Effect of the post-dry heat treatment temperature on the recovery of ascospores of Neosartorya fischeri

Neosartorya fischeri ascospores were subjected to a dry heat treatment at 95°C, 50% relative humidity for 30 and 60 min. The effect of the temperature of the recovery buffer (0–02% v/v Tween 80 in Butterfield's Buffer) was evaluated. As the temperature of the buffer increased, there was an exponential increase in the number of survivors, followed by a levelling off and, in some cases, a decrease. This behaviour may indicate temperature activation of dormant ascospores or reactivation of ascospores rendered dormant by the dry heat treatment. The results also suggest that the rehydration process is affected by temperature.     

Note: Influence of different heating media on thermal resistance of Neosartorya fischeri isolated from papaya fruit

E. RAJASHEKHARA, E.R. SURESH AND S. ETHIRAJ. 1996. A heat-resistant mold identified as a strain of Neosartorya fischeri was isolated from microbiologically spoiled papaya fruits. The optimum heat activation temperature and time for the ascospores of the test mold was found to be 80°C for 15–30 min. The decimal reduction times ( D -values) at 85°, 87° and 89°C in phosphate buffer (pH 7·0) as heating medium were 35·25, 11·1 and 3·90 min respectively and hence the calculated z -value was 4·0°C. In grape and mango juices as heating media, the D _80°C and the D _85°C values were increased as the °Brix level raised from 10 to 45. In commercial fruit juices of mango, orange, pineapple and mango-pineapple blend as heating media D _85°C values were greater than those observed for phosphate buffer.     

The heat resistance of ascospores of four Saccharomyces spp. isolated from spoiled heat-processed soft drinks and fruit products

The heat resistance ( D and z values) of four Saccharomyces spp., viz. S. bailii, S. cerevisiae, S. chevalieri, S. uvarum , was investigated by a previously described method (Put et al. 1977). The highest heat resistance was observed in ascospores of S. cerevisiae 175 showing a decimal reduction time or death rate constant at 60°C of 22.5 minutes. The average D 60°C values of the remaining species were: S. bailii 10 min; S. chevalieri 13 min; and S. uvarum 1.5 min; while z values varied between 4.0 and 6.5°C. It can be postulated that there may exist some comparison between the mechanism of yeast ascospore and bacterial endospore heat resistance. However, (i) washed Saccharomyces ascospores cannot be stored at 5°C for a longer period than 2–3 weeks without loss of heat resistance; and (ii) ascospore heat survival curves are essentially not linear over the whole range, which may be due to some heterogeneity of the ascospore population tested. Besides, it was observed that the heat resistance ( D 60°C values) of the Saccharomyces ascospores proved to be 50–150-fold higher than the D _60°C values of the corresponding vegetative cells.     

Heat resistance in Salmonella enteritidis phage type 4: the influence of storage temperatures before heating

H umphrey , T.J. 1990. Heat resistance in Salmonella enteritidis phage type 4: the influence of storage temperatures before heating. Journal of Applied Bacteriology 69 493–497.
Storage of cultures of Salmonella enteritidis PT4 at either 4° or 8°C before heating significantly increased heat sensitivity. The differences between fresh and stored cultures, which became apparent after 4–7 h, were more pronounced with cultures stored at the lower temperature and in those heated at 60° rather than 55°C. Incubation of the stored cultures in either egg or Lemco broth for 30 min at 37°C prior to heating enabled the organisms to recover heat resistance.     

Heat shock and thermotolerance of Escherichia coli O157:H7 in a model beef gravy system and ground beef

Duplicate beef gravy or ground beef samples inoculated with a suspension of a four-strain cocktail of Escherichia coli O157:H7 were subjected to sublethal heating at 46 °C for 15–30 min, and then heated to a final internal temperature of 60 °C. Survivor curves were fitted using a linear model that incorporated a lag period (T_L), and D-values and 'time to a 4D inactivation' (T_4D) were calculated. Heat-shocking allowed the organism to survive longer than non-heat-shocked cells; the T_4D values at 60 °C increased 1·56- and 1·50-fold in beef gravy and ground beef, respectively. In ground beef stored at 4 °C, thermotolerance was lost after storage for 14 h. However, heat-shocked cells appeared to maintain their thermotolerance for at least 24 h in ground beef held at 15 or 28 °C. A 25 min heat shock at 46 °C in beef gravy resulted in an increase in the levels of two proteins with apparent molecular masses of 60 and 69 kDa. These two proteins were shown to be immunologically related to GroEL and DnaK, respectively. Increased heat resistance due to heat shock must be considered while designing thermal processes to assure the microbiological safety of thermally processed foods.     

