Project description:The protein expression changes was measured at five time points (Exp1: 0, 12, 24 h; Exp2: 6, 12, 48 h) in differentiating THP-1 cell (human) cells and at three time points(0, 12, 24 h) in differentiating C2C12 cells(mouse), using two triple, or one triple Stable isotope labeling by amino acids in cell culture (SILAC) experiment, respectively. These measurements were compared to the relative synthesis and degradation rates in both proliferating and differentiating cells. All measurements were performed in biological triplicates. Sample processing: The lysate was boiled in 1 % deoxycholate, before being separated by SDS-PAGE and/or in-solution digested to peptides and separated by isoelectric focusing (IEF). Finally we measured the synthesis and degradation rates of macromolecular sub-complexes as they eluted from a size exclusion chromatography (SEC) column. Here the cells were lysed by douncing, macromolecular complexes concentrated on a 100 kDa molecular weight cut-off filter, before being fractionated by HPLC-SEC into 48 fractions. The fractions were subsequently individually in solution-digested and analyzed by LC-MS/MS. As a general rule it seems that protein expression is largely controlled by changes in the relative synthesis rate, whereas the relative degradation rate of the majority of proteins stays constant. In these data, we also observe that the proteins in defined sub-structures of larger protein complexes tend to have highly correlated synthesis and degradation rates but that this does not necessarily extend to the holo-complex. Data analysis: Raw MS files from an LTQ-Orbitrap or LTQ-Orbitrap-Velos were analyzed by MaxQuant, MS/MS spectra were searched against Uniprot (proteomes) human 21/6/2011 or mouse 20/4/2012 by the Andromeda search engine. For identification, the false discovery rate (FDR) was set to 0.01 on the protein and on the peptide levels.

Project description:Mole (MSR) and fractional (FSR) synthesis rates of proteins during C2C12 myoblast differentiation were investigated. Myoblast cultures supplemented with D2O during 0-24 h or 72-96 h of differentiation were analysed by LC-MS/MS to calculate protein FSR and MSR after samples were spiked with yeast alcohol dehydrogenase (ADH1).

Project description:WDR5 is a highly-conserved nuclear protein that performs multiple scaffolding functions in the context of chromatin. WDR5 is also a promising target for pharmacological inhibition in cancer, with small molecule inhibitors of an arginine-binding pocket of WDR5 (the 'WIN' site) showing efficacy against a range of cancer cell lines in vitro. Efforts to understand WDR5, or establish the mechanism of action of WIN site inhibitors, however, are stymied by its many functions in the nucleus, and a lack of knowledge of the conserved gene networks-if any-that are under its control. Here, we have performed comparative genomic analyses to identify the conserved sites of WDR5 binding to chromatin, and the conserved genes regulated by WDR5, across a diverse panel of cancer cell lines. We show that a specific cohort of protein synthesis genes (PSGs) are invariantly bound by WDR5, demonstrate that the WIN site anchors WDR5 to chromatin at these sites, and establish that PSGs are bona fide, acute, and persistent targets of WIN site blockade. Together, these data reveal that WDR5 plays a predominant transcriptional role in biomass accumulation and provide further evidence that WIN site inhibitors act to repress gene networks linked to protein synthesis homeostasis.

Project description:WDR5 is a highly-conserved nuclear protein that performs multiple scaffolding functions in the context of chromatin. WDR5 is also a promising target for pharmacological inhibition in cancer, with small molecule inhibitors of an arginine-binding pocket of WDR5 (the "WIN" site) showing efficacy against a range of cancer cell lines in vitro. Efforts to understand WDR5, or establish the mechanism of action of WIN site inhibitors, however, are stymied by its many functions in the nucleus, and a lack of knowledge of the conserved gene networks—if any—that are under its control. Here, we have performed comparative genomic analyses to identify the conserved sites of WDR5 binding to chromatin, and the conserved genes regulated by WDR5, across a diverse panel of cancer cell lines. We show that a specific cohort of protein synthesis genes (PSGs) are invariantly bound by WDR5, demonstrate that the WIN site anchors WDR5 to chromatin at these sites, and establish that PSGs are both acute and persistent targets of WIN site blockade. Together, these data reveal that WDR5 plays a predominant transcriptional role in biomass accumulation and reinforce the notion that WIN site inhibitors kill sensitive cancer cells by disrupting protein synthesis homeostasis.

