Project description:Advanced colorectal cancer (CRC) is an unresolved clinical problem. Epigenetic drugs belonging to the group of histone deacetylase inhibitors (HDACi) may combat CRC in rationally designed treatment schedules. Unfortunately, there is sparse evidence on molecular mechanisms and markers that determine cellular sensitivity to HDACi. Irinotecan is widely used to treat CRC and causes replication stress (RS) and DNA damage as topoisomerase-I inhibitor. We applied irinotecan and the class I HDACi entinostat (MS-275) to isogenic p53-positive and -negative CRC cells. Combinations of irinotecan and MS-275 evoke mitochondrial damage, caspase-mediated apoptosis, and RS-associated DNA damage synergistically and p53-dependently. Targeted mass spectrometry and immunoblot show that irinotecan induces phosphorylation, acetylation, and accumulation of p53 and its target genes. Addition of MS-275 augments the irinotecan-induced acetylation of C-terminal lysine residues of p53 but decreases its phosphorylation and p53 target gene induction. Furthermore, MS-275 increases the amount of acetylated p53 at mitochondria and dysregulates the expression of pro- and anti-apoptotic BCL2 proteins in irinotecan-treated cells. Regarding DNA repair, we see that MS-275 represses the homologous recombination (HR) filament protein RAD51, which limits DNA damage and pro-apoptotic effects of irinotecan. These data suggest that key class I HDAC-dependent functions of p53 in cells with RS are linked to mitochondrial damage and a breakdown of HR. Most importantly, combinations of irinotecan plus MS-275 also kill short-term primary CRC cell cultures and organoids from CRC patients but spare organoids of adjacent matched normal tissue. Thus, irinotecan/HDACi treatment is a promising new approach for the therapy of p53-proficient tumors with clinically tractable inhibitors.

Project description:Readthrough of a translation termination codon is regulated by ribosomal A site recognition and insertion of near-cognate tRNAs. Small molecules exist that mediate the incorporation of amino acids at the stop codon and the production of full-length, often functional protein but defining the actual amino acid that is incorporated remains a challenging area. We report on the development of a human cell model that can be used to determine whether rules can be developed using mass spectrometry that defines the type of amino acid that is placed at a premature termination codon during readthrough mediated by an aminoglycoside. The first premature termination codon we analysed contained the relatively common cancer-associated termination signal at codon 213 in the p53 gene. Although we could detect a tryptic peptide with the incorporation of an R at codon 213 in the presence of the aminoglycoside, there were no other tryptic peptides detected across codon 213 that could be recovered so we needed to create a more robust artificial premature stop codon model. P53 expression plasmids were developed that incorporate a string of single synthetic UGA (opal) stop codons at S127P128A129 within the relatively abundant tryptic p53 peptide 122-SVTCTYSPALNK-132. The treatment of cells stably expressing the p53-UGA129 mutation, treated with Gentamycin, followed by immunoprecipitation and trypsinization of p53, resulted in the identification R, W, or C within the tryptic peptide at codon-UGA129; as expected based on the two base pairing of the respective anticodons to UGA with R being the most abundant using all three codons. By contrast, incorporating the amber or ochre premature stop codons, UAA129 or UAG129 resulted in the incorporation of a Y or Q amino acid, again as expected based on the two base pairings to the anticodons, with Q being the most abundant. The incorporation of these amino acids at codons 127, 128, or 129 generally results in a p53 protein that is predicted to be ‘unfolded’ or inactive as defined by Molecular Dynamic Simulations. As such, the data also highlight the need in the future to not only produce novel small molecules that can read through premature termination codons but also the need to design methods to insert the required amino acid at the position that could result in a ‘wild-type’ functional protein.

Project description:Lysine acetylation plays a prominent regulatory role in eukaryotic cells. Yet, determining the functional consequences of acetylation for a given protein represents a considerable challenge. For instance, lysine residues are subject to various posttranslational modifications, rendering interpretation of mutational studies difficult. The genetic code expansion technology enables the site-specific incorporation of acetyllysine (AcK) into proteins, but the applicability of AcK is limited, as within cells, the acetyl group is removed by deacetylases. Here, we show that site-specific incorporation of the non-hydrolyzable AcK analog ketolysine (KeK) into ubiquitin closely resembles the structural and functional effects of AcK incorporation. Furthermore, AcK and KeK can be efficiently incorporated into the tumor suppressor p53. However, whereas AcK becomes deacetylated, KeK remains stable. Accordingly, incorporation of KeK, but not AcK, affects p53-mediated transcription. Thus, we propose that KeK is the AcK surrogate of choice for studying protein acetylation in cells.

