A.M. Meloni

Overrepresentation of chromosome 12p sequences and karyotypic evolution in i(12p)-negative testicular germ-cell tumors revealed by fluorescence in situ hybridization

Human testicular germ-cell tumors (TGCTs) comprise a heterogeneous group of solid neoplasms. These tumors are characterized by the presence of a highly specific chromosomal abnormality, i.e., an isochromosome of the short arm of chromosome 12. At present, this i(12p) chromosome is found in more than 80% of TGCTs. Isochromosome 12p has also been observed in some ovarian and extragonadal germ cell tumors. In the remaining so-called i(12p)-negative TGCTs other abnormalities involving chromosome 12, mainly 12p, can be found. In order to establish whether 12p abnormalities other than i(12p) are a common phenomenon in TGCTs, a panel of 11 i(12p)-negative tumors was investigated using multicolor fluorescence in situ hybridization. All TGCTs examined appeared to contain chromosomal abnormalities involving 12p, resulting in a distinct overrepresentation of short arm sequences. In addition, indications were obtained for a clonal evolution in one of the tumors. Our data suggest that the occurrence of 12p abnormalities is a common phenomenon in i(12p)-negative TGCTs and that these abnormalities, analogous to i(12p), may contribute to the process of tumor development.

Distinct Xp11.2 breakpoint regions in synovial sarcoma revealed by metaphase and interphase FISH: relationship to histologic subtypes.

Fluorescence in situ hybridization (FISH) and molecular analyses of synovial sarcomas with cytogenetically similar (X;18)(p11.2;q11.2) translocations have revealed two alternative breakpoint regions in Xp11.2, one residing in the ornithine aminotransferase-like 1 (OATL1) region and the other one in the related but distinct OATL2 region. As these results were obtained by different groups, we set out to evaluate an extended series of tumors with special emphasis on the two possible X-related breakpoint regions. Together, seven synovial sarcomas were identified with a break in the OATL1 region and six with a break near OATL2, thereby confirming the actual existence of the two alternative Xp breakpoint regions. We speculate that there seems to be a relationship between the occurrence of these breakpoint regions and the histologic phenotype of the tumors, with a predominance of OATL1-related breakpoints in the classical biphasic tumors and of OATL2-related breakpoints in the monophasic fibrous tumors.

Fine mapping of the human renal oncocytoma-associated translocation (5;11)(q35;q13) breakpoint

Recent cytogenetic analysis of a series of human renal oncocytomas revealed the presence of a recurring chromosomal translocation (5;11)(q35;q13) as sole anomaly in a subset of the tumors. The molecular characterization of this translocation was initiated using two primary t(5;11)-positive renal oncocytomas and a panel of somatic cell hybrids derived from one of these tumors, in conjunction with fluorescence in situ hybridization (FISH) and Southern blot analysis. The breakpoint in chromosome band 11q13 could be located within a genomic interval of at maximum 400 Kb immediately centromeric to the BCL1 locus.

Molecular Analysis of Chromosome 7q21.3 in Uterine Leiomyoma: Analysis using Markers with Linkage to Insulin Resistance

Recent sibling-pair linkage analyses have indicated possible linkage of noninsulin dependent diabetes mellitus (NIDDM) with a number of markers on the long arm of chromosome 7. A coincidental and recent discovery is that specific genetic anomalies identified on chromosome 7 in uterine leiomyoma tumor cells in many cases correspond, cytogenetically, to the same region where genetic linkage to insulin resistance has been identified. In the present study, 15 closely spaced microsatellite markers were used to finely map deletion breakpoints and to test for allelic loss of 7q markers in 12 uterine leiomyoma tumor samples with cytogenetically defined deletions. Of the 9 informative tumor samples, three exhibited breakpoints in the same region where genetic linkage to insulin resistance has been identified (between PON and UT901). Because breakpoints in neoplasias often occur within or adjacent to expressed sequences, these breakpoints may provide a molecular tool to aid in the identification of candidate genes for insulin resistance.

Localization of X chromosome short arm markers relative to synovial sarcoma- and renal adenocarcinoma-associated translocation breakpoints

A series of thirteen different DNA markers was mapped relative to papillary renal cell carcinoma- and synovial sarcoma-associated translocation breakpoints in Xp11.2 using a panel of tumor-derived somatic cell hybrids in conjunction with Southern blot analysis. Our results indicate that the two translocation breakpoints differ from each other and that the chromosomal break in t(X; 1)-positive papillary renal cell carcinoma is located between the markers PFC-TIMP-OATL1-SYP-TFE3 and DXS226-DXS146-DXS255-OATL2-DXS14. In addition, our current breakpoint analysis has resulted in a revision of the regional localization of the proximal Xp marker DXS226.

Allelic Loss Analysis by Capillary Electrophoresis: An Accurate, Automated Method for Detection of Deletions in Solid Tumors

In this report, we describe a fast and accurate capillary electrophoresis, PCR-based method for detecting loss of allelic heterozygosity in solid tumor samples. This automated method requires small sample sizes, and data can be obtained in less than 15 min. The method is particularly powerful for uncovering deletions in tumor sample preparations containing significant normal tissue contamination.

Identification of a yeast artificial chromosome that spans the human papillary renal cell carcinoma-associated t(X;1) breakpoint in Xp11.2

Recently, a specific chromosome abnormality, t(X;1)(p11;q21), was described for a subgroup of human papillary renal cell carcinomas. The translocation breakpoint in Xp11 is located in the same region as that in t(X;18)(p11;q11)-positive synovial sarcoma. We used fluorescence in situ hybridization (FISH) and somatic cell hybridization techniques to demonstrate 1) that the Xp11 translocation breakpoint in papillary renal cell carcinoma differs from that observed in synovial sarcoma and has a more proximal location, and 2) that an ornithine aminotransferase (OAT)L2 containing yeast artificial chromosome (YAC) spans the X;1 translocation. This YAC provides an ideal starting point from which the breakpoint itself and the gene(s) involved can be isolated and characterized.