Enumeration of Bacteriophages by Double Agar Overlay Plaque Assay

This report summarizes the results from an effort to optimize the double-agar plate assay for visualization of the plaques made by six temperate bacteriophages induced from industrial strains of Lactococcus lactis. Among the several parameters found to influence the plaque assay, the effect of incorporating glycine into the growth medium was most striking, resulting in extensive increase in the plaque size of all of the 13 phage-host pairs tested. Notable effects on the plaque size of other factors such as the procedure for sterilization of the agar medium, the volume and softness of the top and bottom layers, and the number and growth stage of the bacterial cells added to the lawn, were also observed. By exploiting these findings in an optimized procedure for plaque assaying, several indicator strains were identified which were unable to support the development of plaques on standard double-agar plates. Since bacterial hosts usually are identified by their ability to support the development of plaques, this observation suggests that the severe difficulty experienced in identifying lactococcal starter strains that are sensitive towards a temperate phage, partly is a problem of methodology.

The plaque assay is the traditional method for the quantification of bacteriophage, particularly for lambda cloning vectors. Unfortunately, this technique is fraught with procedural difficulties, and the quality of the data obtained from this "gold standard" assay may be inaccurate due to the subjective interpretation of the results. The application of quantitative real-time PCR (QPCR) technology can address these issues and be a more accurate platform to evaluate phage growth conditions and quantify viral titers in phage preparations. QPCR, with an improved primer set specific for lambda phage and coupled with fluorescent dye detection of PCR products, was used to detect and quantify phages in lysates with no prior DNA purification. Phages were detected below one plaque-forming unit, and at least 89 viral copies were detected from a purified DNA sample. When unknown concentrations of various phage preparations were assessed using QPCR, they were attained more efficiently, with greater sensitivity and precision, and the method produced more accurate quantitative data spanning a wider linear range than those obtained by the plaque assay (six logs vs. one log, respectively). Finally, QPCR for the detection of phage has multiple applications, including conventional cloning and in alternative fields of study such as environmental sciences.