80 ISSN 1120-1770 online, DOI 10.15586/ijfs.v35i2.2324 P U B L I C A T I O N S CODON Italian Journal of Food Science, 2023; 35 (2): 80–87 P U B L I C A T I O N S CODON Effectiveness of Bdellovibrio bacteriovorus to contain Escherichia coli on milk and temperature impact on predation dynamics Silvia Pieralisi1#, Cristina Canonico1#, Stefania Di Lullo1*, Gabriele Angelico1*, Gianluigi Cardinali2, Elena Rocchegiani1, Diego Maiolatesi1, Donatella Ottaviani1 1Laboratorio Controllo Alimenti, Istituto Zooprofilattico Sperimentale dell’Umbria e delle Marche “Togo Rosati”, Ancona, Italy; 2Facoltà di Scienze Farmaceutiche, Università degli Studi di Perugia, Perugia, Italy #These authors contributed equally to this work. *Corresponding Authors: Stefania Di Lullo, Laboratorio Controllo Alimenti, Istituto Zooprofilattico Sperimentale dell’Umbria e delle Marche “Togo Rosati”, Via Cupa di Posatora 3, 60126 Ancona, Italy. Email: s.dilullo@izsum.it; Gabriele Angelico, Laboratorio Controllo Alimenti, Istituto Zooprofilattico Sperimentale dell’Umbria e delle Marche “Togo Rosati”, Via Cupa di Posatora 3, 60126 Ancona, Italy. Email: g.angelico@izsum.it Received: 17 January 2023; Accepted: 17 March 2023; Published: 23 May 2023 © 2023 Codon Publications OPEN ACCESS PAPER Abstract We tested the predation of B. bacteriovorus against Escherichia coli in milk samples in three different experiments. In Experiment 1, the growth and predatory activity of B. bacteriovorus against E. coli in milk stored at 4°C were evaluated. In Experiment 2, the predatory activity of B. bacteriovorus against E. coli in the milk matrix was com- pared to the optimal one in the medium of choice. In Experiment 3, the influence of the native milk microbial com- munity on the predation of B. bacteriovorus against E. coli experimentally added or indigenous grown at 4°C was tested. The predator increased at 4°C by about 1 Log in the first 48 hours and caused E. coli decrease by about 2 Log after 24 hours. The predator at 30°C reduced E. coli faster (3 Log after 6 hours) than at 4°C (2 Log after 24 hours). B. bacteriovorus at 30°C preyed on E. coli more in the nutrient broth than in the milk, with the most significant dif- ference by about 4 Log after 48 hours. In raw milk contaminated only by the predator, it increased by about 1 Log after 48 hours at 4°C, suggesting that it preyed on indigenous microorganisms. B. bacteriovorus could find appli- cation in raw milk used as food or raw material during storage at 4°C to reduce the microbial load of spoilage and Shigatoxin-producing E. coli (STEC) strains of E. coli and therefore increase its shelf-life and healthiness. Keywords: Bdellovibrio and like organisms; Bdellovibrio bacteriovorus; E. coli; milk Introduction In Italy and other industrialized countries, the consump- tion of raw milk has been increasing in recent years due to the growing interest of consumers in untreated and locally produced foods (Tremonte et al., 2014). Indeed, the consumption of raw milk may have a protective asso- ciation with the development of allergies and it is an important source of vitamin B2 (Macdonald et al., 2011). However, the presence of pathogenic microorganisms in raw milk is reported everywhere (Boor et al., 2017; Macdonald et al., 2011). The legislation dictates to store raw milk at 4°C for 72 hours and to consume it only after boiling to ensure its safety (EU, 2004; Italian Ministry of Health, 2009, 2013). However, the responsibility to sani- tize raw milk lies with the consumer, who may underes- timate or ignore the microbiological risks associated with it (Tremonte et  al., 2014). Moreover, when milk is used as a raw material to produce pasteurized, UHT (Ultra High Temperature) milk, and other milk-based foods, mailto:s.dilullo@izsum.it mailto:g.angelico@izsum.it Italian Journal of Food Science, 2023; 35 (2) 81 Milk and temperature impact on predation dynamics Bacteriovorax and Bdellovibrio for bio-based food sec- tor intervention strategies (USDA, 2018). However, these lines of study have not yet produced published data, to the best of our knowledge. To date, the only data available are those concerning the application of B. bacteriovorus on some sterilized foods and food processing surfaces on a laboratory scale (Fratamico and Cooke, 1995; Lu and Cai, 2010; Ottaviani et al., 2019; Youdkes et al., 2020). The predatory ability of B. bacteriovorus