Rapid Isolation and Genomic Characterization of Sewage-Derived Bacteriophages Targeting Multidrug-Resistant Avian Pathogenic Escherichia coli in Poultry
Published:February 17, 2026
Source :Dibesh karmacharya
Antimicrobial resistance (AMR) in Escherichia coli is a major threat to global poultry production, particularly for controlling colibacillosis caused by avian pathogenic E. coli (APEC). Intensive antibiotic use has accelerated the emergence of multidrug-resistant (MDR) strains, undermining treatment efficacy and facilitating zoonotic transmission of resistance genes. This study evaluated bacteriophage therapy as a targeted, antibiotic-independent strategy to control MDR E. coli in Nepalese poultry systems. Seventeen E. coli isolates were obtained from commercial broiler and local-breed chicken farms. Using the double-layer agar method, 18 lytic phages were isolated from three urban sewage samples, infecting eight isolates. Real Time PCR screening revealed extensive AMR profiles in six isolates; one broiler-derived strain (EcI8) harbored 30 resistance genes, including carbapenemases, ESBLs, aminoglycoside, quinolone, and last-resort antibiotic determinants associated with class 1 and 3 integrons. Purified phages were whole-genome sequenced and all of them belonged to the genera Tequatrovirus, Phapecoctavirus, Vequintavirus, and Gamaleyavirus—lineages previously used in veterinary and human phage therapy. Several exhibited broad host ranges (up to seven isolates) and lacked detectable virulence or resistance genes; they also encoded potent lytic enzymes, including endolysins, holins, spanins, and transglycosylases. Notably, one Phapecoctavirus (PG7) showed close similarity to established APEC-infecting phages. These findings demonstrate that sewage can be a readily accessible source of safe, therapeutically relevant phages targeting highly resistant poultry E. coli. Phage cocktails and derived enzybiotics delivered through drinking water or feed offer a scalable alternative for preventing and treating colibacillosis, reducing antibiotic dependence, and mitigating zoonotic AMR risks. This study establishes a rapid, reproducible pipeline for local phage isolation and genomic validation, supporting field deployment of tailored phage-based interventions in resource-limited poultry systems.
