The effect of the pH of the sporulation environment on the heat resistance ofClostridium perfringens spores

The inactivation ofClostridium perfringens NCTC 8239 spores at 95° and 105° C, as determined by colony formation on an agar base containing lysozyme (BASE + lysozyme), was influenced by the initial pH of the sporulation medium. In the pH range of 7.0–8.5, established by the addition of each of several biological buffers or carbonate buffer to Duncan-Strong (DS) medium, increased pH resulted in formation of spores with greater resistance to inactivation at elevated temperatures. An increase of pH from 8.5 to 9.0 resulted in increased resistance of spores formed in DS-carbonate but not DS-TAPS (N-tris[hydroxymethyl]methyl-3-aminopropanesulfonic acid) medium. Resistance to spore injury, as determined by reduced recovery on BASE compared with BASE + lysozyme, was not increased for spores formed in media with higher pH's. As the pH of the medium increased, cell growth and number of spores formed were decreased, but the percentage of sporulation was apparently not affected.     

Effect of sporulation and recovery medium on the heat resistance and amount of injury of spores from spoilage bacilli

AIMS: To assess the influence of sporulation media on heat resistance, and the use of stress recovery media to measure preservation injury of spores of five representative spoilage bacilli. METHODS AND RESULTS: Bacillus spores prepared on nutrient agar supplemented with Ca2+, Mg2+, Mn2+, Fe2+ and K+ were more heat-resistant than spores obtained from nutrient agar with Mn2+. This increased heat resistance correlated with a decrease in the protoplast water content as determined by buoyant density sedimentation. The degree of preservation injury severity could be assessed on media containing NaCl at moderate pH and organic acids at acid pH. Ca-DPA, K+ or proline were added to the recovery media to demonstrate that heat probably caused injury to both spore germination and the outgrowth system. SIGNIFICANCE AND IMPACT OF THE STUDY: The metal content of sporulation media can strongly effect the validity of preservation resistance studies. The distinctive recovery media developed here can be relevant for assessing and comparing new preservation technologies.     

Heat resistance of Salmonella senftenberg 775W at various sucrose concentrations in distilled water

Summary The heat resistance of Salmonella senftenberg 775 W, NCTC 9959, has been determined in distilled water pH 6.5 at sucrose concentrations up to 2.20 mol l^–1 at temperatures between 63 and 70°C. Surviving cells were counted on minimal and enriched agar media to investigate the influence of the various nutrients on the recovery of heat injured cells. At various sucrose concentrations and temperatures multiphasic exponential parts of inactivation curves were found. Systematic differences between the recovery media depended on sucrose concentration, temperature and phase of exponential inactivation. At 60°C and sucrose concentrations between 0.52 and 1.82 mol l^–1 the relationship between inactivation rate and sucrose concentration could be described by the equation ln k₅=ln k₀-_T [sucrose]. The activation energy of thermal inactivation reactions, substantially decreased when sucrose (1.82 mol l^–1) was added to the heating menstruum. The activation energies in different recovery agars were of the same order, which suggests that the critical sites in heat inactivation are not key enzymes of the synthetic pathways of amino-acids and nucleotides. The differences between activation energies, calculated for cells of the various exponential phases of inactivation in both non-sucrose and 1.82 mol sucrose per 1 heating media, were also small, further suggesting that these critical sites are the same in cells from the various phases. Compared to published data on the heat resistance of S. senftenberg 775 W, we found a decreased resistance in a non-sucrose medium but an equal or increased resistance, depending on the phase of exponential inactivation, at a sucrose concentration of 1.82 mol l^–1.     