in complex natural habitats, with mixed microbial flora, such as raw milk, is yet to be discovered. This study is the first application of B. bacteriovorus as a predator on milk to obtain lab- oratory-scale information on its predation potential on a food matrix never tested before. In particular, it was investigated how the refrigeration, “milk matrix,” and the indigenous microbial community could influence the pre- dation of B. bacteriovorus against its preferred prey, that is, E. coli. Materials and Methods Collection and field strains used E. coli ATCC 15144 was used as prey. B. bacteriovorus 109 J ATCC 15143 was used as a predator. E. coli enrich- ment and the attack phase of the predator were prepared according to previously standardized methods (Ottaviani et al., 2019). For the challenge experiments, we used the predator/prey ratio of 107 PFU/105 CFU per mL (PFU=Plaque-Forming Unit) to activate the best preda- tion (Ottaviani et al., 2019). Milk sampling Each sample was 1460 mL of raw milk from Marche’s breed cows from an automatic raw milk machine inside a dairy farm located in the Ancona province (The Marches Region, Central Italy). Samples were stored in a cool box at 4°C and tested within 2 hours from the sampling. Four batches were made from each sample, one of 540 mL and three of 300 mL. Before the experiment, on other 20 mL of each sample pH (pH meter 300 Hanna Instruments) was measured, and it ranged between 6.68 and 6.88. Raw milk from the same machine had been analyzed for indig- enous E. coli, according to the standard method (ISO 16649-2:2001). In the previous 6 months, E. coli counts never exceeded 4 Log CFU per mL. Experiment 1 A 540 mL volume of the first batch was poured into a sterile container and heated until foam appeared, then the heating was stopped. Immediately after boiling, the its refrigeration for up to 72  hours is the most efficient method to increase its shelf life and eliminate spoilage by mesophilic bacteria (Boor et al., 2017). However, refrig- eration of raw milk does not limit the development of psychrotrophic bacteria like Pseudomonas (Boor et al., 2017). These microorganisms produce thermostable extracellular enzymes that can affect the quality of milk and dairy products after heat treatments when exceed- ing 106 CFU (Colony-Forming Unit) per mL (Boor et al., 2017). To increase the safety and microbiological quality of raw milk, biological control methods based on bacte- rium-bacterium predation could be tested. Bdellovibrio and like organisms (BALOs) are gram-negative, aerobic bacteria that are predatory toward other gram-negative bacteria (Stolp and Starr, 1963; Williams et al., 2005). BALOs have been investigated over the past 50 years with promising results in medicine, agriculture, veterinary, and for the treatment of pathogenic and drug-resistant bacte- ria (Dwidar et al., 2012; Kadouri et al., 2013). Compared to bacteriophages, BALOs show more non-specific pre- dation as they can attack gram-negative bacteria of dis- tinct genera (Dwidar et al., 2012; Fratamico and Whiting, 1995). In particular, the favorite prey of Bdellovibrio bac- teriovorus is Escherichia coli, including commensal and pathogenic as Shigatoxin-producing E. coli strains (STEC) (Fratamico and Whiting, 1995; Ottaviani et al., 2019). However, it is also able to attack other pathogenic and spoilage bacteria such as Salmonella, Shigella, Yersinia, Serratia, Proteus, Pseudomonas (Dashiff et al., 2011). B. bacteriovorus does not pose a risk to humans as it does not grow in eukaryotic cells (Bratanis et al., 2020; Dwidar et al., 2012). B.  bacteriovorus does not carry harmful or antibiotic resistance genes and does not prey on gram- positive bacteria or fungi playing the role of starter cultures for some food products (Dwidar et al., 2012; Shemesh and Jurkevitch, 2004). Finally, B. bacteriovorus can prey on bacteria even if organized in biofilm or viable but non-cultivable (VBNC) (Dashiff et al., 2011; Dwidar et al., 2012; Kadouri and O’Toole, 2005; Markelova, 2010). Previous research has shown that pH, incubation temperature, predator/prey ratio, and the physical and chemical characteristics of the medium can influence predation (Fratamico and Whiting, 1995; Sockett, 2009). Most of the published studies have used pure cultures in liquid medium to elucidate the prey-predator inter- action. In those experimental