A rapid method for the determination of bacterial fatty acid composition

Heat treatment of spores of non-proteolytic strains of Clostridium botulinum at 75–90°C, and enumeration of survivors on a nutrient medium containing lysozyme gave biphasic survival curves. A majority of spores were inactivated rapidly by heating, and the apparent heat-resistance of these spores was similar to that observed by enumeration on medium without lysozyme. A minority of spores showed much greater heat-resistance, due to the fact that the spore coat was permeable to lysozyme, which diffused into the spore from the medium and replaced the heat-inactivated germination system. The proportion of heated spores permeable to lysozyme was between 0.2 and 1.4% for spores of strains 17B (type B) and Beluga (type E), but was about 20% for spores of strain Foster B96 (type E). After treatment of heated spores with alkaline thioglycolate, all were permeable to lysozyme. D-values for heated spores that were permeable to lysozyme (naturally and after treatment with thioglycolate) were: for strain 17B, D₈₅°C, 100 min; D₉₀°C, 18.7 min; D₉₅°C, 4.4 min; for strain Beluga, D₈₅°C, 46 min; D₉₀°C, 11.8 min; D₉₅°C, 2.8 min. The z-values for these spores of strains 17B and Beluga were 7.6°C and 8.3°C.     

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.     

Effects of temperature and heat activation on germination of individual spores of Bacillus subtilis

Phase intensity changes of individual germinating spores of Bacillus subtilis were determined by phase-contrast light microscopy and image analysis. Two germination phases were investigated. The length of the time period before a change in phase brightness was evident and the duration of the phase intensity change until a constant greylevel was maintained. The incubation temperature (37 and 20 °C) and heat activation (10 min at 65 °C) had a distinct effect on both phases. At 37 °C, spores of B. subtilis 604 started to show a decrease in brightness in l -alanine buffer after 3–39 min and needed 10–39 min to complete the phase change. At 20 °C, lag times of 10–100 min were observed and the spores needed 30–100 min to reach a constant greylevel. Heat activation and subsequently exposure to l -alanine buffer at 20 °C reduced the lag phase to 6–90 min and the phase change was finished after 30–60 min. Our results indicate enzymatic involvement before and during the phase intensity change of germinating spores.     

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.     

Occurrence and Thermoresistance of Spores of Psychrophilic and Psychrotrophic Aerobic Sporeformers in Soil and Foods

Spores of psychrotrophic (able to grow at 5°C) aerobic sporeformers occurred in soil in high numbers (2 × 10³-5 × 10⁶/g), whereas psychrophilic (able to grow at 0°C) spores were present at significantly lower levels (500–10⁵/g). Psychrotrophic spores were absent in herbs and spices: in pasteurized meals prepared industrially their numbers varied from <10 to 1000/g. For spores harvested from Trypticase Soy Agar (TSA), the heat resistance of the cold-tolerant sporeformers was low with D _90°C-values from 1–11 min. The recovery of heated psychrophilic spores on this medium at 5°C was equal to their recovery at 20°C. However, the recovery of heated psychrotrophic spores was lower at 5°C than at 20°C, whereas unheated spores gave the same counts at both temperatures. The heat resistance of naturally occurring spores of cold-tolerant sporeformers washed from soil was comparable with the resistance of spores formed on TSA.     

The effect of recovery medium on the estimated heat-inactivation of spores of non-proteolytic Clostridium botulinum

Heating spores of non-proteolytic strains of Clostridium botulinum at 85°C, followed by enumeration of survivors on a highly nutrient medium indicated a 5 decimal kill in less than 2 min. The inclusion of lysozyme or egg yolk emulsion in the recovery medium substantially increased apparent spore heat-resistance, with as little as 0.1 μg lysozyme/ml sufficient to give an increase in the number of survivors. After heating at 85°C for 2 min between 0.1% and 1% of the spores of 11 strains (5 type B, 4 type E, 2 type F) formed colonies on medium containing 10 μg lysozyme/ml. Enumeration of survivors on a medium containing lysozyme showed that heating at 85°C for 5 min resulted in an estimated 2.6 decimal kill of spores of strain 17B (type B). These findings are important in the assessment of heat-treatments required to ensure the safety with respect to non-proteolytic Clostridium botulinum of processed (pasteurized) refrigerated foods for extended storage such as sous-vide foods.     