Heat resistance ofCitrobacter freundii in media with various water activities

Summary The heat resistance ofCitrobacter freundii NCTC 9750 between 45–65°C in media with various water activities has been determined.At a water activity of nearly 1.00, the Arrhenius plot of the death rate shows a sharp breakpoint at 56.5°C, suggesting the existence of at least two different thermal inactivation processes causing lethality of the bacterial cell. The activation energy below 56.5°C is 0.4186 MJ/mol (100 000 cal/mol), above 56.5°C it is 0.1863 MJ/mol (44 500 cal/mol). After addition of sucrose (1.8 mol/l) or NaCl (0.77 mol/l) to the heating medium, such a breakpoint is not observed. The activation energy for these processes are, for sucrose; 0.2097 MJ/mol, for NaCl; 0.3641 MJ/mol. However, at an NaCl concentration of 1.54 mol/l there is a breakpoint at 53.3°C.The influence of the sucrose concentration on the heat resistance can be described by the formula: ln k_S=ln k_O–a [sucrose]. Such a simple correlation does not exist for the influence of NaCl or glycerol.The heat inactivation of whole cells ofC. freundii was also measured with a differential scanning calorimeter. The first irreversible conformation change took place at 323 K, the main conformation change at 343 K.     

Effect of Several Environmental Conditions on the “Thermal Death Rate” of Endospores of Aerobic, Thermophilic Bacteria

The composition of the recovery medium affected the apparent heat resistance of Bacillus stearothermophilus when the pH of the medium was 7.0 but not when the pH was 6.5. The rate of thermal death at 110 C was exponential. Deviations from exponential rates of thermal death during the initial phases of heating at 96 C were observed with endospores of B. coagulans under different conditions of sporulation. Additionally, the apparent heat resistance was influenced by the composition of the media used for sporulation and recovery and by the composition of the suspending menstruum. The presence of 0.001 m sorbic acid in the suspending menstruum at pH 7.0 and the temperature of incubation of the cultures after heating did not affect the apparent heat resistance of B. coagulans. Several explanations are discussed for the observed deviations from exponential thermal death rates and the effect of the environment on the apparent heat resistance of B. coagulans.     

Heat resistance of Klebsiella pneumoniae in media with various sucrose concentrations

Summary The heat resistance of Klebsiella pneumoniae, an organism of widespread occurrence in nature has been determined in media containing various amounts of sucrose at temperatures between 47° and 59°C.In the presence of sucrose and at all temperatures the inactivation curves show a fast initial drop (logarithmic phase) in the number of survivors followed by a less rapid one (tail phase). The influence of the sucrose concentration can be described withln k _s = ln k _O – _T [sucrose] for media with more than 0.52 mol/l sucrose for the logarithmic as well as for the tail phase of inactivation.The heat-injured cells were recovered on various media to investigate the influence of the presence of small metabolites and nutrients on the shape of the inactivation curves and on the death rate. For cells heated in media without sucrose, the recovery on a rich medium was much better than on a poor one; for cells heated in media with more than 0.26 mol/l sucrose, no difference was observed between the various recovery media.The activation energies as determined on the various media are always nearly the same, which strongly suggests that the critical sites in the heat inactivation were not enzymes playing a key role in the synthesis of small molecules such as amino acids or nucleotides.     

Interactive effects of solutes, potassium sorbate and incubation temperature on growth, heat resistance and tolerance to freezing of Zygosaccharomyces rouxii

The interactive effects of solutes, potassium sorbate and incubation temperature on growth, heat resistance and tolerance to freezing of Zygosaccharomyces rouxii were investigated. Growth rates in media supplemented with glucose, sucrose or NaCl to a _w 0.93 were more rapid than in unsupplemented media ( a _w 0.99). Although growth in unsupplemented medium was lower at 35°C, incubation at 21°C or 35°C had little effect on growth in media supplemented with glucose and sucrose. The addition of 300 μg potassium sorbate/ml to media resulted in reduced growth rates, particularly at 35°C. Heat resistance of Z. rouxii was substantially greater in cultures previously incubated at 35°C than in cultures incubated at 21° in media both with and without 300 μg potassium sorbate/ml. Zygosaccharomyces rouxii was tolerant to freezing at - 18°C for up to 120 d in all test media supplemented with glucose, sucrose or NaCl. The addition of 300 μg potassium sorbate/ml to sucrose-supplemented media resulted in increased resistance to freezing in cultures previously incubated at 21°C. Sensitivity to freezing increased when cultures were incubated at 21°C in media not supplemented with solutes. Glucose and sucrose provided the best protection against inactivation by heating and freezing, regardless of the presence of potassium sorbate in growth media.     