The heat shock response in meso- and thermoacidophilic chemolithotrophic bacteria

Abstract The heat shock response was studied in a chemolithotrophic thermoacidophilic archaebacterium Sulfolobus acidocaldarius (shifted from 70° to 85°C) and a mesoacidop0ilic microorganism Thiobacillus ferrooxidans (from 30° to 41°C). When transferred from their normal growth temperature to the stress temperature, cells showed a decrease in the incorporation of Na₂¹⁴CO₃ into proteins, and at the same time, the synthesis of a specific subset of heat shock proteins was observed. Ethanol (4%) at 30°C, also caused a response similar to the heat shock upon T. ferrooxidans cells, whereas Sulfolobus cells at 70°C did not incorporate radioactive CO₂ in the presence of ethanol, apparently being damaged by the organic solvent.     

Effectiveness of various food preservatives in controlling the outgrowth of Byssochlamys nivea ascospores

Potassium sorbate, sodium benzoate, sulfur dioxide, and diethylpyrocarbonate (DEPC) were tested for their effectiveness in preventing the outgrowth ofByssochlamys nivea Westling ascospores. Sulfur dioxide was the most inhibitory of the test antimycotics, complete inhibition of colony formation occurring in acidified (pH 3.5) potato dextrose agar containing 50 ppm of the preservative. Complete inhibition ofB. nivea ascospore outgrowth in grape juice stored for 60 days was noted in the presence of 300 ppm sulfur dioxide, 400 ppm potassium sorbate, and 600 ppm DEPC. Growth was observed in grape juice containing 1000 ppm sodium benzoate. The presence of up to 100 ppm potassium sorbate in grape juice during heat activation appears to have a stimulatory effect on breaking dormancy, while the other test preservatives at this concentration decrease the heat resistance ofB. nivea ascospores. The time elapsed between heat shock and exposure to DEPC or sodium benzoate is critical with respect to the sensitivity of ascospores to these preservatives.     

Heat resistance of Listeria monocytogenes in dairy products as affected by the growth medium

Listeria monocytogenes strains 1151 and Scott A were grown in broth at 30 °C and transferred to half cream, double cream and butter stored at 5 °C to determine the influence of dairy product composition on heat resistance at 52, 56, 60, 64 and 68 °C. Strain 1151 showed a higher heat resistance than strain Scott A. The heat resistance of both strains was higher in the dairy products than in broth, particularly at lower temperatures. A significant difference was observed between log 10 of the D -values in the different dairy products. The D -values obtained for both strains resuspended in all the dairy products would result in efficient elimination of the pathogen at 72·7 °C for 15 s. The highest D -value was 11·30 s at 68 °C and by using a z -value of 6·71 °C it can be determined that at 72·7 °C the D -value would be 1·5 s. The 15 s process would therefore achieve 10 log reductions. The effect of growth conditions on the heat resistance at 60 °C of L. monocytogenes Scott A was also investigated. When the cells were grown in the dairy products themselves, and particularly butter, the heat resistance of Scott A was enhanced; for example, the D -values were 7·15 times higher than in broth. Further studies are required to investigate if this protection against heating exists at higher temperatures, in which case the efficiency of pasteurization treatments or other heat treatments would be considerably lowered.     

Short-Term Changes in Heat Tolerance in the Alpine Cushion Plant Silene acaulis ssp. excapa [All.] J. Braun at Different Altitudes

