Project description:Mutations in the DNA binding domain (DBD) of TP53 are often associated with the gain-of-function (GOF) of mutp53, resulting in pervasive transcription of chromatin regulatory genes that promote genome-wide histone methylation and acetylation. Efforts to target this tumor-promoting function of mutp53 remain elusive. Here, we therapeutically exploit the GOF mechanisms of p53 codon 158 mutation, a DBD mutant found to be prevalent in lung squamous cell carcinoma. Using high throughput compound screening and combination analyses, we uncovered that mutp53R158G exhibits strong synergistic cytotoxicity to cisplatin-induced DNA stress and belinostat, a histone deacetylase inhibitor. This treatment regime acetylates mutp53, alters DNA binding motifs and upregulates TRAIP, a RING domain-containing E3 ubiquitin ligase which dephosphorylates IĸB and impedes nuclear translocation of RelA (p65), thus repressing oncogenic nuclear factor kappa-B (NF-ĸB) signalling and inducing apoptosis. This mechanistic intervention was validated with other acetylators of mutp53 and in several cancer models. Given that this transcriptional modulation and cytotoxic vulnerability appears inapt in p53 wild-type (WT) or null cells, our work provides a novel therapeutic opportunity in Arg158 15 -mutp53 tumors utilizing a regimen consisting of DNA-damaging agents and mutp53 acetylators, which is currently being pursued clinically.

Project description:Inactivating TP53 mutations lead to a loss of function of p53, but can also often result in oncogenic gain-of-function (GOF) of mutant p53 (mutp53) proteins which promote tumor development and progression. The GOF activities of TP53 mutations are well documented, but the mechanisms involved remain poorly understood. Here, we study the mutp53 interactome with IP-MS.

Project description:Mutations in the p53 tumor suppressor gene are the most frequent genetic alteration in cancer and often associated with progression from benign to invasive, metastatic stages. Mutations inactivate tumor suppression by p53 and endow the protein with novel gain-of-function (GOF) activities that actively promote tumor progression, metastasis and therapy resistance. By comparative gene expression profiling of p53-mutated and p53-depleted cancer cells we identified ectonucleoside triphosphate diphosphohydrolase 5 (ENTPD5) as a mutant p53 (mutp53) target gene. A comprehensive pan-cancer analysis revealed a highly significant correlation between GOF p53 mutations and elevated expression of ENTPD5. Mechanistically, regulation of ENTPD5 by mutp53 is mediated by the histone H3 lysine 4 (H3K4) methyltransferase COMPASS complex. ENTPD5 has been shown to function in the endoplasmic reticulum as a UDPase to promote the N-glycosylation and folding of membrane proteins such as growth factor receptors and integrins. We show ENTPD5 to be a mediator of mutp53 GOF activity in clonogenic growth, architectural tissue remodeling, migration, invasion, and lung colonization in an experimental metastasis mouse model. Our study reveals N-glycosylation in the endoplasmic reticulum as a novel mechanism underlying the progression of tumors with mutp53 that could provide new possibilities for treating cancers driven by GOF p53 mutations.

Project description:In the present study, we set out to explore mechanisms of mutp53 GOF by identifying new interaction partners of mutp53. Specifically, we focused on the DNA contact mutant p53R273H, one of the most common p53 hotspot mutants and the most frequent TP53 mutant in pancreatic cancer. We now report that p53R273H binds selectively to the polyubiquitin-binding protein SQSTM1/p62. The crosstalk between p53R273H and p62 leads to proteasomal degradation of several cell adhesion-associated proteins, apparently in conjunction with the Golgi apparatus, resulting in loss of cell-cell junctions and enhancement of cancer cell scattered migration and invasion. This new mechanism, which does not rely on transcriptional regulation by mutp53, is likely to contribute to mutp53 GOF in tumors whose spead is reliant on scattered cell migration.

