Jamil Momand

The mdm-2 oncogene product forms a complex with the p53 protein and inhibits p53-mediated transactivation

A cellular phosphoprotein with an apparent molecular mass of 90 kd (p90) that forms a complex with both mutant and wild-type p53 protein has been characterized, purified, and identified. The protein was identified as a product of the murine double minute 2 gene (mdm-2). The mdm-2 gene enhances the tumorigenic potential of cells when it is overexpressed and encodes a putative transcription factor. To determine if mdm-2 could modulate p53 transactivation, a p53-responsive element from the muscle creatine kinase gene was employed. A wild-type p53-expressing plasmid enhanced the expression of the p53-responsive element when cotransfected into cells that contain no endogenous p53. When a cosmid expressing mdm-2 was transfected with this p53-expressing plasmid, the transactivation of the p53-responsive element was inhibited. Thus, a product of the mdm-2 oncogene forms a tight complex with the p53 protein, and the mdm-2 oncogene can inhibit p53-mediated transactivation.

MDM2 — master regulator of the p53 tumor suppressor protein

MDM2 is an oncogene that mainly functions to modulate p53 tumor suppressor activity. In normal cells the MDM2 protein binds to the p53 protein and maintains p53 at low levels by increasing its susceptibility to proteolysis by the 26S proteosome. Immediately after the application of cellular stress, the ability of MDM2 to bind to p53 is blocked or altered in a fashion that prevents MDM2-mediated degradation. As a result, p53 levels rise, causing cell cycle arrest or apoptosis. In this review, we present evidence for the existence of three highly conserved regions (CRs) shared by MDM2 proteins and MDMX proteins of different species. These highly conserved regions encompass residues 42-94 (CR1), 301-329 (CR2), and 444-483 (CR3) on human MDM2. These three domains are respectively important for binding p53, for binding the retinoblastoma protein, and for transferring ubiquitin to p53. This review discusses the major milestones uncovered in MDM2 research during the past 12 years and potential uses of this knowledge in the fight against cancer.

In vivo evidence for binding of p53 to consensus binding sites in the p21 and GADD45 genes in response to ionizing radiation

The tumor suppressor protein p53 has a transcriptional activation activity thought to mediate its biologic function including G1 arrest and perhaps apoptosis. To learn more about p53s transactivator function in vivo, we performed genomic footprinting experiments examining p53-DNA interactions in the regulatory regions of the p53-regulated genes p21, GADD45, and MDM2. Using ionizing radiation to induce DNA damage in human ML-1 myeloblastic leukemia cells, the promoter and intronic regions of these genes containing p53-consensus binding sites were examined for in vivo footprints. There was a uniform and sustained expression of p53 protein as well as a strong induction of p21, GADD45, and MDM2 mRNA following irradiation. At the two p53 consensus binding sites in the p21 promoter, reduced DNaseI cleavage was observed in irradiated cells beginning 1 to 2u2009h after irradiation, being most pronounced after 2u2009h and diminishing after 8u2009h. A partial in vivo footprint was also observed in the third intron of the GADD45 gene beginning 2 h after irradiation. No in vivo footprints were seen at the two p53 binding sites in the MDM2 gene. Our study provides direct evidence that the DNA damage-induced activity of p53 is mediated by its consensus DNA binding sites in the p21 and GADD45 genes. We suggest that the transient nature and relative instability of p53-DNA interactions in vivo may make the p53 protein more accessible to a rapid turnover pathway which might be impaired under conditions when the protein is stably bound to DNA.

Formation of disulfide bond in p53 correlates with inhibition of DNA binding and tetramerization.

The p53 tumor suppressor protein is susceptible to oxidation, which prevents it from binding to its DNA response element. The goal of the current research was to determine the nature of the cysteine residue thiol oxidation that prevents p53 from binding its DNA target and its effect on p53 structure. Recombinant p53, purified in the presence of the reducing agent dithiothreitol (DTT), contains five free thiol groups on the surface of the protein. In the absence of DTT, p53 contains only four thiol groups, indicating that an average of one surface thiol group is readily susceptible to oxidation. Sulfite-mediated disulfide bond cleavage followed by reaction with 2-nitro-5-thiosulfobenzoate showed that oxidized p53 contains a single disulfide bond per monomer. By atomic force microscopy, we determined that reduced p53 binds to a double-stranded DNA containing the p53 promoter element of the MDM2 gene. The DNA-bound reduced p53 has an average cross-sectional diameter of 8.61 nm and a height of 4.12 nm. The amount of oxidized p53 that bound to the promoter element was ninefold lower, and it has an 18% larger average cross-sectional diameter. Electromobility shift assays showed that binding of oxidized p53 to DNA was enhanced upon addition of DTT, indicating that oxidation is reversible. The possibility that oxidized p53 contained significant amounts of sulfenic (-SOH), sulfinic (-SO2H), or sulfonic acid (-SO3H) was ruled out. Gel filtration chromatography indicated that oxidation increases the percentage of p53 monomers and high-molecular-weight oligomers (>1,000 kDa) relative to tetrameric p53. Protein modeling studies suggest that a mixed disulfide glutathione adduct on Cys182 could account for the observed stoichiometry of oxidized thiols and structural changes. The glutathione adduct may prevent proper helix-helix interaction within the DNA binding domain and contribute to tetramer dissociation.

