Project description:Understanding factors that drive development and function of the sinoatrial node (SAN) is crucial to development of potential therapies for sinus arrhythmias, including potential generation of biological pacemakers. Here, we identify a key cell autonomous role for the LIM homeodomain transcription factor ISL1 for survival, proliferation and function of pacemaker cells throughout development. Chromatin immunoprecipitation assays performed utilizing antibody to ISL1 in chromatin extracts from FACS purified SAN cells demonstrated that ISL1 directly binds genomic regions within several genes critical for normal pacemaker function, including subunits of the L-type calcium channel, Ank2, and Tbx3. Other genes implicated in abnormal heart rhythm in humans were also direct downstream targets of ISL1 in SAN cells. Our studies represent the first in vivo ChIP-seq studies for SAN cells which provide a basis for further exploration of factors critical to SAN formation and function and highlight the potential for utilization of ISL1 in combination with other SAN transcription factors for generating pacemaker cells for therapy or drug screening purposes. ISL1 ChIP-seq profiling was performed in Hcn4-H2BGFP SAN cells purified from neonatal hearts.

Project description:Full Title: Transition from Compensated Hypertrophy to Systolic Heart Failure in the Spontaneously Hypertensive Rat: Structure, Function, and Transcript Analysis Gene expression changes and left ventricular remodeling associated with the transition to systolic heart failure (HF) were determined in the spontaneously hypertensive rat (SHR). By combining transcriptomics of left ventricles from six SHR with HF with changes in function and structure we aimed to better understand the molecular events underlying the onset of systolic HF compared to six age-matched, SHR with compensated hypertrophy. Left ventricle (LV) ejection fraction was depressed (82±4 to 52±3 %) in compensated vs. failing animals.  Systolic blood pressure decreased and LV end-diastolic and systolic volume increased with HF.  Failing SHR hearts also demonstrated increases in left and right ventricular mass relative to non-failing SHRs.  LV papillary muscle force development and shortening velocity decreased, β-adrenergic responsiveness was depressed, myocardial stiffness and myocardial fibrosis increased with HF relative to non-failing animals. Initial micro-array analysis revealed that 1,431 transcripts were differentially expressed with HF compared to non-failing SHR (p<0.05). Of the identified transcripts, lipopolysaccharide binding protein, the most highly expressed transcript with HF, was negatively correlated to myocardial force while elevated expression of the collagen cross-linking enzyme lysyl oxidase correlated positively with muscle stiffness. Besides these individual transcripts, gene set enrichment analysis (GSEA) identified multiple enriched pathways with HF, most prominent of the altered signaling pathways involved TGF-β and insulin signaling. GESA analysis additionally identified altered gene sets involving inflammation, oxidative stress, cell degradation and cell death, among others (all p<0.01). In contrast to diastolic HF where few transcripts are reported to be altered, our data indicate multiple genes and pathways involved in a variety of biological processes characterize the onset of systolic HF, consistent with many functional and structural changes present in the failing hypertensive heart. Comprehensive gene expression profiling of heart failure Rat model vs control.

Project description:Background: Despite its functional importance in various fundamental bioprocesses, the studies of N6-methyladenosine (m6A) in the heart are lacking. Methods: We performed methylated (m6A) RNA immunoprecipitation sequencing (MeRIP-seq) to map transcriptome-wide m6A in healthy and failing hearts. Results: Improving expression of FTO in failing mouse hearts attenuated the ischemia-induced increase in m6A and decrease in cardiac contractile function. This is carried out by the demethylation activity of FTO, which selectively demethylates cardiac contractile transcripts Conclusion: Collectively, our study demonstrates the functional importance of FTO-dependent cardiac m6A methylome in cardiac contraction during heart failure and provides a novel mechanistic insight into the therapeutic mechanisms of FTO.

Project description:The microtubule (MT) cytoskeleton can provide a mechanical resistance that can impede the motion of contracting cardiomyocytes. Yet a role of the MT network in human heart failure is unexplored. Here we utilize mass spectrometry to characterize changes to the cytoskeleton in human heart failure. Proteomic analysis of left ventricle tissue reveals a consistent upregulation and stabilization of intermediate filaments and MTs in human heart failure. This dataset includes left ventricular (LV) myocardium from 34 human hearts – either non-failing (NF) or failing hearts. NF hearts are subdivided into normal or compensated hypertrophy (cHyp), while failing hearts are subdivided into ischemic cardiomyopathy (ICM), dilated cardiomyopathy (DCM), and hypertrophic cardiomyopathy with preserved or reduced ejection fraction (HCMpEF and HCMrEF, respectively). Further details on patient classification and in vivo parameters on each heart are listed in sample details.txt.

