Project description:Myocardin-related transcription factors (MRTFs) are coactivators of serum response factor (SRF), and thereby regulate cytoskeletal gene expression in response to actin dynamics. MRTFs have also been implicated in heat shock protein (hsp) transcription in fly ovaries, but the mechanisms remain unclear. Here we demonstrate that in mammalian cells, MRTFs are dispensable for hsp gene induction. However, the widely used small molecule inhibitors of MRTF/SRF transcription pathway, derived from CCG-1423, efficiently inhibit hsp gene transcription in both fly and mammalian cells also in absence of MRTFs. Quantifying RNA synthesis and RNA polymerase distribution demonstrates that CCG-1423-derived compounds have a genome-wide effect on transcription. Indeed, tracking nascent transcription at nucleotide resolution reveals that CCG-1423-derived compounds reduce RNA polymerase II elongation, and severely dampen the transcriptional response to heat shock. The effects of CCG-1423-derived compounds therefore extend beyond the MRTF/SRF pathway into nascent transcription, opening novel opportunities for their use in transcription research.

Project description:Myocardin-related transcription factors (MRTFs) are coactivators of serum response factor (SRF), and thereby regulate cytoskeletal gene expression in response to actin dynamics. MRTFs have also been implicated in heat shock protein (hsp) transcription in fly ovaries, but the mechanisms remain unclear. Here we demonstrate that in mammalian cells, MRTFs are dispensable for hsp gene induction. However, the widely used small molecule inhibitors of MRTF/SRF transcription pathway, derived from CCG-1423, efficiently inhibit hsp gene transcription in both fly and mammalian cells also in absence of MRTFs. Quantifying RNA synthesis and RNA polymerase distribution demonstrates that CCG-1423-derived compounds have a genome-wide effect on transcription. Indeed, tracking nascent transcription at nucleotide resolution reveals that CCG-1423-derived compounds reduce RNA polymerase II elongation, and severely dampen the transcriptional response to heat shock. The effects of CCG-1423-derived compounds therefore extend beyond the MRTF/SRF pathway into nascent transcription, opening novel opportunities for their use in transcription research.

Project description:To identify in vivo new cardiac SRF target genes and to study the response of these novel genes to SRF overexpression, we employed a cardiac-specific, transgenic mouse model that has a phenotype in young adulthood which resembles that of the typically aged heart. Using this “cardiac aging” model, we identified 207 genes that are important to cardiac function that were differentially expressed in vivo. Among them, 192 genes had SRF binding motifs (56 with CArG and 136 with CArG-like elements) in their promoter region. Fifty-one of 56 genes with classic CArG elements were not previously reported. These SRF target genes were grouped into 12 categories based on their function. It was observed that genes associated with cardiac energy metabolism shifted toward that of carbohydrate metabolism and away from that of fatty acid metabolism. The expression of genes that are involved in transcription and ion regulation were decreased, but expression of cytoskeletal genes were significantly increased. Using public databases of mouse models of stress, we also found that altered expression of the SRF target genes occurred in these hearts as well. Thus, SRF target genes are actively regulated under various physiological and pathological conditions, including hemodynamic stress. The mild elevation of SRF protein in the rodent heart that is observed during typical adult aging may have a major impact on many SRF target genes, thereby affecting cardiac structure and performance. In addition, these results could help to enhance our understanding of SRF regulation of cellular processes, including metabolic and cytoskeletal function. The generation and characterization of transgenic mice with mild cardiac-specific overexpression of SRF was previously reported (Zhang et al., 2003). At 6 months of age, the transgenic mice manifested cardiac changes suggestive of an “aged heart” (Zhang et al., 2003). Therefore, 6-month-old transgenic and non-transgenic mice were used in this study. Cardiac gene expression in SRF Tg heart was compared to that of wild-type mice.

Project description:Analysis of serum starved PC-3 cells treated with CCG-1423, Latrunculin B, or the transcription elongation inhibitor DRB for 2 or 24 hours. Results provide insights to potential therapeutic approaches to cancer metastasis.

