Evaluation of enzymatic mutation detectiontrade mark in hereditary nonpolyposis colorectal cancer.

In hereditary nonpolyposis colorectal cancer (HNPCC), the majority of reported mutations are dispersed throughout the 35 exons of the two principal susceptibility genes, MLH1 and MSH2, and because of this complexity, rapid mutation screening methods are required. The aim of this study was to evaluate the sensitivity of the Enzymatic Mutation Detection (EMD) assay in HNPCC using genomic DNA samples with known gene alterations in MLH1 and MSH2. The EMD assay relies upon the enzyme T4 Endonuclease VII recognizing and cleaving DNA mismatches, created when a PCR product containing a sequence alteration is hybridized with a wild type probe. A total of 68 different sequence variants from 30 exons were analyzed. The EMD assay was able to detect 62 of the 68 sequence variants (91%) with the majority showing strong cleavage products. One of the advantages of the EMD assay over other mutation screening techniques is that larger fragments can be analyzed in a single assay. No specialized equipment is required and one set of primers is sufficient for radioactive detection of the cleavage products. This method can be adapted to use fluorescent dye-labelled primers and may be automated to detect mutations accurately and rapidly in a large number of samples. One new MLH1 mutation (418delA) and two novel MSH2 mutations (1A>C; 227-228delAG) were also detected in HNPCC patients screened using this method.

Reliable and sensitive detection of premature termination mutations using a protein truncation test designed to overcome problems of nonsense-mediated mRNA instability.

The protein truncation test (PTT) is a mutation-detection method used to scan for premature termination (nonsense) mutations. PCR amplification of the DNA or mRNA source material is performed using forward primers containing a T7-promoter sequence and translation initiation signals such that the resultant products can be transcribed and translated in vitro to identify the smaller truncated protein products. mRNA is commonly used as the source material, but success of the PTT and other RNA-based mutation detection methods can be severely compromised by nonsense mutation-induced mRNA decay, a well-documented process that is often overlooked in mutation detection strategies. In this study, we develop an RNA-based PTT that overcomes the problem of mRNA decay by preincubating cells with cycloheximide to stabilise the mutant mRNA. The effectiveness of this method for mutation detection in abundant mRNAs was demonstrated in osteogenesis imperfecta fibroblasts by the protection of type I collagen (COL1A1) mRNA containing nonsense mutations that normally resulted in mutant mRNA degradation. Stabilisation of mutant mismatch repair gene (MLH1) mRNA was also observed in transformed lymphocytes from patients with hereditary nonpolyposis colorectal cancer (HNPCC). Importantly, our strategy also stabilised very low-level (or illegitimate) nonsense-containing transcripts in lymphoblasts from patients with Bethlem myopathy (COL6A1), familial adenomatous polyposis (APC), and breast cancer (BRCA1). The greatly increased sensitivity and reliability of this RT-PCR/PTT protocol has broad applicability to the many genetic diseases in which only blood-derived cells may be readily available for analysis.