Purpose: To enhance classification of variants of uncertain significance (VUS) in the DNA mismatch repair (MMR) genes in the cancer predisposition Lynch syndrome, we developed the cellfree in vitro MMR activity (CIMRA) assay. Here, we calibrate and validate the assay, enabling its integration with in silico and clinical data. Methods: Two sets of previously classified MLH1 and MSH2 variants were selected from a curated MMR gene database, and their biochemical activity determined by the CIMRA assay. The assay was calibrated by regression analysis followed by symmetric cross-validation and Bayesian integration with in silico predictions of pathogenicity. CIMRA assay reproducibility was assessed in four laboratories. Results: Concordance between the training runs met our prespecified validation criterion. The CIMRA assay alone correctly classified 65% of variants, with only 3% discordant classification. Bayesian integration with in silico predictions of pathogenicity increased the proportion of correctly classified variants to 87%, without changing the discordance rate. Interlaboratory results were highly reproducible. Conclusion: The CIMRA assay accurately predicts pathogenic and benign MMR gene variants. Quantitative combination of assay results with in silico analysis correctly classified the majority of variants. Using this calibration, CIMRA assay results can be integrated into the diagnostic algorithm for MMR gene variants.
Monoallelic PMS2 germline mutations cause 5%-15% of Lynch syndrome, a midlife cancer predisposition, whereas biallelic PMS2 mutations cause approximately 60% of constitutional mismatch repair deficiency (CMMRD), a rare childhood cancer syndrome. Recently improved DNA- and RNA-based strategies are applied to overcome problematic PMS2 mutation analysis due to the presence of pseudogenes and frequent gene conversion events. Here, we determined PMS2 mutation detection yield and mutation spectrum in a nationwide cohort of 396 probands. Furthermore, we studied concordance between tumor IHC/MSI (immunohistochemistry/microsatellite instability) profile and mutation carrier state. Overall, we found 52 different pathogenic PMS2 variants explaining 121 Lynch syndrome and nine CMMRD patients. In vitro mismatch repair assays suggested pathogenicity for three missense variants. Ninety-one PMS2 mutation carriers (70%) showed isolated loss of PMS2 in their tumors, for 31 (24%) no or inconclusive IHC was available, and eight carriers (6%) showed discordant IHC (presence of PMS2 or loss of both MLH1 and PMS2). Ten cases with isolated PMS2 loss (10%; 10/97) harbored MLH1 mutations. We confirmed that recently improved mutation analysis provides a high yield of PMS2 mutations in patients with isolated loss of PMS2 expression. Application of universal tumor prescreening methods will however miss some PMS2 germline mutation carriers.
Lynch syndrome (LS) is an autosomal dominant disorder that predisposes to colon, endometrial, and other cancers. LS is caused by a heterozygous germline mutation in one of the DNA mismatch repair (MMR) genes. A significant proportion of all mutations found in suspected LS patients comprises single amino acid alterations. The pathogenicity of these variants of uncertain significance (VUS) is difficult to assess, precluding diagnosis of carriers and their relatives. Here we present a rapid cell-free assay to investigate MMR activity of MSH2 or MSH6 VUS. We used this assay to analyze a series of MSH2 and MSH6 VUS, selected from the Leiden Open Variation Database. Whereas a significant fraction of the MSH2 VUS has lost MMR activity, suggesting pathogenicity, the large majority of the MSH6 VUS appears MMR proficient. We anticipate that this assay will be an important tool in the development of a comprehensive and widely applicable diagnostic procedure for LS-associated VUS.
The RAD54 gene of Saccharomyces cerevisiae plays a crucial role in recombinational repair of double-strand breaks in DNA. Here the isolation and functional characterization of the RAD54 homolog of the fruit fly Drosophila melanogaster, DmRAD54, are described. The putative Dmrad54 protein displays 46 to 57% identity to its homologs from yeast and mammals. DmRAD54 RNA was detected at all stages of fly development, but an increased level was observed in early embryos and ovarian tissue. To determine the function of DmRAD54, a null mutant was isolated by random mutagenesis. DmRAD54-deficient flies develop normally, but the females are sterile. Early development appears normal, but the eggs do not hatch, indicating an essential role for DmRAD54 in development. The larvae of mutant flies are highly sensitive to X rays and methyl methanesulfonate. Moreover, this mutant is defective in X-ray-induced mitotic recombination as measured by a somatic mutation and recombination test. These phenotypes are consistent with a defect in the repair of double-strand breaks and imply that the RAD54 gene is crucial in repair and recombination in a multicellular organism. The results also indicate that the recombinational repair pathway is functionally conserved in evolution.Double-strand breaks (DSBs) in DNA are induced by ionizing radiation and by various chemical compounds, such as free radicals and methyl methanesulfonate (MMS). In addition, DSBs arise as intermediates during V(D)J rearrangement in differentiating lymphocytes, transposition events, and meiotic recombination in germ cells. Unrepaired DSBs often lead to cell death or contribute to the formation of chromosomal aberrations such as deletions and translocations. In eukaryotes, DSBs can be repaired via two main pathways: (i) recombinational repair, which is dependent on the presence of an intact duplicate DNA sequence, and (ii) end-to-end rejoining, which is based on rejoining of the two DNA ends (46). The available evidence suggests that both mechanisms are conserved in eukaryotes from yeasts to humans. However, the relative contributions of both mechanisms in repair of DSBs differ considerably between lower and higher eukaryotes. Repair of DSBs in mammals has been investigated with radiation-sensitive rodent cell lines. Several of these cell lines have defects in repairing radiation-induced DSBs and are also strongly impaired in V(D)J rearrangement. Further studies have revealed that these mutants have defects in the end-to-end rejoining pathway (reviewed in references 26, 47, and 63). Repair of DSBs at defined sites in the genome of mammalian cells also occurs more frequently by end-to-end rejoining than by homologous recombination (21, 33). The same observations have been made in experiments studying the fate of linear plasmid molecules in mammalian cells and Xenopus laevis oocytes (27,29,31). Therefore, DSBs in higher eukaryotes appear to be repaired primarily by end-to-end rejoining mechanisms.In lower eukaryotes, however, repair of DSBs occurs almost exclusively by...
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