Interactive effects of solutes, potassium sorbate and incubation temperature on growth, heat resistance and tolerance to freezing of Zygosaccharomyces rouxii.

The interactive effects of solutes, potassium sorbate and incubation temperature on growth, heat resistance and tolerance to freezing of Zygosaccharomyces rouxii were investigated. Growth rates in media supplemented with glucose, sucrose or NaCl to aw 0.93 were more rapid than in unsupplemented media (aw 0.99). Although growth in unsupplemented medium was lower at 35 degrees C, incubation at 21 degrees C or 35 degrees C had little effect on growth in media supplemented with glucose and sucrose. The addition of 300 micrograms potassium sorbate/ml to media resulted in reduced growth rates, particularly at 35 degrees C. Heat resistance of Z. rouxii was substantially greater in cultures previously incubated at 35 degrees C than in cultures incubated at 21 degrees C in media both with and without 300 micrograms potassium sorbate/ml. Zygosaccharomyces rouxii was tolerant to freezing at -18 degrees C for up to 120 d in all test media supplemented with glucose, sucrose or NaCl. The addition of 300 micrograms potassium sorbate/ml to sucrose-supplemented media resulted in increased resistance to freezing in cultures previously incubated at 21 degrees C. Sensitivity to freezing increased when cultures were incubated at 21 degrees C in media not supplemented with solutes. Glucose and sucrose provided the best protection against inactivation by heating and freezing, regardless of the presence of potassium sorbate in growth media.     

Heat resistance in Rhizobium

Summary Seven of eight Rhizobium strains survived 70° C but not 80° C for half an hour in liquid media. The proportion of cells surviving heat treatment varied with the composition of the media and the age of the cultures, but did never exceed 0.7%. It appears that this heat resistance is not an effect of sporulation, according to the classical definition of a spore. Spore staining gave always negative results. However, spore-like structures could be seen in cells of heat resistant cultures. But it was not possible to correlate the number of these cells with the number of heat resistant cells. There was no difference between cells surviving heat treatment and untreated cells concerning infectivity and effectivity.     

Polygalacturonase,biomass and ascospore production by Byssochlamys fulva. II. Effects of sugars found in fruits

Polygalacturonase, biomass, and ascospore production by four strains of Byssochlamys fulva cultured in laboratory media supplemented with glucose, sucrose, or fructose was studied over a 20-day incubation period at 30° C. The production of polygalacturonase was variable, but most activity was detected between 4 and 8 days in 1% sugar media at an initial pH of 4 or 5. The rate of biomass production was retarded early in the incubation period in media initially at pH 3 or 4 as compared to pH 5, but the amount of growth was about the same in media containing the test sugars after 20 days. Large numbers of ascospores were produced between 8 and 10 days in media containing 5% sugar initially at pH 5 and 4. Production of ascospores was retarded at pH 3 in media containing 5% sugar as compared to media initially at pH 5 and 4.     

The effect of solid medium composition on growth and sporulation ofStreptomyces clavuligerus; spore viability during storage at +4°C

Summary The effect of solid medium composition and pH on growth and sporulation ofStreptomyces clavuligerus was studied in Petri dish and slant cultures at 30 °C. The extent of sporulation was observed under the microscope and the number of viable spores per slant was counted by serial dilution. Abundant aerial mycelium and sporulation were achieved with some of the media tested in this work. In Tris/HCl buffer (0.05 M, pH 7.2), containing 0.1% Tween 80, spores retained 28%, 17% and 2% viability at +4 °C after 1,9 and 17.5 weeks, respectively.     

Influence of the sporulation temperature upon the heat resistance of Bacillus subtilis.

