Effect of Water Activities of Heating and Recovery Media on Apparent Heat Resistance of Bacillus cereus Spores

Spores of Bacillus cereus were heated and recovered in order to investigate the effect of water activity of media on the estimated heat resistance (i.e., the D value) of spores. The water activity (ranging from 0.9 to 1) of the heating medium was first successively controlled with three solutes (glycerol, glucose, and sucrose), while the water activity of the recovery medium was kept near 1. Reciprocally, the water activity of the heating medium was then kept at 1, while the water activity of the recovery medium was controlled from 0.9 to 1 with the same depressors. Lastly, in a third set of experiments, the heating medium and the recovery medium were adjusted to the same activity. As expected, added depressors caused an increase of the heat resistance of spores with a greater efficiency of sucrose with respect to glycerol and glucose. In contrast, when solutes were added to the recovery medium, under an optimal water activity close to 0.98, a decrease of water activity caused a decrease in the estimated D values. This effect was more pronounced when sucrose was used as a depressor instead of glycerol or glucose. When the heating and the recovery media were adjusted to the same water activity, a balancing effect was observed between the protective influence of the solutes during heat treatment and their negative effect during the recovery of injured cells, so that the overall effect of water activity was reduced, with an optimal value near 0.96. The difference between the efficiency of depressors was also less pronounced. It may then be concluded that the overall protective effect of a decrease in water activity is generally overestimated.     

The Effect of Water Activity and the aw Controlling Solute on Spore Germination of Bacillus stearothermophilus

The germination of spores of Bacillus stearothermophilus was studied in nutrient broth in relation to the water activity ( a _w) of the medium, the nature of the a _w controlling solutes glycerol, sucrose, KCl, and NaCl, and temperature. Quantitation of germination was based on the change of the phase-bright spore to phase-dark. Activation of spores was by exposure to 100°C/10 min in a medium of the same composition as that used for germination.
Of the four solutes used, sucrose proved most inhibitory to germination, especially in the upper part of the temperature range 38-75°C, glycerol was the most favourable whereas KCl and NaCl, whose effect was almost identical, occupied an intermediate place. The glycerol effect became more pronounced as the a _w of the medium decreased towards 0.960, becoming inhibitory thereafter.
The solute effect on spore germination followed a pattern that related to the class of solute, i.e. electrolyte or non-electrolyte, and its cell penetration characteristics.
Solute penetration during heat activation and germination was considered as the major germination factor and was associated with the osmoregulation mechanism within the spore proposed recently as the basis of spore dormancy and resistance.     

Effect of the osmotic conditions during sporulation on the subsequent resistance of bacterial spores

The causes of Bacillus spore resistance remain unclear. Many structures including a highly compact envelope, low hydration of the protoplast, high concentrations of Ca-chelated dipicolinic acid, and the presence of small acid-soluble spore proteins seem to contribute to resistance. To evaluate the role of internal protoplast composition and hydration, spores of Bacillus subtilis were produced at different osmotic pressures corresponding to water activities of 0.993 (standard), 0.970, and 0.950, using the two depressors (glycerol or NaCl). Sporulation of Bacillus subtilis was slower and reduced in quantity when the water activity was low, taking 4, 10, and 17 days for 0.993, 0.970, and 0.950 water activity, respectively. The spores produced at lower water activity were smaller and could germinate on agar medium at lower water activity than on standard spores. They were also more sensitive to heat (97 degrees C for 5-60 min) than the standard spores but their resistance to high hydrostatic pressure (350 MPa at 40 degrees C for 20 min to 4 h) was not altered. Our results showed that the water activity of the sporulation medium significantly affects spore properties including size, germination capacity, and resistance to heat but has no role in bacterial spore resistance to high hydrostatic pressure.     