Project description:A goal of this study was to identify and investigate previously unrecognized components of the remodeling process in the progression to heart failure by comparing gene expression in ischemic, failing (F) to non-failing (NF) hearts. These results also were compared to the changes observed in a proteomic analysis of F and NF hearts. RNA extracted from the left ventricle was hybridized to Affymetrix arrays to identify gene expression differences in ischemic, end-stage failing versus non-failing hearts. biological replicate: LV_NF_001, LV_NF002, LV_NF004, LV_NF005 biological replicate: LV_F_003, LV_F005, LV_F009, LV_F006

Project description:to study the effect of induced expression of TBX3 within the atrium of the heart Background: Treatment of congenital or acquired disorders of the sinus node or atrioventricular node requires insight into the molecular mechanisms for the development and homeostasis of these pacemaker tissues. In the developing heart, transcription factor TBX3 is required for pacemaker and conduction system development. Here, we explore the role of TBX3 in the adult heart and investigate whether TBX3 is able to reprogram terminally differentiated working cardiomyocytes into pacemaker cells. This would be an attractive approach in biological pacemaker formation. Methods and results: TBX3 expression was ectopically induced in cardiomyocytes of adult transgenic mice. Expression analysis revealed an efficient switch from the working myocardial expression profile to that of the pacemaker myocardium. This included suppression of genes encoding gap junction subunits (Cx40, Cx43), the cardiac Na+ channel (NaV1.5; INa) and inwardly rectifying K+ ion channels (Kir-genes; IK1). Concordantly, we observed conduction slowing in these hearts, and reductions in INa and IK1 in cardiomyocytes isolated from these hearts. The reduction in IK1 resulted in a more depolarized maximum diastolic potential, thus enabling spontaneous diastolic depolarization. Neither ectopic pacemaker activity nor pacemaker current, If, were observed. Lentiviral expression of TBX3 in ventricular cardiomyocytes resulted in conduction slowing and development of heterogeneous phenotypes, including depolarized and spontaneously active cardiomyocytes. Conclusions: TBX3 partially reprograms terminally differentiated working cardiomyocytes into pacemaker-like cells and induces important pacemaker properties. The ability of TBX3 to reduce intercellular coupling to overcome current-to-load mismatch and the ability to reduce IK1 density to enable diastolic depolarization, are very promising TBX3 characteristics for biological pacemaker formation strategies. 5 TBX3 expressing left atrial appendage samples (Tamoxifen-treated Myh6MCM;CTBX3 adult male mice) and 6 controls ((Tamoxifen-treated Myh6MCM adult male mice)

Project description:To generate the reference for cell composition deconvolution and characterize the cellular expression landscape, we performed single nucleus RNA-Seq (snRNA-Seq) on left ventricles from four non-failing hearts and one failing heart.

Project description:A goal of this study was to identify and investigate previously unrecognized components of the remodeling process in the progression to heart failure by comparing gene expression in ischemic, failing (F) to non-failing (NF) hearts. These results also were compared to the changes observed in a proteomic analysis of F and NF hearts.

Project description:Regulation of gene expression plays a fundamental role in cardiac stress-responses. Modification of coding transcripts by adenosine methylation (m6A) has recently emerged as a critical post-transcriptional mechanism underlying heart disease. Thousands of mammalian mRNAs are known to be m6A-modified, suggesting that remodeling of the m6A landscape may play an important role in cardiac pathophysiology. Here we found an increase in m6A content in human heart failure samples. We then adopted genome-wide analysis to define all m6A-regulated sites in human failing compared to non-failing hearts and identified targeted transcripts involved in histone modification as enriched in heart failure. Further, we compared all m6A sites regulated in human hearts with the ones occurring in isolated rat hypertrophic cardiomyocytes to define cardiomyocyte-specific m6A events conserved across species. Our results identified 38 shared transcripts targeted by m6A during stress conditions, and 11 events that are unique to unstressed cardiomyocytes. Of these, Coronin-6 (CORO6) was further evaluated for mRNA and protein abundances, demonstrating the potential impact of m6A on post-transcriptional regulation of gene expression in the heart.

Project description:Full Title: Transition from Compensated Hypertrophy to Systolic Heart Failure in the Spontaneously Hypertensive Rat: Structure, Function, and Transcript Analysis Gene expression changes and left ventricular remodeling associated with the transition to systolic heart failure (HF) were determined in the spontaneously hypertensive rat (SHR). By combining transcriptomics of left ventricles from six SHR with HF with changes in function and structure we aimed to better understand the molecular events underlying the onset of systolic HF compared to six age-matched, SHR with compensated hypertrophy. Left ventricle (LV) ejection fraction was depressed (82±4 to 52±3 %) in compensated vs. failing animals.  Systolic blood pressure decreased and LV end-diastolic and systolic volume increased with HF.  Failing SHR hearts also demonstrated increases in left and right ventricular mass relative to non-failing SHRs.  LV papillary muscle force development and shortening velocity decreased, β-adrenergic responsiveness was depressed, myocardial stiffness and myocardial fibrosis increased with HF relative to non-failing animals. Initial micro-array analysis revealed that 1,431 transcripts were differentially expressed with HF compared to non-failing SHR (p<0.05). Of the identified transcripts, lipopolysaccharide binding protein, the most highly expressed transcript with HF, was negatively correlated to myocardial force while elevated expression of the collagen cross-linking enzyme lysyl oxidase correlated positively with muscle stiffness. Besides these individual transcripts, gene set enrichment analysis (GSEA) identified multiple enriched pathways with HF, most prominent of the altered signaling pathways involved TGF-β and insulin signaling. GESA analysis additionally identified altered gene sets involving inflammation, oxidative stress, cell degradation and cell death, among others (all p<0.01). In contrast to diastolic HF where few transcripts are reported to be altered, our data indicate multiple genes and pathways involved in a variety of biological processes characterize the onset of systolic HF, consistent with many functional and structural changes present in the failing hypertensive heart.