The influence of different sporulation temperatures (30, 37, 44 and 52 degrees C) upon heat resistance of Bacillus subtilis was investigated. Heat resistance was greater after higher sporulation temperatures. Relation of heat resistance and temperature of sporulation was not linear over all the range of temperatures tested. Heat resistance increased about tenfold in the range of 30-44 degrees C. Sporulation at 52 degrees C did not show any further increase in heat resistance. This effect was constant over all the range of heating temperatures tested (100-120 degrees C). z value remained constant (z = 9 degrees C). Greater heat resistances at higher temperatures of sporulation were not due to selection of more heat resistant cells by a higher sporulation temperature. Spores obtained from cells incubated at 32 or 52 degrees C always possessed heat resistances that corresponded to the sporulation temperature regardless of the incubation temperature of their vegetative cells.     

Influence of the sporulation temperature upon the heat resistance of Bacillus subtilis

The influence of different sporulation temperatures (30, 37, 44 and 52°C) upon heat resistance of Bacillus subtilis was investigated.
Heat resistance was greater after higher sporulation temperatures. Relation of heat resistance and temperature of sporulation was not linear over all the range of temperatures tested. Heat resistance increased about tenfold in the range of 30–44°C. Sporulation at 52°C did not show any further increase in heat resistance.
This effect was constant over all the range of heating temperatures tested (100–120°C). z value remained constant ( z = 9°C).
Greater heat resistances at higher temperatures of sporulation were not due to selection of more heat resistant cells by a higher sporulation temperature. Spores obtained from cells incubated at 32 or 52°C always possessed heat resistances that corresponded to the sporulation temperature regardless of the incubation temperature of their vegetative cells.     

Factors influencing alkali-induced heat resistance in Salmonella enteritidis phage type 4

The culture of cells of Salmonella enteritidis PT4 at either 25, 30 or 37°C in media at pH values between 8.0 and 9.75 resulted in significant increases in heat resistance. At 37°C, induction was rapid and was dependent on protein synthesis, being inhibited by chloramphenicol. Thermotolerance was stable when cells were transferred from pH 9.2 to pH 7.0 and cultures only became heat sensitive again following significant multiplication at the lower pH.     

Strain-dependent induction by heat shock of resistance to ultraviolet light inEscherichia coli

Heat shock induces resistance to killing by ultraviolet light inEscherichia coli JE1011. When cells growing at 30°C were transferred to 42°C, maximum resistance to ultraviolet radition was reached after 30–45 min, but no change in heat resistance occurred. The effect was dependent on growth or protien synthesis. In contrast,E. coli B becomes more sensitive to the radiation and more heat resistant after a similar treatment. Thus, ultraviolet resistance and thermal resistance are not induced together in these two strains and may arise by independent mechanisms. It is also possible that thelon gene is involved in the effect of heat shock on ultraviolet resistance.     

The influence of pH and temperature on ethylene production by mycorrhizal fungi of pine

The production of ethylene by six mycorrhizal fungi of pine (Pinus sylvestris L.) grown in media with and without methionine at temperatures of 20° C and 26° C and at pH 4.0, 6.0 or 7.0 was studied. The fungi produced more ethylene at 26° C than at 20° C, and more ethylene in media containing methionine than in media without this precursor. The fungi studied synthesized the highest amounts of ethylene at 26° C and pH 6.O.     

Sublethal heat stress of Vibrio parahaemolyticus.

When Vibrio parahaemolyticsu ATCC 17802 was heated at 41 degrees C for 30 min in 100 mM phosphate-3% NaCl buffer (pH 7.0), the plate counts obtained when using Trypticase soy agar containing 0.25% added NaCl (0.25 TSAS) were nearly 99.9% higher than plate counts using Trypticase soy agar containing 5.5% added NaCl (5.5 TSAS). A similar result was obtained when cells of V. parahaemolyticus were grown in a glucose salts medium (GSM) and heated at 45 degrees C. The injured cells recovered salt tolerance within 3 h when placed in either 2.5 TSBS or GSM at 30 degrees C. The addition of chloramphenicol, actinomycin D, or nalidixic acid to 2.5 TSBS during recovery of cells grown in 2.5 TSBS indicated that recovery was dependent upon protein, ribonucleic acid (RNA, and deoxyribonucleic acid (DNA) synthesis. Penicillin did not inhibit the recovery process. Heat-injured, GSM-grown cells required RNA synthesis but not DNA synthesis during recovery in GSM. Chemical analyses showed that total cellular RNA decreased and total cellular DNA remained constant during heat injury. The addition of [6-3H]uracil, L-[U-14C]leucine, and [methyl-3H]thymidine to the recovery media confirmed the results of the antibiotic experiments.     

