Relationship between Heat Activation and Percentage Colony Formation for Bacillus stearothermophilus Spores: Effects of Storage and pH of the Recovery Medium

Colony counts of unheated spores were higher in a medium at pH 5·9 than in media of higher pH. The pattern was reversed as the spores were heated. Slide germination studies showed that about 8% or less of unheated spores germinated in slide culture. Optimal heat activation resulted in about 50% germination. The colony counts of heat activated spores dropped significantly upon storage for 9 months, but those of unheated spores did not.     

The effect of acid shock on sporulating Bacillus subtilis cells

AIMS: To study the effect of acid shock in sporulation on the production of acid-shock proteins, and on the heat resistance and germination characteristics of the spores formed subsequently. METHODS AND RESULTS: Bacillus subtilis wild-type (SASP-alpha+beta+) and mutant (SASP-alpha-beta-) cells in 2 x SG medium at 30 degrees C were acid-shocked with HCl (pH 4, 4.3, 5 and 6 against a control pH of 6.2) for 30 min, 1 h into sporulation. The D85-value of B. subtilis wild-type (but not mutant) spores formed from sporulating cells acid-shocked at pH 5 increased from 46.5 min to 78.8 min, and there was also an increase in the resistance of wild-type acid-shocked spores at both 90 degrees C and 95 degrees C. ALA- or AGFK-initiated germination of pH 5-shocked spores was the same as that of non-acid-shocked spores. Two-dimensional gel electrophoresis showed only one novel acid-shock protein, identified as a vegetative catalase 1 (KatA), which appeared 30 min after acid shock but was lost later in sporulation. CONCLUSIONS: Acid shock at pH 5 increased the heat resistance of spores subsequently formed in B. subtilis wild type. The catalase, KatA, was induced by acid shock early in sporulation, but since it was degraded later in sporulation, it appears to act to increase heat resistance by altering spore structure. SIGNIFICANCE AND IMPACT OF THE STUDY: This is the first proteomic study of acid shock in sporulating B. subtilis cells. The increasing spore heat resistance produced by acid shock may have significance for the heat resistance of spores formed in the food industry.     

Characterization of spore germination of a thermoacidophilic spore-forming bacterium, Alicyclobacillus acidoterrestris

The germination behaviors of spores of Alicyclobacillus acidoterrestris, which has been considered to be a causative microorganism of flat sour type spoilage in acidic beverages, were investigated. The spores of A. acidoterrestris showed efficient germination and outgrowth after heat activation (80 degrees C, 20 min) in Potato dextrose medium (pH 4.0). Further, the spores treated with heat activation germinated in McIlvaine buffer (pH 4.0) in the presence of a germinative substance (L-alanine) and commercial fruit juices, although not in phosphate buffer (pH 7.0). Heat activation was necessary for germination. The spores of A. acidoterrestris, which easily survived the heat treatment in acidic conditions, lost their resistance to heat during germination. Our results suggest that the models obtained from spore germination of A. acidoterrestris might be beneficial to determine adequate thermal process in preventing the growth of potential spoilage bacteria in acidic beverages.     

Factors Affecting the Rate of Heat-induced Spore Germination in Dictyostelium discoideum

Washed spores of Dictyostelium discoideum, strains NC-4H, NC-4D, and V-12, germinated rapidly after being heat shocked at or near 45.0 C for 30 min. Cultures of the slime molds were grown in association with Escherichia coli B/r as the host bacterium; spores taken from plates of synthetic medium had a higher final germination value than spores from complex medium containing peptone and yeast extract. Young spores germinated more rapidly than older spores. Optimal germination occurred between pH 6.0 and 7.0, and, of the buffers tested, potassium phosphate allowed the most rapid germination. After heat shocking, spores were diluted into fresh oxygenated buffer to provide enough oxygen for completion of germination. Germination occurred most rapidly between incubation temperatures of 22 and 25 C.     