contexts, B. bacteriovorus showed preferential predation on E. coli, but the basis for this selection is not known. The interest of the scientific community and legislative bodies in these microorgan- isms has been increasing in recent years. Recently, for the first time, experts from the European Food Safety Agency (EFSA) have proposed the use of predatory bacteria such as B. bacteriovorus as one of the measures to be taken in food production environments to contain antimicrobial resistance (EFSA, 2021). Moreover, the United States Department of Agriculture (USDA) is beginning to test 82 Italian Journal of Food Science, 2023; 35 (2) Pieralisi S et al. Table 1. Predator/prey challenge experiments Experiment number and aim Experimental design Storage T°C Timescale predator/prey counts—hours 1 Evaluate growth and predatory activity of B. bacteriovorus against E. coli in milk stored over time up to 7 days. Milk test: Boiled milk contaminated with the predator/prey ratio 107 PFU/105 CFU Milk control: Boiled milk contaminated with 105 CFU prey 4 0, 6, 24, 48, 72, 96, 120, 144, 168 2 (A, B) Evaluate predatory activity of B. bacteriovorus against E. coli in milk matrix: (A) during the shelf-life of raw milk; (B) compared to DNB, the medium of choice. A B 30 0, 6, 24, 48, 72 Milk test: Boiled milk contaminated with the predator/prey ratio 107 PFU/105 CFU Milk control: Boiled milk contaminated with 105 CFU prey DNB test: DNB contaminated with the predator/prey ratio 107 PFU/105 CFU DNB control: DNB contaminated with 105 CFU prey 3 (A, B) Evaluate influence of the native milk microbial community on the predation of B. bacteriovorus against E. coli during the shelf-life of raw milk: (A) by adding E. coli experimentally under the best prey/predator ratio; (B) at natural concentrations of E. coli. A B 4 0, 6, 24, 48, 72 Milk test: Raw milk contaminated with the predator/prey ratio 107 PFU/105 CFU Milk control: Raw milk contaminated with 105 CFU prey Milk test: Raw milk contaminated with 107 PFU predator Milk control: Raw milk DNB, diluted nutrient broth. Graphical scheme of performed experiments: 1, 2 (A, B), 3 (A, B). milk was dispensed into 54 tubes, each with 10 mL of milk. Then, 27 tubes were assigned to the control and the same number to the test. To obtain in milk a predator/ prey ratio of 107 PFU/105 CFU per mL, all tubes were homogeneously contaminated by inoculating 0.5  mL of prey suspension at a concentration of about 5 × 106 CFU per mL. The test tubes were then contaminated with 0.5 mL of about 5 × 108 PFU per mL predator. The same amount of peptone salt solution was added to the control. All tubes were stored at 4°C. Predator and prey counts were performed at 0, 6, 24, 48, 72, 96, 120, 144, 168 hours from the treatment (Table 1). The predator was also tested in the milk control to exclude a cross- contamination with  the predator experimentally added to the milk test. For the prey enumeration, 9 mL were diluted 1:10 in buffered peptone water and from the stock suspension, decimal dilutions in peptone salt solu- tion were made (ISO 6887-1:2017). Then 1 mL of each dilution was inoculated on Tryptone Bile X-GLUC Agar (TBX) (Biolife, Milan, Italy) in duplicate, and the plates were incubated at 44°C for 24 hours (ISO 16649-2:2001). The data were reported as CFU per mL. B. bacteriovorus enumeration was performed with the plaque assay com- bining 0.1 mL of prey enrichment and 1 mL of undiluted or diluted milk, and plates were incubated at 30°C for 24  hours up to 5 days (Ottaviani et al., 2019). The data were reported as PFU per mL. Experiment 2 (A, B) The second batch was heated as in Experiment 1. Immediately after boiling, the milk was dispensed into 30 tubes, each with 10 mL. Fifteen tubes were assigned to the control and the same number to the test. All tubes were homogeneously contaminated as described for Experiment 1 and stored at 30°C. The predator and prey counts were performed at 0, 6, 24, 48, 72 hours from the treatment as in Experiment 1 (Experiment 2A). In par- allel, an analogous test and control were prepared, rep- resented by the medium of choice for predator (2B) that was diluted nutrient broth (DNB) consisting nutrient broth (Biolife, Milan, Italy) at a concentration of 0.08 g per liter of distilled water (Experiment 2B) (Table 1). Experiment 3 (A, B) An experiment analogous to Experiment 2A was per- formed on the third batch