p53-dependent expression of PIG3 during proliferation, genotoxic stress, and reversible growth arrest.

The p53-inducible gene 3 (PIG3) was recently identified in a screen for genes induced by p53 before the onset of apoptosis. PIG3 shares significant homology with oxidoreductases from several species. In this study, PIG3-specific antibodies were used to analyze cellular PIG3 protein levels under control and genotoxic stress conditions. PIG3 protein was localized to the cytoplasm and induced in primary, non-transformed, and transformed cell cultures after exposure to genotoxic agents. The induction of PIG3 was p53-dependent and occurred with delayed kinetics as compared with other p53 downstream targets, such as p21 and MDM2. Using a p53-inducible cell model system, in which p53-mediated growth arrest is reversible, we found that PIG3 levels were increased during p53-mediated growth arrest. Interestingly, elevated levels of PIG3 were maintained in cells that resumed cycling in the absence of ectopic p53 expression, suggesting that PIG3 is a long-lived reporter, which may be useful for detecting transient activation of p53.

p53 regulation of G(2) checkpoint is retinoblastoma protein dependent.

In the present study, we investigated the role of p53 in G(2) checkpoint function by determining the mechanism by which p53 prevents premature exit from G(2) arrest after genotoxic stress. Using three cell model systems, each isogenic, we showed that either ectopic or endogenous p53 sustained a G(2) arrest activated by ionizing radiation or adriamycin. The mechanism was p21 and retinoblastoma protein (pRB) dependent and involved an initial inhibition of cyclin B1-Cdc2 activity and a secondary decrease in cyclin B1 and Cdc2 levels. Abrogation of p21 or pRB function in cells containing wild-type p53 blocked the down-regulation of cyclin B1 and Cdc2 expression and led to an accelerated exit from G(2) after genotoxic stress. Thus, similar to what occurs in p21 and p53 deficiency, pRB loss can uncouple S phase and mitosis after genotoxic stress in tumor cells. These results indicate that similar molecular mechanisms are required for p53 regulation of G(1) and G(2) checkpoints.

Mechanisms of cell-cycle checkpoints: at the crossroads of carcinogenesis and drug discovery.

Human tumors arise from multiple genetic changes that gradually transform growth-limited cells into highly invasive cells that are unresponsive to growth controls. The genetic evolution of normal cells into cancer cells is largely determined by the fidelity of DNA replication, repair, and division. Cell-cycle arrest in response to stress is integral to the maintenance of genomic integrity. The control mechanisms that restrain cell-cycle transition or induce apoptotic signaling pathways after cell stress are known as cell-cycle checkpoints. This review will focus on the mechanisms of cell-cycle checkpoint pathways and how different components of these pathways are frequently altered in the genesis of human tumors. As our knowledge of cell-cycle regulation and checkpoints increases, so will our understanding of how xenobiotic agents can affect these processes to either initiate or inhibit tumorigenesis.

Differential cell cycle checkpoint response in normal human keratinocytes and fibroblasts.

The incidence of DNA mutation and subsequent risk of transformation in different cell types may depend on cell type-specific variation in position and duration of cell cycle arrest after exposure to DNA-damaging agents. To determine whether cell type-specific checkpoints occur, normal human epidermal keratinocytes (HKs) and human dermal fibroblasts (HFs), isolated from the same tissue, were exposed to genotoxic agents. Following exposure, cell cycle arrest profiles, cell proliferation rates, and select protein levels and activities were analyzed and found to be cell type dependent. After exposure to either gamma-radiation or Adriamycin, HFs arrested primarily in G1, whereas HKs arrested predominantly in G2. The attenuated G1 arrest in the HKs correlated with less p53 protein accumulation, as compared to that observed in G1-arrested HFs. Although gamma-irradiated HFs were unable to reenter the cell cycle, HKs began proliferating 72 h posttreatment. Consistent with the cell cycle profiles observed, cyclin-dependent kinase activities were inhibited for a longer duration in HFs as compared to HKs after gamma-irradiation. The results indicate that cell cycle checkpoint response to genotoxic insult may vary according to cell type within any given tissue. The attenuated G1 arrest observed in HKs may be an important factor in the transforming events leading to skin neoplasia.