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Article

Growth and Biocontrol of Listeria monocytogenes in Greek Anthotyros Whey Cheese without or with a Crude Enterocin A-B-P Extract: Interactive Effects of the Native Spoilage Microbiota during Vacuum-Packed Storage at 4 °C

by
Nikoletta Sameli
and
John Samelis
*
Dairy Research Department, Institute of Technology of Agricultural Products, Hellenic Agricultural Organization “DIMITRA”, Katsikas, 45221 Ioannina, Greece
*
Author to whom correspondence should be addressed.
Foods 2022, 11(3), 334; https://0-doi-org.brum.beds.ac.uk/10.3390/foods11030334
Submission received: 15 December 2021 / Revised: 20 January 2022 / Accepted: 21 January 2022 / Published: 25 January 2022
(This article belongs to the Special Issue Microbes in Cheese: Isolation, Molecular Detection and Characterization)
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Abstract

:
Effective biopreservation measures are needed to control the growth of postprocess Listeria monocytogenes contamination in fresh whey cheeses stored under refrigeration. This study assessed growth and biocontrol of inoculated (3 log10 CFU/g) L. monocytogenes in vacuum-packed, fresh (1-day-old) or ‘aged’ (15-day-old) Anthotyros whey cheeses, without or with 5% of a crude enterocin A-B-P extract (CEntE), during storage at 4 °C. Regardless of CEntE addition, the pathogen increased by an average of 2.0 log10 CFU/g in fresh cheeses on day 15. Gram-negative spoilage bacteria also increased by an average of 2.5 log10 CFU/g. However, from day 15 to the sell-by date (days 35–40), L. monocytogenes growth ceased, and progressively, the populations of the pathogen declined in most cheeses. This was due to an unmonitored, batch-dependent natural acidification by spoilage lactic acid bacteria, predominantly Leuconostoc mesenteroides, which reduced the cheese pH to 5.5, and finally to ≤5.0. The pH reductions and associated declines in pathogen viability were greater in the CEntE-treated samples within each batch. L. monocytogenes failed to grow in cheeses previously ‘aged’ in retail for 15 days. Overall, high population levels (>7.5 log10 CFU/g) of psychrotrophic Enterobacteriaceae, particularly Hafnia alvei, were associated with an extended growth and increased survival of L. monocytogenes during storage.

1. Introduction

Listeria monocytogenes remains a food-borne pathogen of great concern for the dairy industry [1,2]. The public health concerns associated with the continuing prevalence of L. monocytogenes in various retail cheeses have been demonstrated by several listeriosis outbreaks, mostly linked to fresh nonripened and/or surface-ripened soft and semisoft cheeses [3,4,5,6]. In general, challenge testing should be done by following the European Commission (2014) technical guidance document on all types of ready-to-eat (RTE) foods that do not comply with the Regulation 2073/2005 safety criteria categories in relation to L. monocytogenes and thus may support its growth during retail distribution and storage [7,8,9,10]. In specific, only RTE cheese products that do not support listerial growth, either a priori based on the pH/aw set value criteria or after research-based challenge testing, can harbor a maximum allowable L. monocytogenes level of 100 CFU/g during retail shelf life [11]. Numerous early to recent challenge studies have shown that fresh whey cheeses are the riskiest soft RTE cheese products with regard to L. monocytogenes outgrowth because of their high pH (>6.0–6.8) and moisture (>60–80%) content that corresponds with water activity values much above the aw 0.94 threshold [12,13,14,15,16,17]. Therefore, the strict alternative microbiological criterion ‘absence of L. monocytogenes in 25 g’, also defined as the ‘zero tolerance’ approach, is required for all RTE whey cheeses, especially when these specialty products are distributed and consumed fresh [11].
Fresh whey cheeses are practically free of native microbiota after manufacture because the indigenous bacteria of the whey, or of the raw milk added to the whey, are inactivated during heating at the high temperatures (>80–95 °C) applied to coagulate the water-soluble milk whey proteins, and no starter cultures are applied after heating [15,18]. Afterward, postprocess handling of the curd results in cross-contamination with a diverse native microbiota, mainly psychrotrophic Gram-negative bacteria, lactic acid bacteria (LAB), staphylococci, spore-forming bacilli, clostridia, yeasts and molds [18,19,20,21]. Therefore, fresh whey cheeses are prone to rapid microbial deterioration, especially at abusive storage temperatures [18], while also being an excellent substrate for the growth of pathogen contaminants. In particular, the psychrotrophic pathogen L. monocytogenes may outgrow in the absence or low presence of a protective background microbiota in fresh whey cheeses during aerobic or anaerobic cold storage conditions to cause infection. Indeed, whey cheeses have been linked to listeriosis cases and product recalls, particularly the most popular Ricotta cheese, originally from Italy [1,22,23]. Various antimicrobial methods have been tested or applied commercially to control microbial contamination and growth in Ricotta-type whey cheeses, with emphasis on L. monocytogenes [14,22,24,25,26]. Biopreservation using natural antimicrobials or protective, bacteriocin-producing (Bac+) LAB cultures is one of the most attractive and consumer-friendly methods to control the growth of L. monocytogenes during retail distribution and storage of Ricotta and other fresh whey cheeses [2,17,27]. In specific, effective antilisterial measures (hurdles) are needed for Myzithra, Anthotyros and Manouri, the most popular traditional Greek whey cheese varieties, because all of them supported a prolific (4.2–6.1 log10 CFU/g) temperature-dependent growth of an artificial L. monocytogenes postprocess contamination during aerobic storage at 5, 12 and 22 °C [13]. Moreover, L. monocytogenes and/or other Listeria spp. were found to persist naturally in 12.8%, 1.5% and 2.2% of whey cheese samples from the Greek market surveyed in the years 1990, 1996 and 2010, respectively [28,29].
Samelis et al. [15] conducted the first biopreservation study that applied Nisaplin, a commercial nisin concentrate, to control L. monocytogenes postprocess contamination in a traditional Greek whey cheese stored at 4 °C in vacuum packages (VPs) for up to 45 days. Nisin was added either to the Anthotyros whey (100 or 500 IU/g) before heating or to the fresh cheese (500 IU/g) before vacuum packaging. In the control cheeses without nisin, L. monocytogenes strain Scott A exceeded 7 log10 CFU/g after only 10 days of VP storage at 4 °C. All nisin treatments had an immediate lethal effect (0.7–2.2 log reduction) after inoculation, but weak antilisterial effects during storage, except for the treatment with 500 IU/g added to the whey which suppressed pathogen growth below the inoculation level of 4 log10 CFU/g throughout storage [15]. An additional technological concern was that Nisaplin reversed the natural spoilage microbiota of Anthotyros from Gram-positive LAB in the control cheeses without nisin to Gram-negative bacteria; this reversal was more pronounced in the most effective Nisaplin treatments [15]. Later efforts to replace Nisaplin with viable cells of the wild, nisin A-producing (NisA+) Lactococcus lactis strain genotype M78/M104 able to produce sufficient amounts of nisin in situ in traditional Greek cheese milk fermentations [30,31] were of limited success in fresh Anthotyros cheese. The primary reason was the inability of the NisA+ L. lactis strain to grow competitively and produce nisin at 4 °C. Conversely, at 12 °C, the NisA+ strain along with adventitious LAB reduced the pH and the sensory quality of the fresh Anthotyros; those defects counteracted the benefits associated with an enhanced inhibition of L. monocytogenes growth at abusive storage conditions [32].
Overall, a reduced in situ bacteriocin (nisin) production due to a lack of growth of the Bac+ (Nis+) culture at refrigeration temperatures remains one of the main concerns regarding the failure of typical mesophilic dairy-protective strains to control the growth of L. monocytogenes in cold-stored soft cheeses [2,33,34]. Alternate biopreservation methods for fresh whey cheeses are the application of psychrotrophic Bac+ strains of nonaciduric LAB, such as Carnobacterium spp. [25,26], or the addition of heat-stable (class I or II) LAB bacteriocin concentrates, other than nisin, active against L. monocytogenes and spoilage non-LAB bacteria, such as enterocins. An increasing number of promising applications of enterocin-producing (Ent+) Enterococcus spp. strains or enterocin preparations in dairy foods are discussed in recent comprehensive reviews [27,35,36], including studies on fresh whey cheeses [17]. In particular, the addition of purified, semipurified or crude enterocin extracts may be a more effective and permissible biopreservation method than the direct addition of viable Ent+ antilisterial cultures in fresh soft (whey) cheeses stored under refrigeration because Enterococcus spp. are not psychrotrophic bacteria and the genus does not have a GRAS status [36].
In a previous study, we assessed the effects of a crude enterocin A-B-P extract on the evolution and species composition of the specific spoilage microbiota prevailing in fresh vacuum-packaged Anthotyros whey cheeses stored at 4 °C [37]. This research is a follow-up challenge study to evaluate growth interactions of L. monocytogenes with the specific spoilage bacterial species during refrigerated (4 °C) storage of fresh vacuum-packaged Anthotyros whey cheeses without or with enterocin A-B-P supplementation. It has been noted that beyond the in situ production or external addition of bacteriocins, the native microbial community as a whole can also be important in preventing the growth of L. monocytogenes in fresh soft cheeses [2]. However, neither sole competitive effects of specific cheese spoilage bacteria against L. monocytogenes nor potentially enhanced interactive antilisterial effects of the native microbiota associated with the use of enterocin(s) have so far been evaluated in fresh (Greek) whey cheeses; therefore, this was the dual aim of the present study.

2. Materials and Methods

2.1. Preparation of the Crude Enterocin A-B-P Extract

The preparation of the crude enterocin A-B-P extract (CEntE) and most methods followed in this study were according to the procedures described by Sameli et al. [37]. Additional experimental methods, such as the whey cheese inoculation with L. monocytogenes and additional analyses relating to the interactive growth of the pathogen with the whey cheese spoilage microbiota, are described in later paragraphs.
Briefly, 150 mL of filter-sterilized CEntE was prepared by combining equal (50 mL) volumes of the cell-free supernatant (CFS) of fresh (24 h at 30 °C) MRS broth (Neogen Culture Media, formerly Lab M, Heywood, UK) cultures of three Ent+ Enterococcus faecium strain biotypes originally isolated from Greek Graviera cheese: the EntA+ E. faecium KE64 (GenBank Acc. No MW644963), the multiple Ent+ (entA-entB-entP) E. faecium KE82 (MW644969) and the multiple Ent+ (entA-entB-entP) E. faecium KE118 (not yet deposited in GenBank) [38]. The same CEntE (150 mL) used by Sameli et al. [37] was also used in the challenge experiments of this follow-up study for direct data comparison. The CEntE containing enterocin A (secreted by all three strains) plus enterocins B and P (secreted by KE82 and KE118) was prepared without preceding pH adjustment and stored at –30 °C until use [37]. The Ent+ antilisterial activity, the enterocin titer (400 AU/mL) and the stability of the enterocin titer of the thawed CEntE after every use [37] were determined by the well diffusion assay procedures previously described by Vandera et al. [39].

2.2. Commercial Anthotyros Whey Cheese Samples

Eight retail VP samples (500 g each) of fresh Anthotyros cheese, representing four batches previously coded A, B, C and D, were obtained from two semi-industrial dairy plants located in Epirus, Greece [37]. In specific, fresh cheese batches A and B were products of the traditional dairy Pappas Bros. (Skarfi E.P.E., Filippiada, Greece), our collaborator SME in the BIO TRUST project, while batches C and D were fresh retail Anthotyros cheese products of another traditional dairy located near Ioannina.
For the purposes of this challenge study, three additional VP Anthotyros whey cheese batches, representing three independent cheese productions in the second dairy plant, were purchased from the Ioannina market while they had already been stored in retail for 15 days after processing, based on their labeling. These nonfresh (15-day-old) Anthotyros batches, coded X-15A, X-15B and X-15C, were used in the experiments for specific reasons relating to their age and explained in later paragraphs.

