Survival of Listeria monocytogenes in yogurt during storage at 4°C

Cows' milk was inoculated with ca 10³and 10⁷cfu/ml Listeria monocytogenes. After fermentation at 42°C for 0–5 h, the yogurt was stored at 4°C. Low and high inocula survived for 48 h and 7 d, respectively; L. monocytogenes cells were not detectable by direct plating or cold-enrichment after 5 and 15 d, respectively. In low inoculum samples, initial pH at the time of refrigeration was 4·9; the final pH at the time of last sampling was 4·2. In the samples with high inoculum the pH decreased from 5·0 to 4·2.     

Effect of Maillard reaction products on the growth of selected food-poisoning micro-organisms

The activity of the Maillard reaction products (MRP) prepared by heating (15 h at 90°C) a solution of 1·71 mol/l glucose and 2·05 mol/l glycine at pH values 6·0 and 8·8, against food-poisoning micro-organisms, including Staphylococcus aureus, Listeria monocytogenes, Salmonella typhimurium, Salmonella enteritidis and Aeromonas hydrophila , was investigated. High and low pH MRPs strongly inhibited A. hydrophila , whereas Staph. aureus and L. monocytogenes were slightly inhibited by the high pH MRPs only and Salmonella strains were resistant to both.     

Antimicrobial properties of plant essential oils and essences against five important food-borne pathogens

The antimicrobial properties of 21 plant essential oils and two essences were investigated against five important food-borne pathogens, Campylobacter jejuni, Salmonella enteritidis, Escherichia coli, Staphylococcus aureus and Listeria monocytogenes. The oils of bay, cinnamon, clove and thyme were the most inhibitory, each having a bacteriostatic concentration of 0·075% or less against all five pathogens. In general, Gram-positive bacteria were more sensitive to inhibition by plant essential oils than the Gram-negative bacteria. Campylobacter jejuni was the most resistant of the bacteria investigated to plant essential oils, with only the oils of bay and thyme having a bacteriocidal concentration of less than 1%. At 35 °C, L. monocytogenes was extremely sensitive to the oil of nutmeg. A concentration of less than 0·01% was bacteriostatic and 0·05% was bacteriocidal, but when the temperature was reduced to 4 °C, the bacteriostatic concentration was increased to 0·5% and the bacteriocidal concentration to greater than 1%.     

Growth and reducing capacity of Listeria monocytogenes under different initial redox potential

Aims:  To determine the reducing capacity of Listeria monocytogenes and to highlight the effect of redox potential on its growth parameters.
Methods and Results:  The reducing capacity of L. monocytogenes was monitored in Brain Heart Infusion Broth media at different initial redox potential (Eh) and pH at 37°C. The effect of Eh obtained by gas flushing (air, N₂ and N₂-H₂) or by adding potassium ferricyanide and dithiotreitol in concentration from 1 to 10 mmol l⁻¹on L. monocytogenes growth parameters at pH 6·0, 7·0 and 8·0 was investigated. A total change of 539 mV (±44 mV) from an initial redox value of +330 ± 8 mV to a more negative potential in redox curves was observed resulting from L. monocytogenes growth at pH 7·0 at 37°C. A significant influence of pH and redox potential on L. monocytogenes lag phase of growth was shown ( P  < 0·05).
Conclusions:  Listeria monocytogenes exhibited longer lag phase in reducing conditions and at pH 6·0. The method used to modify the redox potential was shown to have no effect on growth parameters at pH 7·0.
Significance and Impact of the Study:  The provided information on the extending lag time and the possible delayed growth of this major pathogen in reducing conditions might be useful for its control in foods.     

Fate of low temperature and acid-adapted Yersinia enterocolitica and Listeria monocytogenes that contaminate lactic acid decontaminated meat during chill storage

