Employment of the Phage Cocktail as a Species-Specific Recognition Agent for Wide-Spectrum Detection of Bacterial Strains.

ABSTRACT

Phages have already been employed to detect bacteria because of their specific recognition capability and strong infectious activity toward their host. However, the reported single-phage-based techniques are inevitably restricted by false negative results that arose from extremely high strain specificity of phages. In this study, a cocktail composed of three Klebsiella pneumoniae (K. pneumoniae) phages was prepared as a recognition agent to broaden the recognition spectrum for detecting this bacterial species. A total of 155 clinically isolated strains of K. pneumoniae collected from four hospitals were adopted to test its recognition spectrum. A superior recognition rate of 91.6% for the strains was achieved due to the complementarity of the recognition spectra of the three phages composed of the cocktail. However, the recognition rate is as low as 42.3-62.2% if a single phage is employed. Based on the wide-spectrum recognition capability of the phage cocktail, a fluorescence resonance energy transfer method was established for detecting K. pneumoniae strains by employing fluorescein isothiocyanate labeled to the phage cocktail and Au nanoparticles labeled to p-mercaptophenylboronic acid as energy donors and acceptors, respectively. The detection process can be completed within 35 min, with a wide dynamic range of 5.0 × 102-1.0 × 107 CFU/mL. The application potential was verified by applying it to quantitate K. pneumoniae in different sample matrixes. This pioneer work opens an avenue for achieving wide-spectrum detection of different strains belonging to the same bacterial species with the phage cocktail.