at 4°C (Experiment 3A). Italian Journal of Food Science, 2023; 35 (2) 83 Milk and temperature impact on predation dynamics predation ability toward E. coli was evaluated. Then, we tested boiled milk contaminated with the predator/prey ratio to get the best predation at 4°C. Predator and prey counts were performed at 0, 6, 24, 48, 72, 96, 120, 144, 168 hours from the treatment in test and control. The results are summarized in Figure 1. The optimal growth temperature of B. bacteriovorus is between 28 and 30°C, making it a mesophile (Stolp and Starr, 1963; Williams et al., 2005). However, in this experiment, the predator mul- tiplied from 24 to 72 hours and then held the experimen- tally added charge until the end of the experiment at 4°C. Lower E. coli levels of the test with respect to the control were observed for all time points, with the greatest signif- icant difference of about 2 Log after 24 hours (t = 12.3747; P < 0.0001). Previous studies have shown that B. bacterio- vorus preyed on E. coli in the liquid medium at the tem- perature between 12 and 37°C, with the higher activity in the first 7 hours (Fratamico and Cooke, 1996; Fratamico and Whiting, 1995). In disagreement with that evidence, in this experiment, B. bacteriovorus preyed on E. coli at 4°C. The E. coli level also progressively decreased in the control, possibly due to refrigeration. However, B. bac- teriovorus increased the prey reduction in the test com- pared to the control throughout the analysis time. Experiment 2 (A, B) The aim of this experiment was to evaluate the effect of the milk matrix on the predation of B. bacteriovorus against E. coli for a time corresponding to the shelf-life of raw milk. Then we tested at 30°C both the boiled milk (2A) and DNB (2B) contaminated with predator/prey From the microbiological analyses of raw milk carried out in the previous 6 months indigenous E. coli had never reached 5 Log, which is the optimal level for predation at maximum efficiency (Ottaviani et al., 2019). For this rea- son, the milk sample was contaminated with 5 Log E. coli ATCC 15144. In Experiment 3B, the growth of B. bacte- riovorus and its predation toward natural level of indig- enous E. coli were evaluated in raw milk, under normal storage conditions, for a time corresponding to its shelf- life. Then on the fourth batch, an experiment on raw milk contaminated only with the predator at a concentration of 107 PFU per mL was performed at the same conditions as Experiment 3A (Table 1). Statistical analysis Each experiment was repeated in three separate trials, and each trial was carried out in triplicate (n = 9). Results of microbiological analyses were reported as mean values (Log-transformed) ± standard deviation. Mean of plate counts were analyzed for differences in response to pred- ator treatments using the Student’s t-test (t). Statistical calculations were based on confidence levels (P) equal to or higher than 95%. Results and Discussion Experiment 1 In this experiment, the influence of raw milk storage temperature on the growth of B. bacteriovorus and its BX TEST 10 9 8 7 6 5 4 3 2 1 0 6 24 48 72 Time (h) Lo g 1 0C F U /P F U m l–1 96 120 144 168 0 BX CONTROL E. COLI TEST E. COLI CONTROL Figure 1. Experiment 1. Growth of B. bacteriovorus (BX) and E. coli in test (with BX) and control (without BX) boiled milk at 4°C. ♦ E. coli control; ● E. coli test; ▲ BX control; ■ BX test. Results of microbiological analyses (n = 9) were reported as mean values (Log transformed) ± standard deviation. 84 Italian Journal of Food Science, 2023; 35 (2) Pieralisi S et al. of B. bacteriovorus against E. coli under the best preda- tion conditions in terms of prey/predator ratio, at the refrigeration temperature for a time corresponding to its shelf-life. Then, we tested at 4°C up to 72 hours, the raw milk contaminated with the predator/prey ratio to obtain the best predation. In Experiment 3B, the growth of B. bacteriovorus and its predation toward natural level of indigenous E. coli were evaluated in raw milk, under normal storage conditions, for a time corresponding to its shelf-life. Predator and prey counts were performed at 0, 6, 24, 48, 72 hours from the treatment in test and control. The results are summarized in Figure 3. The predator trends in boiled and raw milk (Experiments 1 and 3A) were similar. Lower E. coli levels were observed in the test compared to the