Author : Huanhuan Cui
Publisher :
Page : pages
File Size : 17,27 MB
Release : 2015
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ISBN :
Author : Jenny Ying Ying Ooi
Publisher :
Page : 392 pages
File Size : 36,89 MB
Release : 2013
Category :
ISBN :
At the cellular level, the hypertrophied myocardium is characterized by profound changes in gene transcription. Published literature suggests that histone acetylation/methylation as well as SWI/SNF chromatin remodeling factors may play a role in transcription regulation during cardiac hypertrophy. In addition, histone deacetylase inhibitors (HDACi) are able to attenuate cardiac hypertrophy and the gene program that accompanies the stressed heart. In this thesis, the role of chromatin modification as well as DNA methylation in gene regulation was explored in animal models of cardiac hypertrophy by defining protein-protein and protein-DNA complexes. SWI/SNF protein complexes were examined using coimmunoprecipitation with the SWI/SNF determinant, BRG1, coupled to mass spectrometry (ms). Due to the unexpected limitation of MALDI-ToF-tof ms and the abundance of contractile proteins in the heart, nuclear proteins of interest, including BRG1, could not be detected. An alternative approach was to examine protein-DNA complexes using chromatin immunoprecipitation (ChIP). Histone H3 lysine 9/14 acetylation (H3K9/K14ac) was characterized by massive parallel sequencing (ChIP-Seq), whereas gene expression changes determined by microarray. A mouse model of transverse aortic constriction (TAC) allowed investigation of cardiac hypertrophy, which was attenuated by the HDAC inhibitor, Trichostatin A (TSA). In response to TAC, the majority of genes have reduced H3K9/K14ac content on their promoters. Although TSA induced an increase in global H3K9/K14ac, gene promoters were also hypoacetylated. Differential H3K9/K14ac on a promoter did not necessarily correspond to alterations in gene expression during TAC or TSA prevention. We next focused on gene regulatory epigenetic changes on SERCA2a (a gene target identified from H3K9/K14ac ChIP-Seq). In response to TAC-induced-pathological hypertrophy, reduction in active histone marks as well as enrichment of repressive marks was consistent with suppression of SERCA2a gene expression. In the constitutively active PI3K animals (model of physiological hypertrophy), reduced histone H3 lysine 9 trimethylation (H3K9me3) levels were also associated with SERCA2a gene activation. Taken together, these experimental results suggest that the contribution of H3K9/K14ac to gene expression is not straightforward in the stressed heart. In addition, the data suggests a surprising complexity of gene regulation events that go beyond the traditional view of HDACi mediated histone hyperacetylation in cardiac hypertrophy.
Author : Lisa Hsiu Chuan Chang
Publisher :
Page : 528 pages
File Size : 18,77 MB
Release : 2013
Category :
ISBN :
Pathological cardiac hypertrophy is an initial compensatory response of the heart to a range of intrinsic stimuli including arterial hypertension, myocardial infarction and cardiomyopathy whereby prolonged stress often results in congestive heart failure and sudden death. This condition is commonly associated with the reactivation of the foetal gene program. Recent work has uncovered the importance of chromatin remodeling in the control of gene expression in heart disease. We used a transverse aortic constricted (TAC) mouse model to induce hypertrophy. The increased expression of Nppa, Nppb and embryonic Myh7 were inversely correlated with reduced expression of the adult Myh6 and Atp2a2 genes in TAC animals. We examined the regulatory complexes associated with hypertrophy and changes in the