Validation of a commercially available test that enables the quantification of the numbers of CGG trinucleotide repeat expansion in FMR1 gene.

In the present study, we evaluated a commercially available TP-PCR-based assay, the FastFraXTM FMR1 Sizing kit, as a test in quantifying the number of CGG repeats in the FMR1 gene. Based on testing with well characterized DNA samples from Coriell, the kit yielded size results within 3 repeats of those obtained by common consensus (n = 14), with the exception of one allele. Furthermore, based on data obtained using all Coriell samples with or without common consensus (n = 29), the Sizing kit was 97.5% in agreement with existing approaches. Additionally, the kit generated consistent size information in repeatability and reproducibility studies (CV 0.39% to 3.42%). Clinical performance was established with 198 archived clinical samples, yielding results of 100% sensitivity (95% CI, 91.03% to 100%) and 100% specificity (95% CI, 97.64% to 100%) in categorizing patient samples into the respective normal, intermediate, premutation and full mutation genotypes.

Validation of a Commercially Available Screening Tool for the Rapid Identification of CGG Trinucleotide Repeat Expansions in FMR1.

Recently developed PCR-based methods for fragile X syndrome testing are often regarded as screening tools because of a reduced reliance on Southern blot analysis. However, existing PCR methods rely essentially on capillary electrophoresis for the analysis of amplicons. These methods not only require an expensive capillary electrophoresis instrument but also involve post-PCR processing steps. Here, we evaluated a commercially available PCR-based assay that uses melt curve analysis as a screening tool for the rapid detection of CGG repeat expansions in the fragile X mental retardation 1 (FMR1) gene. On the basis of testing with well-characterized DNA samples, the assay gave a detection limit of 10 ng per reaction and an analytic specificity beyond 150 ng per reaction. Furthermore, the melt temperatures critical for result interpretation were found to be closely linked to the CGG expansion lengths with great consistency (CV < 0.55%). The clinical performance of the assay was established with 528 blinded and previously analyzed clinical samples, yielding results of 100% sensitivity (95% CI, 91.0%-100%) and 99.6% specificity (95% CI, 98.5%-99.9%) in detecting expansions >55 CGG repeats in FMR1. This new approach eliminates post-PCR handling for all non-expanded samples, and exemplifies a truly efficient screening procedure.