Three novel Enterobacter cloacae bacteriophages for therapeutic use from Ghanaian natural waters.
O L LyytinenC DapuligaD WallingerS PatpatiaBenshak J AuduSaija KiljunenPublished in: Archives of virology (2024)
Infections caused by multidrug-resistant (MDR) bacteria are a growing global concern. Enterobacter cloacae complex (ECC) species are particularly adept at developing antibiotic resistance. Phage therapy is proposed as an alternative treatment for pathogens that no longer respond to antibiotics. Unfortunately, ECC phages are understudied when compared to phages of many other bacterial species. In this Ghanaian-Finnish study, we isolated two ECC strains from ready-to-eat food samples and three novel phages from natural waters against these strains. We sequenced the genomic DNA of the novel Enterobacter phages, fGh-Ecl01, fGh-Ecl02, and fGh-Ecl04, and assessed their therapeutic potential. All of the phages were found to be lytic, easy to propagate, and lacking any toxic, integrase, or antibiotic resistance genes and were thus considered suitable for therapy purposes. They all were found to be related to T4-type viruses: fGh-Ecl01 and fGh-Ecl04 to karamviruses and fGh-Ecl02 to agtreviruses. Testing of Finnish clinical ECC strains showed promising susceptibility to these novel phages. As many as 61.1% of the strains were susceptible to fGh-Ecl01 and fGh-Ecl04, and 7.4% were susceptible to fGh-Ecl02. Finally, we investigated the susceptibility of the newly isolated ECC strains to three antibiotics - meropenem, ciprofloxacin, and cefepime - in combination with the novel phages. The use of phages and antibiotics together had synergistic effects. When using an antibiotic-phage combination, even low concentrations of antibiotics fully inhibited the growth of bacteria.
Keyphrases
- escherichia coli
- multidrug resistant
- pseudomonas aeruginosa
- antibiotic resistance genes
- wastewater treatment
- stem cells
- microbial community
- gene expression
- dna methylation
- single molecule
- klebsiella pneumoniae
- copy number
- high resolution
- climate change
- genome wide
- atomic force microscopy
- combination therapy
- antimicrobial resistance
- drug induced
- anaerobic digestion
- high speed