Project description:p53 executes its diverse functions via different transcriptional targets, but the precise mechanism of promoter-specific regulation by p53 remains largely unknown. Through biochemical purification, we identify PURB, a dual DNA/RNA-binding protein, which acts as a transcriptional co-repressor for p53 in a manner dependent on p53 acetylation status. PURB is overexpressed in human cancers while its knockdown induces p53-dependent activation of p21 but has no effect on other major promoters such as PUMA and Mdm2. In contrast to other p53 corepressors, PURB can recognize a unique DNA element at the p21 promoter, with the loss of this element not affecting p53-mediated transactivation but abrogating the ability of p53 to recruit PURB to the p21 promoter for repression. Mechanistically, PURB requires its sequence-specific binding with lncRNA HOTAIR to exert its repressive role. In turn, HOTAIR interacts directly with EZH2 and, bridged by the PURB/HOTAIR complex, p53 can recruit the EZH2 histone methyltransferase to target promoters for transcriptional repression. Further analysis of p53 targets indicates a number of promoters that may serve as a target for PURB-binding, suggesting that this mechanism of PURB-dependent promoter-specific regulation may not be limited to p21. These data establish a mode of LncRNA-mediated regulation of p53 transcription in a sequence-specific manner and reveal a previously unanticipated mechanism for acetylation-mediated promoter-specific regulation through a cis-regulatory element recognized by the PURB-HOTAIR complex.

Project description:Oncogene-induced senescence (OIS) is a p53-dependent defence mechanism against uncontrolled proliferation. Consequently, many human tumours harbour p53 mutations while others show a dysfunctional p53 pathway, frequently by unknown mechanisms. We identified BRD7, a bromodomain-containing protein whose inhibition allows full neoplastic transformation in the presence of wild-type p53. Intriguingly, in human breast tumours harbouring wild-type, but not mutant p53, the BRD7 gene locus was frequently deleted and low BRD7 expression was found in a subgroup of tumours. Functionally, BRD7 is required for efficient p53-mediated transcription of a subset of target genes. BRD7 interacts with p53 and p300, and is recruited to target gene promoters, affecting histone acetylation, p53 acetylation, and promoter activity. Thus, BRD7 suppresses tumourigenicity by serving as a p53 cofactor required for efficient induction of p53-dependent OIS. We recorded mRNA expression profiles of BJ primary fibroblasts expressing the oncogene RasV12 and either control vector, one of two BRD7 knockdown vectors, or p53 knockdown vector. In addition, we profiled genome-wide protein DNA interactions for p53 and BRD7 using ChIP-Seq. p53- and BRD7-binding sites were recorded in RasV12-expressing BJ cells; as a control we used knockdown of the gene of interest (BRD7 or p53).

Project description:Wild type and mutant p53 were transfected in H1299 cells and the associated complexes were affinity purified. The p53 interacting proteins then analyzed by ms/ms.

Project description:Effects of p53 acetylation at the C terminal domain on p53 binding

Project description:The tetrameric tumor suppressor p53 represents a great challenge for 3D structural analysis due to its high degree of intrinsic disorder (ca. 40%). We developed and applied an integrative structural biology approach combining complementary techniques of structural mass spectrometry (MS), namely cross-linking mass spectrometry (XL-MS), protein footprinting, and hydrogen/deuterium exchange mass spectrometry (HDX-MS), with advanced protein structure prediction approaches to gain insights into the disordered C-terminal region of p53. Additionally, we evaluate possible differences in p53 regarding solvent accessibility and topology upon DNA binding. Our quantitative XL-MS and lysine labeling data show no major conformational differences in p53 between DNA-bound and DNA-free states. Integration of experimental data generate p53 models for p53’s intrinsically disordered regions (IDRs) that reflect substantial compaction of the molecule. Our models provide the most detailed description of the relationship between p53’s folded regions and IDRs that is available to date. The synergies between complementary structural MS techniques and computational modeling as pursued in our integrative approach is envisioned to serve as general strategy for studying intrinsically disordered proteins (IDPs) and IDRs.

Project description:The tumor suppressor protein p53 is a transcription factor that is referred to as the “guardian of the genome” and plays an important role in cancer development. P53 is active as a tetramer; the S100β homodimer binds to the intrinsically disordered C-terminus of p53, affecting its transcriptional activity. The p53/S100β complex is regarded as highly promising therapeutic target in cancer. It has been suggested that S100β exerts its oncogenic effects by altering the p53 oligomeric state. Our aim was to study the structures and oligomerization behavior of different p53/S100β complexes by electrospray ionization mass spectrometry (ESI-MS), cross-linking mass spectrometry (XL-MS), and surface plasmon resonance (SPR). For this, wild-type p53 and single amino acid variants, representing different oligomeric states of p53 (tetrameric wild-type, dimeric L344A variant, and monomeric L344P variant) were individually investigated regarding their binding behavior towards S100β. The stoichiometry of the different p53/S100β complexes were determined by ESI-MS showing that tetrameric, dimeric, and monomeric p53 variants all bind to an S100β dimer. In addition, XL-MS revealed the topologies of the p53/S100β complexes to be independent of p53’s oligomeric state. With SPR, the thermodynamic parameters were determined for S100β binding to tetrameric, dimeric or monomeric p53 variants. Our data prove that the S100β homodimer binds to different oligomeric states of p53 with identical stoichiometries and similar binding affinities. This emphasizes the need for alternative explanations to describe the molecular mechanisms underlying p53/S100β interaction.

Project description:The mouse R178E (EE) mutation of the Trp53 is a p53 mutant protein with native conformation that lacks the ability to form tetramers and thus constitutes a mutant form of p53 that lacks DNA binding cooperativity. Here we want to assess DNA binding ability of the EE mutant in MEFs under untreated conditions and following p53 stabilization with the Mdm2 inhibitor nutlin-3a and compare it to p53 KO and WT mice.