Project description:To demonstrate proof of concept and validate the prediction of lncRNAs’ target genes, we performed three cases of genome editing to knock out the short sequences that contain the predicted DNA binding domains (DBD) of human-specific lncRNAs in three cancer cell lines. The knockout of a 157 bp sequence (containing the DBD of RP13-516M14.1) in the HeLa cell line, a 202 bp sequence (containing the DBD of RP11-426L16.8) in the RKO cell line, and a 198 bp sequence (containing the DBD of SNORA59B) in the SK-MES-1 cell line, all caused the significantly changed expression of target genes.

Project description:Coactivator CREB-binding protein (CBP) regulates the transcription program of p53, which orchestrates cellular responses to a wide-range of stress conditions that cause genomic instability. Given the ability of CBP to regulate transcription by multiple mechanisms, the biological significance of its acetylation-directed functions may not be fully clear. The present study demonstrates the development of a curcumin-derived modulator of CBP histone acetyl-transferase (HAT) activity, CM354, which inhibits acetylation of p53 on lysine 382, acetylation of histone H3K27 and autoacetylation of CBP. These epigenetic changes are concomitant with downregulation of p53 and CBP functions, which facilitate the presence of histone methyl transferase, Enhancer of zeste homolog 2 (EZH2), on CDKNI1A/p21 promoter, thereby, enhancing the level of trimethylation on H3K27. Treatment with CM354 results in the activation of PARP and the abrogation of cellular growth. Genome-wide network analysis depicts that CM354 could alter cell-fate by enrichment of chromatin H3K27 methylation and activation of the polycomb group of proteins. Though previously reported HAT inhibitors act at higher concentrations and lack cell permeability, the present study shows the impact of modulating endogenous CBP HAT activity on chromatin landscape and p53 functions.

Project description:Using a massively parallel reporter assay (MPRA), we examined the effect of local sequence context on p53-dependent enhancer activity.

Project description:Epigenetic events, including covalent post-translational modification of histones, have frequently been demonstrated to play critical roles in tumor development and progression. The transcriptional coactivator, p300/CBP, possesses both histone acetyltransferase (HAT) activity as well as scaffolding properties that directly influence transcriptional activation of targeted genes. We have used a recently reported small molecule inhibitor of p300 HAT activity, C646, to explore the specific contribution of p300/CBP HAT activity to tumor development and progression. We find that C646 inhibits the growth of lineage-specific tumor cell lines including human melanomas through direct transcriptional regulation of cell cycle regulatory proteins. Further evaluation of the p300 HAT transcriptome in human melanoma cells using comprehensive gene expression profiling reveals that p300 HAT activity globally promotes cell cycle progression, nucleosome assembly, and the DNA damage checkpoint through direct transcriptional regulatory mechanisms. Additionally, C646 promotes sensitivity to DNA damaging agents leading to enhanced apoptosis of melanoma cells following combination treatment with cisplatin. Together our data suggest that p300 HAT activity regulates critical growth regulatory pathways in tumors and may serve as a novel therapeutic target for melanoma and other malignancies by promoting cellular responses to DNA damaging agents. Keywords: p300, small molecule inhibitor, melanoma WM35 cells grown under normal culture conditions were treated for 6 and 24 hours with compound C646 to block p300 HAT activity. A vehicle control (DMSO) was included at each time point. RNA was extracted from all 4 samples using the Qiagen RNeasy kit. RNA quality check, labeling, hybridization, initial data processing and analysis was performed by the JHMI Microarray Core Facility. Affymetrix GeneChip Human Exon 1.0 ST Array was used for this study.

Project description:The tumor suppressor p53 is a well-characterized transcription factor that can bind gene promoters and regulate target gene transcription in response to DNA damage. Recent studies, however, have revealed that p53 binding events occur predominantly within regulatory enhancer elements. The effect of p53 binding on enhancer function has not been systematically evaluated. Here, we perform a genome-scale analysis of enhancer activity from p53-bound sequences using a series of massively parallel reporter assays (MPRAs) coupled with the assay for transpose-accessible chromatin (ATAC-Seq). We find that the majority of p53 bound sequences examined are potent regulators of enhancer activity during the DNA damage response. Enhancer regulation requires the presence of the p53 consensus sequence and results in significant induction of target gene transcription. Surprisingly, our analyses revealed that most p53-bound enhancers are located within regions of inaccessible chromatin. Many of these enhancers display significantly increased accessibility in response to DNA damage suggesting that p53 regulates their activity, in part, by altering local chromatin environments. The recognition and activation of inaccessible enhancers may contribute to the ability of the p53 network to function across the diverse chromatin landscapes of different cell and tissue types.

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:TP53 (p53) is the most commonly mutated gene in human cancers, and p53 missense mutations are present in more than 40% of all human tumors. Most p53 mutations are located within the DNA binding domain, including hotspot mutations R175H, R248W, and R273H. To elucidate the precise mechanism by which p53 missense mutants execute their gain-of-functions (GOFs) in vivo, we used a proteomic screen to identify any protein that recognizes the p53 DNA-binding domain (DBD) in a manner dependent on its mutation status. To do so, we first purified the potential binding proteins associated with the p53 DBD through multi-step affinity chromatography from a SFB-p53 H1299 stable cell line. The affinity-purified SFB-p53 interacting proteins were detected by liquid chromatography mass spectrometry/mass spectrometry (LC–MS/MS) and revealed a few cellular proteins that have been reported to interact with the DNA binding domain of p53, such as TP53BP1, USP28, and Sirt1. Interestingly, we also identified many new interacting proteins from the same complex.

