Relationship between Bacillus sphaericus spore heat resistance and sporulation temperature

Bacillus sphaericus 9602 was grown in batch culture at various temperatures. At 10°C and 12°C the maximum sporulation yield was <10%, while at 15°C, 20°C and 30°C, a sporulation yield of >95% was achieved. However at 40°C B. sphaericus grew only vegetatively. The heat resistances (D values at 90°C) of spores grown at 15°C and 20°C were significantly higher than those grown at 30°C.     

Effect of ultrasonic waves on the heat resistance of Bacillus spores.

The effect of ultrasonic treatment on the heat resistance of Bacillus spores differs widely both with the species and the strain tested. Ultrasonic waves do not affect the heat resistance of some strains, whereas they greatly reduce that of other strains of the same species. The heat-sensitizing effect of ultrasonic waves is more pronounced when short heating periods are used. Ultrasonic treatment does not seem to affect the "Z value".     

Ultrastructure and extreme heat resistance of spores from thermophilic Clostridium species

The heat resistance and ultrastructural features of spore suspensions prepared from Clostridium thermocellum LQRI, Clostridium thermosulfurogenes 4B, and Clostridium thermohydrosulfuricum 39E were compared as a function of decimal reduction time. The decimal reduction times at 121 degrees C for strains LQRI, 4B, and 39E were 0.5, 2.5, and 11 min. The higher degree of spore heat resistance was associated with a spore architecture displaying a thicker cortex layer. Heat resistance of these spores was proportional to the ratio of spore cortex volume to cytoplasmic volume. These ratios for spores of strains LQRI, 4B, and 39E were 1.4, 1.6, and 6.6, respectively. The extreme heat resistance and autoclavable nature of C. thermohydrosulfuricum spores under routine sterilization procedures is suggested as a common cause of laboratory contamination with pure cultures of thermophilic, saccharide-fermenting anaerobes.     

Heat resistance of native and demineralized spores of Bacillus subtilis sporulated at different temperatures

Demineralization reduced heat resistance of B. subtilis spores, but the pattern and magnitude of the reduction depended on sporulation temperature and on heating menstruum pH. The differences in heat resistance of native spores caused by sporulation temperature almost disappeared after demineralization. Demineralized spores were still susceptible to the heat-sensitizing effect of acidic pH.     

Relationship between cortex content and properties of Bacillus sphaericus spores.

The muramic lactam content of spores of Bacillus sphaericus mutants defective in meso-diaminopimelic acid synthesis increases almost linearly with an increase of meso-diaminopimelic acid concentration in the medium. Since muramic lactam content is a measure of cortex content, the amount of cortex in spores of the mutants can be easily varied by changing the meso-diaminopimelic acid concentration in the medium. Characteristic properties were tested in spores containing different amounts of cortex. Critical amounts of cortex were associated with different spore properties. Refractility and dipicolinic acid accumulation in the spores both required about 20% of the maximum cortex content (although refractility is independent of dipicolinic acid content). For xylene octanol resistance, about 25% of the maximum cortex content was required.     

The effect of recovery conditions on the apparent heat resistance of Bacillus cereus spores

The effect of recovery media and incubation temperature on the apparent heat resistance of three ATCC strains (4342, 7004 and 9818) of Bacillus cereus spores were studied. Nutrient Agar (NA), Tryptic Soy Agar (TSA), Plate Count Agar (PCA) and Milk Agar (MA) as the media and temperatures in the range of 15–40°C were used to recover heated spores. Higher counts of heat injured spores were obtained on PCA and NA. The optimum subculture temperature was about 5°C below the optimum temperature for unheated spores. No significant differences in heat resistance were observed with the different recovery conditions except for strains 4342 and 9818 when MA was used as plating medium.
Large differences in D -values were found among the strains ( D ₁₀₀=0·28 min for 7004; D ₁₀₀=0·99 min for 4342; D ₁₀₀= 4·57 min for 9818). The 7004 strain showed a sub-population with a greater heat resistance. The z values obtained for the three strains studied under the different recovery conditions were similar (7·64°C 0·25).     

Heat-induced resistance of Bacillus stearothermophilus spores

Spores of Bacillus stearothermophilus CNCH 5781 were suspended in distilled water or nutrient medium. A 28 μl aliquot of each was inoculated into haematocrit capillaries and subjected at different time intervals to sublethal temperatures of 63° or 100°C as heat activation for germination. This was followed by heat treatment at 121·1°C and the heat parameter D _121·1 was measured. Contrary to standard observations, heat resistance was observed to increase following activation, a phenomenon which we named 'heat-induced resistance'.     

Effects of minerals on resistance of Bacillus subtilis spores to heat and hydrostatic pressure

Among Bacillus subtilis IFO13722 spores sporulated at 30, 37, and 44 degrees C, those sporulated at 30 degrees C had the highest resistance to treatments with high hydrostatic pressure (100 to 300 MPa, 55 degrees C, 30 min). Pressure resistance increased after demineralization of the spores and decreased after remineralization of the spores with Ca(2+) or Mg(2+), whereas the resistance did not change when spores were remineralized with Mn(2+) or K(+), suggesting that former two divalent ions were involved in the activation of cortex-lytic enzymes during germination.     

Heat shock proteins do not influence wet heat resistance of Bacillus subtilis spores

Spores of Bacillus subtilis are significantly more resistant to wet heat than are their vegetative cell counterparts. Analysis of the effects of mutations in and the expression of fusions of a coding gene for a thermostable β-galactosidase to a number of heat shock genes has shown that heat shock proteins play no significant role in the wet heat resistance of B. subtilis spores.     

