Prevalence of Virulence Determinants and Antimicrobial Resistance among Commensal Escherichia coli Derived from Dairy and Beef Cattle

Bok, Ewa; Mazurek, Justyna; Stosik, Michał; Wojciech, Magdalena; Baldy-Chudzik, Katarzyna

doi:10.3390/ijerph120100970

Cited by 32 publications

(32 citation statements)

References 43 publications

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“…1). These findings are basically concordant with the previous finding that most bovine commensal isolates belonged to phylogroups B1 and A (Bok et al 2015;Madoshi et al 2016;Mercat et al 2016). As for human commensal isolates, it was reported that B2 strains predominate in people residing in developed countries in the temperate regions of the world (Escobar-Paramo et al 2004;Skurnik et al 2008).…”

Section: Discussionsupporting

confidence: 91%

Large-scale genome analysis of bovine commensal Escherichia coli reveals that bovine-adapted E. coli lineages are serving as evolutionary sources of the emergence of human intestinal pathogenic strains

et al. 2019

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Section: Discussionsupporting

confidence: 91%

Large-scale genome analysis of bovine commensal Escherichia coli reveals that bovine-adapted E. coli lineages are serving as evolutionary sources of the emergence of human intestinal pathogenic strains

et al. 2019

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“…Phylogenetic Groups B1 and D, and virulence Group Ia were specific among patients and cattle strains in Cluster 2, which confirmed the results of our previous study (Wang et al 2013). Bok et al (2015) also observed that the phylogenetic Group B1 was predominant among isolates from beef cattle; similarly, an Australian survey (Staples et al 2013) reported that the majority of EPEC strains fell into Group B1. Together, these findings suggested that cattle are a major source of strains that are diarrhoeagenic in humans, particularly for strains of Group B1.…”

Section: Discussionsupporting

confidence: 89%

“…Bok et al . () also observed that the phylogenetic Group B1 was predominant among isolates from beef cattle; similarly, an Australian survey (Staples et al . ) reported that the majority of EPEC strains fell into Group B1.…”

Section: Discussionsupporting

confidence: 52%

Comparison by multilocus variable-number tandem repeat analysis and antimicrobial resistance among atypical enteropathogenicEscherichia colistrains isolated from food samples and human and animal faecal specimens

et al. 2016

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Aim: This study assessed whether multilocus variable-number tandem repeat analysis (MLVA) and antimicrobial susceptibility testing discriminated diarrhoeagenic atypical enteropathogenic Escherichia coli (aEPEC) from aEPEC indigenous to domestic animals or healthy people. Methods and Results: MLVA genotyping of 142 aEPEC strains isolated from foods and faecal samples of domestic animals and humans revealed 126 distinct MLVA profiles that distributed to four clusters, yielding a Simpson's index of diversity (D) of 99Á8%. Cluster 2 included 87% of cattle isolates and 67% of patient isolates. The plurality (15/34, 44%) of strains from healthy humans mapped to Cluster 1, while half (18/41, 44%) of the swine strains belonged to Cluster 4. Testing for antimicrobial susceptibility revealed that 52 strains (37%) of aEPEC were resistant to one or more agents; only 10 strains (7%) exhibited resistance to more than three agents. Strains isolated from swine or food exhibited a wider variety of resistance phenotypes than bovine or human strains. Conclusions: MLVA assigned the aEPEC isolates from cattle and patients to Cluster 2, distinct from aEPEC from other sources. Hog yards may be a larger source of drug-resistant strains than are cattle ranches. Significance and Impact of the Study: MLVA suggests that human diarrhoeagenic aEPEC are derived from cattle and are distinct from strains carried by healthy people and other animals. Cattle appear to be reservoirs of human diarrhoeagenic aEPEC.

