Project description:We used snRNA-seq to investigate an entire adult mammalian heart of BL6 mice. Whole hearts were harvested from 4 male mice (12 weeks) after cervical dislocation. The hearts were pooled and nuclei isolated using the Nuclei PURE Prep isolation kit (Sigma-Aldrich, Darmstadt, Germany) according to the manufacturer’s protocol. Sequencing was conducted by Genewiz (Leipzig, Germany) on the 10xGenomics system. Single nuclei were captured in droplet emulsions and snRNA-seq libraries were constructed as per the 10x Genomics protocol using GemCode Single-Cell 3′ Gel Bead and Library V3 Kit. RNA was controlled for sufficient quality on an Agilent 2100 Bioanalyzer system and quantified using a Qubit Fluorometer.

Project description:To identify novel, cell-specific, pathological pathways that mediate heart dysfunction in Barth Syndrome, we performed single-nucleus RNA-sequencing (snRNA-seq) on wild type and Tafazzin-knockout mouse hearts.

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:Adult mammalian hearts lack regenerative potential and this is a significant contributing cause of the extensive morbidity and mortality of cardiovascular disease. We performed single nucleus RNA sequencing (snRNA-seq) to capture of cell diversity and gender-specific changes as well as identification of critical differentially expressed genes in cellular clusters throughout the heart.

Project description:The cardiac autonomic nervous system is crucial in controlling cardiac function, such as heart rate and cardiac contractility, and is divided into sympathetic and parasympathetic branches. Normally, there is a balance between these two branches to maintain homeostasis. However, cardiac disease states such as myocardial infarction, heart failure, and hypertension can induce the remodeling of cells involved in cardiac innervation, which is associated with an adverse clinical outcome. Although there are vast amounts of data for the histological structure and function of the cardiac autonomic nervous system, its molecular biological architecture in health and disease is still enigmatic in many aspects. Novel technologies such as single-cell RNA sequencing (scRNA-seq) hold promise for the genetic characterization of tissues at single-cell resolution. However, the relatively large size of neurons may impede the standardized use of these techniques. Here, this protocol exploits droplet-based single-nucleus RNA sequencing (snRNA-seq), a method to characterize the biological architecture of cardiac sympathetic neurons in health and disease. A stepwise approach is demonstrated to perform snRNA-seq of the bilateral superior cervical (SCG) and stellate ganglia (StG) dissected from adult mice. This method enables long-term sample preservation, maintaining an adequate RNA quality when samples from multiple individuals/experiments cannot be collected all at once within a short period of time. Barcoding the nuclei with hashtag oligos (HTOs) enables demultiplexing and the trace-back of distinct ganglionic samples post sequencing. Subsequent analyses revealed successful nuclei capture of neuronal, satellite glial, and endothelial cells of the sympathetic ganglia, as validated by snRNA-seq. In summary, this protocol provides a stepwise approach for snRNA-seq of sympathetic extrinsic cardiac ganglia, a method that has the potential for broader application in studies of the innervation of other organs and tissues.

Project description:We used snRNA-seq to investigate for the first time an entire adult mammalian heart. To avoid potential aberrations due to inbreeding, we relied on an outbred mice strain (Fzt:DU) (Dietl, G.; Langhammer, M.; Renne, U. Model simulations for genetic random drift in the outbred strain Fzt:DU. Arch. Anim. Breed. 2004, 47, 595–604). Whole hearts were harvested from 4 male mice (12 weeks) after cervical dislocation. The hearts were pooled and nuclei isolated using the Nuclei PURE Prep isolation kit (Sigma-Aldrich, Darmstadt, Germany) according to the manufacturer’s protocol. Sequencing was conducted by Genewiz (Leipzig, Germany) on the 10xGenomics system. Single nuclei were captured in droplet emulsions and snRNA-seq libraries were constructed as per the 10x Genomics protocol using GemCode Single-Cell 3′ Gel Bead and Library V3 Kit. RNA was controlled for sufficient quality on an Agilent 2100 Bioanalyzer system and quantified using a Qubit Fluorometer. For further experimental details as well as computational scripts and results can be obtained from http://doi.org/10.15490/FAIRDOMHUB.1.STUDY.713.1.

Project description:Postnatal cardiac development requires the orchestrated maturation of diverse cellular components, for which unifying control mechanisms are still lacking. Using full-length sequencing, we examined the transcriptomic landscape of the maturating mouse heart (E18.5-P28) at single-cell and transcript isoform resolution. We identified dynamically changing intercellular networks as a molecular basis of the maturing heart, and alternative splicing (AS) as a common mechanism that distinguished developmental age. Manipulation of RNA-binding proteins (RBPs) remodeled the AS landscape, cardiac cell maturation, and intercellular communication through direct binding of splice targets, which were enriched for functions related to general, as well as cell type-specific, maturation. Overexpression of an RBP NCBP2 in neonatal hearts repressed cardiac maturation. Together, our data suggest AS regulation by RBPs as an organ-level control mechanism in mammalian postnatal cardiac development, and provide insight into the possibility of manipulating RBPs for therapeutic purposes.

Project description:Analysis of the transcriptional changes in the heart resulting from the loss of cardiac enhancers. As there remains a limited understanding of the phenotypic consequences of enhancer mutations, we examined the impact of loss of function mutations by deleting two enhancers near heart disease genes in mice. In both cases, we observed loss of target gene expression, as well as cardiac phenotypes consistent with heart disease in humans, highlighting the functional importance of enhancers for normal heart function, as well as the potential contribution of enhancer mutations to heart disease. Hearts were dissected from wild-type and enhancer-null mice (either embryonic or adult) and processed for deep RNA-seq analysis.

Project description:Postnatal heart maturation is the basis of normal cardiac function and provides critical insights into heart repair and regenerative medicine. While static snapshots of the maturing heart have provided much insight into its molecular signatures, few key events during postnatal cardiomyocyte maturation have been uncovered.Here we processed single cell RNASeq of Cardiomyocyte at different postnatal time points.

Project description:Cardiac maturation lays the foundation for postnatal heart development and disease, yet little is known about the contributions of the microenvironment to cardiomyocyte maturation. By integrating single-cell RNA-sequencing data of mouse hearts at multiple postnatal stages, we construct cellular interactomes and regulatory signaling networks. Here we report switching of fibroblast subtypes from a neonatal to adult state and this drives cardiomyocyte maturation. Molecular and functional maturation of neonatal mouse cardiomyocytes and human embryonic stem cell-derived cardiomyocytes are considerably enhanced upon coculture with corresponding adult cardiac fibroblasts. Further, single-cell analysis of in vivo and in vitro cardiomyocyte maturation trajectories identify highly conserved signaling pathways, pharmacological targeting of which substantially delays cardiomyocyte maturation in postnatal hearts, and markedly enhances cardiomyocyte proliferation and improves cardiac function in infarcted hearts. Together, we identify cardiac fibroblasts as a key constituent in the microenvironment promoting cardiomyocyte maturation, providing insights into how the manipulation of cardiomyocyte maturity may impact on disease development and regeneration.