Mathematical Model of Thermal Destruction of Bacillus stearothermophilus Spores

The experimental survival curves of Bacillus stearothermophilus spores in aqueous suspension, for six constant temperatures ranging from 105 to 130°C, displayed an initial shoulder before a linear decline. To interpret these observations, we supposed that, before the heat treatment, the designated spore suspension contained a countable and mortal N₀ population of activated spores and an M₀ population of dormant spores which remained masked during spore counting and had to be activated before being destroyed by heat. We also hypothesized that the mechanisms of both activation and destruction are, at constant temperature, ruled by first-order kinetics, with velocity constants k_A and k_D, respectively. Mathematical analysis showed that this model could represent not only our experimental survival curves, but also all other shapes (linear and biphasic) of survival curves found in the literature; also, there is an inherent symmetry in the model formulation between the activation and destruction reactions, and we showed that the dormancy rate (τ = M₀/N₀) is the only parameter which permits a distinction between the two reactions. By applying the model to our experimental data and considering that the dormancy rate is not dependent on the treatment temperature, we showed that, for the studied suspension, the limiting reaction was the activation reaction.     

Fatty Acids from Vegetative Cells and Spores of Bacillus stearothermophilus

In spores of Bacillus stearothermophilus produced at 45 and 55 C, branched-chain fatty acids predominated in the former and straight-chain acids in the latter.     

Thermal Injury and Recovery of Bacillus subtilis

Exposure of Bacillus subtilis NCTC 8236 to sublethal temperatures produced a change in the sensitivity of the organism to salt and polymyxin. After 30 min at 47 C, 90% of the population was unable to grow on a modified sulfite polymyxin sulfadiazine agar containing an added 1% NaCl, 1% glucose, and 1% asparagine. The data presented demonstrate that thermal injury results in degradation of both 16S and 23S ribonucleic acid (RNA) and in damage to the cell membrane, suggested by leakage into the heating mestruum of material absorbing at 260 nm. When the cells were placed in a recovery medium (Trypticase soy broth), complete recovery, indicated by a returned tolerance to salt and polymyxin, occurred within 2 hr. The presence of a protein inhibitor (chloramphenicol) and cell wall inhibitors (vancomycin and penicillin) during recovery had no effect, whereas the presence of an RNA inhibitor (actinomycin D) effectively inhibited recovery. Further data demonstrated that the injured cells were able to resynthesize both species of ribosomal RNA during recovery by using the fragments which resulted from the injury process. Also, precursor 16S and precursor 23S particles accumulated during recovery. The maturation of the precursor particles during recovery was not affected by the presence of chloramphenicol in the recovery medium.     

The Effect of Sodium Chloride on Heat Resistance and Recovery of Heated Spores of Bacillus stearothermophilus

Increasing concentrations (2, 4 and 8% w/v) of sodium chloride in the heating medium progressively reduced the heat resistance of spores of Bacillus stearothermophilus. Storage at 4° in water or in sodium chloride solutions had little effect on viable counts of unheated spores, but with the increase in sodium chloride concentration there was a reduction in the heat activation effect and a small decrease in heat resistance of the spores. Increasing the severity of heat treatment rendered spores increasingly sensitive to sodium chloride in the plating medium.     

Graphical Procedure for Comparing Thermal Death of Bacillus stearothermophilus Spores in Saturated and Superheated Steam

The thermal death curve of dried spores of Bacillus stearothermophilus in saturated steam was characterized by three phases: (i) a sharp initial rise in viable count; (ii) a low rate of death which gradually increased; and (iii) logarithmic death at maximal rate. The first phase was a reflection of inadequate heat activation of the spore population. The second and third phases represented the characteristic thermal death curve of the spores in saturated steam. A jacketed steam sterilizer, equipped with a system for initial evacuation of the chamber, was examined for superheat during normal operation. Measurements of spore inactivation and temperature revealed superheat in surface layers of fabrics being processed in steam at 121 C. The high temperature of the fabric surfaces was attributed to absorption of excess heat energy from superheated steam. The superheated steam was produced at the beginning of the normal sterilizing cycle by transfer of heat from the steam-heated jacket to saturated steam entering the vessel.     

