Antimicrobial resistance of enterococci isolated from food in South Brazil: Comparing pre- and post-RDC 20/2011

COSTA, LETÍCIA DA F.X.; FALCÃO, DAIANE A.; GRASSOTTI, TIELA T.; CHRISTIANO, FRANCIELE D.P.; FRAZZON, JEVERSON; FRAZZON, ANA PAULA G.

doi:10.1590/0001-3765202220201765

Abstract

Antimicrobial resistance has been attributed to the overuse of antibiotics. To control the use of antibiotics, Brazil adopted the RDC 20/2011. A comparison the antibiotic-resistance profile of bacterial has provided important insights into resistance evolution. Enterococci are ubiquitous bacteria recommended to be used as a sentinel organism, in national surveillance systems, for tracking antimicrobial resistance through the food chain. The present study aimed to evaluate the diversity and antimicrobial resistance of enterococci collected from food in South Brazil in 2017 (pos-RDC 20/11) for comparison with isolated in 2007 (pre-RDC 20/11). A total of 310 enterococci were isolated from vegetables and products of animal origin, identified by PCR and MALDI-TOF, tested for antimicrobial susceptibility and screened for resistance genes. Enterococcus casseliflavus was dominant in vegetables and E. faecalis in products of animal origin. Enterococcal isolates in 2017 were mostly sensitive to ampicillin, gentamicin, chloramphenicol, and vancomycin when compared to isolated collected in 2007. While resistance levels to most compounds remained relatively stable, multidrug resistance decreased by 24% during this period. Our results suggest that RDC 20/11 had a positive outcome in controlling the spread of antimicrobial resistance. This study provides baseline data to measure future changes in the prevalence of resistant enterococci.

Key words
Enterococcal isolates; vegetable and products of animal origin; antibiotic resistance; RDC 20/2011

INTRODUCTION

Antimicrobials are widely used to treat bacterial infections in humans and animals. Moreover, they are also used as growth promoters in animal husbandry and aquaculture. The misuse and overuse of antimicrobials are the main driving forces for the selection of resistant bacterial populations in various environments (World Health Organization 2020WORLD HEALTH ORGANIZATION (WHO). 2020. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland. https://www.who.int/news-room/fact-sheets/detail/antibiotic-resistance.
https://www.who.int/news-room/fact-sheet... ). The impact of the presence of antimicrobial agents or resistant bacteria in all environments is a growing global public health concern. Antibiotic-resistant bacteria can reach humans directly through the consumption of contaminated food and/or indirectly through environmental pollution containing human or animal excrements (Kristiansson et al. 2011KRISTIANSSON E, FICK J, JANZON A, GRABIC R, RUTGERSSON C, WEIJDEGARD B, SODERSTROM H & LARSSON DG. 2011. Pyrosequencing of antibiotic-contaminated river sediments reveals high levels of resistance and gene transfer elements. PLoS ONE 6: e17038., Marathe et al. 2013MARATHE NP, REGINA VR, WALUJKAR SA, CHARAN SS, MOORE ERB, LARSSON DGJ & SHOUCHE YS. 2013. A treatment plant receiving waste water from multiple bulk drug manufacturers is a reservoir for highly multi-drug resistant integron-bearing bacteria. PLoS ONE 8: e77310.).

In terms of transmission through food, antimicrobial resistant bacteria can contaminate animal products during slaughter and processing. Moreover, fruits and vegetables can be contaminated by direct contact with soil, water, or fertilizer containing insufficiently treated material (e.g., animal feces-based fertilizers or human sewage). Several studies have identified resistant bacteria in food products and animal samples, such as methicillin-resistant Staphylococcus aureus in livestock (Price et al. 2012PRICE LB ET AL. 2012. Staphylococcus aureus CC398: host adaptation and emergence of methicillin resistance in livestock. MBio 3: e00305-e00311.), extended spectrum-beta-lactamase Escherichia coli on vegetables, raw chicken, raw egg-surfaces, and raw meat (Rasheed et al. 2014RASHEED MU, THAJUDDIN N, AHAMED P, TEKLEMARIAM Z & JAMIL K. 2014. Antimicrobial drug resistance in strains of Escherichia coli isolated from food sources. Rev Inst Med Trop São Paulo 56: 341-346.), and antibiotic-resistant enterococci in various foods (McGowan et al. 2006MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982., Gomes et al. 2008GOMES BC, ESTEVES CT, PALAZZO ICV, DARINI ALC, FELIS GE, SECHI LA, FRANCO BDGM & MARTINIS ECP. 2008. Prevalence and characterization of Enterococcus spp. isolated from Brazilian foods. Food Microbiol 25: 668-675., Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Riboldi et al. 2009RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128., Ben Said et al. 2015BEN SAID L, KLIBI N, DZIRI R, BORGO F, BOUDABOUS A, SLAMA KB & TORRES C. 2015. Prevalence, antimicrobial resistance and genetic lineages of Enterococcus spp. from vegetable food, soil and irrigation water in farm environments in Tunisia. J Sci Food Agric 96: 1627-1633.). Studies have suggested that antimicrobial-resistant bacteria and their resistance genes can be transmitted from food to humans via the food chain (Leverstein-van Hall et al. 2011LEVERSTEIN-VAN HALL MA, DIERIKX CM, COHEN STUART J, VOETS GM, VAN DEN MUNCKHOF MP, VAN ESSEN-ZANDBERGEN A, PLATTEEL T & FLUI AC. 2011. Dutch patients, retail chicken meat and poultry share the same ESBL genes, plasmids and strains. Clin Microbiol Infect 17: 873-880., Verraes et al. 2013VERRAES C ET AL. 2013. Antimicrobial resistance in the food chain: a review. Int J Environ Res Public Health 10: 2643-2669.).

Enterococci are ubiquitous microorganisms found in the gastrointestinal tracts of humans and animals, as well as in plants, sewage, water, soil, and foods (Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Lebreton et al. 2014LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59., Grassotti et al. 2018GRASSOTTI TT, ZVOBODA DA, COSTA LFX, ARAÚJO AJG, PEREIRA RI, SOARES RO, WAGNER PGC, FRAZZON J & FRAZZON APG. 2018. Antimicrobial resistance profiles in Enterococcus spp. isolates from fecal samples of wild and captive black capuchin monkeys (Sapajus nigritus) in South Brazil. Front Microbiol 9: 2366., Costa et al. 2019COSTA LFX, GRASSOTTI TT, CANANI CR, DE LIRA AD, DE MOURA TM, CAMPOS AAS, FRAZZON J & FRAZZON APG. 2019. Diversidade, perfis de resistência e virulência de Enterococcus spp. em fezes de morcegos urbanos Tadarida brasiliensis (Brazilian free-tailed bats). Braz J Biosci 17: 43-52., Bhardwaj 2019BHARDWAJ SB. 2019. Enterococci: An Important Nosocomial Pathogen. In: KIRMUSAOGLU S (Ed), Pathogenic Bacteria, IntechOpen. Rijeka, Croatia, p. 1-17.). Enterococcus spp. exhibit greater environmental persistence and are regarded as robust organisms capable of tolerating a wide range of temperatures and pH levels that can grow in the presence of 6.5 % sodium chloride (NaCl) or 40% of bile salts. Additionally, they can exchange resistance determinants through gene transfer by plasmids and transposons, among themselves and with other genera (Lebreton et al. 2014LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59.). Due to their ubiquity, resilience and ability to acquire antibiotic resistance, enterococci have been recommended for integration into antimicrobial resistance-monitoring systems as sentinel bacteria (World Health Organization 2013WORLD HEALTH ORGANIZATION (WHO). 2013. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland.).

Some enterococci species have been used in food and feed, such as starter-culture and probiotics, respectively (Giraffa 2002GIRAFFA G. 2002. Enterococci from foods. FEMS Microbiol Rev 26: 163-171., Franz et al. 2003FRANZ CMAP, STILES ME, SCHLEIFER KH & HOLZAPFEL WH. 2003. Enterococci in foods – a conundrum for food safety. Int J Food Microbiol 88: 105-122.). However, despite their beneficial effects in foods, they can also be involved in food spoilage and their presence may also serve as an indicator of microbial contamination of fecal origin (Hanchi et al. 2018HANCHI HM, MOTTAWEA W, KHALED SE & HAMMAMI R. 2018. The Genus Enterococcus: Between Probiotic Potential and Safety Concerns-An Update. Front Microbiol 9: 1791.). Furthermore, enterococci are among the most important MDR microorganisms associated with health-associated infection worldwide, causing a wide range of infections in immunocompromised and hospitalized patients (Lebreton et al. 2014LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59., Bhardwaj 2019BHARDWAJ SB. 2019. Enterococci: An Important Nosocomial Pathogen. In: KIRMUSAOGLU S (Ed), Pathogenic Bacteria, IntechOpen. Rijeka, Croatia, p. 1-17.). Nonetheless, resistant enterococci are not restricted to clinical samples, since strains have been isolated from various environments, including food, animals, and environmental samples (Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Lebreton et al. 2014LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59., Grassotti et al. 2018GRASSOTTI TT, ZVOBODA DA, COSTA LFX, ARAÚJO AJG, PEREIRA RI, SOARES RO, WAGNER PGC, FRAZZON J & FRAZZON APG. 2018. Antimicrobial resistance profiles in Enterococcus spp. isolates from fecal samples of wild and captive black capuchin monkeys (Sapajus nigritus) in South Brazil. Front Microbiol 9: 2366., Costa et al. 2019COSTA LFX, GRASSOTTI TT, CANANI CR, DE LIRA AD, DE MOURA TM, CAMPOS AAS, FRAZZON J & FRAZZON APG. 2019. Diversidade, perfis de resistência e virulência de Enterococcus spp. em fezes de morcegos urbanos Tadarida brasiliensis (Brazilian free-tailed bats). Braz J Biosci 17: 43-52., Bhardwaj 2019BHARDWAJ SB. 2019. Enterococci: An Important Nosocomial Pathogen. In: KIRMUSAOGLU S (Ed), Pathogenic Bacteria, IntechOpen. Rijeka, Croatia, p. 1-17.).

