Permeabilization and inhibition of the germination of spores of Aspergillus niger for gluconic acid production from glucose

In this study, the role of citral to permeabilize the spores of Aspergillus niger and replace sodium azide in the bioconversion medium was studied. Further, characterization of glucose oxidase of spores was carried out by exposing both permeabilized and unpermeabilized spores to different pressures (1, 2, 2.7 kb) and temperatures (60, 70, 80, 90 degrees C). Unpermeabilized spores after exposure to high temperatures were permeabilized by freezing before using as catalyst in the bioconversion reaction. Results showed that citral permeabilized the spores and could inhibit spore germination in the bioconversion medium. Rate of reaction was significantly increased from 1.5 to 4.35 g/Lh which was higher than the commercial glucose oxidase 2g/Lh). Glucose oxidase activity of A. niger was resistant to pressure. However, pressure treatment could not permeabilize them. Behaviour of fresh and permeabilized spores to temperature varied significantly. Glucose oxidase activity of fresh spores exposed to high temperature was unaffected at 70 degrees C till 15 min and 84% of relative activity was retained even after 1h at 70 degrees C while permeabilized spore got inactivated at 70 degrees C for 15 min, which followed the same pattern as commercial glucose oxidase. Cellular membrane integrity was lost due to permeabilization by freezing which resulted in heat-inactivation of glucose oxidase when spores were permeabilized before heat treatment. Thus, glucose oxidase of spore remains heat stable when unpermeabilized and active while permeabilized and its reaction rate is higher than the commercial glucose oxidase.     

Combined effects of high hydrostatic pressure and temperature for inactivation of Bacillus anthracis spores

Spores of Bacillus anthracis are known to be extremely resistant to heat treatment, irradiation, desiccation, and disinfectants. To determine inactivation kinetics of spores by high pressure, B. anthracis spores of a Sterne strain-derived mutant deficient in the production of the toxin components (strain RP42) were exposed to pressures ranging from 280 to 500 MPa for 10 min to 6 h, combined with temperatures ranging from 20 to 75 degrees C. The combination of heat and pressure resulted in complete destruction of B. anthracis spores, with a D value (exposure time for 90% inactivation of the spore population) of approximately 4 min after pressurization at 500 MPa and 75 degrees C, compared to 160 min at 500 MPa and 20 degrees C and 348 min at atmospheric pressure (0.1 MPa) and 75 degrees C. The use of high pressure for spore inactivation represents a considerable improvement over other available methods of spore inactivation and could be of interest for antigenic spore preparation.     

Cold shock response in sporulating Bacillus subtilis and its effect on spore heat resistance

Cold shock and ethanol and puromycin stress responses in sporulating Bacillus subtilis cells have been investigated. We show that a total of 13 proteins are strongly induced after a short cold shock treatment of sporulating cells. The cold shock pretreatment affected the heat resistance of the spores formed subsequently, with spores heat killed at 85 or 90 degrees C being more heat resistant than the control spores while they were more heat sensitive than controls that were heat treated at 95 or 100 degrees C. However, B. subtilis spores with mutations in the main cold shock proteins, CspB, -C, and -D, did not display decreased heat resistance compared to controls, indicating that these proteins are not directly responsible for the increased heat resistance of the spores. The disappearance of the stress proteins later in sporulation suggests that they cannot be involved in repairing heat damage during spore germination and outgrowth but must alter spore structure in a way which increases or decreases heat resistance. Since heat, ethanol, and puromycin stress produce similar proteins and similar changes in spore heat resistance while cold shock is different in both respects, these alterations appear to be very specific.     

Heat stability of Bacillus cereus enzymes within spores and in extracts.

