Antimicrobial resistance patterns and characterisation of emerging beta‐lactamase‐producing Escherichia coli in camels sampled from Northern Kenya

BACKGROUND: Animal husbandry practices in different livestock production systems and increased livestock–wildlife interactions are thought to be primary drivers of antimicrobial resistance (AMR) in Arid and Semi‐Arid Lands (ASALs). Despite a tenfold increase in the camel population within the last decade, paired with widespread use of camel products, there is a lack of comprehensive information concerning beta‐lactamase‐producing Escherichia coli (E. coli) within these production systems. OBJECTIVES: Our study sought to establish an AMR profile and to identify and characterise emerging beta‐lactamase‐producing E. coli isolated from faecal samples obtained from camel herds in Northern Kenya. METHODS: The antimicrobial susceptibility profiles of E. coli isolates were established using the disk diffusion method, with beta‐lactamase (bla) gene PCR product sequencing performed for phylogenetic grouping and genetic diversity assessments. RESULTS: Here we show, among the recovered E. coli isolates (n = 123), the highest level of resistance was observed for cefaclor at 28.5% of isolates, followed by cefotaxime at 16.3% and ampicillin at 9.7%. Moreover, extended‐spectrum beta‐lactamase (ESBL)‐producing E. coli harbouring the bla (CTX‐M‐15) or bla (CTX‐M‐27) genes were detected in 3.3% of total samples, and are associated with phylogenetic groups B1, B2 and D. Multiple variants of non‐ESBL bla (TEM) genes were detected, the majority of which were the bla (TEM‐1) and bla (TEM‐116) genes. CONCLUSIONS: Findings from this study shed light on the increased occurrence of ESBL‐ and non‐ESBL‐encoding gene variants in E. coli isolates with demonstrated multidrug resistant phenotypes. This study highlights the need for an expanded One Health approach to understanding AMR transmission dynamics, drivers of AMR development, and appropriate practices for antimicrobial stewardship in camel production systems within ASALs.