Assessment of biofilm-forming capacity and multidrug resistance in Staphylococcus aureus isolates from animal-source foods: implications for lactic acid bacteria intervention

Background

Staphylococcus aureus, a Gram-positive bacterium, poses a significant threat to public health and food safety due to its virulence and its ability to develop antimicrobial resistance (AMR). Moreover, S. aureus can form biofilms in food environments, making it difficult to eradicate and pose a major challenge in foodborne illness prevention.

Methods

The study aimed to investigate the biofilm-forming capabilities and AMR profiles of 107 S. aureus isolates derived from milk, chicken meat, and chicken eggs. Further, the study compared the biofilm formation tendencies between multi-drug resistant (MDR) and non-MDR S. aureus isolates. Additionally, the research explored the antibacterial and anti-biofilm properties of Lactobacillus rhamnosus and Lactobacillus casei, focusing on their aggregation and co-aggregation effects with S. aureus.

Results

Around 70.10% of S. aureus isolates were found to be resistant to at least three antibiotic classes. The biofilm assay revealed that 16.82% isolates were strong biofilm formers. The MDR isolates displayed a strong biofilm-forming ability (i.e., 18.67%) and a higher prevalence of biofilm-associated genes [i.e., icaA (53.33%) and icaD (44.0%)] compared to non-MDR isolates. The LAB strain, L. rhamnosus exhibited a 29.06 mm mean antibacterial inhibition zone, an average reduction of 48.19% in biofilm growth, 55.46% auto-aggregation, and 40.61% co-aggregation with S. aureus. Similarly, L. casei demonstrated a 21.80 mm mean antibacterial inhibition zone, an average reduction of 31.56% in biofilm growth, 45.23% auto-aggregation, and 36.81% co-aggregation with S. aureus isolates.

Conclusion

This study provides valuable insights into the biofilm formation of MDR S. aureus and underscores the potential of L. rhamnosus and L. casei as bio-control agents. These findings highlight the necessity for additional research into the mechanisms through which LAB strains inhibit pathogenic biofilms and their potential applications in enhancing food safety.

Staphylococcus aureus, a Gram-positive bacterium, can cause illness in both animals and humans. Its ability to survive under a range of environmental conditions and resistance to various sanitizing chemicals make it a formidable pathogen, especially in food processing environments (Tallent et al. 2019). The presence of organism in food or on food processing equipment can lead to food poisoning outbreaks, making it as a serious public health biohazard in the food industry (Kadariya et al. 2014).

S. aureus poses a substantial risk for foodborne illnesses, primarily due to its ability to produce enterotoxins. This bacterium can proliferate on the mucous membranes and skin of food handlers, presenting a major challenge for food processing facilities (Miao et al. 2017). The heat stability of staphylococcal enterotoxins allows them to persist and be released during bacterial growth in food matrices, potentially contaminating the food through contact with handlers or animals (Giaouris et al. 2015; Galié et al. 2018). Furthermore, S. aureus demonstrates a high capability in forming biofilms on diverse surfaces within animal environments, further complicating control measures along the food production chain (Ferry et al. 2005; Vergara et al. 2017). Biofilms are complex colonial structures where bacteria aggregate and attach to each other and to surfaces, with genes responsible for extracellular polymeric substances (EPS) or ‘slime’ production, followed by maturation (Flemming 2016). Biofilm development is particularly concerning, as it increases the bacteria's ability to persist long enough in adverse environment. The icaADBC operon, which encodes icaA, icaD, icaB, and icaC core genes, as well as a regulatory gene (icaR), initiates the maturation of the biofilm matrix into multi-layered patterns. The co-expression of icaA and icaD genes facilitates the production of slime/EPS (Atshan et al. 2012). Additionally, diverse environmental stressors during biofilm formation can result in genetic variation and the formation of distinct biofilm communities, making them resistant and challenging to eradicate from the surfaces due to their diversity and intricacy (Sharan et al. 2022).

In addition to biofilms, the antimicrobial resistance (AMR) also poses a serious challenge to counter S. aureus as a foodborne pathogen (Sharan et al. 2023). The overuse and misuse of antibiotics have led to the emergence of AMR clones in food animal production systems, resulting in the development of drug-resistant strains of S. aureus that are challenging to human and animal health (Kadariya et al. 2014). Once the AMR strains establish biofilms, they render them resistant to antibacterial treatments and tolerant to harsh conditions, making eradication challenging (Sharan et al. 2022). Given the gravity of the problem, it is crucial to implement effective measures to control and prevent the spread of AMR strains of S. aureus.