Inactivation rates for nine enzymes extracted from Bacillus cereus spores were measured at several temperatures, and the temperature at which each enzyme had a half-life of 10 min (inactivation temperature) was determined. Inactivation temperatures ranged from 47 degrees C for glucose 6-phosphate dehydrogenase to 70 degrees C for leucine dehydrogenase, showing that spore enzymes were not unusually heat stable. Enzymes extracted from vegetative cells of B. cereus had heat stabilities similar to the respective enzymes from spores. When spores were heated and the enzymes were subsequently extracted and assayed, inactivation temperatures for enzymes within the spore ranged from 86 degrees C for glucose 6-phosphate dehydrogenase to 96 degrees C for aldolase. The internal environment of the spore raised the inactivation temperature of most enzymes by approximately 38 degrees C. Loss of dipicolinic acid from spores was initially slow compared with enzyme inactivation but increased rapidly with longer heating. Viability loss was faster than loss of most enzyme activities and faster than dipicolinic acid release.     

Inactivation of Bacillus piliformis spores by heat and certain chemical disinfectants

The inactivation of Tyzzer's organism (Bacillus piliformis) spore isolated from rats by heat and various chemical disinfectants was studied. The spores were from B. piliformis-infected rat liver tissues. The spore suspension (10(4) 50% of rat liver lesion producing dose with prednisolone treatment/ml) was treated with heart or disinfectants. Inactivation of the spores was examined in experimentally infected rats. Rats were inoculated perorally with a treated spore suspension and injected subcutaneously with prednisolone. On the sixth day after inoculation, rats were examined grossly for liver lesions. Spores were inactivated at 80 degrees C for 15 min but not at 60 degrees C for 30 min. Spores were inactivated by 0.4% peracetic acid, 0.015% sodium hypochrolite, 1% iodophol, 5% phenol. Alcide and 0.37% formaldehyde solution, but not by 0.037% formaldehyde solution, 70% ethanol, 0.3% benzethonium chloride solution, 3% cresol and soap solution, or 4% chlorhexidine digluconate. These findings suggest that B. piliformis spores are relatively sensitive to heat and certain chemical disinfectants.     

Effect of heat treatment on survival of, and growth from, spores of nonproteolytic Clostridium botulinum at refrigeration temperatures.

Spores of five type B, five type E, and two type F strains of nonproteolytic Clostridium botulinum were inoculated into tubes of an anaerobic meat medium plus lysozyme to give approximately 10(6) spores per tube. Sets of tubes were then subjected to a heat treatment, cooled, and incubated at 6, 8, 10, 12, and 25 degrees C for up to 60 days. Treatments equivalent to heating at 65 degrees C for 364 min, 70 degrees C for 8 min, and 75 degrees C for 27 min had little effect on growth and toxin formation. After a treatment equivalent to heating at 85 degrees C for 23 min, growth occurred at 6 and 8 degrees C within 28 to 40 days. After a treatment equivalent to heating at 80 degrees C for 19 min, growth occurred in some tubes at 6, 8, 10, or 12 degrees C within 28 to 53 days and at 25 degrees C in all tubes within 15 days. Following a treatment equivalent to heating at 95 degrees C for 15 mine, growth was detected in some tubes incubated at 25 degrees C for fewer than 60 days but not in tubes incubated at 6 to 12 degrees C. The results indicate that heat treatment of processed foods equivalent to maintenance at 85 degrees C for 19 min combined with storage below 12 degrees C and a shelf life of not more than 28 days would reduce the risk of growth from spores of nonproteolytic C. botulinum by a factor of 10(6).(ABSTRACT TRUNCATED AT 250 WORDS)     

Novel strains of Moorella thermoacetica form unusually heat-resistant spores

Two strains of Moorella thermoacetica, JW/B-2 and JW/DB-4, isolated as contaminants from autoclaved media for chemolithoautotrophic growth containing 0.1% (wt/vol) yeast extract, formed unusually heat-resistant spores. Spores of the two strains required heat activation at 100 degrees C of more than 2 min and up to 90 min for maximal percentage of germination. Kinetic analysis indicated the presence of two distinct subpopulations of heat-resistant spores. The decimal reduction time (D10-time=time of exposure to reduce viable spore counts by 90%) at 121 degrees C was determined for each strain using spores obtained under different conditions. For strains JW/DB-2 and JW/ DB-4, respectively, spores obtained at approximately 25 degrees C from cells grown chemolithoautotrophically had D10-times of 43 min and 23 min; spores obtained at 60 degrees C from cells grown chemoorganoheterotrophically had D10-times of 44 min and 38 min; spores obtained at 60 degrees C from cells grown chemolithoautotrophically had D10-times of 83 min and 111 min. The thickness of the cortex varied between 0.10 and 0.29 microm and the radius of the cytoplasm from 0.14 to 0.46 microm. These spores are amongst the most heat-resistant noted to date. Electron microscopy revealed structures within the exosporia of spores prior to full maturity that were assumed to be layers of the outer spore coat.     

