Effect of prior heat shock on heat resistance of Listeria monocytogenes in meat

The effect of prior heat shock on the thermal resistance of Listeria monocytogenes in meat was investigated. A sausage mix inoculated with approximately 10(7) L. monocytogenes per g was initially subjected to a heat shock temperature of 48 degrees C before being heated at a final test temperature of 62 or 64 degrees C. Although cells heat shocked at 48 degrees C for 30 or 60 min did not show a significant increase in thermotolerance as compared with control cells (non-heat shocked), bacteria heat shocked for 120 min did, showing an average 2.4-fold increase in the D64 degrees C value. Heat-shocked cells shifted to 4 degrees C appeared to maintain their thermotolerance for at least 24 h after heat shock.     

Effect of rising temperature on the heat resistance of Listeria monocytogenes in meat emulsion

The heat resistance of a strain of L. monocytogenes was determined both in broth and in meat emulsion. The D -values for meat emulsion were approximately two to three times higher than those for broth and also the z -value increased significantly. The micro-organism proved to be more resistant when the cells were heated up slowly (0·5°C/min) to constant temperatures of 60, 63 and 66°C in meat emulsion. The D ₆₀, D ₆₃ and D ₆₆ were, respectively 12·95, 5·4 and 2·3 min. Results may have implications in the survival of Listeria monocytogenes in particular food preparations.     

The effect of acid shock on the heat resistance of Listeria monocytogenes

The effect of acid shock on the heat resistance of Listeria monocytogenes was investigated. After growth for 24 h at 30°C in tryptic soy broth containing 0.6% yeast extract, cell culture suspensions of L. monocytogenes were acidified with HCl or acetic acid over various time periods before being heated in whole milk to a temperature of 58°C. When cells were acid-shocked immediately with HCl for 1, 2 or 4 h, those acid-shocked for 1 h demonstrated the largest increase in thermotolerance as compared to control cells, when heated at 58°C in whole milk. In fact, cells acid-shocked for longer than 1 h with HCl demonstrated in some instances a decreased recovery as compared to control cells. Other types of acid-shock treatments included lowering the pH gradually either over a 4 h or a 24 h period. However, regardless of the type of acid-shock treatment, cells acid-shocked with HCl (but not acetic acid) prior to heating had significantly greater heat resistance as compared to control (non-acid-shocked) cells. It appears that acidification with HCl prior to final heating can enhance the heat resistance of L. monocytogenes.     

Effect of tempering on the heat resistance of Listeria monocytogenes

Cultures of Listeria monocytogenes were preheated at 48°C for 1 h in broth and UHT milk before heating at 60°C. Preheating resulted in a marked increase in heat resistance compared with untreated controls.     

The heat resistance of Listeria monocytogenes

Heat resistance data for Listeria monocytogenes are reviewed. The organism is appreciably more resistant than common Salmonella serotypes but less resistant than Salmonella senftenberg 775W. Reports that the organism can survive heating at 80°C have not been substantiated and are incompatible with carefully determined D and z values in milk and a range of foods. Cooking food to an internal temperature of 70°C for 2 min is adequate to ensure destruction of L. monocytogenes. Normal pasteurization procedures will inactivate L. monocytogenes in milk but the margin of safety is greater for vat pasteurization than for high temperature short time treatment.     

Thermotolerance of Listeria monocytogenes and Salmonella typhimurium after sublethal heat shock.

The effect of prior heat shock on thermotolerance of Listeria monocytogenes and Salmonella typhimurium in broth culture was determined. Bacteria were grown at the permissive temperature of 35 degrees C, sublethally heated at 35 (control), 42, 48, and 52 degrees C (nonpermissive control) for various times, and inactivated at either 57.8 or 52 degrees C. The induction of increased thermotolerance by heat shock, although consistent within each experiment, was generally not significant for L. monocytogenes; the increase was significant for S. typhimurium. Temperature shift experiments with L. monocytogenes suggested that induced thermotolerance was not long lived unless the shock temperature was maintained.     