Interventions to promote practical antibiotic use are essential to reduce the emergence and spread of antimicrobial-resistant bacteria in human healthcare and food production. Many countries have been improving the prudent use and dispensing of antimicrobials (Roca et al. 2015ROCA I ET AL. 2015. The global threat of antimicrobial resistance: science for intervention. New Microbes New Infect 6: 22-29.). Notably, the World Health Organization (WHO) has created a set of strategies to combat rising antibiotic resistance, which include, colon improving sanitation and hygiene to reduce overall infection rates, and optimizing the use (and preventing the overuse) of antibiotics in humans and animals (World Health Organization 2013WORLD HEALTH ORGANIZATION (WHO). 2013. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland.). In this sense, in 2010, the Brazilian Health Surveillance Agency published the RDC nº 20/2011 (RDC 20/11) to facilitate the dispensation and control of antimicrobial use (Brasil 2011BRASIL. 2011. Ministério da Saúde, Agência Nacional de Vigilância em Saúde (ANVISA). Resolução da Diretoria Colegiada – RDC nº 20, de 5 de maio de 2011. Dispõe sobre o controle de medicamentos à base de substâncias classificadas como antimicrobianos, de uso sob prescrição, isoladas ou em associação. Diário Oficial da União, Brasília: Ministério da Saúde, 2011.).

Studies comparing antibiotic resistance patterns in collections of clinical strains have been conducted to address the antibiotic resistance in community settings (Ventola 2015VENTOLA CL. 2015. The antibiotic resistance crisis: part 1: causes and threats. P&T 40: 277-283., Massot et al. 2016MASSOT M ET AL. 2016. Phylogenetic, virulence and antibiotic resistance characteristics of commensal strain populations of Escherichia coli from community subjects in the Paris area in 2010 and evolution over 30 years. Microbiol 162: 642-650., Kulik et al. 2019KULIK EM, THURNHUEER T, KARYGIANNI L, WALTER C, SCULEAN A & EICK S. 2019. Antibiotic susceptibility patterns of Aggregatibacter actinomycetemcomitans and Porphyromonas gingivalis strains from different decades. Antibiotics 8: 253.). However, few studies have compared antibiotic-resistant strains from food collections (Alonso-Hernando et al. 2012ALONSO-HERNANDO A, PRIETO M, GARCÍA-FERNÁNDEZ C, ALONSO-CALLEJA C & CAPITA R. 2012. Increase over time in the prevalence of multiple antibiotic resistance among isolates of Listeria monocytogenes from poultry in Spain. Food Control 23: 37-41., Tyson et al. 2017TYSON GH, NYIRABAHIZI E, CRAREY E, KABERA C, LAM C, RICE-TRUJILLO C, MCDERMOTT PF & TATE H. 2017. Prevalence and Antimicrobial Resistance of Enterococci Isolated from Retail Meats in the United States, 2002 to 2014. Appl Environ Microbiol 84: e01902-17.). To date, no study in Brazil has compared antibiotic-resistant enterococci isolated from food products, since the RDC 20/11 was implemented. Therefore, the present study aimed to compare the species distribution and antibiotic resistance patterns of enterococci isolated from food products in South Brazil in 2017 (pos-RDC 20/11) with those collected and isolated in 2007 (pre-RDC 20/11).

MATERIALS AND METHODS

Enterococci from foods

Isolation: A total of 30 food samples comprising: vegetables (cassava, beetroot, potato, sweet potato, parsley, carrot and cabbage), and food of animal sources (raw chicken meat, colonial cheese type and soft cheese) were purchased from different popular markets in the Porto Alegre, South Brazil in 2017. The enterococci isolation was performed according to protocol described by Riboldi et al. (2009)RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128..

Previous collection: Enterococcus faecalis (n=27), E. faecium (n=23), E. mundtii (n=1) and Enterococcus sp. (n=5)- isolated under the same conditions in 2007 (Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Riboldi et al. 2009RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128.) were used to compare species distribution and antibiotic resistance patterns.

Genus and species identification

DNA extraction: Genomic DNA was extracted by boiling method, as described by Depardieu et al. (2004)DEPARDIEU F, PERICHON B & COURVALIN P. 2004. Detection of the van alphabet and identification of enterococci and staphylococci at the species level by multiplex PCR. J Clin Microbiol 42: 5857-5860.. Genus-specific polymerase chain reaction (PCR) assays, which targeted the tuf gene, performed as described by Ke et al. (1999)KE D, PICARD FJ, MARTINEAU F, MENARD C, ROY PH, OUELLTTE M & BERGERON MG. 1999. Development of a PCR assay for rapid detection of Enterococci. J Clin Microbiol 37: 3497-3503. (Table I). The E. faecalis ATCC 29212 and E. faecium SS1274 (D’Azevedo et al. 2006D’AZEVEDO PA, DIAS CAG & TEIXEIRA LM. 2006. Genetic diversity and antimicrobial resistance of enterococcal isolates from southern regions of Brazil. Rev Inst Med Trop São Paulo 48: 11-16.) were used as positive control.

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Table I
Primers used in the PCR reactions carried out for identification of enterococci genus and species.

PCR assay: Isolates were screened with the species-specific PCR assay for E. faecalis, E. faecium, E. casseliflavus and E. hirae (Table I). Amplifications were carried out in a total volume of 25 μL containing: 100 ng of template DNA, 1 X reaction buffer (Ludwig Biotechnology), 0.4 μM of each primer (Ludwig Biotechnology), 1.5 mM MgCl2, 200 μM of dNTPs (Ludwig Biotechnology), 1 U Taq DNA polymerase (Ludwig Biotechnology), and MilliQ water. PCR amplifications were performed in the conventional thermocycler (Applied Biosystems 2720 Thermal Cycler) according to the following program: 94 °C for 5 min followed by 35 cycles of 94 °C for 1 min, appropriate annealing temperature for each primer for 1 min, extension at 72 °C for 1 min, and a final extension at 72 °C for 5 min. The DNA fragments amplified were analyzed in 1.5% (w/v) agarose gels stained with SYBR® Safe DNA Gel, and visualized on a photo-documenter.

Isolates not identified by PCR were submitted to matrix-assisted laser desorption and ionization time-of-flight technique (MALDI-TOF), according to Sauget et al. (2017)SAUGET M, VALOT B, BERTRAND X & HOCQUET D. 2017. Can MALDI-TOF mass spectrometry reasonably type bacteria? Trends Microbiol 25: 447-455..

Antimicrobial susceptibility analysis

Determination of antimicrobial susceptibility was performed by disk diffusion method, according to Clinical and Laboratory Standards Institute (CLSI 2017CLSI - CLINICAL AND LABORATORY STANDARDS INSTITUTE. 2017. M100 Performance Standards for Antimicrobial Susceptibility Testing, 26ª ed., informational supplement M100.). Eleven antibiotics commonly used in clinical and veterinary medicine were evaluated: ampicillin (AMP - 10 µg), ciprofloxacin (CIP - 5 µg), chloramphenicol (CHL - 30 µg), erythromycin (ERY - 15 µg), gentamicin (GEN - 120 µg), nitrofurantoin (NIT - 300 µg), norfloxacin (NOR - 10 µg), streptomycin (STR - 300 µg), tetracycline (TET - 30 µg), rifampicin (RIF - 5 µg) and vancomycin (VAN - 30 µg). The minimum inhibitory concentration (MIC) for streptomycin, gentamicin and vancomycin was performed using the microdilution method according to CLSI (2017)CLSI - CLINICAL AND LABORATORY STANDARDS INSTITUTE. 2017. M100 Performance Standards for Antimicrobial Susceptibility Testing, 26ª ed., informational supplement M100.. Strains resistant to three or more unrelated antibiotics were considered as multidrug resistant (MDR) (Schwarz et al. 2010SCHWARZ S, SILLEY P, SIMJEE S, WOODFORD N, VAN DUIJKEREN E, JOHNSON AP & GAASTRA W. 2010. Assessing the antimicrobial susceptibility of bacteria obtained from animals. Vet Microbiol 141: 1-4.).