Prevention of DNA damage in spores and in vitro by small, acid-soluble proteins from Bacillus species.

The DNA in dormant spores of Bacillus species is saturated with a group of nonspecific DNA-binding proteins, termed alpha/beta-type small, acid-soluble spore proteins (SASP). These proteins alter DNA structure in vivo and in vitro, providing spore resistance to UV light. In addition, heat treatments (e.g., 85 degrees C for 30 min) which give little killing of wild-type spores of B. subtilis kill > 99% of spores which lack most alpha/beta-type SASP (termed alpha - beta - spores). Similar large differences in survival of wild-type and alpha - beta - spores were found at 90, 80, 65, 22, and 10 degrees C. After heat treatment (85 degrees C for 30 min) or prolonged storage (22 degrees C for 6 months) that gave > 99% killing of alpha - beta - spores, 10 to 20% of the survivors contained auxotrophic or asporogenous mutations. However, alpha - beta - spores heated for 30 min at 85 degrees C released no more dipicolinic acid than similarly heated wild-type spores (< 20% of the total dipicolinic acid) and triggered germination normally. In contrast, after a heat treatment (93 degrees C for 30 min) that gave > or = 99% killing of wild-type spores, < 1% of the survivors had acquired new obvious mutations, > 85% of the spore's dipicolinic acid had been released, and < 1% of the surviving spores could initiate spore germination. Analysis of DNA extracted from heated (85 degrees C, 30 min) and unheated wild-type spores and unheated alpha - beta - spores revealed very few single-strand breaks (< 1 per 20 kb) in the DNA. In contrast, the DNA from heated alpha- beta- spores had more than 10 single-strand breaks per 20 kb. These data suggest that binding of alpha/beta-type SASP to spore DNA in vivo greatly reduces DNA damage caused by heating, increasing spore heat resistance and long-term survival. While the precise nature of the initial DNA damage after heating of alpha- beta- spores that results in the single-strand breaks is not clear, a likely possibility is DNA depurination. A role for alpha/beta-type SASP in protecting DNA against depurination (and thus promoting spore survival) was further suggested by the demonstration that these proteins reduce the rate of DNA depurination in vitro at least 20-fold.     

Inactivation of Geobacillus stearothermophilus spores by high-pressure carbon dioxide treatment

High-pressure CO2 treatment has been studied as a promising method for inactivating bacterial spores. In the present study, we compared this method with other sterilization techniques, including heat and pressure treatment. Spores of Bacillus coagulans, Bacillus subtilis, Bacillus cereus, Bacillus licheniformis, and Geobacillus stearothermophilus were subjected to CO2 treatment at 30 MPa and 35 degrees C, to high-hydrostatic-pressure treatment at 200 MPa and 65 degrees C, or to heat treatment at 0.1 MPa and 85 degrees C. All of the bacterial spores except the G. stearothermophilus spores were easily inactivated by the heat treatment. The highly heat- and pressure-resistant spores of G. stearothermophilus were not the most resistant to CO2 treatment. We also investigated the influence of temperature on CO2 inactivation of G. stearothermophilus. Treatment with CO2 and 30 MPa of pressure at 95 degrees C for 120 min resulted in 5-log-order spore inactivation, whereas heat treatment at 95 degrees C for 120 min and high-hydrostatic-pressure treatment at 30 MPa and 95 degrees C for 120 min had little effect. The activation energy required for CO2 treatment of G. stearothermophilus spores was lower than the activation energy for heat or pressure treatment. Although heat was not necessary for inactivationby CO2 treatment of G. stearothermophilus spores, CO2 treatment at 95 degrees C was more effective than treatment at 95 degrees C alone.     