Heat-induced injury inListeria monocytogenes

Summary Heating ofListeria monocytogenes (Scott A strain) in potassium phosphate buffer (0.1 M, pH 7.2) at 52°C for 1 h led to injury, with the heat-injured cells failing to produce colonies on agar medium containing 5% NaCl. The detection of injury was based on the use of differential media: plating on tryptose phosphate broth+2% agar and 1% sodium pyruvate (TPBA+P) and on tryptose phosphate broth+2% agar and 5% NaCl (TPBA+S). Only non-injuredListeria formed colonies on TPBA+S whereas both heat-injured and non-injured cells formed colonies on TPBA+P. The bacterial count on TPBA+P minus that on TPBA+S represents the extent of heat injury. A large number of selective agars were tested and compared to TPBA+P for their ability to support repair and colony formation of heat-injuredL. monocytogenes. Media containing 0.025% phenylethanol, 0.0012–0.0025% acriflavin, 0.1–0.2% potassium tellurite, 0.001% polymyxin B sulfate, 5% NaCl or a combination of these ingredients were detrimental to the recovery of heat-injuredL. monocytogenes. Media currently in use forL. monocytogenes are not satisfactory for the recovery of injured cells.     

Growth and thermal inactivation of Listeria monocytogenes in cabbage and cabbage juice

Studies were done to determine the interacting effects of pH, NaCl, temperature, and time on growth, survival, and death of two strains of Listeria monocytogenes. Viable population of the organism steadily declined in heat-sterilized cabbage stored at 5 degrees C for 42 days. In contrast, the organism grew on raw cabbage during the first 25 days of a 64-day storage period at 5 degrees C. Growth was observed in heat-sterilized unclarified cabbage juice containing less than or equal to 5% NaCl and tryptic phosphate broth containing less than or equal to 10% NaCl. Rates of thermal inactivation increased as pH of clarified cabbage juice heating medium was decreased from 5.6 to 4.0. At 58 degrees C (pH 5.6), 4 X 10(6) cells/mL were reduced to undetectable levels within 10 min. Thermal inactivation rates in clarified cabbage juice (pH 5.6) were not significantly influenced by the presence of up to 2% NaCl; however, heat-stressed cells had increased sensitivity to NaCl in tryptic soy agar recovery medium. Cold enrichment of heat-stressed cells at 5 degrees C for 21 days enhanced resuscitation. Results indicate that L. monocytogenes can proliferate on refrigerated (5 degrees C) raw cabbage which, in turn, may represent a hazard to health of the consumer. Heat pasteurization treatments normally given to cabbage juice or sauerkraut would be expected to kill any L. monocytogenes cells which may be present.     

Suitability of some enrichment broths and diluents for enumerating cold- and heat-stressed Vibrio parahaemolyticus.

Vibrio parahaemolyticus cells were injured by chilling and heating, and their recovery was tested in glucose-salt-Teepol broth (GSTB), tryptic soy broth containing 7% NaCl (TSBS), Horie - arabinose - ethyl violet broth (HAEB), and water blue - alizarin yellow broth (WBAY). Exponential phase cells were more sensitive to cold shock than were stationary phase cells. Exposure of chill-injured V. parahaemolyticus to GSTB and TSBS resulted in 70 to 80% death; about 70% lethality was noted for heat-injured cells inoculated into TSBS. Neither HAEB nor WBAY enrichment media were lethal to stressed cells, although rates of growth were retarded. The 3% NaCl in 0.1 M potassium phosphate (pH 7.0) diluent proved to be most suitable for protecting against inactivation of cold- and heat-injured cells.