Effect of relative humidity of hot air on the heat resistance of Bacillus cereus spores

The heat resistance to hot air of spores of Bacillus cereus (ATCC 14579) attached to carriers of stainless steel or silicone rubber was investigated in a range from 1% to 100% relative humidity (RH). Apart from an initial stage, linear survivor curves were obtained for all relative humidities. Neither the attachment itself nor the material of the carrier had an influence on the resistance. A distinct maximum of heat resistance was found at 40% RH. At 122°C the rate constants at 40% RH were five orders of magnitude smaller than at 100% RH and two orders of magnitude smaller than at 1% RH. At relative humidities of more than 40% the rate constants were strongly temperature dependent, whereas at lower relative humidities they were less temperature dependent. No significant influence of the relative humidity on the Arrhenius activation energy was found within each humidity range. The mean values were 295 kJ mol^-1 for relative humidities of 60% to 100% RH and 165 kJ mol^-1 for 1% to 20% RH. The occurrence of a maximum is ascribed to the existence of two inactivation mechanisms, the first is retarded and the second is accelerated by a reduction of relative humidity. It is assumed that the first mechanism is a protein denaturation. The second mechanism may be an oxidative process.     

Effect of sporulation conditions on the resistance of Bacillus subtilis spores to heat and high pressure

Bacillus subtilis(B. subtilis) cells were placed in various environmental conditions to study the effects of aeration, water activity of the medium, temperature, pH, and calcium content on spore formation and the resulting properties. Modification of the sporulation conditions lengthened the growth period of B. subtilis and its sporulation. In some cases, it reduced the final spore concentration. The sporulation conditions significantly affected the spore properties, including germination capacity and resistance to heat treatment in water (30 min at 97°C) or to high pressure (60 min at 350 MPa and 40°C). The relationship between the modifications of these spore properties and the change in the spore structure induced by different sporulation conditions is also considered. According to this study, sporulation conditions must be carefully taken into account during settling sterilization processes applied in the food industry.     

Emergence and development of resistance to antimicrobial chemicals and heat in spores of Bacillus subtilis

The emergence and development of chemical and thermal resistance in spores of Bacillus subtilis was examined. The chemicals studied were of the disinfectant type: glutaraldehyde, hypochlorite, hypochlorite-methanol and povidone-iodine. Growth and sporulation were followed by electron microscopy and resistance assigned to specific stages in relation to 45Ca and DPA accumulation. A sequential development of resistance was observed with thermal resistance appearing first at early Stage V corresponding to maturation of cortex and deposition of rudimentary spore coat material. Chemical resistance coincided with middle to late Stage V dependent on the chemical concerned. A progressive development of resistance was observed on prolonged incubation in sporulation medium and was affected by inclusion of lysozyme in the spore washing sequence.     

Emergence and development of resistance to antimicrobial chemicals and heat in spores of Bacillus subtilis

The emergence and development of chemical and thermal resistance in spores of Bacillus subtilis was examined. The chemicals studied were of the disinfectant type: glutaraldehyde, hypochlorite, hypochlorite-methanol and povidone-iodine. Growth and sporulation were followed by electron microscopy and resistance assigned to specific stages in relation to ⁴⁵Ca and DPA accumulation. A sequential development of resistance was observed with thermal resistance appearing first at early Stage V corresponding to maturation of cortex and deposition of rudimentary spore coat material. Chemical resistance coincided with middle to late Stage V dependent on the chemical concerned. A progressive development of resistance was observed on prolonged incubation in sporulation medium and was affected by inclusion of lysozyme in the spore washing sequence.     

Influence of the incubation temperature after heat treatment upon the estimated heat resistance values of spores of Bacillus subtilis

S. CONDÓN, A. PALOP, J. RASO AND F.J. SALA. 1996. The influence of the incubation temperature on the estimated heat resistance for survivors after heat treatment was investigated. The survival curves and the D _t values of spores of Bacillus subtilis heated at different temperatures in pH 7 buffer, obtained after incubating survivors at different temperatures (30, 37, 44 or 51°C), were compared. The incubation temperature influenced the profile of survival curves. Lower incubation temperatures led to bigger D _t values and longer shoulders. D _t values obtained after incubating at 30°C were higher (x3 approx.) than those obtained by incubating at 51°C. The incubation temperature did not modify z values ( z = 9.1). These results show that shoulders are not only due to the activation of dormant spores but also to heat damage repair mechanisms. From the profile of survival curves at different incubation temperatures it would seem that heat damage is accumulative. Cells can repair the initial heat injury, but the accumulation of injuries would eventually make the damage irreversible.     

Gamma radiation resistance of Bacillus anthracis spores

The aim of the presented study was determined the effectiveness of action the gamma radiation on water suspension B. anthracis spores. The irradiation was performed using a Cobalt 60 (Co 60) source, by using single and fractionary irradiation doses. In the investigations was used B. anthracis stain "Sterne" 34F2. The obtained results show, that gamma radiation effectively inactivates B. anthracis spores. On the efficiency of sterilization process influence the irradiation's method and the number of spores in 1 ml suspension. In the suspension 1.5 x 10(9) spore in 1 ml, sporicidal doses gamma radiation amount to 25.0 kGy (single dose) or 41.5 kGy (fractionary dose). The volume suspension about definite inoculum of spores, subjected working the gamma rays has not influence on sporicidal effectiveness of radiation sterilization.