Parc: a cytoplasmic anchor for p53

Nuclear localization of p53 is essential for its tumor suppressor function. Here, we have identified Parc, a Parkin-like ubiquitin ligase, as a cytoplasmic anchor protein in p53-associated protein complexes. Parc directly interacts and forms a approximately 1 MDa complex with p53 in the cytoplasm of unstressed cells. In the absence of stress, inactivation of Parc induces nuclear localization of endogenous p53 and activates p53-dependent apoptosis. Overexpression of Parc promotes cytoplasmic sequestration of ectopic p53. Furthermore, abnormal cytoplasmic localization of p53 was observed in a number of neuroblastoma cell lines; RNAi-mediated reduction of endogenous Parc significantly sensitizes these neuroblastoma cells in the DNA damage response. These results reveal that Parc is a critical regulator in controlling p53 subcellular localization and subsequent function.     

Control of Tumor Suppressor p53 Function by Endoplasmic Reticulum Stress

Alterations in the homeostasis of the endoplasmic reticulum (ER) by various forms of stress can lead to the accumulation of unfolded proteins and protein aggregates that are detrimental to cell survival. Eukaryotic cells can adapt to ER stress by activating specific signalling pathways and mechanisms, whose primary purpose is to limit the accumulation of unfolded proteins in the ER. We recently reported a novel mechanism of cell adaptation to ER stress, which proceeds through the inhibition of the apoptotic function of the tumour suppressor p53 [Genes & Development 2004;18:261-277]. We found that ER stress increases the cytoplasmic localization and enhances the destabilization of the tumour suppressor. This process requires the phosphorylation of p53 at serine 315 and serine 376, which is mediated by the activation of glycogen synthase kinase-3beta (GSK-3?). ER stress also prevents p53 activation and p53-mediated apoptosis in response to DNA damage. These findings demonstrate that ER stress utilizes mechanisms that are distinct from other types of stress to modulate p53. In addition, they reveal that ER stress and nuclear DNA damage can induce inter-organellar cross-talk pathways targeting p53 with important implications for the treatment of tumours with dysfunctional ER.     

Control of tumor suppressor p53 function by endoplasmic reticulum stress

Alterations in the homeostasis of the endoplasmic reticulum (ER) by various forms of stress can lead to the accumulation of unfolded proteins and protein aggregates that are detrimental to cell survival. Eukaryotic cells can adapt to ER stress by activating specific signaling pathways and mechanisms, whose primary purpose is to limit the accumulation of unfolded proteins in the ER. We recently reported a novel mechanism of cell adaptation to ER stress, which proceeds through the inhibition of the apoptotic function of the tumor suppressor p53 (Genes Dev 2004;18:261-277). We found that ER stress increases the cytoplasmic localization and enhances the destabilization of the tumor suppressor. This process requires the phosphorylation of p53 at serine 315 and serine 376, which is mediated by the activation of glycogen synthase kinase-3beta (GSK-3beta). ER stress also prevents p53 activation and p53-mediated apoptosis in response to DNA damage. These findings demonstrate that ER stress utilizes mechanisms that are distinct from other types of stress to modulate p53. In addition, they reveal that ER stress and nuclear DNA damage can induce inter-organellar cross-talk pathways targeting p53 with important implications for the treatment of tumors with dysfunctional ER.     

Sequestration of p53 in the cytoplasm by adenovirus type 12 E1B 55-kilodalton oncoprotein is required for inhibition of p53-mediated apoptosis

The adenovirus E1B 55-kDa protein is a potent inhibitor of p53-mediated transactivation and apoptosis. The proposed mechanisms include tethering the E1B repression domain to p53-responsive promoters via direct E1B-p53 interaction. Cytoplasmic sequestration of p53 by the 55-kDa protein would impose additional inhibition on p53-mediated effects. To investigate further the role of cytoplasmic sequestration of p53 in its inhibition by the E1B 55-kDa protein we systematically examined domains in both the Ad12 55-kDa protein and p53 that underpin their colocalization in the cytoplasmic body and show that the N-terminal transactivation domain (TAD) of p53 is essential for retaining p53 in the cytoplasmic body. Deletion of amino acids 11 to 27 or even point mutation L22Q/W23S abolished the localization of p53 to the cytoplasmic body, whereas other parts of TAD and the C-terminal domain of p53 are dispensable. This cytoplasmic body is distinct from aggresome associated with overexpression of some proteins, since it neither altered vimentin intermediate filaments nor associated with centrosome or ubiquitin. Formation of this structure is sensitive to mutation of the Ad12 55-kDa protein. Strikingly, mutation S476/477A near the C terminus of the Ad12 55-kDa protein eliminated the formation of the cytoplasmic body. The equivalent residues in the Ad5 55-kDa protein were shown to be critical for its ability to inhibit p53. Indeed, Ad12 55-kDa mutants that cannot form a cytoplasmic body can no longer inhibit p53-mediated effects. Conversely, the Ad12 55-kDa protein does not suppress p53 mutant L22Q/W23S-mediated apoptosis. Finally, we show that E1B can still sequester p53 that contains the mitochondrial import sequence, thereby potentially preventing the localization of p53 to mitochondria. Thus, cytoplasmic sequestration of p53 by the E1B 55-kDa protein plays an important role in restricting p53 activities.     