2.3. Cheese Inoculation, Enterocin Addition and Storage

Within one hour after transportation to our microbiology laboratory in insulated ice boxes, all fresh whey cheese samples (batches A to D) were removed from their original VP films under a laminar flow hood. Then, the 500 g soft cheese masses of the two retail VP samples from each batch were combined aseptically for experimental reasons addressed by Sameli et al. [37]. Next, 50 g portions of soft cheese were transferred by weighing, with the aid of presterilized stainless steel spatulas, into new clean vacuum bags of small size suitable for food storage (Cryovac BK3550 bag; Food Care, Sealed Air Corporation, Milano, Italy). Afterward, all bag samples were artificially contaminated with L. monocytogenes strain No. 10 by adding 1 mL of inoculum in each bag, diluted to yield approximately 3 log10 of listerial cells/g of cheese. The inoculated cells were from a fresh (24 h; 30 °C) 10 mL culture of L. monocytogenes strain No. 10 in brain heart infusion broth (BHI; Neogen), decimally diluted in sterile quarter-strength Ringer solution (Neogen, Lab M) to obtain the cell density for inoculation. L. monocytogenes No. 10 (serotype 4ab) is a highly suitable and convenient avirulent target strain, similar to virulent L. monocytogenes strains. According to a previous Galotyri PDO cheese challenge study by Sameli et al. [40], strain No. 10 was used as a single target inoculum to exclude potential strain variation effects of L. monocytogenes from the Anthotyros whey cheese trials to facilitate the assessment of the CEntE antilisterial effects. For this task, half of the Listeria-inoculated, fresh whey cheese bags were vacuum-packaged directly (vacuum level: minus 1 bar; 99.9%) using a MiniPack-Torre, model MVS45L vacuum sealing machine (Dalmine BG, Italy). The remaining half of the bags were vacuum-packaged, as above, following the addition of 5% (v/w) CEntE; i.e., 2.5 mL of thawed CEntE was added last in each bag with 50 g of cheese before sealing [37]. All Listeria-inoculated cheese samples, with or without CEntE addition, were massaged by hand for 30 s from outside the bag to evenly distribute the inocula and the active enterocin molecules before vacuum packaging. All cheese samples were stored in a refrigerated incubator (Velp Scientifica FOC 225I, Milano, Italy) at 4.0 ± 0.1 °C and analyzed on days 0, 8, 15, 30 and 40 of storage, according to the sampling protocol and the retail shelf life duration of both Anthotyros brand products reported by Sameli et al. [37]
The three ‘aged’ whey cheese batches, X-15A, X-15B and X-15C, were removed from their original bags, distributed in 50 g portions in new bags, inoculated with L. monocytogenes No. 10 and vacuum-packaged without previous addition of 5% CEntE by the same procedures described above. This supplementary challenge experiment was conducted to evaluate whether the growth potential and/or survival pattern of L. monocytogenes might change in the case cross-contamination of commercial Anthotyros with the pathogen occurs in an ‘aged’ (15-day-old) naturally acidified whey cheese after opening in retail or at home, compared to a fresh (24-hour-old) whey cheese product after manufacture. The VP samples of the ‘aged’ batches were also stored at 4 °C, as above, and analyzed microbiologically and for pH on days 0, 8 and 20 of additional refrigerated storage, which corresponded to a total retail VP storage for 15, 23 and 35 days, respectively, under refrigeration.

2.4. Cheese Analyses

For microbial quantification, each VP sample was opened aseptically near a Bunsen burner and 10 g of whey cheese was homogenized with 90 mL of sterilized quarter-strength Ringer solution in stomacher bags (Lab Blender, Seward, London, UK) for 60 s. The homogenates were decimally diluted with Ringer, and duplicate 0.1 mL samples of the appropriate dilutions were spread on total and selective enumeration agar media, all purchased from Neogen Culture Media. The populations of L. monocytogenes strain No. 10 were counted on Palcam agar incubated at 30 °C for 48 h; the plates were rechecked at 72 to 96 h of incubation for detection of slow recovery of enterocin-stressed and/or acid-stressed colonies of strain No. 10 in the whey cheese samples. Total mesophilic whey cheese spoilage bacteria were enumerated on Milk Plate Count Agar (MPCA) incubated at 37 °C for 48–72 h. Total psychrotrophic spoilage bacteria were enumerated on Tryptone Soya Agar with 0.6% yeast extract (TSAYE) incubated at 12 °C for 5–7 days. Selective enumerations of the dominant LAB and Gram-negative bacteria colonies were performed on high-dilution MPCA/37 °C and TSAYE/12 °C plates for most samples, as detailed by Sameli et al. [37]. Total aciduric LAB were enumerated on MRS agar incubated at 30 °C for 72 h. Pseudomonas and related Gram-negative bacteria were enumerated on cetrimide–fucidin–cephaloridine (CFC) agar, incubated at 25 °C for 48 h [37].
In addition, for the purposes of this study, total mesophilic cheese spoilage bacteria prevailing in the three ‘aged’ whey cheese batches, X-15A, X-15B and X-15C, discriminated in LAB and Gram-negative bacteria colonies as above, were counted on M17 agar plates, incubated at 22 °C for 72 h. Total enterobacteria were enumerated on double-layered Violet Red Bile Glucose (VRBG) agar plates incubated at 37 °C for 24–48 h; enterococci, on Kanamycin Aesculin Azide (KAA) agar incubated at 37 °C for 48 h; total staphylococci, on Baird-Parker agar base with egg yolk tellurite incubated at 37 °C for 48 h; and yeasts, on Rose Bengal Chloramphenicol (RBC) agar incubated at 25 °C for 5 days.
The pH was measured with a digital pH meter (Jenway 3510, Dunmow, Essex, UK) by immersing the electrode in the soft cheese mass after the microbiological sampling.

2.5. Isolation and Characterization of the Dominant Whey Cheese Spoilage Microbiota

The most prevalent bacterial species during storage, with emphasis on the end of storage when specific spoilage species had been established in each cheese batch, were isolated and identified. Briefly, the terminal spoilage association of all fresh whey cheese samples after 40 days of VP storage at 4 °C was characterized by purification and biochemical identification of a total of 120 LAB and 96 Gram-negative bacteria isolates from the highest dilution MPCA/37 °C, MRS/30 °C and TSAYE/12 °C plates, i.e., 40 LAB isolates from each agar medium, 30 isolates from each whey cheese batch A to D and 15 isolates from the CN or CEntE sample of each batch [37]. The species identification of 17 LAB isolates selected to represent the most prevalent spoilage LAB biotypes was assured by 16S rRNA gene sequencing; their identities are provided by Sameli et al. [37].
An additional 24 LAB and 12 Gram-negative bacterial isolates from the most diversified whey cheese batches C and D were collected on day 15 of VP storage at 4 °C and characterized to check whether they were similar to, or differed from, the isolates of the specific spoilage LAB or Gram-negative species prevailing in the same batches on day 40. Moreover, 20 LAB and 6 Gram-negative bacterial isolates were recovered from the ‘aged’ X-15A whey cheese batch, as a random representative retail product of the second plant, to check their species similarity to the respective isolates prevailing in the spoiling fresh whey cheese batches C and D on day 15.
Following transfer of their colonies for growth in glass tubes with 10 mL MRS or BHI broth, each of the additional 44 LAB and 18 Gram-negative bacteria isolates was checked for purity by streaking on MRS agar (pH 5.7 ± 0.1) or BHI agar (pH 7.4 ± 0.2) incubated at 30 °C for 72 h or 25 °C for 48 h, respectively; stored in MRS or BHI broth with 20% (w/v) glycerol at −30 °C; and later characterized, according to the procedures described by Sameli et al. [37]. Briefly, the 44 LAB isolates were first confirmed for their Gram-positive and catalase-negative reactions and then were tested for cell morphology, growth at 37 °C and 45 °C, gas (CO2) production from glucose, ammonia (NH3) production from arginine, growth in 4% and 6.5% NaCl, slime formation from sucrose and fermentation of 13 differentiating sugars. All Gram-negative bacteria isolates were confirmed for their Gram reaction, separated into oxidase-positive and oxidase-negative isolates and then identified at the genus or species level using the API 20E kit and the corresponding biochemical identification code manual (BioMerieux, Marcy l’ Etoile, Lyon, France), according to the manufacturer’s instructions.

2.6. Statistical Analysis

The microbiological data of the fresh whey cheese batches (n = 4; main challenge experiment) and of the ‘aged’ whey cheese batches (n = 3; supplementary challenge experiment) were converted to log10 CFU/g and along with the data for pH were subjected to a one-way analysis of variance using the software Statgraphics Plus for Windows v. 5.2 (Manugistics, Inc., Rockville, MD, USA). The means were separated by the least significant difference procedure at the 95% confidence level (p < 0.05) for determining the significance of differences with time of whey cheese storage and between the CN and Ent-treated fresh cheese samples on each sampling interval of the main experiment.

3. Results

3.1. Behavior of L. monocytogenes in Fresh Anthotyros Whey Cheeses: Potential pH-Dependent Antilisterial Effects of the CEntE during VP Storage at 4 °C