transcriptional response using strategies that allowed us to immunopurify soluble chromatin fractions. Chromatin immunopurifications were performed on the left ventricles of SHAM and TAC cardiac tissues. Quantification of the immunopurified chromatin indicated a unique pattern of binding on the promoters of Nppa, Nppb, Myh6 and Myh7 genes. Our findings suggested that the ATP-dependent chromatin remodeling complex, SWI/SNF, could act in a coordinated fashion with histone acetyltransferase (HAT) or histone deacetylase (HDAC) complexes to regulate the expression of these genes in the hypertrophic heart. SWI/SNF complex serves as a co-regulator in the development of pathological cardiac hypertrophy. We observed enrichment of SWI/SNF subunit BRM and p300 HAT during the reactivation of the foetal gene program on the promoters of upregulated Nppa, Nppb and Myh7 genes. We also observed the recruitment of the SWI/SNF subunit BRG1 and HDAC2 on the Myh6 gene which was consistent with its suppressed gene expression in the hypertrophic heart. The data presented indicate that components of SWI/SNF machinery are associated with diverse regulatory mechanism and the suppression and activation of gene expression. Suppression of HDACs is known to blunt pressure-overload cardiac hypertrophy. However, the molecular mechanism behind this blockade remains unclear. We used a broad-spectrum HDAC inhibitor, Trichostatin A (TSA) to investigate hypertrophy prevention in a mouse model of TAC. TSA treatment resulted in the downregulation of Nppa, Nppb and embryonic Myh7 which was intrinsically highly expressed in the hypertrophic heart. The observed changes in gene expression were found to be associated with concurrent release of BRM, H3K9/14 acetylation and recruitment of BRG1, HDAC2 on suppressed Nppa, Nppb and Myh6 gene promoters in the TSA treated TAC animals. This study described the reciprocoal association of SWI/SNF subunits, BRG1 and BRM, with histone modifications correlated with the regulation of cardiac gene transcription in pathological hypertrophy and their regulatory function in response to TSA exposure. To determine changes in the expression of genes mediated by pathological cardiac hypertrophy, we used a global approach using RNA-Seq. In recent years, high-throughput technologies have been developed and rapidly improved to interrogate several aspects of cellular processes. RNA-Seq was used to map global mRNA expression profile, providing a more sensitive approach than microarrays. It allowed the identification of rare transcripts and gene isoforms which the array approach was unable to detect. This was followed by further investigation using bioinformatics resources such as gene enrichment analysis, pathways, and regulatory network analysis. This enabled us to classify the differentially expressed genes and transcript isoforms into functional categories. A major challenge in deciphering the molecular mechanism associated with the development and prevention of cardiac hypertrophy is the identification of regulatory determinants that are thought to regulate gene expression. We have identified that SWI/SNF chromatin remodeling complex, more specifically, BRM was associated with HAT whereas BRG1 was associated with HDAC2 in correlation with gene expression. Further investigation of regulatory determinants mediated gene expression would need to be carried out to provide a useful framework for understanding and distinguishing the regulatory function of SWI/SNF in pathological cardiac hypertrophy. These studies could lead to more precise understanding of heart disease and potential new strategy to personalised therapies to prevent or reverse cardiac hypertrophy and in turn, cardiac failure.
