Heat Resistance of Salmonella: the Uniqueness of Salmonella senftenberg 775W

Of approximately 300 cultures of Salmonella, representing 75 different serotypes, none was found to be as heat-resistant as S. senftenberg 775W. However, S. blockley 2004 was 5 times more heat-resistant and S. senftenberg 775W was 30 times more heat-resistant than S. typhimurium Tm-1, the reference strain in this study. All other strains of Salmonella tested, including 19 strains of S. senftenberg and 7 strains of S. blockley, had decimal reduction times at 57 C of about 1 min, equivalent to that of the reference organism, Tm-1. As observed in other bacterial species, strain 775W is more heat-sensitive in the log phase than in the stationary phase of growth. Cells from cultures grown at 44 C were more heat-resistant than those grown at either 35 or 15 C; the medium of growth, whether minimal or complex, made no appreciable difference in heat resistance. Cells from cultures limited by a carbon source were killed at a much slower rate than those limited by a nitrogen source and exhibited a 1-hr lag at 55 C before a significant rate of kill was attained. For any given set of growth conditions, strain 775W was always more heat-resistant than another strain of S. senftenberg, 197B, which has normal heat resistance.     

Heat resistance of Salmonella senftenberg 775W at various sucrose concentrations in distilled water

Summary The heat resistance of Salmonella senftenberg 775 W, NCTC 9959, has been determined in distilled water pH 6.5 at sucrose concentrations up to 2.20 mol l^–1 at temperatures between 63 and 70°C. Surviving cells were counted on minimal and enriched agar media to investigate the influence of the various nutrients on the recovery of heat injured cells. At various sucrose concentrations and temperatures multiphasic exponential parts of inactivation curves were found. Systematic differences between the recovery media depended on sucrose concentration, temperature and phase of exponential inactivation. At 60°C and sucrose concentrations between 0.52 and 1.82 mol l^–1 the relationship between inactivation rate and sucrose concentration could be described by the equation ln k₅=ln k₀-_T [sucrose]. The activation energy of thermal inactivation reactions, substantially decreased when sucrose (1.82 mol l^–1) was added to the heating menstruum. The activation energies in different recovery agars were of the same order, which suggests that the critical sites in heat inactivation are not key enzymes of the synthetic pathways of amino-acids and nucleotides. The differences between activation energies, calculated for cells of the various exponential phases of inactivation in both non-sucrose and 1.82 mol sucrose per 1 heating media, were also small, further suggesting that these critical sites are the same in cells from the various phases. Compared to published data on the heat resistance of S. senftenberg 775 W, we found a decreased resistance in a non-sucrose medium but an equal or increased resistance, depending on the phase of exponential inactivation, at a sucrose concentration of 1.82 mol l^–1.     

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.     

Heat Resistance of Salmonella in Various Egg Products

The heat-resistance characteristics of Salmonella typhimurium Tm-1, a reference strain in the stationary phase of growth, were determined at several temperatures in the major types of products produced by the egg industry. The time required to kill 90% of the population (D value) at a given temperature in specific egg products was as follows: at 60 C (140 F), D = 0.27 min for whole egg; D = 0.60 min for whole egg plus 10% sucrose; D = 1.0 min for fortified whole egg; D = 0.20 min for egg white (pH 7.3), stabilized with aluminum; D = 0.40 min for egg yolk; D = 4.0 min for egg yolk plus 10% sucrose; D = 5.1 min for egg yolk plus 10% NaCl; D = 1.0 min for scrambled egg mix; at 55 C (131 F), D = 0.55 min for egg white (pH 9.2); D = 1.2 min for egg white (pH 9.2) plus 10% sucrose. The average Z value (number of degrees, either centigrade or fahrenheit, for a thermal destruction time curve to traverse one logarithmic cycle) was 4.6 C (8.3 F) with a range from 4.2 to 5.3 C. Supplementation with 10% sucrose appeared to have a severalfold greater effect on the heat stabilization of egg white proteins than on S. typhimurium Tm-1. This information should be of value in the formulation of heat treatments to insure that all egg products be free of viable salmonellae.     

Survival of Salmonella senftenberg and Salmonella typhimurium in glassy and rubbery states of gelatin

Salmonella senftenberg and Salmonella typhimurium survived the production of gelatin sheets containing nutrient broth although there was some evidence of cell damage. Both strains survived but did not grow in glassy states with an a _w of 0.45–0.28 and rubbery states with an a _w of 0.93–0.96 for at least 28 d. Survival was less in intermediate states with an a _w between 0.55 and 0.74. The results suggest that salmonellas should be excluded from glassy state products in order to prevent salmonellosis.     