The effect of recovery conditions on the apparent heat resistance of Bacillus cereus spores

The effect of recovery media and incubation temperature on the apparent heat resistance of three ATCC strains (4342, 7004 and 9818) of Bacillus cereus spores were studied. Nutrient Agar (NA), Tryptic Soy Agar (TSA), Plate Count Agar (PCA) and Milk Agar (MA) as the media and temperatures in the range of 15–40°C were used to recover heated spores. Higher counts of heat injured spores were obtained on PCA and NA. The optimum subculture temperature was about 5°C below the optimum temperature for unheated spores. No significant differences in heat resistance were observed with the different recovery conditions except for strains 4342 and 9818 when MA was used as plating medium.
Large differences in D -values were found among the strains ( D ₁₀₀=0·28 min for 7004; D ₁₀₀=0·99 min for 4342; D ₁₀₀= 4·57 min for 9818). The 7004 strain showed a sub-population with a greater heat resistance. The z values obtained for the three strains studied under the different recovery conditions were similar (7·64°C 0·25).     

Comparison of coats and surface-dependent properties of Bacillus cereus T prepared in two sporulation environments

The surface or coat-associated properties of Bacillus cereus T spores produced from modified G medium (MGM) and fortified nutrient agar (FNA) were compared. The two populations appeared structurally similar by transmission electron microscopy. Spores prepared on FNA were more susceptible to ozone inactivation than MGM-prepared spores. When activated by heating for 15 min at 70–85°C, FNA-prepared spores were optimally activated at 85°C and did not become hydrophilic on heat activation while MGM spores were optimally activated at 70°C and became hydrophilic on activation. Susceptibility to removal of coat and outer membrane by chemical and enzymatic extraction treatments was measured by monitoring reduced ability to germinate in nutrients and acquired ability to germinate in the presence of lysozyme. Bacillus cereus T MGM-prepared spores germinated in lysozyme upon<1 h exposure to sodium dodecyl sulphate-dithiothreitol. FNA-prepared spores were lysozyme sensitive after > 2 h treatment. Thus, B. cereus T FNA spore coats and outer membranes were more resistant to these denaturing agents. Transmission electron micrographs revealed no change in appearance of extracted spores. Sporulation environment must be considered when laboratory-prepared spores are used to assess or predict the effect of control procedures on spores present in nature.     

A Model System for Testing the Microbiological Stability of Foods Processed in Laminated Flexible Pouches

A suitable time temperature process for packaging small potatoes in flexible pouches is described. Spores of Bacillus stearothermophilus were inoculated onto the surface of peeled potatoes in flexible pouches. These were evacuated, heat sealed and heated in a steam retort modified to allow a water cooking process with an air overpressure of ca. 68·95 kPa (10 lbf/in²). The D and z values determined in the retort were confirmed by parallel heat-resistance tests with spores in glass ampoules held in an oil bath. Heat treatment at 121·1 °C for 20 min in the retort satisfactorily killed test inocula of spores without overcooking the potatoes. Uninoculated peeled potatoes with a natural level of contamination ( ca. 4 x 10³ spores/sealed pouch) were treated in the retort for different times at 121·1 °C and then incubated at 30 °C for 6 months. No pouches heated for 17–25 min showed microbial growth. This procedure may be applied to any type of food if the numbers of naturally occurring heat-resistant contaminants can be related to the number and heat resistance of a suitable test micro-organism.     

