Effect of p21waf1/cip1 transgene on radiation induced apoptosis in T cells.

The cyclin kinase inhibitor p21WAF1/Cip1 is upregulated by the tumor suppressor p53. While p21 is central for the G-1 arrest mediated by p53, it is still unclear if p21 also functions as a downstream effector of p53 dependent apoptosis. Apoptosis induced by DNA damage but not dexamethasone is p53 dependent in thymocytes. To investigate the physiological role of p21 in apoptosis, we have generated transgenic mice in which the p21 transgene is targeted for restricted expression in the T cell lineage. Thymocytes from p21 transgenic mice were hypersensitive to cell death induced by DNA damaging agents such as ionizing radiation and UV, but not be dexamethasone. Irradiated p21 transgenic thymocytes had approximately twofold more apoptotic cells as compared to irradiated age matched littermate control mice. Radiation induced death is comparable in thymocytes from p21 + Bcl2 + double transgenic mice and age matched littermate controls, indicating that the Bcl2 transgene rescues the radiation hypersensitivity imposed by p21. However, thymocytes from p53-/- mice even when they expressed the p21 transgene, were resistant to death induced by radiation. Together these results show that thymocytes from p21 transgenic mice are hypersensitive to radiation induced programmed cell death and suggest that the radiation hypersensitivity of p21 transgenic thymocytes involves p53 dependent pathway and signals in addition to p21.

Role for cyclin A-dependent kinase in DNA replication in human S phase cell extracts.

Cell cycle progression is regulated by cyclin-dependent kinases. Using in vitro replication of SV40 origin containing DNA as a model system, we have performed a detailed analysis of the dependence on cyclin-associated kinases of mammalian DNA replication. Complete immunodepletion of cyclin A from human S phase cell extracts decreases replication, and replication activity of cyclin A-depleted S phase extracts can subsequently be restored by the addition of purified CDK2-cyclin A kinase. Addition of cyclin A alone reconstitutes both kinase activity and DNA replication, whereas addition of cyclin E or cyclin B reconstitutes neither. We therefore conclude that reconstitution of DNA replication specifically correlates with an increase in kinase activity. By comparison, depletion of cyclin E from S phase cell extracts does not have any significant inhibitory effect on DNA replication. Moreover, specific p21(Waf1) mutants that bind to CDK2-cyclin and inhibit both cyclin A and cyclin E kinase activities, but do not bind to proliferating cell nuclear antigen, inhibit DNA replication to the same extent as cyclin A depletion. Together, these results show that the kinase activity associated with cyclin A, but not with cyclin E, is primarily responsible for activating SV40 plasmid replication in mammalian S phase cell extracts. Finally, we present evidence that the cyclin-dependent kinase does not influence the assembly of initiation complexes but acts at a stage prior to elongation.

A conserved domain of the large subunit of replication factor C binds PCNA and acts like a dominant negative inhibitor of DNA replication in mammalian cells.

Replication factor C (RF-C), a complex of five polypeptides, is essential for cell-free SV40 origin-dependent DNA replication and viability in yeast. The cDNA encoding the large subunit of human RF-C (RF-Cp145) was cloned in a Southwestern screen. Using deletion mutants of RF-Cp145 we have mapped the DNA binding domain of RF-Cp145 to amino acid residues 369-480. This domain is conserved among both prokaryotic DNA ligases and eukaryotic poly(ADP-ribose) polymerases and is absent in other subunits of RF-C. The PCNA binding domain maps to amino acid residues 481-728 and is conserved in all five subunits of RF-C. The PCNA binding domain of RF-Cp145 inhibits several functions of RF-C, such as: (i) in vitro DNA replication of SV40 origin-containing DNA; (ii) RF-C-dependent loading of PCNA onto DNA; and (iii) RF-C-dependent DNA elongation. The PCNA binding domain of RF-Cp145 localizes to the nucleus and inhibits DNA synthesis in transfected mammalian cells. In contrast, the DNA binding domain of RF-Cp145 does not inhibit DNA synthesis in vitro or in vivo. We therefore conclude that amino acid residues 481-728 of human RF-Cp145 are critical and act as a dominant negative mutant of RF-C function in DNA replication in vivo.

p21 contains independent binding sites for cyclin and cdk2: both sites are required to inhibit cdk2 kinase activity.

Cyclin dependent kinases regulate the progression of eukaryotic cells through the cell cycle. p21Cip1/Waf1/Sdi1 is an inhibitor of cdk-cyclin kinase activity, and has been shown to form complexes with cdk-cyclins and with PCNA, an accessory protein of DNA polymerase delta. The kinase inhibitory domain maps to the N-terminus (1-82) and contains the cdk2 binding site (28-82). We have generated a panel of deletion mutants of p21. A functional characterization of p21 mutants in the N-terminal domain reveals that cyclins bind to this domain independently of cdk2. Correlating with these results we find that p21 can associate with cyclin-cdk kinases in two functionally distinct forms, one in which the kinase activity is inhibited and the other in which the kinase is still active. The cdk2 and cyclin binding sites on p21 are both required to inhibit kinase activity. The second type of interaction, in which an active cyclin-cdk complex only interacts with p21 either via the cyclin or the cdk2 binding site but not through both, does not lead to inhibition of cyclin kinase activity. These results thus provide a basis for understanding the mechanism by which p21, and perhaps other cdk-cyclin kinase inhibitory proteins, suppress kinase activity.