Inhibition of the p53-hdm2 interaction with low molecular weight compounds

The hdm2 protein, upon binding to p53, inhibits its tumor suppressor activity. The inhibition of the p53-hdm2 interaction represents therefore a new therapeutic strategy to activate wild type p53 in tumors. Potent low molecular weight compounds inhibiting this protein-protein interaction, which are active in vivo, have just been identified. This offers new perspectives and hopes in this research area.     

Inhibition of the p53-hdm2 Interaction with Low Molecular Weight Compounds

The hdm2 protein, upon binding to p53, inhibits its tumour suppressor activity. The inhibition of the p53-hdm2 interaction represents therefore a new therapeutic strategy to activate wild type p53 in tumours. Potent low molecular weight compounds inhibiting this protein-protein interaction, which are active in vivo, have just been identified. This offers new perspectives and hopes in this research area.     

Hoiamide D, a marine cyanobacteria-derived inhibitor of p53/MDM2 interaction

Bioassay-guided fractionation of two cyanobacterial extracts from Papua New Guinea has yielded hoiamide D in both its carboxylic acid and conjugate base forms. Hoiamide D is a polyketide synthase (PKS)/non-ribosomal peptide synthetase (NRPS)-derived natural product that features two consecutive thiazolines and a thiazole, as well as a modified isoleucine residue. Hoiamide D displayed inhibitory activity against p53/MDM2 interaction (EC(50)=4.5 μM), an attractive target for anticancer drug development.     

Fluorescence polarization assay and inhibitor design for MDM2/p53 interaction

MDM2 is an important negative regulator of the tumor suppressor protein p53 which regulates the expression of many genes including MDM2. The delicate balance of this autoregulatory loop is crucial for the maintenance of the genome and control of the cell cycle and apoptosis. MDM2 hyperactivity, due to amplification/overexpression or mutational inactivation of the ARF locus, inhibits the function of wild-type p53 and can lead to the development of a wide variety of cancers. Thus, the development of anti-MDM2 therapies may restore normal p53 function in tumor cells and induce growth suppression and apoptosis. We report here a novel high-throughput fluorescence polarization binding assay and its application in rank ordering small-molecule inhibitors that block the binding of MDM2 to a p53-derived fluorescent peptide.     

Stereochemical studies of hexylitaconic acid,an inhibitor of p53–HDM2 interaction

Hexylitaconic acid (1) is an intriguing natural product possessing a chiral carbon, and both its enantiomers have been found in nature. Enantiomeric pure (+)-(1) and (?)-(1) were successfully prepared by racemic synthesis followed by enantiomeric separation in a chiral HPLC system. Their absolute configurations were clarified by the vibrational circular dichroism technique using their methyl esters 2 and lactones 3. Their inhibitory activities against the interaction of p53–HDM2 were also examined.     

Luliberin analogues exhibiting a cytotoxic effect on tumor cells in vitro

Luliberin analogues modified at the N-terminus were synthesized to search for drugs exerting a cytotoxic effect on cells of hormone-dependent tumors. A synthetic scheme effective in the preparation of analogues containing fatty acid residues was proposed. The cytotoxic effect of the peptides was studied on a number of cell lines of human tumors in vitro. The dependence of the antitumor effect on the length of peptide chain, amino acid sequence, and structure of the N-terminal group was demonstrated. Modification with palmitic acid was found to result in highly active compounds in the case of analogues containing more than ten aa, whereas modifications with lauric, caproic, or trimethylacetic acid led to compounds with significantly lower activities. Analogues of luliberin containing a palmitic acid residue and effectively inhibiting the growth of tumor cells in vitro were synthesized.     

Hexylitaconic acid: a new inhibitor of p53-HDM2 interaction isolated from a marine-derived fungus, Arthrinium sp

A new inhibitor of p53-HDM2 interaction was isolated from a culture of marine-derived fungus, Arthrinium sp. The structure was identified to be (-)-hexylitaconic acid (1) by spectroscopic analysis. The inhibition of p53-HDM2 binding was tested by the ELISA method, and 1 inhibited the binding with an IC(50) value of 50 microg/mL. Although a number of synthetic inhibitors of p53-HDM2 interaction have been reported so far, 1 is the second inhibitor isolated from natural resources.     

Hdmx modulates the outcome of p53 activation in human tumor cells

Tumors that express wild-type P53 provide a target for therapies designed to reactivate P53 function. This is supported by the potent activation of P53 in tumor cells by Nutlin, a cis-imidazoline that inhibits the Hdm2-P53 interaction. The efficacy of Hdm2.P53 antagonists could be compromised if they do not antagonize Hdmx, an Hdm2 homolog that inhibits P53 transactivation. We evaluated the role of Hdmx expression in sensitivity to Nutlin in a range of cancer cell lines. Nutlin reduced Hdmx levels in normal cells and some cancer cell lines, whereas other cancer cells were refractory to such down-regulation. Strikingly, Nutlin did not disrupt Hdmx.P53 complexes, and in cell lines where no Hdmx degradation occurred, Nutlin failed to induce apoptosis. shRNA-mediated reduction of Hdmx sensitized cells to apoptosis, but caspase-3 was neither required nor sufficient for Hdmx degradation or apoptosis. Our data imply that Hdmx is an important determinant of the outcome of P53 activation. Thus, targeting Hdmx may be a therapeutic strategy that complements drugs such as Nutlin.     

TNF-alpha promotes Doxorubicin-induced cell apoptosis and anti-cancer effect through downregulation of p21 in p53-deficient tumor cells

p53 is a key regulator in cell apoptosis, and cancer cells deficient in p53 expression fail to respond to chemotherapy. Here we show that effective Doxorubicin (DOX)-induced apoptosis is p53-dependent. However, an alternative treatment of DOX/TNF-alpha/DOX restored sensitivity of p53-deficient cells to DOX-induced apoptosis. Treatment of cells with TNF-alpha resulted in a decrease of p21 (waf1/cip1/sdi1) expression following second dose of DOX. In previous work, we demonstrated that p21 suppressed DOX-induced apoptosis via its (cyclin-dependent kinase) CDK-binding and CDK-inhibitory activity. Thus, we propose that TNF-alpha enhances the anti-cancer effect of DOX through suppressing the anti-apoptotic activity of p21, and that a combined treatment TNF-alpha/Dox is an effective chemotherapeutic strategy for p53-deficient cancers.     

Drosophila p53 is a structural and functional homolog of the tumor suppressor p53

The importance of p53 in carcinogenesis stems from its central role in inducing cell cycle arrest or apoptosis in response to cellular stresses. We have identified a Drosophila homolog of p53 ("Dmp53"). Like mammalian p53, Dmp53 binds specifically to human p53 binding sites, and overexpression of Dmp53 induces apoptosis. Importantly, inhibition of Dmp53 function renders cells resistant to X ray-induced apoptosis, suggesting that Dmp53 is required for the apoptotic response to DNA damage. Unlike mammalian p53, Dmp53 appears unable to induce a G1 cell cycle block when overexpressed, and inhibition of Dmp53 activity does not affect X ray-induced cell cycle arrest. These data reveal an ancestral proapoptotic function for p53 and identify Drosophila as an ideal model system for elucidating the p53 apoptotic pathway(s) induced by DNA damage.