Project description:Mis-sense mutations affecting TP53 promote carcinogenesis both by inactivating its tumor suppressive functions, and by conferring aberrant pro-carcinogenic activities. We report here that mis-sense mutants in the p53 DNA-binding domain (DBD) and the transactivation domain (TAD) unexpectedly activate pro-carcinogenic epidermal growth factor receptor (EGFR) signaling via distinct, previously unrecognized molecular mechanisms. DBD- and TAD-specific TP53 mutants exhibited different cellular localization patterns and induced distinct gene expression profiles. Combining mass spectrometry with drug compound screens, we identified EGFR as a major signaling factor that is stabilized by TAD and DBD mutants in the cytosolic and nuclear compartments respectively, in a tissue-independent manner. Mechanistically, TAD mutants promote EGFR-mediated signaling by enhancing EGFR interaction with AKT via DDX31 in the cytosol. Conversely, DBD mutants maintain EGFR activity in the nucleus, by blocking EGFR interaction with the phosphatase SHP1, triggering upregulation of c-Myc and Cyclin D1 levels. Therapeutically, the sensitivity of DBD mutants to EGFR inhibition is enhanced by increasing the affinity of EGFR for SHP1, while that of TAD mutants can be induced by concurrent inhibition of AKT, mTOR or PI3K signaling. Thus, our findings suggest that gain-of-function, mis-sense mutations affecting two different p53 domains promote carcinogenesis by enhancing EGFR signaling via distinctive mechanisms. Our findings imply that cancer cells bearing domain-specific mutations may have distinct and exploitable therapeutic vulnerabilities.

Project description:p63, like its homologue, the tumor suppressor p53, is also able to induce apoptosis in several cancer cell types. p53 family proteins are composed of three characteristic domains which are: 1) an N-terminal transactivation domain (TAD); 2) a central DNA-binding domain (DBD); and 3) an oligomerization domain (OD). In this study, we constructed recombinant adenoviruses containing hybrid genes composed of fragments of p53 and TAp63γ genes by connecting coding sequences of their three functional domains. The potency of tumor growth suppression of these hybrid molecules was evaluated using in vitro and in vivo models. One of the p53-p63 hybrid molecules, p63-53O, was observed to be the most potent activator of human cancer cells to apoptosis when compared to the p53, TAp63γ or several alternative p53-p63 hybrid molecules. p63-53O hybrid is composed of TAD and DBD of TAp63γ and OD of p53. In an effort to identify specific targets regulated by pro-apoptotic hybrid p63-53O, we next performed Affymetrix Genechip analysis and compared expression patterns in a human osteosarcoma cell line Saos-2 transfected separately with Ad-p53, Ad-TAp63γ and Ad-p63-53O. Saos-2 osteosarcoma cells were either transduced with adenoviral vectors expressing p53, TAp63gamma, p53-p63 hybrid (p63-53O), or GFP. After 24 hours, mRNA was isolated and analyzed by hybridization to Affymetrix HG-U133 plus 2 arrays.

Project description:The p53 protein is encoded by TP53 gene and plays the key role in significant number of cellular processes including proliferation, apoptosis and regulation of many stress response pathways. P53 acts like a direct transcription activator of numerous genes regulating cell cycle arrest, DNA repair, growth inhibition and many others (Mollereau and Ma, 2014). The canonical biological function of p53 is maintaining genome integrity via elimination of damaged or exposed to genotoxic stress cells. Immortalized HaCaT cells are widely used for keratinocyte research, since they maintain stable keratinocyte phenotype, have nearly unlimited proliferative potential, do not require specific growth and differentiation factors (Colombo et al., 2017). Also, HaCaT cells produce typical differentiation markers such as cytokeratins K14 and K10, involucrin (Colombo et al., 2017) and respond to keratinocyte differentiation stimuli. Taking together, HaCaT cells have similar to normal human keratinocytes (NHK) properties, however, as many of spontaneously immortalized cell lines HaCaT cells bear two mutant p53 alleles - R282Q and H179Y (Lehman et al., 1993). Mutp53 in HaCaT has an increased affinity to other p53 family members (p63, p73), which significantly expands p53 properties. Moreover, mutp53 indirectly affects specific target genes via protein-protein interactions with other transcription factors (NF-Y, E2F1, NF-KB) or by tethering p63 to new promotor locations. For more detailed investigation of mutp53 impact on various processes in HaCaT cells we performed a shRNA mediated knockdown of mutp53. For generation of stable TP53 knockdown we employed plasmid vector pLKO-p53-shRNA-941 (Addgene # #25637) followed by puromycin selection of transduced cells. Here we present proteomic dataset obtained from wild type HaCaT cells and p53 knock down HaCaT keratinocytes.

