Risk of Misdiagnosis Due to Allele Dropout and False-Positive PCR Artifacts in Molecular Diagnostics: Analysis of 30,769 Genotypes.

Quality control is a complex issue for clinical molecular diagnostic applications. In the case of genotyping assays, artifacts such as allele dropout represent a risk of misdiagnosis for amplification-based methods. However, its frequency of occurrence in PCR-based diagnostic assays remains unknown. To maximize the likelihood of detecting allele dropout, our clinical genotyping PCR-based assays are designed with two independent assays for each allele (nonoverlapping primers on each DNA strand). To estimate the incidence of allelic dropout, we took advantage of the capacity of our clinical assays to detect such events. We retrospectively studied their occurrence in the initial PCR assay for 30,769 patient reports for mutations involved in four diseases produced over 8 years. Ninety-three allele dropout events were detected and all were solved before reporting. In addition, 42 cases of artifacts caused by amplification of an allele ultimately confirmed to not be part of the genotype (drop-in events) were detected and solved. These artifacts affected 1:227 genotypes, 94% of which were due to nonreproducible PCR failures rather than sequence variants interfering with the assay, suggesting that careful primer design cannot prevent most of these errors. This provides a quantitative estimate for clinical laboratories to take this phenomenon into account in quality management and to favor assay designs that can detect (and minimize) occurrence of these artifacts in routine clinical use.

The fragile x mental retardation syndrome 20 years after the FMR1 gene discovery: an expanding universe of knowledge.

The fragile X mental retardation (FXMR) syndrome is one of the most frequent causes of mental retardation. Affected individuals display a wide range of additional characteristic features including behavioural and physical phenotypes, and the extent to which individuals are affected is highly variable. For these reasons, elucidation of the pathophysiology of this disease has been an important challenge to the scientific community. 1991 marks the year of the discovery of both the FMR1 gene mutations involved in this disease, and of their dynamic nature. Although a mouse model for the disease has been available for 16 years and extensive research has been performed on the FMR1 protein (FMRP), we still understand little about how the disease develops, and no treatment has yet been shown to be effective. In this review, we summarise current knowledge on FXMR with an emphasis on the technical challenges of molecular diagnostics, on its prevalence and dynamics among populations, and on the potential of screening for FMR1 mutations.

High-density polymorphisms analysis of 23 candidate genes for association with bone mineral density.

Osteoporosis is a bone disease characterized by low bone mineral density (BMD), a highly heritable and polygenic trait. Women are more prone than men to develop osteoporosis due to a lower peak bone mass and accelerated bone loss at menopause. Peak bone mass has been convincingly shown to be due to genetic factors with heritability up to 80%. Menopausal bone loss has been shown to have around 38% to 49% heritability depending on the site studied. To have more statistical power to detect small genetic effects we focused on premenopausal women. We studied 23 candidate genes, some involved in calcium and vitamin-D regulation and others because estrogens strongly induced their gene expression in mice where it was correlated with humerus trabecular bone density. High-density polymorphisms were selected to cover the entire gene variability and 231 polymorphisms were genotyped in a first sample of 709 premenopausal women. Positive associations were retested in a second, independent, sample of 673 premenopausal women. Ten polymorphisms remained associated with BMD in the combined samples and one was further associated in a large sample of postmenopausal women (1401 women). This associated polymorphism was located in the gene CSF3R (granulocyte colony stimulating factor receptor) that had never been associated with BMD before. The results reported in this study suggest a role for CSF3R in the determination of bone density in women.