Prediction of reversibly oxidized protein cysteine thiols using protein structure properties.

Protein cysteine thiols can be divided into four groups based on their reactivities: those that form permanent structural disulfide bonds, those that coordinate with metals, those that remain in the reduced state, and those that are susceptible to reversible oxidation. Physicochemical parameters of oxidation‐susceptible protein thiols were organized into a database named the Balanced Oxidation Susceptible Cysteine Thiol Database (BALOSCTdb). BALOSCTdb contains 161 cysteine thiols that undergo reversible oxidation and 161 cysteine thiols that are not susceptible to oxidation. Each cysteine was represented by a set of 12 parameters, one of which was a label (1/0) to indicate whether its thiol moiety is susceptible to oxidation. A computer program (the C4.5 decision tree classifier re‐implemented as the J48 classifier) segregated cysteines into oxidation‐susceptible and oxidation‐non‐susceptible classes. The classifier selected three parameters critical for prediction of thiol oxidation susceptibility: (1) distance to the nearest cysteine sulfur atom, (2) solvent accessibility, and (3) pKa. The classifier was optimized to correctly predict 136 of the 161 cysteine thiols susceptible to oxidation. Leave‐one‐out cross‐validation analysis showed that the percent of correctly classified cysteines was 80.1% and that 16.1% of the oxidation‐susceptible cysteine thiols were incorrectly classified. The algorithm developed from these parameters, named the Cysteine Oxidation Prediction Algorithm (COPA), is presented here. COPA prediction of oxidation‐susceptible sites can be utilized to locate protein cysteines susceptible to redox‐mediated regulation and identify possible enzyme catalytic sites with reactive cysteine thiols.

Pyrrolidine Dithiocarbamate Prevents p53 Activation and Promotes p53 Cysteine Residue Oxidation

Pyrrolidine dithiocarbamate (PDTC) is a thiol compound widely used to study the activation of redox-sensitive transcription factors. Although normally used as an antioxidant, PDTC has been shown to exert pro-oxidant activity on proteins both in vitro and in vivo. Because p53 redox status has been shown to alter its DNA binding capability, we decided to test the effect of PDTC on p53 activation. In this communication, we report that PDTC inhibits the activation of temperature-sensitive murine p53Val-135 (TSp53) in the transformed rat embryo fibroblast line, A1-5, as well as wild-type human p53 in the normal diploid fibroblast line, WS1neo. In A1-5 cells, PDTC abrogated UV- and temperature shift-induced TSp53 nuclear translocation and p53-mediated transactivation of MDM2. PDTC also blocked UV-induced accumulation of wild-type p53 in WS1neo cells. Continual presence of PDTC was required for its effect as both UV-induced nuclear translocation and accumulation resumed after PDTC removal. We next investigated whether PDTC treatment altered the p53 redox state. We found that PDTC increased p53 cysteine residue oxidation in vivo. This represents the first direct evidence showing that the p53 redox state can be altered in vivo and that increased oxidation correlates with its inability to perform its downstream functions.

Capture of p53 by Electrodes Modified with Consensus DNA Duplexes and Amplified Voltammetric Detection Using Ferrocene-Capped Gold Nanoparticle/Streptavidin Conjugates

