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.     

Apoptosis factor EI24/PIG8 is a novel endoplasmic reticulum-localized Bcl-2-binding protein which is associated with suppression of breast cancer invasiveness

p53 is a critical tumor suppressor which removes cells with DNA damage by regulating expression and activity of a select group of p53-induced genes (PIG) that subsequently induce apoptosis. PIG8 was also identified as a gene induced by etoposide and named etoposide-induced gene 24 (EI24). Later experiments established EI24/PIG8 as a proapoptotic factor and suggested that it may function as a tumor suppressor. Indeed, EI24/PIG8 is relatively highly mutated in aggressive breast cancers and is located in a region which expresses frequent loss of heterozygosity. However, despite these important observations, the activity and role of EI24/PIG8 remain largely unknown. We used (immmuno)fluorescence microscopy and subcellular fractionation techniques to show that EI24/PIG8 is localized in the endoplasmic reticulum (ER). Pull-down experiments showed that it specifically binds with Bcl-2, a death regulator known to reside in mitochondria, ER, and the nuclear envelope. EI24/PIG8-Bcl-2 binding was corroborated by coimmunoprecipitation and other in vitro and in vivo protein-protein binding assays. Further analysis showed that EI24/PIG8 uses its N-terminal region to bind the BH3 domain in Bcl-2. Finally, we used immunohistochemical techniques to analyze expression of EI24/PIG8 in breast cancer tissue progression arrays and showed that loss of EI24/PIG8 is associated with tumor invasiveness but not with the development of the primary tumor. These results suggest that EI24/PIG8 is a novel, ER-localized Bcl-2-binding protein which may contribute to apoptosis by modulating the activity and/or function of Bcl-2 in this organelle. EI24/PIG8 may serve to prevent tumor spreading, consistent with its suspected role as a tumor suppressor.     

PCTAIRE3: a putative mediator of growth arrest and death induced by CTS-1, a dominant-positive p53-derived synthetic tumor suppressor, in human malignant glioma cells

Chimeric tumor suppressor-1 (CTS-1) is based on the sequence of p53 and was designed as a therapeutic tool resisting various mechanisms of p53 inactivation. We previously reported that an adenovirus expressing CTS-1 (Ad-CTS-1) has superior cell death-inducing activity in glioma cells compared with wild-type p53. Here, we used cDNA microarrays to detect changes in gene expression preferentially induced by Ad-CTS-1. The putative serine threonine kinase, PCTAIRE3, and the quinone oxireductase, PIG3, were strongly induced by Ad-CTS-1 compared with wild-type p53. An adenoviral vector encoding PCTAIRE3 (Ad-PCTAIRE3) induced growth arrest and killed a minor proportion of the glioma cells. Ad-PIG3 alone affected neither growth nor viability. However, coinfection with Ad-PCTAIRE3 and Ad-PIG3 resulted in enhanced growth inhibition compared with Ad-PCTAIRE3 infection alone. Ad-CTS1, Ad-PCTAIRE3 or Ad-PIG3 induced the formation of free reactive oxygen species (ROS). However, the prevention of ROS formation induced by Ad-PCTAIRE3 and Ad-CTS-1 did not block growth arrest and cell death, suggesting that ROS formation is not essential for these effects. Altogether, these data identify PCTAIRE3 as one novel growth-inhibitory and death-inducing p53 response gene and suggest that changes in the expression of specific target genes contribute to the superior anti-glioma activity of CTS-1.     

High frequency in esophageal cancers of p53 alterations inactivating the regulation of genes involved in cell cycle and apoptosis

Somatic mutations of the tumor suppressor gene p53 have been frequently detected in esophagal cancers, but their biological significance remains to be established. The tumor suppressor activity of p53 results in part from its ability to transactivate genes involved in the cell cycle and apoptosis, such as p21, bax and PIG3, and some p53 mutations may have a differential effect on the transactivation of these target genes. We developed yeast strains in which the activation by wild-type p53 of reporter plasmids containing p53 binding sites present within these target genes induces a change in the color of the colonies (red/white). Using these strains, we analyzed 56 esophageal cancers from patients residing in Normandy, France, a high incidence geographic area. Forty-seven tumors (84%), scored as mutant with the p21, bax and PIG3 reporter strains and in most of the cases (76%), the percentage of red colonies suggested that both p53 alleles were inactivated. Sequencing analysis allowed the identification of a p53 mutation in each positive sample, and the spectrum of mutations was in agreement with the etiological role of tobacco and alcohol. These results confirm the high frequency of biallelic p53 mutations in esophageal carcinoma and strongly suggest that their biological consequence is the complete alteration of the transactivation of genes involved in the cell cycle and apoptosis, which indicates that p53 alteration is a key event in esophagus carcinogenesis.     

