Chantal Desmaze

Interphase molecular cytogenetics of Ewing's sarcoma and peripheral neuroepithelioma t(11;22) with flanking and overlapping cosmid probes☆

The translocation, t(11;22)(q24;q12), recurrently observed in Ewings sarcoma and in peripheral neuroepithelioma has been recently cloned. The analysis of a series of ES/PNE has revealed that the chromosome 22 breakpoints are clustered in a small region of 7 kb, called EWSR1, and that those on chromosome 11 are spread over a larger region of 40-50 kb, called EWSR2. Cosmids from loci flanking or overlapping these two regions have been obtained. We demonstrate here that fluorescence in situ hybridization (FISH) with these cosmids allows the localization of the two breakpoints with a 10-kb resolution and leads to a rapid and reliable ES/PNE diagnosis.

Multiple chromosomal mechanisms generate an EWS/FLI1 or an EWS/ERG fusion gene in Ewing tumors☆

The t(11;22)(q24;q12) translocation is found in about 85% of Ewing tumors and leads in all cases to an EWS/FLI1 fusion gene. In a few instances, complex translocations, involving chromosomes 11, 22 and a third chromosome or other variant translocations not involving chromosome 11 also have been reported. These rearrangements generate an active fusion gene between the EWS gene and either the human FLI1 gene or other members of the ETS gene family: the ERG gene localized in band 21q22.2, the ETV1 gene localized in band 7p22, or the E1AF gene localized in band 17q12. Using fluorescence in situ hybridization (FISH) on interphase nuclei or metaphases, we report here the characterization of particular karyotypes in Ewing tumors, namely a complex t(2;11;22) translocation, a variant t(12;22) translocation, and one Ewing tumor without specific rearrangements but with an EWS/ERG fusion gene demonstrated by molecular analysis. These molecular cytogenetic methods allowed us (1) to precisely localize the genomic breakpoints within-EWSR1 and EWSR2 and to identify the chromosome carrying the fusion gene; (2) to determine the nature of events generating the fusion genes; (3) to demonstrate that some variant translocations represent masked complex translocations; and (4) to show that the generation of an EWS/ERG fusion gene cannot be obtained through a simple balanced translocation.

Routine diagnosis of DiGeorge syndrome by fluorescent in situ hybridization

In a series of ten patients affected by DiGeorge syndrome, we screened, by high resolution banding and fluorescent in situ hybridization of a cosmid probe, for microdeletions associated with this syndrome. In the ten patients, a microdeletion was demonstrated by in situ hybridization, but suspected only in two patients by high resolution banding.

Neurofibromatosis type 2

Neurofibromatosis type 2 is a disorder characterized by the growth of noncancerous tumors in the nervous system. The most common tumors associated with neurofibromatosis type 2 are called vestibular schwannomas or acoustic neuromas. These growths develop along the nerve that carries information from the inner ear to the brain (the auditory nerve). Tumors that occur on other nerves are also commonly found with this condition.

Rapid isolation of cosmids from defined subregions by differential Alu-PCR hybridization on chromosome 22-specific library

A method based on the differential screening of a chromosome-specific cosmid library with amplified inter-Alu sequences obtained from a set of somatic cell hybrids has been developed to target the isolation of probes from predefined subchromosomal regions. As a model system, we have used a chromosome 22-specific cosmid library and four cell hybrids containing different parts of this chromosome. The procedure has identified cosmids that demonstrate differential hybridization signals with Alu-PCR products from these cell hybrids. We show, by in situ hybridization or individual mapping, that their hybridization pattern is indicative of their sublocalization on chromosome 22, thus resulting in a large enrichment factor for the isolation of probes from specific small chromosome subregions. Depending on the local Alu-sequence density, from 3 to 10 independent loci per megabase of genome can thus be identified.

In situ hybridization of PCR amplified inter-Alu sequences from a hybrid cell line

SummaryPolymerase chain reaction amplified products promoted by oligonucleotides complementary to the highly repetitive human Alu sequence can be used for in situ hybridization on metaphase chromosomes to investigate the human content of a hybrid cell line. The TC65 primer, which combines the advantages of promoting the amplification of large inter-Alu sequences together with only small flanking Alu sequences, enables a simple and precise characterization to be made, with a high signal to noise ratio. Total human DNA is an efficient competitor in the removal of non-specific signals. The use of this oligonucleotide should be considered in the characterization of the human content of hybrids or in the generation of specific reagents for chromosome decoration.

Precise localization on chromosome 12 of the ATF-1 gene by fluorescence in situ hybridization.

The ATF-1 gene encodes for a transcription factor normally regulated by cAMP (Hai et al. 1989, Yoshimura et al. 1990). Recently, it has been shown to be involved in the recurrent t(12;22) translocation observed in soft tissue malignant melanoma, in a fusion gene with the EWS gene (Zucman et al. 1993). We report here on its precise localization on chromosome 12 by fluorescence in situ hybridization.