Effect of Water Activity on Heat Survival of Staphylococcus aureus, Salmonella typhimurium and Salm. senftenberg

The viability of Staphylococcus aureus heated at 55° in phosphate buffer was determined on recovery media of different water activity ( a_w ) levels. The basal recovery medium, tryptone–soya agar ( a_w 0.997) was adjusted to lower a_w levels by the addition of NaCl, glycerol or sucrose. Maximum survival occurred at a_w 0.997. Viability was reduced to 1/10 of the maximum at a_w 0.98 when a_w , was controlled by sucrose or NaCl but not until a_w 0.93 with glycerol. To eliminate effects such as incomplete mixing or post-heating dilution and in order to use conditions comparable to those occurring in foods, a solid medium heating/recovery method was also used. This involved heating, by immersion, of surface-inoculated agar plates and recovery of survivors in situ . Heat resistance studies could thus only be carried out at a_w levels permitting growth on the heating/recovery medium. Staphylococcus aureus, Salmonella typhimurium and Salm. senftenberg 775W were heated at 55° and recovered in situ on tryptone-soya agar adjusted to lower a_w levels as above. Maximum survival of Staph. aureus occurred at a higher a_w with glycerol ( a_w 0.965) than with NaCl (0.92) or sucrose (0.90). The maximum survival of both Salm. typhimurium and Staph. aureus heated at 55° occurred at the same a_w (0.965) with glycerol. This maximum was not affected by the duration of heating. As a contrast, heat resistance of Salm. senftenberg 775W was virtually unaffected by reduction in the a_w of the heating/recovery medium.     

The Effect of Sugars and Polyols on the Heat Resistance of Salmonellae

S ummary . The heat resistance at 65° of 3 strains of salmonellae in solutions of sugars or polyols was enhanced as the concentration of the solutes increased. There was no linear relationship between heat resistance and water activity ( a_w ), but for all solutes except glycerol there was a linear relationship between log D ₆₅ and concentration (% w/w) of solute. Comparison of D ₆₅ at a particular a_w or percentage (w/w) solute concentration showed that the value decreased in the order: sucrose > glucose > sorbitol > fructose > glycerol. In glycerol, D ₆₅ values were always very much lower than in any other solute. With sucrose–glycerol or sucrose–glucose mixtures, heat resistance depended both on the total concentration (% w/w) of solutes present and also on the a_w of the solution.     

Enhancement effect of water activity on enzymatic synthesis of cephalexin

The effect of water activity (a(w)) of the reaction medium on the enzymatic synthesis of cephalexin (CEX) from 7-amino-3-deacetoxycephalosporanic acid (7-ADCA) and D-alpha-phenylglycine methyl ester (PGM) was investigated using the alpha-amino acid ester hydrolase enzyme from Xanthomonas citri. It was found that the synthetic activity of the enzyme and the conversion yield were markedly improved when the a(w) of the reaction medium was lowered to about 0.97. The water activity depressing agents evaluated were glycerol, sucrose, and sorbitol, and the conversion yields were improved up to 170% with 15% glycerol, 230% with 30% sucrose, and 270% with 20% sorbitol, respectively. The extent of favorable effect of a(w) on the conversion yield was not the same among the a(w) depressors, probably due to other unknown interactions between the enzyme and depressors. However, optimal a(w) values corresponding to the maximum conversion yield coincided for all a(w) depressors used. The conversion yield of CEX showed an increasing trend with increasing a(w) up to the optimal a(w) value (0.96-0.97) which corresponds to the maximum conversion yield and a decreasing trend beyond the optimal a(w). There appears to be a delicate balance between the hydrolytic reaction of PGM and synthetic reaction of CEX. The increasing a(w)-[E . PGM] complex and the branched reaction pathway fluxes from [E . PGM] to PG (D-alpha-phenyl glycine) and CEX are balanced in such a way that the maximum CEX conversion yield is obtained at a(w) value of 0.96-0.97. The a(w) depressors stabilized the enzyme somewhat, but this positive effect was considered to be only a minor contribution to the substantial yield enhancement. The a(w) depressor effect on viscosity and in turn the mass transfer rate limitation was ruled out since the change in conversion due to the viscosity change was found to be insignificant. (c) 1993 John Wiley & Sons, Inc.     

Reversal of radiation-dependent heat sensitization of Clostridium perfringens spores.