Detection of antibiotic resistance genes by PCR

Erythromycin-, gentamicin- and tetracycline-resistant strains were tested by PCR for presence resistance genes commonly associated with clinical and environmental enterococci. The erm(A), erm(B), erm(C) genes (Sutcliffe et al. 1996SUTCLIFFE J, GREBE T, TAIT-KAMRADT A & WONDRACK L. 1996. Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Chemother 40: 2562-2566.), which encode resistance to erythromycin from the modification of the target preventing the binding of macrolides, and the msrC gene (Werner et al. 2001WERNER G, HILDEBRANDT B & WITTE W. 2001. The newly described msrC gene is not equally distributed among all isolates of Enterococcus faecium. Antimicrob Agents Chemother 45: 3672-3673.), which produces low-level resistance to erythromycin through the efflux pump mechanism were tested in all erythromycin-resistant strains. To gentamicin-resistant strains, the aac(6’)-aph(2’) gene (Jia et al. 2014JIA W, LI G & WANG W. 2014. Prevalence and antimicrobial resistance of Enterococcus species: a hospital-based study in China. Int J Environ Res Public Health 11: 3424-3442.), which encode an enzymatic modification was evaluated. The tet(M) and tet(S) genes (Aarestrup et al. 2000AARESTRUP FM, AGERSO Y, GERNER-SMIDT P, MADSEN M & JENSEN LB. 2000. Comparison of antimicrobial resistance phenotypes and resistance genes in Enterococcus faecalis and Enterococcus faecium from humans in the community, broilers, and pigs in Denmark. Diagn Microbiol Infect Dis 37: 127-137.) that encode for ribosome protection, and tet(L) gene (Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370.) that encodes for efflux proteins were evaluated in all tetracycline-resistant strains. The primers used are listed in Table II.

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Table II
Primers used in the PCR reactions carried out for detection of resistance genes.

Amplifications were carried out in a total volume of 25 μL containing: 100 ng of template DNA, 1 X reaction buffer (Ludwig Biotechnology), 0.4 μM of each primer (Ludwig Biotechnology), 1.5 mM MgCl2, 200 μM of dNTPs (Ludwig Biotechnology), 1 U Taq DNA polymerase (Ludwig Biotechnology), and MilliQ water. PCR amplifications were performed in the conventional thermocycler (Applied Biosystems 2720 Thermal Cycler) according to the following program: 94 °C for 5 min followed by 35 cycles of 94 °C for 1 min, appropriate annealing temperature for each primer for 1 min, extension at 72 °C for 1 min, and a final extension at 72 °C for 5 min. The DNA fragments amplified were analyzed in 1.5% (w/v) agarose gels stained with SYBR® Safe DNA Gel, and visualized on a photo-documenter.

Statistical analysis

The results obtained here were used to compare species distribution and antimicrobial resistant profile with our enterococcal collection isolated pre-RDC 20/11. The results obtained were submitted to statistical analysis, which was performed using Statistic Package of the Social Science (SPSS) software 18th edition, using Pearson’s chi-square test (χ²) (p≤0.05) and Fisher’s exact test as evaluation parameters.

RESULTS AND DISCUSSION

Enterococcus species diversity in food

Among the 360 Gram-positive and catalase-negative cocci isolated, 310 (86.1%) were confirmed as enterococci. E. faecalis (57.1%) was the most abundant species detected in both groups of analyzed food, followed by E. casseliflavus (33.2%), E. hirae (5.5%), E. faecium (1.9%), and E. durans (1.0%) (Table III). Four isolates (1.3%) could not be identified at the species level and were classified as Enterococcus sp. Considering the ubiquitous natural distribution of enterococci, the presence of these species in food is consistent with previous studies (McGowan et al. 2006MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982., Gomes et al. 2008GOMES BC, ESTEVES CT, PALAZZO ICV, DARINI ALC, FELIS GE, SECHI LA, FRANCO BDGM & MARTINIS ECP. 2008. Prevalence and characterization of Enterococcus spp. isolated from Brazilian foods. Food Microbiol 25: 668-675., Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Riboldi et al. 2009RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128., Kim et al. 2020KIM NH, KIM HW, PARK SM, SEO GH, CHO TJ, YU HR, KIM SH, HWANG JH, CHOI C & RHEE MS. 2020. Virulence patterns and prevalence of seven Enterococcus species isolated from meats and leafy vegetables in South Korea. Food Control 108: 106867.).

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Table III
Distribution of Enterococcus species among food samples.

In the vegetables group, E. casseliflavus (50.99%) and E. faecalis (43.56%) were the most frequent species detected in cassava, beetroot, potato, sweet potato, parsley, and cabbage. Enterococcus hirae (2.47%), and Enterococcus faecium (0.99%) were identified in low rates. In all foods of animal origin, E. faecalis was more frequently found (82.4%), while E. hirae (11.11%), E. faecium (3.7%) and E. durans (2.77%) were only isolated in soft cheeses samples, and none of the samples contained E. casseliflavus. Although some differences in enterococcal distribution were detected among food samples from distinct origins, not significant differences could be verified (p > 0.05).

The predominance of E. casseliflavus in vegetables is consistent with previous studies (McGowan et al. 2006MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982., Gomes et al. 2008GOMES BC, ESTEVES CT, PALAZZO ICV, DARINI ALC, FELIS GE, SECHI LA, FRANCO BDGM & MARTINIS ECP. 2008. Prevalence and characterization of Enterococcus spp. isolated from Brazilian foods. Food Microbiol 25: 668-675., Kim et al. 2020KIM NH, KIM HW, PARK SM, SEO GH, CHO TJ, YU HR, KIM SH, HWANG JH, CHOI C & RHEE MS. 2020. Virulence patterns and prevalence of seven Enterococcus species isolated from meats and leafy vegetables in South Korea. Food Control 108: 106867.). The presence of E. casseliflavus, E. faecium, and E. hirae in vegetables samples can be associated with untreated wastewater used for agriculture (mainly irrigation) and/or raw animal manure (organic fertilizers) used on vegetable crops. This finding is supported by the published study of Ben Said et al. (2015)BEN SAID L, KLIBI N, DZIRI R, BORGO F, BOUDABOUS A, SLAMA KB & TORRES C. 2015. Prevalence, antimicrobial resistance and genetic lineages of Enterococcus spp. from vegetable food, soil and irrigation water in farm environments in Tunisia. J Sci Food Agric 96: 1627-1633. who isolated the same species from vegetables, soil, and irrigation water samples from farms in Tunisia.

The occurrence of E. faecalis, E. hirae, E. faecium, and E. durans is consistent with the results of McGowan et al. (2006)MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982., Gomes et al. (2008)GOMES BC, ESTEVES CT, PALAZZO ICV, DARINI ALC, FELIS GE, SECHI LA, FRANCO BDGM & MARTINIS ECP. 2008. Prevalence and characterization of Enterococcus spp. isolated from Brazilian foods. Food Microbiol 25: 668-675., Frazzon et al. (2009)FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Campos et al. (2013)CAMPOS ACFB, SOUZA NR, SILVA PHC & SANTANA AP. 2013. Resistência antimicrobiana em Enterococcus faecalis e Enterococcus faecium isolados de carcaças de frango. Pesq Vet Bras 33: 575-580., Camargo et al. (2014)CAMARGO CH, BRUDER-NASCIMENTO A, LEE SHI, JÚNIOR AF, KANENO R & RALL VLM. 2014. Prevalence and phenotypic characterization of Enterococcus spp. isolated from food in Brazil. Braz J Microbiol 45: 111-115., Kim et al. (2018)KIM YJ, PARK JH & SEO KH. 2018. Comparison of the loads and antibiotic-resistance proﬁles of Enterococcus species from conventional and organic chicken carcasses in South Korea. Poult Sci 97: 271-278. and Tyson et al. (2017)TYSON GH, NYIRABAHIZI E, CRAREY E, KABERA C, LAM C, RICE-TRUJILLO C, MCDERMOTT PF & TATE H. 2017. Prevalence and Antimicrobial Resistance of Enterococci Isolated from Retail Meats in the United States, 2002 to 2014. Appl Environ Microbiol 84: e01902-17., who also noted these species were predominant in meats and cheese samples. The higher occurrence of E. faecalis in raw chicken meat, can be justified by the manipulation and elevated susceptibility of these products to contamination with feces from slaughtered animals during the processing (Hölzel et al. 2018HÖLZEL CS, TETENS JL & SCHWAIGER K. 2018. Unraveling the role of vegetables in spreading antimicrobial-resistant bacteria: a need for quantitative risk assessment. Foodborne Pathog Dis 15: 671-688.). The presence of E. faecalis, E. faecium, E. durans, and E. hirae in cheese samples may be related to the raw material used in cheese making process. Different enterococci species were found in artisanal cheeses made from raw or pasteurized milk from goats, sheep, buffaloes, and cows (Gelsomino et al. 2002GELSOMINO R, VANCANNEYT M, COGAN TM, CONDON S & SWINGS J. 2002. Source of enterococci in a farmhouse raw-milk cheese. Appl Environ Microbiol 68: 3560-3565.). In cheeses, enterococci represent a major part of the microbiota and are the predominant microorganisms in the ripened cheeses (Lebreton et al. 2014LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59.).

Upon comparing the enterococci diversity observed in this study with the enterococcal collection isolated in 2007, some differences were observed. For example, in this study E. casseliflavus and E. hirae was detected in vegetables, while Riboldi et al. (2009)RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128. and Frazzon et al. (2009)FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370. isolated only E. faecalis and E. faecium from vegetables. This difference can be related to numerous sources beyond the soil sources, fertilization and irrigation used in vegetable production (e.g., handling and storage) (Regitano & Leal 2010REGITANO JB & LEAL RMP. 2010. Comportamento e impacto ambiental de antibióticos usados na produção animal brasileira. Rev Bras Ciênc Solo 34: 601-616.). On the other hand, no differences in the proportion of enterococci isolates from foods of animal origin (e.g., raw meat and colonial and soft cheeses) were observed upon isolates from 2007 and 2017. In both studies, E. faecalis was the most frequently isolated species.