Abstract: The habit of cushion growth positively affects plant temperature but at the same may increase the risk of occasional overheating. In order to determine the adaptive response to short-term heat stress, we exposed S. acaulis cushions at field sites to controlled heat treatments using infrared lamps. Natural diurnal changes in heat tolerance were monitored at alpine sites and at a site distinctly below the natural distribution boundary, where higher temperatures were expected. The range of heat tolerance limits in summer, 45.5 - 54.5 °C (9 K), exceeded that reported for other alpine species (0.1 - 5 K) and even that for total seasonal changes (5 - 8 K). Heat tolerance either increased or decreased on most days (80 %). The maximum diurnal increase was + 4.7 K. Under the experimental conditions heat hardening started at leaf temperatures around 30 °C and proceeded at mean rates of 1.0 ± 0.5 K/h. The onset of functional disturbances in photosystem II also occurred at 30 °C. Heating rates exceeding those naturally found above 30 °C (> 10 K/h) appeared to retard heat hardening. During summer average leaf temperature maxima were 12.4 K (600 m) and 13.0 K (1945 m) higher than air temperature which corroborates the heat trapping nature of cushion plants. At 600 m, as compared to 1945 m, cushions experienced significantly higher leaf temperature maxima (+ 8.8 K) and exceeded 30 °C on most days (80 %). This resulted in a significantly higher heat tolerance (LT₅₀) at 600 m (51.7 ± 0.2 °C) than at 1945 m (49.8 ± 0.2 °C). The fast short-term changes of heat tolerance in summer help S. acaulis to cope with the occasional diurnal short-term heat stress associated with cushion growth.     

The influence of the rate of temperature change on the activation of dormant seeds of Rumex obtusifolius L.

1. One temperature shift from 20 to 30°C in darkness induces 30–40% germination in Rumex obtusifolius seeds. The same germination percentages are found with heat treatment varying between 1 and 6h duration, indicating that the total heat sum of the temperature shift is not important.
2. Germination is greatly enhanced by three consecutive heat shifts of 1h at 30°C separated by 1h periods at 20°C.
3. The seeds are activated to a small extent after a slow warming (+2°Ch^–1) from 20 to 30°C, followed by incubation for 1h at 30°C. Germination is much higher after rapid heating (+10°Ch^–1) to 30°C, followed by 1h incubation at this temperature. Repeated fast heating treatments on four consecutive days enhances germination. Moderately rapid heatings (+3·3°Ch^–1) give intermediate results.
4. The rate of cooling does not influence the germination percentage. Cooling alone cannot induce germination.
5. Heating alone from 15 to 25°C without cooling also activates germination. In this temperature range the seeds are more activated by rapid warming than by slow warming.
6. The ecological relevance of the response to different warming rate is discussed. The insensitivity of seeds to a slow warming might keep deeply buried seeds in a dormant stage.     

Growth and fumitremorgin production by Neosartorya fischeri as affected by food preservatives and organic acids

The effects of potassium sorbate, sodium benzoate, sulphur dioxide and citric, malic and tartaric acids on growth and fumitremorgin production by a heat-resistant mould, Neosartorya fischeri , cultured on Czapek yeast autolysate agar (CYA) were studied over a 32-day incubation period. Colonies were examined, and extracts of agar and mycelia were analyzed for mycotoxin content using high performance liquid chromatography (HPLC). Growth of N. fischeri always resulted in production of the fumitremorgins verruculogen and fumitremorgin A and C. Growth on CYA (pH 3.5) was highly repressed by potassium sorbate and sodium benzoate; 75 mg/1 completely inhibited germination of ascospores. Sulphur dioxide was less inhibitory; growth occurred on CYA containing 100 but not 200 mg/1. Growth of N. fischeri was significantly reduced when the pH of CYA was reduced from 7.0 to 4.5 to 3.5 to 2.5. Citric, malic and tartaric acids promoted growth and fumitremorgin production when supplemented to CYA (pH 2.5). These observations indicate that growth and fumitremorgin production by N. fischeri are influenced by pH and type of acid present and can be controlled by small amounts of preservatives.     

Growth and formation of toxin by Clostridium botulinum in peeled, inoculated, vacuum-packed potatoes after a double pasteurization and storage at 25°C

A process that claims to use a double pasteurization to produce vacuum-packed potatoes for storage at ambient temperature has been evaluated. After the first pasteurization, potatoes are vacuum-packed and stored at 25°C–35°C for up to 24 h, which is intended to allow germination of bacterial spores, and are then pasteurized again. When potatoes were inoculated with spores of Clostridium botulinum and subjected to this double-pasteurization process a high proportion of spores remained viable and resulted in growth and formation of toxin within 5–9 d at 25°C. To provide an appropriate reduction in the risk of survival and growth of Cl. botulinum , peeled, vacuum-packed potatoes for storage at ambient temperature should be given a heat treatment equivalent to an F₀3 process. If they are not given such a heat treatment they should be stored at a temperature below 4°C.     