Mitochondrial p53 mediates a transcription-independent regulation of cell respiration and interacts with the mitochondrial F₁F₀-ATP synthase

We and others previously reported that endogenous p53 can be located at mitochondria in the absence of stress, suggesting that p53 has a role in the normal physiology of this organelle. The aim of this study was to characterize in unstressed cells the intramitochondrial localization of p53 and identify new partners and functions of p53 in mitochondria. We find that the intramitochondrial pool of p53 is located in the intermembrane space and the matrix. Of note, unstressed HCT116 p53^+/+ cells simultaneously show increased O₂ consumption and decreased mitochondrial superoxide production compared with their p53-null counterpart. This data was confirmed by stable H1299 cell lines expressing low levels of p53 specifically targeted to the matrix. Using immunoprecipitation and mass spectrometry, we identified the oligomycin sensitivity-conferring protein (OSCP), a subunit of the F₁F₀-ATP synthase complex, as a new partner of endogenous p53, specifically interacting with p53 localized in the matrix. Interestingly, this interaction seems implicated in mitochondrial p53 localization. Moreover, p53 localized in the matrix promotes the assembly of F₁F₀-ATP synthase. Taking into account that deregulations of mitochondrial respiration and reactive oxygen species production are tightly linked to cancer development, we suggest that mitochondrial p53 may be an important regulator of normal mitochondrial and cellular physiology, potentially exerting tumor suppression activity inside mitochondria.     

The Wnt Target Protein Peter Pan Defines a Novel p53-independent Nucleolar Stress-Response Pathway

Proper ribosome formation is a prerequisite for cell growth and proliferation. Failure of this process results in nucleolar stress and p53-mediated apoptosis. The Wnt target Peter Pan (PPAN) is required for 45 S rRNA maturation. So far, the role of PPAN in nucleolar stress response has remained elusive. We demonstrate that PPAN localizes to mitochondria in addition to its nucleolar localization and inhibits the mitochondrial apoptosis pathway in a p53-independent manner. Loss of PPAN induces BAX stabilization, depolarization of mitochondria, and release of cytochrome c, demonstrating its important role as an anti-apoptotic factor. Staurosporine-induced nucleolar stress and apoptosis disrupt nucleolar PPAN localization and induce its accumulation in the cytoplasm. This is accompanied by phosphorylation and subsequent cleavage of PPAN by caspases. Moreover, we show that PPAN is a novel interaction partner of the anti-apoptotic protein nucleophosmin (NPM). PPAN depletion induces NPM and upstream-binding factor (UBF) degradation, which is independent of caspases. In summary, we provide evidence for a novel nucleolar stress-response pathway involving PPAN, NPM, and BAX to guarantee cell survival in a p53-independent manner.     

Mitochondrial p53 activates Bak and causes disruption of a Bak-Mcl1 complex

The tumour suppressor activity of the p53 protein has been explained by its ability to induce apoptosis in response to a variety of cellular stresses. Thus, understanding the mechanism by which p53 functions in the execution of cell death pathways is of considerable importance in cancer biology. Recent studies have indicated that p53 has a direct signalling role at mitochondria in the induction of apoptosis, although the mechanisms involved are not completely understood. Here we show that, after cell stress, p53 interacts with the pro-apoptotic mitochondrial membrane protein Bak. Interaction of p53 with Bak causes oligomerization of Bak and release of cytochrome c from mitochondria. Notably, we show that formation of the p53-Bak complex coincides with loss of an interaction between Bak and the anti-apoptotic Bcl2-family member Mcl1. These results are consistent with a model in which p53 and Mcl1 have opposing effects on mitochondrial apoptosis by interacting with, and modulating the activity of, the death effector Bak.     

High-mobility group A1 protein inhibits p53-mediated intrinsic apoptosis by interacting with Bcl-2 at mitochondria

The high-mobility group A (HMGA) proteins are a family of non-histone chromatin factors, encoded by the HMGA1 and HMGA2 genes. Several studies demonstrate that HMGA proteins have a critical role in neoplastic transformation, and their overexpression is mainly associated with a highly malignant phenotype, also representing a poor prognostic index. Even though a cytoplasmic localization of these proteins has been previously reported in some highly malignant neoplasias, a clear role for this localization has not been defined. Here, we first confirm the localization of the HMGA1 proteins in the cytoplasm of cancer cells, and then we report a novel mechanism through which HMGA1 inhibits p53-mitochondrial apoptosis by counteracting the binding of p53 to the anti-apoptotic factor Bcl-2. Indeed, we demonstrate a physical and functional interaction between HMGA1 and Bcl-2 proteins. This interaction occurs at mitochondria interfering with the ability of p53 protein to bind Bcl-2, thus counteracting p53-mediated mitochondrial apoptosis. This effect is associated with the inhibition of cytochrome c release and activation of caspases. Consistent with this mechanism, a strong correlation between HMGA1 cytoplasmic localization and a more aggressive histotype of thyroid, breast and colon carcinomas has been observed. Therefore, cytoplasmic localization of HMGA1 proteins in malignant tissues is a novel mechanism of inactivation of p53 apoptotic function.