Effect of Iysozyme concentration, heating at 90°C, and then incubation at chilled temperatures on growth from spores of non-proteolytic Clostridium botulinum

The heat treatment necessary to inactivate spores of non-proteolytic Clostridium botulinum in refrigerated, processed foods may be influenced by the occurrence of lysozyme in these foods. Spores of six strains of non-proteolytic Cl. botulinum were inoculated into tubes of an anaerobic meat medium, to give 10⁶ spores per tube. Hen egg white lysozyme (0–50 μg ml^-1) was added, and the tubes were given a heat treatment equivalent to 19·8 min at 90°C, cooled, and incubated at 8°, 12°, 16° and 25°C for up to 93 d. In the absence of added lysozyme, neither growth nor toxin formation were observed. A 6–D inactivation was therefore achieved. In tubes to which lysozyme (5–50 μg ml^-1) had been added prior to heating, growth and toxin formation were observed. With lysozyme added at 50 μg ml^-1, growth was first observed after 68 d at 8°C, 31 d at 12°C, 24 d at 16°C, and 9 d at 25°C. Thus, in these circumstances, a heat treatment equivalent to 19·8 min at 90°C was not sufficient, on its own, to give a 6–D inactivation. A combination of the heat treatment, maintenance at less than 12°C, and a shelf-life not more than 4 weeks reduced the risk of growth of non-proteolytic Cl. botulinum by a factor of 10⁶.     

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.     

Use of the direct epifluorescent filter technique for the enumeration of bacterial spores

Heat treatment at 80°C for 10 min effectively destroyed all vegetative cells (except for Gram-positive cocci) and made easier the counting of bacterial spores, which stained orange, green or rarely transparent/black with a dull green halo, in the direct epifluorescent filter technique. The numbers of both orange- or green-staining spores were lower than the plate count. A variety of physiological conditions were used to investigate the relationship of the different staining patterns with germination status. It was concluded that orange-staining spores had germinated and their number agreed with the plate count after incubation in yeast glucose broth at 30°C for 4 h. This observation was unreliable, however, but it was found that a total spore count in the DEFT gave a good agreement with the plate count.     

Sensitivity of Bacillus coagulans spores to combinations of high hydrostatic pressure, heat, acidity and nisin

We investigated the combined effects of pressure, temperature, pH, initial spore concentration and the presence of nisin on the survival of spores of Bacillus coagulans. Spores were more sensitive to pressure both at lower pH and at higher treatment temperatures. An additional 1.5-log₁₀ reduction in cfu ml^-1 was observed when pH was lowered from 7.0 to 4.0 during pressurization at 400 Mpa and 45°C. A 4-log₁₀ cfu ml^-1 reduction was observed when the temperature was increased from 25°C to 70°C during pressurization at 400 Mpa. The spores were sensitive to nisin at concentrations as low as 0.2 IU ml^-1. At least a 6-log₁₀ reduction was generally achieved with pressurization at 400 Mpa in pH 4.0 buffer at 70°C for 30 min when plated in nutrient agar containing 0.8 IU ml^-1 nisin.     

A note on the effect of sporulation conditions on the resistance of Bacillus spores to heat and chemicals

Spores of Bacillus subtilis SA22 harvested after 22 d incubation on nutrient agar at 30°C were more resistant to 0–04% peracetic acid at 20°C than spores harvested following 2 d incubation. Similarly, spores of B. subtilis globigii B17, harvested after 7 d incubation on a sporulation agar were up to 10 times less resistant to 0.04% peracetic acid at 20°C than spores harvested after 35 d incubation. An increase in resistance to heating at 100°C and to exposure to 17.7% hydrogen peroxide at 20°C occurred as the age of B. subtilis SA22 spores prior to harvesting increased, whereas differences in resistance were not observed with spores of B. subtilis globigii B17.     

A lithotrophic Clostridium strain with extremely thermoresistant spores isolated from a pectin-limited continuous culture of Clostridium thermosaccharolyticum strain Haren

Abstract A thermophilic Clostridium sp. with extremely thermoresistant spores was isolated from a pectin-limited continuous culture of Clostridium thermosaccharolyticum . The decimal reduction time of the spores was 70 min at 121°C. Because of the ability of the bacterium to grow both heterotrophically and lithotrophically, it has a potential for infecting a wide range of thermophilic anaerobic cultures.     