Heat Activation and Heat-induced Dormancy of Bacillus stearothermophilus Spores

Heat-induced dormancy was observed when spores of two strains of Bacillus stearothermophilus were heated in distilled water at 80, 90, and 100 C. At temperatures above 100 C, true activation occurred; however, maximal activation was not achieved until temperatures of 110 to 115 C were employed. A heat treatment of 115 C for 3 min was required to induce maximal activation in one suspension of strain 1518 spores, whereas a heat treatment of 110 C for 7 to 10 min was adequate for the other suspension of strain 1518 spores. Spores from both strain M suspensions required heat treatments of 110 C for 9 to 15 min for maximal activation. The degree to which the spores could be activated was strain dependent and variable among spore suspensions of the same strain.     

Heat Shock Affects Permeability and Resistance of Bacillus stearothermophilus Spores

[This corrects the article on p. 2517 in vol. 54.].     

Germination of Spores of Bacillus stearothermophilus Induced by Analogues of Dipicolinate Di-Anion

The structural specificity required for induction of germination of spores of Bacillus stearothermophilus by analogues of dipicolinate in buffer at pH 5.5 is similar to that found previously with spores of Bacillus megaterium and calcium chelate salts at pH 8. 4H-pyran-2,6-dicarboxylate, but no other analogue tested, is as effective as dipicolinate di-anion.     

Effect of Carbohydrates in Phosphate Buffer on Germination of Bacillus stearothermophilus Spores

Among strains, and among spore suspensions of the same strain, different spore-germination responses were observed when spores were heated in monosaccharides, disaccharides, and polysaccharides in 0.0083 m phosphate buffer (pH 7.1). It was hypothesized that these differences were due to rough and smooth variants in the spore population and to variation in the osmosensitivity of spores of variants within the population when subjected to a heat shock of 110 C.     

Phospholipids from Bacillus stearothermophilus

The lipids of Bacillus stearothermophilus strain 2184 were extracted with chloroform-methanol and separated into neutral lipid and three phospholipid fractions by chromatography on silicic acid columns. The phospholipids were identified by specific staining reactions on silicic acid-impregnated paper, by chromatography of alkaline and acid hydrolysis products, and by determination of acyl ester:glycerol:nitrogen:phosphorus molar ratios. The total extractable lipid was 8% of the dry weight of whole cells and consisted of 30 to 40% neutral lipid and 60 to 70% phospholipid. The phospholipid consisted of diphosphatidyl glycerol (23 to 42%), phosphatidyl glycerol (22 to 39%), and phosphatidyl ethanolamine (21 to 32%). The concentrations of diphosphatidyl glycerol and phosphatidyl glycerol were lower in 2-hr cells than in 4- and 8-hr cells. Whole cells were fractionated by sonic treatment and differential centrifugation. The total lipid content, expressed in per cent of dry weight of each fraction was: whole protoplasts, 10%; membrane fraction, 18%; 30,000 x g particulate fraction, 22%; and 105,000 x g particulate fraction, 26%. The relative phospholipid concentrations in each fraction were about the same. As had been previously reported, none of the phospholipid was stable to alkaline hydrolysis.     

Thermal inactivation and injury of Bacillus stearothermophilus spores

Aqueous spore suspensions of Bacillus stearothermophilus ATCC 12980 were heated at different temperatures for various time intervals in a resistometer, spread plated on antibiotic assay medium supplemented with 0.1% soluble starch without (AAMS) or with (AAMS-S) 0.9% NaCl, and incubated at 55 degrees C unless otherwise indicated. Uninjured spores formed colonies on AAMS and AAMS-S; injured spores formed colonies only on AAMS. Values of D, the decimal reduction time (time required at a given temperature for destruction of 90% of the cells), when survivors were recovered on AAMS were 62.04, 18.00, 8.00, 3.33, and 1.05 min at 112.8, 115.6, 118.3, 121.1, and 123.9 degrees C, respectively. Recovery on AAMS-S resulted in reduced decimal reduction time. The computed z value (the temperature change which will alter the D value by a factor of 10) for spores recovered on AAMS was 8.3 degrees C; for spores recovered on AAMS-S, it was 7.6 degrees C. The rates of inactivation and injury were similar. Injury (judged by salt sensitivity) was a linear function of the heating temperature. At a heating temperature of less than or equal to 118.3 degrees C, spore injury was indicated by the curvilinear portion of the survival curve (judged by salt sensitivity), showing that injury occurred early in the thermal treatment as well as during logarithmic inactivation (reduced decimal reduction time). Heat-injured spores showed an increased sensitivity not only to 0.9% NaCl but also to other postprocessing environmental factors such as incubation temperatures, a pH of 6.6 for the medium, and anaerobiosis during incubation.     