Mean populations of L. monocytogenes strain No. 10 increased (p < 0.05) by an average of 1.21 log10 CFU/g and 1.33 log10 CFU/g in the fresh untreated (CN) and the Ent-treated Anthotyros whey cheese samples, respectively, from day 0 to 8 of VP storage at 4 °C (Table 1). Neither the prolific mean growth of the native LAB (1.8–2.4 log10 CFU/g increase) and Gram-negative bacteria (1.1–1.8 log10 CFU/g increase) in all fresh cheese samples nor the presence of 0.5% CEntE prevented pathogen growth during the first week at 4 °C. Contrary to our experimental anticipation, this early growth of L. monocytogenes was not even retarded in the Ent-treated samples compared to the control (CN) samples (Table 1). Instead, the high mean initial pH 6.8 of fresh Anthotyros supported the growth of L. monocytogenes (approximately 50-fold increase) while the mean population levels of an actively growing antagonistic LAB biota were still below the 7 log10 CFU/g threshold. Accordingly, the initial, almost neutral, pH values underwent minor changes (p > 0.05) in most fresh whey cheese samples from day 0 to 8 of storage (Table 1).
Listeria monocytogenes continued growth at reduced rates in both treatments from day 8 to 15. This resulted in further population increases of the pathogen, which on average were 0.65 log10 CFU/g and 0.73 log10 CFU/g in the untreated and the Ent-treated whey cheese samples, respectively (Table 1). On day 15, the mean pH was reduced (p < 0.05) to pH 6.2 in the CN samples, and even more (pH 6.0) in the Ent-treated samples. The above pH reductions were due to an unmonitored natural acidification by native LAB which prevailed on days 15, 30 and 40 in all cheese samples and quite faster in the Ent-treated samples on day 15. Gram-negative bacteria also increased well above the 7 log10 CFU/g level in most whey cheese samples during storage. However, the prevalence of the antagonistic LAB biota was always higher than the prevalence of Gram-negative bacteria on days 15, 30 and 40 (Table 1). Accordingly, from day 15 to 30, growth of L. monocytogenes ceased in most cheese samples, and the pathogen populations generally started to decline. Afterward, from day 30 to 40, except for one sample to be discussed later, the populations of L. monocytogenes either remained constant or continued declining while the pH was still decreasing in most naturally acidified whey cheese samples. Overall, pH decreases and consequently the declines of L. monocytogenes were greater (p < 0.05) in the Ent-treated than in the CN cheese samples on the late days 30 and 40 of storage. Thus, the natural whey cheese acidification and the associated antagonistic effects of LAB against L. monocytogenes were somehow stimulated in the presence of the CEntE after the first two weeks of VP storage at 4 °C (Table 1).
At this point, certain major batch-dependent or plant-dependent differences in the growth/survival pattern of L. monocytogenes (Figure 1A) should be examined in association with the pH reduction pattern in each whey cheese batch (Figure 1B). First, the significant early growth of the pathogen in all batches supported by the minor changes of their high pH from day 0 to 8 is clearly shown in Figure 1. However, Figure 1A further shows that this early listerial growth was significantly more restricted in batch D, particularly in the CN samples, while it was more pronounced in batch C, particularly in the Ent-treated samples. Notably, batch D and C samples correspondingly had the lowest (pH 6.5–6.6) and the highest (pH 7.1–7.2) pH values on day 8 (Figure 1B). In particular, batch C was the only whey cheese product whose initial pH was increased slightly above 7.0 after the first week of storage (Figure 1B). In fact, although batches C and D were fresh Anthotyros cheese products of the second dairy plant manufactured with only a three-day difference in the plant’s processing line, the initiation of their pH-dependent bacterial spoilage and the support of L. monocytogenes growth immediately after processing varied greatly.
Consistent with the above findings, growth continuation of L. monocytogenes during the second week (day 8 to 15) of storage was not always significant (Table 1), because the individual pathogen increases differed greatly from batch to batch (Figure 1A). In specific, the growth levels of L. monocytogenes became higher by 1–2 log10 CFU/g in batches A and C compared to B and D (Figure 1A). In relation, the Ent-treated samples of batch C (pH 6.53) and the CN samples of batch A (pH 6.38) had the highest pH values on day 15 (Figure 1B). Major batch-dependent and/or treatment-dependent fluctuations in L. monocytogenes populations continued to occur from day 15 to 30, when, however, the growth of the pathogen ceased and its viable populations started to decline in most batches or treatments (Figure 1A). The most prominent exception was the continuation of major growth of L. monocytogenes toward its highest population level of 6.55 log10 CFU/g in the untreated (CN) samples of batch C (pH 5.50) on day 30 (Figure 1A). Eventually, with the prominent exception of the CN samples of batch B which supported listerial growth till the end of storage, the viability of L. monocytogenes was stabilized (batch D/CN) or underwent further minor (A/CN; B/Ent; C/Ent) or major (A/Ent; C/CN; D/Ent) declines from day 30 to 40, which also varied greatly between batches and treatments (Figure 1A).
In summary, the growth of L. monocytogenes was not fully controlled in any of the fresh whey cheese products studied. Indeed, from its lowest population after inoculation (day 0) to its highest batch-dependent population on day 15, or 30 or 40, the total net growth of L. monocytogenes in the CN and Ent-treated samples of batches A, B, C and D was 2.62, 2.26, 3.14 and 0.89 log10 CFU/g and 2.05, 1.42, 3.23 and 1.53 log10 CFU/g, respectively. Eventually, the whey cheese samples formed two distinct clusters on the basis of the terminal L. monocytogenes survival on day 40: the first ‘high-risk’ cluster with final pathogen populations ≥5.5 log10 CFU/g included batch C and the untreated (CN) batches A and B, whereas the second ‘low-risk’ cluster with final pathogen populations ≤4.5 log10 CFU/g included batch D and the Ent-treated batches A and B (Figure 1A). Batch C was the most supportive whereas batch D was the least supportive for L. monocytogenes growth, irrespective of CEntE and despite both batches being produced in the same plant. Increased antilisterial effects that were likely to be associated with the addition of 0.5% CEntE occurred in the fresh Anthotyros products of the Pappas dairy only, i.e., in batch A and mainly in batch B (Figure 1A). Overall, significant reductions of L. monocytogenes associated with the CEntE occurred after two weeks at 4 °C, provided the cheese pH declined below 5.5. Therefore, on late storage days 30 and 40, the Ent-treated samples of all whey cheese batches clustered at a more acidic pH range than their untreated (CN) counterpart samples (Figure 1B). This finding supports that the growth of native LAB and thereby the natural whey cheese acidification were somehow stimulated in the presence of the CEntE. Stimulation of LAB growth and acidification in turn enhanced the in situ antilisterial activity of the enterocin A, B and P molecules contained in the CEntE after the whey cheese matrix was acidified to pH values from 5.2 down to 4.5 (Figure 1B).

3.2. Effects of the Native Spoilage Microbiota on the Growth/Survival Pattern of L. monocytogenes in Fresh VP Anthotyros Whey Cheeses during Storage at 4 °C

Apparently, the aforementioned batch-dependent and plant-dependent differences in the rate and extent of natural acidification, L. monocytogenes growth and efficacy of the CEntE were affected by the numbers and types of spoilage bacteria prevailing in each whey cheese batch, without or with CEntE, during VP storage at 4 °C. Therefore, the evolution of specific spoilage species in batches A to D, previously studied in detail by Sameli et al. [37], was reconsidered herein relative to the growth/survival pattern of L. monocytogenes. For this purpose, additionally to the total microbial growth data in Table 1, the selective growth on MRS and CFC agar plates of the two main spoilage bacterial groups, LAB and Pseudomonas-like bacteria, in each whey cheese batch during VP storage at 4 °C is presented in Figure 2A and Figure 2B, respectively. In addition, an overview of the dominant spoilage LAB and Gram-negative bacteria species in each batch by the end of storage is shown (Table 2). It should be clarified that the graphical data in Figure 2 were previously provided in the supplementary Tables S4 and S5 by Sameli et al. [37].
Starting from the kinetic data, Figure 2 clearly shows the exponential cogrowth of LAB and Pseudomonas-like bacteria in all fresh Anthotyros batches during mainly the first (day 8) and the second (day 15) weeks of storage. Additionally, the growth cessation of Pseudomonas and related Gram-negative bacteria after day 15 (Figure 2B) while the growth of LAB continued until day 30 (Figure 2A) is evident, in agreement with the corresponding total mean counts in Table 1. However, by examining growth kinetics more carefully in each batch, it can be noted that batch D samples, which supported the least early growth of L. monocytogenes (Figure 1A) and had the lowest pH on day 8 (Figure 1B), also had the highest levels of natural aciduric LAB contamination at the beginning of storage (day 0) and the fastest and greatest LAB growth on MRS from day 0 to 15 (Figure 2A). Conversely, all other fresh whey cheese batches had an approximate 2 log10 CFU/g lower postprocess LAB contamination on day 0 (Figure 2A), while batches A and B produced in the Pappas dairy plant had an approximate 2 log10 CFU/g higher postprocess contamination with Pseudomonas-like bacteria (Figure 2B). Hence, after the first week (day 8), the levels of exponentially growing Pseudomonas-like bacteria in batches A, B and C ranged from a maximum of 6.5 log10 CFU/g to a minimum of 5.5 log10 CFU/g (Figure 2B), while the corresponding levels of LAB were lower by approximately 1.5 log10 CFU/g, irrespective of CEntE treatment (Figure 2A). After the second week (day 15), growth of Pseudomonas-like bacteria in batches A to C increased close to, or above, the 8 log10 CFU/g level (Figure 2B), while the growth levels of aciduric LAB on MRS were still 1–1.5 log10 CFU/g units lower, particularly in the untreated (CN) samples (Figure 2A). Batch D continued to be an exception because it had 10-fold higher populations of LAB than Pseudomonas-like bacteria on day 15 (Figure 2). As a result, growth of Pseudomonas-like bacteria in batch D was suppressed one week earlier than in batches A, B and C (Figure 2B) due to the faster growth increases of competitive LAB on days 8 (>7 log10 CFU/g) and 15 (> 8 log10 CFU/g) of storage (Figure 2A). Regarding the most prominent interactions of the native spoilage microbiota with L. monocytogenes, the high (> 4 log10 CFU/g) postprocess contamination of batch D with LAB and their early growth above the 7 log10 CFU/g threshold (Figure 2A) retarded pathogen growth within the first two weeks of VP storage at 4 °C (Figure 1A). In contrast, the high (>4 log10 CFU/g) postprocess contamination and/or the high (>6–8 log10 CFU/g) growth of Pseudomonas and related Gram-negative spoilage bacteria in batches A to C (Figure 2B) allowed or enhanced the growth of L. monocytogenes during early (day 0 to 15) and, in few samples, during late (day 15 to 40) periods of storage (Figure 1A). The fact that the untreated (CN) samples of batches C (mainly) and B continued to support the growth of L. monocytogenes after days 15 and 30, respectively, appeared to correlate with the fact that the above two CN batch treatments had the lowest LAB (MRS) counts on day 30 (Figure 2A) while simultaneously having Pseudomonas (CFC) counts at the highest (8 log10 CFU/g) level (Figure 2B).
Eventually, the whey cheese samples formed two distinct clusters on the basis of the final levels of Pseudomonas-like bacteria surviving on days 30 and 40 (Figure 2B), which coincided with the respective two clusters formed by L. monocytogenes survivors on day 40 (Figure 1A). The first ‘high-risk’ cluster with final pathogen populations ≥ 5.5 log10 CFU/g that included batch C and the untreated (CN) batches A and B (Figure 1A) had final CFC counts ranging from 6.4 to 8.0 log10 CFU/g (Figure 2B), whereas the second ‘low-risk’ cluster with final pathogen populations ≤4.5 log10 CFU/g that included batch D and the Ent-treated batches A and B (Figure 1A) had final CFC counts ranging from 3.0 to 5.7 log10 CFU/g (Figure 2B). Thus, the increased low pH-dependent antilisterial effects correlated strongly with reduced levels of Gram-negative spoilage bacteria in all Ent-treated batches except for batch C, and in batch D irrespective of CEntE addition. By somehow stimulating LAB growth in batches A and B from day 15 to 30 (Figure 2A), the CEntE enhanced natural acidification (Figure 1B) and the declines of L. monocytogenes (Figure 1A) and Gram-negative spoilage bacteria (Figure 2B) by late storage. The high final CFC counts in the CN and mainly the Ent-treated samples of batch C (Figure 2B) coincided with the fact that this particular cheese product was the most supportive for L. monocytogenes growth (Figure 1A).
The overviews of the spoilage LAB and Gram-negative bacteria species in batches A to D after 30 to 40 days of storage at 4 °C (Table 2), previously detailed by Sameli et al. [37], provide further potential associations with the growth variability of L. monocytogenes noted between batches and treatments (Figure 1A). For instance, it is worth noting that (i) indigenous nonaciduric Carnobacterium maltaromaticum isolates were recovered from the high-pH batches B and C only (Table 2), both supporting growth of L. monocytogenes on late storage days (Figure 1A); (ii) the high terminal levels of Gram-negative spoilage bacteria in batch C (Figure 2B), which was at the highest risk with regard to the outgrowth of L. monocytogenes (Figure 1A), consisted mainly of Hafnia alvei (Table 2); (iii) the high levels of Gram-negative bacteria in the CN samples of batches A and B that were less supportive for L. monocytogenes growth than batch C comprised mainly oxidase-negative fermentative enterobacteria isolates of Rahnella aquatilis and Serratia liquefaciens, whereas oxidase-positive, nonfermentative Pseudomonas spp. isolates were more frequent in the corresponding Ent-treated samples of batches A and B (Table 2), in which the progressive declines of L. monocytogenes during storage were much greater (Figure 1A); and (iv) the ‘lowest risk’ batch D contained members of the nonfermentative genera Aeromonas and Flavibacterium along with another H. alvei biotype recovered at 3 to 4 log10 CFU/g lower levels than the dominant H. alvei biotype in batch C (Table 2).
Overall, regardless of supplementation with the CEntE, the terminal spoilage community of all fresh Anthotyros whey cheese batches was dominated by psychrotrophic, non-slime-producing biotypes of Leuconostoc mesenteroides (Table 2). In addition, one typical slime-producing biotype of Lc. mesenteroides was recovered mainly from the batch A and B products of the Pappas dairy plant (Table 2). Otherwise, neither did the numerical isolate distribution of the four distinct Lc. mesenteroides biotypes in the CN and Ent-treated samples vary greatly nor were other psychrotrophic LAB species exclusively isolated from the Ent-treated samples of batches A and B or from the ‘low-risk’ batch D samples (Table 2) to suggest an increased species-dependent or biotype-dependent antilisterial activity in the above products. However, to our surprise, batch D was the only whey cheese product that contained Streptococcus thermophilus after 40 days of VP storage at 4 °C (Table 2). Because proliferate of this thermophilic dairy starter species during fresh Anthotyros whey cheese storage at refrigeration temperatures was impossible, the origin of those dormant S. thermophilus isolates as a ‘natural LAB contaminant’ in batch D was assessed and is discussed in Section 3.3 below.