Growth and Destruction of Salmonella typhimurium in Egg White Foam Products Cooked by Microwaves

Currently, in both home and institutional food preparation, attempts are being made to produce high quality foods with a minimum of time and effort. Research is being carried out to develop equipment capable of cooking foods in a fraction of the time required by conventional methods; as a result, the problem arises as to the bacteriological safety of these products. We investigated the microbiological aspects of lemon and chocolate foam pies before and after cooking by microwaves for less than 2 min. Pies prepared with sterile equipment under sanitary conditions were inoculated with washed cells from a 24-hr broth culture of Salmonella typhimurium and were incubated for 24, 48, and 72 hr at 33 C. The same procedures were followed in model systems to determine the effects of various sugar and pH levels on the survival of S. typhimurium. No S. typhimurium was detected in inoculated cooked or uncooked lemon pies by the plating method; with the Lactose Broth pre-enrichment method, survivors were detected in lemon pies immediately after preparation. After electronic cooking, no survivors were detected in lemon pies by plate counts, whereas cells were recovered from chocolate pies by the Lactose Broth method. Both chocolate and lemon pies had lower counts throughout the 72-hr incubation period than the model systems compared to them. With the model systems, at pH 7.3, media containing sugar inhibited the growth of S. typhimurium but did not cause a significant reduction in counts during the incubation times studied. At pH 3.7, media without sugar yielded no cells with the Lactose Broth pre-enrichment method after 48 hr of incubation, whereas media with sugar were not sterile until after 72 hr of incubation. Apparently, the presence of sugar in the medium had a protective influence which made the lethal effect of the low pH less severe.     

A rapid monitoring assay for the detection of Salmonella spp. and Salmonella Senftenberg strain W775 in composts

AIMS: The composting process needs to be validated for its hygienic status in order to ensure that it is free of pathogens. Generally, this is evaluated through temperature monitoring, or additionally through active inoculation and monitoring of indicator organisms. We aimed to develop a monitoring method for the heat-resistant indicator organism Salmonella enterica ssp. enterica serovar Senftenberg strain W775 for detection in composting biowastes. METHODS AND RESULTS: The method development is comprised of: (i) optimization of molecular detection of bacteria belonging to the genus Salmonella; (ii) identification of a DNA marker for Salmonella strain W775; and (iii) development of a multiplex polymerase chain reaction (PCR)-based on both DNA markers. Subsequently, Salmonella strain W775 was inoculated and monitored during composting of biowastes in an industrial composting facility. CONCLUSIONS: A highly sensitive and specific detection of viable cells was obtained by enriching the compost sample prior to multiplex PCR analysis. Complete inactivation of Salmonella strain W775 was obtained within 4 days in an industrial composting facility at temperatures ranging between 41 and 57 degrees C. SIGNIFICANCE AND IMPACT OF THE STUDY: We describe a monitoring method for the simultaneous detection of naturally occurring Salmonella strains and artificially introduced Salmonella strain W775 in composting biowastes that can be applied in routine analysis.     

Effect of Added Moisture on the Heat Resistance of Salmonella anatum in Milk Chocolate

The heat resistance of Salmonella anatum in milk chocolate at a processing temperature (71 C) was greatly decreased by adding 1 to 4% moisture.     

Effect of cyclopentaneglycine on metabolism in Salmonella typhimurium

Cyclopentaneglycine (CPG) inhibited the growth of wild-type Salmonella typhimurium. The inhibition was overcome by isoleucine or any isoleucine precursor formed after threonine. CPG appeared to mimic isoleucine as a strong inhibitor of the activity of l-threonine deaminase. The analogue was a poor inhibitor of isoleucyl-transfer ribonucleic acid synthetase. CPG did not appear to be incorporated into protein nor did it replace isoleucine in repression. Cells that had recovered from growth inhibition by CPG had derepressed levels of the isoleucine-valine biosynthetic enzymes.     

Effect of pH, temperature, and potassium sorbate on amino acid uptake in Salmonella typhimurium 7136

The effect of sorbate on L-serine and L-histidine uptake in Salmonella typhimurium was studied at various pH levels, temperatures, and amino acid and sorbate concentrations. Low pH had an apparent synergistic effect on amino acid uptake inhibition caused by sorbate. The relationship between sorbate concentration and the amount of amino acid uptake inhibition was not linear. Compared with L-histidine, L-serine uptake was more sensitive to changes in pH, temperature, and sorbate concentration. Various degrees of amino acid uptake inhibition by sorbate may be related to differences between amino acid transport systems. The results of this study suggest that sorbate acts as a noncompetitive inhibitor of amino acid uptake in S. typhimurium.     

