Allelic imbalance in selected chromosomal regions in ovarian cancer.

Ovarian cancer (OC) is often asymptomatic at the initial stage. When diagnosed, up to 75% of the patients present grade III or IV tumors with metastasis in nearby organs of the abdomen. Genetic imbalance is abundant in OC, and allelic loss (AL) of specific chromosomal regions is considered an early event. To establish association between genetic markers for early diagnosis/prognosis of OC, our target was to define narrow specific regions of AL. We analyzed 65 ovarian carcinomas by using 19 microsatellite markers located in three different chromosomes. First, a 7.6-Mb region containing the estrogen receptor (ESR1) and the tumor suppressor gene LATS1 was analyzed. Several chromosomal breakpoints flanking ESR1 affecting the region harboring LATS1 were found. Second, we found chromosomal breakpoints on 13q13.1 approximately q13.3 that defined two narrow regions flanking the BRCA2 locus. Third, our ovarian tumors exhibited a very high frequency of AL on 16q and chromosomal breakpoints defining two narrow regions within 16q22.2 approximately q24.3. In this article, we report three new polymorphic microsatellite markers and strong evidence of AL of narrow well-defined regions in hot spots on 6q, 13q, and 16q in ovarian tumors.

Frequent LOH at hMLH1, a highly variable SNP in hMSH3, and negligible coding instability in ovarian cancer.

BACKGROUND: Molecular alterations such as DNA microsatellite instability (MSI/RER), single nucleotide polymorphism (SNP) and loss of heterozygosity (LOH) can occur throughout the genome and be associated with different types of cancer. In the present study, we aimed at detecting molecular alterations within the mismatch DNA repair genes in ovarian cancer (OC), using a sensitive, accurate and reliable protocol we have developed. MATERIALS AND METHODS: A combination of high-resolution GeneScan software analysis and automated DNA cycle sequencing was used. RESULTS: Negligible coding MSI was observed in selected sequences of mismatch DNA repair genes in our series of sixty-two ovarian tumors and matched blood DNAs. Unlike MSI, loss of one hMLH1 allele was scored in almost half (47%) of the informative cases. In addition, an SNP in hMSH3/intron 5 was found to be highly variable in OC patients. CONCLUSION: 1) Coding DNA instability is likely to be a very rare event in OC and, therefore, may not significantly contribute to the development of OC, and 2) the high frequency of LOH at hMLH1 observed in our ovarian tumors suggests that further investigation is needed to determine if such a trend exists in other mismatch DNA repair and/or critical genes.