3.3. Effects of Anthotyros Aging on the Behavior of L. monocytogenes during VP Storage at 4 °C

Altogether, the results in Figure 1 and Figure 2 reveal that the high growth potential of L. monocytogenes in fresh VP Anthotyros products stored at 4 °C was suppressed after the cheese pH declined to pH 5.5, or below, due to the progressive LAB growth causing natural acidification. In most trials, the cold storage time breakpoint for growth cessation of L. monocytogenes was day 15. As it was illustrated, earlier growth cessation times were noted in batch D due to the superior early growth of LAB, whereas later growth cessation times were noted in CN samples of batches C (mainly) and B due to the high prevalence of Gram-negative bacteria associated with delayed cheese pH declines. Therefore, it appears that ‘cold aging’ of fresh Anthotyros cheese products per se might prevent the growth of an accidental natural L. monocytogenes contamination during retail storage, irrespective of treatment with the CEntE or other preservatives. To validate this, three individual ‘aged’ (15-day-old) retail batches of VP Anthotyros were inoculated with L. monocytogenes strain No. 10, without CEntE addition, and analyzed comparatively to the diverse fresh whey cheese batches C to D of the same dairy plant; the results are summarized in Table 3.
As it was anticipated, L. monocytogenes strain No. 10 failed to grow (<0.5 log10 CFU/g increase) but survived without death in all ‘aged’ whey cheese batches for an additional 20 days, i.e., 35 days of total storage (Table 3). On day 0 of additional storage, the reduced mean pH 6.1 of the three ‘aged’ whey cheese samples reflected the prevalence of a native competitive LAB biota already grown well above 7.5 log10 CFU/g, thus preventing the growth of L. monocytogenes after day 15 of total storage (Table 3). In agreement with our previous findings [37], the cheeses aged for 15 days under the retail storage conditions contained high levels of total Gram-negative bacteria (7.6 to 7.8 log10 CFU/g) and Pseudomonas-like bacteria (7.3 to 7.8 log10 CFU/g) grown on M17/22 °C and CFC/25 °C, respectively. Another finding in agreement was that the mean levels of total aciduric LAB on MRS/30 °C and coliform bacteria on VRB/37 °C were lower than the levels of total cheese spoilage bacteria on M17/22 °C. Overall, psychrotrophic Gram-negative bacteria and LAB dominated in the ‘aged’ retail cheeses before inoculation with L. monocytogenes strain No. 10 (day 0). During storage of the inoculated ‘aged’ cheeses for additional 20 days, spoilage LAB continued growth in all VP samples, while the growth of Gram-negative bacteria ceased or declined (Table 3). Levels of enterococci, total staphylococci and yeasts fluctuated greatly in the ‘aged’ batches on day 15 of retail storage. However, their counts never exceeded 7, 6 and 5 log10 CFU/g, respectively, after 20 days of additional storage (Table 3); thus, they were subdominant spoilers in the ‘aged’ whey cheeses. The mean pH of the ‘aged’ cheese batches declined further (p < 0.05) to a final pH range of 4.6 to 5.0 after 20 days of additional storage at 4 °C (Table 3). Thus, as it happened in most fresh batches before (Figure 1B), the natural whey cheese acidification by native LAB continued up to day 35 of total storage (Table 3). This progressive LAB acidification resulted in complete growth suppression of L. monocytogenes until the sell-by date of the ‘aged’ VP Anthotyros products of the second dairy plant (Table 3).
In an attempt to associate the great variations in pH and the growth pattern of L. monocytogenes with potential differences in the specific spoilage LAB and Gram-negative bacteria species prevailing in the Anthotyros products of the second dairy, an additional 44 representative LAB (Table 4) and 18 Gram-negative bacterial (Table 5) isolates, recovered from TSAYE, MRS and CFC plates of the fresh spoiling batches C and D on day 15 and the ‘aged’ batch X-15A, were identified according to Sameli et al. [37]. The majority of the prevalent LAB isolates (38/44; 86.4%) on day 15 were non-slime-producing Leuconostoc spp.; most of them (27/44; 61.4%) were assigned to three atypical L. mesenteroides biotypes L1–L3 (Table 4), also found to prevail in the terminal spoilage LAB association of batches C and D on day 40 (Table 2). However, while biotype L1 of L. mesenteroides predominated in batch D on day 15 (Table 4) and continued so on day 40 (Table 2), no biotype L1 isolates and only one biotype L2 isolate of L. mesenteroides were recovered from batch C on day 15. Most LAB isolates from batch C on day 15 were assigned to an additional Leuconostoc biotype L7, which fermented lactose, galactose, trehalose and raffinose but did not ferment L-arabinose and D-xylose (Table 4). Thus, L7 was an intermediate Leuconostoc argentinum/lactis biotype [41,42]. Notably, biotype L7 isolates were also recovered from the ‘aged’ batch X-15A, which mainly contained biotype L2 and L3 L. mesenteroides isolates (Table 4). Consistent with the results in Table 2, nonaciduric C. maltaromaticum was isolated from batch C, but not from batch D, on day 15; C. maltaromaticum was isolated from batch X-15A as well (Table 4). Finally, it should be stressed that no MRS or TSAYE isolates of S. thermophilus were recovered from batch D on day 15 (Table 4). However, all fresh (day 0) samples of batch D were confirmed to harbor an unexpectedly high (ca. 7-log10 CFU/g) population of a typical S. thermophilus starter biotype selectively grown/enumerated on MPCA and M17 agar plates at 37 °C (data not shown). Apparently, the fresh curd of batch D was somehow ‘postprocess contaminated’ heavily with those starter S. thermophilus cells, which might have multiplied to the 7-log level while the curd was still warm in the plastic molds transferred for draining.
Representative isolates of Hafnia alvei biotype I were exclusively isolated from batch C on day 15 (Table 5) and eventually became the predominant spoilage Gram-negative bacterium in batch C (Table 2) on days 30 and 40 of storage [37]. Conversely, Klebsiella oxytoca and, most surprisingly, Shewanella putrefaciens were recovered from batch D on day 15 (Table 5). Notably, S. putrefaciens, a specific spoilage species of animal foods at pH > 6.0, was not detectable in batch D by late storage (Table 2), probably because it was inhibited by the acid pH; instead, the spoilage association of batch D on days 30 and 40 was dominated by H. alvei and Aeromonas strains (Table 2). H. alvei and Pantoea sp. were recovered from the ‘aged’ spoiling samples of batch X-15A as well (Table 5).