Author : Gaurav Mehta
Publisher :
Page : 76 pages
File Size : 19,7 MB
Release : 2015
Category :
ISBN :
Cardiovascular disorders are the major cause of death in the western world with a total economic impact in billions of dollars. Heart failure represents a final common end point for various cardiovascular conditions and is responsible for high mortality rates. Cardiac hypertrophy is initiated as a cellular mechanism to protect the heart from increased hemodynamic load and ventricular wall tension. Contrary to physiological hypertrophy, pathological hypertrophy, if prolonged, is associated with increased cardiomyocyte loss and represents the most important factor responsible for heart failure. The hallmark feature of pathological hypertrophy is re-expression of the fetal gene program, which involves interplay between transcription factors and chromatin remodeling enzymes. The Microphthalmia-associated transcription factor (MITF) plays a critical role in the development of pathological cardiac hypertrophy in mice in response to isoproterenol and angiotensin II treatment. However, the transcriptional mechanisms by which MITF promotes cardiac hypertrophy have not been elucidated. Brahma-related gene 1 (BRG1), the catalytic ATPase subunit of the Switching defective/Sucrose Non-Fermenting (SWI/SNF) chromatin remodeling complex regulates cardiac hypertrophy in mice. Nonetheless, the transcriptional circuitry of BRG1 containing SWI/SNF complexes and the interaction with other proteins is not understood. In this study, we tested the hypothesis that MITF promotes pathological cardiac hypertrophy by activating transcription of pro-hypertrophy genes through interactions with the SWI/SNF chromatin remodeling complex. We utilized transverse aorta constriction (TAC) induced pressure overload as an in vivo model of pathological cardiac hypertrophy. The expression of MITF and the BRG1 subunit of the SWI/SNF complex increase coordinately in response to pressure overload. Expression of MITF and BRG1 also increased under in vitro conditions in cardiomyocytes isolated from adult mice when stimulated with angiotensin II. Rat heart-derived H9c2 cardiomyocytes showed a similar response when treated with isoproterenol, a known ß-adrenergic agonist. In H9c2 cells, both MITF and BRG1 were required to increase cardiomyocyte size and activate expression of hypertrophy markers: atrial natriuretic peptide (ANP) and brain natriuretic peptide (BNP) in response to ß-adrenergic stimulation. We detected physical interactions between the heart specific isoform of MITF (MITF-H) and BRG1 in cardiomyocytes as well as HEK 293T cells and found that they cooperate to regulate expression of a pro-hypertrophic transcription factor, GATA4. By utilizing Chromatin immunoprecipitation (ChIP), luciferase, and electrophoretic mobility shift assays, we demonstrate that MITF binds to the E box element in the GATA4 promoter. The binding of MITF facilitates recruitment of BRG1 and is associated with enhanced expression of the GATA4 gene as evidenced by increased Histone3 lysine4 tri-methylation (H3K4me3), an active mark of transcription on the GATA4 promoter. Further, down regulating MITF and BRG1 independently results in a significant abrogation in the expression of the GATA4 gene in H9c2 cells when treated with isoproterenol. Thus, in conclusion, we provide evidence that in hypertrophic cardiomyocytes, MITF is a key transcriptional activator of a pro-hypertrophic gene, GATA4, and this regulation is dependent upon the BRG1 component of the SWI/SNF complex.
Author : Silke Rickert-Sperling
Publisher : Springer Nature
Page : 1098 pages
File Size : 11,70 MB
Release :
Category :
ISBN : 3031440870
Author : Calvin Tyi Hang
Publisher :
Page : pages
File Size : 33,47 MB
Release : 2011
Category :
ISBN :
The heart is the first organ to function in development and continues to beat for seventy or more years in an adult's life. Cardiogenesis therefore is no simple task; genes have to be precisely regulated to meet the needs of a developing heart. ATP-dependent chromatin remodeling provides an important mechanism to regulate gene expression. Specifically, Brg1-associated factor, or the BAF, complexes, are crucial in heart development. Endocardial Brg1 represses the expression of a metalloproteinase, ADAMTS1, in order to allow sufficient cardiac jelly expansion for trabecular development. In addition, Brg1 functions in the myocardium to repress VEGFA to prevent the ectopic formation of coronary vasculature from the epicardium in a non-cell autonomous manner. And lastly, Brg1 serves as a bridge linking embryonic development and adult cardiomyopathies. Brg1 functions in the myocardium to keep the cardiomyocytes in a proliferating state through promoting BMP10 and repressing a cyclin-dependent kinase inhibitor p57kip2. Without Brg1, cardiomyocytes cease cell division, mature, and express adult form of myosin heavy (MHC) chain gene. Brg1 is normally turned off in adult life; however, following cardiac stress it is reactivated and turns on embryonic fetal program characterized by re-induction of embryonic MHC expression. Preventing Brg1 re-expression can repress cardiac hypertrophy and restore adult MHC expression. Furthermore, Brg1physically interacts with other chromatin remodeling enzymes such as histone deacetylases and poly-ADP ribose polymerases to control expression of MHC genes and regulate cardiomyocyte differentiation. In all, ATP-dependent chromatin remodeling plays important roles in heart development and disease and may provide a suitable therapeutic target for human cardiomyopathies in the future.