Antimicrobial susceptibility patterns of enterococci isolated from food samples

Among the 310 strains isolated in this study, 33 (10.6%) were susceptible to all antimicrobials tested, while 277 (89.4%) showed resistance to at least one antimicrobial (Table IV). Resistance to rifampicin (54.8%) was the most commonly observed profile, followed by resistance to erythromycin (47.7%), tetracycline (31.3%), and ciprofloxacin (20%). A lower rate was found to streptomycin (14.8%), norfloxacin (12.6%), nitrofurantoin (9.3%), gentamicin (3.5%), chloramphenicol (2.3%), and ampicillin (0.6%). No resistance to vancomycin was observed. These findings are consistent with published data that also reported the presence of resistant enterococci in foods of animal and vegetable origin (McGowan et al. 2006MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982., Ben Said et al. 2015BEN SAID L, KLIBI N, DZIRI R, BORGO F, BOUDABOUS A, SLAMA KB & TORRES C. 2015. Prevalence, antimicrobial resistance and genetic lineages of Enterococcus spp. from vegetable food, soil and irrigation water in farm environments in Tunisia. J Sci Food Agric 96: 1627-1633., Ngbede et al. 2017NGBEDE EO, RAJI MA, KWANASHIE CN, KWAGA JKP, ADIKWU AA, MAURICE NA & ADAMU AM. 2017. Characterization of high-level ampicillin- and aminoglycoside-resistant enterococci isolated from non-hospital sources. J Med Microbiol 66: 1027-1032., Kim et al. 2018KIM YJ, PARK JH & SEO KH. 2018. Comparison of the loads and antibiotic-resistance proﬁles of Enterococcus species from conventional and organic chicken carcasses in South Korea. Poult Sci 97: 271-278.).

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Table IV
Antimicrobial resistance profiles among enterococci isolated from different type of food.

Enterococci isolated from vegetables showed elevated rates of resistance to rifampicin (125/202, 61.88%) and erythromycin (82/202, 40.6%) were detected. Moderate rates of resistance were observed for ciprofloxacin (38/202, 18%), and tetracycline (34/202, 16.83%). Moreover, low rates of resistance were detected for norfloxacin (29/202, 14.3%), nitrofurantoin (26/202, 12.8%), streptomycin (25/202, 12.3%), and chloramphenicol (6/202, 2.9%). Several studies conducted with vegetables have isolated antimicrobial resistant enterococci (McGowan et al. 2006MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982., Ben Said et al. 2015BEN SAID L, KLIBI N, DZIRI R, BORGO F, BOUDABOUS A, SLAMA KB & TORRES C. 2015. Prevalence, antimicrobial resistance and genetic lineages of Enterococcus spp. from vegetable food, soil and irrigation water in farm environments in Tunisia. J Sci Food Agric 96: 1627-1633., Kim et al. 2017KIM MC, CHA MH, RYU JG & WOO GJ. 2017. Characterization of vancomycin-resistant Enterococcus faecalis and Enterococcus faecium isolated from fresh produces and human fecal samples. Foodborne Pathog Dis 14: 195-201., Hölzel et al. 2018HÖLZEL CS, TETENS JL & SCHWAIGER K. 2018. Unraveling the role of vegetables in spreading antimicrobial-resistant bacteria: a need for quantitative risk assessment. Foodborne Pathog Dis 15: 671-688.). Ben Said et al. (2015)BEN SAID L, KLIBI N, DZIRI R, BORGO F, BOUDABOUS A, SLAMA KB & TORRES C. 2015. Prevalence, antimicrobial resistance and genetic lineages of Enterococcus spp. from vegetable food, soil and irrigation water in farm environments in Tunisia. J Sci Food Agric 96: 1627-1633. evaluated the antimicrobial resistance of enterococci isolated from vegetables sourced from farms and markets in Tunisia, and noted resistance for ciprofloxacin, erythromycin, tetracycline, chloramphenicol, and streptomycin. Resistant strains were also observed in vegetables from grocery stores in Athens, Georgia, USA from 2000 to 2001 (McGowan et al. 2006MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982.). Furthermore, Ngbede et al. (2017)NGBEDE EO, RAJI MA, KWANASHIE CN, KWAGA JKP, ADIKWU AA, MAURICE NA & ADAMU AM. 2017. Characterization of high-level ampicillin- and aminoglycoside-resistant enterococci isolated from non-hospital sources. J Med Microbiol 66: 1027-1032. detected ampicillin- and aminoglycosides-resistant E. faecium strains isolated from vegetables in Nigeria. The occurrence of erythromycin-resistant enterococci in vegetable samples observed in our study might be associated with the application of untreated irrigation water and natural fertilizers from animal manure (Regitano & Leal 2010REGITANO JB & LEAL RMP. 2010. Comportamento e impacto ambiental de antibióticos usados na produção animal brasileira. Rev Bras Ciênc Solo 34: 601-616.). Erythromycin is excreted as an active metabolite via the manure or urine of livestock and remains stable in the environments such as soil and water (Gothwal & Shashidhar 2014GOTHWAL R & SHASHIDHAR T. 2014. Antibiotic pollution in the environment: A Review. CLEAN - Soil, Air, Water 43: 479-489., Dizavandi et al. 2017DIZAVANDI ZR, ALIAKBAR A & SHEYKHAN M. 2017. A novel Pb-poly aminophenol glassy carbon electrode for determination of tetracycline by adsorptive differential pulse cathodic stripping voltammetry. Electrochim Acta 227: 345-356.). Biological fluids (e.g., urine and feces) contaminated with antimicrobials or antimicrobial-resistant strains are released into the environment, especially soil, water and wastewater. Kim et al. (2017)KIM MC, CHA MH, RYU JG & WOO GJ. 2017. Characterization of vancomycin-resistant Enterococcus faecalis and Enterococcus faecium isolated from fresh produces and human fecal samples. Foodborne Pathog Dis 14: 195-201. compared in Korea fecal samples with fresh vegetable samples in Korea and observed that the vegetables can be contaminated by human and animal fecal material via environmental sources.

Regarding enterococci isolated from foods of animal origin in the present study, high rates of resistance to erythromycin (66/108, 61.11%), tetracycline (63/108, 58.3%), and rifampicin (45/108, 41.66%) were observed, while moderate rates of resistance were observed for ciprofloxacin (24/108, 22.2%), and streptomycin (21/108, 19.4%). Moreover, low rates of resistance were detected for gentamicin (10/108, 9.2%), and norfloxacin (10/108, 9.2%). Resistant strains have also been reported in animal food sources (McGowan et al. 2006, Lebreton et al. 2014LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59., Vaz Jr 2016VAZ JR S. 2016. Erratum to: Sorption behavior of the oxytetracycline antibiotic to two Brazilian soils. Chem Biol Technol Agric 3: 14.). McGowan et al. (2006)MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982. isolated bacitracin, lincomycin, tetracycline and streptomycin-resistant enterococci from meat samples in Athens, Georgia in 2000 and 2001. Notably, relatively high rates of resistance for erythromycin and tetracycline were observed in our study. These profiles might be related to antibiotics that are used to treat animal infections. Although tetracycline was banned as a growth promoter in Brazil in 1998, this antibiotic class continues to be widely used to treat Salmonella-related infections in poultry and represents one of the main classes of antibiotics marketed and applied to the Brazilian livestock (Vaz Jr 2016VAZ JR S. 2016. Erratum to: Sorption behavior of the oxytetracycline antibiotic to two Brazilian soils. Chem Biol Technol Agric 3: 14.). Erythromycin is also a narrow-spectrum antibiotic used by veterinarians to treat specific types of bacterial infections in animals (Dinos 2017DINOS GP. 2017. The macrolide antibiotic renaissance. Br J Pharmaco 174: 2967-2983.).

Enterococci antimicrobial profiles from the present study were compared to those of the enterococcal collection from 2007. The results showed a reduction in the prevalence of ampicillin, gentamicin, chloramphenicol, and vancomycin-resistant strains (Figure 1). Resistance to ampicillin decreased from 6.7% in 2007 to 0.6% in 2017, while gentamicin resistance decreased from 16.1% in 2007 to 3.5% in 2017, chloramphenicol resistance decreased from 23.65% in 2007 to 2.3% in 2017, and vancomycin resistance decreased from 5.4% in 2007 to 0.0% in 2017. These reductions in resistant enterococci observed in food samples over the 10-years study period might be associated with the control of the antimicrobial use under the RDC 20/11.

Figure 1
Distribution of resistant enterococci isolated from foods comparing pre-RDC 20/2011 (Riboldi et al. 2009RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128., Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370.) with post-RDC 20/2011 (our data). Antimicrobials: AMP: ampicillin, CIP: ciprofloxacin, CHL: chloramphenicol, ERY: erythromycin, GEN: gentamicin, NIT: nitrofurantoin, NOR: norfloxacin, TET: tetracycline, VAN: vancomycin, MDR: Multidrug resistance profile.

Resistance to erythromycin, tetracycline, ciprofloxacin, norfloxacin, and nitrofurantoin remained the same throughout the evaluated period. This result might be explained by the fact that these drugs being widely used in veterinary medicine. Veterinary drugs are primarily used in avian production and dairy cattle management mainly for therapy and disease prophylaxis of diseases (Novaes et al. 2017NOVAES SF, SCHREINER LL, SILVA IP & FRANCO RM. 2017. Residues of veterinary drugs in milk in Brazil. Cienc Rural 47: e20170215.). Additionally, in Brazil there is not a controlling antimicrobial used in veterinary medicine in Brazil.

