Human chromosome 11 contains two different growth suppressor genes for embryonal rhabdomyosarcoma.

The identification of acquired homozygosity in human cancers implies locations of tumor suppressor genes without providing functional evidence. The localization of a defect in embryonal rhabdomyosarcomas to chromosomal region 11p15 provides one such example. In this report, we show that transfer of a normal human chromosome 11 into an embryonal rhabdomyosarcoma cell line elicited a dramatic loss of the proliferative capacity of the transferrants. Indeed, the majority of the viable microcell hybrids had either eliminated genetic information on the short arm of the transferred chromosome 11 or increased the copy number of the rhabdomyosarcoma-derived chromosomes 11. Cells that possessed only the long arm of chromosome 11 also demonstrated a decreased growth rate. In contrast, all microcell hybrids retained the ability to form tumors upon inoculation into animals. These functional data support molecular studies indicating loss of genetic information on chromosome 11p15 during the development of embryonal rhabdomyosarcoma. In addition, our studies demonstrate the existence of a second gene on the long arm, previously unrecognized by molecular analyses, which negatively regulates the growth of embryonal rhabdomyosarcoma cell lines.

Molecular genetics of human cancer predisposition and progression.

The development of human cancer is generally thought to entail a series of events that cause a progressively more malignant phenotype. Such a hypothesis predicts that tumor cells of the ultimate stage will carry each of the events, cells of the penultimate stage will carry each of the events less the last one and so on. A dissection of the pathway from a normal cell to a fully malignant tumor may thus be viewed as the unraveling of a nested set of aberrations. In experiments designed to elucidate these events we have compared genotypic combinations at genomic loci defined by restriction endonuclease recognition site variation in normal and tumor tissues from patients with various forms and stages of cancer. The first step, inherited predisposition, is best described for retinoblastoma in which a recessive mutation of a locus residing in the 13q14 region of the genome is unmasked by aberrant, but specific, mitotic chromosomal segregation. Similar mechanisms involving the distal short arm of chromosome 17 are apparent in astrocytic tumors and the events are shared by cells in each malignancy state. DNA sequencing indicates that these events accomplish the homozygosis of mutant alleles of the p53 gene. Copy number amplification of the epidermal growth factor receptor gene occurs in intermediate and late-stage tumors whereas loss of heterozygosity for loci on chromosome 10 is restricted to the ultimate stage, glioblastoma multiforme. These results suggest a genetic approach to defining degrees of tumor progression and the locations of genes involved in the pathway as a prelude to their molecular isolation and characterization.

Mechanisms of p53 loss in human sarcomas.

An important role for the p53 gene in neoplastic transformation in vitro and in vivo has been imputed by functional studies and identification of tumor-acquired gene defects or alterations in its expression. To study the generality and mechanisms of p53 alteration in human cancer, we examined 241 tumors of several types for structural aberrations of the locus. Alterations of the gene or its RNA or protein products consistent with loss of function by either recessive or dominant mechanisms were identified among this set uniquely in rhabdomyosarcomas and osteosarcomas. The alterations of p53 in rhabdomyosarcoma tumors included cases with complete deletion of both p53 alleles, complete deletions of one allele with or without point mutation of the remaining allele, and absence of detectable RNA. Similarly, we detected homozygous deletion and lack of expression of p53 RNA or aberrant expression of p53 protein in osteosarcomas. These observations provide strong support for the inclusion of the p53 locus in the group of loci whose functional inactivation by either dominant or recessive modes plays a significant role in human cancer.

Rhabdomyosarcoma-associated locus and MYOD1 are syntenic but separate loci on the short arm of human chromosome 11.

The MYOD1 locus is preferentially expressed in skeletal muscle and at higher levels in its related neoplasm, rhabdomyosarcoma. We have combined physical mapping of the human locus with meiotic and physical mapping in the mouse, together with synteny homologies between the two species, to compare the physical relationship between MYOD1 and the genetically ascertained human rhabdomyosarcoma-associated locus. We have determined that the myogenic differentiation gene is tightly linked to the structural gene for the M (muscle) subunit of lactate dehydrogenase in band p15.4 on human chromosome 11 and close to the p and Ldh-1 loci in the homologous region of mouse chromosome 7. Because the rhabdomyosarcoma locus maps to 11p15.5, MYOD1 is very unlikely to be the primary site of alteration in these tumors. Further, these analyses identify two syntenic clusters of muscle-associated genes on the short arm of human chromosome 11, one in the region of rhabdomyosarcoma locus that includes IGF2 and TH and the second the tightly linked MYOD1 and LDHA loci, which have been evolutionarily conserved in homologous regions of both the mouse and the rat genomes.

Loss of genetic information in cancer.

The determination and comparison of genotypic combinations at genomic loci in normal and tumour tissues from patients with various types of cancer have defined the chromosomal locations of loci at which recessive mutations play a role in disease. The predisposing nature of some of these mutant alleles is exemplified in studies of retinoblastoma and osteogenic sarcoma. These two clinically associated diseases share a pathogenetically causal predisposition that maps to chromosome position 13q14. A similar mechanism at 11p15.5 is involved in the development of the embryonal variant of rhabdomyo-sarcoma, Wilms' tumour and hepatoblastoma. Finally, genomic alteration of chromosome 10 is apparent in glioblastomas and mixed tumours of glioblastoma/astrocytoma grade III but not in homogenous astrocytoma grades II or III, suggesting the definition of a locus involved in tumour progression and, perhaps, an approach to molecular genetic staging of tumours.

Chromosomal localization of the human rhabdomyosarcoma locus by mitotic recombination mapping.

A genetic description of the human genome requires maps of three types. The first shows the frequency of chromosomal interchange during meiosis, relying on many equally spaced markers, and is limited to interchanges that do not unmask defects lethal to the conceptus, whose every cell will contain such abnormalities. The second is the physical description of genomic regions defined by karyotypic rearrangements, DNA segments, genes, or their products. A third description of somatic chromosomal interchanges at mitosis is also required. Because mitotic exchanges occur in a single postembryonic somatic progenitor cell, lethal effects on the organism are reduced. These events have been important in genetic mapping in Drosophila melanogaster and fungi, but they have rarely been detected in mammals. Here we report a significant frequency of mitotic recombination in human tumours and the first application of this information in localizing their predisposing locus.