A selection of 200 predominantly Enterobacteriaceae strains, most of which were previously isolated from food enrichment broths, were selected for this study (Supplementary Table S1). Seven E. coli strains representing clinically important STEC serotypes and five Shigella strains were used as the indicator strains for testing sensitivity to inhibition from cell-free extracts (Table 1). All strains were stored at −80°C in 15% glycerol and were plated on Brain-Heart Infusion agar (BHI; OXOID, Nepean, ON, Canada) overnight (14–16 h) at 37°C prior to use.

Cell-free extracts were prepared from (1) overnight cultures of bacterial strains, and (2) food enrichment cultures from negative samples collected by the CFIA’s food testing laboratories in Ottawa (ON), Toronto (ON), and Saint-Hyacinthe (QC).

Bacterial strains (n = 200; Supplementary Table S1) were grown overnight at 37°C in 10 ml of Nutrient broth (OXOID) and broths were filtered using a 0.22 μm Vacuum filter (EMD Millipore Steriflip™ Sterile Disposable Vacuum Filter Units; Thermo Fisher Scientific, Ottawa). The cell-free extracts were stored at 4°C for up to 3 months and at −20°C for longer storage (Figure 1).

Food products were sampled between the fall 2016 and winter 2017 and were representative of the types of foods tested in regulatory food testing programs (Supplementary Table S2). Extracts were prepared from 332 enrichment cultures derived from 235 food samples. Categories of food products tested included fruits [46 (14%)], salads and coleslaws [78 (23%)], meats [85 (26%)] and vegetables, cheese and other [123 (37%)]. Enrichment cultures were generated using methods described in the Canadian Compendium of Analytical Methods: either the method for detection of Shigella spp. in foods (MFLP-26; n = 23; Bin Kingombe et al., 2006) or the method for detection of STEC in foods (MFLP-30; n = 115; Microbiological Methods Committee, 2012) or both (n = 97). The meats and cheeses were only enriched in mTSB and the rest were enriched in SB or both broths. For the MFLP-26 method, samples are enriched in a 1:10 dilution of sample to Shigella broth (SB; SB base, OXOID) with Tween-80 (Sigma, Markham, ON, Canada) containing 0.5 μg/ml of novobiocin (Sigma-Aldrich, Oakville, ON). The SB is enriched for 20 h at 42°C in a CO₂ incubator or CO₂ jar system. The MFLP-30 method involves a 1:10 dilution of sample to modified Tryptone Soya Broth (mTSB, OXOID) containing 20 μg/ml of novobiocin, followed by aerobic incubation of the enrichment at 42°C for 18–24 h. Typically, 25 g of food are enriched in 225 ml of enrichment broth using both methods. Note that enrichments were negative for targeted pathogens and that bacterial growth was observed for all samples based on turbidity of broths.

Enrichment broths were stored at 4°C prior to use. Cell-free extracts were prepared from 25 to 50 ml of enrichment broth by centrifugation at 500 × g for 5 min, transferring the supernatant to a new tube, followed by centrifugation at 14000 × g for 10 min (Figure 1). The supernatant was then filtered as described above and stored at 4°C or −20°C. The pellets from the high-speed spin were resuspended in 30% glycerol and stored at −80°C.

The methods for evaluating the inhibitory activity of cell-free extracts were modified from methods developed by (Arici et al., 2004) and (Vijayakumar and Muriana, 2015; Figure 1). Shigella and STEC were grown overnight in 10 ml of Nutrient Broth (NB, OXOID) at 37°C to obtain a concentration of approximately 10⁸ cells/ml. Overnight cultures of each of the indicator strains were enumerated to assess reproducibility of this approximation for initial experiments, but enumeration was not done routinely (data not shown). The overnight Shigella or STEC culture was added at a concentration of approximately 1 × 10⁶ cells/ml into soft agar cooled to 40°C [NB (OXOID) containing 0.5% (w/v) bacteriological agar (Sigma-Aldrich)] and poured into a Petri dish. Once the plates were solidified, 3 μl spots of the cell-free extracts were added and left to absorb into the agar before incubating plates overnight at 37°C. To enable high-throughput analyses, multichannel pipets were used to generate 36 spots on square Petri plates. All extracts were tested in triplicate.