Project description:p63, like its homologue, the tumor suppressor p53, is also able to induce apoptosis in several cancer cell types. p53 family proteins are composed of three characteristic domains which are: 1) an N-terminal transactivation domain (TAD); 2) a central DNA-binding domain (DBD); and 3) an oligomerization domain (OD). In this study, we constructed recombinant adenoviruses containing hybrid genes composed of fragments of p53 and TAp63γ genes by connecting coding sequences of their three functional domains. The potency of tumor growth suppression of these hybrid molecules was evaluated using in vitro and in vivo models. One of the p53-p63 hybrid molecules, p63-53O, was observed to be the most potent activator of human cancer cells to apoptosis when compared to the p53, TAp63γ or several alternative p53-p63 hybrid molecules. p63-53O hybrid is composed of TAD and DBD of TAp63γ and OD of p53. In an effort to identify specific targets regulated by pro-apoptotic hybrid p63-53O, we next performed Affymetrix Genechip analysis and compared expression patterns in a human osteosarcoma cell line Saos-2 transfected separately with Ad-p53, Ad-TAp63γ and Ad-p63-53O.

Project description:Missense point mutations in the TP53 gene are frequent genetic alterations in human tumor tissue and cell lines derived thereof. Mutant p53 (mutp53) proteins have lost sequence-specific DNA binding, but have retained the ability to interact in a structure-selective manner with non-B DNA and to act as regulators of transcription. To identify functional binding sites of mutp53, we established a small library of genomic sequences bound by p53R273H in U251 human glioblastoma cells using chromatin immunoprecipitation (ChIP). Mutp53 binding to isolated DNA fragments confirmed the specificity of the ChIP. The mutp53 bound DNA sequences are rich in repetitive DNA elements, which are dispersed over non-coding DNA regions. Stable down-regulation of mutp53 expression strongly suggested that mutp53 binding to genomic DNA is functional. We identified the PPARGC1A and FRMD5 genes as p53R273H targets regulated by binding to intronic and intra-genic sequences. We propose a model that attributes the oncogenic functions of mutp53 to its ability to interact with intronic and intergenic non-B DNA sequences and modulate gene transcription via re-organization of chromatin. For the study of the consequences of mutant p53 (R273H) knockdown on gene expression, total RNA from parental U251 glioblastoma cells and UsiA12 clone was prepared from two independent cell culture experiments (biological replicates) and processed for microarray-based profiling of gene expression. UsiA12 clone was derived from the U251 cells transfected with the pSuper-p53 and pCI-neo vectors.

Project description:TP53, encoding for the tumor suppressor p53, is the most frequently mutated gene in human cancer. The selective pressures shaping its mutational spectrum, dominated by missense mutations, have remained enigmatic, and neomorphic gain-of-function (GOF) activities have been implicated. We generated isogenic human leukemia cell lines of the most common TP53 missense mutations using CRISPR/Cas9. Functional, DNA binding, and transcriptional analyses revealed loss-of-function (LOF) without GOF effects of missense mutations. Comprehensive mutational scanning of p53 single amino acid variants demonstrated that DNA-binding domain missense variants exert dominant-negative effects (DNE). In mice, DNE of p53 missense variants confer a selective advantage on hematopoietic cells upon DNA damage in vivo. Clinical outcomes in acute myeloid leukemia patients showed no evidence of GOF for TP53 missense mutations. These findings establish dominant-negativity as the primary unit of selection for TP53 missense mutations in myeloid malignancies.