The effect of solute concentration on the sensitization of Clostridium perfringens spores to heat by ionizing radiation was investigated. As we have shown previously, spores of C. perfringens treated with gamma radiation are now sensitive to subsequent heat treatments than are spores that receive no radiation treatment. When gamma-irradiated spores were heated in the presence of increasing concentrations of glycerol or sucrose, the heat sensitivity induced by irradiation was progressively decreased. The magnitude of the increase in heat resistance induced by extracellular solutes was greater in gamma-irradiated spores than in nonirradiated spores. Based on these observations, it is proposed that the induction of heat sensitivity in spores by radiation is related to the loss of osmoregulatory or dehydrating mechanisms in irradiated spores.     

Reversal of radiation-dependent heat sensitization of Clostridium perfringens spores

The effect of solute concentration on the sensitization of Clostridium perfringens spores to heat by ionizing radiation was investigated. As we have shown previously, spores of C. perfringens treated with gamma radiation are now sensitive to subsequent heat treatments than are spores that receive no radiation treatment. When gamma-irradiated spores were heated in the presence of increasing concentrations of glycerol or sucrose, the heat sensitivity induced by irradiation was progressively decreased. The magnitude of the increase in heat resistance induced by extracellular solutes was greater in gamma-irradiated spores than in nonirradiated spores. Based on these observations, it is proposed that the induction of heat sensitivity in spores by radiation is related to the loss of osmoregulatory or dehydrating mechanisms in irradiated spores.     

Sugar and Polyol Permeability of Salmonella and Osmophilic Yeast Cell Membranes Measured by Turbidimetry, and its Relation to Heat Resistance

Studies of turbidity of Salmonella typhimurium 7M 4987 and of two osmophilic yeasts ( Saccharomyces rouxii NCYC 381 and Schizosaccharomyces pombe NCYC 380) in solutions of sucrose, glucose, fructose, sorbitol and glycerol up to 0·5 molal indicate that the extent by which turbidity (a measure of the degree of plasmolysis) increases correlates well with the degree of protection afforded by the solutes (at higher concentration) during heating at 65·. These results support the hypothesis that degree of protection of the solutes can be correlated with degree of plasmolysis or cell shrinkage, indicating that heat resistance is associated more with dehydration of the cell than with replacement of cell water by solutes.     

Physiological response of Pseudomonas putida S12 subjected to reduced water activity

Abstract The effect of osmotic stress, given as decreased water activity (a_w), on growth and the accumulation of potassium and the compatible solute betaine by Pseudomonas putida S12 was investigated. Reduced a_w was imposed by addition of sodium chloride, sucrose, glycerol or polyethylene glycol to the growth medium. Accumulation of potassium and betaine was established when sodium chloride and sucrose were used to cause osmotic stress. No accumulation of these solutes was found in the presence of glycerol. Addition of polyethylene glycol to the medium strongly decreased the growth rate in comparison with the other osmolytes tested at the corresponding a_w. Although polyethylene glycol did decrease the a_w, neither potassium nor betaine was accumulated by the cells.     

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.     

The Effect of Water Activity and aw-Controlling Solute on Sporulation of Bacillus cereus

The influence of water activity (aw) on the formation of phase bright, heat stable, and dipicoiir.ic acid-containing spores of Bacillus cereus T from stage III to stage IV forespores has beer. investigated. Decreasing a_w levels reduced the rate of sporulation and the number of forespores which lysed was determined by the a_w-controlling solute used. The limiting a_w value for ir.e formation of mature spores was about 0·95 for glucose, sorbitol and NaCl whereas it was about 0·91 for glycerol. The development of refractility. the synthesis of dipicolinic acid, and acquisition of heat stability were affected equally by decrease in a_w during sporulation. With the range of a_w value where spores could be formed NaCl and glycerol had no signifcant: influence on the D value of the resulting spores whereas at all a_w levels, when sorbitol was use: as the a_w-controlling solute, the heat resistance was greater than in the basal medium. It Is suggested that the a_w of the sporulation medium determines the quantity of spores rather than. the spore properties.     

