p300/CBP-mediated p53 acetylation is commonly induced by p53-activating agents and inhibited by MDM2

The tumor suppressor p53 is activated in response to many types of cellular and environmental insults via mechanisms involving post-translational modification. Here we demonstrate that, unlike phosphorylation, p53 invariably undergoes acetylation in cells exposed to a variety of stress-inducing agents including hypoxia, anti-metabolites, nuclear export inhibitor and actinomycin D treatment. In vivo, p53 acetylation is mediated by the p300 and CBP acetyltransferases. Overexpression of either p300 or CBP, but not an acetyltransferase-deficient mutant, efficiently induces specific p53 acetylation. In contrast, MDM2, a negative regulator of p53, actively suppresses p300/CBP-mediated p53 acetylation in vivo and in vitro. This inhibitory activity of MDM2 on p53 acetylation is in turn abrogated by tumor suppressor p19(ARF), indicating that regulation of acetylation is a central target of the p53-MDM2-p19(ARF) feedback loop. Functionally, inhibition of deacetylation promotes p53 stability, suggesting that acetylation plays a positive role in the accumulation of p53 protein in stress response. Our results provide evidence that p300/CBP-mediated acetylation may be a universal and critical modification for p53 function.     

Over-expression of the human MDM2 p53 binding domain by fusion to a p53 transactivation peptide

MDM2 binds to the tumor suppressor protein p53 and regulates the level of p53 in cells. Although it is possible to prepare a small amount of the region of MDM2 that binds to p53, the expression level of this fragment of MDM2 is relatively low, limiting the studies involving this protein. Here, we describe a construct for the optimized bacterial expression and purification of the MDM2 p53 binding domain. We found that the expression level of the soluble MDM2 p53 binding domain in bacteria was increased dramatically by fusing it to its interaction partner, the p53 transactivation peptide. Attachment of the p53 transactivation peptide (residues 17-29) to the N-terminus of MDM2 resulted in a more than 200-fold increase of soluble protein expression of the p53 binding domain in bacteria. To obtain the final MDM2 p53 binding domain (residues 5-109) we inserted a tobacco etch virus protease recognition site between the P53 peptide and the MDM2 p53 binding domain. To weaken the protein/peptide interaction and facilitate the separation of the protein from the complex, we introduced a point mutation of one of the key interaction residues (F19A or W23A) in the p53 peptide. The advantages of our new construct are high yield and easy purification of the MDM2 protein.     

Activation of targeted necrosis by a p53 peptide: a novel death pathway that circumvents apoptotic resistance

Cancer cells escape apoptosis by intrinsic or acquired mechanisms of drug resistance. An alternative strategy to circumvent resistance to apoptosis could be through redirection into other death pathways, such as necrosis. However, necrosis is a nonspecific, nontargeted process resulting in cell lysis and inflammation of both cancer and normal cells and is therefore not a viable alternative. Here, we report that a C-terminal peptide of p53, called p53p-Ant, induced targeted necrosis only in multiple mutant p53 human prostate cancer lines and not normal cells, because the mechanism of cytotoxicity by p53p-Ant is dependent on the presence of high levels of mutant p53. Topotecan- and paclitaxel-resistant prostate cancer lines were as sensitive to p53p-Ant-induced targeted necrosis as parental lines. A massive loss of ATP pools and intracellular generation of reactive oxygen species was involved in the mechanism of targeted necrosis, which was inhibited by O(2)(.) scavengers. We hypothesize that targeted necrosis by p53p-Ant is dependent on mutant p53, is mediated by O(2)(.) loss and ATP, and can circumvent chemotherapy resistance to apoptosis. Targeted necrosis, as an alternative pathway for selective killing of cancer cells, may overcome the problems of nonspecificity in utilizing the necrotic pathway.     

Design of a novel MDM2 binding peptide based on the p53 family

p53 is a major tumor suppressor protein, that binds to, and is negatively regulated by MDM2. In tumors over expressing MDM2, p53 function can be rescued through the disruption of the MDM2-p53 interactions by small molecules and peptides. It is known that MDM2 also binds p73 but not p63, the two homologues of p53. We dissect the structural and energetic reasons underlying this discrimination and have identified a peptide that is intrinsically less helical than p53 and yet has a higher affinity for MDM2. The increased disorder has been introduced by localizing a cationic residue in between two anionic residues, imparting a degree of frustration to the system. In addition, the introduction of a bulkier hydrophobic group towards the centre of the peptide enables the peptide to adapt a bound conformation that on the one hand is most strained, and yet enables the peptide to straddle the largest surface of MDM2, amongst all the peptides. Computations also reveal that this peptide is a dual inhibitor, binding to MDMX. The computed affinity of the new peptide has been validated against MDM2 using fluorescence-based thermal shift assays.     