Addressing biofilms remains a formidable challenge at the interface of food industry. Traditional control measures such as physical methods (hot steam, ultrasonication) and use of chemical compounds (sodium hypochlorite, sodium hydroxide solutions, hydrogen peroxide, peracetic acid, etc.) often fall short in effectively eliminating adhered bacteria from processing equipment, underscoring the pressing need for alternative strategies (Galié et al. 2018). Among the promising approaches, the utilization of probiotics stands out as a potential method for biofilm control. The Lactobacillus genus, comprising the most commonly used probiotic species, such as L. rhamnosus, L. casei, L. acidophilus, L. plantarum, L. delbrueckii, and L. reuteri, is the largest among LAB bacteria (Sengupta and Paramasivan 2019). Lactobacilli are Generally Recognized as Safe (GRAS) for consumption (Giordani et al. 2021). Furthermore, Lactobacilli release bacteriocins, biosurfactants, lactic acids, and exopolysaccharides. These compounds inhibit the growth of other microorganisms by reducing the pH of the surrounding environment and exerting antagonistic effects (Galié et al. 2018; Giordani et al. 2021). These characteristics make Lactobacilli a promising candidate for the prevention of biofilm formation, both as a probiotic supplement and as a biocontrol agent.

With this background, the current study was undertaken to examine the biofilm-forming capacity of S. aureus strains isolated from different animal-source foods. The objectives were to ascertain the correlation between biofilm formation and multi-drug resistance (MDR) in S. aureus and to assess the potential impact of lactic acid bacteria on S. aureus biofilm formation.

S. aureus isolates from animal-source foods

The study involved the analysis of 116 S. aureus isolates obtained from different animal-source foods, including milk (n = 41), chicken meat (n = 39), and chicken eggs (n = 36). The milk and chicken meat isolates were obtained from the repository of the Centre for One Health, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, Punjab, while the chicken egg isolates were taken from the previous study conducted by Sharan et al. (2023).

Isolation and identification

S. aureus isolates were identified using standard microbiological procedures on Baird-Parker agar (BPA) plates supplemented with egg yolk tellurite, as outlined in the Bacteriological Analytical Manual (Tallent et al. 2019). Additionally, biochemical confirmation was performed using a Microxpress Staphylococcus spp. identification kit (HiMedia, India).

The recovered isolates were further validated by using polymerase chain reaction (PCR) targeting 16S rRNA and nuc genes of S. aureus. The PCR protocol was adopted from Zehra et al. (2019). S. aureus ATCC 33591 strain was used as a positive control. In brief, the total reaction mixture of 25 μl was made containing 6.5 μl Go Taq green master mix (Promega, U.S.A), 0.5 µl of 10 pmol/µl of forward and reverse primers each, 5 μl of DNA template and nuclease-free water (NFW) to make up the reaction volume. The cycling conditions were as follows: 1 cycle of initial denaturation (94 °C/3 min), 30 cycles each of denaturation (94 °C/30 s), annealing (55 °C/30 s), extension (72 °C/2 min), 1 cycle final extension (72 °C/4 min) and withhold at 4 °C. The amplified PCR products were visualized through the agarose gel electrophoresis and further recorded under Gel documentation system (UVP Gel Seq. Software; Syngene, U.S.A). The details of the primers are listed in Table 1.

Antibiotic sensitivity test

The antibiotic susceptibility was tested against nine different classes of antibiotics viz., aminopenicillin (ampicillin), aminoglycosides (gentamicin), cephalosporins (cefoxitin), chloramphenicol (chloramphenicol), fluoroquinolones (ciprofloxacin), macrolides (erythromycin), oxazolidinones (linezolid), sulphonamides (sulpha-cotrimoxazole), and tetracyclines (tetracycline) as per Kirby-Bauer disc diffusion method (Bauer et al. 1966). The antibiotic selection was carried out with discussions between veterinary academicians and field experts to target the commonly used antibiotics in the region. The results were interpreted as per the guidelines of Clinical and Laboratory Standards Institute (M100 Performance Standards for Antimicrobial Susceptibility Testing, 32rd edition) (CLSI 2022). In brief, the isolates were added to Muller Hinton (MH) broth and incubated for 2–3 h at 37 °C, and the turbidity was adjusted using McFarland standards (0.5). Further, the inoculums were placed on MHA plates and allowed to dry. The discs were placed and incubated for 18–24 h at 37 °C to measure the inhibition zone. The multiple antibiotic resistance (MAR) index was calculated using the formula provided (Krumperman 1983):

whereas,

X = Number of antibiotics exhibited resistance towards the isolate.

Y_n = Number of tested antibiotics.

The MAR index of more than 0.2 indicates high risk of antibiotics’ exposure to the microorganism.

Biofilm evaluation using crystal violet (CV) assay

The biofilm formation was evaluated using the crystal violet (CV) assay as described by Stepanovic et al. (2000) with minor modifications. The overnight test cultures were suspended in 1000 μl of tryptic soy broth (TSB) for 18 h at 37 °C and further diluted to 1:100 in 1% glucose-supplemented TSB. In triplicates, 200 μl of culture adjusted to 10⁷–10⁸ CFU/mL was added per well and incubated for 48 h at 37 °C, with negative control wells containing no test culture. The plates were washed with phosphate-buffered saline (PBS; pH 7.2), fixed with 200 μl methanol/well for 15 min and stained with 200 μl of 2% crystal violet dye. The plates were then washed and air-dried. Lastly, 200 μl of 33% peracetic acid was added per well, and absorbance (OD) was measured using microtiter plate reader at 570 nm.