The Effect of Water Activity on the Growth and Respiration of Pseudomonas fluorescens

The growth rate of Pseudomonas fluorescens was greater and continued at lower water activity ( a _w) values when glycerol controlled the a _w of glucose minimal medium than when the a _w was controlled by NaCl and sucrose. Growth was not observed below 0·945, 0·970 and 0·964 a _w when glycerol, sucrose and NaCl respectively controlled the a _w. The catabolism of glucose, Na lactate and DL-arginine as measured by respirometry was completely inhibited at a _w values greater than the minimum for growth when the a _w was controlled with NaCl. When the a _w was controlled with glycerol, catabolism of the three substrates continued at a _w values significantly below the a _w for growth on glucose. Catabolism of glucose in the presence of sucrose occurred at a level below the minimum growth a _w but catabolism of the other two substrates ceased at a _w values greater than the minimum growth a _w. Arrhenius plots between 10° and 34°C of the growth rate in glucose minimal medium at 0·98 a _w showed that the order of inhibition was sucrose > NaCl > glycerol. The order of inhibition differed when Arrhenius plots of catabolism of glucose was examined between 10° and 34 °C, namely NaCl > sucrose > glycerol. The mechanism of action of solutes controlling a _w is discussed.     

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.     

Recovery of Viability and Radiation Resistance by Heat-Injured Conidia of Penicillium expansum Lk. ex Thom

Spores heated in water at 54 C for up to 1 hr were plated on nutrient agar immediately or held for 3 days in aerated water at 23 C and then plated. Under these conditions, holding was optimal for recovery, increasing survival percentage up to 20-fold over values for immediate plating. Recovery was prevented partially or completely, however, when spores were held in any of the following solutions: glucose, potassium phosphate, ammonium or sodium acetate, sodium azide, or 2,4-dinitrophenol, or in the sodium or potassium salts of pyruvate, and tricarboxylic acid cycle acids. Both anaerobiosis and incubation at 0 C prevented recovery. Survivors of a heat treatment were more sensitive to gamma radiation than were unheated spores. Conditions which affected the recovery of viability had the same effect on restoration of radiation resistance. Thus, many of the processes for restoration of radiation resistance seem involved also in recovery of viability after heating. After a 99% inactivating treatment (about 30 min at 54 C), heated spores respired as fast as unheated spores, or faster. Malate, citrate, succinate, and acetate stimulated respiration in unheated spores and inhibited it in heated spores.     

Solute stresses affect growth patterns, endogenous water potentials and accumulation of sugars and sugar alcohols in cells of the biocontrol yeast Candida sake

AIM: To evaluate the effect of modifications of water activity (aw 0. 996-0.92) of a molasses medium with different solutes (glycerol, glucose, NaCl, proline or sorbitol) on growth, intracellular water potentials (psi(c)) and endogenous accumulation of polyols/sugars in the biocontrol yeast Candida sake. METHODS AND RESULTS: Modification of solute stress significantly influenced growth, psi(c) and accumulation of sugars (glucose/trehalose) and polyols (glycerol, erythritol, arabitol and mannitol) in the yeast cells. Regardless of the solute used to modify aw, growth was always decreased as water stress increased. Candida sake cells grew better in glycerol- and proline-amended media, but were sensitive to NaCl. The psi(c) measured using psychrometry showed a significant effect of solutes, aw and time. Cells from the 0.96 aw NaCl treatment presented the lowest psic value (- 5.20 MPa) while cells from unmodified media (aw = 0. 996) had the highest value (- 0.30 MPa). In unmodified medium, glycerol was the predominant reserve accumulated. Glycerol and arabitol were the major compounds accumulated in media modified with glucose or NaCl. In proline media, the concentration of arabitol increased. In glycerol- and sorbitol-amended media, the concentration of glycerol rose. Some correlations were obtained between compatible solutes and psi(c). CONCLUSIONS AND SIGNIFICANCE: This study demonstrates that subtle changes in physiological parameters significantly affect the endogenous contents of C. sake cells. It may be possible to utilize such physiological information to develop biocontrol inocula with improved quality.     