control for all time points, with the greatest significant difference of about 2 Log after 24 hours (t = 5.9747; P = 0.0001). B. bacteriovorus demonstrated a greater (3 Log) and faster (after 6 hours) capacity to contain prey in the milk test at 30°C than at 4°C, that is, 2 Log after 24 hours. This evidence is real- istic as 30°C is the optimum temperature for predation. Similar prey concentrations were present in the boiled and raw milk tests (Experiments 1 and 3A), at all the time points. This evidence suggests that when E. coli is at an optimal concentration for B. bacteriovorus preda- tion, the indigenous microorganisms of milk potentially competing with E. coli as prey, do not affect the preda- tor’s performance toward its favorite prey. Raw milk rep- resents a relevant source of infection by STECs (Caprioli et al., 2015; Jang et al., 2017). We tested B. bacteriovorus with a non-pathogenic strain of E. coli, however, previous work had shown that the growth rates of pathogenic and non-pathogenic E. coli are similar (Cassin et al., 1998). ratios to activate the best predation. For both milk and DNB, predator and prey counts were performed at 0, 6, 24, 48, 72 hours from the treatment in test and control. The results are summarized in Figure 2. By comparing predator concentrations at different time points in milk and DNB tests, higher B. bacteriovorus levels for all- time points in DNB than in milk were observed, with the greatest significant difference of about 2 Log after 6 hours (t = 3.9497; P = 0.0027). By comparing prey con- centrations at different time points in the milk test and control, lower E. coli levels were observed in the test than in the control from 6 to 48 hours, with the greatest signif- icant difference by about 3 Log after 6 hours (t = 10.6956; P < 0.0001). By comparing prey concentrations at differ- ent time points in milk and DNB tests, lower levels for all-time points in DNB than in milk were observed, with the greatest significant difference of about 4 Log at 48 hours (t = 4.0068; P = 0.0025). B. bacteriovorus preyed on E. coli more in DNB than in milk. The higher viscosity of milk than in DNB could make the former less suitable for predation than the latter by hindering B. bacteriovorus to swim and attack the prey. This hypothesis is reinforced by lower predator counts in milk than DNB for the entire analysis period. Comparing the growth trends of E.  coli in milk and DNB controls, a lower growth trend was observed in milk than in DNB. This evidence suggests that the milk matrix also slowed prey growth. Experiment 3 (A, B) The aim of Experiment 3A was to evaluate the influence of the native milk microbial community on the predation BX TEST 10 (A) (B) 9 8 7 6 5 4 3 2 1 0 6 24 48 72 Time (h) Lo g 1 0C F U /P F U m l–1 0 BX CONTROL E. COLI TEST E. COLI CONTROL BX TEST 10 9 8 7 6 5 4 3 2 1 0 6 24 48 72 Time (h) Lo g 1 0C F U /P F U m l–1 0 BX CONTROL E. COLI TEST E. COLI CONTROL Figure 2. Experiment 2. Growth of B. bacteriovorus (BX) and E. coli in test (with BX) and control (without BX) boiled milk (A) and DNB (B) at 30°C. ♦ E. coli control; ● E. coli test; ▲ BX control; ■ BX test. Results of microbiological analyses (n = 9) were reported as mean values (Log transformed) ± standard deviation. DNB, diluted nutrient broth. Italian Journal of Food Science, 2023; 35 (2) 85 Milk and temperature impact on predation dynamics refrigeration and the “matrix of the milk” have limited its performance. At the refrigeration temperature, when E. coli was at an optimal concentration for the predation, the presence of other potential preys in the milk did not affect the predatory efficiency of B. bacteriovorus toward its preferred prey. On the other hand, when E. coli was at a low concentration, the predator grew without predating it, probably by preying on other bacteria present in milk at a high concentration, such as psychrotrophs. Our next goal will be to test the predatory activity of B. bacteriovo- rus against native strains of E. coli and Pseudomonas iso- lated from raw milk and tested both in monoculture and in mixtures. This will help us understand the dynamics of B. bacteriovorus predation and toward which prey the predator shows the greatest affinity. Moreover, we are going to test B. bacteriovorus pre- dation against native E. coli in raw milk samples heav- ily contaminated by this microorganism, extending the