The results were interpreted following the guidelines provided by Stepanović et al. (2007) based on the ODc (control), and the isolates were classified into four categories:

1. a)

   Non-biofilm formers: OD of the test isolate ≤ OD_c

2. b)

   Weak biofilm formers: OD of the test isolate between OD_c to 2xOD_c

3. c)

   Moderate biofilm formers: OD of the test isolate between 2 to 4xOD_c

4. d)

   Strong biofilm formers: OD of the test isolate > 4xOD_c

Molecular detection of biofilm forming genes of S. aureus

The detection of biofilm-forming icaA and icaD genes in S. aureus was carried out using polymerase chain reaction (PCR). The 2 μl DNA template of previously identified S. aureus isolates (i.e., Isolate ID: SE 12 for icaA and Isolate ID: SE169 for icaD gene) was used as a positive control (Sharan et al. 2023). The PCR assay for icaA and icaD genes were adopted from Diemond-Hernández et al. (2010) and Vasudevan et al. (2003), respectively. The details of the primers used are listed in the Table 1. The PCR cycling conditions for the icaA gene was: 1 cycle initial denaturation (94 °C/3 min), 30 cycles each of denaturation (94 °C/30 s), annealing (56 °C/30 s), extension (68 °C/30 s), 1 cycle final extension (72 °C/7 min) and withholding at 4 °C. The PCR cycling conditions for icaD gene was: 1 cycle initial denaturation (94 °C/3 min), 30 cycles each of denaturation (92 °C/45 s), annealing (45 °C/30 s), extension (72 °C/1 min), 1 cycle final extension (72 °C/7 min) and withholding at 4 °C. The amplified PCR products were visualized through the agarose gel electrophoresis and further recorded under Gel documentation system (UVP Gel Seq. Software; Syngene, U.S.A).

Extracellular polymeric substance (EPS) quantification

The EPS was extracted and quantified by following phenol sulphuric acid method as described by Amrutha et al. (2017) and Dubois et al. (1956), respectively with minor modification. The total EPS was estimated using standard curve for different concentrations (in µg/ml) developed using regression model. The absorbance was obtained with different concentration of working standard glucose solution at 490 nm (Fig. 1) and the regression equation of Y = 0.1546*X—0.006730 was formed to determine the EPS concentration of each isolate. The overnight cultured test isolates were harvested by centrifugation at 8000 rpm for 30 min at 20 °C, and the filtered supernatant was added to three volumes of chilled 100% ethanol and incubated overnight at -20 °C. EPS was collected by centrifugation at 7000 rpm for 30 min at 5 °C. After that, 1 ml of MilliQ water was added to pellet with 0.05 ml of 80% phenol and 5 ml of conc. H₂SO₄ (Al-Shabib et al. 2017). The tubes were placed for 10–20 min in a water bath at 25 °C, and the absorbance was read at 490 nm using microtiter plate reader.

Standard curve for determination of extracellular polymeric substance (EPS) concentration

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Measurement of antibacterial activity using agar spot diffusion assay

The antibacterial activity of two LAB strains, Lactobacillus rhamnosus ATCC 53103 and Lactobacillus casei ATCC 393, was measured using an agar spot diffusion assay as described by Leite et al. (2015). Overnight cultured LAB strains (10 μl) were spotted on the surface of de Man, Rogosa and Sharpe (MRS) agar and incubated for 24 h at 37 °C. MRS agar was overlaid with 5 ml of tryptic soy agar (TSA) containing 100 μl of test culture and incubated for 24 h at 37 °C. The antibacterial activity was evaluated by measuring the clear zone diameter (mm) around the LAB strain. The results were interpreted as follows:

1. a)

   The inhibition zone with no halo: negative (-)

2. b)

   The inhibition zone with a halo of 1 mm: positive ( +)

3. c)

   An inhibition zone between 2 and 5 mm: positive (+ +)

Effect of LAB strains on in vitro biofilm formation using modified crystal violet assay

The effect of the LAB strains on biofilm production was assessed using the protocols described by Gómez et al. (2016). The overnight test culture of S. aureus isolates was diluted 1:100 in TSB supplemented with 1% glucose, while LAB strains were cultured in MRS and turbidity was adjusted to 0.5 MacFarland. A 100 μl culture of S. aureus (SA) was inoculated in triplicate with an equal amount of L. rhamnosus (LR) and L. casei (LC) culture strains, both alone (SA + LR; SA + LC) and in combination (SA + LR + LC). The remaining steps were carried out as described in Sect. "Biofilm evaluation using crystal violet (CV) assay", following the modified crystal violet assay protocol to evaluate the effect of LAB strains on biofilm formation of S. aureus.

Assessment of auto aggregation

The auto-aggregation assay was performed as described by Lee et al. (2021). The overnight cultures of S. aureus and LAB cultures were harvested by centrifugation at 10,000 rpm for 5 min at 4 °C. The pellet was washed with 1 ml of 1X PBS (pH 7.2), and the turbidity was adjusted to 0.5 MacFarland. Afterwards, 200 µl of homogenized bacterial suspension was inoculated into a 96 well polystyrene microtiter plate (in triplicate). The OD of the homogenized bacterial suspension was initially measured at 0 h and then re-evaluated after allowing the same suspension to rest for 24 h at 37 °C without agitation. The absorbance was measured at 600 nm, and the data were interpreted using the following formula:

where,

OD_t represents the absorbance of the mixture at 24 h.