4. Discussion

The significant growth of L. monocytogenes strain No. 10 in the fresh untreated (CN) Anthotyros samples during VP storage at 4 °C was consistent with previous studies indicating a high growth potential of this psychrotrophic pathogen in cold-stored whey cheeses [12,13,14,15,16,17,23] and confirmed the utmost need for in-package antimicrobial hurdles to control growth of postprocess listerial contamination in RTE Greek whey cheeses [15]. The mixed CFS of three Ent+ E. faecium strains (CEntE) evaluated as an alternative biopreservative to Nisaplin in this study had no immediate lethal antilisterial effects, because, apparently, it contained fewer active enterocin A-B-P molecules than the nisin molecules contained in the concentrated Nisaplin powder [15]. However, the antilisterial effectiveness of the CEntE appeared to increase after day 15, while the pH was declining below 5.5 during storage. The enterocin A-B-P activity against the target L. monocytogenes cells was probably enhanced at the low pH range of the naturally acidified Anthotyros cheeses, similarly to nisin and most enterocins in vitro and in situ in fresh acid-curd cheeses or other fermented cheese types [2,27,36,43]. In particular, the in situ antilisterial effects of E. faecium KE82 used as a bioprotective adjunct culture in fermenting cheese milks were stronger in the presence of a commercial starter culture containing S. thermophilus as the primary milk acidifier than in the respective cheese milks without addition of the starter [44]. In general agreement with the above studies, in this study, the antilisterial effects of the CEntE in most Ent-treated whey cheese samples increased with delay, which means that afterward, the native LAB biota, dominated by atypical L. mesenteroides strains, reduced the cheese pH below 5.5 to 4.5 to enhance the combined enterocin A-B-P activity. It is well known that the in situ effectiveness of the enterocins A and B increases when they are copresent to act synergistically [45,46].
Previous studies on the use of purified, semipurified or crude enterocin preparations for inhibiting L. monocytogenes in fresh, high-pH whey cheeses are scarce, if any; i.e., refer to the recent reviews by Silva et al. [27] and Falardeau et al. [2]. Most previous studies on this topic have dealt with soft acid-curd cheeses and other real or model cheese fermentations. Under these conditions, the native LAB present in the raw milk, or the starter LAB added to the milk after pasteurization, grow rapidly and acidify the milk, clotted with or without rennet. Rapid acidification creates an unfavorable low-pH niche for the growth of L. monocytogenes, whose inactivation is enhanced by adding enterocins or the viable Ent+ Enterococcus strains [40,47,48,49,50]. Conversely, in fresh whey cheeses stored under refrigeration, natural acidification is slow because of the lack of starter cultures and the reduced growth rates of the native LAB at cold temperatures. Therefore, a strong enterocin activity sufficient to cause major inactivation of L. monocytogenes in situ is very unlikely at least during early storage days when the natural whey cheese acidification is still mild. To our knowledge, there is only one previous challenge study by Aspri et al. [17] that found a complete 3 log10 CFU/g net inactivation of the inoculated target strain L. monocytogenes 33,413 in fresh Cyprian Anari whey cheese, after coinoculation with 6 log10 CFU/g of the EntA/B+ E. faecium DM 33 and aerobic storage of the cheeses at 4 °C for 9 days only. Interestingly, E. faecium DM 33 strain, which was listericidal, and two additional EntA/B+ E. faecium strains, which exerted listeriostatic effects in Anari under the same challenge conditions, originated from raw donkey milk [17].
In this study, neither was the growth of inoculated L. monocytogenes strain No. 10 prevented nor was the early growth of psychrotrophic spoilage Enterobacteriaceae and Pseudomonadaceae suppressed. However, the increasing growth competition and prevalence of naturally selected members of Lc. mesenteroides, Lc. lactis and C. maltaromaticum exerted a mitigation effect against the pathogen and the Gram-negative spoilage community in the ‘aging’ Anthotyros whey cheeses after day 15 of VP/4 °C storage. In particular, the populations of L. monocytogenes never increased above 6.5 log units, not even in the untreated (CN) samples of batches A to D. Significant growth inhibition or mitigation effects against Gram-negative spoilage bacteria have been attributed to the use of Carnobacterium spp. in the form of single selected adjunct strains or commercial bioprotective cultures (i.e., Lyofast CNBAL, Lyofast FPR2) in fresh MAP Ricotta cheese [25,26] and another Italian fresh cheese type [51]. Lyofast CNBAL containing Carnobacterium spp. was the best performing commercial culture against spoilage Pseudomonas spp. in fresh Ricotta cheese [26]. However, the primary role of the Lyofast CNBAL bioprotective culture marketed by Sacco System (Italy) is a strong (approximately 4-log10 CFU/g) inhibition of L. monocytogenes growth by its Ent+ Carnobacterium spp. strain constituents in situ in cheese ripened at low temperatures and without sugar [52]. In this study, there was no evidence that the presence of C. maltaromaticum in batches B and C was associated with bacteriocin (carnocin)-mediated antilisterial effects in situ. However, native Bac+ strains within the most prevalent Lc. mesenteroides, Lc. lactis and C. maltraromaticum isolates might exist to have contributed to the retardation or the strongest inhibition of L. monocytogenes growth in the CN samples of batches B and D, respectively (Figure 1A). Although the production of bacteriocins, such as mesentericin Y105, by dairy Leuconostoc spp. has been well established [53], applications of the producer strains or of Leuconostoc bacteriocin preparations to cheese and other dairy products have so far been very limited [2,27,43]. Conversely, few promising applications of bacteriocins or Bac+ strains of S. thermophilus and S. macedonicus against cheese spoilage bacteria have been reported [27,43], including a recent study on the antibacterial effects of in situ produced thermophilin T by S. thermophilus ACA-DC 0040 in fermented whey used for Myzithra cheese production [54]. This particular application is emphasized because, in this study, the increased growth inhibition of L. monocytogenes in batch D during storage (Figure 1A) might have been due to beneficial metabolic activities of the excessive S. thermophilus ‘natural contamination’ that had occurred during the handling of the fresh batch D curd in the plant for 24 h before VP storage under refrigeration [37]. Additional studies are required to elucidate the potential presence and impact of Bac+ isolates in fresh Anthotyros cheeses.
The native microbial community as a whole (i.e., termed microbial consortia that include adventitious LAB and various other Gram-positive and Gram-negative bacterial species and yeasts) has been reported to be more effective against L. monocytogenes than individual strains alone or artificial simplified consortia of few selected strains [2,55,56,57]. However, the microbial consortia mechanisms and specific strain interactions behind the in situ inactivation or growth inhibition of L. monocytogenes in fresh cheeses are still unclear [2]. In this study, apart from the prevalent native LAB biota dominated by several diverse Lc. mesenteroides biotypes followed by C. maltraromaticum and Lc. lactis/argentinum biotypes, the Gram-negative biota appeared to be significant not only as spoilers but also as modulators of the growth/survival responses of L. monocytogenes in the fresh ‘aging’ Anthotyros cheese batches in situ. Indeed, based on their isolation frequencies, lowered levels of Gram-negative bacteria with a higher prevalence of nonfermentative aerobic Pseudomonas and related species (i.e., prevalent in batch D and selected by the CEntE in batches A and B; Table 2) were associated with greater declines of L. monocytogenes (Figure 1A). The above positive interactive effects probably developed because the aerobic Pseudomonas-like spoilage bacteria, unable to ferment lactose, might have exerted a reduced nutrient (sugar) competition against the LAB biota growing primarily at the expense of fermentable lactose. In contrast, high levels of psychrotrophic fermentative enterobacteria, mainly H. alvei and S. liquefaciens, likely enhanced growth and survival of L. monocytogenes in batch C and in the CN samples of batches A and B. H. alvei and S. liquefaciens probably managed a fast lactose uptake and thus exerted increased competitive ‘early’ growth effects against LAB at 4 °C under vacuum. Overall, Pseudomonas putida, other Pseudomonas spp., S. liquefaciens and mainly Hafnia-Obesumbacterium have been genotyped within the most prevalent members of the very diverse non-LAB communities in various fresh cheese products [51,56,57,58]. Moreover, the above primary Gram-negative genera along with Shewanella spp. and Flavibacterium spp. were members of the spoilage microbial community of the whey used in Ricotta cheese production [21]. Particularly H. alvei was shown to have a high ecological and aromatic impact as part of the whole microbial community in an experimental smear soft cheese [56] and in pasteurized Ricotta cheese whey batches [21]. H. alvei appears to have a similar high impact in traditional Greek whey cheeses because it has been the most prevalent Gram-negative bacterium in the microbial spoilage community of Anthotyros [37] and Manouri [59]. Additional in-depth studies at the strain level are required to elucidate growth interactions between the most prevalent spoilage LAB and Gram-negative bacteria species or biotypes in fresh Ent-treated and CN Anthotyros cheese batches and their specific effects on the behavior of L. monocytogenes during VP storage at 4 °C or higher abusive storage temperatures.
In summary, postprocessing contamination of Anthotyros and other Greek whey cheeses with L. monocytogenes remains a food safety concern, although the percentage of contaminated market cheese products appears to be decreasing during the last three decades due to improvements in the equipment and the cheese processing and storage conditions [28,29]. Notably, 15.4% of the retail whey cheese samples collected from the Greek market in 2010 had pH < 4.4 and, thus, would not permit the growth of L. monocytogenes [29]. Angelidis et al. [29] stated that such low pH values for whey cheese products are unexpected based on their manufacturing technology and, therefore, are associated with lower quality and reduced shelf life. In our opinion, altogether, the results of the present study reveal that such low pH values indicate that those commercial whey cheese samples were already ‘aged’ for two or more weeks in the supermarket freezers before their sampling, and some of them were likely to have been temperature abused during retail distribution and storage. Abusive or extended cold storage periods of whey cheeses not only result in short residual shelf life, but also may provide misleading results as regards the behavior of L. monocytogenes in case they are used as RTE market samples in challenge tests. For instance, a recent comprehensive study assessing the capacity of growth of L. monocytogenes in various cheeses from the Greek market included the whey cheeses Anthotyros and Manouri among those that did not support the growth of L. monocytogenes due to the high microbial competition and low pH during vacuum storage at 7 °C, thus mimicking temperature abuse [9]. In specific, the mean pH values of those Anthotyros cheeses recorded at the beginning (day 0), middle (day 8) and end (day 16) of storage were 6.72, 5.27 and 4.84, respectively [9]. Thus, the latter two pH values were very acidic, contrary to the corresponding mean pH values of the present fresh VP Anthotyros cheese samples without enterocin that were much higher, i.e., 6.80 (day 0), 6.84 (day 8) and 6.21 (day 15), during storage at 4 °C (Table 1). However, in that previous challenge study of Kapetanakou et al. [9], the native LAB and other bacteria, claimed by the authors as responsible for the natural whey cheese acidification and overall microbial competition, were not identified. Nonetheless, this study clearly demonstrated that none of the ‘aged’ (15-day-old) retail batches permitted L. monocytogenes growth, due to the reduction in their pH by an already high population level of native psychrotrophic LAB biota at the beginning of the additional 20-day VP storage period at 4 °C (Table 3), mainly consisting of Lc. mesenteroides, Lc. lactis and C. maltaromaticum (Table 4). However, challenge testing conditions of an ‘aged’ whey cheese rather represent an unrealistic scenario because the highest possibility for accidental natural contamination of a fresh RTE whey cheese with L. monocytogenes, as well as with all types of spoilage bacteria interacting with the pathogen’s growth, exists before or during vacuum packaging or MAP in individual plastic bags or trays in the plant prior to retail distribution [18,21,60,61]. Of course, an ‘aged’ whey cheese may be cross-contaminated with the pathogen after opening at home and storage in a domestic refrigerator, but this possibility and the safety risks associated with this possibility seem negligible. Nevertheless, care is needed when selecting fresh (whey) commercial cheese samples for challenge tests. In addition, their industrial or traditional manufacturers should be interviewed as regards the potential use of any chemical or natural preservatives or commercial bioprotective cultures. In this challenge study, we did ensure that the isolated C. maltaromaticum strains were not of commercial culture origin and no other types of biopreservatives had been intentionally added in the fresh Anthotyros whey cheeses studied.

5. Conclusions

In conclusion, this challenge study validated an average 2-log growth potential of L. monocytogenes in Greek Anthotyros whey cheeses when the artificial contamination with the pathogen was introduced in 50 g portions of fresh (1-day-old) retail cheese batches (mean pH 6.8; mean LAB level < 3.0 log10 CFU/g) before vacuum packaging and storage at 4 °C for up to 40 days. In contrast, the pathogen failed to promote major growth (<0.5 log increase) when it was artificially contaminated in Anthotyros batches that had been ‘aged’ (mean pH 6.1; mean LAB level >7.5 log10 CFU/g) in retail for 15 days after manufacture and then stored as above for an additional 20 days at 4 °C. Overall, the results revealed the vital importance of an unmonitored whey cheese acidification by native LAB, predominantly Lc. mesenteroides, in controlling growth of L. monocytogenes after a preceding storage at 4 °C in VP for approximately two weeks. In specific, listerial growth was suppressed after the whey cheese acidification reached a pH of 5.5, while listerial survival declined at pH 5.0 to 4.5 in most naturally acidified cheese batches after 30 to 40 days of storage. The addition of 5% CEntE in the fresh cheeses reduced the survival of L. monocytogenes by late storage, probably because the antilisterial activity of the enterocin A-B-P mix was enhanced at low pH in situ. However, neither the CEntE nor the native LAB biota could prevent a major (>1–2 log10 CFU/g) growth of L. monocytogenes during the first (mainly) and second weeks of VP storage at 4 °C. Regardless of CEntE addition, the growth/survival of L. monocytogenes in fresh Anthotyros was strongly batch-dependent and likely plant-dependent. Overall, higher postprocess contamination levels of native LAB, accompanied by cogrowth of a non-LAB spoilage microbiota dominated by Pseudomonas spp. or related nonfermentative Gram-negative bacteria, was associated with earlier growth cessation times and lowered surviving populations of L. monocytogenes, whereas high early growth levels (>8.0–8.5 log10 CFU/g) of spoilage fermentative psychrotrophic Enterobacteriaceae, predominantly Hafnia alvei, were likely associated with increased and more extended growth of L. monocytogenes during storage. Further research is required to assess potentially increased antilisterial effects during refrigerated storage of traditional Greek fresh whey cheeses by the application of a more active enterocin A-B-P concentrate than the CEntE (400 AU/mL) herein, singly or in combination with bioprotective (Bac+) strains derived from the native psychrotrophic whey cheese spoilage LAB biota.

Author Contributions

Conceptualization, J.S.; methodology, N.S. and J.S.; validation, J.S.; formal analysis, N.S. and J.S.; resources, J.S.; data curation, J.S.; writing—original draft preparation, N.S. and J.S.; writing—review and editing, J.S; supervision, J.S. All authors have read and agreed to the published version of the manuscript.