Mathematical modelling of the heat resistance of Listeria monocytogenes

The heat resistance of Listeria monocytogenes phagovar 2389/2425/3274/2671/47/108/340 (1992 French outbreak strain) in broth was studied at 55, 60 and 65 °C. Experiments were carried out on bacterial cultures in three different physiological states: cultures at the end of the log phase, cultures heat-shocked at 42 °C for 1 h, and subcultures of cells resistant to prolonged heating. Survivor curves were better fitted using a sigmoidal equation than the classical log-linear model. This approach was justified by the existence of heat resistance distributions within the bacterial populations. Peaks (log₁₀ of heating time) of heat resistance distributions of untreated, heat-shocked, and selected cultures at 55, 60 and 65 °C were 0·34, −0·90 and −1·84 min, 0·74, −0·51 and −1·24 min, and 0·17, −0·94 and−1·45 min, respectively. The widths of the distributions are proportional to 0·29, 0·36and 0·41 min^0·5, 0·26, 0·36 and 0·41 min^0·5, and 0·34, 0·44 and 0·41 min^0·5. An increase in thethermal tolerance could then be induced by sublethal heat shock or by selection of heatresistant cells.     

Listeria monocytogenes serotypes in Italian meat products

Listeria monocytogenes was isolated and enumerated in Italian fresh ground beef, fresh pork meat and industrial sausages. All the samples contained less than 2000 L. monocytogenes /g of meat. The main serotype isolated was 1/2c (56.9%). Other serotypes isolated included 1/2a, 1/2b, 3c, 4b and 4c. A prevalence of less virulent serotypes over more virulent was thus noted. It seems that the low incidence of listeriosis from these products is related to the low concentration and virulence of L. monocytogenes present.     

Thermal resistance of wild-type and antibiotic-resistant Listeria monocytogenes in meat and potato substrates

AIMS: This study aimed to elucidate the relationship, if any, between the acquisition/possession of antibiotic resistance in strains of Listeria monocytogenes and the resistance of such strains to heat stress. METHODS AND RESULTS: D-values calculated using a linear survival model were used to compare the heat resistance of two wild-type (WT) and two antibiotic (streptomycin)-resistant (AR) mutant strains of L. monocytogenes measured in minced beef and potato substrates at 55 degrees C, with and without prior heat shock at 48 degrees C. In both minced beef and potato, no significant differences (P < 0.05) between D-values of AR and WT strains were noted. Heat shock did not significantly increase D-values of WT or AR strains in minced beef, while in potato slices, D-values in almost all cases were significantly higher in samples which had received heat-shock treatment. In minced beef, the use of a non-selective/overlay recovery medium did not result in higher D-values for any strains, while in potato, significantly higher (P < 0.05) D-values were obtained in most cases. CONCLUSION: The presence or absence of antibiotic resistance genes did not modulate the heat resistance of the strains examined in this study. SIGNIFICANCE AND IMPACT OF THE STUDY: The study demonstrated that heat shock, and the type of media used to determine bacterial numbers during heat processing, can significantly affect the D-values obtained.     

Effect of pre- and post-heat shock temperature on the persistence of thermotolerance and heat shock-induced proteins in Listeria monocytogenes

The effect of incubation temperature, before and after a heat shock, on thermotolerance of Listeria monocytogenes at 58°C was investigated. Exposing cells grown at 10°C and 30°C to a heat shock resulted in similar rises in thermotolerance while the increase was significantly higher when cells were grown at 4°C prior to the heat shock. Cells held at 4°C and 10°C after heat shock maintained heat shock-induced thermotolerance for longer than cells held at 30°C. The growth temperature prior to inactivation had negligible effect on the persistence of heat shock-induced thermotolerance. Concurrent with measurements of thermotolerance were measurements of the levels of heat shock-induced proteins. Major proteins showing increased synthesis upon the heat shock had approximate molecular weights of 84, 74, 63, 25 and 19 kDa. There was little correlation between the loss of thermotolerance after the heat shock and the levels of these proteins. Thermotolerance of heat shocked and non-heat shocked cells was described by traditional log-linear kinetics and a model describing a sigmoidal death curve (logistic model). Employing log-linear kinetics resulted in a poor fit to a major part of the data whereas a good fit was achieved by the use of a logistic model.     