The method from Henning et al. (2015) was used to isolate the inhibitor-producing bacteria from a subset of 13 of the food enrichment broths that were active against at least one indicator organism. Dilutions of the enrichment broths were spread plated on nutrient agar (OXOID) then immediately overlaid with a thin nutrient agar sandwich layer. The plates were incubated at 37°C overnight before a soft agar containing ~1 × 10⁶ cells/ml of the indicator species (Shigella sonnei OLC2340) was layered on top (see above). The triple layer agar was incubated overnight at 37°C. Note that only S. sonnei OLC2340 was used in this experiment, due to the complexity of the method, and the susceptibility of this strain to most of the cell-free extracts.

Following incubation, the triple agar plates were inverted and placed onto their Petri dish covers, and colonies surrounded by zones of clearing were streaked onto a new nutrient agar plate. The streaked plates were incubated overnight at 37°C and isolated colonies were patched onto two nutrient agar plates. The two plates were incubated at 37°C for 4 h and then one of the duplicate plates was overlaid with soft agar containing ~1 × 10⁶ cells/ml of S. sonnei OLC2340. The plates were again incubated at 37°C overnight. Isolates recovered from these plates were streaked for purity, then re-tested to confirm inhibitory activity. Isolates confirmed to cause inhibition were stored and maintained as described above.

Proteolytic enzymes were used to assess the proteinaceous nature of the inhibitory cell-free extracts (Elayaraja et al., 2014). Proteinase K (Thermo Fisher Scientific) and trypsin (Sigma-Aldrich) were added to the extracts at a final concentration of 1 mg/ml or 1X, respectively. The extracts were incubated for 2 h at 30°C before spotting on soft agar containing target bacteria as described above, alongside an untreated control. The presence of bacteriophage was assessed using the dilution method from Hockett and Baltrus (2017). Cell-free extracts were serially diluted two times in nutrient broth (1:10 and 1:100). Dilutions were spotted on soft agar as described above. Bacteriophage presence was confirmed if individual plaques were visible in the diluted samples and/or the clearing was unaffected by proteolytic enzymes. The pH of the cell-free extracts were measured with pH indicator strips (Thermo Fisher Scientific).

Cell-free extracts from 200 bacterial strains, primarily recovered from food (Supplementary Table S1), were tested to detect inhibition of growth of five strains of Shigella and seven strains of STEC (Table 1). Twenty-three of the 200 strains tested (11.5%) inhibited the growth of at least one of the 12 indicator organisms (Shigella and EHEC) used in this study. Most of the strains tested were Enterobacteriaceae (194/200), except for six strains (Pseudomonadaceae and Aeromonadaceae; Figure 2; Supplementary Table S1). The three main genera evaluated were Escherichia, Enterobacter and Hafnia [118 (48.5%), 31(14.5%), and 20(10%), respectively]. Cell-free extracts produced by 21 E. coli (10.5% of all strains, 17.8% of E. coli) inhibited growth of at least one strain of Shigella, and cell-free extracts from two Enterobacter spp. strains (1% of all strains, 6.5% of Enterobacter spp.) inhibited growth of at least one strain of STEC (Figure 2). Most of the inhibitor-producing E. coli affected S. sonnei (18 of 21, 86%), with a smaller proportion (n = 7, 33%) affecting Shigella flexneri. E. coli classified as STEC were more likely to produce bacteriocins (10 of 19 strains, 52.6%), compared to other E. coli (11 of 99 strains, 11.1%). In most samples, both strains of S. sonnei (OLC0024 and OLC2340) were inhibited (16 out of 18) whereas only three out of the seven extracts affecting S. flexneri inhibited both of the strains used in this study (Figure 3). The inhibitor-producing Enterobacter spp. affected E. coli O45 (two extracts) and E. coli O103 (one extract; Figure 3). None of the strains evaluated in this study inhibited growth of Shigella dysenteriae.

The relative strength of inhibition varied among cell-free extracts and was assessed based on the diameter of the zone of inhibition and the opacity of the clearing (Figure 3A). Samples were designated as very weak (3 mm diameter) to very strong (11 mm diameter; Figure 3; Supplementary Table S3). The inhibitory activity of cell-free extracts from E. coli on S. sonnei was generally categorized as strong and very strong, whereas inhibitory activity on S. flexneri was largely determined to be medium or weak. Similarly, the cell-free extracts from Enterobacter spp. that inhibited STEC produced medium or weak inhibition of growth.

