Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:SRF is a ubiquitous transcription factor that binds DNA in association with myocardin-family proteins (e.g. MKL1), or the ternary complex factor (TCF) family of ETS proteins. In primary hematopoietic cells, knockout of either SRF or MKL1 decreases megakaryocyte maturation caused thrombocytopenia, and MKL1 over-expression (MKL1OE) in the Human Erythroleukemia (HEL) cell line enhances megakaryopoiesis, but the mechanisms underlying these effects are unknown. To elucidate the role of SRF and MKL1 in megakaryopoiesis, integrated analysis was performed of anti-SRF ChIP-seq and RNA-seq data in undifferentiated and differentiated HEL cells, both with and without induction of MKL1OE. MKL1OE enhances TPA-induced megakaryopoiesis with 25% of genes upregulated, as opposed to 11% with TPA alone. MKL1OE increases SRF binding to genomic sites, and enhances expression of specific target cytoskeletal genes in response to TPA. Genes upregulated in response to TPA are predicted to be regulated by SRF and ETS factors, whereas those upregulated in TPA plus MKL1OE lack ETS binding motifs. Using ChIP-PCR, we validated that both SRF and MKL1 have increased binding at target upregulated genes, e.g. CORO1A, with MKL1OE. We show for the first time that MKL1 increases both the genomic association and activity of SRF, and upregulates genes that enhance megakaryopoiesis.

Project description:SRF is a ubiquitous transcription factor that binds DNA in association with myocardin-family proteins (e.g. MKL1), or the ternary complex factor (TCF) family of ETS proteins. In primary hematopoietic cells, knockout of either SRF or MKL1 decreases megakaryocyte maturation caused thrombocytopenia, and MKL1 over-expression (MKL1OE) in the Human Erythroleukemia (HEL) cell line enhances megakaryopoiesis, but the mechanisms underlying these effects are unknown. To elucidate the role of SRF and MKL1 in megakaryopoiesis, integrated analysis was performed of anti-SRF ChIP-seq and RNA-seq data in undifferentiated and differentiated HEL cells, both with and without induction of MKL1OE. MKL1OE enhances TPA-induced megakaryopoiesis with 25% of genes upregulated, as opposed to 11% with TPA alone. MKL1OE increases SRF binding to genomic sites, and enhances expression of specific target cytoskeletal genes in response to TPA. Genes upregulated in response to TPA are predicted to be regulated by SRF and ETS factors, whereas those upregulated in TPA plus MKL1OE lack ETS binding motifs. Using ChIP-PCR, we validated that both SRF and MKL1 have increased binding at target upregulated genes, e.g. CORO1A, with MKL1OE. We show for the first time that MKL1 increases both the genomic association and activity of SRF, and upregulates genes that enhance megakaryopoiesis.

Project description:MKL1 augments megakaryocyte maturation by enhancing the SRF regulatory axis

Project description:MKL1 augments megakaryocyte maturation by enhancing the SRF regulatory axis [ChIP-seq]

Project description:MKL1 augments megakaryocyte maturation by enhancing the SRF regulatory axis [RNA-seq]

Project description:Thrombocytopenia is a major side effect of a new class of anticancer agents that target histone deacetylase (HDAC). Their mechanism is poorly understood. Here, we show that HDAC6 inhibition and genetic knockdown lead to a strong decrease in human proplatelet formation (PPF). Unexpectedly, HDAC6 inhibition-induced tubulin hyperacetylation has no effect on PPF. The PPF decrease induced by HDAC6 inhibition is related to cortactin (CTTN) hyperacetylation associated with actin disorganization inducing important changes in the distribution of megakaryocyte (MK) organelles. CTTN silencing in human MKs phenocopies HDAC6 inactivation and knockdown leads to a strong PPF defect. This is rescued by forced expression of a deacetylated CTTN mimetic. Unexpectedly, unlike human-derived MKs, HDAC6 and CTTN are shown to be dispensable for mouse PPF in vitro and platelet production in vivo. Our results highlight an unexpected function of HDAC6-CTTN axis as a positive regulator of human but not mouse MK maturation.