Pathogens found in the environment of abattoirs may become adapted to lactic acid used to decontaminate meat. Such organisms are more acid tolerant than non-adapted parents and can contaminate meat after lactic acid decontamination (LAD). The fate of acid-adapted Yersinia enterocolitica and Listeria monocytogenes, inoculated on skin surface of pork bellies 2 h after LAD, was examined during chilled storage. LAD included dipping in 1%, 2% or 5% lactic acid solutions at 55°C for 120 s. LAD brought about sharp reductions in meat surface pH, but these recovered with time after LAD at ≈1–1·5 pH units below that of water-treated controls. Growth permitting pH at 4·8–5·2 was reached after 1% LAD in less than 0·5 d (pH 4·8–5·0), 2% LAD within 1·5 d (pH 4·9–5·1) and after 5% LAD (pH 5·0–5·2) within 4 d. During the lag on 2% LAD meat Y. enterocolitica counts decreased by 0·9 log₁₀ cfu per cm² and on 5% LAD the reduction was more than 1·4 log₁₀ cfu per cm². The reductions in L. monocytogenes were about a third of those in Y. enterocolitica . On 1% LAD the counts of both pathogens did not decrease significantly. The generation times of Y. enterocolitica and L. monocytogenes on 2–5% LAD meats were by up to twofold longer than on water-treated controls and on 1% LAD-treated meat they were similar to those on water-treated controls. Low temperature and acid-adapted L. monocytogenes and Y. enterocolitica that contaminate skin surface after hot 2–5% LAD did not cause an increased health hazard, although the number of Gram-negative spoilage organisms were drastically reduced by hot 2–5% LAD and intrinsic (lactic acid content, pH) conditions were created that may benefit the survival and the growth of acid-adapted organisms.     

Nisin induces changes in membrane fatty acid composition of Listeria monocytogenes nisin-resistant strains at 10°C and 30°C

Listeria monocytogenes isolates resistant to 10⁵ IU ml^-1 nisin were obtained at 30°C (NR30) and at 10°C (NR10). Nisin prolonged the lag phase of isolate NR30 at 10°C. Isolates NR30 and NR10 did not produce a nisinase. Protoplasts of isolate NR30 were unaffected by exposure to nisin. The fatty acid composition from the wild-type strain and NR isolates was determined. As expected, temperature-induced differences in the C15/C17 fatty acid ratios were found. Growth of the NR strains in the presence of nisin resulted in significantly different C15/C17 ratios and a significant increase in the percentage of C16:0, C16: 1, C18:0 and C18: 1 fatty acids at 10°C and 30°C. Both the NR10 and NR30 isolates had similar growth rates at low temperatures, but these were slower than the wild-type strain. These results indicate that 'nisin resistance'is an environmentally defined phenotype and that nisin induces changes in the fatty acid composition of the membrane in L. monocytogenes nisin-resistant isolates regardless of the growth temperature.     

Immersion heat treatments for inactivation of Salmonella enteritidis with intact eggs

The effects of water-bath immersion heat treatments on the inactivation of Salmonellaenteritidis within intact shell eggs were evaluated. Six pooled strains of Salm. enteritidis ( ca 3×10⁸ cfu, inoculated near the centre of the yolk) were completelyinactivated within 50–57·5 min at a bath temperature of 58°C and within 65–75min at 57°C (an 8·4 to 8·5- D process per egg). Following the initial 24 to35-min come-up period, semilogarithmic survivor curves obtained at 58 and 57°C yieldedapparent decimal reduction times ( D -values) of 4·5 and 6·0 min, respectively.Haugh unit values increased during heating, while yolk index and albumen pH values wereunaffected. Albumen clarity and functionality were affected by the thermal treatments; therefore,extended whip times would be required for meringue preparation using immersion-heated eggwhites. Immersion-heated shell eggs could provide Salmonella -free ingredients for thepreparation of a variety of minimally-cooked foods of interest to consumers and foodserviceoperators.     

Modelling the effect of the redox potential and pH of heating media on Listeria monocytogenes heat resistance

Aims:  Study the effect of redox potential and pH of the heating media on Listeria monocytogenes heat resistance and model its action at fixed temperature.
Methods and Results:  The heat resistance of Listeria monocytogenes at 58°C was studied in Brain Heart Infusion broth as a function of pH (from 5·0 to 7·0) and redox potential ( E _h7). The media redox was adjusted with nitrogen gas, potassium ferricyanide and dithiothreitol. A Weibull model was used to fit survival curves. The heat resistance parameter (δ_58°C) was estimated from each inactivation curve. A major effect of pH was observed. Bigelow model was used to describe the effect of redox potential on the apparent L. monocytogenes heat resistance. The highest δ_58°C values have been obtained at pH 7·0 and oxidizing conditions.
Conclusions:  The developed model indicates that the E _h7 has a significant effect and varied depending on the pH of the heating media. The z _redox values, calculated from δ_58°C allowed quantifying the influence of heating media redox potential on L. monocytogenes thermal inactivation.
Significance and Impact of the Study:  The obtained model shows the action of redox potential on L. monocytogenes thermal destruction and might be useful to take into account in food thermal processes.     