Cell-free extracts from 332 food-enrichment broths derived from 235 food products (Figure 4; Supplementary Table S2) were evaluated to determine prevalence of inhibitors to Shigella spp. or STEC in food enrichments. Of the 332 enrichment broths tested, cell-free extracts from 25 (7.55%) samples inhibited growth of at least one of the 12 Shigella or STEC strains used in this study (Figure 5). Twenty-one samples (6%) inhibited growth of Shigella spp. and seven (2%) inhibited growth of STEC (Figure 5). Among the 25 cell-free extracts containing inhibitors, 21 (84%) affected S. sonnei, six (24%) affected S. flexneri and seven (28%) affected STEC growth (Figure 5). One of the extracts (GTA-1452) inhibited growth of all STEC strains tested in this study and three extracts inhibited both Shigella and STEC strains. None of the extracts affected growth of S. dysenteriae.

As with the extracts from bacterial strains, the relative strength of inhibition was assessed based on the diameter of the zone of inhibition and the opacity of the clearing (Figure 3A). Strength of inhibition varied among the extracts and among indicator organisms tested (Figure 5; Supplementary Table S3). Inhibitory activity against S. sonnei tended to be strong, whereas inhibitory activity against S. flexneri and STEC was weaker (Figure 5). Shigella inhibitors were found in two (1.7%) of the 120 SB extracts (curry leaves and broccoli slaw) and STEC inhibitors were present in seven (3.2%) of 213 mTSB extracts tested. In contrast, mTSB extracts examined in this study were more likely to contain Shigella spp. inhibitors (8.9%), whereas none of the SB extracts contained STEC inhibitors. All the food enrichments had relatively neutral pH values between 6.0 and 7.5.

Cell-free extracts derived from the 85 meat mTSB extracts were most likely to contain inhibitors to either Shigella and/or STEC (19 extracts, 22% of meat enrichments; Figure 6; Supplementary Table S2). These extracts inhibited growth of Shigella spp. (14 extracts), STEC (two extracts) or both (three extracts). Two of the 23 cell-free extracts derived from cheese mTSB enrichments inhibited growth of either Shigella spp. or STEC. In contrast, only four of the 224 extracts derived from plant products (flax seeds, fruit, and vegetables) enriched in mTSB (n = 104) or SB (n = 120) contained inhibitors. In the 97 samples where plant products were enriched in both mTSB and SB, inhibition was only observed in one of the broths. For two of these samples (curry leaves and broccoli slaw), inhibitory compounds were detected in the SB extracts, but not the mTSB extracts. For two samples (both leafy greens) inhibitory compounds were detected the mTSB extracts, but not in the SB extracts.

All the cell-free extracts causing inhibition in at least one of the indicator Shigella or STEC strains were treated with proteolytic enzymes (proteinase-K and trypsin) to determine if inhibition was eliminated by the removal of the protein components of the extracts indicating that inhibitor was likely to be a bacteriocin (Figure 7A). The inhibitory activity of the cell-free extracts from most of the food strains [17 (74%)] and the food enrichments [15 (60%)] were affected by at least one proteolytic enzyme (suspected bacteriocins in Figures 3, 5). For the food enrichment broths, there were two samples that were indeterminate for all inhibited strains and one sample indeterminate for S. flexneri due to lack of inhibition in the untreated control. Inconclusive results were likely associated with prolonged storage of these extracts as inhibitory activity was found to generally decrease over time during storage at 4°C (data not shown). For the cell-free extract from OLC1219, the proteinase treatment reduced inhibition for S. sonnei strains but not for S. flexneri (Figure 3) indicating the presence of different inhibition mechanisms for these two species. Most of the cell-free extracts that inhibited Shigella (particularly S. sonnei) were affected by proteolytic enzymes (suspected bacteriocins in Figures 3, 5). Cell-free extracts that inhibited STEC were generally not affected by proteolytic enzymes (Figures 3, 5).

To identify bacteriophages, the inhibitory cell-free extracts from the food strains and food enrichments that were resistant to proteolytic digestion were also diluted to assess the presence of plaques (Figure 7A). Plaques were observed in dilutions derived from eight of the cell-free extracts from bacterial strains (suspected bacteriophage in Figures 3, 7B). For strain OLC1219 plaques were observed with S. flexneri but not S. sonnei indicating that inhibition of S. flexneri growth was likely due to bacteriophage, and inhibition against S. sonnei growth was likely due to production of bacteriocins (see above). Extracts from the OLC1028 strain were not completely affected by proteolytic enzymes and plaques were observed following treatment with proteolytic enzymes indicating production of both bacteriocin and bacteriophage inhibitors of S. sonnei. Plaques were observed in extracts from five of the food enrichment broths (bacteriophage in Figure 5, 7C).