Injury and repair in biocide-treated spores of Bacillus subtilis

Abstract Bacillus subtilis NCTC 8236 spores exposed to appropriate concentrations of test biocides (glutaraldehyde, two iodine and two chlorine preparations) were able to repair injury if subsequently held in nutrient broth at 37°C but not in broth at 22°C, sterile filtered water at 4, 22 or 37°C or germination medium at 37°C. Repair appeared to occur primarily during outgrowth and was initiated soonest for iodine-treated spores and latest for glutaraldehyde-treated ones.     

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

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

A note on the microbial spoilage of undercooked chub-packed luncheon meat

Contrary to expectations slight undercooking (68.5°C instead of 70°C for 90 min) dramatically increased the shelf-life of chub-packed luncheon meat stored at 25°C. The pH of undercooked chubs fell rapidly to below 5.0 as a result of the growth of enterococci. The accumulated acid prevented the growth of Bacillus spores and gave the luncheon meat a not unpleasant tangy flavour. Degradative changes associated with the spoilage of commercially cooked chub-packed luncheon meat did not occur, even after 42 d storage. Apparently, post-cooking fermentation by enterococci can effectively convert a perishable product into a 'shelf stable' one by lowering the pH below 5.0.     

Cryopreservation of entrapped monoxenically produced spores of an arbuscular mycorrhizal fungus

A study was conducted to quantify the ability of entrapped, monoxenically produced spores of an arbuscular mycorrhizal fungus to germinate and reproduce the fungal life cycle after cryopreservation. No germination was obtained after incubation of entrapped spores in glycerol and mannitol and subsequent cryopreservation at −70 °C, regardless of the concentration of cryoprotectants and duration of incubation. Incubation for 1 d in 0.5 M sucrose, and for 1 and 2 d in 0.5 M trehalose, led to spore germination after cryopreservation at −70 °C. Lower cryopreservation temperatures were tested with entrapped spores incubated for 1 d in 0.5 M trehalose. The highest germination rate, estimated by the percentage of potentially infective beads (%PIB), was obtained at −100 °C. A %PIB of 95% (water agar medium) to 100% (Strullu–Romand medium) was obtained at this temperature. Thereafter, %PIB rapidly decreased at −140 and −180 °C. Heavy sporulation and high internal root colonization were obtained after re-association of the entrapped spores, incubated for 1 d in 0.5 M trehalose and subsequently cryopreserved at −100 °C, with transformed carrot roots. This demonstrates the ability of entrapped spores to reproduce the fungal life cycle following cold treatment.     

Properties and attempted culture of Pasteuria penetrans, a bacterial parasite of root-knot nematode (Meloidogyne javanica)

When they were subjected to a range of physical and chemical treatments, spores of Pasteuria penetrans showed properties similar to those of other endospore-forming bacteria. The spores did not take up some stains, were resistant to desiccation and sonication and showed extrusion of spore contents ('spore popping') on prolonged exposure to 0.1% KMnO₄ in 0.3 n HNO₃. Calcium and dipicolinic acid (DPA) were present at concentrations of 0.28% and 0.96% of the spore dry weight respectively, giving a Ca: DPA molar ratio of 1.2. The infectivity of P. penetrans spores was reduced to a low level after heating at 100°C for 5 min, but spore attachment was not markedly affected by heating at 100°C for 15 min. Evidence for the presence of catalase in P. penetrans spores was equivocal because the low levels of catalase activity observed in spore suspensions may have been due to contamination from catalase-positive nematode tissue. When P. penetrans spores were exposed to a range of substances known to act as germinants for spores of Bacillus spp., germination or loss of refractility was not observed by phase microscopy. In vitro culture of P. penetrans was attempted by inoculating either spores or vegetative mycelial bodies onto a diverse range of simple and complex media and incubating them in aerobic, reduced oxygen, anaerobic and increased CO₂ environments. Signs of spore germination or growth of vegetative stages were never observed.