Project description:Epigenetic events, including covalent post-translational modification of histones, have frequently been demonstrated to play critical roles in tumor development and progression. The transcriptional coactivator, p300/CBP, possesses both histone acetyltransferase (HAT) activity as well as scaffolding properties that directly influence transcriptional activation of targeted genes. We have used a recently reported small molecule inhibitor of p300 HAT activity, C646, to explore the specific contribution of p300/CBP HAT activity to tumor development and progression. We find that C646 inhibits the growth of lineage-specific tumor cell lines including human melanomas through direct transcriptional regulation of cell cycle regulatory proteins. Further evaluation of the p300 HAT transcriptome in human melanoma cells using comprehensive gene expression profiling reveals that p300 HAT activity globally promotes cell cycle progression, nucleosome assembly, and the DNA damage checkpoint through direct transcriptional regulatory mechanisms. Additionally, C646 promotes sensitivity to DNA damaging agents leading to enhanced apoptosis of melanoma cells following combination treatment with cisplatin. Together our data suggest that p300 HAT activity regulates critical growth regulatory pathways in tumors and may serve as a novel therapeutic target for melanoma and other malignancies by promoting cellular responses to DNA damaging agents. Keywords: p300, small molecule inhibitor, melanoma

Project description:The Forkhead transcription factor, FOXM1, is a key regulator of the cell cycle and is over-expressed in most types of cancer. FOXM1, similar to other Forkhead (FKH) factors binds to a canonical FKH motif in vitro. However, genome-wide mapping studies in different cell lines have shown a lack of enrichment of the FKH motif at FOXM1 binding sites suggesting an alternative mode of chromatin recruitment. We have investigated the role of direct versus indirect DNA binding in FOXM1 recruitment by performing ChIP-seq with WT and DNA binding deficient FOXM1. An in vitro fluorescence polarization (FP) assay was used to identify point mutations in the DNA binding domain (DBD) of FOXM1 that inhibit binding to a FKH consensus sequence. Stable cell lines expressing either WT or DBD mutant green fluorescence protein (GFP)-tagged FOXM1 were utilized for genome-wide mapping studies comparing the distribution of the DBD mutant protein to the WT. This showed that interaction of the DBD of FOXM1 with target DNA is essential for recruitment. Moreover, analysis of protein interactome of the WT versus DBD mutant FOXM1 showed that the reduced recruitment is not due to the mutation inhibiting protein-protein interactions. This study showed that a functional DBD domain is essential for FOXM1 chromatin recruitment. Even in FOXM1 mutants that show almost complete loss of binding the protein-protein interactome and pattern of phosphorylation are largely unaffected. These results strongly support a model whereby FOXM1 is specifically recruited to chromatin through co-factor interactions by binding directly to both canonical and non-canonical DNA sequences.

Project description:Transcription factors are often regarded as having two distinct components: a DNA binding domain (DBD) to allow binding to the regulatory region of a target gene and a trans-acting functional domain (FD) to modulate gene expression. Recently, it is becoming clear that the DBDs of transcription factors alone are incapable of providing sufficient specificity to account for the highly complex genomic structures in eukaryotes. Other regions, outside of the DBD, may play a role in transcription factor DNA binding specificity in vivo. In order to test this hypothesis, we examined a model zinc finger transcription factor, Krüppel-like factor 3 (KLF3) with a FD that recruits partner proteins for its repressive activity and a three zinc finger DBD. Previously, we showed that deletion of the entire KLF3 FD reduced DNA binding across the genome. This implied the importance of the FD for in vivo DNA binding specificity. In the current study, we fused the KLF3 FD onto an unrelated, but well characterised Artificial Zinc Finger (AZF) targeting a standard target gene, VEGF-A. We compared the genomic DNA binding profile of this chimeric KLF3 construct, termed KLF3FD-AZF, to that of the AZF alone. Chromatin Immunoprecipitation followed by next generation sequencing was used to assess genomic wide DNA-binding of these AZFs. Remarkably, in these gain-of-function experiments, we again observed that the KLF3 FD is critical for in vivo DNA binding specificity. The addition of KLF3 FD increased the number of binding sites by more than two fold compared to the AZF alone. KLF3 FD also directed more binding to the promoter regions. Further investigations of these acquired sites identified a substantial portion of these sites as the known endogenous KLF3 bound regions, whilst others contain sequences that are similar but not identical to the predicted AZF target sequence. These results clearly demonstrate that the specific localisation of this model transcription factor to target genes is not solely dependent on the DBD and that the regions outside of this domain may also play an important role. ChIP-Seq experiments were performed on four HEK293 cell lines, two each stably expressing AZF or KLF3FD.AZF or KLF3FD only (two biological replicates). Input samples were included as controls.