Funding

Funding was provided by the European Union and Greek national funds through the EPAnEK 2014-2020 Operational Program Competitiveness, Entrepreneurship and Innovation, under RESEARCH-CREATE-INNOVATE (project: T1EDK-00968; project acronym BIO TRUST).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The data presented in this study, as well as the bacterial isolates identified, are available on request from the corresponding author.

Acknowledgments

The authors wish to thank Pappas Bros. traditional dairy (Skarfi E.P.E., Filippiada, Epirus, Greece) and, anonymously, the owner of the second traditional dairy located near Ioannina, Epirus, for providing the fresh Anthotyros whey market cheeses used in this study.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Melo, J.; Andrew, P.W.; Faleiro, M.L. Listeria monocytogenes in cheese and the dairy environment remains a food safety challenge: The role of stress responses. Food Res. Int. 2015, 67, 75–90. [Google Scholar] [CrossRef]
  2. Falardeau, J.; Trmčić, A.; Wang, S. The occurrence, growth, and biocontrol of Listeria monocytogenes in fresh and surface–ripened soft and semisoft cheeses. Compr. Rev. Food Sci. Food Saf. 2021, 20, 4019–4048. [Google Scholar] [CrossRef] [PubMed]
  3. Gould, L.H.; Mungai, E.; Behravesh, C.B. Outbreaks attributed to cheese: Differences between outbreaks caused by unpasteurized and pasteurized dairy products, United States, 1998-2011. Foodborne Path. Dis. 2014, 11, 545–551. [Google Scholar] [CrossRef] [PubMed]
  4. Gérard, A.; El-Hajjaji, S.; Niyonzima, E.; Daube, G.; Sindic, M. Prevalence and survival of Listeria monocytogenes in various types of cheese—A review. Int. J. Dairy Technol. 2018, 71, 825–843. [Google Scholar] [CrossRef]
  5. Martinez-Rios, V.; Dalgaard, P. Prevalence of Listeria monocytogenes in European cheeses: A systematic review and meta-analysis. Food Control 2018, 84, 205–214. [Google Scholar] [CrossRef] [Green Version]
  6. European Food Safety Authority-European Center Disease Control (EFSA-ECSC). The European Union one health 2018 Zoonoses Report. EFSA J. 2019, 17, 5926. [Google Scholar]
  7. Álvarez-Ordóñez, A.; Leong, D.; Hickey, B.; Beaufort, A.; Jordan, K. The challenge of challenge testing to monitor Listeria monocytogenes growth on ready-to-eat foods in Europe by following the European Commission (2014) Technical Guidance document. Food Res. Int. 2015, 75, 233–243. [Google Scholar] [CrossRef]
  8. Lahou, E.; Uyttendaele, M. Growth potential of Listeria monocytogenes in soft, semi-soft and semi-hard artisanal cheeses after post-processing contamination in deli retail establishments. Food Control 2017, 76, 13–23. [Google Scholar] [CrossRef]
  9. Kapetanakou, A.E.; Gkerekou, M.A.; Vitzilaiou, E.S.; Skandamis, P.N. Assessing the capacity of growth, survival, and acid adaptive response of Listeria monocytogenes during storage of various cheeses and subsequent simulated gastric digestion. Int. J. Food Microbiol. 2017, 246, 50–63. [Google Scholar] [CrossRef]
  10. Gérard, A.; El-Hajjaji, S.; Van Coillie, E.; Bentaïb, A.; Daube, G.; Sindic, M. Determination of the growth potential of Listeria monocytogenes in various types of Belgian artisanal cheeses by challenge tests. Food Microbiol. 2020, 92, 103582. [Google Scholar] [CrossRef]
  11. European Commission. Commission Regulation (EC) No 2073/2005. Microbiological criteria for foodstuffs. 15 November 2005. Off. J. Eur. Union 2005, L338, 1–26. [Google Scholar]
  12. Genigeorgis, C.; Carniciu, M.; Dutulescu, D.; Farver, T.B. Growth and survival of Listeria monocytogenes in market cheeses stored at 4 °C to 30 °C. J. Food Prot. 1991, 54, 662–668. [Google Scholar] [CrossRef] [PubMed]
  13. Papageorgiou, D.K.; Bori, M.; Mantis, A. Growth of Listeria monocytogenes in the whey cheeses Myzithra, Anthotyros, and Manouri during storage at 5, 12, and 22 °C. J. Food Prot. 1996, 59, 1193–1199. [Google Scholar] [CrossRef] [PubMed]
  14. Davies, E.A.; Bevis, H.E.; Delves-Broughton, J. The use of bacteriocin nisin, as a preservative in ricotta-type cheeses to control the food-borne pathogen Listeria monocytogenes. Lett. Appl. Microbiol. 1997, 24, 343–346. [Google Scholar] [CrossRef]
  15. Samelis, J.; Kakouri, A.; Rogga, K.J.; Savvaidis, I.N.; Kontominas, M.G. Nisin treatments to control Listeria monocytogenes post-processing contamination on Anthotyros, a traditional Greek whey cheese, stored at 4 °C in vacuum packages. Food Microbiol. 2003, 20, 661–669. [Google Scholar] [CrossRef]
  16. Spanu, C.; Scarano, C.; Spanu, V.; Penna, C.; Virdis, S.; De Santis, E.P.L. Listeria monocytogenes growth potential in Ricotta salata cheese. Int. Dairy J. 2012, 24, 120–122. [Google Scholar] [CrossRef]
  17. Aspri, M.; O’Connor, P.M.; Field, D.; Cotter, P.D.; Ross, P.; Hill, C.; Papademas, P. Application of bacteriocin-producing Enterococcus faecium isolated from donkey milk, in the bio-control of Listeria monocytogenes in fresh whey cheese. Int. Dairy J. 2017, 73, 1–9. [Google Scholar] [CrossRef]
  18. Pintado, M.E.; Macedo, A.C.; Malcata, F.X. Review: Technology, chemistry and microbiology of whey cheeses. Food Sci. Technol. Int. 2001, 7, 105–116. [Google Scholar] [CrossRef]
  19. Spanu, C.; Scarano, C.; Spanu, V.; Pala, C.; Casti, D.; Lamon, S.; Cossu, F.; Ibba, M.; Nieddu, G.; De Santis, E.P.L. Occurrence and behavior of Bacillus cereus in naturally contaminated ricotta salata cheese during refrigerated storage. Food Microbiol. 2016, 58, 135–138. [Google Scholar] [CrossRef]
  20. Sattin, E.; Andreani, N.A.; Carraro, L.; Fasolato, L.; Balzan, S.; Novelli, E.; Squartini, A.; Telatin, A.; Simionati, B.; Cardazzo, B. Microbial dynamics during shelf-life of industrial Ricotta cheese and identification of a Bacillus strain as a cause of a pink discolouration. Food Microbiol. 2016, 57, 8–15. [Google Scholar] [CrossRef]
  21. Sattin, E.; Andreani, N.A.; Carraro, L.; Lucchini, R.; Fasolato, L.; Telatin, A.; Balzan, S.; Novelli, E.; Simionati, B.; Cardazzo, B. A multi-omics approach to evaluate the quality of milk whey used in ricotta cheese production. Front. Microbiol. 2016, 7, 1272. [Google Scholar] [CrossRef] [Green Version]
  22. Spanu, C.; Scarano, C.; Spanu, V.; Pala, C.; Di Salvo, R.; Piga, C.; Buschettu, L.; Casti, D.; Lamon, S.; Cossu, F. Comparison of post-lethality thermal treatment conditions on the reduction of Listeria monocytogenes and sensory properties of vacuum packed ricotta salata cheese. Food Control 2015, 50, 740–747. [Google Scholar] [CrossRef]
  23. Coroneo, V.; Carraro, V.; Aissani, N.; Sanna, A.; Ruggeri, A.; Succa, S.; Meloni, B.; Pinna, A.; Sanna, C. Detection of virulence genes and growth potential in Listeria monocytogenes strains isolated from ricotta salata cheese. J. Food Sci. 2016, 81, M114–M120. [Google Scholar] [CrossRef] [PubMed]
  24. Fernández, M.V.; Jagus, R.J.; Mugliaroli, S.L. Effect of combined natural antimicrobials on spoilage microorganisms and Listeria innocua in a whey cheese “Ricotta”. Food Bioprocess Technol. 2014, 7, 2528–2537. [Google Scholar] [CrossRef]
  25. Spanu, C.; Scarano, C.; Piras, F.; Spanu, V.; Pala, C.; Casti, D.; Lamon, S.; Cossu, F.; Ibba, M.; Nieddu, G. Testing commercial biopreservative against spoilage microorganisms in MAP packed Ricotta fresca cheese. Food Microbiol. 2017, 66, 72–76. [Google Scholar] [CrossRef] [PubMed]
  26. Spanu, C.; Piras, F.; Mocci, A.M.; Nieddu, G.; De Santis, E.P.L.; Scarano, C. Use of Carnobacterium spp. protective culture in MAP packed Ricotta fresca cheese to control Pseudomonas spp. Food Microbiol. 2018, 74, 50–56. [Google Scholar] [CrossRef]
  27. Silva, C.C.G.; Silva, S.P.M.; Ribeiro, S.C. Application of bacteriocins and protective cultures in dairy food preservation. Front. Microbiol. 2018, 9, 594. [Google Scholar] [CrossRef]
  28. Theodoridis, A.; Abrahim, A.; Sarimvei, A.; Panoulis, C.; Karaioannoglou, P.; Genigeorgis, C.; Mantis, A. Prevalence and significance of Listeria monocytogenes in Greek whey cheeses. A comparison between the years 1990 and 1996. Milchwissenschaft 1998, 53, 147–148. [Google Scholar]
  29. Angelidis, A.S.; Georgiadou, S.S.; Zafeiropoulou, V.; Velonakis, E.N.; Papageorgiou, D.K.; Vatopoulos, A. A survey of soft cheeses in Greek retail outlets highlights a low prevalence of Listeria spp. Dairy Sci. Technol. 2012, 92, 189–201. [Google Scholar] [CrossRef] [Green Version]
  30. Noutsopoulos, D.; Kakouri, A.; Kartezini, E.; Pappas, D.; Hatziloukas, E.; Samelis, J. Growth, nisA gene expression and in situ nisin A activity of novel Lactococcus lactis subsp. cremoris costarter culture in commercial hard cheese production. J. Food Prot. 2017, 80, 2137–2146. [Google Scholar]
  31. Samelis, J.; Kakouri, A. Cell growth density and nisin A activity of the indigenous Lactococcus lactis subsp. cremoris M78 costarter depend strongly on inoculation levels of a commercial Streptococcus thermophilus starter in milk: Practical aspects for traditional Greek cheese processors. J. Food Prot. 2020, 83, 542–551. [Google Scholar] [PubMed]
  32. Kakouri, A.; Lianou, A.; Samelis, J. Antilisterial activity of wild, novel nisin-producing Lactococcus lactis subsp. cremoris strains in synthetic culture media and different dairy foods. In Proceedings of the 23rd International ICFMH Symposium (FoodMicro 2012), Istanbul, Turkey, 3–7 September 2012; Abstract P-573. p. 761. [Google Scholar]
  33. Mojgani, N.; Ameli, M.; Vaseji, N.; Hejazi, M.A.; Torshizi, M.A.K.; Amirinia, C. Growth control of Listeria monocytogenes in experimental cheese samples by Lactobacillus casei RN78 and its bacteriocin. African J. Microbiol. Res. 2010, 4, 1044–1050. [Google Scholar]
