Project description:Phenotypic modulation of smooth muscle cells (SMC) is a hallmark of vascular disease and a classic cell state transformation mediated by convergent signal-integration in the nucleus. Here, using PDGF-mediated SMC activation, we describe for the first time the dynamic active chromatin response and global transcriptional remodeling of cell state. We find that PDGF stimulation drives global transcriptional amplification and anabolism concurrent with increased proliferation and motility. Kinetic gene expression and Brd4 chromatin co-activator occupancy analysis reveals transcription factor (TF) directed enhancer re-wiring shaped by an immediate-early (Jun/Fos) response followed by increased nuclear hormone receptor transcriptional signaling that is Rev-erbdependent. Interdicting signaling between enhancers and transcription via Brd4 inhibition halts canonical cellular features of PDGF stimulation, and in vivo Brd4 inhibition potently abrogates vascular injury responses. These data provide a global map of TF-directed chromatin remodeling during SMC phenotypic modulation and elucidate key therapeutic mechanisms of transcriptional inhibition in vascular disease.

Project description:Phenotypic modulation of smooth muscle cells (SMC) is a hallmark of vascular disease and a classic cell state transformation mediated by convergent signal-integration in the nucleus. Here, using PDGF-mediated SMC activation, we describe for the first time the dynamic active chromatin response and global transcriptional remodeling of cell state. We find that PDGF stimulation drives global transcriptional amplification and anabolism concurrent with increased proliferation and motility. Kinetic gene expression and Brd4 chromatin co-activator occupancy analysis reveals transcription factor (TF) directed enhancer re-wiring shaped by an immediate-early (Jun/Fos) response followed by increased nuclear hormone receptor transcriptional signaling that is Rev-erbdependent. Interdicting signaling between enhancers and transcription via Brd4 inhibition halts canonical cellular features of PDGF stimulation, and in vivo Brd4 inhibition potently abrogates vascular injury responses. These data provide a global map of TF-directed chromatin remodeling during SMC phenotypic modulation and elucidate key therapeutic mechanisms of transcriptional inhibition in vascular disease.

Project description:Phenotypic modulation of smooth muscle cells (SMC) is a hallmark of vascular disease and a classic cell state transformation mediated by convergent signal-integration in the nucleus. Here, using PDGF-mediated SMC activation, we describe for the first time the dynamic active chromatin response and global transcriptional remodeling of cell state. We find that PDGF stimulation drives global transcriptional amplification and anabolism concurrent with increased proliferation and motility. Kinetic gene expression and Brd4 chromatin co-activator occupancy analysis reveals transcription factor (TF) directed enhancer re-wiring shaped by an immediate-early (Jun/Fos) response followed by increased nuclear hormone receptor transcriptional signaling that is Rev-erbdependent. Interdicting signaling between enhancers and transcription via Brd4 inhibition halts canonical cellular features of PDGF stimulation, and in vivo Brd4 inhibition potently abrogates vascular injury responses. These data provide a global map of TF-directed chromatin remodeling during SMC phenotypic modulation and elucidate key therapeutic mechanisms of transcriptional inhibition in vascular disease.

Project description:Platelet-derived growth factor (PDGF) signalling and the subsequent activation of the calcium ion channel, ORAI1 are critical drivers of pathological remodelling of native vascular smooth muscle cells to proliferative state, which is a process associated with various vascular diseases. This study aims to reveal transcriptional networks altered following ORAI1 inhibition in vascular smooth muscle cells. To study the effect of ORAI1 inhibition on VSMC biology, we performed RNA-Seq analysis of PDGF-stimulated primary human aortic smooth muscle cells treated with either ORAI1 inhibitor, (n=4) or with vehicle (n=4), and investigated the effect of ORAI1 inhibition on the transcriptional response of cells.

Project description:Unlike other terminally differentiated cell types, vascular SMCs display remarkable phenotypic plasticity. The adult, differentiated state is traditionally defined by expression of well-characterized SMC contractile genes. Extracellular cues, however, can induce contractile SMCs to remodel toward a synthetic state characterized by a spectrum of proliferative, migratory, and inflammatory phenotypes. We used whole-genome expression arrays to to identify genes associated with SMC phenotypic modulation. Experiment Overall Design: Rat aortic SMCs were serum-starved for 72 hours and subsequently treated with either PDGF-BB or its respective vehicle (n=2). RNA samples were hybridzed to Affymetrix arrays with the intent to identify early genes associated with SMC phenotypic modulation.