study to sheep and goat milk. Finally, it will be assessed whether B. bacteriovorus and its metabolites produced during growth have any effect on the organoleptic char- acteristics, pH, and nutrients of raw milk during its shelf life. It is known that B. bacteriovorus reduces but does not eliminate prey because a balance is established in the growth medium that allows the survival of both the prey, although quantitatively reduced, and the predator (Bratanis et al., 2020). In light of this, even if B. bacterio- vorus cannot be used to eliminate prey microorganisms, it can still reduce their microbial load and thus improve the microbiological quality of raw milk during its storage at 4°C. It would also be interesting to test this predator in integrated biological-chemical-physical approaches to Moreover, in our previous study, B. bacteriovorus showed lytic ability toward STECs and multidrug-resistant E. coli strains of different origins (Ottaviani et al., 2019). So it is realistic to think that B. bacteriovorus could similarly contain STECs if they are in raw milk. In Experiment 3B, the predator trend was like that of Experiment 3A where the prey was experimentally added. In the milk control, predator counts were always not detectable. No signifi- cant difference in prey concentration between the test and control was observed. However, in the milk test, B. bacteriovorus grew between 24 and 48 hours, suggest- ing that it preyed on indigenous microorganisms other than E. coli. Previously, it has been reported that B. bac- teriovorus showed lytic ability toward psychrotrophic spoilage bacteria like Pseudomonas that are commonly found in raw milk (Dashiff et al., 2011; Fratamico and Whiting, 1995; Tremonte et al., 2014; Vianna et al., 2012). Psychrotrophic bacteria and Pseudomonas in the raw milk increase during refrigeration, reaching over- time values higher than 6 Log CFU per mL (Tremonte et al., 2019; Vianna et al., 2012). In light of this, in Experiment 3B, B. bacteriovorus might have preyed on psychrotrophic microorganisms. This aspect would con- firm B. bacteriovorus as a potential candidate to contain gram-negative pathogenic and spoilage bacteria in raw milk, while preserving those gram-positive bacteria, such as streptococci and lactobacilli, which represent part of the natural flora of milk or used as starters in dairy pro- duction. This is a preliminary laboratory-scale study to understand whether B. bacteriovorus has the potential as a predator in milk. Our results showed that B. bacteriov- orus at 4°C survived in milk for the entire analysis time, about 1 week, and preyed for up to 48 hours, although BX TEST 10 (A) (B) 9 8 7 6 5 4 3 2 1 0 6 24 48 72 Time (h) Lo g 1 0C F U /P F U m l–1 0 BX CONTROL E. COLI TEST E. COLI CONTROL BX TEST 10 9 8 7 6 5 4 3 2 1 0 6 24 48 72 Time (h) Lo g 1 0C F U /P F U m l–1 0 BX CONTROL E. COLI TEST E. COLI CONTROL Figure 3. Experiment 3. Growth of B. bacteriovorus (BX) and E. coli experimentally added in test (with BX) and control (without BX) raw milk at 4°C (A); Growth of B. bacteriovorus (BX) and indigenous E. coli in test (with BX) and control (without BX) raw milk at 4°C (B) ♦ E. coli control; ● E. coli test; ▲ BX control; ■ BX test. Results of microbiological analyses (n = 9) were reported as mean values (Log transformed) ± standard deviation. 86 Italian Journal of Food Science, 2023; 35 (2) Pieralisi S et al. contain experiments involving human participants and/ or animals. References Bonfiglio, G., Neroni, B., Radocchia, G., Marazzato, M., Pantanella,  F. and Schippa, S., 2020a. Insight into the possible use of the predator Bdellovibrio bacteriovorus as a probiotic. Nutrients 12: 2252. https://doi.org/10.3390/nu12082252 Bonfiglio, G., Neroni, B., Radocchia, G., Pompilio, A., Mura, F., Trancassini, M., et al. 2020b. Growth control of adherent- invasive Escherichia coli (AIEC) by the predator bacteria Bdellovibrio bacteriovorus: a new therapeutic approach for Crohn’s disease patients. Microorganisms 8(1): 17. https://doi. org/10.3390/microorganisms8010017 Boor, K.J., Wiedmann, M., Murphy, S. and Alcaine, S., 2017. A 100-year review: microbiology and safety of milk handling. Journal Dairy Science 100: 9933–9951. https://doi.org/10.3168/ jds.2017-12969 Bratanis, E., Andersson, T., Lood, R. and Bukowska-Faniband, E., 2020. Biotechnological potential of Bdellovibrio and like organ- isms and