Author : Haodong Chen
Publisher :
Page : 163 pages
File Size : 41,94 MB
Release : 2013
Category :
ISBN :
Heart failure is a syndrome resulting from multiple genetic and environmental factors. In response to neural/hormonal changes or hemodynamic stress, the heart can generate extra force through hypertrophic growth. Chronic hypertrophy, however, is deleterious because it leads to irreversible decrease of cardiac contractility. This process requires many molecular and cellular abnormalities in the cells of the failing heart. Cardiac hypertrophy and heart failure arise as the result of multiple biological processes acting within the context of multicomponent, interrelated cellular networks. The past decade has seen an explosion of research using high-throughput techniques, identifying hundreds of genes involved in disease pathogenesis. These studies raise the question of how global, coordinated changes in transcription are precisely regulated within the cardiac nucleus. We reason that altered chromatin structure and DNA methylation endow distinct gene expression patterns during the development of disease. This dissertation details several systems biology approaches aimed at defining cardiac epigenomic variations in the hypertrophied and failing heart. Chapter 1 reports the genome-wide nucleosome positioning in normal and pressure overload-induced hypertrophic cardiac myocytes. Because nucleosomes are the basic units of chromatin, their localization fundamentally affects the actions many types of regulatory machinery. In Chapter 2, we examined the non-histone chromatin structural protein High Mobility Group Protein B2, which we had previously determined to be a regulator of hypertrophic growth. We measured its genome-wide binding pattern in both normal and alpha-adrenergic receptor agonist-induced hypertrophic cardiac myocytes. Our findings demonstrate that HMGB2 is reorganized away from coding regions in the genome of the hypertrophic myocyte, an action we interpret as globally coordinated relaxation of specific loci. In Chapter 3, we detail a comprehensive analysis of the DNA methylome in both normal and beta-adrenergic agonist-induced failing heart. We used two different mouse strains with different susceptibility to heart failure and identified several strain-specific DNA methylation modules. The results presented here advance our understanding of the cardiac epigenome and provided essential insights into global mechanisms of chromatin structural remodeling.
Author : Benoit G. Bruneau
Publisher :
Page : 0 pages
File Size : 11,38 MB
Release : 2020
Category : Medical
ISBN : 9781621823582
Development of the heart is a complex process and can lead to serious congenital disease if the process goes awry. This book provides a detailed description of the cell lineages involved in heart development and how their migration and morphogenesis are controlled. It also examines the genetic and environmental bases for congenital heart disease and how model systems are revealing more about the processes involved. Topics covered in this essential volume include: - Anatomy of a Developing Heart - Genetic and Epigenetic Control of Heart Development - Development of the Cardiac Conduction System - Genetic Basis of Human Congenital Heart Disease - In Vivo and In Vitro Genetic Models of Congenital Heart Disease
Author : Jörg Hinrich Hacker
Publisher : Wiley-Spektrum
Page : 370 pages
File Size : 13,44 MB
Release : 2002-10-03
Category : Medical
ISBN :
This comprehensive volume focuses on molecular methods and principles of prokaryotic and eukaryotic pathogens. The authors present the molecular and cellular aspects by focusing on the interactions between pathogenic microorganisms and their hosts. The publication begins with an overview of the most important and dangerous causative agents of infectious diseases. Next are discussions of how microbial "weapons," pathogenicity factors, protein secretion machines, and surface variation systems work, presenting the molecular and genetic methods that are used by scientists for their discovery and analysis. Furthermore, infectious diseases are discussed in light of the newly formed research areas of evolutionary and cellular microbiology and genomics. Future aspects on diagnostic techniques, therapy, and vaccine development are also presented.
Author : Hugh Davson
Publisher :
Page : 440 pages
File Size : 13,83 MB
Release : 1962
Category : Eye
ISBN :