Project description:Smooth muscle cell (SMC) phenotypic switching from a contractile to a synthetic state is implicated in diverse vascular pathologies, including neointimal formation. This study was designed to identify lncRNAs that may play a role in vascular pathologies. Primary smooth muscle cells cultured from surplus human saphenous vein tissue were treated with inflammatory and proliferative stimuli, IL1α and PDGF, for 72h and RNA extracted for RNA-sequencing. Using edgeR processed data we found expression of many lncRNAs was altered following treatment and could play a role in vascular disease. 4 groups of samples, n= 3/group each replicate using cells cultured from a different venous patient sample. Cells were quiesced in 0.2% serum for 48h followed by addition of 10ng/ml IL1α , 20ng/ml PDGF or both 10ng/ml IL1α and 20ng/ml PDGF together. Cells were collected after 72h and RNA extracted using Qiagen RNeasy kits. RNA-sequencing was carried out by Beckman Coulter Genomics on the r-RNA depleted fraction.

Project description:The bromodomain and extraterminal (BET) protein Brd4 is a validated drug target in leukemia, yet its regulatory function in this disease is not well understood. Here, we show that Brd4 chromatin occupancy in acute myeloid leukemia closely correlates with the hematopoietic transcription factors (TFs) Pu.1, Fli1, Erg, C/EBPα, C/EBPβ, and Myb at nucleosome-depleted enhancer and promoter regions. We provide evidence that these TFs, in conjunction with the lysine acetyltransferase activity of p300/CBP, facilitate Brd4 recruitment to their occupied sites to promote transcriptional activation. Moreover, chemical inhibition of BET bromodomains is found to suppress the functional output each hematopoietic TF, thereby interfering with essential lineage-specific transcriptional circuits in this disease. These findings reveal a chromatin-based signaling cascade comprised of hematopoietic TFs, p300/CBP, and Brd4, which supports leukemia maintenance and is suppressed by BET bromodomain inhibition. ChIP-Seq for regulatory factors of Brd4 in MLL-AF9 transformed acute myeloid leukemia cells (RN2)

Project description:The bromodomain and extraterminal (BET) protein Brd4 is a validated drug target in leukemia, yet its regulatory function in this disease is not well understood. Here, we show that Brd4 chromatin occupancy in acute myeloid leukemia closely correlates with the hematopoietic transcription factors (TFs) Pu.1, Fli1, Erg, C/EBPα, C/EBPβ, and Myb at nucleosome-depleted enhancer and promoter regions. We provide evidence that these TFs, in conjunction with the lysine acetyltransferase activity of p300/CBP, facilitate Brd4 recruitment to their occupied sites to promote transcriptional activation. Moreover, chemical inhibition of BET bromodomains is found to suppress the functional output each hematopoietic TF, thereby interfering with essential lineage-specific transcriptional circuits in this disease. These findings reveal a chromatin-based signaling cascade comprised of hematopoietic TFs, p300/CBP, and Brd4, which supports leukemia maintenance and is suppressed by BET bromodomain inhibition. PolyA selected RNA-Seq for drug treated or shRNA-expressing MLL-AF9 transformed acute myeloid leukemia cells (RN2)

Project description:SILAC analysis of human primary bladder smooth muscle cells treated with platelet-derived growth factor for 0, 4, and 24 h. Platelet-derived growth factor-BB (PDGF-BB) is a mitogen and motogen that has been implicated in the proliferation, migration and synthetic activities of smooth muscle cells (SMC) that characterize pathologic tissue remodeling in hollow organs. To explore the signals induced by PDGF on a global scale, we performed expression profiling and quantitative proteomics analysis of PDGF-treated human visceral SMC. 1695 genes and 241 proteins were identified as differentially expressed in PDGF-treated primary bladder SMC versus non-treated cells. Analysis of gene expression data revealed MYC, JUN, EGR1, MYB and RUNX1 as the transcription factors most significantly networked with upregulated genes; DDIT3, NFAT5, and SOX5 were most networked with downregulated genes. For protein identification and quantification, raw mass spectrometric data were analyzed with MaxQuant software (version 1.0.13.13). The parameters were set as follows. In the Quant module, SILAC triplets was selected; oxidation (M) and acetyl (Protein N-term) were set as variable modification; carbamidomethyl (C) was set as fixed modification; concatenated IPI human database (version 3.52) (74,190 forward sequences and 74,190 reverse sequences) was used for database searching; all other parameters were default. Tandem mass spectra were searched by Mascot (version 2.2.0.4) (Matrix Science, Boston, MA). In the Identify module, all parameters were default, except that maximal peptide posterior error probability was set as 0.05. False discovery rates for protein and peptide identifications were both set at 0.01.

Project description:Smooth muscle cell (SMC) phenotypic switching from a contractile to a synthetic state is implicated in diverse vascular pathologies, including neointimal formation. This study was designed to identify lncRNAs that may play a role in vascular pathologies. Primary smooth muscle cells cultured from surplus human saphenous vein tissue were treated with inflammatory and proliferative stimuli, IL1α and PDGF, for 72h and RNA extracted for RNA-sequencing. Using edgeR processed data we found expression of many lncRNAs was altered following treatment and could play a role in vascular disease.