Fatty acid desaturation in monogalactosyldiacylglycerol of Brassica napus leaves during low temperature acclimation

Brassica napus plants grown at 5°C have the potential to desaturate fatty acids in the major membrane diacylglycerols of leaves at rates much higher than those of plants grown at 30°C. This low temperature-induced desaturation (LTD) is rapidly deactivated if plants grown at 5°C are transferred to 30°C for several hours. By exposure to ¹⁴CO₂ and a computer simulation program, we estimated the rate of desaturation of monogalactosyldiacylglycerol by (ω9-, ω6- and ω3-desaturases of plants grown at 5, 10, 20 and 30°C. Data show that LTD can be induced in mature leaves of plants grown at 20 and 30°C after transfer to 5°C. Full activation of LTD takes several weeks and occurs more rapidly in plants grown at 20°C than 30°C. This activation is largely due to the increased activity of ω9- and ω6-desaturases on C16 fatty acids and ω6-desaturase on C18 fatty acids.     

Bioactivity of stored luteinizing hormone-releasing hormone analogue (LHRHa) in sea bass, Lates calcarifer Bloch

The spawning induction activity of dissolved and pelleted (D-Ala⁶, Pro⁹ N ethylamide) luteinizing hormone-releasing hormone analogue (LHRHa) stored for various periods was assessed in mature female sea bass. The spawning response of mature fish was reduced significantly after injection of dissolved LHRHa (20 μg kg⁻¹) stored for more than 90 days in a refrigerator (4–10°C) or for more than 30 days at room temperature (28–30°C). Similar to fish administered fresh preparations of LHRHa, fish spawned successfully after injection of a solution of LHRHa previously frozen, subjected to alternate freezing and thawing, exposed to sunlight or implanted pelleted LHRHa (50 ng kg⁻¹) stored at room temperature for 30–120 days. Loss of hormone bioactivity after prolonged storage may have been due to bacterial growth in solubilized preparations. Injection or implantation of stored LHRHa did not influence egg production among treated sea bass. These results demonstrated the relatively prolonged shelf life of stored LHRHa.     

Heat-induced resistance of Bacillus stearothermophilus spores

Spores of Bacillus stearothermophilus CNCH 5781 were suspended in distilled water or nutrient medium. A 28 μl aliquot of each was inoculated into haematocrit capillaries and subjected at different time intervals to sublethal temperatures of 63° or 100°C as heat activation for germination. This was followed by heat treatment at 121·1°C and the heat parameter D _121·1 was measured. Contrary to standard observations, heat resistance was observed to increase following activation, a phenomenon which we named 'heat-induced resistance'.     

Influence of the incubation temperature after heat treatment upon the estimated heat resistance values of spores of Bacillus subtilis

S. CONDÓN, A. PALOP, J. RASO AND F.J. SALA. 1996. The influence of the incubation temperature on the estimated heat resistance for survivors after heat treatment was investigated. The survival curves and the D _t values of spores of Bacillus subtilis heated at different temperatures in pH 7 buffer, obtained after incubating survivors at different temperatures (30, 37, 44 or 51°C), were compared. The incubation temperature influenced the profile of survival curves. Lower incubation temperatures led to bigger D _t values and longer shoulders. D _t values obtained after incubating at 30°C were higher (x3 approx.) than those obtained by incubating at 51°C. The incubation temperature did not modify z values ( z = 9.1). These results show that shoulders are not only due to the activation of dormant spores but also to heat damage repair mechanisms. From the profile of survival curves at different incubation temperatures it would seem that heat damage is accumulative. Cells can repair the initial heat injury, but the accumulation of injuries would eventually make the damage irreversible.     

Occurrence of molds on laminated paperboard for aseptic packaging, selection of the most hydrogen peroxide- and heat-resistant isolates and determination of their thermal death kinetics in sterile distilled water