  34. Martinez, R.C.R.; Staliano, C.D.; Vieira, A.D.S.; Villarreal, M.L.M.; Todorov, S.D.; Saad, S.M.I.; Franco, B.D.G.M. Bacteriocin production and inhibition of Listeria monocytogenes by Lactobacillus sakei subsp. sakei 2a in a potentially symbiotic cheese spread. Food Microbiol. 2015, 48, 143–152. [Google Scholar]
  35. Dapkevicious, M.L.E.; Sgardioli, B.; Câmara, S.P.A.; Poeta, P.; Malcata, F.X. Current trends of enterococci in dairy products: A comprehensive review of their multiple roles. Foods 2021, 10, 821. [Google Scholar] [CrossRef] [PubMed]
  36. Graham, K.; Stack, H.; Rea, R. Safety, beneficial and technological properties of enterococci for use in functional food applications—A review. Crit. Rev. Food Sci. Nutr. 2020, 60, 3836–3861. [Google Scholar] [CrossRef]
  37. Sameli, N.; Sioziou, E.; Bosnea, L.; Kakouri, A.; Samelis, J. Assessment of the spoilage microbiota during refrigerated (4 °C) vacuum-packed storage of fresh Greek Anthotyros whey cheese without or with a crude enterocin A-B-P-containing extract. Foods 2021, 10, 2946. [Google Scholar] [CrossRef]
  38. Tsanasidou, C.; Asimakoula, S.; Sameli, N.; Fanitsios, C.; Vandera, E.; Bosnea, L.; Koukou, A.I.; Samelis, J. Safety evaluation, biogenic amine formation, and enzymatic activity profiles of autochthonous enterocin-producing Greek cheese isolates of the Enterococcus faecium/durans group. Microorganisms 2021, 9, 777. [Google Scholar] [CrossRef]
  39. Vandera, E.; Parapouli, M.; Kakouri, A.; Koukkou, A.I.; Hatziloukas, E.; Samelis, J. Structural enterocin gene profiles and mode of antilisterial activity in synthetic liquid media and skim milk of autochthonous Enterococcus spp. isolates from artisan Greek Graviera and Galotyri cheeses. Food Microbiol. 2020, 86, 103335. [Google Scholar] [CrossRef]
  40. Sameli, N.; Skandamis, P.N.; Samelis, J. Application of Enterococcus faecium KE82, an enterocin A-B-P–producing strain, as an adjunct culture enhances inactivation of Listeria monocytogenes during traditional Protected Designation of Origin Galotyri processing. J. Food Prot. 2021, 84, 87–98. [Google Scholar] [CrossRef]
  41. Dicks, L.M.T.; Fantuzzi, L.; Gonzalez, F.C.; Du Toit, M.; Dellaglio, F. Leuconostoc argentinum sp. nov., isolated from Argentine raw milk. Int. J. Syst. Evol. Microbiol. 1993, 43, 347–351. [Google Scholar] [CrossRef]
  42. Vancanneyt, M.; Zamfir, M.; De Wachter, M.; Cleenwerck, I.; Hoste, B.; Rossi, F.; Dellaglio, F.; De Vuyst, L.; Swings, J. Reclassification of Leuconostoc argentinum as a later synonym of Leuconostoc lactis. Int. J. Syst. Evol. Microbiol. 2006, 56, 213–216. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  43. Beshkova, D.; Frengova, G. Bacteriocins from lactic acid bacteria: Microorganisms of potential biotechnological importance for the dairy industry. Eng. Life Sci. 2012, 12, 419–432. [Google Scholar] [CrossRef]
  44. Vandera, E.; Lianou, A.; Kakouri, A.; Feng, J.; Koukkou, A.-I.; Samelis, J. Enhanced control of Listeria monocytogenes by Enterococcus faecium KE82, a multiple enterocin-producing strain, in different milk environments. J. Food Prot. 2017, 80, 74–85. [Google Scholar] [CrossRef] [PubMed]
  45. De Vuyst, L.; Moreno, F.M.R.; Revets, H. Screening for enterocins and detection of hemolysin and vancomycin resistance in enterococci of different origins. Int. J. Food Microbiol. 2003, 84, 299–318. [Google Scholar] [CrossRef]
  46. Asimakoula, S.; Giaka, K.; Fanitsios, C.; Kakouri, A.; Vandera, E.; Samelis, J.; Koukkou, A.-I. Monitoring growth compatibility and bacteriocin gene transcription of adjunct and starter lactic acid bacterial strains in milk. J. Food Prot. 2021, 84, 509–520. [Google Scholar] [CrossRef]
  47. Lauková, A.; Czikková, S. Antagonistic effect of enterocin CCM 4231 from Enterococcus faecium on “bryndza”, a traditional Slovak dairy product from sheep milk. Microbiol. Res. 2001, 156, 31–34. [Google Scholar] [CrossRef]
  48. Huang, E.; Zhang, L.W.; Chung, Y.K.; Zheng, Z.X.; Yousef, A.E. Characterization and application of enterocin RM6, a bacteriocin from Enterococcus faecalis. Biomed Res. Int. 2013, 2013, 206917. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  49. Coelho, M.C.; Silva, C.C.G.; Ribeiro, S.C.; Dapkevicius, M.; Rosa, H.J.D. Control of Listeria monocytogenes in fresh cheese using protective lactic acid bacteria. Int. J. Food Microbiol. 2014, 191, 53–59. [Google Scholar] [CrossRef]
  50. Ribeiro, S.C.; Ross, R.P.; Stanton, C.; Silva, C.C.G. Characterization and application of antilisterial enterocins on model fresh cheese. J. Food Prot. 2017, 80, 1303–1316. [Google Scholar] [CrossRef]
  51. Bassi, D.; Gazzola, S.; Sattin, E.; Dal Bello, F.; Simionati, B.; Cocconcelli, P.S. Lactic acid bacteria adjunct cultures exert a mitigation effect against spoilage microbiota in fresh cheese. Microorganisms 2020, 8, 1199. [Google Scholar] [CrossRef]
  52. Sacco System. Supporting Food Culture & Life. 4-Protection. Special Protective Food Cultures: Tradition, Passion, Innovation; Sacco System: Cadorago, Italy, 2020; Available online: www.saccosystem.com (accessed on 4 March 2020).
  53. Hemme, D.; Foucaud-Scheunemann, C. Leuconostoc, characteristics, use in dairy technology and prospects in functional foods. Int. Dairy J. 2004, 14, 467–494. [Google Scholar] [CrossRef]
  54. Kaminarides, S.; Aktypis, A.; Koronios, G.; Massouras, T.; Papanikolaou, S. Effect of ‘in situ’ produced bacteriocin thermophilin T on the microbiological and physicochemical characteristics of Myzithra whey cheese. Int. J. Dairy Technol. 2018, 71, 213–222. [Google Scholar] [CrossRef]
  55. Callon, C.; Saubusse, M.; Didienne, R.; Buchin, S.; Montel, M.C. Simplification of a complex microbial antilisterial consortium to evaluate the contribution of its flora in uncooked pressed cheese. Int. J. Food Microbiol. 2011, 145, 379–389. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Irlinger, F.; Yung, S.A.Y.I.; Sarthou, A.-S.; Delbès-Paus, C.; Montel, M.-C.; Coton, E.; Coton, M.; Helinck, S. Ecological and aromatic impact of two Gram-negative bacteria (Psychrobacter celer and Hafnia alvei) inoculated as part of the whole microbial community of an experimental smear soft cheese. Int. J. Food Microbiol. 2012, 153, 332–338. [Google Scholar] [CrossRef] [PubMed]
  57. Imran, M.; Bré, J.-M.; Guéguen, M.; Vernoux, J.-P.; Desmasures, N. Reduced growth of Listeria monocytogenes in two novel model cheese microcosms is not associated with individual microbial strains. Food Microbiol. 2013, 33, 30–39. [Google Scholar] [CrossRef]
  58. Abreu, A.C.S.; Carazzole, M.F.; Crippa, B.L.; Barboza, G.R.; Rall, V.L.M.; Rocha, L.O.; Silva, N.C.C. Bacterial diversity in organic and conventional Minas Frescal cheese production using targeted 16S rRNA sequencing. Int. Dairy J. 2021, 122, 105139. [Google Scholar] [CrossRef]
  59. Lioliou, K.; Litopoulou-Tzanetaki, E.; Tzanetakis, N.; Robinson, R.K. Changes in the microflora of Manouri, A traditional Greek whey cheese, during storage. Int. J. Dairy Technol. 2001, 54, 100–106. [Google Scholar] [CrossRef]
  60. Pala, C.; Scarano, C.; Venusti, M.; Sardo, D.; Casti, D.; Cossu, F.; Lamon, S.; Spanu, V.; Ibba, M.; Marras, M. Shelf life evaluation of ricotta fresca sheep cheese in modified atmosphere packaging. Ital. J. Food Saf. 2016, 5, 5502. [Google Scholar] [CrossRef] [Green Version]
  61. Kousta, M.; Mataragas, M.; Skandamis, P.; Drosinos, E. Prevalence and sources of cheese contamination with pathogens at farm and processing levels. Food Control 2010, 21, 805–815. [Google Scholar] [CrossRef]
Foods 11 00334 g001 550
Figure 1. Cheese batch-dependent growth and survival of Listeria monocytogenes (A) in association with the pH changes (B) during refrigerated (4 °C), vacuum-packed storage of four batches (A, B, C and D) of fresh Greek Anthotyros whey cheeses without (CN) or with 5% (v/w) of an added crude enterocin A-B-P extract (ENT). The pH data in Figure 1B were adapted from Table S1 [37].
Figure 1. Cheese batch-dependent growth and survival of Listeria monocytogenes (A) in association with the pH changes (B) during refrigerated (4 °C), vacuum-packed storage of four batches (A, B, C and D) of fresh Greek Anthotyros whey cheeses without (CN) or with 5% (v/w) of an added crude enterocin A-B-P extract (ENT). The pH data in Figure 1B were adapted from Table S1 [37].
Foods 11 00334 g001
Foods 11 00334 g002 550
Figure 2. Cheese batch-dependent growth (log10 CFU/g) of spoilage lactic acid bacteria, enumerated on MRS agar at 30 °C (A), and spoilage Pseudomonas-like bacteria, enumerated on CFC agar at 25 °C (B), during refrigerated (4 °C), vacuum-packed storage of four batches (A, B, C and D) of fresh Greek Anthotyros whey cheeses without (CN) or with 5% (v/w) of an added crude enterocin A-B-P extract (ENT).
Figure 2. Cheese batch-dependent growth (log10 CFU/g) of spoilage lactic acid bacteria, enumerated on MRS agar at 30 °C (A), and spoilage Pseudomonas-like bacteria, enumerated on CFC agar at 25 °C (B), during refrigerated (4 °C), vacuum-packed storage of four batches (A, B, C and D) of fresh Greek Anthotyros whey cheeses without (CN) or with 5% (v/w) of an added crude enterocin A-B-P extract (ENT).
Foods 11 00334 g002
Table
Table 1. Behavior of the inoculated Listeria monocytogenes (log10 CFU/g) populations in association with the evolution of the primary spoilage bacterial groups and the pH changes during refrigerated (4 °C) storage of fresh, vacuum packaged Anthotyros whey cheeses without (CN) or with (CEntE) addition of 0.5% crude enterocin A-B-P extract a.