OD_i is absorbance at 0 hr

Assessment of co-aggregation assay with S. aureus

The preparation of the homogenized bacterial strain suspension followed the procedure outlined in the auto-aggregation assay described in Sect. "Assessment of auto aggregation". The LAB strain suspensions of L. rhamnosus and L. casei were mixed with equal volumes (100 µl) of the test culture alone (SA + LR; SA + LC) and in combination (SA + LR + LC) per well (in triplicate).

OD was assessed as described in the auto-aggregation assay in Sect. "Assessment of auto aggregation". The percentage of co-aggregation was calculated as described by Gómez et al. (2016) using the formula:

where OD_p and OD_L represent the absorbance in the tubes containing only the test or LAB strain, respectively, measured at 0 h, while OD_mix represents the absorbance of the mixture for both pathogen and LAB strains at 24 h. The calculations were carried out by adjusting the formula as per the input parameters.

Statistical analysis

The data obtained from the experiments were recorded in a Microsoft® Office Excel 2019 spreadsheet. The normal distribution of data was assessed using the Kolmogorov–Smirnov test, which was performed using IBM SPSS Statistics (version 26.0; IBM Corporation, Armonk, New York, USA). The statistical analysis was conducted as necessary, employing Fisher’s exact test, chi-squared test, Spearman’s correlation analysis, and Wilcoxon signed rank test. The figures were generated using GraphPad Prism 14.0 and Microsoft® Office Excel 2019.

Isolation and molecular identification of S. aureus

A total of 107 S. aureus isolates, comprising 35 from milk, 36 from chicken meat, and 36 from chicken eggs, were revived on Baird Parker agar. These isolates were subjected to biochemical characterization and were further confirmed by the presence of the 16S rRNA (genus-specific) and nuc (species-specific) genes, specifically identifying them as Staphylococcus aureus within the Staphylococcus genus.

Phenotypic AMR profile

A total of 70.10% isolates were resistant for ≥ 3 tested antibiotics with 77.57% of isolates showing MAR index > 0.2 (Table 2). The S. aureus isolates from milk showed the highest resistance against ampicillin and erythromycin (88.57%) followed by cefoxitin (85.71%), tetracycline (45.71%), linezolid (31.42%), gentamicin (17.14%), sulpha-cotrimoxazole (14.28%), and ciprofloxacin (8.57%), with none demonstrating resistance to chloramphenicol. Similarly, among chicken meat isolates, highest resistance was observed for cefoxitin (100%) followed by tetracycline (88.88%), erythromycin (86.11%), ampicillin (83.33%), linezolid (80.55%), sulpha-cotrimoxazole (77.77%), gentamicin (61.11%), ciprofloxacin (55.55%), and chloramphenicol (50%). Among egg isolates, the highest resistance was observed for cefoxitin (100%), followed by erythromycin (97.22%), ampicillin (86.11%), tetracycline (77.77%), sulpha-cotrimoxazole (55.55%), chloramphenicol (33.33%), gentamicin (33.33%), ciprofloxacin (25%), and linezolid (19.44%) (Fig. 2).

Phenotypic antibiogram profile (in percentage) of S. aureus isolates (SM: Milk S. aureus isolates; SC: Chicken meat S. aureus isolates; SE: Chicken eggs S. aureus isolates)

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Biofilm forming ability

In present study, 16.82% (18/107) isolates were strong biofilm former, 13.1% (14/107) were moderate, and 55.14% (59/107) were weak biofilm former, whereas 14.95% (16/107) were non-biofilm producers. Among 35 milk isolates, 17.14% (6/35) were strong, 20.0% (7/35) were moderate and 48.57% (17/35) were weak biofilm producers, whereas 14.28% (5/35) isolates were non-biofilm producer. In 36 chicken meat isolates, 11.11% (4/36) were strong, 8.33% (3/36) as moderate, and 72.22% (26/36) were weak biofilm producers, whereas 8.33% (3/36) of the isolates were non biofilm producers. Among 36 egg isolates, 22.22% (8/36) were strong, 11.11% (4/36) were moderate, and 44.44% (16/36) were weak biofilm producers, whereas, 22.22% (8/36) of the isolates were non-biofilm producer. The comparison of the ability of S. aureus biofilm formation from different foods are presented as Fig. 3.. On statistical analysis using Kruskal–Wallis’s test, a non-significant association (p-value > 0.05; 95% CI) was observed between the mean OD values of different isolates sources (i.e., milk, meat and eggs).