This study aimed at enumerating molds (heat-labile and heat-resistant) on the surface of paperboard material to be filled with tomato pulps through an aseptic system and at determining the most heat- and hydrogen peroxide-resistant strains. A total of 118 samples of laminated paperboard before filling were collected, being 68 before and 50 after the hydrogen peroxide bath. Seven molds, including heat-resistant strains (Penicillium variotii and Talaromyces flavus) with counts ranging between 0.71 and 1.02 CFU/cm(2) were isolated. P. variotii was more resistant to hydrogen peroxide than T. flavus and was inactivated after heating at 85 °C/15 min. When exposed to 35 % hydrogen peroxide at 25 °C, T. flavus (F5E2) and N. fischeri (control) were less resistant than P. variotti (F1A1). P. citrinum (F7E2) was shown to be as resistant as P. variotti. The D values (the time to cause one logarithmic cycle reduction in a microbial population at a determined temperature) for spores of P. variotii (F1A1) and N. fischeri (control) with 4 months of age at 85 and 90 °C were 3.9 and 4.5 min, respectively. Although the contamination of packages was low, the presence of heat- and chemical-resistant molds may be of concern for package sterility and product stability during shelf-life. To our knowledge, this is the first report that focuses on the isolation of molds, including heat-resistant ones, contaminating paperboard packaging material and on estimating their resistance to the chemical and physical processes used for packaging sterilization.     

Combining heat treatment and subsequent incubation temperature to prevent growth from spores of non-proteolytic Clostridium botulinum

Refrigerated processed foods of extended durability rely on a mild heat treatment combined with refrigerated storage to ensure microbiological safety and quality. The principal microbiological safety risk in foods of this type is non-proteolytic Clostridium botulinum. In this article the combined effect of mild heat treatment and refrigerated storage on the time to growth and probability of growth from spores of non-proteolytic Cl. botulinum is described. Spores of non-proteolytic Cl. botulinum (two strains each of type B, E and F) were heated at 90°C for between 0 and 60 min and subsequently incubated at 5°, 10° or 30°C in PYGS broth in the presence or absence of lysozyme. The number of spores that resulted in turbidity depended on the combination of heat treatment, incubation time and incubation temperature they received. Heating at 90°C for 1 or more min ensured a 10⁶ reduction when spores were subsequently incubated at 5°C for up to 23 weeks. Heating at 90°C for 60 min ensured a 10⁶ reduction over 23 weeks when subsequent incubation was at 10°C in the presence of added lysozyme. The same treatment did not reduce the spore population by 10⁶ when subsequent incubation was at 30°C.     

Effect of culture age, pre-incubation at low temperature and pH on the thermal resistance of Aeromonas hydrophila

S. CONDON, M.L. GARCIA, A. OTERO AND F.J. SALA. 1992. The thermal resistance of Aeromonas hydrophila strain NCTC 8049 was determined within the range 48°-65°C with a thermoresistometer TR-SC and McIlvaine buffer. The effects of culture age, pre-incubation at 7°C and the pH of the heating menstruum were evaluated. The pattern of thermal death was dependent on culture age. Cells heated in the late logarithmic growth phase (15 h at 30°C) were twice as resistant as those in the early stage (5 h at 30°C), and the maximum D -value was obtained after 72 h incubation (5.5 total increase). The age of the cells did not affect z -values significantly. The heat resistance of cells incubated for 48 h at 30°C increased (twice) after holding at 7°C for 72 h. Pre-incubation at low temperature of older cultures (72 h, 30°C) did not influence their D -values. Maximum heat resistance was found at pH 6.0 and minimal at pH 4.0. Decreasing the pH from 6.0 4.0 reduced D -values by a factor of 5. Although the strain studied was heat-sensitive ( D _55°C= 0.17 min; z = 5.11°C), survivor curves of cultures older than 50 h showed a significant tailing. Organisms surviving in the tails were only slightly more resistant than were the original population.     

Thermal Activation and Dry-heat Inactivation of Spores of Bacillus subtilis MD2 and Bacillus subtilis var. niger

Spores of Bacillus subtilis MD2 and Bacillus subtilis var. niger were heat activated for different times at 60° and 80°C. Strain MD2 required considerable heat activation while B. subtilis var. niger did not. Maximum germination rates increased with heat activation dose and declined subsequently without loss of germinability. Germination rates and percentages were considerably greater in tryptone glucose extract (TGE) than in nutrient broth. The addition of 2°° dimethyl sulphoxide did not increase germination in nutrient broth. The spores of var. niger are more resistant to dry-heat than MD2 although they are less resistant to moist heat. Survivor curves in the dry-heat range 140°-170°C gave D-values from 4–123 to 0.106 min for MD2 and 5.679 to 0.233 min for var. niger recovered on TGE agar. D-values were lower on poorer media. The z-values for MD2 and var. niger on TGE were 18.7°C and 21.25C respectively.