p53, a tumor suppressor protein and a transcription factor, is capable of inhibiting the growth of tumor cells by eliciting either cell-cycle arrest or apoptosis through a cascade of events. p53 binds sites within the promoters of several genes that conform to a sequence commonly defined as the consensus site. In more than 50% of cancer cases, the p53 gene has been found to be mutated and the p53 protein loses its ability to bind the consensus DNA. In this work, double-stranded (ds-) oligonucleotides (ODNs) containing the consensus site are immobilized onto gold electrodes to capture wild-type p53. The cysteine residues on the exterior of the p53 molecule were derivatized for the attachment of gold nanoparticle/streptavidin conjugates capped with multiple ferrocene (Fc) groups. Well-defined voltammetric peaks of high signal intensity were obtained, and p53 concentration as low as 2.2 pM was measured. The peak heights were found to be dependent on the surface density of the consensus ds-ODN, the sequence of the immobilized ODNs, and the p53 concentration. With base pair(s) in the full consensus binding sequence altered, the level of p53 binding was found to decrease sharply, and no p53 binding occurred at electrodes covered with nonconsensus ds-ODNs. The amenability of this method to the analyses of p53 from normal and cancer cell lysates was also demonstrated. Owing to the p53 mutation in the cancer cells, the concentration of the wild-type p53 was found to decrease significantly (by about 50-182 times). The sensitivity and amenability for real sample analysis of the method compared well with enzyme-linked immunosorbant assay (ELISA), and complements ELISA in that wild-type p53, instead of total p53 (wild-type and mutant p53) concentration, is measured. The method described herein is simple and selective and does not require the use of p53 antibodies.

Copper uptake is required for pyrrolidine dithiocarbamate-mediated oxidation and protein level increase of p53 in cells

The p53 tumour-suppressor protein is a transcription factor that activates the expression of genes involved in cell cycle arrest, apoptosis and DNA repair. The p53 protein is vulnerable to oxidation at cysteine thiol groups. The metal-chelating dithiocarbamates, pyrrolidine dithiocarbamate (PDTC), diethyldithiocarbamate, ethylene(bis)dithiocarbamate and H(2)O(2) were tested for their oxidative effects on p53 in cultured human breast cancer cells. Only PDTC oxidized p53, although all oxidants tested increased the p53 level. Inductively coupled plasma MS analysis indicated that the addition of 60 microM PDTC increased the cellular copper concentration by 4-fold, which was the highest level of copper accumulated amongst all the oxidants tested. Bathocuproinedisulphonic acid, a membrane-impermeable Cu(I) chelator inhibited the PDTC-mediated copper accumulation. Bathocuproinedisulphonic acid as well as the hydroxyl radical scavenger d-mannitol inhibited the PDTC-dependent increase in p53 protein and oxidation. Our results show that a low level of copper accumulation in the range of 25-40 microg/g of cellular protein increases the steady-state levels of p53. At copper accumulation levels higher than 60 microg/g of cellular protein, p53 is oxidized. These results suggest that p53 is vulnerable to free radical-mediated oxidation at cysteine residues.

Development of a sensitive assay to detect reversibly oxidized protein cysteine sulfhydryl groups.

Protein sulfhydryl groups can undergo reversible oxidation reactions in response to reactive oxygen and reactive nitrogen species. Sensitive detection of sulfhydryl group oxidation in specific proteins is required to further our understanding of protein redox changes in biological systems. In general, to detect reversible oxidation reactions the oxidized sulfur atom is reduced to a sulfhydryl group followed by a reaction with a quantifiable agent. Our aim was to develop a sensitive method to detect reversibly oxidized protein sulfhydryl groups in a Western blot format. Conjugation of methoxypolyethylene glycol-maleimide (MAL-PEG) to protein sulfhydryl groups was optimized. Once MAL-PEG forms a covalent bond with the protein, the MAL-PEG-protein conjugate can be detected as a band shift by western analysis. The efficiency of MAL-PEG conjugation to protein was determined with creatine kinase. MAL-PEG conjugated to approximately 100% of the available sulfhydryl groups on creatine kinase within 30 min. Band shift detection sensitivity was measured using the redox-regulated protein p53. MAL-PEG conjugation coupled to western analysis detected a minimum of 0.23 pmol of oxidized p53. The MAL-PEG conjugation method described in this communication can be used to assess the reversible sulfhydryl oxidation status of proteins for which antibodies suitable for western analysis are available.

Solution conformation of an essential region of the p53 transactivation domain

BACKGROUNDnThe peptide segment surrounding residues Leu22 and Trp23 of the p53 transactivation domain plays a critical role in the transactivation activity of p53. This region binds basal transcriptional components such as the TATA-box binding protein associated factors TAFII40 and TAFII60 as well as the mdm-2 and adenovirus type 5 E1B 55 kDa oncoproteins.nnnRESULTSnThe structure of residues 14-28 of p53 was studied by nuclear magnetic resonance spectroscopy and found to prefer a two-beta-turn structure stabilized by a hydrophobic cluster consisting of residues known to be important for transactivation and binding to p53-binding proteins. A peptide segment in which Leu22 and Trp23 were replaced by Gln and Ser displays a random structure.nnnCONCLUSIONSnThis structural propensity observed in the wild-type p53 peptide is important for understanding the mechanism of transcriptional activation, because very few structural data are available on transactivation domains to date. These results should aid in the design of therapeutics that could competitively inhibit binding of p53 to the oncogene product mdm-2.