Attempts were made to recover isolates of bacteria producing inhibitors from 13 of the mTSB enrichment broths producing inhibitory compounds (Figure 5, stars) using the triple overlay method (Henning et al., 2015). Inhibiting organisms were successfully recovered from seven of these samples (Figure 5, yellow stars and Table 2). All recovered isolates were determined to be E. coli based on whole-genome sequence analysis (data not shown). Cell-free extracts from isolates generally exhibited similar inhibitory properties to the cell-free extracts from enrichment cultures (Table 2; Figure 5, yellow stars). For example, all seven isolates inhibited growth of both strains of S. sonnei. Activity of the extracts from six of the E. coli isolates was affected by proteolytic enzymes indicating that inhibition was likely due to the production of bacteriocins (Table 2). The isolate recovered from STH-2768 m produced an inhibitor that affected both S. sonnei and S. flexneri, and was determined to produce bacteriophage as the inhibition was not impacted by proteolytic enzymes.

A collection of 200 food-associated bacterial strains (Supplementary Table S1) was tested for the production of inhibitory activity against a panel of seven STEC and five Shigella strains. The panel of indicator strains was selected to represent clinically important species and strains of pathogens that are targeted in food testing programs. The Gram-negative foodborne bacteria included in this study would typically be highly represented in food-enrichment cultures aimed at recovery of Shigella/STEC. Most methods integrate antibiotics such as novobiocin to reduce growth of Gram-positive bacteria, but generally do not include selective agents that reduce growth of Gram-negative bacteria (Vimont et al., 2007). Only two of the 36 Enterobacter strains tested inhibited growth of STEC (Figure 3B; OLC1633 and OLC1667). In previous investigations organisms such as Clostridium spp., E. coli, Hafnia alvei, Brochothrix thermosphacta, and Pediococcus acidilactici present in meats were shown to outcompete STEC; however, the mechanism for this was not identified (Duffy et al., 1999; Kang et al., 2021). Similarly, Paquette et al. (2018) identified E. coli strains capable of inhibiting STEC due to production of diffusible antimicrobial compounds (Paquette et al., 2018). While E. coli with this activity was not found in the present study, analysis of a larger number of strains or food samples may have led to the identification of strains with similar properties. In contrast, extracts from 20 of the 118 E. coli strains tested were found to inhibit growth of Shigella spp., particularly S. sonnei, indicating that this species is highly susceptible to antimicrobial compounds produced by food microbiota. The inhibition of Shigella spp. by antibiotics produced by E. coli recovered from human sources was first described over 70 years ago (Halbert, 1948; Halbert and Gravatt, 1949), and S. sonnei strains have been used as indicator organisms for bacteriocins detection due to known susceptibility to a variety of colicins (Šmarda and Obdržálek, 2001; Micenková et al., 2014). It is interesting to note that STEC strains were more likely to produce inhibitors impacting growth of Shigella spp. compared to non-pathogenic strains. The association of bacteriocins and virulence factors in E. coli has been previously reported (Bradley et al., 1991; Micenková et al., 2014). Both of these traits may provide a competitive advantage in certain environments.

Analysis of cell-free extracts derived from a variety of food enrichments was done to evaluate the production of inhibitors by more complex communities of representative food microbiota. While Shigella broth would not be used for detection of STEC, and mTSB would not be used for detection of Shigella, similar analyses conducted with both types of enrichment broths enabled comparison of inhibitor production by organisms growing in the two media. Inhibition of at least one of the 12 indicator organisms tested was observed for 7.5% of the enrichment cultures tested, making it a relatively common occurrence overall. Inhibitors were more commonly associated with raw meat products enriched in mTSB (22% of raw meat enrichments) relative to plant products (1.8%). Similarly, a recent study found pathogen-killing bacteriophage to be more prevalent in raw beef and chicken than in vegetables and seafood (Premarathne et al., 2017). The relatively high prevalence of Shigella inhibition in the mTSB enrichments may be due to the species of bacteria present in the food matrix rather than differences in the enrichment broths. For example, E. coli is known to be associated with animal products (Barco et al., 2015). Shigella-inhibiting E. coli has long been known to be associated with human clinical samples (Halbert, 1948; Halbert and Gravatt, 1949; Levine and Tanimoto, 1954), but to confirm animal association, samples of animal fecal matter should be further examined. The association of inhibition to mTSB is partly due to the fact that meat and cheese products were not enriched in Shigella broth in this study. Paired enrichments of raw meat products in both broths could be evaluated to confirm the association of inhibitor-production with raw meats rather than enrichment broths. In the 97 plant products enriched with both broths, no association of the inhibiting organisms to the enrichment broths was observed; however, only four of the 224 broths examined produced inhibitors.