Analysis of carbohydrate metabolism enzymes and cellular contents of sugars and proteins during spruce somatic embryogenesis suggests a regulatory role of exogenous sucrose in embryo development.

Carbohydrate metabolism was investigated during spruce somatic embryogenesis. During the period of maintenance corresponding to the active phase of embryogenic tissue growth, activities of soluble acid invertase and alkaline invertase increased together with cellular glucose and fructose levels. During the same time, sucrose phosphate synthase (SPS) activity increased while sucrose synthase (SuSy) activity stayed constant together with the cellular sucrose level. Therefore, during maintenance, invertases were thought to generate the hexoses necessary for embryogenic tissue growth while SuSy and SPS would allow cellular sucrose to be kept at a constant level. During maturation on sucrose-containing medium, SuSy and SPS activities stayed constant whereas invertase activities were high during the early stage of maturation before declining markedly from the second to the fifth week. This decrease of invertase activities resulted in a decreased hexose:sucrose ratio accompanied by starch and protein deposition. Additionally, carbohydrate metabolism was strongly modified when sucrose in the maturation medium was replaced by equimolar concentrations of glucose and fructose. Essentially, during the first 2 weeks, invertase activities were low in tissues growing on hexose-containing medium while cellular glucose and fructose levels increased. During the same period, SuSy activity increased while the SPS activity stayed constant together with the cellular sucrose level. This metabolism reorganization on hexose-containing medium affected cellular protein and starch levels resulting in a decrease of embryo number and quality. These results provide new knowledge on carbohydrate metabolism during spruce somatic embryogenesis and suggest a regulatory role of exogenous sucrose in embryo development.     

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.     

Effect of heat and ultrasonic waves on the survival of two strains of Bacillus subtilis

The combined effect of ultrasonic (20 KHz, 150 W) and heat treatment on the survival of two strains of Bacillus subtilis in three suspending media (distilled water, glycerol and milk) has been studied. When spores suspended in water or milk were subjected to ultrasonic waves before heat treatments a little or no decrease of the heat resistance was observed. However, both sporicidal agents applied simultaneously (thermo-ultrasonication) decreased by 63% (B. subtilis, var. niger-40) and 74% (B. subtilis ATCC 6051) the decimal reduction times for the heat treatment when the spores were suspended in glycerol and by 79% and 40%, respectively when suspended in milk. The thermo-ultrasonication of spores in water markedly reduced the heat resistance of them (between 99.9% and 70%) in the range 70-95 degrees C but the effect of the thermo-ultrasonication significantly diminished as the temperature of the treatment was approached to the boiling point of the water.     

Energy flux and osmoregulation of Saccharomyces cerevisiae grown in chemostats under NaCl stress.

The energetics and accumulation of solutes in Saccharomyces cerevisiae were investigated for cells grown aerobically in a chemostat under NaCl stress and glucose limitation. Changed energy requirements in relation to external salinity were examined by energy balance determinations performed by substrate and product analyses, with the latter including heat measurements by microcalorimetry. In both 0 and 0.9 M NaCl cultures, the catabolism was entirely respiratory at the lowest dilution rates tested but shifted to a mixed respiratory-fermentative metabolism at higher dilution rates. This shift occurred at a considerably lower dilution rate for salt-grown cells. The intracellular solute concentrations, as calculated on the basis of intracellular soluble space determinations, showed that the internal Na+ concentration increased from about 0.02 molal in basal medium to about 0.18 molal in 0.9 M NaCl medium, while intracellular K+ was maintained around 0.29 molal despite the variation in external salinity. The intracellular glycerol concentration increased from below 0.05 molal at low salinity to about 1.2 molal at 0.9 M NaCl. The concentrations of the internal solutes, however, changed insignificantly with growth rate and energy metabolism. The additional maintenance energy expenditure for growth at 0.9 M NaCl was, depending on the growth rate, 14 to 31% of the total energy requirement for growth at 0 M NaCl. Including the energy conserved in glycerol, the total additional energy demand for growth at 0.9 M NaCl corresponded to 28 to 51% of the energy required for growth at 0 M NaCl.