Table 1. Behavior of the inoculated Listeria monocytogenes (log10 CFU/g) populations in association with the evolution of the primary spoilage bacterial groups and the pH changes during refrigerated (4 °C) storage of fresh, vacuum packaged Anthotyros whey cheeses without (CN) or with (CEntE) addition of 0.5% crude enterocin A-B-P extract a.
Bacterial GroupCheese TreatmentDays of Storage at 4 °C
08153040
Listeria monocytogenes strain No. 10CN3.34 a4.55 b5.20 b5.35 b5.25 b B
(0.09)(0.38)(0.87)(1.17)(0.89)
CEntE3.32 a4.65 b5.38 c4.90 cb4.25 ab A
(0.10)(0.22)(0.85)(0.72)(1.04)
Total dairy lactic acid bacteria (LAB)—selective colony enumeration on MPCA plates at 37 °C for 48 hCN4.28 a6.70 ab7.17 b AB8.39 c B8.67 c B
(2.06)(1.12)(0.97)(0.27)(0.52)
CEntE4.00 a6.12 a8.32 b B8.68 b B8.66 b B
(2.13)(1.21)(0.63)(0.61)(0.29)
Total Gram-negative dairy bacteria—selective colony enumeration on MPCA plates at 37 °C for 48 hCN4.51 a6.24 b6.67 bc A 7.46 c A 7.05 bc A
(1.15)(1.03)(1.61)(0.69)(0.45)
CEntE4.97 a5.85 b7.14 c AB7.52 c A6.89 bc A
(1.29)(1.25)(1.31)(0.60)(0.89)
Whey cheese pH bCN6.80 d6.84 d6.21 c5.51 b B5.14 a B
(0.18)(0.28)(0.13)(0.23)(0.21)
CEntE6.83 c6.82 c5.98 b4.87 a A4.63 a A
(0.14)(0.23)(0.54)(0.28)(0.21)
a Values are the means of four independent whey cheese batches (n = 4); standard deviation values are shown in brackets. Within a row, means lacking a common lowercase letter are significantly different (p < 0.05). Within a column for each analysis, means bearing an uppercase A versus B are significantly different (p < 0.05); b Whey cheese pH data are adapted from Sameli et al. [37].
Table
Table 2. Overview of the terminal spoilage association in four batches (A, B, C and D) of fresh Anthotyros whey cheese without (CN) or with 5% crude enterocin A-B-P extract (Ent) after 30 to 40 days of vacuum-packaged storage at 4 °C (data adapted from Sameli et al. [37] were suitably modified to present the numerical distribution of the isolates per CN or Ent treatment within each whey cheese batch).
Table 2. Overview of the terminal spoilage association in four batches (A, B, C and D) of fresh Anthotyros whey cheese without (CN) or with 5% crude enterocin A-B-P extract (Ent) after 30 to 40 days of vacuum-packaged storage at 4 °C (data adapted from Sameli et al. [37] were suitably modified to present the numerical distribution of the isolates per CN or Ent treatment within each whey cheese batch).
SpeciesBiotypesWhey Cheese Batch IsolatesTotal Isolates
(%)
ABCD
CNEntCNEntCNEntCNEnt
Leuconostoc mesenteroides
(Non-slime-producers)		3108111079101075 (62.5)
Leuconostoc mesenteroides
(Slime-producers)		147222 17 (14.2)
Leuconostoc lactis1 2 24 (3.3)
Carnobacterium maltaromaticum4 2344 13 (10.9)
Streptococcus thermophilus1 527 (5.9)
Enterococcus faecium1 11 (0.8)
Lactococcus lactis1 2 2 (1.6)
Mesophilic Lactobacillus sp.11 1 (0.8)
Total LAB isolates 1515151515151515120
Hafnia alvei2 13172941 (42.7)
Serratia liquefaciens23 7331 17 (17.7)
Rahnella aquatilis25 3 8 (8.3)
Pantoea sp.1 1 1 (1.1)
Klebsiella oxytoca2 1 2 3 (3.1)
Enterobacter sp./E. cloacae2 11114 (4.2)
Pseudomonas sp.325 4 11 (11.4)
Aeromonas sp. 2 9 9 (9.4)
Flavibacterium sp. 1 2 2 (2.1)
Total Gram-negative bacteria isolates 1051071919161096
Table
Table 3. Behavior of inoculated L. monocytogenes (log10 CFU/g) in association with the growth of the spoilage microbiota (log10 CFU/g) and the pH changes during additional refrigerated (4 °C) VP storage of the ‘aged’ (15-day-old) retail Anthotyros whey cheeses a.
Table 3. Behavior of inoculated L. monocytogenes (log10 CFU/g) in association with the growth of the spoilage microbiota (log10 CFU/g) and the pH changes during additional refrigerated (4 °C) VP storage of the ‘aged’ (15-day-old) retail Anthotyros whey cheeses a.
Bacterial GroupEnumeration Medium/Incubation ConditionsDays of Additional
Storage at 4 °C
0 (15)8 (23)20 (35)
Listeria monocytogenes No. 10PALCAM agar/30 °C; 48–72 h; aerobically3.13 a
(0.28)		3.29 a
(0.31)		3.01 a
(0.23)
Total spoilage lactic acid bacteria (LAB)M17 agar/22 °C; 72 h; aerobically8.29 a
(0.25)		8.64 b*
(0.07)		8.49 ab*
(0.56)
Total spoilage Gram-negative bacteria7.70 a
(0.10)		7.29 a*
(0.96)		7.18 a*
(1.03)
Total mesophilic aciduric LAB MRS agar/30 °C; 72 h; aerobically 7.74 a
(0.89)		8.09 a
(0.72)		7.99 a
(0.79)
Pseudomonas and related Gram-negative bacteriaCephalothin–fucidin–cetrimide (CFC) agar/
25 °C; 48 h; aerobically		7.60 b
(0.25)		6.48 ab
(1.89)		6.13 a
(1.99)
Coliform bacteriaViolet Red Bile agar (VRBA)/37 °C; 18–24 h;
anaerobically (double-layered)		6.70 b
(0.92)		5.95 ab
(1.91)		5.00 a
(1.20)
EnterococciKanamycin Aesclulin Azide (KAA) agar/
37 °C; 48 h; aerobically		4.11 a
(2.12)		4.63 a
(1.70)		4.67 a
(1.74)
Total staphylococciBaird-Parker agar with egg yolk tellurite/
37 °C; 48 h; aerobically		4.65 a
(1.36)		4.62 a
(1.37)		3.43 a
(1.29)
YeastsRose Begnal Chloramphenicol (RBC) agar/
25 °C; 48 h; aerobically 		2.58 a
(0.53)		2.65 a
(0.16)		3.69 a
(1.21)
Whey cheese pH 6.10 b
(0.16)		5.14 a
(0.35)		4.86 a
(0.24)
a Values are the means of three independent cheese batches (n = 3); standard deviation values are shown in brackets. Within a row, means lacking a common lowercase letter are significantly different (p < 0.05). Within a column for each analysis, means bearing an asterisk are significantly different (p < 0.05).
Table
Table 4. Biochemical characterization of additional 44 representative LAB isolates recovered from MRS and TSAYE agar plates of spoiling (day 15) Anthotyros whey cheese products stored at 4 °C in vacuum.
Table 4. Biochemical characterization of additional 44 representative LAB isolates recovered from MRS and TSAYE agar plates of spoiling (day 15) Anthotyros whey cheese products stored at 4 °C in vacuum.
Biochemical TestLeuconostoc spp. IsolatesOther LAB Isolates Total
Isolates
L1L2L3L6L7CnLbEnt
Cell morphologyBCBCBCBCBCSRCC
CO2 from glucose+++++
NH3 from arginine(+)++
Growth at 45 °C+
Growth in 4% NaCl++++++++
Growth in 6.5% NaCl+++++++
Slime from sucrose
Growth on KAA agar(+)−/(+)+−/(+)++
Acid from:
Maltose6/12+1/6++++
Mannitol+++
Lactose++++++++
Ribose(+)/+1/6++
L-Arabinose++++
Xylose+++++
Raffinose++−/+d+
Sucrose++++++++
Cellobiose 4/91/65/10+++
Trehalose+++++2/3++
Galactose++++++++
Total isolates129611032144
Batch C (CN/Ent)0/01/00/00/13/41/01/10/012
Batch D (CN/Ent)6/50/00/00/00/00/00/00/112
Batch X-15A1860320020
+, positive reaction; −, negative reaction; (+), weak positive reaction; +d, delayed positive reaction; ++, strong positive reaction; 6/12, 6 out of 12 isolates were positive. Biochemical characterization: L1, L2, L3 and L6, Leuconostoc mesenteroides (different dairy biotypes); L7, Leuconostoc argentinum/Leuc. lactis; Cn, Carnobacterium maltaromaticum; Lb, unidentified mesophilic Lactobacillus sp.; Ent, Enterococcus faecium.
Table
Table 5. Identification of additional 18 representative isolates of Gram-negative bacteria recovered from CFC and TSAYE agar plates of spoiling (day 15) VP Anthotyros whey cheese products at 4 °C, as determined by the API 20E identification method.
Table 5. Identification of additional 18 representative isolates of Gram-negative bacteria recovered from CFC and TSAYE agar plates of spoiling (day 15) VP Anthotyros whey cheese products at 4 °C, as determined by the API 20E identification method.
TestReactions/EnzymesHafnia
alvei I		Pantoea sp.Klebsiella
oxytoca		Shewanella
putrefaciens		Total
Isolates
ONPGβ-Galactosidase+/−++
ADHArginine dihydrolase
LDCLysine decarboxylase++
ODCOrnithine decarboxylase+
CITCitrate utilization++
H2SH2S production+
UREUrease
TDATryptophane deaminase
INDIndole production+
VPAcetoin production++
GELGelatinase++
GLUGlucose (F/O)+++
MANMannitol (F/O)+++
INOInositol (F/O)+
SORSorbitol(F/O)+
RHARhamnose (F/O)++
SACSaccharose (F/O)++
MELMelibiose (F/O)+
AMYAmygdalin (F/O)+
ARAArabinose (F/O)+++
OXOxidase reaction+
API code4305112
5305112		100612252457730402004
Identification accuracyExcellent
Very good		AcceptableGoodExcellent
Total isolates841518
Isolates/batch C (CN/Ent)3/30/00/00/06
Isolates/batch D (CN/Ent)0/00/00/13/26
Isolates/batch X-15M24006
+, positive colored reaction; −, negative colored reaction, according to the API 20E manual instructions.
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Sameli, N.; Samelis, J. Growth and Biocontrol of Listeria monocytogenes in Greek Anthotyros Whey Cheese without or with a Crude Enterocin A-B-P Extract: Interactive Effects of the Native Spoilage Microbiota during Vacuum-Packed Storage at 4 °C. Foods 2022, 11, 334. https://0-doi-org.brum.beds.ac.uk/10.3390/foods11030334

AMA Style

Sameli N, Samelis J. Growth and Biocontrol of Listeria monocytogenes in Greek Anthotyros Whey Cheese without or with a Crude Enterocin A-B-P Extract: Interactive Effects of the Native Spoilage Microbiota during Vacuum-Packed Storage at 4 °C. Foods. 2022; 11(3):334. https://0-doi-org.brum.beds.ac.uk/10.3390/foods11030334

Chicago/Turabian Style

Sameli, Nikoletta, and John Samelis. 2022. "Growth and Biocontrol of Listeria monocytogenes in Greek Anthotyros Whey Cheese without or with a Crude Enterocin A-B-P Extract: Interactive Effects of the Native Spoilage Microbiota during Vacuum-Packed Storage at 4 °C" Foods 11, no. 3: 334. https://0-doi-org.brum.beds.ac.uk/10.3390/foods11030334

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