Analysis of the Loss in Heat and Acid Resistance during Germination of Spores of Bacillus Species

A major event in the nutrient germination of spores of Bacillus species is release of the spores'' large depot of dipicolinic acid (DPA). This event is preceded by both commitment, in which spores continue through germination even if germinants are removed, and loss of spore heat resistance. The latter event is puzzling, since spore heat resistance is due largely to core water content, which does not change until DPA is released during germination. We now find that for spores of two Bacillus species, the early loss in heat resistance during germination is most likely due to release of committed spores'' DPA at temperatures not lethal for dormant spores. Loss in spore acid resistance during germination also paralleled commitment and was also associated with the release of DPA from committed spores at acid concentrations not lethal for dormant spores. These observations plus previous findings that DPA release during germination is preceded by a significant release of spore core cations suggest that there is a significant change in spore inner membrane permeability at commitment. Presumably, this altered membrane cannot retain DPA during heat or acid treatments innocuous for dormant spores, resulting in DPA-less spores that are rapidly killed.     

Heat Resistance of Bacillus Spores at Various Relative Humidities

The thermal resistance characteristics of spores from strains of five different Bacillus species were determined in phosphate buffer and at relative humidities ranging from <0.001 to 100% in a closed-can system. Spores tested in the closed-can system showed a marked increase in heat resistance over those in phosphate buffer, with the greatest increases occurring at relative humidities between 1 and 50%. When estimates of the time to reduce the initial spore concentration 99.99% (F value) at eight different relative humidities were plotted against temperature, three different types of heat resistance profiles were obtained, with maximum resistances at relative humidities of 1, 7, and 30%. When the various strains of spores were heated at the relative humidity of their maximum heat resistance, their relative order of heat resistance was different from that seen in buffer. Spores from the soil isolate were most resistant under these conditions (F_121.1 = 99.5 h).     

Heat Resistance and Population Stability of Lyophilized Bacillus subtilis Spores

Bacillus subtilis 5230 spores were lyophilized in 0.067 M phosphate buffer and stored at 2 to 8°C for 9 to 27 months. The lyophilized spores were reconstituted with buffer or 0.9% saline, and the heat resistance was determined in a thermoresistometer. Lyophilization had no effect on the heat resistance of the spores but did result in a slight decrease in population (≤0.3-logarithm reduction). The lyophilized spores maintained heat resistance and population levels over the test periods. The D-values ranged from 0.44 to 0.54 min at 121.1°C, and the z-values ranged from 6.1 to 6.6°C. Lyophilization was concluded to be an acceptable alternative for storage of bacterial spores that are to be used as biological indicators in sterilization processes.     

Heat Shock Affects Permeability and Resistance of Bacillus stearothermophilus Spores

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

Identification of a Germination System Involved in the Heat Injury of Bacillus Subtilis Spores

Bacillus subtilis A spores were injured by exposure to heat treatments of 110 to 132 C. Injury was demonstrated by the inability to form colonies on fortified nutrient agar (FNA) unless the medium was supplemented with CaCl(2) and Na(2) dipicolinate (CNA). A preliminary heat treatment fully heat-activated the spores, was not lethal, and did not prevent injury by subsequent secondary heat treatment. Exposure of heat-activated spores to 122 C reduced germination in FNA. The primary germination agents in FNA were identified, and a defined germination medium of glucose, NaCl, l-alanine, and sodium phosphate (GNAP) was developed. Germination of heat-activated spores in GNAP was equivalent to germination in FNA. Injury measured by colony formation on FNA and CNA was correlated to injury measured by reduced germination in both FNA and GNAP. Inactivation of the FNA and GNAP germination systems by secondary treatment exhibited similar kinetics. Therefore, injury expressed as the inability to form colonies on FNA involved alteration of the GNAP germination system.     

Heat Resistance Correlated with DNA Content in Bacillus megaterium Spores

Two subpopulations of Bacillus megaterium spores (1.360 and 1.355 g/ml) were obtained by density gradient centrifugation. The heavier spores had a higher thermoresistance (e.g., D₈₀ = 186 versus 81 min) and a higher DNA content (1.25 × 10⁻¹⁴ versus 0.65 × 10⁻¹⁴ g per spore, apparently corresponding to digenomic versus monogenomic spores). No appreciable differences were found in the mineral and dipicolinic acid contents or in the inactivation kinetics of the two subpopulations. The implications of the findings are discussed with regard to mechanisms of heat resistance and of inactivation.     