In the present study, MDR strains were identified in foods of vegetable and animal origin. A total of 101 enterococci (33.1%) strains had an MDR profile (Table II). High rates of MDR were observed in strains isolated from cabbage (20/33, 66.66%), colonial cheese (22/36, 61.11%), and chicken meat (21/36, 58.33%). Among these strains, an MDR profile was more frequently in E. faecalis (71.3%), followed by E. casseliflavus (22.8%), E. hirae (1.9%), E. durans (1.9%), E. faecium (0.9%), and Enterococcus sp. (0.9%). MDR enterococci have previously been previously isolated from food (McGrowan et al. 2007, Frazzon et al. 2009FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370., Soares-Santos et al. 2015SOARES-SANTOS V, BARRETO AS & SEMEDO-LEMSADDEK T. 2015. Characterization of Enterococci from food and food-related settings. J Food Prot 78: 1320-1326., Kim et al. 2017KIM MC, CHA MH, RYU JG & WOO GJ. 2017. Characterization of vancomycin-resistant Enterococcus faecalis and Enterococcus faecium isolated from fresh produces and human fecal samples. Foodborne Pathog Dis 14: 195-201.). Multidrug resistance decreased from 57.1% of the isolates in 2007 to 33.1% in 2017 (Figure 1). However, it is important to highlight that the emergence of MDR appears to be driven by the ubiquitous nature of Enterococcus spp., the plasticity of their genomes, and the widespread use of antibiotics (Prieto et al. 2016PRIETO AMG, VAN SCHAIK W, ROGERS MRC, COQUE TM, BAQUERO F, CORANDER J & WILLEMS RJL. 2016. Global emergence and dissemination of enterococci as nosocomial pathogens: attack of the clones? Front Microbiol 7: 788.).

Frequency of antibiotic resistance genes

Of the 95 tetracycline-resistant strains, 76 (78.3%) were positive for the tet(M) gene and 23 (23.7%) were positive for the tet(L) gene. Among the 123 erythromycin-resistant strains, 63 (42.6%) were positive for the erm(B) gene and 7 (4.7%) were positive for the msrC gene. Moreover, the aac(6’)-aph(2’) gene was detected in 10 (90.9%) gentamicin-resistant strains isolated from raw chicken meat. Similar results have previously been observed by Frazzon et al. (2009)FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370. among tetracycline-resistant strains isolated from beetroot, raw chicken meat, potato, cassava, and colonial and soft cheeses in southern Brazil in 2009. Ben Said et al. (2015)BEN SAID L, KLIBI N, DZIRI R, BORGO F, BOUDABOUS A, SLAMA KB & TORRES C. 2015. Prevalence, antimicrobial resistance and genetic lineages of Enterococcus spp. from vegetable food, soil and irrigation water in farm environments in Tunisia. J Sci Food Agric 96: 1627-1633. also discovered tet(M) and/or tet(L), erm(B) and aac(6’)-aph(2’) genes in enterococci isolates from vegetables, soil, and irrigation water in Tunisia. According to the same authors, the potential presence of other antibiotic resistance genes cannot be ignored.

Cooking is an effective step that can be used to kill most harmful bacteria. Currently, there is a growing demand for ready-to-eat or ready-to-use products. Minimally processed fruits and vegetables are fresh fruits and vegetables processed to preserve their nutritional value and obtain their maximum benefits (Panja 2017PANJA P. 2017. Minimal Processing of Fruits and Vegetables. In: Deb P, Bhowmick N, Munsi PS & Ghosh SK (Eds), Innovative Horticulture: Concepts for Sustainable Development, Recent trends: New Delhi Publishers, p. 217-226.). In the present study, we primarily focused on analyzing mainly ready-to-eat products since they are usually eaten raw, without washing or other decontamination procedures. Recently, Cruz et al. (2019)CRUZ MRG, LEITE YJBS, MARQUES JL, PAVELQUESI SLS, OLIVEIRA LRA, SILVA ICR & ORSI DC. 2019. Microbiological quality of minimally processed vegetables commercialized in Brasilia, DF, Brazil. Food Sci Technol 39: 498-503. showed that minimally processed vegetables may contain pathogenic bacteria and therefore could represent a risk for consumers. Notably, the presence of antibiotic-resistant bacteria in this type of food could pose a risk to consumer. As reported by Hölzel et al. (2018)HÖLZEL CS, TETENS JL & SCHWAIGER K. 2018. Unraveling the role of vegetables in spreading antimicrobial-resistant bacteria: a need for quantitative risk assessment. Foodborne Pathog Dis 15: 671-688., three additional situations can be connected to antimicrobial-resistant microorganisms in vegetables: (1) foodborne infectious disease due to obligate or opportunistic pathogens, (2) foodborne microbial intoxication, and (3) foodborne colonization, which could be followed by opportunistic disease after a considerable period of time. Studies have noted the transfer of antibiotic resistance genes between species, which are often passed to humans (Leverstein-van Hall et al. 2011LEVERSTEIN-VAN HALL MA, DIERIKX CM, COHEN STUART J, VOETS GM, VAN DEN MUNCKHOF MP, VAN ESSEN-ZANDBERGEN A, PLATTEEL T & FLUI AC. 2011. Dutch patients, retail chicken meat and poultry share the same ESBL genes, plasmids and strains. Clin Microbiol Infect 17: 873-880., Nawaz et al. 2011NAWAZ M, WANG J, ZHOU A, CHAOFENG M, WU X, MOORE JE, MILLAR BC & XU J. 2011. Characterization and transfer of antibiotic resistance in lactic acid bacteria from fermented food products. Curr Microbiol 62: 1081-1089.).

CONCLUSION

In the present study, E. casseliflavus was predominant in vegetables, while E. faecalis was dominant in food sources of animal origin. Upon comparing the antimicrobial resistance profiles of enterococci recovered from food samples between 2007 and 2017, a reduction in the prevalence of resistant isolates associated with some antimicrobials used to treat human infections was observed. These results suggest that RDC 20/11 had a positive outcome in controlling the spread of antimicrobial resistance in the environment. Thus, the present study highlights that there is scope for improvement in food security through advancing food safety knowledge and practices. Therefore, it is recommended that the population should be educated on food safety and safer food practices. Ultimately, effective precautionary measures must be taken to prevent the transmission of enterococci through food. This study provides baseline data to measure future changes in the prevalence of resistant enterococci in Brazil.

ACKNOWLEDGMENTS

This work was supported by the Conselho Nacional de Desenvolvimento Científico e Tecnológico - Brazil, CNPq #401714/2016-0 and #302574/2017-4 and Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES).