Similar to what was observed with the bacterial strains, S. sonnei was the indicator species that was the most sensitive to inhibition (21 out of 25 extracts), followed by S. flexneri and STEC (Figure 5). The observation of similar trends between the bacterial strains and enrichments indicates that the bacterial strains used in this study are representative of the bacteria in food enrichments. Most enrichments affected only one species (e.g., S. sonnei or STEC for 19 of 25 extracts) however there were some samples that showed a broader activity. For instance, cell-free extracts from one enrichment culture inhibited all seven STEC strains (GTA-1452, Figure 5). There were also three enrichment broths that inhibited both STEC and Shigella strains (GTA-1549, STH-2577 and STH-2777). This is likely indicative of an inhibitor that has a larger spectrum of activity, or potentially more than one strain with this activity in the samples (see below). Bacteriocins and bacteriophages can have broad or narrow spectrums of activity (Penadés et al., 2015; Simons et al., 2020). Note that the approach used to evaluate cell-free extracts was only semi-quantitative, as interpretation could be somewhat subjective, particularly for “weak” and “very weak” spots. Size of spots was also influenced by length of storage, with reduced activity over time (data not shown). Nonetheless, general trends could be determined with the screening approach used in this study.

Recovery of inhibiting organisms from enrichment cultures was challenging. Out of 13 enrichment cultures, seven E. coli isolates were recovered from cultures derived from raw meat products using a triple agar overlay method (Henning et al., 2015; Table 2). Recovery of inhibitor-producing E. coli is consistent with observations for the food-associated bacterial strains, and further supports the finding that E. coli may be an important source of inhibition, particularly for growth of S. sonnei. Results may be biased by the use of only one of the indicator strains (S. sonnei, OLC2340) for the recovery of inhibitory isolates, which were all derived from meat enrichments. E. coli is an indicator of fecal matter contamination which could occur during the slaughter process, potentially explaining the association of these organisms with raw meat products (Tallon et al., 2005; Odonkor and Ampofo, 2013; Barco et al., 2015). Failure to recover isolates in six samples may be because the method required recovery of a bacterial strain producing the inhibition. This approach would not work for the recovery of bacteriophage that may have been present in the foods, but not associated with a bacterial host. Cell-free extracts from the isolated E. coli strains had similar inhibitory properties to the extracts from the food samples from which they were isolated (Table 2; Supplementary Table S3), particularly to S. sonnei, which was the organism used for the recovery of these isolates. However, differences in activity against other indicator strains were observed. For example, OLC3032 was active against S. flexneri, unlike in the original enrichment culture where only S. sonnei was affected and conversely OLC3028 did not inhibit growth of S. flexneri, unlike the original food enrichment culture. This indicates that multiple strains may have been responsible for inhibitory activity in the more complex enrichment cultures. Use of multiple indicator strains, and characterization of additional bacterial isolates may have led to recovery of additional strains.

S. sonnei and S. flexneri were included as indicator organisms in this study as they are the Shigella species most commonly associated with outbreaks in North America (Thompson et al., 2015; Centers for Disease Control and Prevention (CDC), 2016; The et al., 2016). Shigella sonnei was most commonly affected by antimicrobial compounds, followed by S. flexneri (Figures 3, 5). Previous studies have that shown that S. flexneri was more highly affected by organic acids (e.g., by-products from food and food microbiota) than S. sonnei (Hentges, 1969; Uyttendaele et al., 2001; Zhang et al., 2011). S. dysenteriae was not affected by any of the cell-free extracts, so it is possible this species has a tolerance or resistance to inhibitors such as bacteriocins due to differences in targeted receptors in this species (Alonso et al., 2000). The acidity of the cultures was not likely to be an important factor in the observed growth inhibition. The pH range of Shigella growth is between 4.8–9.3 and the range of STEC growth is 4.0–10.0 (Food and Drug Administration, 2011). The pH of the bacterial isolate cell-free extracts (6.5–7.5) and food enrichment extracts (6.0–7.5) was well within these ranges.

