Pathways for activation of the ras-oncogene-encoded p21 protein

Abstract

The ras-oncogene-encoded p21 protein is known to cause a large number of human tumors. This protein differs from its normal counterpart protein, which is present in all eukaryotic cells, in that it contains a single amino acid substitution at critical positions in the polypeptide chain, such as at Gly 12, Gly 13, Ala 59, and Gln 61. Using computer-based molecular modeling, it has been found that one region of this protein that is a candidate for interacting with other intracellular proteins is the region from residues 35 to 47. In oocyte microinjection experiments, it was found that this peptide strongly inhibits the mitogenic effects of oncogenic (Val 12-containing)p21 but does not inhibit the cellular effects of activation of normal p21 protein. Furthermore, it has been shown that the cellular effects of oncogenic p21 protein can be completely inhibited by selectively blocking protein kinase C (PKC) with a highly specific inhibitor of this protein, CGP 41 251, a staurosporine derivative. This inhibitor, however, only weakly inhibits the effects of normal cellular ras-p21 protein. In addition, a photoaffinity-labeled p21 protein has been microinjected into NIH 3T3 fibroblasts and have isolated intracellular proteins of MW 35, 43 and 61 kda covalently bound to it. The 43 kda protein is the major one and appears to be critical to the functioning of the p21 protein. Our results suggest that oncogenic and normal p21 proteins utilize overlapping but distinct pathways; the oncogenic pathway can be blocked selectively and requires the activation of PKC and the presence of the 43 kda protein.