Effects of Temperature on Activation, Germination, and Outgrowth of Bacillus megaterium Spores

The effects of temperature on the activation, glucose-induced germination, and outgrowth of Bacillus megaterium QM B1551 spores were investigated. There was no evidence for discontinuities in the response of spores to temperature in these processes reflecting reported thermal anomalies in the physical structure of water. Increasing the temperature of heat activation (aqueous suspensions, 5 min) increased the germinability of spores. Activation, as measured by extent of germination, was optimal after heating at 62 to 78 C, and the rate of spore germination was maximal after heat activation at 64 to 68 C. Increasing the temperature of activation above 68 C depressed the germination rate and increased the time lag before this rate was reached. Germination occurred over a wide range of temperatures, but was optimal between 28 and 38 C. The highest rate of germination was at 38 C; at lower incubation temperatures, the maximum attained rate was lower and the lag in attaining this rate was extended. Outgrowth (postgerminative development through the first cell division) of the germinated spores in Brain Heart Infusion (BHI) occurred in at least two phases-a temperature-dependent lag phase followed by a relatively temperature-independent phase of maximum outgrowth rate, during which increase in optical density was a linear function of time. Outgrowth time (time required for doubling of the initial optical density), essentially dependent on the time for completion of the lag phase, was shortest at temperatures between 34 and 40 C. The temperature-dependent lag phase was completed in a rich medium (e.g., BHI) but not in the glucose germination medium, suggesting that the endogenous reserves of the germinated spore were inadequate to support the metabolic synthetic events occurring during this period.     

Influence of NaCl, NaNO2 and oxygen on the germination and growth of Bacillus licheniformis, a spoilage organism of chub-packed luncheon meat

The thermal resistance of Bacillus licheniformis spores was increased from a D70-value of 590 min to one of 900 min by the addition of 4% NaCl to the heating medium [tryptone-yeast extract-glucose (TYG) broth, pH 6.8], but was decreased to 470 min in TYG broth acidified to pH 4.4. Sodium nitrite (0.02%) enhanced spore destruction at 80 degrees C but not at 70 degrees C; addition of 4% NaCl eliminated this effect. Less than half the number of spores surviving heat comparable to commercial cooking were heat-damaged to the extent of being unable to grow aerobically in the presence of 4% NaCl. No growth occurred during anaerobic incubation even when the media contained no added NaCl. Oxygen was not required to trigger spore germination, but trace amounts were needed for the successful outgrowth of germinated spores. Spore germination was accelerated and enhanced by the presence of at least 2% NaCl. Therefore under anaerobic conditions NaCl promotes microbiological stability because the germinated spores cannot develop further and become moribund. It is concluded that the plastic casing of luncheon-meat chubs is not sufficiently oxygen-impermeable to allow the product a long shelf-life other than at chill temperatures unless the chubs are stored in an oxygen-free atmosphere.     

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.     

REVERSIBLE ACTIVATION FOR GERMINATION AND SUBSEQUENT CHANGES IN BACTERIAL SPORES

Lee, W. H. (University of Illinois, Urbana) and Z. John Ordal. Reversible activation for germination and subsequent changes in bacterial spores. J. Bacteriol. 85:207-217. 1963.-It was possible to isolate refractile spores of Bacillus megaterium, from a calcium dipicolinate germination solution, that were activated and would germinate spontaneously in distilled water. Some of the characteristics of the initial phases of bacterial spore germination were determined by studying these unstable activated spores. Activated spores of B. megaterium were resistant to stains and possessed a heat resistance intermediate between that of dormant and of germinated spores. The spontaneous germination of activated spores was inhibited by copper, iron, silver, or mercury salts, saturated o-phenanthroline, or solutions having a low pH value, but not by many common inhibitors. These inhibitions could be partially or completely reversed by the addition of sodium dipicolinate. The activated spores could be deactivated and made similar to dormant spores by treatment with acid. Analyses of the exudates from the variously treated spore suspensions revealed that whatever inhibited the germination of activated spores also inhibited the release of spore material. The composition of the germination exudates was different than that of extracts of dormant spores. Although heavy suspensions of activated spores gradually became swollen and dark when suspended in solutions of o-phenanthroline or at pH 4, the materials released resembled those found in extracts of dormant spores rather than those of normal germination exudates.     