Foodborne Shigella outbreaks are often associated with plant products (Kozak et al., 2013; Nygren et al., 2013). While enrichment broths derived from plant products were less likely to contain bacteriocins than those derived from meats in this study, this does not mean that recovery of Shigella spp. from plant products would not be problematic. Shigella contamination of foods is exclusively from human sources, and such contamination would likely also include E. coli. Given that human isolates of E. coli commonly inhibit Shigella spp. (Halbert, 1948; Levine and Tanimoto, 1954), the combination of organisms could impact recovering Shigella from the implicated foods. In fact, in a foodborne outbreak associated with baby corn in 2007, Shigella was not recovered from implicated samples despite strong epidemiological evidence, however, samples had high levels of E. coli (100–350 cfu/g) indicating potential issues with food hygiene (Lewis et al., 2009).

To gain a better understanding of the mechanism of the inhibition, cell-free extracts were digested with proteolytic enzymes to determine if the inhibitor was impacted, as would be expected for bacteriocins which are proteinaceous compounds (Elayaraja et al., 2014), and extracts were diluted to identify the plaques that would be attributed to bacteriophages (Hockett and Baltrus, 2017; Figure 7). Most of the inhibitors, particularly those affecting S. sonnei, were affected by proteolytic enzymes and are likely to be bacteriocins (Figures 3, 5, 7). Notably, there were two E. coli strains (OLC1028 and OLC1219) that were predicted to produce both bacteriocins and bacteriophages with antimicrobial activity against Shigella spp. (Figure 3). In contrast, STEC inhibition was more commonly associated with bacteriophages (Figures 3, 5). The Enterobacter strains that inhibited growth of the O45 and O103 were both predicted to produce bacteriophages (Figure 3). Similarly, the broad spectrum inhibition of STEC observed for sample GTA-1452 was also determined to be associated with bacteriophages. This inhibition could be due to the presence of a bacteriophage that has a wide spectrum of activity, or multiple bacteriophages targeting a few strains (Penadés et al., 2015; Simons et al., 2020). For example, STEC-killing phage can have broad or narrow host ranges (Litt et al., 2018; Mangieri et al., 2020). Interestingly, the inhibition produced by the isolate recovered from the STH-2768 m (OLC3032) was determined to be due to bacteriophages (Table 2) rather than the bacteriocins observed in the original culture (Supplementary Table S3), indicating that there was likely at least one bacteriocin-producing organism in the original culture that was not recovered. The identification of multiple inhibiting organisms within a single enrichment culture is further evidence that these strains may be an important factor in the success of competitive enrichment for food microbiology methods.

Bacteriophages active against STEC have been isolated from numerous zoonotic sources and may be relatively common indicating potential importance for enrichment cultures (Litt et al., 2018; Mangieri et al., 2020; Pinto et al., 2021). Presence of bacteriophages active against target species in enrichment cultures has been shown to reduce relative proportions of target Salmonella and S. sonnei by over a log indicating their critical impact on food microbiological methods (Muniesa et al., 2005). Bacteriocins would be expected to have similar inhibitory activity in food enrichment cultures. The ability to produce bacteriocins impacting closely related species is a common feature of E. coli enabling their survival in competitive environments (Micenková et al., 2016; Cameron et al., 2019). E. coli, particularly human isolates, frequently produce colicins, some of which have been shown to specifically target Shigella spp. (Halbert and Gravatt, 1949; Levine and Tanimoto, 1954). Only two colicins (colicin Z and J_s) that specifically target Enteroinvasive E. coli (EIEC) and Shigella species have been characterized (Micenková et al., 2019). Further analysis of the E. coli recovered in this study will be conducted to determine if the strains recovered encode related colicins.

In this study, S. sonnei were more susceptible to bacteriocins than S. flexneri and STEC. Due to practical considerations, the number of indicator strains used in this study was necessarily limited. It is possible that some of the indicator organisms used had higher resilience to phage and bacteriocins due to biological factors such as presence of immunity proteins, or other defense mechanisms (Rendueles et al., 2022). Use of a larger panel of Shigella strains, particularly strains associated with food outbreaks, will be necessary to establish whether S. sonnei strains are more susceptible than others. An understanding of the impact of bacteriocins on enrichment dynamics could lead to approaches to mitigating their impact. For example, fermentable sugars have been shown to reduce colicin production by S. sonnei (Lavoie et al., 1973). Future studies will target enrichment dynamics associated with bacteriocins in food matrices.

While outside of the scope of the current study, there is currently significant interest in alternatives to antibiotics for the prevention of food contamination with these Shigella spp. and STEC, and for the development of therapeutics (Yang et al., 2014; Mangieri et al., 2020; Telhig et al., 2020; Jiang et al., 2022). The bacteria recovered in this study are highly active against pathogenic strains of Shigella spp. and STEC, with potential for future use in the production of alternatives to antibiotics.