Monitoring Changes in the Antimicrobial-Resistance Gene Set (ARG) of Raw Milk and Dairy Products in a Cattle Farm, from Production to Consumption

Ádám Kerek^{1

2}, Virág Németh¹, Ábel Szabó¹, Márton Papp^{2

3}, Krisztián Bányai^{1

2

4}, Gábor Kardos^{2

5

6

7}, Eszter Kaszab^{2

5

8}, Krisztina Bali^{2

8}, Zoltán Nagy⁹, Miklós Süth^{2

10}, Ákos Jerzsele^{1

2}

Affiliations

¹ Department of Pharmacology and Toxicology, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.
² National Laboratory of Infectious Animal Diseases, Antimicrobial Resistance, Veterinary Public Health and Food Chain Safety, University of Veterinary Medicine Budapest, István utca 2, H-1078 Budapest, Hungary.
³ Centre for Bioinformatics, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.
⁴ Veterinary Medical Research Institute, HUN-REN, Hungária krt. 21, H-1143, Budapest, Hungary.
⁵ One Health Institute, University of Debrecen, Nagyerdei krt. 98, H-4032 Debrecen, Hungary.
⁶ National Public Health Center, Albert Flórián út 2-6, H-1097 Budapest, Hungary.
⁷ Department of Gerontology, Faculty of Health Sciences, University of Debrecen, Sóstói út 2-4, H-4400 Nyiregyhaza, Hungary.
⁸ Department of Microbiology and Infectious Diseases, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.
⁹ Biological Research and Development Department, CEVA-Phlyaxia Zrt., Szállás utca 5, H-1107 Budapest, Hungary.
¹⁰ Institute of Food Chain Science, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.

PMID: 38922012
PMCID: PMC11209563
DOI: 10.3390/vetsci11060265

Monitoring Changes in the Antimicrobial-Resistance Gene Set (ARG) of Raw Milk and Dairy Products in a Cattle Farm, from Production to Consumption

Ádám Kerek et al. Vet Sci. 2024.

. 2024 Jun 8;11(6):265.

doi: 10.3390/vetsci11060265.

Authors

Affiliations

¹ Department of Pharmacology and Toxicology, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.
² National Laboratory of Infectious Animal Diseases, Antimicrobial Resistance, Veterinary Public Health and Food Chain Safety, University of Veterinary Medicine Budapest, István utca 2, H-1078 Budapest, Hungary.
³ Centre for Bioinformatics, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.
⁴ Veterinary Medical Research Institute, HUN-REN, Hungária krt. 21, H-1143, Budapest, Hungary.
⁵ One Health Institute, University of Debrecen, Nagyerdei krt. 98, H-4032 Debrecen, Hungary.
⁶ National Public Health Center, Albert Flórián út 2-6, H-1097 Budapest, Hungary.
⁷ Department of Gerontology, Faculty of Health Sciences, University of Debrecen, Sóstói út 2-4, H-4400 Nyiregyhaza, Hungary.
⁸ Department of Microbiology and Infectious Diseases, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.
⁹ Biological Research and Development Department, CEVA-Phlyaxia Zrt., Szállás utca 5, H-1107 Budapest, Hungary.
¹⁰ Institute of Food Chain Science, University of Veterinary Medicine, István utca 2, H-1078 Budapest, Hungary.

