Introduction to PCR/OLA/SCS, a multiplex DNA test, and its application to cystic fibrosis.

The field of medical, molecular diagnostics has grown rapidly over the last few years, becoming increasingly informative to both clinician and patient. As genes associated with specific diseases have been discovered and sequenced, many genotype-phenotype relationships have been defined. For those genetic diseases with associated, defined, gene mutations, sophisticated DNA diagnostic tests are being developed. As an example, the Cystic Fibrosis Transmembrane Conductance Regulator (CFTR) gene, is associated with Cystic Fibrosis (CF). We have developed a new molecular diagnostic technology, PCR/OLA/SCS, and applied it first to the diagnosis of CF. Test design in the field of molecular diagnostics must consider such characteristics as specificity, sensitivity, ease and speed of protocol, multiplex capacity, and cost. PCR/OLA/SCS addresses these requirements. Polymerase Chain Reaction (PCR) is widely used in both diagnostics and research. We have combined well established PCR technology with Oligonucleotide Ligation Assay (OLA) and Sequence-Coded Separation (SCS), two relatively new technologies.

High-density multiplex detection of nucleic acid sequences: oligonucleotide ligation assay and sequence-coded separation.

We describe a non-isotopic, semi-automated method for large-scale multiplex analysis of nucleic acid sequences, using the cystic fibrosis transmembrane regulator (CFTR) gene as an example. Products of a multiplex oligonucleotide ligation assay (OLA) are resolved electrophoretically from one another and from unligated probes under denaturing conditions with fluorescence detection. One ligation probe for each OLA target carries a fluorescent tag, while the other probe carries an oligomeric non-nucleotide mobility modifier. Each OLA product has a unique electrophoretic mobility determined by the ligated oligonucleotides and the mobility-modifier oligomer arbitrarily assigned (coded) to its target. The mobility range for practical mobility modifiers is much wider than the accessible range from unmodified ligated oligonucleotides of practical length. Each mobility modifier is built from phosphoramidite monomers in a stepwise manner on its associated oligonucleotide using an automated synthesizer. The resulting mobility modifiers lower the probe-target duplex Tm by less than 3 degrees C and retard probe-target annealing by less than 50%, with negligible effect on OLA yield and specificity. This method is especially useful for allelic discrimination in highly polymorphic genes such as CFTR.