Effect of water activity and pH on growth and toxin production by Clostridium botulinum type G

The combined effect of water activity (aw) and pH on growth and toxin production by Clostridium botulinum type G strain 89 was investigated. The minimum aw at which growth and toxin formation occurred was 0.965, for media in which the pH was adjusted with either sodium chloride or sucrose. The minimum pH (at the optimum aw) for growth and toxin production of C. botulinum type G was found to be 5.6. Optimum conditions for toxin activation were a trypsin concentration of 0.1%, a pH of the medium of 6.5, and an incubation for 45 min at 37 degrees C. These data did not show evidence of heat-labile spores, since a heat shock of 75 degrees C for 10 min did not significantly decrease the spore count of strain 89G in media at pH 7.0 or 5.6. It was frequently observed that cells grown at reduced aw or pH experienced severe morphological changes.     

Effect of water activity and pH on growth and toxin production by Clostridium botulinum type G.

The combined effect of water activity (aw) and pH on growth and toxin production by Clostridium botulinum type G strain 89 was investigated. The minimum aw at which growth and toxin formation occurred was 0.965, for media in which the pH was adjusted with either sodium chloride or sucrose. The minimum pH (at the optimum aw) for growth and toxin production of C. botulinum type G was found to be 5.6. Optimum conditions for toxin activation were a trypsin concentration of 0.1%, a pH of the medium of 6.5, and an incubation for 45 min at 37 degrees C. These data did not show evidence of heat-labile spores, since a heat shock of 75 degrees C for 10 min did not significantly decrease the spore count of strain 89G in media at pH 7.0 or 5.6. It was frequently observed that cells grown at reduced aw or pH experienced severe morphological changes.     

Activation and killing of Dictyostelium discoideum spores with urea.

The optimal conditions for activation of Dictyostellium discoideum spores are an 8 M urea treatment for 30 min. The lag between activation and swelling is 45 min. Lower concentrations of urea do not activate entire spore populations. Incubating spores in 8 M urea for 60 min or treatment with 10 M urea for 30 min results in a lengthening of the post-activation lag and a decrease in the final percentage of germination. Urea-activated spores can be deactivated by azide, cyanide, osmotic pressure, and low-temperature incubation. Activated spores do not germinate if incubated in 1 M urea for 24 h but will complete germination upon resuspension in urea-free buffer. Shocking spores at 45 degrees C in 8 M urea or incubating spores in 4-8 M urea for 10 h at 23.5 degrees C causes inactivation. When suspended in urea-free buffer, a larger percentage of these dead spores release spheroplasts through a longitudinal split in the spore case. Sequential enzyme treatment of spheroplasts with cellulase and pronase causes them to release lysable protoplasts. The data of these experiments suggest that shedding of the outer and middle wall layers during physiological spore swelling may be a physical process rather than an enzymatic one.     

Conditions Affecting Germination of Clostridium botulinum 62A Spores in a Chemically Defined Medium

Spores of Clostridium botulinum type 62A were germinated in a chemically defined medium (8 mm l-cysteine, 11.9 mm sodium bicarbonate, 4.4 mm sodium thioglycolate; buffered with 100 mm TES, pH 7.0). The rate and extent of germination were increased when an aqueous spore suspension was heated sublethally (80 C, 60 min) before addition to the germination medium. Neither sublethal nor lethal doses of gamma radiation had any marked effect on subsequent germination. Maximum germination (>90% in 2 hr) in the defined medium occurred in the pH range of 6.5 to 7.5, at 30 to 37 C, with an l-cysteine level of 8 mm. Increasing l-cysteine to 32 mm increased the rate (over that with 8 mm l-cysteine) but not the extent of germination. The rate and extent of germination increased with NaHCO(3) addition to 8.3 mm, but increasing levels to 11.9 mm had no further effect. For maximum germination, 2.2 mm sodium thioglycolate was required and higher levels (to 8.8 mm) had no further enhancing or inhibitory effect. Under optimal conditions for germination, 97% of the spores had become heat sensitive; 98% had become sensitive to radiation; 88 and 91% had become phase dark and stainable, respectively, and the spore suspension had lost 46% of its initial optical density by 2 hr. Loss of heat resistance preceded loss of radiation resistance, acquisition of stainability, and phase darkening by about 12 min.     