Antimicrobial resistance of Listeria monocytogenes

Listeria monocytogenes is an opportunistic pathogen that causes rare but frequently fatal infections, termed listerioses. In general, strains of L. monocytogenes are susceptible to a wide range of antibiotics, except for the cephalosporins, fluorochinolones and fosfomycin (Hof, 1991). The current therapy of choice is a combination of ampicillin and aminoglycoside, usually gentamicin (Lorber, 1997). In cases when it is not possible to use a beta-lactam antibiotic, second-choice therapy involves the use of an association of trimethoprim with a sulfonamide, such as in co-trimoxazole, in which the more active in the combination seems trimethoprim, synergized by the sulfa compound. Other second line agents for listeriosis include erythromycin and vancomycin (Temple and Nahata, 2000). The first strains of L. monocytogenes resistant to antibiotics were reported in 1988 (Poyart-Salmeron et al. 1990) The present paper reviews the current state of affairs with regard to the resistance of L. monocytogenes isolated from food products and clinical material to different antibiotics, with particular emphasis on those used in the therapy of listeriosis.     

Fate of Listeria monocytogenes in processed meat products during refrigerated storage.

The fate of Listeria monocytogenes during refrigerated storage was determined on several processed meat products, including ham, bologna, wieners, sliced chicken, sliced turkey, fermented semidried sausage, bratwurst, and cooked roast beef. The meats were surface inoculated with a five-strain mixture of less than or equal to 200 or ca. 10(5) L. monocytogenes cells per package, vacuum packaged, and stored at 4.4 degrees C. Survival or growth of listeriae was determined for up to 12 weeks of storage or until the product was spoiled. The organism survived but did not grow on summer sausage, grew only slightly on cooked roast beef, grew well on some wiener products but not on others, grew well (10(3) to 10(5) CFU/g increase within 4 weeks) on ham, bologna, and bratwurst, and grew exceptionally well (10(3) to 10(5) CFU/g increase within 4 weeks) on sliced chicken and turkey. The rate of growth depended largely upon the type of product and the pH of the product. Growth was most prolific on processed poultry products. The organism generally grew well on meats near or above pH 6 and poorly or not at all on products near or below pH 5. These results indicate the importance of preventing postprocessing contamination of L. monocytogenes in a variety of ready-to-eat meat products.     

Ecogenetics of antibiotic resistance in Listeria monocytogenes

The acquisition process of antibiotic resistance in an otherwise susceptible organism is shaped by the ecology of the species. Unlike other relevant human pathogens, Listeria monocytogenes has maintained a high rate of susceptibility to the antibiotics used for decades to treat human and animal infections. However, L. monocytogenes can acquire antibiotic resistance genes from other organisms’ plasmids and conjugative transposons. Ecological factors could account for its susceptibility. L. monocytogenes is ubiquitous in nature, most frequently including reservoirs unexposed to antibiotics, including intracellular sanctuaries. L. monocytogenes has a remarkably closed genome, reflecting limited community interactions, small population sizes and high niche specialization. The L. monocytogenes species is divided into variants that are specialized in small specific niches, which reduces the possibility of coexistence with potential donors of antibiotic resistance. Interactions with potential donors are also hampered by interspecies antagonism. However, occasional increases in population sizes (and thus the possibility of acquiring antibiotic resistance) can derive from selection of the species based on intrinsic or acquired resistance to antibiotics, biocides, heavy metals or by a natural tolerance to extreme conditions. High-quality surveillance of the emergence of resistance to the key drugs used in primary therapy is mandatory.     

Plasmids in Listeria monocytogenes in relation to cadmium resistance.

One hundred and seventy-three unrelated Listeria monocytogenes strains isolated from humans, animals, the environment, and food were analyzed for the presence of plasmids. Extrachromosomal DNA was found in 28% of the strains. Plasmid DNA was extracted more frequently from L. monocytogenes serogroup 1 strains (35%) than from serogroup 4 strains (15%). Among strains from food and the environment, 40% and 29%, respectively, harbored plasmids, whereas only 13% of the strains from humans and animals with listeriosis bore plasmids. We also investigated the susceptibility of 90 strains to seven antibiotics and four heavy-metal salts. No antibiotic resistance could be detected, but 95.3% of the plasmid-positive strains and only 12.7% of the plasmid-negative strains were resistant to cadmium. The plasmid-determined genetic basis of cadmium resistance was proven by conjugation between strains of L. monocytogenes and by cure of the plasmid. This is the first time that plasmids of L. monocytogenes have been shown to be associated with cadmium resistance.     

Plasmids in Listeria monocytogenes in relation to cadmium resistance.

