Project description:GLP-1 induces an increase in heart rate, but its mechanism remains elusive. We used a phosphoproteomic approach to evaluate the effect of GLP-1 on the porcine sinus node. Tissue samples from the sinus node region and left ventricle were collected from eight animals following a 60-minute infusion with either GLP-1 or saline. We employed a tandem mass tag (TMT) labeling strategy to multiplex samples, enriched for phosphorylated peptides by titanium dioxide chromatography, and pre-fractionated the resulting peptide pool prior to LC-MS/MS measurements on an Orbitrap Ascend Tribrid mass spectrometer.

Project description:The sinus node is a collection of highly specialized cells that constitute the natural pacemaker activity of our heart. The protein expression landscape of the sinus node differs from the surrounding cardiac tissue, although it is primarily comprised of myocytes and fibroblasts like the rest of the cardiac tissue, endowing it with its unique ability to regulate heart rate. Here we performed quantitative proteomics experiments to profile protein expression in the pacemaker of the heart, and compared it to protein expression in the neighbouring atrial muscle. In summary, the quantitative proteomics data presented here offer a highly detailed insight into the unique composition of the pacemaker of our heart.

Project description:The sinus node is a collection of highly specialised cells constituting the heart’s pacemaker. It is keenly debated whether the so-called membrane or alternatively Ca2+ clocks provide the molecular substrate of pacemaking. By high-resolution mass spectrometry, we quantified >7,000 proteins from sinus node and neighbouring atrial muscle. The abundances of 575 proteins differed between the two tissues, including particular differences in metabolic profiles and extracellular matrix composition. Most notably, the data reveal significant differences between the tissues in the ion channels responsible for the membrane clock, but not in Ca2+ clock proteins, suggesting that the membrane clock underpins pacemaking. By performing single-nucleus RNA sequencing of sinus node biopsies, we attributed protein abundances to specific cell types. Consistent with these results, incorporation of the ion channel expression differences into a biophysically-detailed atrial action potential model resulted in pacemaking and a sinus node-like action potential. Combining our quantitative proteomics data with computational modeling, we estimate ion channel copy numbers for sinus node myocytes. Our findings provide detailed insights into the unique molecular make-up of the pacemaker of the heart.

Project description:Heart failure is associated with atrioventricular (AV) node dysfunction, and AV node dysfunction in the setting of heart failure is associated with an increased risk of mortality and heart failure hospitalisation. This study aims to understand the causes of AV node dysfunction in heart failure by studying changes in the whole nodal transcriptome. The mouse transverse aortic constriction model of heart failure was studied; functional changes were assessed using electrocardiography and echocardiography and the transcriptome of the AV node was quantified using RNA-seq. Heart failure was associated with a significant increase in the PR interval, indicating a slowing of AV node conduction and AV node dysfunction, and significant changes in 3,077 transcripts (5.6% of the transcriptome). Many systems were affected: transcripts supporting AV node conduction were downregulated and there were changes in transcripts identified by GWAS as determinants of the PR interval. In addition, there was evidence of remodelling of the sarcomere, a shift from fatty acid to glucose metabolism, and remodelling of the extracellular matrix. There was evidence of the causes of this widespread remodelling of the AV node: evidence of dysregulation of multiple intracellular signalling pathways, dysregulation of 109 protein kinases and 148 transcription factors, and an immune response with a proliferation of neutrophils, monocytes, macrophages and B lymphocytes and a dysregulation of 40 cytokines. In conclusion, inflammation and a widespread transcriptional remodelling of the AV node underlies AV node dysfunction in heart failure.

Project description:The sinoatrial node regulates the heart rate throughout life. Failure of this primary pacemaker results in life-threatening, slow heart rhythm. Despite its important function, the cellular and molecular composition of the human sinoatrial node is not resolved. Particularly, no cell surface marker to identify and isolate sinoatrial node pacemaker cells has been reported. Here we use single-nuclei/cell RNA sequencing of fetal and human pluripotent stem cell-derived sinoatrial node cells and show that they consist of three subtypes of pacemaker cells, including Core Pacemaker, Sinus Venosus, and Transitional Cells. Our study identifies a host of sinoatrial node pacemaker markers including MYH11, BMP4, and the cell surface antigen CD34. We demonstrate that sorting for CD34+ cells from stem cell differentiation cultures enriches for sinoatrial node cells with a functional pacemaker phenotype. This sinoatrial node pacemaker cell surface marker is highly valuable for stem cell-based disease modelling, drug discovery, cell replacement therapies, as well as the delivery of therapeutics to sinoatrial node cells in vivo using antibody-drug conjugates.