Influence of NaCl, NaNO2 and oxygen on the germination and growth of Bacillus licheniformis, a spoilage organism of chub-packed luncheon meat

The thermal resistance of Bacillus licheniformis spores was increased from a D ₇₀-value of 590 min to one of 900 min by the addition of 4% NaCl to the heating medium [tryptone-yeast extract-glucose (TYG) broth, pH 6.8], but was decreased to 470 min in TYG broth acidified to pH 4.4. Sodium nitrite (0.02%) enhanced spore destruction at 80°C but not at 70°C; addition of 4% NaCl eliminated this effect. Less than half the number of spores surviving heat comparable to commercial cooking were heat-damaged to the extent of being unable to grow aerobically in the presence of 4% NaCl. No growth occurred during anaerobic incubation even when the media contained no added NaCl. Oxygen was not required to trigger spore germination, but trace amounts were needed for the successful outgrowth of germinated spores. Spore germination was accelerated and enhanced by the presence of at least 2% NaCl. Therefore under anaerobic conditions NaCl promotes microbiological stability because the germinated spores cannot develop further and become moribund. It is concluded that the plastic casing of luncheon-meat chubs is not sufficiently oxygen-impermeable to allow the product a long shelf-life other than at chill temperatures unless the chubs are stored in an oxygen-free atmosphere.     

A rapid screening method for the detection of viable spores in powder using bioluminescence.

A rapid diagnosis of a biological threat in a powder sample is important for fi rst responders who have to make decisions on-site. The present culture-based method does not provide timely results, which is a critical barrier for a quick response when a suspicious powder sample is found. The ATP bioluminescence method, combined with a heat shock, was investigated to determine the presence of spores in powder. The results show that only spore-containing powder samples provided a dramatic increase in the bioluminescence signal after the heat shock, which induces germination of the spores. Various conditions were tested to fi nd the most effective and rapid germination procedure. Elevated temperatures (37 degrees C and 50 degrees C) were more effective in germination than room temperature. At 50 degrees C, a double-strength germinant was more effective in germination than the regular strength. The 37 degrees C/15 min procedure induced the germination of spores most effectively, while a 50 degrees C/2 min procedure provided reasonably high signals, so it could make the entire procedure even faster (< 5 min). The detection limit of the bioluminescence method is < 100 spores.     

Properties of Germinating Spores of Dictyostelium discoideum

The process of spore germination in Dictyostelium discoideum consists of three sequential stages: activation of dormant spores, swelling of activated spores, and emergence of myxamoebae from swollen spores. Dormant and activated spores are resistant to heating, freezing, or drying. Drying and freezing, moreover, may maintain the activated state until the spores are returned to normal conditions. Low temperature incubation after heat shock or the presence of an autoinhibitor will return activated spores to the dormant state. The entire spore germination process is aerobic, being inhibited at any point by oxygen deprivation or respiratory poisons. Each spore of this social organism appears to germinate at its own rate and independent of the other spores in the suspension.     

Heat shock protects germinating conidiospores of Neurospora crassa against freezing injury.