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.     

The effect of various heat activation treatments on fast, intermediate and slow germinating spores of Bacillus spp.

Fast, intermediate and slow germinating Bacillus spp., isolated from raw milk supplies, were subjected to activation treatments of 80C/10 min, 9C/10 min, 100C/1 min and 100C/10 min. Significant differences were observed between the three spore types at all activation treatments with 80C/10 min giving the highest overall germination rate. The 80C/10 min activation treatment, which is the most commonly used, also favoured germination of the fast germinating spores to a greater extent than the other spore types. The detection of such spores is important because they have the greatest spoilage potential.     

Thermal inactivation of nonproteolytic Clostridium botulinum type E spores in model fish media and in vacuum-packaged hot-smoked fish products

Thermal inactivation of nonproteolytic Clostridium botulinum type E spores was investigated in rainbow trout and whitefish media at 75 to 93 degrees C. Lysozyme was applied in the recovery of spores, yielding biphasic thermal destruction curves. Approximately 0.1% of the spores were permeable to lysozyme, showing an increased measured heat resistance. Decimal reduction times for the heat-resistant spore fraction in rainbow trout medium were 255, 98, and 4.2 min at 75, 85, and 93 degrees C, respectively, and those in whitefish medium were 55 and 7.1 min at 81 and 90 degrees C, respectively. The z values were 10.4 degrees C in trout medium and 10.1 degrees C in whitefish medium. Commercial hot-smoking processes employed in five Finnish fish-smoking companies provided reduction in the numbers of spores of nonproteolytic C. botulinum of less than 10(3). An inoculated-pack study revealed that a time-temperature combination of 42 min at 85 degrees C (fish surface temperature) with >70% relative humidity (RH) prevented growth from 10(6) spores in vacuum-packaged hot-smoked rainbow trout fillets and whole whitefish stored for 5 weeks at 8 degrees C. In Finland it is recommended that hot-smoked fish be stored at or below 3 degrees C, further extending product safety. However, heating whitefish for 44 min at 85 degrees C with 10% RH resulted in growth and toxicity in 5 weeks at 8 degrees C. Moist heat thus enhanced spore thermal inactivation and is essential to an effective process. The sensory qualities of safely processed and more lightly processed whitefish were similar, while differences between the sensory qualities of safely processed and lightly processed rainbow trout were observed.     

Assessment of heat resistance of bacterial spores from food product isolates by fluorescence monitoring of dipicolinic acid release

This study is aimed at the development and application of a convenient and rapid optical assay to monitor the wet-heat resistance of bacterial endospores occurring in food samples. We tested the feasibility of measuring the release of the abundant spore component dipicolinic acid (DPA) as a probe for heat inactivation. Spores were isolated from the laboratory type strain Bacillus subtilis 168 and from two food product isolates, Bacillus subtilis A163 and Bacillus sporothermodurans IC4. Spores from the lab strain appeared much less heat resistant than those from the two food product isolates. The decimal reduction times (D values) for spores from strains 168, A163, and IC4 recovered on Trypticase soy agar were 1.4, 0.7, and 0.3 min at 105 degrees C, 120 degrees C, and 131 degrees C, respectively. The estimated Z values were 6.3 degrees C, 6.1 degrees C, and 9.7 degrees C, respectively. The extent of DPA release from the three spore crops was monitored as a function of incubation time and temperature. DPA concentrations were determined by measuring the emission at 545 nm of the fluorescent terbium-DPA complex in a microtiter plate fluorometer. We defined spore heat resistance as the critical DPA release temperature (Tc), the temperature at which half the DPA content has been released within a fixed incubation time. We found Tc values for spores from Bacillus strains 168, A163, and IC4 of 108 degrees C, 121 degrees C, and 131 degrees C, respectively. On the basis of these observations, we developed a quantitative model that describes the time and temperature dependence of the experimentally determined extent of DPA release and spore inactivation. The model predicts a DPA release rate profile for each inactivated spore. In addition, it uncovers remarkable differences in the values for the temperature dependence parameters for the rate of spore inactivation, DPA release duration, and DPA release delay.     