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GRASSOTTI TT, ZVOBODA DA, COSTA LFX, ARAÚJO AJG, PEREIRA RI, SOARES RO, WAGNER PGC, FRAZZON J & FRAZZON APG. 2018. Antimicrobial resistance profiles in Enterococcus spp. isolates from fecal samples of wild and captive black capuchin monkeys (Sapajus nigritus) in South Brazil. Front Microbiol 9: 2366.
HANCHI HM, MOTTAWEA W, KHALED SE & HAMMAMI R. 2018. The Genus Enterococcus: Between Probiotic Potential and Safety Concerns-An Update. Front Microbiol 9: 1791.
HÖLZEL CS, TETENS JL & SCHWAIGER K. 2018. Unraveling the role of vegetables in spreading antimicrobial-resistant bacteria: a need for quantitative risk assessment. Foodborne Pathog Dis 15: 671-688.
JIA W, LI G & WANG W. 2014. Prevalence and antimicrobial resistance of Enterococcus species: a hospital-based study in China. Int J Environ Res Public Health 11: 3424-3442.
KE D, PICARD FJ, MARTINEAU F, MENARD C, ROY PH, OUELLTTE M & BERGERON MG. 1999. Development of a PCR assay for rapid detection of Enterococci. J Clin Microbiol 37: 3497-3503.
KIM MC, CHA MH, RYU JG & WOO GJ. 2017. Characterization of vancomycin-resistant Enterococcus faecalis and Enterococcus faecium isolated from fresh produces and human fecal samples. Foodborne Pathog Dis 14: 195-201.
KIM NH, KIM HW, PARK SM, SEO GH, CHO TJ, YU HR, KIM SH, HWANG JH, CHOI C & RHEE MS. 2020. Virulence patterns and prevalence of seven Enterococcus species isolated from meats and leafy vegetables in South Korea. Food Control 108: 106867.
KIM YJ, PARK JH & SEO KH. 2018. Comparison of the loads and antibiotic-resistance proﬁles of Enterococcus species from conventional and organic chicken carcasses in South Korea. Poult Sci 97: 271-278.
KRISTIANSSON E, FICK J, JANZON A, GRABIC R, RUTGERSSON C, WEIJDEGARD B, SODERSTROM H & LARSSON DG. 2011. Pyrosequencing of antibiotic-contaminated river sediments reveals high levels of resistance and gene transfer elements. PLoS ONE 6: e17038.
KULIK EM, THURNHUEER T, KARYGIANNI L, WALTER C, SCULEAN A & EICK S. 2019. Antibiotic susceptibility patterns of Aggregatibacter actinomycetemcomitans and Porphyromonas gingivalis strains from different decades. Antibiotics 8: 253.
LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59.
LEVERSTEIN-VAN HALL MA, DIERIKX CM, COHEN STUART J, VOETS GM, VAN DEN MUNCKHOF MP, VAN ESSEN-ZANDBERGEN A, PLATTEEL T & FLUI AC. 2011. Dutch patients, retail chicken meat and poultry share the same ESBL genes, plasmids and strains. Clin Microbiol Infect 17: 873-880.
MARATHE NP, REGINA VR, WALUJKAR SA, CHARAN SS, MOORE ERB, LARSSON DGJ & SHOUCHE YS. 2013. A treatment plant receiving waste water from multiple bulk drug manufacturers is a reservoir for highly multi-drug resistant integron-bearing bacteria. PLoS ONE 8: e77310.
MASSOT M ET AL. 2016. Phylogenetic, virulence and antibiotic resistance characteristics of commensal strain populations of Escherichia coli from community subjects in the Paris area in 2010 and evolution over 30 years. Microbiol 162: 642-650.
MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982.
MEDEIROS AW, AMORIM DB, TAVARES M, MOURA TM, FRANCO AC, D’AZEVEDO PA, FRAZZON J & FRAZZON APG. 2016. Enterococcus species diversity in fecal samples of wild marine species as determined by real-time PCR. Can J Microbiol 63: 129-136.
NAWAZ M, WANG J, ZHOU A, CHAOFENG M, WU X, MOORE JE, MILLAR BC & XU J. 2011. Characterization and transfer of antibiotic resistance in lactic acid bacteria from fermented food products. Curr Microbiol 62: 1081-1089.
NGBEDE EO, RAJI MA, KWANASHIE CN, KWAGA JKP, ADIKWU AA, MAURICE NA & ADAMU AM. 2017. Characterization of high-level ampicillin- and aminoglycoside-resistant enterococci isolated from non-hospital sources. J Med Microbiol 66: 1027-1032.
NOVAES SF, SCHREINER LL, SILVA IP & FRANCO RM. 2017. Residues of veterinary drugs in milk in Brazil. Cienc Rural 47: e20170215.
PANJA P. 2017. Minimal Processing of Fruits and Vegetables. In: Deb P, Bhowmick N, Munsi PS & Ghosh SK (Eds), Innovative Horticulture: Concepts for Sustainable Development, Recent trends: New Delhi Publishers, p. 217-226.
PRICE LB ET AL. 2012. Staphylococcus aureus CC398: host adaptation and emergence of methicillin resistance in livestock. MBio 3: e00305-e00311.
PRIETO AMG, VAN SCHAIK W, ROGERS MRC, COQUE TM, BAQUERO F, CORANDER J & WILLEMS RJL. 2016. Global emergence and dissemination of enterococci as nosocomial pathogens: attack of the clones? Front Microbiol 7: 788.
RASHEED MU, THAJUDDIN N, AHAMED P, TEKLEMARIAM Z & JAMIL K. 2014. Antimicrobial drug resistance in strains of Escherichia coli isolated from food sources. Rev Inst Med Trop São Paulo 56: 341-346.
REGITANO JB & LEAL RMP. 2010. Comportamento e impacto ambiental de antibióticos usados na produção animal brasileira. Rev Bras Ciênc Solo 34: 601-616.
RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128.
ROCA I ET AL. 2015. The global threat of antimicrobial resistance: science for intervention. New Microbes New Infect 6: 22-29.
SAUGET M, VALOT B, BERTRAND X & HOCQUET D. 2017. Can MALDI-TOF mass spectrometry reasonably type bacteria? Trends Microbiol 25: 447-455.
SCHWARZ S, SILLEY P, SIMJEE S, WOODFORD N, VAN DUIJKEREN E, JOHNSON AP & GAASTRA W. 2010. Assessing the antimicrobial susceptibility of bacteria obtained from animals. Vet Microbiol 141: 1-4.
SEDGLEY CM, NAGEL AC, SHELBURNE CE, CLEWELL DB, APPELBE O & MOLANDER A. 2005. Quantitative real-time PCR detection of oral Enterococcus faecalis in humans. Arch Oral Biol 50: 575-583.
SOARES-SANTOS V, BARRETO AS & SEMEDO-LEMSADDEK T. 2015. Characterization of Enterococci from food and food-related settings. J Food Prot 78: 1320-1326.
SUTCLIFFE J, GREBE T, TAIT-KAMRADT A & WONDRACK L. 1996. Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Chemother 40: 2562-2566.
TYSON GH, NYIRABAHIZI E, CRAREY E, KABERA C, LAM C, RICE-TRUJILLO C, MCDERMOTT PF & TATE H. 2017. Prevalence and Antimicrobial Resistance of Enterococci Isolated from Retail Meats in the United States, 2002 to 2014. Appl Environ Microbiol 84: e01902-17.
VAZ JR S. 2016. Erratum to: Sorption behavior of the oxytetracycline antibiotic to two Brazilian soils. Chem Biol Technol Agric 3: 14.
VENTOLA CL. 2015. The antibiotic resistance crisis: part 1: causes and threats. P&T 40: 277-283.
VERRAES C ET AL. 2013. Antimicrobial resistance in the food chain: a review. Int J Environ Res Public Health 10: 2643-2669.
WERNER G, HILDEBRANDT B & WITTE W. 2001. The newly described msrC gene is not equally distributed among all isolates of Enterococcus faecium. Antimicrob Agents Chemother 45: 3672-3673.
WORLD HEALTH ORGANIZATION (WHO). 2013. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland.
WORLD HEALTH ORGANIZATION (WHO). 2020. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland. https://www.who.int/news-room/fact-sheets/detail/antibiotic-resistance
» https://www.who.int/news-room/fact-sheets/detail/antibiotic-resistance

Publication Dates

Publication in this collection
11 Mar 2022
Date of issue
2022

History

Received
11 Nov 2020
Accepted
15 Mar 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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[2] ALONSO-HERNANDO A, PRIETO M, GARCÍA-FERNÁNDEZ C, ALONSO-CALLEJA C & CAPITA R. 2012. Increase over time in the prevalence of multiple antibiotic resistance among isolates of Listeria monocytogenes from poultry in Spain. Food Control 23: 37-41.

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[16] FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370.

[17] GELSOMINO R, VANCANNEYT M, COGAN TM, CONDON S & SWINGS J. 2002. Source of enterococci in a farmhouse raw-milk cheese. Appl Environ Microbiol 68: 3560-3565.

[18] GIRAFFA G. 2002. Enterococci from foods. FEMS Microbiol Rev 26: 163-171.

[19] GOMES BC, ESTEVES CT, PALAZZO ICV, DARINI ALC, FELIS GE, SECHI LA, FRANCO BDGM & MARTINIS ECP. 2008. Prevalence and characterization of Enterococcus spp. isolated from Brazilian foods. Food Microbiol 25: 668-675.

[20] GOTHWAL R & SHASHIDHAR T. 2014. Antibiotic pollution in the environment: A Review. CLEAN - Soil, Air, Water 43: 479-489.

[21] GRASSOTTI TT, ZVOBODA DA, COSTA LFX, ARAÚJO AJG, PEREIRA RI, SOARES RO, WAGNER PGC, FRAZZON J & FRAZZON APG. 2018. Antimicrobial resistance profiles in Enterococcus spp. isolates from fecal samples of wild and captive black capuchin monkeys (Sapajus nigritus) in South Brazil. Front Microbiol 9: 2366.

[22] HANCHI HM, MOTTAWEA W, KHALED SE & HAMMAMI R. 2018. The Genus Enterococcus: Between Probiotic Potential and Safety Concerns-An Update. Front Microbiol 9: 1791.

[23] HÖLZEL CS, TETENS JL & SCHWAIGER K. 2018. Unraveling the role of vegetables in spreading antimicrobial-resistant bacteria: a need for quantitative risk assessment. Foodborne Pathog Dis 15: 671-688.

[24] JIA W, LI G & WANG W. 2014. Prevalence and antimicrobial resistance of Enterococcus species: a hospital-based study in China. Int J Environ Res Public Health 11: 3424-3442.

[25] KE D, PICARD FJ, MARTINEAU F, MENARD C, ROY PH, OUELLTTE M & BERGERON MG. 1999. Development of a PCR assay for rapid detection of Enterococci. J Clin Microbiol 37: 3497-3503.

[26] KIM MC, CHA MH, RYU JG & WOO GJ. 2017. Characterization of vancomycin-resistant Enterococcus faecalis and Enterococcus faecium isolated from fresh produces and human fecal samples. Foodborne Pathog Dis 14: 195-201.

[27] KIM NH, KIM HW, PARK SM, SEO GH, CHO TJ, YU HR, KIM SH, HWANG JH, CHOI C & RHEE MS. 2020. Virulence patterns and prevalence of seven Enterococcus species isolated from meats and leafy vegetables in South Korea. Food Control 108: 106867.

[28] KIM YJ, PARK JH & SEO KH. 2018. Comparison of the loads and antibiotic-resistance proﬁles of Enterococcus species from conventional and organic chicken carcasses in South Korea. Poult Sci 97: 271-278.

[29] KRISTIANSSON E, FICK J, JANZON A, GRABIC R, RUTGERSSON C, WEIJDEGARD B, SODERSTROM H & LARSSON DG. 2011. Pyrosequencing of antibiotic-contaminated river sediments reveals high levels of resistance and gene transfer elements. PLoS ONE 6: e17038.