Sporulation and Heat Resistance of Bacillus stearothermophilus Spores Produced in Chemically Defined Media

The effect of amino acids on sporulation is discussed. Heat-resistant spores were produced in a chemically defined medium.     

Heat Injury of Bacillus subtilis Spores at Ultrahigh Temperatures

The following three criteria indicated that Bacillus subtilis A spores were injured, but not completely inactivated, by ultrahigh temperature treatment. (i) Significant reductions in survivors were observed when spores were enumerated with a standard medium but not when the medium contained added CaCl(2) and sodium dipicolinate. (ii) After a damaging heat treatment, more survivors were enumerated with the standard medium after incubation at 32 C than at 45 C, which was opposite to the result with untreated or slightly heated spores. (iii) Apparent numbers of survivors increased during the initial period of 3 C storage when enumerated with the standard medium at 45 C. No injury was evident when survivors were enumerated at either incubation temperature with the medium containing added CaCl(2) and sodium dipicolinate. Heat activation of the spores did not significantly influence the appearance of heat injury. The data suggested that the heat injury occurred in a germination system which was required in the absence of CaCl(2) and sodium dipicolinate.     

Effect of Heat on Spores of Rough and Smooth Variants of Bacillus stearothermophilus

Spores of variants of Bacillus stearothermophilus were subjected to activating and lethal temperatures. Spore suspensions which were incubated longer contained a higher percentage of spores of the rough variant. The effect of sublethal heat on spore suspensions containing mixed variants (rough and smooth) was difficult to measure at sublethal temperatures (110 C), since the rough variant was not as heat-resistant. While the rough variant was activated in a shorter time, the smooth variant was not activated; when the smooth variant was activated, the rough was killed. A higher percentage of the smooth variant was forced into dormancy after being held at 50 C for 30 hr than the rough variant. When mixed populations were subjected to a lethal temperature (120 C), the curves only reflected the smooth variant. Since the curves which represented the smooth variant or mixtures containing the smooth variant were not linear, this was thought to be due to activation overbalancing the lethal effect. This research emphasized the importance of variants in explaining differences in spore resistance among spore suspensions of the same strain.     

beta-Galactosidase from Bacillus stearothermophilus.

Several strains of thermophilic aerobic spore-forming bacilli synthesize beta-galactosidase (EC 3.2.1.23) constitutively. The constitutivity is apparently not the result of a temperature-sensitive repressor. The beta-galactosidase from one strain, investigated in cell-free extracts, has a pH optimum between 6.0 and 6.4 and a very sharp pH dependence on the acid side of its optimum. The optimum temperature for this enzyme is 65 degrees C and the Arrhenius activation energy is about 24 kcal/mol below 47 degrees C and 16 kcal/mol above that temperature. At 55 degrees C the Km is 0.11 M for lactose and 9.8 X 10(-3) M for 9-nitrophenyl-beta-D-galactopyranoside. The enzyme is strongly product-inhibited by galactose (Ki equals 2.5 X 10(-3) M). It is relatively stable at 50 degrees C, losing only half of its activity after 20 days at this temperature. At 60 degrees C more than 60% of the activity is lost in 10 min. However, the enzyme is protected somewhat against thermal inactivation by protein, and in the presence of 4 mg/ml of bovine serum albumin the enzyme is only 18% inactivated in 10 min at 60 degrees C. Its molecular weight, estimated by disc gel electrophoresis, is 215 000.     