Relationship between the heat resistance of spores and the optimum and maximum growth temperatures of Bacillus species

Heat resistance of spores of Bacillus strains was compared with the temperature adaptation of each strain as measured by the optimum and maximum growth temperatures and the heat resistance of vegetative cells. Maximum growth temperatures ranged from 31 to 76 degrees C and were little affected by the nature of the growth medium. The temperature giving maximum growth rate was closely correlated to the maximum temperature for growth, and about 6 degrees C lower. Vetetative-cell heat resistance, determined on exponential-phase cells, was also correlated with maximum growth temperature. The temperature at which spores were inactivated with a decimal reduction time of 10 min was in the range of 75 to 121 degrees C. This temperature was 46 +/- 7 degrees C higher than the maximum growth temperature and correlated with it and the other cell parameters. Spore heat resistance can be considered to have two components, the temperature adaptation characteristic of the species and the stabilization conferred by the spore state.     

A two-dimensional protein gel electrophoresis study of the heat stress response of Bacillus subtilis cells during sporulation

The heat resistance of spores of Bacillus subtilis formed at 30 degrees C was enhanced by pretreatment at 48 degrees C for 30 min, 60 min into sporulation, for all four strains examined. High-resolution two-dimensional gel electrophoresis showed the generation and/or overexpression of 60 proteins, 11 of which were specific to heat shock, concurrent to this acquired thermotolerance. The greatest number of new proteins was observed between 30 and 60 min after heat shock, and the longer the time between exponential growth and heat treatment, the fewer differences were observed on corresponding protein profiles. The time at which heating produced the maximum increase in spore resistance and the most new proteins on two-dimensional gels occurred before alkaline phosphatase and dipicolinic acid production and corresponded to stage I or II of sporulation. The stress proteins formed disappeared later in sporulation, suggesting that heat shock proteins increase spore heat resistance by altering spore structure rather than by repairing heat damage during germination and outgrowth.     

The effect of peroxyacetic acid-based sanitizer, heat and ultrasonic waves on the survival of Clostridium estertheticum spores in vitro

AIM: To determine the effect of selected physical and chemical treatments on the survival of 'blown pack'-causing Clostridium estertheticum. METHODS AND RESULTS: The study investigated the survival of the spores of 'blown pack'-causing C. estertheticum following the four treatments, which include: heat alone, ultrasound followed by heat treatment, peroxyacetic acid (POAA)-based sanitizer followed by heat treatment and POAA sanitizer followed by heat treatment in the presence of 20% animal fat. No C. estertheticum survivors were recovered in spore preparations that underwent either of the two treatments with the sanitizer, resulting in the inactivation of 4 to 5 log CFU ml(-1) of spores. Similarly, no survivors were detected in spore preparations that were treated with the sanitizer for 5 min at room temperature without further heat treatment. When using heat alone and ultrasound followed by heat treatment, complete spore inactivation did not occur for spores heated at times and temperature combinations other than 240 s at 100 degrees C. CONCLUSIONS: POAA sanitizer used with or without heat is capable of in vitro inactivation of at least 4 log CFU ml(-1)C. estertheticum spores. SIGNIFICANCE AND IMPACT OF THE STUDY: The data generated in the study provide background information for controlling 'blown pack'-causing clostridia on dressed carcasses and in meat plant environment.     