Comparison of the biofilm formation ability of S. aureus from different animal-source foods (SM: Milk S. aureus; SC: Chicken meat S. aureus; SE: Chicken eggs S. aureus)

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Correlation between biofilm forming ability and antimicrobial resistance

Out of all 107 isolates, 75 were found to be MDR and among them 18.67% (14/75) were strong, 13.33% (10/75) were moderate and 53.33% (40/75) were weak biofilm formers, while 14.67% (11/75) were non-biofilm producer. Among 32 non-MDR isolates, 12.50% (4/32) were strong, 12.50% (4/32) were moderate, and 59.38% (19/32) were weak biofilm former, while 15.63% (5/32) were non-biofilm producer. The relationship between biofilm formation ability and antimicrobial resistance was analysed (Fig. 4). The plot was drawn by converting the isolate number falling into each grade into percentage. The darker colour in the Fig. 4 denotes higher proportion of isolates. The statistical analysis revealed non-significant difference (p value: > 0.05; 95% CI) between biofilm forming ability of MDR and non-MDR isolates.

Relationship between biofilm formation ability (BFA) and antimicrobial resistance (AMR) of S. aureus isolates

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Among 35 milk isolates, 24 were MDR and among them 12.5% (3/24) were strong, 25.0% (6/24) were moderate, and 50% (12/24) were weak biofilm producers whereas, 12.5% (3/24) were non biofilm producer. Among 11 non-MDR isolates, 27.27% (3/11) were strong, 9.1% (1/11) were moderate, 45.45% (5/11) were weak biofilm producers, whereas 18.18% (2/11) were non-biofilm producers. Out of 36 chicken meat isolates, 26 were MDR and among them 15.38% (4/26) were strong, 7.69% (2/26) were moderate, and 73.07% (19/26) were weak biofilm former, whereas a single isolate was non biofilm producer. Among, 10 non-MDR isolates, 10.0% (1/10) were moderate, 70.0% (7/10) were weak and 20.0% (2/10) were non biofilm producers. Out of 36 egg isolates, 25 were MDR and among them, 28.0% (7/25) were strong, 8.0% (2/25) were moderate and 36.0% (9/25) were weak biofilm former, whereas 28.0% (7/25) of the isolates were non biofilm former. Among 11 non-MDR isolates, 9.10% (1/11) were strong, 18.18% (2/11) were moderate, and 63.64% (7/11) were weak biofilm formers, whereas a single isolate was non biofilm former. On statistical analysis, non-significant difference (p value: > 0.05; 95% CI) was observed between biofilm forming ability of MDR and non-MDR isolates among all three animal-source foods.

Detection of biofilm forming icaA and icaD genes

The presence of the icaA gene was detected in 45.80% (49/107) of all S. aureus isolates. Among MDR and non-MDR isolates, positivity rates were 53.33% (40/75) and 28.12% (9/32), respectively. Among 35 milk isolates, 45.71% (16/35) carried the icaA gene wherein among MDR and non-MDR, 50.0% (12/24) and 36.36% (4/11) isolates were positive, respectively. Among 36 chicken meat isolates, 33.33% (12/36) isolates were positive wherein among MDR and non-MDR isolates, 38.46% (10/26) and 20.0% (2/10) positivity were observed, respectively. Among 36 egg isolates, 58.33% (21/36) isolates carried the icaA gene wherein among MDR and non-MDR, 72.0% (18/25) and 27.27% (3/11) isolates were positive, respectively.

The presence of the icaD gene was observed in 38.31% (41/107) of all isolates, with positivity rates of 44.0% (33/75) among MDR isolates and 25.0% (8/32) among non-MDR isolates. Among 35 milk isolates, 42.85% (15/35) isolates carried the icaD gene wherein among MDR and non-MDR, 47.83% (11/23) and 36.36% (4/11) of were positive, respectively. Moreover, among 36 chicken meat isolates, 25.0% (9/36) isolates were positive for icaD gene, whereas among MDR and non-MDR, 30.77% (8/26) and 10.0% (1/10) of isolates were positive, respectively. Among 36 egg isolates, 47.22% (17/36) isolates were positive wherein among MDR and non-MDR, 56.0% (14/25) and 27.27% (3/11) of the isolates were positive, respectively.

Quantification of extracellular polymeric substance (EPS)

The EPS yield obtained from S. aureus isolates was ranging from 3.11 to 59.64 mg/ml (mean: 14.10 mg/ml). Among the milk S. aureus isolate, the EPS concentration obtained was 3.90 to 59.64 mg/ml (mean: 15.21 mg/ml). Among chicken meat isolates, the EPS concentration ranged from 3.11 to 44.83 mg/ml (mean: 11.42 mg/ml), wherein among egg isolates the EPS concentration lies between 3.38 to 46.51 mg/ml (mean: 15.67 mg/ml). Three isolates, one each from milk, meat and egg produced a significantly higher EPS with the concentration 59.64 mg/ml, 44.83 mg/ml and 46.51 mg/ml, respectively (Fig. 5). The difference between the EPS production among various source isolates were found to be non-significant (p value: > 0.05; 95% CI). Overall, the highest average EPS yield was observed among the S. aureus isolates of egg, followed by milk and chicken meat.

Boxplot depicting the distribution of extracellular polymeric substance (EPS) concentration (in mg/ml) among S. aureus isolates (SM: Milk S. aureus isolates; SC: Chicken meat S. aureus isolates; SE: Chicken eggs S. aureus isolates)

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Measurement of anti-bacterial activity of LAB strains on S. aureus isolates using agar spot diffusion assay

All the S. aureus isolates showed a halo inhibition zone of diameter > 2 mm around L. rhamnosus and L. casei strains (Fig. 6). Overall, the inhibition zone diameter range observed was 15 to 34 mm (Fig. 7).