Survival of Escherichia coli O157 : H7 in yoghurt during preparation and storage at 4°C

Cow's milk was inoculated with ca 10³ and 10⁷ cfu ml⁻¹ Escherichia coli O157 : H7. After fermentation at 42°C for 0–5 h, the yoghurt was stored at 4°C. Two kinds of yoghurt were used : traditional yoghurt (TY), made with Streptococcus thermophilus and Lactobacillus bulgaricus starter cultures, and 'bifido' yoghurt (BY), made with the two starter cultures plus Bifidobacterium bifidum . After 7 d E. coli O157 : H7 decreased from 3·52 to 2·72 log₁₀ cfu ml⁻¹ and from 7·08 to 5·32 log₁₀ cfu ml⁻¹ in TY, and from 3·49 to 2·73 log₁₀ cfu ml⁻¹ and from 7·38 to 5·41 log₁₀ cfu ml⁻¹ in BY. The pH values of yoghurt dropped from 6·6 to 4·5 and 4·4 in TY (for low and high pathogen inocula, respectively), and from 6·6 to 4·6 and 4·5 in BY (for low and high pathogen inocula, respectively).     

Survival of Listeria monocytogenes in sea water and effect of exposure on thermal resistance

Survival, recoverability and sublethal injury of two strains of Listeria monocytogenes , Scott A and an environmental strain KM, on exposure to sea water at 12·8 or 20·8 °C was determined using in situ diffusion chambers. Plate counts were used to assess recoverability and injury while 5-cyano-2,3-ditolyl tetrazolium chloride (CTC) reduction was used to determine respiratory activity. T₉₀ values (times for 10-fold decreases in numbers of recoverable cells) on non-selective medium (trypticase soya agar with 0·6% yeast extract) at 12·8 and 20·8 °C were 61·7 and 69·2 h for L. monocytogenes Scott A, and 103·0 and 67·0 h for L. monocytogenes KM, respectively. On selective medium (Oxford agar), T₉₀ values at 12·8 and 20·8 °C were 60·6 and 56·9 h for L. monocytogenes Scott A, and 83·0 and 65·9 h for L. monocytogenes KM, respectively. With Scott A, the percentage of sublethally injured cells at 12·8 and 20·8 °C was 1·7 and 17·7%, respectively, while for KM the values were 19·0 and 1·6%, respectively. The fraction of cells reducing CTC but which were not recoverable on plating progressively increased on exposure to sea water. Listeria monocytogenes KM challenged at 58 °C showed an apparent increase in heat resistance after exposure to sea water at 20·8 °C for 7 d ( D ₅₈= 2·64 min) compared with before exposure ( D ₅₈= 1·24). This increase in thermal resistance was not apparent at temperatures greater than 63 °C, and analysis of the best-fit regression lines fitted to the thermal data obtained from the two cell populations indicated that their thermal resistance was not significantly different ( P > 0·05) over the temperature range tested (58–62 °C).     

The use of the bacteriocin, nisin, as a preservative in ricotta-type cheeses to control the food-borne pathogen Listeria monocytogenes

The efficacy of nisin to control the food-borne pathogen Listeria monocytogenes in ricotta-type cheeses over long storage (70 d) at 6–8°C was determined. Cheeses were prepared from unpasteurized milk by direct acidification with acetic acid (final pH 5·9) and/or calcium chloride addition during heat treatment. Nisin was added in the commercial form of Nisaplin^® pre-production to the milk. Each batch of cheese was inoculated with 10²–10³ cfu g⁻¹ of a five-strain cocktail of L. monocytogenes before storage. Shelf-life analysis demonstrated that incorporation of nisin at a level of 2·5 mg l⁻¹ could effectively inhibit the growth of L. monocytogenes for a period of 8 weeks or more (dependent on cheese type). Cheese made without the addition of nisin contained unsafe levels of the organism within 1–2 weeks of incubation. Measurement of initial and residual nisin indicated a high level of retention over the 10-week incubation period at 6–8°C, with only 10–32% nisin loss.     

