Whereas the p53 tumor suppressor protein plays a central role in cellular checkpoints that respond to damage or stress to prevent tumorigenesis, the transcriptional control of the p53 gene has remained unclear. We show that chemotherapeutic agents induce p53 transcription and that p73 or p53 transactivates endogenous p53 expression through direct binding to the p53 promoter. Silencing of p53 or p73 by RNA interference significantly suppresses p53 transcription under physiologic conditions or in response to cellular stress. Mutational analysis of the human p53 promoter localized a p53 DNA-binding site, which confers p53-or p73-dependent p53 promoter activation. Importantly, impaired p53-mediated autoregulation of p53 transcription by inducible-interfering RNA results in aberrant cell cycle regulation and suppression of p53-mediated apoptosis. Thus, a positive feedback loop regulates human p53 expression and involves p73 and p53. Disruption of p53 transcription contributes to defective checkpoint control. (Cancer Res 2006; 66 (14): 6982-9)

p53-dependent apoptosis is a major determinant of its tumor suppressor activity and can be triggered by hypoxia. No p53 target is known to be induced by p53 or to mediate p53-dependent apoptosis during hypoxia. We report that p53 can directly upregulate expression of Bnip3L, a cell death inducer. During hypoxia, Bnip3L is highly induced in wild-type p53-expressing cells, in part due to increased recruitment of p53 and CBP to Bnip3L. Apoptosis is reduced in hypoxia-exposed cells with functional p53 following Bnip3L knockdown. In vivo, Bnip3L knockdown promotes tumorigenicity of wild-type versus mutant p53-expressing tumors. Thus, Bnip3L, capable of attenuating tumorigenicity, mediates p53-dependent apoptosis under hypoxia, which provides a novel understanding of p53 in tumor suppression.

To identify genes responsive to cold stress, we employed the differential display mRNA analysis technique to isolate a novel gene from Tetrahymena thermophila which encodes a protein kinase of 430 amino acids. A homolog of this kinase with 90% amino acid sequence identity was also found in T. pyriformis. Both kinases contain 11 subdomains typical of protein kinases. Sequence analysis revealed that the predicted amino acid sequences resemble those of mitogen-activated protein kinase (MAPK), especially p38 and stressactivated protein kinase which are known to be involvedin various stress responses. However, it should be noted that the tyrosine residue in the normally conserved MAPK phosphorylation site (Thr-X-Tyr) is replaced by histidine (Thr226-Gly-His228) in this MAPK-related kinase (MRK). The recombinant MRK expressed in Escherichia coli phosphorylated myelin basic protein (MBP) and became autophosphorylated. However, the mutated recombinant protein in which Thr226 was replaced by Ala lost the ability to phosphorylate MBP, suggesting that Thr226 residue is essential for kinase activity. The MRK mRNA transcript in T. thermophila increased markedly upon temperature downshift from 35 to 15℃ (0.8℃/min). Interestingly, osmotic shock either by sorbitol (100-200mm) or NaCl (25-100 mM) also induced mRNA expression of the MRK in T. pyriformis. In addition, the activity of the kinase as determined by an immune complex kinase assay using MBP as a substrate was also induced by osmotic stress. This is the first demonstration of a MAPK-related kinase in the unicellular eukaryotic protozoan Tetrahymena that is induced by physical stresses such as cold temperature and osmolarity. The present results suggest that this MRK may function in the stress-signaling pathway in Tetrahymena cells.

With the intention of investigating the signal-transduction pathway that mediates the cold-stress response in Tetrahymena, we isolated a gene that encodes a novel protein kinase of 561 amino acids, termed Tetrahymena pyriformis NIMA (never-inmitosis in Aspergillus nidulans)-related protein kinase (TpNrk), by differential display from Tetrahymena cells exposed to temperature shift-down. TpNrk possesses an N-terminal protein kinase domain that is highly homologous with other NIMArelated protein kinases (Neks) involved in the control of the cell cycle. The TpNrk protein is 42%identical in its catalytic domain with human Nek2, 41% identical with mouse Nek1 and 37% with A. nidulans NIMA. In addition, TpNrk and these NIMArelated kinases have long, basic C-terminal extensions and are therefore similar in overall structure. In order to further explorethe function of the TpNrk gene and the association of the cold stress with the cell cycle of Tetrahymena, changes of TpNrk mRNA were determined during the course of the synchronous cell division induced by the intermittent heat treatment. The level of TpNrk transcription increased immediately after the end of the heat treatment, with a peak at 30min, and declined thereafter reaching the minimum level when nearly 80% of the cells synchronously entered cell division (75min after the end of heat treatment). The accumulation of TpNrk mRNA starting from 0min to 30min after the end of the heat treatment was assumed to be a prerequisite for the start of synchronous cell division. These results suggest that TpNrk may have a role in the cell cycle of Tetrahymena, and that mRNA expression, at least, is under tight cell-cycle control.