Effect of inactivating various components of the signal pathways of the tumor suppressor p53 on genomic stability

To evaluate the role of different p53-regulated signaling pathways in the control of genomic integrity, we studied the frequency of changes in chromosome number and structure of cells of the sublines of mouse primary embryonic fibroblasts with the "knocked-out" genes for proteins p53, p21WAF, pRb, and p19ARF. Protein p21WAF is transactivated by p53 and is responsible for the cell block in the G1 phase of the damaged cells; protein pRb is a target for p21WAF which controls the G1-S-phase transition; and p19ARF protein is responsible for p53 activation in cells with certain anomalies. Inactivation of either of the studied genes proved to increase significantly the frequency of changes in the karyotype. However, the resultant chromosome instability differed: the frequency of the chromosome breaks, both spontaneous and induced with ethylmethane sulfonate (EMS), was in cells with inactivated p53 and lowest in cells with inactivated pRb. These distinctions were not caused by a different effect of various gene inactivation on the cell cycle progression: in all sublines, the cell block in G1 was abolished and the checkpoint function in G2 remained normal. However, the induction of apoptosis in EMS-treated cells differed in the studied sublines. The lowest number of apoptotic nuclei were determined in p53-/- cultures, whereas the highest were in the Rb-/- cultures. It is apparent that the degree of genetic instability is determined by a combined effect of apoptosis and abnormal regulation of the cell-cycle checkpoints.