Anti-bacterial inhibition zone formation by Lactobacillus rhamnosus (LR) and Lactobacillus casei (LC) on a S. aureus isolate

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Boxplot for antibacterial activity mean inhibition zone (in mm) by Lactobacillus rhamnosus (LR) and Lactobacillus casei (LC) for S. aureus

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The L. rhamnosus strain showed an inhibition zone within the range 19 to 34 mm (mean: 29.06 mm). The inhibition range in milk was 19 to 34 mm (mean: 28.76 mm), in chicken meat was 24 to 34 mm (mean: 28.96 mm) and in chicken egg was 26 to 33 mm (mean: 29.58 mm). Similarly, the L. casei strain showed an inhibition zone within the range 15 to 31 mm (mean: 21.80 mm). The inhibition zone range in milk was 16 to 29 mm (mean: 21.48 mm), in chicken meat was 17 to 31 mm (mean: 22.15 mm) and in chicken egg was 15 to 28 mm (mean: 21.74 mm).

Determination of LAB strains effect on biofilm formation of S. aureus isolates

All the isolates were subjected to crystal violet (CV) assay with L. rhamnosus and L. casei, both individually and in combination. The results showed a marked reduction in absorbance when the isolates were co-incubated with L. rhamnosus and L. casei strains (Fig. 8a, b, c). The L. rhamnosus showed average reduction in absorbance by 48.19% to the absorbance of S. aureus isolates biofilm. On co-culture with L. rhamnosus, an average reduction of 48.08%, 47.76% and 48.93% was observed in S. aureus isolates of milk, chicken meat and chicken eggs, respectively. Similarly, the L. casei strain reduced the biofilm formation of S. aureus isolates by 31.56%. An average reduction of 29.02% was observed in milk isolates, 33.35% in chicken meat isolates, and 32.43% in chicken egg isolates, on co-culture of S. aureus with L. casei. Furthermore, on combined treatment (i.e., with LR and LC strains), an average reduction of 38.51% in absorbance was observed. A reduction of 34.57% was observed in milk isolates, 43.26% in chicken meat isolates, and 37.19% in chicken egg isolates, on co-culture of S. aureus with L. rhamnosus and L. casei. Further, the absorbance value of S. aureus isolates was compared with the absorbance value obtained after co-incubating with the LAB strains (alone and in combination) using Wilcoxon signed rank test. On analysis, the results were found statistically significant (p-value: < 0.05; 95% CI) among all combinations (SA + LR; SA + LC; SA + LR + LC).

Effect of Lactobacillus rhamnosus (LR) and Lactobacillus casei (LC) strains on biofilm formation of (a) Milk S. aureus isolates, (b) Chicken meat S. aureus isolates and (c) Chicken egg S. aureus isolates

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Assessment of auto-aggregation

The highest auto-aggregation percentage was observed after 24 h of incubation. The aggregation abilities of L. rhamnosus and L. casei was observed to be 55.46% and 45.23%, respectively. Overall, the S. aureus isolates (n = 107) was observed to have auto-aggregation percentage between 11.24% and 50.90% (mean: 25.59%). Further, the aggregation in milk isolates was observed to be 11.24% to 50.90% (mean: 26.30%), in chicken meat, 16.28% to 38.95% (mean: 24.79%), wherein among egg isolates, 14.53% to 42.62% (mean: 25.77%).

Assessment of co-aggregation in between S. aureus and LAB strains (L. rhamnosus and L. casei)

Overall, the co-aggregation percentage of L. rhamnosus with S. aureus isolates was observed in the range of 27.19% to 55.15% (mean: 40.61%). The range in milk, chicken meat and chicken eggs were observed as 27.19% to 55.15% (mean: 40.30%), 31.59% to 52.12% (mean: 39.93%) and 30.70% to 51.22% (mean: 41.60%), respectively. Similarly, the co-aggregation of L. casei with S. aureus isolates was observed in the range of 25.28% to 50.12% (mean: 36.81%). Among milk isolates, the range were observed to be 25.83% to 50.12% (mean: 36.20%) and in chicken meat isolates was 27.57% to 47.89% (mean: 36.48%), and in chicken egg isolates was 25.28% to 49.87% (mean: 37.75%). In addition, the co-aggregation of L. rhamnosus and L. casei strains with S. aureus isolates were also assessed, where cell to cell interaction was observed to be in the range of 25.0% to 52.28% (mean: 38.21). Among milk isolates, the range was 27.04% to 52.28% (mean: 38.18%), in chicken meat isolates, the range was 25.20% to 51.39% (mean: 37.93%), and in chicken egg isolates, the range was 24.42% to 52.28% (mean: 38.51%). The co-aggregation abilities between LAB strains and pathogen are present in Fig. 9.

