Malignant transformation of human diploid fibroblasts and suppression of their anchorage independence by introduction of chromosome 13.

Abstract

Isolation of cell lines that display various degrees of transformed phenotypes may be very useful to clarify multistep mechanisms of oncogenesis, but malignant transformation of human diploid fibroblasts in culture is a very rare event. We attempted to isolate variously transformed cell lines from human diploid fibroblasts (RB) of a patient with hereditary retinoblastoma. The RB cells exhibited normal karyotypes with the exception of one copy of chromosome 13, which contained a large deletion at the q14-22 region, where the RB1 gene is located. By transfection with SV40 early genes and repeated passage, we succeeded in obtaining SV40-transfected mortal, immortalized, anchorage-independent, and tumorigenic RB cell lines. DNA fingerprinting showed that these cell lines were not contaminants, but derivatives of the original RB cells. The remaining RB1 allele may be wild-type even in the malignant cell lines, because the expression and the LT-binding ability were normal. Furthermore, we did not find any homozygous loss in 16 polymorphic markers located in the 13q14-22 region in the transformed cell lines. However, introduction of a copy of a normal chromosome 13 into the anchorage-independent cell line suppressed its anchorage-independent growth ability. All these data, together with the fact that the RB cells containing the deletion progressed to a tumorigenic state spontaneously, but normal fibroblasts did not, raise the possibility that a new tumor suppressor gene, located at 13q14-22, may play a critical role in neoplastic transformation. We conclude that these RB cell lines provide an excellent system for identification of genes involved in malignant transformation of human cells. Genes Chromosomes Cancer 26:47-53, 1999.