Project description:The sinoatrial node regulates the heart rate throughout life. Failure of this primary pacemaker results in life-threatening, slow heart rhythm. Despite its important function, the cellular and molecular composition of the human sinoatrial node is not resolved. Particularly, no cell surface marker to identify and isolate sinoatrial node pacemaker cells has been reported. Here we use single-nuclei/cell RNA sequencing of fetal and human pluripotent stem cell-derived sinoatrial node cells and show that they consist of three subtypes of pacemaker cells, including Core Pacemaker, Sinus Venosus, and Transitional Cells. Our study identifies a host of sinoatrial node pacemaker markers including MYH11, BMP4, and the cell surface antigen CD34. We demonstrate that sorting for CD34+ cells from stem cell differentiation cultures enriches for sinoatrial node cells with a functional pacemaker phenotype. This sinoatrial node pacemaker cell surface marker is highly valuable for stem cell-based disease modelling, drug discovery, cell replacement therapies, as well as the delivery of therapeutics to sinoatrial node cells in vivo using antibody-drug conjugates.

Project description:The sinoatrial node regulates the heart rate throughout life. Failure of this primary pacemaker results in life-threatening, slow heart rhythm. Despite its important function, the cellular and molecular composition of the human sinoatrial node is not resolved. Particularly, no cell surface marker to identify and isolate sinoatrial node pacemaker cells has been reported. Here we use single-nuclei/cell RNA sequencing of fetal and human pluripotent stem cell-derived sinoatrial node cells and show that they consist of three subtypes of pacemaker cells, including Core Pacemaker, Sinus Venosus, and Transitional Cells. Our study identifies a host of sinoatrial node pacemaker markers including MYH11, BMP4, and the cell surface antigen CD34. We demonstrate that sorting for CD34+ cells from stem cell differentiation cultures enriches for sinoatrial node cells with a functional pacemaker phenotype. This sinoatrial node pacemaker cell surface marker is highly valuable for stem cell-based disease modelling, drug discovery, cell replacement therapies, as well as the delivery of therapeutics to sinoatrial node cells in vivo using antibody-drug conjugates.

Project description:This project contains a Modelica implementation of the model of the human baroreflex developed by H. Seidel in his PhD thesis (Seidel 1997) under the supervision of H. Herzel. We published and presented this implementation at the 2015 International Modelica Conference. The Seidel-Herzel model (SHM) describes the autonomic control of the heart rate in humans at a high level of abstraction as a hybrid (discrete and continuous), deterministic, quantitative, macro-level model. All effects are described on the organ level, including the time course of systemic arterial blood pressure generated by the pumping of the heart; the Windkessel effect of the expanding arteries dampening the initial rise in blood pressure; the arterial baroreceptors generating a neural signal depending on the absolute value and the increase in blood pressure; the autonomic nervous system emitting norepinephrine and acetylcholine as hormone and neurotransmitter based on signals from the baroreceptor and the lungs; and the cardiac conduction system with the SA node as main pacemaker and the AV node as a fallback system. The model is able to simulate several relevant disease conditions such as first and second degree atrioventricular block (Seidel 1997), carotid sinus hypersensitivity (Seidel and Herzel 1998), congestive heart failure (Kotani et al. 2005), and primary autonomic failure (Kotani et al. 2005) as well as treatment options such as the administration of atropine or metoprolol (Kotani et al. 2005). It is also especially interesting with regard to its dynamical properties such as the emergence of Mayer waves (Seidel 1997), bifurcations (Seidel and Herzel 1998) and cardiorespiratory synchronization (Kotani et al. 2002). The current version of the model can also be found at https://github.com/CSchoel/shm.

Project description:Heart failure is a multisystem syndrome caused by structural and functional defects in multiple tissues. The study aims to identify differentially regulated genes in skeletal muscle of heart failure patients. Here, we obtained biopsies from the pectoralis major muscle and performed RNA sequencing to profile the gene expression patterns from six heart failure patients and three healthy controls.

Project description:Failure of immunotherapy after applying checkpoint inhibitors or CAR-T cells is linked to T cell exhaustion. Here, we explored the T cell landscape in chronic lymphocytic leukemia (CLL) by single-cell omics analyses of blood, bone marrow and lymph node samples of patients and spleen samples of a CLL mouse model. By single-cell RNA-sequencing, mass cytometry (CyTOF), and multiplex image analysis of tissue microarrays, we defined the spectrum of phenotypes and transcriptional programs of T cells and and their differentiation state trajectories. We identified disease-specific accumulation of distinct regulatory T cell subsets and T cells harboring an exhausted phenotype exclusively in the CLL lymph node tissue. Integration of TCR data revealed a clonal expansion of CD8+ precursor exhausted T cells, suggesting their reactivity for CLL cells. Interactome analyses identified the TIM3 ligand Galectin-9 as novel immunoregulatory molecule in CLL. Blocking of Galectin-9 in CLL-bearing mice slowed down disease development and reduced the number of TIM3 expressing T cells. Galectin-9 expression correlated with shorter survival of CLL patients. Thus, Galectin-9 contributes to immune escape in CLL and represents a novel target for immunotherapy.