Project description:The intestinal epithelium is a dynamic barrier that maintains the distinct environments of intestinal tissue and lumen. Epithelial barrier function is defined principally by tight junctions, which, in turn, depend on the regulated expression of claudin family proteins. Claudins are expressed differentially during intestinal epithelial cell (IEC) differentiation. However, regulatory mechanisms governing claudin expression during epithelial differentiation are incompletely understood. We investigated the molecular mechanisms regulating claudin-7 during IEC differentiation. Claudin-7 expression is increased as epithelial cells differentiate along the intestinal crypt-luminal axis. By using model IECs we observed increased claudin-7 mRNA and nascent heteronuclear RNA levels during differentiation. A screen for potential regulators of the CLDN7 gene during IEC differentiation was performed using a transcription factor/DNA binding array, CLDN7 luciferase reporters, and in silico promoter analysis. We identified hepatocyte nuclear factor 4α as a regulatory factor that bound endogenous CLDN7 promoter in differentiating IECs and stimulated CLDN7 promoter activity. These findings support a role of hepatocyte nuclear factor 4α in controlling claudin-7 expression during IEC differentiation.

Project description:WDR5 is a conserved regulator of protein synthesis gene expression

Project description:ATF6 encodes a transcription factor that is anchored in the endoplasmic reticulum (ER) and activated during the unfolded protein response (UPR) to protect cells from ER stress. Deletion of the isoform activating transcription factor 6? (ATF6?) and its paralog ATF6? results in embryonic lethality and notochord dysgenesis in nonhuman vertebrates, and loss-of-function mutations in ATF6? are associated with malformed neuroretina and congenital vision loss in humans. These phenotypes implicate an essential role for ATF6 during vertebrate development. We investigated this hypothesis using human stem cells undergoing differentiation into multipotent germ layers, nascent tissues, and organs. We artificially activated ATF6 in stem cells with a small-molecule ATF6 agonist and, conversely, inhibited ATF6 using induced pluripotent stem cells from patients with ATF6 mutations. We found that ATF6 suppressed pluripotency, enhanced differentiation, and unexpectedly directed mesodermal cell fate. Our findings reveal a role for ATF6 during differentiation and identify a new strategy to generate mesodermal tissues through the modulation of the ATF6 arm of the UPR.

Project description:A regulated splicing event in protein 4.1R pre-mRNA-the inclusion of exon 16-encoding peptides for spectrin-actin binding-occurs in late erythroid differentiation. We defined the functional significance of an intronic splicing enhancer, UGCAUG, and its cognate splicing factor, mFox2A, on exon 16 splicing during differentiation. UGCAUG displays cell-type-specific splicing regulation in a test neutral reporter and has a dose-dependent enhancing effect. Erythroid cells express 2 UGCAUG-binding mFox-2 isoforms, an erythroid differentiation-inducible mFox-2A and a commonly expressed mFox-2F. When overexpressed, both enhanced internal exon splicing in an UGCAUG-dependent manner, with mFox-2A exerting a much stronger effect than mFox-2F. A significant reciprocal increase in mFox-2A and decrease in mFox-2F occurred during erythroid differentiation and correlated with exon 16 inclusion. Furthermore, isoform-specific expression reduction reversed mFox-2A-enhancing activity, but not that of mFox-2F on exon 16 inclusion. Our results suggest that an erythroid differentiation-inducible mFox-2A isoform is a critical regulator of the differentiation-specific exon 16 splicing switch, and that its up-regulation in late erythroid differentiation is vital for exon 16 splicing.