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“…The results observed in this study are in agreement with studies done in Ethiopia, Iran, and Pakistan [41–44]. Meanwhile, our findings contradict findings of earlier studies done in South Africa and Poland that reported lower prevalences [25,29].…”

Section: Discussionsupporting

confidence: 88%

“…The other reason could be the co-selection of resistant determinant and co-resistance of the E. coli isolates. The simultaneous resistance to penicillin, streptomycin, tetracycline, erythromycin, kanamycin, and virginiamycin has been reported in studies conducted elsewhere [29–31]. A similar co-selection of sulphonamide resistance genes was reported in chickens treated with streptomycin [32].…”

Section: Discussionsupporting

confidence: 54%

Prevalence and distribution of antimicrobial resistance determinants ofEscherichia coliisolates obtained from meat in South Africa

Jaja

Oguttu

Green

et al. 2019

Preprint

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28Objective: This study aimed to characterise antibiotics resistance of Escherichia coli isolates 29 from the formal meat sector (FMS) and informal meat sectors (INMS). 30Method: A total of 162 and 102 E. coli isolates from the FMS, and INMS respectively were 31 isolated by standard culture-based, and biochemical reactions. The isolates were further 32 confirmed by polymerase chain reaction (PCR). The disc diffusion method was used to 33 screen for antimicrobial susceptibility against 19 different antibiotics. The presence of class 34 1-2 integrons in each E. coli isolates was assessed using 3-CS and 5-CS regions specific 35 primers. 36Result: Among the 19 antimicrobials, resistance to tetracyclines, aminoglycosides, 37 cephalosporins, and nitrofurans were found to be more frequent than carbapenems and 38 phenicol with a noticeable increase in the number of multi-drug resistance ranging from three 39 to ten antimicrobials. A total of 20 resistance determinants were assessed with their 40 prevalence and distributions obtained as follows for FMS and INMS respectively; 41 [aminoglycosides: aadA (40.6%; 31.9%), aacC2 (21.4%; 31%), aphA1 (20.8%; 15.1%), 42 aphA2 (37.7%; 18.9%) and strA (6.5%; 9.4%)], [β-lactams: ampC (20%; 45%), blaTEM, 43 (4.4%; 13.3), and blaZ (8.9%; 2.2%)], [Chloramphenicol: catI (1.7%; 1.7%), and cmIA1 44 (1.7%; 1.7%)] and [tetracyclines: tetA (7.7%; 15.4%), tetB (11.5%; 24%), and tetM, (1.9%; 45 8.7%)], and [sulfonamides: sul1 (22.2%; 26.7%), sul2 (17.8%; 6.7%)]. 46 Conclusion: Multiple antibiotic resistance (MAR) indexes ranged from 0.2 -0.5. The results 47 reveal a high prevalence of multidrug-resistant E. coli isolates and resistance determinants 48 suggesting that consumers and handlers of such meat are at risk of contracting antibiotic 49 resistant E. coli-related foodborne disease. 50 51 1 Background 53Meat is a high-risk food, and many studies have shown a causal relationship between meat 54 consumption and disease outbreaks. Meat-related foodborne diseases frequently occur due to 55 the consumption of Escherichia coli contaminated raw or poorly processed meat. The United 56 States, Center for Disease Control and Prevention (CDC) estimates for the year 2011 that one 57 in six or forty-eight million people are infected with a foodborne illness each year, resulting 58 in 3000 deaths. Of this number, E. coli O157: H7 caused an estimated 73480 illnesses each 59 year, resulting in more than 2000 hospitalisations and 60 deaths [1]. 60 Even though raw food hygiene and food safety epidemiology is still in its infancy in Africa, 61 foodborne disease (FBD) is common in developing countries. For instance, 10200 cases of 62 Shiga toxin E.coli (STEC) related FBD was reported in WHO subregion AFR D and E circa 3 63 2012 [2]. The actual prevalence of food-borne infections is difficult to determine, primarily 64 because only a small percentage of incidence is officially reported. Even when cases of 65 foodborne infections are reported, only in a limited number is the aetiology determined [3]. 6...

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Prevalence of Virulence Determinants and Antimicrobial Resistance among Commensal Escherichia coli Derived from Dairy and Beef Cattle

Cited by 32 publications

References 43 publications

Large-scale genome analysis of bovine commensal Escherichia coli reveals that bovine-adapted E. coli lineages are serving as evolutionary sources of the emergence of human intestinal pathogenic strains

Large-scale genome analysis of bovine commensal Escherichia coli reveals that bovine-adapted E. coli lineages are serving as evolutionary sources of the emergence of human intestinal pathogenic strains

Comparison by multilocus variable-number tandem repeat analysis and antimicrobial resistance among atypical enteropathogenicEscherichia colistrains isolated from food samples and human and animal faecal specimens

Prevalence and distribution of antimicrobial resistance determinants ofEscherichia coliisolates obtained from meat in South Africa

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