Effect of pH on the Heat Resistance of Clostridium sporogenes Spores in Minced Meat

S ummary : The effect of the pH value of minced meat on the heat resistance of Clostridium sporogenes spores inoculated in it was examined. A drop in pH from 6·0 to 4·8 decreased the decimal reduction time by 40%, irrespective of the heating temperature. In other words, the z value is independent of pH.     

Effects of pH on the mutagenicity of sodium azide in Neurospora crassa and Salmonella typhimurium

Sodium azide at various pH values did not cause a significant increase in the frequency of forward mutation above the control frequency at the adenine-3 (ad-3) region in resting conidia and in conidia from growing cultures of heterokaryons 12 and 59 of Neurospora crassa. Conidia from ad-3 mutants were plated with sodium azide at various pH values, and no obvious increase in reverse mutation above the controls was observed. Data are presented showing that sodium azide at pH 3 is inactivating conidia by interacting with the cytoplasma rather than the nucleus, and this may be the primary reasons that no mutation at the ad-3 region was detected. The dependence of sodium azide mutagenicity on pH was investigated in histidine-requiring mutants of Salmonella typhimurium using a suspension test. There were no significant differences in the reversion frequencies among the pH values (3-8) tested. Thus, no pH dependence is associated with sodium azide mutagenicity, nor are growth and/or DNA replication required for mutagenicity by sodium azide, in S. typhimurium.     

Inducible pH homeostasis and the acid tolerance response of Salmonella typhimurium.

The acid tolerance response (ATR) is an adaptive system triggered at external pH (pHo) values of 5.5 to 6.0 that will protect cells from more severe acid stress (J. Foster and H. Hall, J. Bacteriol. 172:771-778, 1990). Correlations between the internal pH (pHi) of adapted versus unadapted cells at pHo of 3.3 indicate that the ATR system produces an inducible pH-homeostatic function. This function serves to maintain the pHi above 5 to 5.5. Below this range, cells rapidly lose viability. Development of this pH homeostasis mechanism was sensitive to protein synthesis inhibitors and operated only to augment the pHi at pHo values below 4. In contrast, classical constitutive pH homeostasis was insensitive to protein synthesis inhibitors and was efficient only at pHo values above 4. Physiological studies indicated an important role for the Mg(2+)-dependent proton-translocating ATPase in affording ATR-associated survival during exposure to severe acid challenges. Along with being acid intolerant, cells deficient in this ATPase did not exhibit inducible pH homeostasis. We speculate that adaptive acid tolerance is important to Salmonella species in surviving acid encounters in both the environment and the infected host.     

Effect of pH, temperature, and potassium sorbate on amino acid uptake in Salmonella typhimurium 7136.

The effect of sorbate on L-serine and L-histidine uptake in Salmonella typhimurium was studied at various pH levels, temperatures, and amino acid and sorbate concentrations. Low pH had an apparent synergistic effect on amino acid uptake inhibition caused by sorbate. The relationship between sorbate concentration and the amount of amino acid uptake inhibition was not linear. Compared with L-histidine, L-serine uptake was more sensitive to changes in pH, temperature, and sorbate concentration. Various degrees of amino acid uptake inhibition by sorbate may be related to differences between amino acid transport systems. The results of this study suggest that sorbate acts as a noncompetitive inhibitor of amino acid uptake in S. typhimurium.     

Effect of NaCl, pH, temperature, and atmosphere on growth of Salmonella typhimurium in glucose-mineral salts medium

The interactions of pH (5.0, 6.0, and 7.0), temperature (19, 28, and 37 degrees C), and atmosphere (aerobic versus anaerobic) with NaCl (0, 1, 2, 3, 4, and 5%) on the growth of Salmonella typhimurium ATCC 14028 in defined glucose-mineral salts culture medium were evaluated. Response surface methodology was used to develop equations describing the response of S. typhimurium to environmental changes. The response to an increasing concentration of NaCl at any temperature tested was nonlinear. The maximum growth was predicted to occur at an NaCl concentration of 0.5%, a temperature of 19 degrees C, and an initial pH of 7.0 under aerobic growth conditions. The relative amounts of aerobic growth at 19 degrees C, pH 7.0, and NaCl concentrations of 0, 0.5, 1, 2, 3, 4, and 5% were predicted to be 99.2, 100.0, 98.8, 90.2, 73.5, 48.6, and 15.6%, respectively. Anaerobic growth conditions repressed the amount of growth relative to that under aerobic conditions, and the effects of NaCl and pH were additive at low salt concentrations; however, at higher salt levels anaerobiosis provided protection against the effects of NaCl.