PMID: 38922012
PMCID: PMC11209563
DOI: 10.3390/vetsci11060265

Abstract

Raw milk and dairy products can serve as potential vectors for transmissible bacterial, viral and protozoal diseases, alongside harboring antimicrobial-resistance genes. This study monitors the changes in the antimicrobial-resistance gene pool in raw milk and cheese, from farm to consumer, utilizing next-generation sequencing. Five parallel sampling runs were conducted to assess the resistance gene pool, as well as phage or plasmid carriage and potential mobility. In terms of taxonomic composition, in raw milk the Firmicutes phylum made up 41%, while the Proteobacteria phylum accounted for 58%. In fresh cheese, this ratio shifted to 93% Firmicutes and 7% Proteobacteria. In matured cheese, the composition was 79% Firmicutes and 21% Proteobacteria. In total, 112 antimicrobial-resistance genes were identified. While a notable reduction in the resistance gene pool was observed in the freshly made raw cheese compared to the raw milk samples, a significant growth in the resistance gene pool occurred after one month of maturation, surpassing the initial gene frequency. Notably, the presence of extended-spectrum beta-lactamase (ESBL) genes, such as OXA-662 (100% coverage, 99.3% identity) and OXA-309 (97.1% coverage, 96.2% identity), raised concerns; these genes have a major public health relevance. In total, nineteen such genes belonging to nine gene families (ACT, CMY, EC, ORN, OXA, OXY, PLA, RAHN, TER) have been identified. The largest number of resistance genes were identified against fluoroquinolone drugs, which determined efflux pumps predominantly. Our findings underscore the importance of monitoring gene pool variations throughout the product pathway and the potential for horizontal gene transfer in raw products. We advocate the adoption of a new approach to food safety investigations, incorporating next-generation sequencing techniques.

Keywords: ESBL; NGS; antimicrobial-resistance genes; cattle; dairy products; food safety; next-generation sequencing; public health; raw milk; taxonomy.

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Conflict of interest statement

The authors declare no conflict of interest.

Figures

**Figure 1**
Frequency of antimicrobial-resistance genes identified in raw milk samples, by drug group and resistance mechanism. PEN—penicillins; CEF—cephalosporins; MON—monobactams; CAR—carbapenems; TET—tetracyclines; AMG—aminoglycosides; FEN—phenicols; MAC—macrolides; LIN—lincosamides; PLE—pleuromutilins; PEP—peptide antibiotics; FOS—phosphomicin; FLQ—fluoroquinolones; SUL—sulphonamides; DIA—diaminopyrimidines; RIF—rifamicins; NIT—nitroimidazoles; DIS—disinfectants; AMC—aminocoumarins. The numbers in the bar chart represent the exact number of pieces of each resistance mechanism.

**Figure 2**
Frequency of antimicrobial-resistance genes identified in fresh cheese samples, by drug group and resistance mechanism. PEN—penicillins; CEF—cephalosporins; MON—monobactams; CAR—carbapenems; TET—tetracyclines; AMG—aminoglycosides; FEN—phenicols; MAC—macrolides; LIN—lincosamides; PLE—pleuromutilins; PEP—peptide antibiotics; FOS—phosphomicin; FLQ—fluoroquinolones; SUL—sulphonamides; DIA—diaminopyrimidines; RIF—rifamicins; NIT—nitroimidazoles; DIS—disinfectants; AMC—aminocoumarins. The numbers in the bar chart represent the exact number of pieces of each resistance mechanism.

**Figure 3**
Frequency of antimicrobial-resistance genes identified in matured cheese samples, by drug group and resistance mechanism. PEN—penicillins; CEF—cephalosporins; MON—monobactams; CAR—carbapenems; TET—tetracyclines; AMG—aminoglycosides; FEN—phenicols; MAC—macrolides; LIN—lincosamides; PLE—pleuromutilins; PEP—peptide antibiotics; FOS—phosphomicin; FLQ—fluoroquinolones; SUL—sulphonamides; DIA—diaminopyrimidines; RIF—rifamicins; NIT—nitroimidazoles; DIS—disinfectants; AMC—aminocoumarins. The numbers in the bar chart represent the exact number of pieces of each resistance mechanism.

**Figure 4**
The abundances of core-bacteriome (genera present in at least 10% of samples with a minimum abundance of 1%) varied among samples, including raw milk, raw cheese made from it and cheese examined after one month of aging. It is noticeable that following the inoculation of raw cheese, there is a selection for Gram-positive genera, followed by dominance of the *Streptococcus* genus during maturation. Az űrlap teteje.

See this image and copyright information in PMC

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Monitoring Changes in the Antimicrobial-Resistance Gene Set (ARG) of Raw Milk and Dairy Products in a Cattle Farm, from Production to Consumption

Affiliations

Monitoring Changes in the Antimicrobial-Resistance Gene Set (ARG) of Raw Milk and Dairy Products in a Cattle Farm, from Production to Consumption

Authors

Affiliations

Abstract

Conflict of interest statement

Figures

References

Grants and funding

LinkOut - more resources

Full Text Sources