Activation of p53-dependent responses in tumor cells treated with a PARC-interacting peptide

We tested the activity of a p53 carboxy-terminal peptide containing the PARC-interacting region in cancer cells with wild type cytoplasmic p53. Peptide delivery was achieved by fusing it to the TAT transduction domain (TAT-p53-C-ter peptide). In a two-hybrid assay, the tetramerization domain (TD) of p53 was necessary and sufficient to bind PARC. The TAT-p53-C-ter peptide disrupted the PARC-p53 complex. Peptide treatment caused p53 nuclear relocation, p53-dependent changes in gene expression and enhancement of etoposide-induced apoptosis. These studies suggest that PARC-interacting peptides are promising candidates for the enhancement of p53-dependent apoptosis in tumors with wt cytoplasmic p53.     

p53DINP1, a p53-inducible gene, regulates p53-dependent apoptosis

Using the differential display method combined with a cell line that carries a well-controlled expression system for wild-type p53, we isolated a p53-inducible gene, termed p53DINP1 (p53-dependent damage-inducible nuclear protein 1). Cell death induced by DNA double-strand breaks (DSBs), as well as Ser46 phosphorylation of p53 and induction of p53AIP1, were blocked when we inhibited expression of p53DINP1 by means of an antisense oligonucleotide. Overexpression of p53DINP1 and DNA damage by DSBs synergistically enhanced Ser46 phosphorylation of p53, induction of p53AIP1 expression, and apoptotic cell death. Furthermore, the protein complex interacting with p53DINP1 was shown to phosphorylate Ser46 of p53. Our results suggest that p53DINP1 may regulate p53-dependent apoptosis through phosphorylation of p53 at Ser46, serving as a cofactor for the putative p53-Ser46 kinase.     

Conformational and molecular basis for induction of apoptosis by a p53 C-terminal peptide in human cancer cells

A p53-derived C-terminal peptide induced rapid apoptosis in breast cancer cell lines carrying endogenous p53 mutations or overexpressed wild-type (wt) p53 but was not toxic to nonmalignant human cell lines containing wt p53. Apoptosis occurred through a Fas/APO-1 signaling pathway involving increased extracellular levels of Fas/FasL in the absence of protein synthesis, as well as activation of a Fas/APO-1-specific protease, FLICE. The peptide activity was p53-dependent, and it had no effect in three tumor cell lines with null p53. Furthermore, the C-terminal peptide bound to p53 protein in cell extracts. Thus, p53-dependent, Fas/APO-1 mediated apoptosis can be induced in breast cancer cells with mutant p53 similar to the recently described Fas/APO-1 induced apoptosis by wt p53. However, mutant p53 without p53 peptide does not induce a Fas/APO-1 activation or apoptosis. Docking of the computed low energy conformations for the C-terminal peptide with those for a recently defined proline-rich regulatory region from the N-terminal domain of p53 suggests a unique low energy complex between the two peptide domains. The selective and rapid induction of apoptosis in cancer cells carrying p53 abnormalities may lead to a novel therapeutic modality.     

Reconstitution of p53 expression in a nonproducer Ab-MuLV-transformed cell line by transfection of a functional p53 gene

L12 are Ab-MuLV-transformed cells that express the abl p120 oncogene product but lack the cellularly encoded p53. The functional p53 gene in these cells has been inactivated by the insertion of Moloney virus-like sequences into the first p53 intron. Transfection of L12 cells with a functional p53 gene, contained in a 16 kb Eco RI genomic cloned fragment gave rise to L12-derived cell lines with novel p53 sequences of various sizes and copy number. A high percentage of L12-derived clones efficiently transcribed p53 mRNA and synthesized the p53 protein. Whereas injection of L12 parental cells into syngeneic mice caused the development of local tumors that later regressed, L12-derived clones that expressed p53 caused lethal tumors in syngeneic mice, thus behaving similarly to other Ab-MuLV-transformed p53-producer cell lines. These results suggest that the expression of p53 is essential for tumor cells to exhibit a fully transformed phenotype, manifested in lethal tumors in syngeneic mice.     

Reactivation of mutant p53 through interaction of a C-terminal peptide with the core domain

A synthetic 22-mer peptide (peptide 46) derived from the p53 C-terminal domain can restore the growth suppressor function of mutant p53 proteins in human tumor cells (G. Selivanova et al., Nat. Med. 3:632-638, 1997). Here we demonstrate that peptide 46 binds mutant p53. Peptide 46 binding sites were found within both the core and C-terminal domains of p53. Lys residues within the peptide were critical for both p53 activation and core domain binding. The sequence-specific DNA binding of isolated tumor-derived mutant p53 core domains was restored by a C-terminal polypeptide. Our results indicate that C-terminal peptide binding to the core domain activates p53 through displacement of the negative regulatory C-terminal domain. Furthermore, stabilization of the core domain structure and/or establishment of novel DNA contacts may contribute to the reactivation of mutant p53. These findings should facilitate the design of p53-reactivating drugs for cancer therapy.     

p53 regulation by ubiquitin

The ubiquitination pathway is a highly dynamic and coordinated process that regulates degradation as well as numerous processes of proteins within a cell. The p53 tumor suppressor and several factors in the pathway are regulated by ubiquitin as well as ubiquitin-like proteins. These modifications are critical for the function of p53 and control both the degradation of the protein as well as localization and activity. Importantly, more recent studies have identified deubiquitination enzymes that can specifically remove ubiquitin moieties from p53 or other factors in the pathway, and the reversible nature of this process adds yet another layer of regulatory control of p53. This review highlights the recent advances in our knowledge of ubiquitin and the p53 pathway.