Co-aggregation percentage of S. aureus and LAB strains (L. rhamnosus and L. casei) (SM: Milk S. aureus isolates; SC: Chicken meat S. aureus isolates; SE: Chicken eggs S. aureus isolates)

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The multi-drug resistance (MDR) has been identified as a major public health concern around the world. We observed a high MDR in S. aureus isolates from chicken meat (72.23%) followed by chicken eggs (69.44%) and milk (68.60%). The observed high resistance in poultry products might be due to overuse of antibiotics for therapeutic and prophylactic purpose in poultry sector. Similar observations, indicating high MDR prevalence in the poultry sector, were also reported by Rahman et al. (2018). Among the MDR isolates, the highest MDR resistance was observed in S. aureus isolates from eggs (90.91%), followed by chicken meat (53.85%), and milk (12.0%). It is widely recognized that the misuse or overuse of antibiotics creates selection pressure, which promotes the development of resistance in microbes (Bissong and Ateba 2020). Furthermore, the present study also assessed the potential relationship between AMR and the ability to form biofilm among both MDR and non-MDR isolates. As shown in Fig. 4, most of the isolates with drug-resistance characteristics have a strong biofilm formation ability. This indicates a relationship between biofilm formation ability and AMR. Notably, among the isolates forming biofilms, the proportion of MDR isolates forming weak biofilms was slightly lower (53.33%) than that of non-MDR isolates (59.38%). However, assuming that isolates with strong biofilm formation inherently display high levels of drug resistance poses a challenge, as the underlying mechanisms, despite the observed correlation, remain unclear. Various factors such as bacterial species or strain, type of antimicrobial agent, stage of biofilm development, and growth conditions are reported to influence biofilm formation and associated antimicrobial resistance in many studies (Barros et al. 2017; Al-Shabib et al. 2017; Bissong and Ateba 2020; Idrees et al. 2021).

The findings of the present study revealed that S. aureus isolates from various animal-origin foods exhibit diverse levels of biofilm-forming ability. Isolates from chicken eggs showed the highest rate of strong biofilm formation (22.22%), followed by those from milk (17.14%) and chicken meat (11.11%) (Fig. 3). Additionally, the mean values of biofilm formation ability (@OD570) for S. aureus derived from different sources were found to be similar. Similarly, a study by Ou et al. (2020) demonstrated comparable mean biofilm-forming abilities of S. aureus from various animal-origin food sources (pork, chicken, beef, duck, lamb, aquatic products, egg, and milk). The findings suggests that the shared characteristics of food substrates, such as surface properties and viscosity plays a more pivotal role in facilitating the successful colonization of S. aureus than variations in food surface properties and bacterial species. In essence, animal-source food serves as an excellent adhesive medium and reservoir for S. aureus biofilm growth (Koohestani et al. 2018).

The development of biofilm of S. aureus is regulated by the icaADBC operon in which icaA and icaD genes play significant role in their adherence to surfaces during early stages of biofilm development (Idrees et al. 2021). In the present study, nearly half of the biofilm-forming isolates possessed either the icaA or icaD gene, which play a major role in surface adherence. None of the non-biofilm producer isolates were positive for either icaA or icaD gene. The past studies demonstrated that in addition to the role of the icaA and icaD genes in bacteria's biofilm formation, there are many additional bacterial and environmental factors that also influence the adhesion properties (O’Gara 2007; Kroning et al. 2016). The varying prevalence rates of these genes are likely due to distinct gene expression exhibited by S. aureus when exposed to different temperatures and contact surfaces over varying periods (Atshan et al. 2012; Kroning et al. 2016). A study by O’Gara (2007) highlighted the existence of ica independent biofilm mechanisms in S. aureus. However, the understanding of the regulatory mechanisms governing the ica locus in the present study remains incomplete and requires further exploration in future research.

In addition to the regulation of the icaADBC operon, microbial surface adherence is facilitated by extracellular polymeric substances (EPS) (Flemming 2016). The carbohydrate content of EPS was assessed in the present study. It was found that all isolates exhibiting biofilm activity produced a significantly varied concentration of EPS (mean: 14.1 mg/ml). Strong biofilm formers exhibited a higher concentration of EPS compared to weak biofilm formers. Furthermore, no significant difference in EPS production was observed among isolates from different sources, such as milk, chicken meat, and chicken eggs. Earlier studies have reported varied concentrations of EPS from different microbial strains. For example, Amrutha et al. (2017) observed EPS yields ranging from 35 to 100 mg/ml among Salmonella isolates, which is significantly higher than the findings of our study. In contrast, Patel et al. (2012) reported an EPS yield of 0.5 mg/ml from Weissella sp. isolated from fermented food. Thereby, the variation in the production of EPS can be specifically strain dependent and vary among different environmental conditions (Flemming and Wingender 2010). The EPS matrix is extremely complex and dynamic structure that warrants detailed exploration in future studies (Flemming 2016).

