Accumulation of genetic defects during astrocytoma progression

Abstract

Background: The development of human cancer generally is thought to entail a series of events that cause a progressively more malignant phenotype. This 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 minus the last one; and so on. Therefore, a dissection of the pathway from a normal cell to a fully malignant tumor may be viewed as the unraveling of a nested set of aberrations.

Methods: In experiments designed to elucidate these events, genotypic combinations were compared at genomic loci defined by restriction endonuclease recognition-site variations in normal and tumor tissues from patients with various forms and stages of cancer.

Results: The first step, inherited predisposition, is described best for retinoblastomas 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. A similar mechanism involving the distal short arm of chromosome 17 is apparent in astrocytic tumors, and the event is shared by cells in each malignant stage. This is distinct from a loss of heterozygosity for loci on chromosome 10, which is restricted to the ultimate stage, glioblastoma multiforme. In addition, this approach has been extended to include a wide variety of human cancers, and generally it is applicable.

Conclusions: These results identify a genetic approach to defining degrees of tumor progression and a means for determining the genomic locations of genes involved in the pathway as a prelude to their molecular isolation and characterization. They provide a molecular genetic-based oncology with clinical utility in differential pathologic findings, in disease groupings for therapeutic purposes, and in prenatal identification of latent disease carriers.