Project description:Analysis of serum starved PC-3 cells treated with CCG-1423, Latrunculin B, or the transcription elongation inhibitor DRB for 2 or 24 hours. Results provide insights to potential therapeutic approaches to cancer metastasis. Twenty one samples in triplicate were analyzed and compared to the DMSO-treated control. The primary condition tested was the effect of the Rho-transcription pathway inhibitor, CCG-1423 As a biologically related control, the actin polymerization inhibitor, Latrunculin B, that also blocks Rho-stimulated gene transcription was tested. As a control for non-specific transcription inhibition, DRB was used. All samples, 2-hr and 24-hr treated samples were compared to the 24-hr DMSO sample.

Project description:PGM1 deficiency is recognized as the third most common N-linked Congenital Disorders of Glycosylation (CDG) in humans. Affected individuals present with liver, musculoskeletal, endocrine, and coagulation symptoms; however, the most life-threatening complication is an early onset of dilated cardiomyopathy (DCM). Recently, we discovered that oral D-galactose supplementation improved liver disease, endocrine and coagulation abnormalities, but does not alleviate the fatal cardiomyopathy and the associated myopathy. To study the pathobiology of the cardiac disease observed in PGM1-CDG, we constructed a novel cardiomyocyte-specific conditional Pgm2 (mouse ortholog of human PGM1) knockout (Pgm2 cKO) mouse model. Echocardiography studies corroborated a DCM phenotype with significantly reduced ejection fraction and left ventricular dilatation similar to those seen in individuals with PGM1-CDG. Histological studies demonstrated excess glycogen accumulation and fibrosis, while ultrastructural analysis revealed Z-disk disarray and swollen/fragmented mitochondria. We observed similar ultrastructural pathology in the cardiac explant of an individual with PGM1-CDG. We found decreased mitochondrial function in the heart of Pgm2 cKO mice. Transcriptomic analysis of hearts from Pgm2 cKO mice demonstrated a gene signature of DCM. Although proteomics revealed only mild changes in global protein expression in left ventricular tissue of Pgm2 cKO mice, a glycoproteomic analysis revealed an overall decreased protein glycosylation with significant glycosylation defects in sarcolemmal proteins including different subunits of laminin protein. Finally, augmentation of PGM1 in KO mice via AAV9-PGM1 gene replacement therapy prevented and halted the progression of the DCM phenotype.

Project description:Insulin resistance in skeletal muscle is a key phenotype associated with type 2 diabetes (T2D) and is even present in offspring of diabetic parents. However, molecular mediators of insulin resistance remain unclear. We find that the top-ranking gene set in expression analysis of muscle from humans with T2D and normoglycemic insulin resistant subjects with parental family history (FH+) of T2D is increased expression of actin cytoskeleton genes regulated by serum response factor (SRF) and its coactivator MKL1. Furthermore, the SRF activator STARS is upregulated in FH+ and T2D and inversely correlated with insulin sensitivity. These patterns are recapitulated in insulin resistant mice, and linked to alterations in two other regulators of this pathway: reduced G-actin and increased nuclear localization of MKL1. Both genetic and pharmacologic manipulation of STARS/MKL1/SRF pathway significantly alter insulin action: 1) Overexpression of MKL1 or reduction in G-actin decreased insulin-stimulated Akt phosphorylation; 2) reduced STARS expression increased insulin signalling and glucose uptake, and 3) SRF inhibition by CCG-1423 reduced nuclear MKL1, improved glucose uptake, and improved glucose tolerance in insulin resistant mice in vivo. Thus, SRF pathway alterations are a signature of insulin resistance which may also contribute to T2D pathogenesis and be a novel therapeutic target.