The present study investigated the effectiveness of both LAB strains’ antibacterial activity, anti-biofilm activity, auto-aggregation and coaggregation ability against S. aureus. L. rhamnosus showed better antibacterial property in comparison to L. casei strains against all S. aureus isolates, regardless of their source of origin. The results revealed that antibacterial activity produced an inhibition zone with a diameter greater than 12 mm against all S. aureus strains tested. Consequently, both LAB strains were further tested for their efficacy against biofilm forming ability of S. aureus isolates. The LAB strains (alone and in combination) removed the biofilm growth of S. aureus. The observed high anti-biofilm activity of LAB strains against food associated S. aureus might be due to production of anti-biofilm compounds such as lactic acid as it alters the pH and disrupts the bacterial viability (Gerbaldo et al. 2012; Van Der Weerden et al. 2013). Moreover, LAB provides competitive conditions to microbial cells by inhibiting their adhesions and by adapting competitive exclusion approach towards bacteria to prevent it from colonizing (Giaouris 2020). When comparing both LAB strains, the L. rhamnosus were observed to be more effective in biofilm removal than L. casei (alone and in combination). Furthermore, several investigations have made similar observations and concluded that the anti-biofilm activity of LAB strains is a species-dependent phenomenon (Song and Lee 2017; Koohestani et al. 2018). The findings of present study observed that both the LAB strains, L. rhamnosus and L. casei (alone and in combination), possess a potent biofilm removal potential against S. aureus biofilm. Therefore, these strains can be used as biocontrol agents in food production, either alone and in combination to reduce the risk of microbial contamination and improving food safety in sustainable way.

Furthermore, both LAB strains exhibited weak biofilm formation, but demonstrated higher auto-aggregation ability compared to S. aureus. The majority of S. aureus isolates were found to have low aggregation ability, potentially contributing to the formation of weaker biofilms. In comparison, L. rhamnosus exhibited higher aggregation ability than the L. casei strain, consistent with a study conducted by Woo and Ahn (2013), which also reported higher auto-aggregation ability in L. rhamnosus compared to L. casei and L. acidophilus strains. In addition, when determining the co-aggregation ability of both LAB strains, the results were consistent with those of auto-aggregation, with L. rhamnosus exhibiting higher co-aggregation than L. casei. The results suggests that an aggregative phenotype can be one criterion to screen the strains with co-aggregative properties. In general, probiotics inhibit pathogen colonization and biofilm formation by binding pathogens into co-aggregates, altering their microenvironment, competing for nutrients and adherence sites, and releasing inhibitory substances (García-Cayuela et al. 2014; Monteagudo-Mera et al. 2019).

A notable limitation of our study is that the experiments were conducted in vitro within a controlled laboratory setting rather than in vivo. While we aimed to assess various parameters associated with biofilm and intervention by LAB, conducting experiments in food matrices and under food processing conditions would provide more accurate evidence regarding the impacts of probiotics. Also, additional investigation is required to elucidate the precise mechanisms by which LAB and their active compounds impede the growth of foodborne pathogens.

In conclusion, the present study demonstrates that S. aureus isolates from animal-source foods display a high resistance to more than three classes of antibiotics. Additionally, these isolates were found to be capable of forming biofilms, which could act as a persistent source of foodborne contamination. Also, surface properties of various food samples act as an important factor in determining the colonisation of S. aureus strains. The study also revealed that MDR isolates have a higher potential to form strong biofilms and possess a greater percentage of biofilm genes than non-MDR isolates. Further, the study investigated the use of LAB strains (L. rhamnosus and L. casei), both individually and in combination, for their ability to combat S. aureus biofilms. The findings suggest that both strains are effective in removing biofilm growth, with L. rhamnosus proving to be more effective than L. casei. Thereby, probiotic-based intervention strategies may provide a promising approach to reduce the establishment of both MDR and non-MDR biofilms.

All data are incorporated into the article and its online supplementary material.

AMR:

Antimicrobial resistance

EPS:

Extracellular polymeric substance

LAB:

Lactic acid bacteria

LR:

Lactobacillus rhamnosus

LC:

Lactobacillus casei

MDR:

Multidrug Resistant

MHA:

Mueller Hinton Agar

OD:

Optical density

SA:

Staphylococcus aureus

Authors are thankful to the Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana for providing necessary help to carry out the research work.

The financial support received from the project of ‘Rashtriya Krishi Vikas Yojana (RKVY), India’ is thankfully acknowledged.

Authors and Affiliations

1. Centre for One Health, College of Veterinary Science, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, 141004, India

   Manjeet Sharan, Pankaj Dhaka, Jasbir Singh Bedi & Randhir Singh

2. Department of Livestock Products Technology, College of Veterinary Science, Guru Angad Dev Veterinary and Animal Sciences University, Ludhiana, 141004, India

   Nitin Mehta

Contributions

Manjeet Sharan: Conceptualization; Data curation; Formal analysis; Investigation; Methodology; Software; Writing – original draft; Pankaj Dhaka: Conceptualization; Data curation; Formal analysis; Funding acquisition; Investigation; Methodology; Project administration; Supervision; Visualization; Writing – original draft; Writing – review & editing; Jasbir Singh Bedi: Conceptualization; Funding acquisition; Methodology; Project administration; Supervision; Validation; Writing – review & editing; Nitin Mehta: Conceptualization; Methodology; Resources; Supervision; Writing – review & editing; Randhir Singh: Conceptualization; Methodology; Resources; Supervision; Writing – review & editing.

Corresponding author

Correspondence to Pankaj Dhaka.

Competing interests

The authors have declared that no competing interests exist.

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