Heat Resistance of Bacillus subtilis Spores at Various Water Activities

S ummary : The heat resistance of spores of Bacillus subtilis was determined in water vapour and in aqueous solutions of NaCl, LiCl, glucose and glycerol at various water activities. In water vapour and in glycerol solutions, maximal resistance appeared at low, but not zero water activity. In NaCl and glucose solutions only small variations in heat resistance occurred with decreasing water activity although a small increase was observed at the highest concentrations tested. With increasing concentrations of LiCl, heat resistance at first decreased but increased at water activities below 0·5. The possible interaction of compounds controlling water activity and water activity per se on heat resistance is discussed.     

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.     

Effect of Ultrasonic Waves on the Heat Resistance of Bacillus cereus and Bacillus licheniformis Spores

Heat resistance of Bacillus cereus and Bacillus licheniformis spores in quarter-strength Ringer solution decreases markedly after ultrasonic treatments which are unable to kill a significant proportion of the spore population. This effect does not seem to be caused by a loss of Ca(2+) or dipicolinic acid. The use of ultrasonics to eliminate vegetative cells or to break aggregates in Bacillus spore suspensions to be used subsequently in heat resistance experiments appears to be unadvisable.     

Activation Energy for Glucose-Induced Germination of Bacillus megaterium Spores

The maximum germination rate of Bacillus megaterium QM B1551 spores in glucose increased, and the lag before its attainment decreased, with increasing germination temperature. The activation energy for germination (μ = approximately 20 kcal/mole), based on rate or on lag, was consistent with an enzymatic mechanism.     

Superdormant Spores of Bacillus Species Have Elevated Wet-Heat Resistance and Temperature Requirements for Heat Activation

Purified superdormant spores of Bacillus cereus, B. megaterium, and B. subtilis isolated after optimal heat activation of dormant spores and subsequent germination with inosine, d-glucose, or l-valine, respectively, germinate very poorly with the original germinants used to remove dormant spores from spore populations, thus allowing isolation of the superdormant spores, and even with alternate germinants. However, these superdormant spores exhibited significant germination with the original or alternate germinants if the spores were heat activated at temperatures 8 to 15°C higher than the optimal temperatures for the original dormant spores, although the levels of superdormant spore germination were not as great as those of dormant spores. Use of mixtures of original and alternate germinants lowered the heat activation temperature optima for both dormant and superdormant spores. The superdormant spores had higher wet-heat resistance and lower core water content than the original dormant spore populations, and the environment of dipicolinic acid in the core of superdormant spores as determined by Raman spectroscopy of individual spores differed from that in dormant spores. These results provide new information about the germination, heat activation optima, and wet-heat resistance of superdormant spores and the heterogeneity in these properties between individual members of dormant spore populations.Spores of Bacillus species are formed in sporulation and are metabolically dormant and extremely resistant to a variety of stress factors (31, 32). While spores can remain dormant for long periods, if given the proper stimulus, they can rapidly “return to life” in the process of spore germination followed by outgrowth (30). Since spores are generally present in significant amounts on many foodstuffs and growing cells of a number of Bacillus species are significant agents of food spoilage and food-borne disease (32), there is continued applied interest in spore resistance and germination. While dormant spores can be killed by a treatment such as wet heat, this requires high temperatures that are costly and detrimental to food quality. Consequently, there has long been interest in triggering spore germination in foodstuffs, since germinated spores have lost the extreme resistance of dormant spores and are relatively easy to kill. However, this strategy has been difficult to apply because of the significant heterogeneity in germination rates between individual spores in populations. One reflection of this heterogeneity is the extremely variable lag times following addition of germinants but prior to initiation of germination events; while these lag times can vary from 10 to 30 min for most spores in populations, some spores have lag times of many hours or even many days (2, 12, 13, 15, 25). The spores that are extremely slow to germinate have been termed superdormant spores, and populations of superdormant spores have recently been isolated from three Bacillus species, and their germination properties characterized (9, 10). These superdormant spores germinate extremely poorly with the original germinants used to remove dormant spores from spore populations, thus allowing superdormant spore isolation, and also poorly with a number of other germinants, in particular, germinants that target nutrient germinant receptors different than those activated to isolate the superdormant spores. However, the superdormant spores germinate reasonably well with mixtures of nutrient germinants that target multiple germinant receptors. All reasons for spore superdormancy are not known, but one contributing factor is the number of nutrient germinant receptors in the spore''s inner membrane that trigger spore germination by binding to nutrient germinants (9). The levels of these receptors are most likely in the tens of molecules per spore (24), and thus stochastic variation in receptor numbers might result in some spores with such low receptor numbers that these spores germinate very poorly (23). Indeed, 20- to 200-fold elevated levels of at least one nutrient germinant receptor greatly decreases yields of superdormant spores of Bacillus subtilis (9).Spores of Bacillus species generally exhibit a requirement for an activation step in order to exhibit maximum germination (17). Usually this activation is a sublethal heat treatment that for a spore population exhibits an optimum of 60 to 100°C depending on the species. Spores are also extremely resistant to wet heat, generally requiring temperatures of 80 to 110°C to achieve rapid spore killing, with the major factor influencing the wet-heat resistance of spores of mesophilic strains being the spore core''s water content, which can be as low as 30% of wet weight as water in a fully hydrated spore (8, 19, 27, 28, 31). Invariably, increases in core water content are associated with a decrease in spore wet-heat resistance (8, 19, 22, 25). While spore populations most often exhibit log-linear kinetics of wet-heat killing, the observation of tailing in such killing curves at high levels of killing is not uncommon, suggesting there is significant heterogeneity in the wet-heat resistances of individual spores in populations (27, 28). While there has been no comparable work suggesting that there is also heterogeneity in the temperature optima for heat activation of individual spores in populations, this certainly seems possible and indeed was suggested as one cause of spore superdormancy, as yields of superdormant spores from spore populations that are not heat activated are much higher (9, 10). Consequently, the current work was initiated to test the hypothesis that superdormant spores require heat activation temperatures that are higher than those of the original dormant spores. Once this was found to be the case, the wet-heat resistance and core water content of the superdormant and original dormant spores were compared, and the environment of the spore core''s major small molecule, pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]) was assessed by Raman spectroscopy of individual spores.     