Project description:To identify in vivo new cardiac SRF target genes and to study the response of these novel genes to SRF overexpression, we employed a cardiac-specific, transgenic mouse model that has a phenotype in young adulthood which resembles that of the typically aged heart. Using this “cardiac aging” model, we identified 207 genes that are important to cardiac function that were differentially expressed in vivo. Among them, 192 genes had SRF binding motifs (56 with CArG and 136 with CArG-like elements) in their promoter region. Fifty-one of 56 genes with classic CArG elements were not previously reported. These SRF target genes were grouped into 12 categories based on their function. It was observed that genes associated with cardiac energy metabolism shifted toward that of carbohydrate metabolism and away from that of fatty acid metabolism. The expression of genes that are involved in transcription and ion regulation were decreased, but expression of cytoskeletal genes were significantly increased. Using public databases of mouse models of stress, we also found that altered expression of the SRF target genes occurred in these hearts as well. Thus, SRF target genes are actively regulated under various physiological and pathological conditions, including hemodynamic stress. The mild elevation of SRF protein in the rodent heart that is observed during typical adult aging may have a major impact on many SRF target genes, thereby affecting cardiac structure and performance. In addition, these results could help to enhance our understanding of SRF regulation of cellular processes, including metabolic and cytoskeletal function. The generation and characterization of transgenic mice with mild cardiac-specific overexpression of SRF was previously reported (Zhang et al., 2003). At 6 months of age, the transgenic mice manifested cardiac changes suggestive of an “aged heart” (Zhang et al., 2003). Therefore, 6-month-old transgenic and non-transgenic mice were used in this study.

Project description:Insulin resistance in skeletal muscle is a key phenotype associated with type 2 diabetes (T2D) and is even present in offspring of diabetic parents. However, molecular mediators of insulin resistance remain unclear. We find that the top-ranking gene set in expression analysis of muscle from humans with T2D and normoglycemic insulin resistant subjects with parental family history (FH+) of T2D is increased expression of actin cytoskeleton genes regulated by serum response factor (SRF) and its coactivator MKL1. Furthermore, the SRF activator STARS is upregulated in FH+ and T2D and inversely correlated with insulin sensitivity. These patterns are recapitulated in insulin resistant mice, and linked to alterations in two other regulators of this pathway: reduced G-actin and increased nuclear localization of MKL1. Both genetic and pharmacologic manipulation of STARS/MKL1/SRF pathway significantly alter insulin action: 1) Overexpression of MKL1 or reduction in G-actin decreased insulin-stimulated Akt phosphorylation; 2) reduced STARS expression increased insulin signalling and glucose uptake, and 3) SRF inhibition by CCG-1423 reduced nuclear MKL1, improved glucose uptake, and improved glucose tolerance in insulin resistant mice in vivo. Thus, SRF pathway alterations are a signature of insulin resistance which may also contribute to T2D pathogenesis and be a novel therapeutic target. Skeletal muscle samples were obtained from 10 subjects with type 2 diabetes, 25 subjects with a family history of type 2 diabetes (one or both parents), and 15 subjects with no family history of type 2 diabetes. In this analysis RNA was isolated for cRNA preparation and hybridized to Affymetrix Human Genome U133 Plus 2.0 microarrays.

Project description:Myocardin-Related Transcription Factors A and B (MRTF-A and MRTF-B) are highly homologous proteins that function as powerful coactivators of serum response factor (SRF), a ubiquitously expressed transcription factor essential for cardiac development. The SRF/MRTF complex binds to CArG boxes found in the control regions of genes that regulate cytoskeletal dynamics and muscle contraction, among other processes. While SRF is required for heart development and function, the role of MRTFs in the developing or adult heart has not been explored. Through cardiac-specific deletion of MRTF alleles in mice, we show that either MRTF-A or MRTF-B is dispensable for cardiac development and function, whereas deletion of both MRTF-A and MRTF-B causes a spectrum of structural and functional cardiac abnormalities. Defects observed in MRTF-A/B null mice ranged from reduced cardiac contractility and adult onset heart failure to neonatal lethality accompanied by sarcomere disarray. RNA-seq analysis on neonatal hearts identified the most altered pathways in MRTF double knockout hearts as being involved in cytoskeletal organization. Together, these findings demonstrate redundant but essential roles of the MRTFs in maintenance of cardiac structure and function and as indispensible links in cardiac cytoskeletal gene regulatory networks.