their secreted enzymes. Frontiers Microbiology 11: 662. https://doi.org/10.3389/fmicb.2020.00662 Caprioli, A., Scavia, G. and Morabito, S., 2015. Public health micro- biology of Shiga toxin-producing Escherichia coli. In: Vanessa, S. and Carolyn, J.H. (eds.) Enterohemorrhagic Escherichia coli and other Shiga toxin-producing E. coli. 1st ed. American Society of Microbiology, Washington, DC, pp. 263–295. https://doi. org/10.1128/microbiolspec.EHEC-0014-2013 Cassin, M.H., Lammerding, A.M., Todd, E.C.D., Ross, W. and McColl, R.S., 1998. Quantitative risk assessment for Escherichia coli O157:H7 in ground beef hamburgers. International Journal of Food Microbiology 41: 21–44. https://doi.org/10.1016/ s0168-1605(98)00028-2 Dashiff, A., Junka, R.A., Libera, M. and Kadouri, D.E., 2011. Predation of human pathogens by the predatory bacteria Micavibrio aeruginosavorus and Bdellovibrio bacteriovorus. Journal of Applied Microbiology 110: 431–444. https://doi. org/10.1111/j.1365-2672.2010.04900.x Dwidar, M., Monnappa, A.K. and Mitchell, R.J., 2012. The dual probiotic and antibiotic nature of Bdellovibrio bacterio- vorus. BMB Reports 45: 71–78. https://doi.org/10.5483/ BMBRep.2012.45.2.71 EFSA BIOHAZ Panel (EFSA Panel on Biological Hazards), Koutsoumanis, K., Allende, A., Álvarez-Ordóñez, A., Bolton, D., Bover-Cid, S., et al. 2021. Scientific opinion on the role played by the environment in the emergence and spread of antimicrobial resistance (AMR) through the food chain. EFSA Journal 19(6): 6651, 188 pp. https://doi.org/10.2903/j.efsa.2021.6651 EFSA FEEDAP Panel (EFSA Panel on Additives and Products or Substances used in Animal Feed), Rychen, G., Aquilina, G., Azimonti, G., Bampidis, V., Bastos, M.L., et al. 2018. Guidance on the characterisation of microorganisms used as feed addi- tives or as production organisms. EFSA Journal 16(3): 5206, 24 pp. https://doi.org/10.2903/j.efsa.2018.5206 maximize the inhibitory effect on prey milk microorgan- isms. For example, an innovative and promising approach used CO2 during 4°C storage of raw milk to reduce its microbial load (Bratanis et al., 2020). Recently, it has been demonstrated that B. bacteriovorus is part of the intes- tinal microbiota of vertebrates, including humans, and plays a key role in maintaining health (Bonfiglio et al., 2020a, 2020b; Dwidar et al., 2012; Iebba et al., 2013). As Bdellovibrios are natural residents of the intestinal micro- bial ecosystem, their functionality and stability should not be affected by the chemical–physical characteristics of the intestinal habitat. Probiotics are defined as live microor- ganisms that confer a health benefit to the host (EFSA, 2018). Assessment of safety, functionality, and stability are the first points to consider for a microorganism in terms of its use as a probiotic (EFSA, 2018). Many in vitro and in vivo studies have shown that Bdellovibrios meet all these requirements (Bonfiglio et al., 2020a, 2020b). As far as our knowledge is concerned, this is the first report on the application of B. bacteriovorus as a predator in milk: we believe our results are promising and that B. bacteriovo- rus merits further investigation. This approach to decon- tamination of raw milk based on Bdellovibrio is certainly economically sustainable, non-aggressive as it uses micro- organisms which are natural components of the human intestinal flora and that also have potential as probiotics. Conclusions Due to its biological properties and predation mode, B. bacteriovorus could find application in raw milk used as food or raw material during storage at 4°C to reduce the microbial load of E. coli including both spoilage and STEC strains and therefore increase its shelf-life, qual- ity, and healthiness. Furthermore, if we confirm that B. bacteriovorus preys on the psychrotrophic microor- ganisms of raw milk and, consequently, also reduces the production of thermostable enzymes, this could also be effective in increasing the shelf life of UHT, pasteurized milk, and other milk-derived foods. Acknowledgements Authors thank General Director of IZSUM for providing necessary facilities for the experiments. This work was sup- ported by Italian Ministry of Health (grant RC 2020-011). Declarations Conflicts of interest/Competing interests The authors declare that they have no financial/non-fi- nancial conflict of interest. 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