Germinating conidiospores of Neurospora crassa that were exposed to 45 degrees C, a temperature that induces a heat shock response, were protected from injury caused by freezing in liquid nitrogen and subsequent thawing at 0 degrees C. Whereas up to 90% of the control spores were killed by this freezing and slow thawing, a prior heat shock increased cell survival four- to fivefold. Survival was determined by three assays: the extent of spore germination in liquid medium, the number of colonies that grew on solid medium, and dry-weight accumulation during exponential growth in liquid culture. The heat shock-induced protection against freezing injury was transient. Spores transferred to normal growth temperature after exposure to heat shock and before freezing lost the heat shock-induced protection within 30 min. Spores subjected to freezing and thawing stress synthesized small amounts of the heat shock proteins that are synthesized in large quantities by cells exposed to 45 degrees C. Pulse-labeling studies demonstrated that neither chilling the spores to 10 degrees C or 0 degrees C in the absence of freezing nor warming the spores from 0 degrees C to 30 degrees C induced heat shock protein synthesis. The presence of the protein synthesis inhibitor cycloheximide during spore exposure to 45 degrees C did not abolish the protection against freezing injury induced by heat shock. Treatment of the cells with cycloheximide before freezing, without exposure to heat shock, itself increased spore survival.     

Levels of H+ and other monovalent cations in dormant and germinating spores of Bacillus megaterium.

Previous investigators using the extent of uptake of the weak base methylamine to measure internal pH have shown that the pH in the core region of dormant spores of Bacillus megaterium is 6.3 to 6.5. Elevation of the internal pH of spores by 1.6 U had no significant effect on their degree of dormancy or their heat or ultraviolet light resistance. Surprisingly, the rate of methylamine uptake into dormant spores was slow (time for half-maximal uptake, 2.5 h at 24 degrees C). Most of the methylamine taken up by dormant spores was rapidly (time for half-maximal uptake, less than 3 min) released during spore germination as the internal pH of spores rose to approximately 7.5. This rise in internal spore pH took place before dipicolinic acid release, was not abolished by inhibition of energy metabolism, and during germination at pH 8.0 was accompanied by a decrease in the pH of the germination medium. Also accompanying the rise in internal spore pH during germination was the release of greater than 80% of the spores K+ and Na+. The K+ was subsequently reabsorbed in an energy-dependent process. These data indicate (i) that between pH 6.2 and 7.8 internal spore pH has little effect on dormant spore properties, (ii) that there is a strong permeability barrier in dormant spores to movement of charged molecules and small uncharged molecules, and (iii) that extremely early in spore germination this permeability barrier is breached, allowing rapid release of internal monovalent cations (H+, Na+, and K+).     

Inducement of a Heat-Shock Requirement for Germination and Production of Increased Heat Resistance in Bacillus fastidiosus Spores by Manganous Ions

Bacillus fastidiosus, which requires uric acid or allantoin, grows and sporulates on a simple medium containing 59.5 mM uric acid, 5.7 mM K₂HPO₄, and 2% agar in distilled water. Seventy to ninety percent sporulation was achieved in 96 h. Spores obtained on this medium do not need a heat shock prior to germination. The necessary germination conditions for this organism are 30 C, phosphate or this(hydroxymethyl)aminomethane buffer at pH 7.0, and 5.95 mM uric acid. Sporulation occurred earlier (48 h) and with higher frequency (greater than 99%) when Mn²⁺ was added to the growth medium. However, these spores germinated only after heat activation (70 C, 30 min). The effectiveness of heat activation was directly dependent upon the concentration of Mn²⁺ in the growth medium; 10⁻⁵ M Mn²⁺ was the minimal concentration for the effect. This phenomenon was not found upon addition of Ca²⁺, Mg²⁺, Fe²⁺, Zn²⁺, or Cu²⁺ to the medium. The Mn²⁺ content of the spores depended upon the concentration of Mn²⁺ in the sporulation medium. There was a significant difference in heat resistance between spores harvested from unsupplemented medium and those harvested from medium supplemented with 5 × 10⁻⁵ M Mn²⁺. A D_{85 C} value of 6.5 min was determined with the former, whereas the latter had a value of 17.0 min. Very little change in either Ca²⁺ or dipicolinic acid content was detected in spores harvested from various Mn²⁺-supplemented media. Thus Mn²⁺ may play a role in the inducement of the heat-shock requirement and the formation of spores with increased heat resistance.