model predictions in ultrahigh temperature (UHT) treated and sterilized whole and skim milk. Model predictions were fail safe, predicting higher D-values (decimal reduction times) in buffer than actually noted in milk. CONCLUSIONS: The D-values for spores were lower in milk as compared with those predicted in potassium phosphate buffer contrary to the popular expectation of better spore survival in complex food systems. The Bias factor, a quantitative measure of the model performance, indicated that on average the model predictions exceed the observations by 40% in the case of whole milk and by 60% in the case of skim milk. SIGNIFICANCE AND IMPACT OF THE STUDY: The present work is an attempt to ascertain the extent of reliability that one can safely place in polynomial model predictions, without compromising on the safety or palatability of foods where it is eventually intended to be applied. The work has also highlighted the differences in the thermal inactivation pattern of spores in buffer and in milk with a possible influence of the various constituents of milk. The work will assist the dairy industry to better design thermal processes to ensure longer shelf life of dairy foods.     

Purification,properties, and metabolic roles of NAD+-glutamate dehydrogenase in Clostridium botulinum 113B

Cell-free extracts of proteolytic strains of Clostridium botulinum types A, B and F (group I) were found to have unusually high specific activities of NAD⁺-dependent L-glutamate dehydrogenase (NAD-GDH). In comparison, nonproteolytic strains of types B, E and F (group II) had low specific activities. The enzyme was purified 131-fold from C. botulinum 113B to a final specific activity of >1,092 molxmin^-1xmg protein^-1. The enzyme is a hexamer of a polypeptide of Mr=42,500, and the native molecular weight is 250,800. The apparent K _m values for substrates were 5.3 mM for glutamate and 0.028 mM for NAD⁺ in the deamination reaction, and 7.2 mM for -ketoglutarate, 243 mM for NH ₄ ⁺ and 0.028 mM for NADH in the reverse reaction. NADP⁺ did not serve as a hydrogen acceptor for the enzyme. Activity in the animation direction was inhibited by fumarate, oxalacetate, aspartate, glutamate and glutamine. The results suggest that GDH is important in group I (proteolytic) C. botulinum to generate -ketoglutarate as a substrate for transamination reactions. We have also found that the high activity decreases significantly when cells are exposed to sodium chloride. Therefore GDH probably has several important physiological roles in group I proteolytic C. botulinum.     

Effects of inoculum level and pressure pulse on the inactivation of Clostridium sporogenes spores by pressure-assisted thermal processing

The effects of initial concentration and pulsed pressurization on the inactivation of Clostridium sporogenes spores suspended in deionized water were determined during thermal processing (TP; 105 degrees C, 0.1 MPa) and pressure-assisted thermal processing (PATP; 105 degrees C and 700 MPa) treatments for 40 min and 5 min holding times, respectively. Different inoculum levels (10(4), 10(6), and 10(8) CFU/ml) of C. sporogenes spores suspended in deionized water were treated at 105 degrees C under 700 MPa with single, double, and triple pulses. Thermally treated samples served as control. No statistical significances (p > 0.05) were observed among all different inoculum levels during the thermal treatment, whereas the inactivation rates (k1 and k2) were decreased with increasing the initial concentrations of C. sporogenes spores during the PATP treatments. Double- and triple-pulsed pressurization reduced more effectively the number of C. sporogenes spores than single-pulse pressurization. The study shows that the spore clumps formed during the PATP may lead to an increase in pressure-thermal resistance, and multiple-pulsed pressurization can be more effective in inactivating bacterial spores. The results provide an interesting insight on the spore inactivation mechanisms with regard to inoculum level and pulsed pressurization.