Abstract
AbstractThe gold standard for the isolation and characterization of bacteriophages (phages), the plaque assay, has remained almost unchanged for over 100 years. The need for improvements to its scalability has been driven home by successes with personalized phage therapy requiring large phage libraries and rapid sensitivity testing. Using a robotic pinning platform, we miniaturized plaque assays from bacterial lawns to micro-colonies from 100 nl of inoculant, increasing throughput by >1000 fold without compromising sensitivity. A comparable manual workflow with one quarter the throughput maintained the same sensitivity. These micro-plaque assays can replace plaque assays as a new gold standard in phage biology. As proof of principle, we used our technique to isolate and de-replicate 21 uniquePseudomonas aeruginosaphages from a single environmental sample. We then demonstrated – using the same assay - that of 17 multi-drug resistant clinicalP. aeruginosastrains, 15 were susceptible to infection by one or more of the 21 phages tested. Our method allows rapid isolation and de-replication of phages, as well as enabling screening of large phage libraries against bacterial isolates of interest.
Publisher
Cold Spring Harbor Laboratory
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