Abstract
The amplification and detection of diverse strains of an infectious virus or bacteria, or variants within a gene family is important for both clinical and basic research but can be difficult using conventional PCR. This report describes and illustrates a novel closed-tube method for amplifying and characterizing heterogeneous target sequences using members of the CTX-M beta-lactamase gene family. Different subgroups of CTX-M genes exhibit low sequence identity, but accurate and efficient detection of these variants is critical because they all confer resistance to penicillin, cefotaxime, and other antibiotics of the beta-lactam class. The method combines a single pair of "thermodynamic consensus primers" (tcPrimers) with one or more "initiator primers" (iPrimers), added at low concentration (5-10 nM). Each iPrimer improves the initial amplification of one or more variants because it has fewer mismatches to its intended target than the more abundant tcPrimers. As a result of initial amplification, each heterogeneous sequence is shifted stepwise toward a better match with the tcPrimers. As soon as the tcPrimer hybridization takes place, amplification proceeds with high efficiency. The tcPrimer pairs can be designed for symmetric PCR or for Linear-After-The-Exponential (LATE)-PCR. LATE-PCR offers the advantage of generating single-stranded DNA that can be characterized for different gene variants in the same closed tube, using low-temperature mismatch-tolerant fluorescent probes.