Project description:CD4+ T follicular helper (Tfh) cells are essential for germinal center (GC) and high-affinity antibody responses. Yet the regulation that determines the initial development of Tfh cells is still largely unknown. Here we find that transcription factor Foxp1, previously shown to be essential in maintaining T cell quiescence, is a rate-limiting and essential negative regulator of Tfh cell differentiation. NaM-CM-/ve CD4+ T cells constitutively express Foxp1A, and stimulation through the T cell receptor (TCR) transiently induces the expression of a shorter Foxp1D isoform. In T cell-dependent (TD) humoral responses, CD4+ T cells deficient in all Foxp1 isoforms preferentially differentiate into Tfh cells, resulting in substantially increased GC and antibody responses. This negative regulation of Foxp1 on Tfh cell differentiation shows profound dominance: even in the absence of B cells, Foxp1-deficient CD4+ T cells differentiate into Tfh cells with high frequencies and sustained Bcl6 expression. Further, in the absence of Foxp1, Tfh cells are generated in higher frequencies than seen with Bcl6 overexpression and Tfh cell differentiation becomes significantly resistant to Blimp1-mediated repression. Finally, our experiments reveal specific roles of Foxp1A and Foxp1D in inhibiting Tfh cell differentiation: TCR-induced Foxp1D functions as a M-bM-^@M-^XgatekeeperM-bM-^@M-^Y to block the initial Tfh cell development, and together Foxp1A and Foxp1D proteins inversely determine Tfh cell generation in a dosage-dependent manner. Our study suggests that two Foxp1 isoforms provide a M-bM-^@M-^\double checkM-bM-^@M-^] mechanism as fundamental regulators in Tfh cell differentiation and humoral responses. Gene expression analysis of ex vivo OT-II Foxp1-WT Tfh cells and OT-II Foxp-conditional knockout (CKO) Tfh cells 5 days after immunization.

Project description:BackgroundThe guanine nucleotide binding protein (G protein)-coupled receptors (GPCRs) regulate cell growth, proliferation and differentiation. G proteins are also implicated in erythroid differentiation, and some of them are expressed principally in hematopoietic cells. GPCRs-linked NO/cGMP and p38 MAPK signaling pathways already demonstrated potency for globin gene stimulation. By analyzing erythroid progenitors, derived from hematopoietic cells through in vitro ontogeny, our study intends to determine early markers and signaling pathways of globin gene regulation and their relation to GPCR expression.ResultsHuman hematopoietic CD34+ progenitors are isolated from fetal liver (FL), cord blood (CB), adult bone marrow (BM), peripheral blood (PB) and G-CSF stimulated mobilized PB (mPB), and then differentiated in vitro into erythroid progenitors. We find that growth capacity is most abundant in FL- and CB-derived erythroid cells. The erythroid progenitor cells are sorted as 100% CD71+, but we did not find statistical significance in the variations of CD34, CD36 and GlyA antigens and that confirms similarity in maturation of studied ontogenic periods. During ontogeny, beta-globin gene expression reaches maximum levels in cells of adult blood origin (176 fmol/μg), while gamma-globin gene expression is consistently up-regulated in CB-derived cells (60 fmol/μg). During gamma-globin induction by hydroxycarbamide, we identify stimulated GPCRs (PTGDR, PTGER1) and GPCRs-coupled genes known to be activated via the cAMP/PKA (ADIPOQ), MAPK pathway (JUN) and NO/cGMP (PRPF18) signaling pathways. During ontogeny, GPR45 and ARRDC1 genes have the most prominent expression in FL-derived erythroid progenitor cells, GNL3 and GRP65 genes in CB-derived cells (high gamma-globin gene expression), GPR110 and GNG10 in BM-derived cells, GPR89C and GPR172A in PB-derived cells, and GPR44 and GNAQ genes in mPB-derived cells (high beta-globin gene expression).ConclusionsThese results demonstrate the concomitant activity of GPCR-coupled genes and related signaling pathways during erythropoietic stimulation of globin genes. In accordance with previous reports, the stimulation of GPCRs supports the postulated connection between cAMP/PKA and NO/cGMP pathways in activation of γ-globin expression, via JUN and p38 MAPK signaling.