Differential involvement of reactive oxygen species in apoptosis induced by two classes of selenium compounds in human prostate cancer cells

Selenium is a promising chemopreventive agent for prostate cancer, possibly via an induction of apoptosis. Earlier studies have shown that selenite induces DNA single strand breaks (SSBs), reactive oxygen species (ROS), p53 Ser‐15 phosphorylation and caspase‐dependent and ‐independent apoptosis, whereas a methylselenol precursor methylseleninic acid (MSeA) induces caspase‐mediated apoptosis regardless of p53 status. Here we address three main questions: What types of ROS are induced by selenite vs. MSeA in LNCaP (p53 wild type, androgen‐responsive) and DU145 (mutant p53, androgen‐independent) prostate cancer cells? Does ROS generation depend on androgen signaling? What are the relationships among ROS, DNA SSBs, p53 and caspases? We show that selenite (5 μM) induced superoxide and hydrogen peroxide in LNCaP cells much more than in DU145 cells and the ROS generation was not affected by physiological androgen stimulation. MSeA (10 μM) induced apoptosis without either type of ROS in both cell lines. In LNCaP cells, we established superoxide as a primary mediator for selenite‐induced DNA SSBs, p53 activation and caspase‐mediated apoptosis. Furthermore a p53‐dominant negative mutant attenuated selenite‐induced ROS, leading to a proportionate protection against apoptosis. The results support the p53‐mitochondria axis in a feedback loop for sustaining superoxide production to lead to efficient caspase‐mediated apoptosis by selenite. In contrast, caspase‐mediated apoptosis induced by MSeA does not involve ROS induction. Since p53 is frequently mutated or deleted in prostate cancer and many other cancers, our results suggest that genotoxic vs. nongenotoxic classes of selenium may exert differential apoptosis efficacy depending on the p53 status of the cancer cells. © 2007 Wiley‐Liss, Inc.     

In vivo analyses of UV-irradiation-induced p53 promoter binding using a novel quantitative real-time PCR assay

The p53 tumor suppressor protein mediates cell cycle arrest and apoptosis through transactivation of downstream target genes. While many target genes have been identified to date, the mechanisms and time course of their induction are still unclear. We investigated the kinetics of p53 binding to the p21CIP1, MDM2, BAX and PIG3 promoters in vivo using a novel quantitative real-time chromatin immunoprecipitation-PCR assay. Our results demonstrate distinct kinetics of p53 promoter binding dependent on the target gene promoters. The timed induction of target genes due to genotoxic stress is likely to play a pivotal role for the divergent functions of p53.     

Differential regulation of cellular target genes by p53 devoid of the PXXP motifs with impaired apoptotic activity.

Activation of the p53 tumor suppressor protein can lead to either cell cycle arrest or apoptosis. Several functional domains necessary for mediating cell cycle arrest and apoptosis in p53 have been mapped, e.g., the proline-rich domain. The proline-rich domain is located within residues 60-90, which comprise five PXXP motifs (where P represents proline and X any amino acid). To further delineate the function of the proline-rich domain and its potential role in transactivation, we generated several groups of cell lines that inducibly express various p53 mutants using a tetracycline-regulated expression system. We found that p53(delta62-91), which lacks all five PXXP motifs in human p53, is capable of inducing cell cycle arrest but not apoptosis, while p53(gln22-ser23/delta62-91), which contains a double point mutation in the activation domain as well as deletion of the proline-rich domain, completely loses its activity. However, p53(delta74-91), which contains only one PXXP motif at its N-terminus, is not only capable of inducing cell cycle arrest but also retains a partial apoptotic activity. Furthermore, we found that deletion of the proline-rich region has no or very mild effects on activation of several transiently transfected p53 target gene promoters, i.e., the p21, MDM2, BAX, and GADD45 promoters. However, such deletion differentially affects p53 induction of endogenous target genes, i.e., induction of p21, MDM2, BTG2, p85, PIG3, PIG6 and PIG11 was reduced or abrogated but induction of BAX, KILLER/DR5, PIG2, PIG7 and PIG8 was not substantially affected. Interestingly, induction of GADD45 was enhanced. These results suggest that the proline-rich region may play a role in chromatin remodeling, which counteracts chromatin-mediated repression for some of the endogenous p53 target genes.     

Proline oxidase, encoded by p53-induced gene-6, catalyzes the generation of proline-dependent reactive oxygen species

The p53-dependent initiation of apoptosis is accompanied by the induction of proline oxidase (POX), a mitochondrial enzyme catalyzing the conversion of proline to pyrroline-5-carboxylate with the concomitant transfer of electrons to cytochrome c. However, the contribution of increased POX activity to apoptosis, if any, remains unknown. Using Adriamycin to initiate p53-dependent apoptosis, we showed that the expression of POX is up-regulated in a time- and dose-dependent manner in a human colon cancer cell line (LoVo). In cells expressing POX, the addition of proline increases reactive oxygen species (ROS) generation in a concentration-dependent manner; glutamate, a downstream product of proline oxidation, had no effect. Induction of POX was dependent on the p53 status of the cell. In the conditionally immortalized murine colonic epithelial cell line YAMC, where the p53 phenotype can be modulated by temperature, proline oxidase expression and ROS production could only be induced when the cells were phenotypically p53-positive. To confirm that the observed ROS production was not secondary to some other effect of p53, we also conditionally expressed POX in a p53-negative colon cancer line. Again, we found a proline-dependent ROS increase with POX expression. We hypothesize that proline oxidation supports the generation of ROS by donating reducing potential to an electron transport chain altered either by p53-dependent mechanisms or by overexpression of POX.