Germination of Spores of Bacillus cereus in Milk and Milk Dialysates: Effect of Heat Treatment

S ummary . The germination of spores of Bacillus cereus was studied in milk and in media consisting of the low M.W. fraction of milk. Dialysates, centrifugates, filtrates and acid whey supported germination to an extent similar to that in the milk from which they were derived. HTST (72° for 15 sec) pasteurized milk or derived media supported appreciable germination whereas raw milk or media derived from it supported little or none. Whey produced by the action of rennet was an exception in that it was equally stimulatory for germination whether derived from raw or pasteurized milk. Heat treatments for 15 see using temperatures between 65–75° rendered the milk most suitable as a germination medium but temperatures > 80° were necessary for spore activation. Of the 2 effects, activation was the more important; at treatment temperatures > 80° germination was increased despite the less favourable medium which resulted. The extent of germination in pasteurized milk varied with different isolates and could be related to their source, those from pasteurized milk germinating the most readily. The practical implications of these findings are discussed together with the preliminary work to examine the nature of the germination factor(s) produced during HTST pasteurization.     

Monitoring Rates and Heterogeneity of High-Pressure Germination of Bacillus Spores by Phase-Contrast Microscopy of Individual Spores

Germination of Bacillus spores with a high pressure (HP) of ∼150 MPa is via activation of spores'' germinant receptors (GRs). The HP germination of multiple individual Bacillus subtilis spores in a diamond anvil cell (DAC) was monitored with phase-contrast microscopy. Major conclusions were that (i) >95% of wild-type spores germinated in 40 min in a DAC at ∼150 MPa and 37°C but individual spores'' germination kinetics were heterogeneous; (ii) individual spores'' HP germination kinetic parameters were similar to those of nutrient-triggered germination with a variable lag time (T_lag) prior to a period of the rapid release (ΔT_release) of the spores'' dipicolinic acid in a 1:1 chelate with Ca²⁺ (CaDPA); (iii) spore germination at 50 MPa had longer average T_lag values than that at ∼150 MPa, but the ΔT_release values at the two pressures were identical and HPs of <10 MPa did not induce germination; (iv) B. subtilis spores that lacked the cortex-lytic enzyme CwlJ and that were germinated with an HP of 150 MPa exhibited average ΔT_release values ∼15-fold longer than those for wild-type spores, but the two types of spores exhibited similar average T_lag values; and (v) the germination of wild-type spores given a ≥30-s 140-MPa HP pulse followed by a constant pressure of 1 MPa was the same as that of spores exposed to a constant pressure of 140 MPa that was continued for ≥35 min; (vi) however, after short 150-MPa HP pulses and incubation at 0.1 MPa (ambient pressure), spore germination stopped 5 to 10 min after the HP was released. These results suggest that an HP of ∼150 MPa for ≤30 s is sufficient to fully activate spores'' GRs, which remain activated at 1 MPa but can deactivate at ambient pressure.     