One hundred and seventy-three unrelated Listeria monocytogenes strains isolated from humans, animals, the environment, and food were analyzed for the presence of plasmids. Extrachromosomal DNA was found in 28% of the strains. Plasmid DNA was extracted more frequently from L. monocytogenes serogroup 1 strains (35%) than from serogroup 4 strains (15%). Among strains from food and the environment, 40% and 29%, respectively, harbored plasmids, whereas only 13% of the strains from humans and animals with listeriosis bore plasmids. We also investigated the susceptibility of 90 strains to seven antibiotics and four heavy-metal salts. No antibiotic resistance could be detected, but 95.3% of the plasmid-positive strains and only 12.7% of the plasmid-negative strains were resistant to cadmium. The plasmid-determined genetic basis of cadmium resistance was proven by conjugation between strains of L. monocytogenes and by cure of the plasmid. This is the first time that plasmids of L. monocytogenes have been shown to be associated with cadmium resistance.     

Survival and heat resistance of Listeria monocytogenes after exposure to alkali and chlorine

A strain of Listeria monocytogenes isolated from a drain in a food-processing plant was demonstrated, by determination of D values, to be more resistant to the lethal effect of heat at 56 or 59 degrees C following incubation for 45 min in tryptose phosphate broth (TPB) at pH 12.0 than to that of incubation for the same time in TPB at pH 7.3. Cells survived for at least 6 days when they were suspended in TPB at pHs 9.0, 10.0, and 11.0 and stored at 4 or 21 degrees C. Cells of L. monocytogenes incubated at 37 degrees C for 45 min and then stored for 48 or 144 h in TPB at pH 10.0 were more resistant to heat treatment at 56 degrees C than were cells stored in TPB at pH 7.3. The alkaline-stress response in L. monocytogenes may induce resistance to otherwise lethal thermal-processing conditions. Treatment of cells in 0.05 M potassium phosphate buffer (pH 7.00 +/- 0.05) containing 2.0 or 2.4 mg of free chlorine per liter reduced populations by as much as 1.3 log(10) CFU/ml, while treatment with 6.0 mg of free chlorine per liter reduced populations by as much as 4.02 log(10) CFU/ml. Remaining subpopulations of chlorine-treated cells exhibited some injury, and cells treated with chlorine for 10 min were more sensitive to heating at 56 degrees C than cells treated for 5 min. Contamination of foods by L. monocytogenes cells that have survived exposure to processing environments ineffectively cleaned or sanitized with alkaline detergents or disinfectants may have more severe implications than previously recognized. Alkaline-pH-induced cross-protection of L. monocytogenes against heat has the potential to enhance survival in minimally processed as well as in heat-and-serve foods and in foods on holding tables, in food service facilities, and in the home. Cells surviving exposure to chlorine, in contrast, are more sensitive to heat; thus, the effectiveness of thermal processing in achieving desired log(10)-unit reductions is not compromised in these cells.     

Cold shock induction of thermal sensitivity in Listeria monocytogenes

Cold shock at 0 to 15 degrees C for 1 to 3 h increased the thermal sensitivity of Listeria monocytogenes. In a model broth system, thermal death time at 60 degrees C was reduced by up to 45% after L. monocytogenes Scott A was cold shocked for 3 h. The duration of the cold shock affected thermal tolerance more than did the magnitude of the temperature downshift. The Z values were 8.8 degrees C for controls and 7.7 degrees C for cold-shocked cells. The D values of cold-shocked cells did not return to control levels after incubation for 3 h at 28 degrees C followed by heating at 60 degrees C. Nine L. monocytogenes strains that were cold shocked for 3 h exhibited D(60) values that were reduced by 13 to 37%. The D-value reduction was greatest in cold-shocked stationary-phase cells compared to cells from cultures in either the lag or exponential phases of growth. In addition, cold-shocked cells were more likely to be inactivated by a given heat treatment than nonshocked cells, which were more likely to experience sublethal injury. The D values of chloramphenicol-treated control cells and chloramphenicol-treated cold-shocked cells were no different from those of untreated cold-shocked cells, suggesting that cold shock suppresses synthesis of proteins responsible for heat protection. In related experiments, the D values of L. monocytogenes Scott A were decreased 25% on frankfurter skins and 15% in ultra-high temperature milk if the inoculated products were first cold shocked. Induction of increased thermal sensitivity in L. monocytogenes by thermal flux shows potential to become a practical and efficacious preventative control method.