Changes in the hydrophobic characteristics of Clostridium perfringens spores and spore coats by heat

The hydrophobic characteristics of Clostridium perfringens NCTC 8679 spores were demonstrated by adherence to toluene in a toluene-aqueous partition system. Spores and spore coat preparations were hydrophobic. Vegetative cells and spores extracted with a dithiothreitol-sodium dodecyl sulfate treatment known to remove spore coats were not hydrophobic. A heat activation treatment (75 degrees C for 20 min) which promotes more rapid spore germination increased the hydrophobicity of intact spores and decreased that of isolated spore coats. The hydrophobic changes were reversed by washing and stabilized by 0.5% glutaraldehyde. Heat-induced hydrophobic changes were observed in spore coats prepared from spores that were preheated and washed before rupturing in a buffer containing glutaraldehyde. These results suggest the occurrence of a heat-induced change in the spore coat (possibly in the conformation of a macromolecule) which was stable only within the architectural confines of the intact spore.     

Effects of high hydrostatic pressure on Clostridium sporogenes spores

Spores of Clostridium sporogenes were found to be resistant to ultra high pressure, with treatments of 600 MPa for 30 min at 20 °C causing no significant inactivation. Combination treatments including heat and pressure applied simultaneously (e.g. 400 MPa at 60 °C for 30 min) or sequentially (e.g. 80 °C for 10 min followed by 400 MPa for 30 min) proved more effective at inactivating spores. Pressure cycling (e.g. 60 MPa followed by 400 MPa at 60 °C) also reduced spore numbers. Overall, these pressure treatments resulted in less than a 3 log reduction, and it was concluded that the spores could not be inactivated by pressure alone. This could indicate that for the effective inactivation of bacterial spores, high pressure technology may have to be used in combination with other preservation methods.     

Analysis of deamidation of small, acid-soluble spore proteins from Bacillus subtilis in vitro and in vivo.

Deamidation of one specific asparagine residue in an alpha/beta-type small, acid-soluble spore protein (SASP) of Bacillus subtilis took place readily in vitro (time for 50% deamidation [t(1/2)], approximately 1 h at 70 degrees C), and the deamidated SASP no longer bound to DNA effectively. However, DNA binding protected against this deamidation in vitro. A mutant alpha/beta-type SASP in which the reactive asparagine was changed to aspartate also failed to bind to DNA in vitro, and this protein did not restore UV radiation and heat resistance to spores lacking the majority of their alpha/beta-type SASP. When expressed in Escherichia coli, where it is bound to DNA, the alpha/beta-type SASP deamidated with a t(1/2) of 2 to 3 h at 95 degrees C. However, the alpha/beta-type SASP was extremely resistant to deamidation within spores (t(1/2), >50 h at 95 degrees C). A gamma-type SASP of B. subtilis also deamidated readily in vitro (t(1/2) for one net deamidation, approximately 1 h at 70 degrees C), but this protein (which is not associated with DNA) deamidated fairly readily in spores (t(1/2), approximately 1 h at 95 degrees C). Total spore core protein also deamidated in vivo, although the rate was two- to threefold slower than that of deamidation of total protein in heated vegetative cells. These data indicate that protein deamidation is slowed significantly in spores, presumably due to the spore's environment. However, alpha/beta-type SASP are even more strongly protected against deamidation in vivo, presumably by their binding to spore DNA. Thus, not only do alpha/beta-type SASP protect spore DNA from damage; DNA also protects alpha/beta-type SASP.     

Combined Effects of High Hydrostatic Pressure and Temperature for Inactivation of Bacillus anthracis Spores

Spores of Bacillus anthracis are known to be extremely resistant to heat treatment, irradiation, desiccation, and disinfectants. To determine inactivation kinetics of spores by high pressure, B. anthracis spores of a Sterne strain-derived mutant deficient in the production of the toxin components (strain RP42) were exposed to pressures ranging from 280 to 500 MPa for 10 min to 6 h, combined with temperatures ranging from 20 to 75°C. The combination of heat and pressure resulted in complete destruction of B. anthracis spores, with a D value (exposure time for 90% inactivation of the spore population) of approximately 4 min after pressurization at 500 MPa and 75°C, compared to 160 min at 500 MPa and 20°C and 348 min at atmospheric pressure (0.1 MPa) and 75°C. The use of high pressure for spore inactivation represents a considerable improvement over other available methods of spore inactivation and could be of interest for antigenic spore preparation.