Project description:The paucity of knowledge about cardiomyocyte maturation is a major bottleneck in cardiac regenerative medicine. In development, cardiomyocyte maturation is characterized by orchestrated structural, transcriptional, and functional specializations that occur mainly at the perinatal stage. Sarcomeres are the key cytoskeletal structures that regulate the ultrastructural maturation of other organelles, but whether sarcomeres modulate the signal transduction pathways that are essential for cardiomyocyte maturation remains unclear. To address this question, here we generated mice with cardiomyocyte-specific, mosaic, and hypomorphic mutations of α-actinin-2 (Actn2) to study the cell-autonomous roles of sarcomeres in postnatal cardiomyocyte maturation. Actn2 mutation resulted in defective structural maturation of transverse-tubules and mitochondria. In addition, Actn2 mutation triggered transcriptional dysregulation, including abnormal expression of key sarcomeric and mitochondrial genes, and profound impairment of the normal progression of maturational gene expression. Mechanistically, the transcriptional changes in Actn2 mutant cardiomyocytes strongly correlated with those in cardiomyocytes deleted of serum response factor (SRF), a critical transcription factor that regulates cardiomyocyte maturation. Actn2 mutation increased the monomeric form of cardiac α-actin, which interacted with the SRF cofactor MRTFA and perturbed its nuclear localization. Overexpression of a dominant-negative MRTFA mutant was sufficient to recapitulate the morphological and transcriptional defects in Actn2 and Srf mutant cardiomyocytes. Together, these data indicate that Actn2-based sarcomere organization regulates structural and transcriptional maturation of cardiomyocytes through MRTF-SRF signaling.

Project description:The transcription factor GATA1 coordinates timely activation and repression of megakaryocyte gene expression. Loss of GATA1 function results in excessive megakaryocyte proliferation and disordered terminal platelet maturation, leading to thrombocytopenia and leukemia in patients. The mechanisms by which GATA1 does this are unclear. We have used in vivo biotinylated GATA1 to isolate megakaryocyte GATA1-partner proteins. Here, several independent approaches show that GATA1 interacts with several proteins in the megakaryocyte cell line L8057 and in primary megakaryocytes. They include FOG1, the NURD complex, the pentameric complex containing SCL/TAL-1, the zinc-finger regulators GFI1B and ZFP143, and the corepressor ETO2. Knockdown of ETO2 expression promotes megakaryocyte differentiation and enhances expression of select genes expressed in terminal megakaryocyte maturation, eg, platelet factor 4 (Pf4). ETO2-dependent direct repression of the Pf4 proximal promoter is mediated by GATA-binding sites and an E-Box motif. Consistent with this, endogenous ETO2, GATA1, and the SCL pentameric complex all specifically bind the promoter in vivo. Finally, as ETO2 expression is restricted to immature megakaryocytes, these data suggest that ETO2 directly represses inappropriate early expression of a subset of terminally expressed megakaryocyte genes by binding to GATA1 and SCL.

Project description:The molecular mechanism underlying the initiation of somatic cell reprogramming into induced pluripotent stem cells (iPSCs) has not been well described. Thus, we generated single-cell-derived clones by using a combination of drug-inducible vectors encoding transcription factors (Oct4, Sox2, Klf4 and Myc) and a single-cell expansion strategy. This system achieved a high reprogramming efficiency after metabolic and epigenetic remodeling. Functional analyses of the cloned cells revealed that extracellular signal-regulated kinase (ERK) signaling was downregulated at an early stage of reprogramming and that its inhibition was a driving force for iPSC formation. Among the reprogramming factors, Myc predominantly induced ERK suppression. ERK inhibition upregulated the conversion of somatic cells into iPSCs through concomitant suppression of serum response factor (SRF). Conversely, SRF activation suppressed the reprogramming induced by ERK inhibition and negatively regulated embryonic pluripotency by inducing differentiation via upregulation of immediate early genes, such as c-Jun, c-Fos and EGR1. These data reveal that suppression of the ERK-SRF axis is an initial molecular event that facilitates iPSC formation and may be a useful surrogate marker for cellular reprogramming.