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.     

Isolation and characterization of nisin-producing Lactococcus lactis subsp. lactis from bean-sprouts

Bacterial isolates from bean-sprouts were screened for anti- Listeria monocytogenes bacteriocins using a well diffusion method. Thirty-four of 72 isolates inhibited the growth of L.monocytogenes Scott A. One, HPB 1688, which had the biggest inhibition zone against L.monocytogenes Scott A, was selected for subsequent analysis. Both ribotyping and DNAsequencing of 16S ribosomal RNA gene demonstrated that the isolate was Lactococcus lactis subsp. lactis . Polymerase chain reaction and nucleotide sequencing revealed that thegenomic DNA of the bean-sprout isolates contained a nisin Z structural gene. In MRS broth,bean-sprout isolate HPB 1688 survived at 3–4·5°C for at least 20 d, grew at 4°Cand produced anti-listerial compoundsat 5°C. When co-cultured with L. monocytogenes in MRS broth, the isolate inhibited thegrowth of L. monocytogenes at 4°C after 14d and at 10°C after 2 d. When co-inoculatedwith 10²cells g⁻¹ of L.monocytogenes on fresh-cut ready-to-eat Caesar salad, L. lactis subsp. lactis (10⁸cells g⁻¹) was able to reduce the number of L. monocytogenes by 1–1·4 logs after storage for 10 d at 7° and 10°C. A bacteriocin-producing Enterococcusfaecium was also able to reduce the numbers of L. monocytogenes onCaesar salad, butdid not act synergistically when co-inoculated with L. lactis subsp. lactis .     

Detection and characterization of a bacteriocin produced by Lactococcus lactis subsp. cremoris R isolated from radish

Bacteria isolated from radish were identified as Lactococcus lactis subsp. cremoris R and their bacteriocin was designated lactococcin R. Lactococcin R was sensitive to some proteolytic enzymes (proteinase-K, pronase-E, proteases, pepsin, α-chymotrypsin) but was resistant to trypsin, papain, catalase, lysozyme and lipase, organic solvents, or heating at 90 °C for 15, 30 and 60 min, or 121 °C for 15 min. Lactococcin R remained active after storage at −20 and −70 °C for 3 months and after exposure to a pH of 2–9. The molecular weight of lactococcin R was about 2·5 kDa. Lactococcin R was active against many food-borne pathogenic and food spoilage bacteria such as Clostridium, Staphylococcus, Listeria, Bacillus, Micrococcus, Enterococcus, Lactobacillus, Leuconostoc, Streptococcus and Pediococcus spp., but was not active against any Gram-negative bacteria. Lactococcin R was produced during log phase and reached a maximum activity (1600 AU ml⁻¹) at early stationary phase. The highest lactococcin R production was obtained in MRS broth with 0·5% glucose, at 6·5–7·0 initial pH values, 30 °C temperature and 18–24-h incubation times. Lactococcin R adsorbed maximally to its heat-killed producing cells at pH 6–7 (95%). Crude lactococcin R at 1280 AU ml⁻¹ was bactericidal, reducing colony counts of Listeria monocytogenes by 99·98% in 3 h. Lactococcin R should be useful as a biopreservative to prevent growth of food-borne pathogenic and food spoilage bacteria in ready-to-eat, dairy, meat, poultry and other food products. Lactococcin R differs from nisin in having a lower molecular weight, 2·5 kDa vs 3·4 kDa, and in being sensitive to pepsin and α-chymotrypsin to which nisin is resistant.     

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.     

Effectiveness of cell-adsorbed bacteriocin produced by Lactobacillus curvatus CWBI-B28 and selected essential oils to control Listeria monocytogenes in pork meat during cold storage