[30] KULIK EM, THURNHUEER T, KARYGIANNI L, WALTER C, SCULEAN A & EICK S. 2019. Antibiotic susceptibility patterns of Aggregatibacter actinomycetemcomitans and Porphyromonas gingivalis strains from different decades. Antibiotics 8: 253.

[31] LEBRETON F, WILLEMS RJL & GILMORE MS. 2014. Enterococcus diversity, origins in nature, and gut colonization. In: In: Gilmore MS, Clewell DB, Ike Y & Shankar N (Eds), Enterococci from commensals to leading causes of drug resistance infection: Eye and Ear Infirmary, Boston, p. 1-59.

[32] LEVERSTEIN-VAN HALL MA, DIERIKX CM, COHEN STUART J, VOETS GM, VAN DEN MUNCKHOF MP, VAN ESSEN-ZANDBERGEN A, PLATTEEL T & FLUI AC. 2011. Dutch patients, retail chicken meat and poultry share the same ESBL genes, plasmids and strains. Clin Microbiol Infect 17: 873-880.

[33] MARATHE NP, REGINA VR, WALUJKAR SA, CHARAN SS, MOORE ERB, LARSSON DGJ & SHOUCHE YS. 2013. A treatment plant receiving waste water from multiple bulk drug manufacturers is a reservoir for highly multi-drug resistant integron-bearing bacteria. PLoS ONE 8: e77310.

[34] MASSOT M ET AL. 2016. Phylogenetic, virulence and antibiotic resistance characteristics of commensal strain populations of Escherichia coli from community subjects in the Paris area in 2010 and evolution over 30 years. Microbiol 162: 642-650.

[35] MCGOWAN LL, JACKSON CR, BARRETT JB, HIOTT LM & FEDORKA-CRAY PJ. 2006. Prevalence and antimicrobial resistance of enterococci isolated from retail fruits, vegetables and meats. J Food Prot 69: 2976-2982.

[36] MEDEIROS AW, AMORIM DB, TAVARES M, MOURA TM, FRANCO AC, D’AZEVEDO PA, FRAZZON J & FRAZZON APG. 2016. Enterococcus species diversity in fecal samples of wild marine species as determined by real-time PCR. Can J Microbiol 63: 129-136.

[37] NAWAZ M, WANG J, ZHOU A, CHAOFENG M, WU X, MOORE JE, MILLAR BC & XU J. 2011. Characterization and transfer of antibiotic resistance in lactic acid bacteria from fermented food products. Curr Microbiol 62: 1081-1089.

[38] NGBEDE EO, RAJI MA, KWANASHIE CN, KWAGA JKP, ADIKWU AA, MAURICE NA & ADAMU AM. 2017. Characterization of high-level ampicillin- and aminoglycoside-resistant enterococci isolated from non-hospital sources. J Med Microbiol 66: 1027-1032.

[39] NOVAES SF, SCHREINER LL, SILVA IP & FRANCO RM. 2017. Residues of veterinary drugs in milk in Brazil. Cienc Rural 47: e20170215.

[40] PANJA P. 2017. Minimal Processing of Fruits and Vegetables. In: Deb P, Bhowmick N, Munsi PS & Ghosh SK (Eds), Innovative Horticulture: Concepts for Sustainable Development, Recent trends: New Delhi Publishers, p. 217-226.

[41] PRICE LB ET AL. 2012. Staphylococcus aureus CC398: host adaptation and emergence of methicillin resistance in livestock. MBio 3: e00305-e00311.

[42] PRIETO AMG, VAN SCHAIK W, ROGERS MRC, COQUE TM, BAQUERO F, CORANDER J & WILLEMS RJL. 2016. Global emergence and dissemination of enterococci as nosocomial pathogens: attack of the clones? Front Microbiol 7: 788.

[43] RASHEED MU, THAJUDDIN N, AHAMED P, TEKLEMARIAM Z & JAMIL K. 2014. Antimicrobial drug resistance in strains of Escherichia coli isolated from food sources. Rev Inst Med Trop São Paulo 56: 341-346.

[44] REGITANO JB & LEAL RMP. 2010. Comportamento e impacto ambiental de antibióticos usados na produção animal brasileira. Rev Bras Ciênc Solo 34: 601-616.

[45] RIBOLDI GP, FRAZZON J, D’AZEVEDO PA & FRAZZON APG. 2009. Antimicrobial resistance profile of Enterococcus spp. isolated from food in Southern Brazil. Braz J Microbiol 40: 125-128.

[46] ROCA I ET AL. 2015. The global threat of antimicrobial resistance: science for intervention. New Microbes New Infect 6: 22-29.

[47] SAUGET M, VALOT B, BERTRAND X & HOCQUET D. 2017. Can MALDI-TOF mass spectrometry reasonably type bacteria? Trends Microbiol 25: 447-455.

[48] SCHWARZ S, SILLEY P, SIMJEE S, WOODFORD N, VAN DUIJKEREN E, JOHNSON AP & GAASTRA W. 2010. Assessing the antimicrobial susceptibility of bacteria obtained from animals. Vet Microbiol 141: 1-4.

[49] SEDGLEY CM, NAGEL AC, SHELBURNE CE, CLEWELL DB, APPELBE O & MOLANDER A. 2005. Quantitative real-time PCR detection of oral Enterococcus faecalis in humans. Arch Oral Biol 50: 575-583.

[50] SOARES-SANTOS V, BARRETO AS & SEMEDO-LEMSADDEK T. 2015. Characterization of Enterococci from food and food-related settings. J Food Prot 78: 1320-1326.

[51] SUTCLIFFE J, GREBE T, TAIT-KAMRADT A & WONDRACK L. 1996. Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Chemother 40: 2562-2566.

[52] TYSON GH, NYIRABAHIZI E, CRAREY E, KABERA C, LAM C, RICE-TRUJILLO C, MCDERMOTT PF & TATE H. 2017. Prevalence and Antimicrobial Resistance of Enterococci Isolated from Retail Meats in the United States, 2002 to 2014. Appl Environ Microbiol 84: e01902-17.

[53] VAZ JR S. 2016. Erratum to: Sorption behavior of the oxytetracycline antibiotic to two Brazilian soils. Chem Biol Technol Agric 3: 14.

[54] VENTOLA CL. 2015. The antibiotic resistance crisis: part 1: causes and threats. P&T 40: 277-283.

[55] VERRAES C ET AL. 2013. Antimicrobial resistance in the food chain: a review. Int J Environ Res Public Health 10: 2643-2669.

[56] WERNER G, HILDEBRANDT B & WITTE W. 2001. The newly described msrC gene is not equally distributed among all isolates of Enterococcus faecium. Antimicrob Agents Chemother 45: 3672-3673.

[57] WORLD HEALTH ORGANIZATION (WHO). 2013. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland.

[58] WORLD HEALTH ORGANIZATION (WHO). 2020. Integrated surveillance of antimicrobial resistance: guidance from a WHO Advisory Group. World Health Organization, Geneva, Switzerland. https://www.who.int/news-room/fact-sheets/detail/antibiotic-resistance
» https://www.who.int/news-room/fact-sheets/detail/antibiotic-resistance

		Nucleotide sequence (5’-3’)	Size¹ (bp)	AT²(°C)	References
Genus
		TACTGACAAACCATTCATGATG	112	55	Ke et al. (1999)KE D, PICARD FJ, MARTINEAU F, MENARD C, ROY PH, OUELLTTE M & BERGERON MG. 1999. Development of a PCR assay for rapid detection of Enterococci. J Clin Microbiol 37: 3497-3503.
		AACTTCGTCACCAACGCGAAC	112	55
Species
	E. casseliflavus	TAGGATGTTACGTCTGCGTG	139	58	Medeiros et al. (2016)MEDEIROS AW, AMORIM DB, TAVARES M, MOURA TM, FRANCO AC, D’AZEVEDO PA, FRAZZON J & FRAZZON APG. 2016. Enterococcus species diversity in fecal samples of wild marine species as determined by real-time PCR. Can J Microbiol 63: 129-136.
	E. casseliflavus	TTGTTGGTTTGGGCTTTTCCCG	139	58
	E. faecalis	CCGAGTGCTTGCACTCAATTGG	136	66	Sedgley et al. (2005)SEDGLEY CM, NAGEL AC, SHELBURNE CE, CLEWELL DB, APPELBE O & MOLANDER A. 2005. Quantitative real-time PCR detection of oral Enterococcus faecalis in humans. Arch Oral Biol 50: 575-583.
	E. faecalis	CTCTTATGCCATGCGGCATAAAC	136	66
	E. faecium	TTGAGGCAGACCAGATTGACG	172	62	Medeiros et al. (2016)MEDEIROS AW, AMORIM DB, TAVARES M, MOURA TM, FRANCO AC, D’AZEVEDO PA, FRAZZON J & FRAZZON APG. 2016. Enterococcus species diversity in fecal samples of wild marine species as determined by real-time PCR. Can J Microbiol 63: 129-136.
	E. faecium	CGGAAGTGATGCTTCCTACTG	172	62
	E. hirae	TTATGTCCCWGTWTTGAAAAATCAA	94	62	Medeiros et al. (2016)MEDEIROS AW, AMORIM DB, TAVARES M, MOURA TM, FRANCO AC, D’AZEVEDO PA, FRAZZON J & FRAZZON APG. 2016. Enterococcus species diversity in fecal samples of wild marine species as determined by real-time PCR. Can J Microbiol 63: 129-136.
	E. hirae	TATTGATAAGCTAATGCAAGCGC	94	62

