UNIPARENTAL ORIGIN OF I(12P) IN HUMAN GERM-CELL TUMORS

We present molecular data to demonstrate that the isochromosome 12p, specific for human germ cell tumors (GCTs), is of uniparental origin. Eight GCT-derived cell lines, containing one or more copies of i(12p) and/or other 12p anomalies, were analyzed with different 12p-derived polymorphic markers. The results from Ma-90, a near-diploid cell line with only one i(12p) in addition to two copies of a normal chromosome 12, clearly show an allelic 12p ratio of approximately 3:1, indicating that both 12p arms are of identical parental origin. These results were further substantiated by data obtained from the other i(12p)-positive GCT-derived cell lines. Therefore, we conclude that the i(12p) in GCTs constitutes a genuine isochromosome with genetically identical arms. The isochromosome most likely originates from a misdivision of the centromere rather than from a translocation or a non-sister chromatid exchange as proposed by others. We also found that supernumerary 12p copies, as observed in i(12p)-negative GCTs, are of uniparental origin. These observations seem to point to an important role for certain 12p-derived sequences in the development of human GCTs

VERIFICATION OF ISOCHROMOSOME-12P AND IDENTIFICATION OF OTHER CHROMOSOME-12 ABERRATIONS IN GONADAL AND EXTRAGONADAL HUMAN GERM-CELL TUMORS BY BICOLOR DOUBLE FLUORESCENCE INSITU HYBRIDIZATION

A diverse group of gonadal and extragonadal human germ cell tumors (GCT) and GCT-derived cell lines was examined for the presence of an i(12p) marker chromosome and/or other abnormalities involving chromosome 12, especially 12p, by bicolor double fluorescence in situ hybridization (FISH). For this purpose three probes, pBS-12, M28, and palpha12H8, were used, allowing specific identification of the entire chromosome 12, its short arm, and its pericentromeric region, respectively. The presence of one or more copies of a genuine i(12p) chromosome could be demonstrated in three GCT of the testis, in one ovarian GCT, in one dysgenetic GCT, and in one extragonadal intracranial GCT. Moreover, additional aberrations involving chromosome 12 were shown to be present not only in i(12p) minus but also in i(12p) positive GCT. These data suggest that the occurrence of such aberrations may be a common, although less clearly perceptible and frequent, phenomenon in human GCT

Comparative genomic hybridization of germ cell tumors of the adult testis: Confirmation of karyotypic findings and identification of a 12p-amplicon

Comparative genomic hybridization (CGH) was carried out on 15 primary testicular germ cell tumors (TGCT) of adolescents and adults and two metastatic residual tumors after chemotherapeutic treatment. The results were compared with karyotypic data obtained form the same tumor specimens after direct harvesting of metaphases or short-term in vitro culture. Both techniques revealed that the most consistent abnormality in primary TGCT is gain of 12p-sequences. Although in most cases overrepresentation of the complete short arm was observed, CGH revealed a specific amplification of 12p11.1-p12.1 region in two independent primary tumors. In addition, loss of (parts of) chromosome 13 (always involving q31-qter), and gain of (parts of) chromosome 7 (mostly involving q11), (parts of) chromosome 8, and the X chromosome were detected in more than 25% of the rumors by this latter technique. Loss of 6q15-q21 in both residual tumors analyzed may suggest a role for this anomaly in acquired resistance to chemotherapeutic treatment. Overall, the CGH analyses confirmed gains and losses of certain chromosomal regions in TGCT as observed by karyotyping, and thus support their role in the development of these neoplasms. The amplification of a restricted region of 12p in primary TGCT confirms and extends our previous observations and, as such, represents an important step forward in the identification of gene(s) on 12p relevant far the pathogenesis of these tumors

A SYNOVIAL SARCOMA WITH A COMPLEX T(X/18/5/4) AND A BREAK IN THE ORNITHINE AMINOTRANSFERASE (OAT)LI CLUSTER ON XP11.2

The initial cytogenetic analysis of a biphasic synovial sarcoma revealed complex anomalies involving six different chromosomes: 46,Y,t(X;18;5;4)(p11;q11;p13;q12),t(2;5)(q35;q11). After fluorescence in situ hybridization (FISH) analysis, using chromosome X-specific plasmid library and YAC probes, the situation appeared to be even more complex, with an insertion of part of the X chromosome short arm into the der(5)t(5;18). In spite of these complex chromosomal rearrangements, the Xp11 breakpoint could be mapped to within the ornithine aminotransferase (OAT)L1 cluster, very similar to that reported previously for the standard t(X;18)(p11;q11) in synovial sarcomas. These findings suggest common pathogenetic pathways in these cytogenetically different but morphologically similar tumors. (C) 1994 Wiley-Liss, Inc