Aims:  To study the effectiveness of a combination of cell-adsorbed bacteriocin (CAB; a suspension of producer cells on which maximum bacteriocin has been immobilized by pH adjustments) of a Lactobacillus curvatus strain with oregano or savory essential oil to control Listeria monocytogenes in pork meat at 4°C.
Methods and Results:  The antimicrobial activity of the CAB and six different essential oils was tested by the well diffusion assay against L. monocytogenes M, Escherichia coli 10536 and Salmonella serotype Typhi CWBI-H1. The anti- Listeria activity of the CAB and oregano or savory essential oils was also investigated in pork meat. The results of the well diffusion assay showed that CAB was only inhibitory to L. monocytogenes while savory and oregano essential oils were the most active against the three indicator bacteria. In pork meat, Listeria counts have declined from c. 10² CFU g⁻¹ to below the detectable limit during the first week of storage in samples treated with CAB or oregano essential oil and in those treated with CAB combined with oregano or savory essential oil. However, the counts of L. monocytogenes have increased after the third week of storage in all samples with the exception of those treated with the combination of CAB and oregano essential oil. The combination of CAB with savory essential oil resulted in a 2-week delay of the growth rebound compared with samples treated with CAB alone.
Conclusions:  Addition of oregano or savory essential oil exhibited a synergistic effect with CAB to control L. monocytogenes in pork meat during storage at 4°C.
Significance and Impact of the Study:  The combination of CAB with oregano or savory essential oil may be effectively used in meat industry to enhance the safety and stability of meat products.     

Production and stability of pediocin N5p in grape juice medium

The production and stability of pediocin N5p from Pediococcus pentosaceus , isolated from wine, were examined in grape juice medium. Maximum growth and higher titre (4000 U ml^-1) were observed at a initial pH of 7·5 and 30°C. The activity of the inhibitory substance was stable between pH values from 2·0 to 5·0 at 4° and 30°C. At pH 10·0 it was completely inactivated. When submitted to 30 min at 80°, 100° and 115°C, maximal stability was observed at pH 2·0. Ethanol up to 10% did not affect pediocin activity at acid pH, nor did 40–80 mg 1^-1 SO₂, independently or combined with different ethanol concentrations, affect inhibitory activity.     

Modelling the effectiveness of a natural antimicrobial on Salmonella enteritidis as a function of concentration, temperature and pH, using conductance measurements

The growth of Salmonella enteritidis in a brain heart infusion medium was monitored using the traditional viable count method and by conductance measurements using a Rabit impedance instrument. Growth curves (log₁₀ cfu ml⁻¹ vs time) at three different concentrations of oleuropein (0, 0·2 and 0·8%), pH values in the range of 5–8 and incubation temperatures from 22 to 42 °C were modelled using the Gompertz equation. A good correlation between the maximum growth rate from the viable count method and the maximum slope of the conductance curve from the impedance instrument was established. Based on this correlation, the maximum specific growth rate of Salm. enteritidis was modelled as a function of the oleuropein concentration, initial pH values and the incubation temperature with a quadratic equation, using a new, larger dataset of growth measurements by conductance. The developed model was validated by statistical comparison of predicted growth rates with growth rates determined by the viable count method, within the limits of the antimicrobial, pH and temperature domain.     

Physiological and biochemical studies on psychrotolerance in Listeria monocytogenes

Studies were undertaken to explain the ability of Listeria monocytogenes to grow at low temperatures in a chemostat. It was found that when grown in continuous culture at a dilution rate of 0·02 h⁻¹ L. monocytogenes had a lower proportion of anteiso -17:0, and a higher proportion of anteiso -15:0, and smaller chain fatty acids when grown at 10°C compared to 30°C. A previously unreported glycolipid was only seen after growth at low temperature. Growth temperature had no effect on the rate of glucose uptake.     

Effects of gaseous environment and temperature on the storage behaviour of Listeria monocytogenes on chicken breast meat

Portions of skinless chicken breast meat (pH 5·8) were inoculated with a strain of Listeria monocytogenes and stored at 1, 6 or 15°C in (1) aerobic conditions; (2) 30% CO₂+ air; (3) 30% CO₂+ N₂; and (4) 100% CO₂. When samples were held at 1°C the organism failed to grow under any of the test conditions, despite marked differences between treatments in spoilage rate and ultimate microflora. At 6°C counts of L. monocytogenes increased ca 10-fold in aerobic conditions before spoilage of the meat, but only when the inoculum culture was incubated at 1°C rather than 37°C. In CO₂ atmospheres growth of L. monocytogenes was inhibited on meat held at 6°C, especially under 100% CO₂. By contrast, storage at 15°C led to spoilage of the meat within 2 d, in all gaseous environments, and listeria levels increased up to 100-fold. Differences in the behaviour of L. monocytogenes on poultry and red meats are discussed.