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°C, those sporulated at 30°C had the highest resistance to treatments with high hydrostatic pressure (100 to 300 MPa, 55°C, 30 min). Pressure resistance increased after demineralization of the spores and decreased after remineralization of the spores with Ca²⁺ or Mg²⁺, whereas the resistance did not change when spores were remineralized with Mn²⁺ or K⁺, suggesting that former two divalent ions were involved in the activation of cortex-lytic enzymes during germination.     

Initiation of Germination and Inactivation of Bacillus pumilus Spores by Hydrostatic Pressure

The effect of hydrostatic pressures as high as 1,700 atm at 25 C on the heat and radiation resistance of Bacillus pumilus spores was studied. Phosphate-buffered spores were more sensitive to compression than spores suspended in distilled water. Measurements of the turbidity of suspensions, the viability, refractility, stainability, dry weight, and respiratory activity of spores, and calcium and dipicolinic acid release were made for different pressures and times. Initiation of germination occurred at pressures exceeding 500 atm and was the prerequisite for inactivation by compression. The rate of initiation increased with increasing pressure at constant temperature. This result is interpreted as a net decrease in the volume of the system during initiation as a result of increased solvation of the spore components.     

Chromosomes in Bacillus subtilis Spores and Their Segregation During Germination

Spores of a thymine-requiring mutant of Bacillus subtilis 168 leucine(-), indole(-), thymine(-)) were uniformly labeled with (3)H-thymidine. These were seeded on thinlayer agar plates where they germinated into long-chained microcolonies. Autoradiograms were used to measure the distribution of labeled deoxyribonucleic acid in the chains of cells, which ranged in length from 2 to 32 cells. Four major grain clusters appeared in most chains. These clusters were homogeneous in size; their grain numbers were distributed symmetrically from 9 to 15 with an average of 12.0. When three or fewer major clusters appeared in short chains, some of them were composed of two subclusters. However, there were always four clusters per chain when these subclusters were counted as individuals. Groupings containing two to eight grains appeared, as well as the four major clusters in longer chains. These minor groups were fragments of the major clusters. In contrast to the symmetrical distribution of major clusters, fragmented clusters were distributed at random, indicating random fragmentation. The total number of major and minor clusters increased at a constant exponential rate when measured against total cell number per chain, i.e., number of generations. It was calculated from the rate that a detectable fragmentation, at least 16% of a conserved unit (defined as a single strand of the complete chromosome), occurred every 6.0 generations. These results led us to conclude that each B. subtilis spore contained four conserved units or two completed chromosomes. Segregation of the four units into progeny cells was almost random. The one notable exception was a conserved unit which frequently appeared in a terminal cell to which an empty spore coat was attached. The presence of two chromosomes in the spore is consistent with our proposed structure of the completed chromosome, in which two sister chromosomes are covalently linked at the initiation region. This double chromosome may be incorporated into the spore without further structural change.     

Resistance and Structure of Spores of Bacillus subtilis

Spores of Bacillus subtilis NCDO 2130 were produced on five different media and their structure and resistance to chemicals, to heat and to ultraviolet (uv) irradiation compared. Resistance to one chemical was not necessarily related to resistance to another, to uv irradiation or to heat. Spores with the smallest protoplasts and largest cortices were most resistant to heat, while the least resistant were those in which the protoplasts became electron dense after staining and which had the lowest concentrations of calcium and dipicolinic acid.     

Rhythmic Changes in Dry Heat Resistance of Bacillus subtilis Spores After Rapid Changes in pH

Heat resistance of freeze-dried Bacillus subtilis spores varied in a rhythmic manner as a function of time between acidification to about pH 1.5 and freezing. A comparable rapid shift to pH 11 produced little change in resistance to heat.     

Role of Disulphide Bonds in the Resistance of Bacillus cereus Spores to Gamma Irradiation and Heat

S ummary . Spores of Bacillus cereus were treated with thioglycollic acid which ruptures at least 10–30% of the spore disulphide bonds by reducing them to thiol groups. The treated spores were still viable and were sensitive to lysozyme but remained as resistant to γ-irradiation and to heat as untreated spores. Neither treated nor untreated spores were sensitized to irradiation by reagents which block thiol groups. The results did not indicate that the high content of disulphide bonds in spore coat protein protects spores against inactivation by irradiation or heat.