Thermostable peroxidase from Bacillus stearothermophilus

A peroxidase from Bacillus stearothermophilus was purified to homogeneity. The enzyme (Mr 175,000) was composed of two subunits of equal size, and showed a Soret band at 406 nm. On reduction with sodium dithionite, absorption at 434 nm and 558 nm was observed. The spectrum of reduced pyridine haemochrome showed peaks at 418, 526 and 557 nm; the reduced minus oxidized spectrum of pyridine haemochrome showed peaks of 418, 524 and 556 nm with a trough at 452 nm. These results indicate that the enzyme contained protohaem IX as a prosthetic group. The optimum pH was about 6 and the apparent optimum temperature was 70 degrees C. The enzyme was relatively stable up to 70 degrees C; at 30 degrees C it was stable for a month. The enzyme had peroxidase activity toward a mixture of 2,4-dichlorophenol and 4-aminoantipyrine with a Km for H2O2 of 1.3 mM. It also acted as a catalase with a Km for H2O2 of 7.5 mM.     

Thermal inactivation and injury of Bacillus stearothermophilus spores.

Aqueous spore suspensions of Bacillus stearothermophilus ATCC 12980 were heated at different temperatures for various time intervals in a resistometer, spread plated on antibiotic assay medium supplemented with 0.1% soluble starch without (AAMS) or with (AAMS-S) 0.9% NaCl, and incubated at 55 degrees C unless otherwise indicated. Uninjured spores formed colonies on AAMS and AAMS-S; injured spores formed colonies only on AAMS. Values of D, the decimal reduction time (time required at a given temperature for destruction of 90% of the cells), when survivors were recovered on AAMS were 62.04, 18.00, 8.00, 3.33, and 1.05 min at 112.8, 115.6, 118.3, 121.1, and 123.9 degrees C, respectively. Recovery on AAMS-S resulted in reduced decimal reduction time. The computed z value (the temperature change which will alter the D value by a factor of 10) for spores recovered on AAMS was 8.3 degrees C; for spores recovered on AAMS-S, it was 7.6 degrees C. The rates of inactivation and injury were similar. Injury (judged by salt sensitivity) was a linear function of the heating temperature. At a heating temperature of less than or equal to 118.3 degrees C, spore injury was indicated by the curvilinear portion of the survival curve (judged by salt sensitivity), showing that injury occurred early in the thermal treatment as well as during logarithmic inactivation (reduced decimal reduction time). Heat-injured spores showed an increased sensitivity not only to 0.9% NaCl but also to other postprocessing environmental factors such as incubation temperatures, a pH of 6.6 for the medium, and anaerobiosis during incubation.     

Thermal Inactivation of Bacillus anthracis Spores in Cow's Milk

Decimal reduction time (time to inactivate 90% of the population) (D) values of Bacillus anthracis spores in milk ranged from 3.4 to 16.7 h at 72°C and from 1.6 to 3.3 s at 112°C. The calculated increase of temperature needed to reduce the D value by 90% varied from 8.7 to 11.0°C, and the Arrhenius activation energies ranged from 227.4 to 291.3 kJ/mol. Six-log-unit viability reductions were achieved at 120°C for 16 s. These results suggest that a thermal process similar to commercial ultrahigh-temperature pasteurization could inactivate B. anthracis spores in milk.     

Cloning and Expression of Thermostable alpha-Amylase Gene from Bacillus stearothermophilus in Bacillus stearothermophilus and Bacillus subtilis

The structural gene for a thermostable alpha-amylase from Bacillus stearothermophilus was cloned in plasmids pTB90 and pTB53. It was expressed in both B. stearothermophilus and Bacillus subtilis. B. stearothermophilus carrying the recombinant plasmid produced about fivefold more alpha-amylase (20.9 U/mg of dry cells) than did the wild-type strain of B. stearothermophilus. Some properties of the alpha-amylases that were purified from the transformants of B. stearothermophilus and B. subtilis were examined. No significant differences were observed among the enzyme properties despite the difference in host cells. It was found that the alpha-amylase, with a molecular weight of 53,000, retained about 60% of its activity even after treatment at 80 degrees C for 60 min.