Resistance	gene	Nucleotide sequence (5’-3’)	Size¹ (bp)	AT²(°C)	References
Erythromycin	erm(A)	TCTAAAAAGCATGTAAAAGAA	420	52	Sutcliffe et al. (1996)SUTCLIFFE J, GREBE T, TAIT-KAMRADT A & WONDRACK L. 1996. Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Chemother 40: 2562-2566.
		CTTCGATAGTTTATTAATATTAGT
	erm(B)	GAAAAGGTACTCAACCAAATA	547	52	Sutcliffe et al. (1996)SUTCLIFFE J, GREBE T, TAIT-KAMRADT A & WONDRACK L. 1996. Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Chemother 40: 2562-2566.
	erm(B)	AGTAACGGTACTTAAATTGTTTAC	547	52
	erm(C)	TCAAAACATAATATAGATAAA	837	52	Sutcliffe et al. (1996)SUTCLIFFE J, GREBE T, TAIT-KAMRADT A & WONDRACK L. 1996. Detection of erythromycin-resistant determinants by PCR. Antimicrob Agents Chemother 40: 2562-2566.
	erm(C)	GCTAATATTGTTTAAATCGTCAAT	837	52
	msrC	AAGGAATCCTTCTCTCTCCG	343	52	Werner et al. (2001)WERNER G, HILDEBRANDT B & WITTE W. 2001. The newly described msrC gene is not equally distributed among all isolates of Enterococcus faecium. Antimicrob Agents Chemother 45: 3672-3673.
	msrC	GTAAACAAAATCGTTCCCG	343	52
Gentamycin	aac(6’)-aph(2’)	CACTATCATAACCACTACCG	220	56	Jia et al. (2014)JIA W, LI G & WANG W. 2014. Prevalence and antimicrobial resistance of Enterococcus species: a hospital-based study in China. Int J Environ Res Public Health 11: 3424-3442.
		CCAAGAGCAATAAGGGCATA
Tetracycline	tet(L)	ACTCGTAATGGTGTAGTTGC	625	58	Frazzon et al. (2009)FRAZZON APG, GAMA BA, HERMES V, BIERHALS CG, PEREIRA RI, GUEDES AG, D’AZEVEDO PA & FRAZZON J. 2009. Prevalence of antimicrobial resistance and molecular characterization of tetracycline resistance mediated by tet(M) and tet(L) genes in Enterococcus spp. isolated from food in Southern Brazil. World J Microbiol Biotechnol 26: 365-370.
		TGTAACTCCGATGTTTAACACG
	tet(M)	GTTAAATAGTGTTCTTGGAG	657	52	Aarestrup et al. (2000)AARESTRUP FM, AGERSO Y, GERNER-SMIDT P, MADSEN M & JENSEN LB. 2000. Comparison of antimicrobial resistance phenotypes and resistance genes in Enterococcus faecalis and Enterococcus faecium from humans in the community, broilers, and pigs in Denmark. Diagn Microbiol Infect Dis 37: 127-137.
	tet(M)	CTAAGATATGGCTCTAACAA	657	52
	tet(S)	TGGAACGCCAGAGAGGTATT	720	58	Aarestrup et al. (2000)AARESTRUP FM, AGERSO Y, GERNER-SMIDT P, MADSEN M & JENSEN LB. 2000. Comparison of antimicrobial resistance phenotypes and resistance genes in Enterococcus faecalis and Enterococcus faecium from humans in the community, broilers, and pigs in Denmark. Diagn Microbiol Infect Dis 37: 127-137.
	tet(S)	ACATAGACAAGCCGTTGACC	720	58

Source	Food samples (n)	Number (%) of species isolated
Source	Food samples (n)	E. casseliflavus	E. durans	E. faecalis	E. faecium	E. hirae	Enterococcus sp.
Vegetables	Sweet potato (35)	21 (6.8) ^c	0 ^a	12 (3.9) ^a	1 (0.3) ^a	0 ^a	2 (0.65) ^a
	Potato (36)	19 (6.1) ^c	0 ^a	17 (5.5) ^b	0 ^a	0 ^a	0 ^a
	Beetroot (24)	24 (7.7) ^c	0 ^a	0 ^a	0 ^a	0 ^a	0 ^a
	Carrot (3)	0 ^a	0 ^a	3 (1.0) ^b	0 ^a	0 ^a	0 ^a
	Cabbage (33)	5 (1.6) ^a	0 ^a	26 (8.4) ^c	1 (0.3) ^a	1 (0.3) ^b	0 ^a
	Parsley (34)	22 (7.1) ^c	0 ^a	6 (1.9) ^a	0 ^a	4 (1.3) ^b	2 (0.65) ^a
	Cassava (36)	12 (3.9) ^b	0 ^a	24 (7.7) ^b	0 ^a	0 ^a	0 ^a
	Sub-total (202)	103 (50.99)	0	88 (43.56)	2 (0.99)	5 (2.47)	4 (1.98)
Animal	Raw chicken meat (36)	0 ^a	0 ^a	36 (11.6) ^c	0 ^a	0 ^a	0 ^a
	Colonial cheese (36)	0 ^a	0 ^a	36 (11.6) ^c	0 ^a	0 ^a	0 ^a
	Soft cheese (36)	0 ^a	3 (1.0) ^a	17 (5.5) ^b	4 (1.3) ^a	12 (3.9) ^c	0 ^a
	Sub-total (108)	0	3 (2.77)	89 (82.4)	4 (3.7)	12 (11.11)	0
	Total (310)	103 (33.2)	3 (1.0)	177 (57.1)	6 (1.9)	17 (5.5)	4 (1.3)

Food samples	Species (n)	Number of the resistant strains to*
Food samples	Species (n)	AMP	CIP	CHL	ERY	STR	GEN	NIT	NOR	RIF	TET	MDR^**
Vegetables
Sweet potato	E. casseliflavus (21)	-	1 ^a	-	5 ^a	-	-	7 ^b	7 ^a	18 ^c	1 ^a	6
	E. faecalis (12)	-	-	-	-	-	-	3 ^b	-	12 ^c	-	-
	E. faecium (1)	-	-	-	-	-	-	-	-	1 ^c	-	-
	Enterococcus sp. (2)	-	-	-	-	-	-	1 ^b	1 ^a	1 ^c	-	1
Potato	E. casseliflavus (19)	-	-	-	1 ^a	-	-	-	-	7 ^b	-	-
	E. faecalis (17)	-	-	-	-	-	-	-	-	17 ^b	-	-
Beetroot	E. casseliflavus (24)	-	4 ^b	1 ^a	11 ^b	5 ^a	-	-	-	23 ^c	1 ^a	3
Carrot	E. faecalis (3)	-	-	-	1^b	-	-	2 ^b	1 ^a	3 ^b	-	1
Cabbage	E. casseliflavus (5)	-	3 ^c	-	4 ^c	-	-	-	-	5 ^b	-	2
	E. faecalis (26)	-	15 ^c	4 ^b	19 ^c	13 ^b	-	-	7 ^a	8 ^b	12 ^b	17
	E. faecium (1)	-	1 ^c	-	1 ^c	1 ^b	-	-	-	-	1 ^b	1
	E. hirae (1)	-	-	-	1 ^c	-	-	-	-	1 ^b	-	-
Parsley	E. casseliflavus (22)	-	2 ^b	-	6 ^a	-	-	3 ^a	4 ^a	8 ^a	11 ^b	5
	E. faecalis (6)	-	3 ^b	-	1 ^a	-	-	3 ^a	3 ^a	6 ^a	-	4
	E. hirae (4)	-	-	-	-	-	-	-	-	-	-	-
	Enterococcus sp. (2)	-	-	-	-	-	-	-	-	-	2 ^b	-
Cassava	E. casseliflavus (12)	1 ^a	4 ^b	1 ^a	12 ^c	4 ^a	1^a	7 ^b	1 ^a	3 ^b	3 ^a	7
	E. faecalis (24)	-	5 ^b	-	20 ^c	2 ^a	-	-	5 ^a	12 ^b	3 ^a	5
	Sub-total (202)	1	38	6	82	25	1	26	29	125	34	52
Animals
Raw chicken meat	E. faecalis (36)	-	6 ^b	-	21 ^b	9 ^a	10 ^b	1 ^a	7 ^a	9 ^a	24 ^c	21
Colonial cheese	E. faecalis (36)	1 ^a	7 ^b	1 ^a	33 ^c	12 ^b	-	-	1 ^a	25 ^b	23 ^c	22
	E. durans (3)	-	1 ^b	-	2 ^b	-	-	2 ^a	-	-	2 ^b	2
Soft cheese	E. faecalis (17)	-	7 ^b	-	2 ^b	-	-	-	2 ^a	3 ^a	4 ^b	2
	E. faecium (4)	-	3 ^b	-	4 ^b	-	-	-	-	-	-	-
	E. hirae (12)	-	-	-	4 ^b	-	-	-	-	8 ^a	10 ^b	2
	Sub-total (108)	1	24	1	66	21	10	3	10	45	63	49
	Total (%)	2 (0.6)	62 (20)	7 (2.3)	148 (47.7)	46 (14.8)	11 (3.5)	29 (9.3)	39 (12.6)	170 (54.8)	97 (31.3)	101 (33.1)