Refinement within single yeast artificial chromosome clones of a minimal region commonly deleted on the short arm of chromosome 7 in Wilms tumours.

Cytogenetic and molecular data indicate an involvement of genes mapped to the proximal portion of the short arm of chromosome 7 (7p) in Wilms tumours (WTs). We have analysed 38 WTs using a panel of eight microsatellite markers mapped to proximal 7p. Loss of heterozygosity (LOH) in tumour, compared with matched constitutional DNA, was identified in eight cases. To define better the minimal region commonly deleted in these tumours, they were analysed with nine additional markers, mapped within the region of interest. One tumour (case 30) showed LOH for only one marker (D7S510), while maintaining heterozygosity for the two immediately flanking loci (D7S555 and D7S668). This result was confirmed by fluorescence in situ hybridisation analysis, which showed that in the majority (65%) of nuclei from tumour 30 hybridising with a bacterial artificial chromosome clone containing the D7S510 locus, only one signal was visible. Noticeably, both markers defining the limits of the observed deleted region are simultaneously present within two distinct overlapping yeast artificial chromosome (YAC) clones mapped to chromosome bands 7p13-p14. This suggests that the maximum length of the missing DNA fragment was approximately 1.3 Mb, corresponding to the length of the smaller of the two YAC clones. In all other cases that showed LOH, the deletion encompassed the 7p13-p14 region. For this reason, we speculate that the identified interval contains a gene whose inactivation is important for the development of at least a fraction of WTs.

Low grade fibromyxoid sarcoma. a further low-grade soft tissue malignancy characterized by a ring chromosome.

Supernumerary rings in the context of a simple karyotype characterize several low-grade malignant tumors of soft tissue and bone. Low-grade fibromyxoid sarcoma is an uncommon low-grade sarcoma, the cytogenetics of which has not yet been reported. Here we describe the first molecular-cytogenetic characterization of a pulmonary metastasis of low-grade fibromyxoid sarcoma. The histology of the primary and recurrent tumors was consistent with the diagnosis of low-grade fibromyxoid sarcoma of the usual type, whereas the pulmonary metastasis was of the "giant rosettes" variant. Cytogenetic analysis revealed a ring chromosome. Because gain of material of chromosomes 7 and 16 was detected by CGH, the ring chromosome is assumed to be composed of material from these respective chromosomes.

A novel zinc finger gene is fused to EWS in small round cell tumor.

Ewing sarcoma family of tumors share recurrent translocations that fuse EWS from 22q12 to five different members of transcription factors namely FLI-1, ERG, ETV1, E1AF and FEV. Different classes of DNA binding proteins, ATF1, WT1 and CHOP are fused to EWS generating distinct tumor phenotypes: clear cell sarcoma, desmoplastic small round cell tumor, and myxoid liposarcoma, respectively. We have cloned a novel gene located at 22q12 fused to EWS by a submicroscopic inversion of 22q in a small round cell sarcoma showing a translocation (t(1;22)(p36.1;q12). The gene, designated ZSG (Zinc finger Sarcoma Gene), is a putative Cys2-His2 zinc finger protein which contains a POZ transcriptional repressor-like domain at the N-terminus. The rearrangement involves intron 8 of EWS and exon 1 of ZSG creating a chimeric sequence containing the transactivation domain of EWS fused to zinc finger domain of ZSG. This product lacks the transcriptional repressor domain at the N-terminus of ZSG. A rearrangement of the second ZSG allele was also found in tumor cells. This is the first example of an intra-chromosomal rearrangement of chromosome 22, undetectable by cytogenetics, activating EWS in soft tissue sarcoma.

Advances in cancer cytogenetics.

As the end of the millenium approaches, recognition of the milestones achieved in the field of cancer cytogenetics is mandatory. With regard to cancer cytogenetics, the turning century can be divided in three main era: the pre-banding period that has posed important hypothesis and technical premises, the fruitful banding era that led to the discovery of the critical chromosomal rearrangements and cloning of cancer genes and the more recent revolutionizing era of molecular cytogenetics where technological advances permit a global visualization and high-level resolution of chromosomal alterations. J. Cell. Biochem. Suppls. 32/33:173-182, 1999.