Project description:6761 CHD non-coding DNVs were prioritized from 749 unexplained CHD trios and functionally assessed in iPSC-CMs using lentiMPRA.

Project description:To assess human cardiac enhancer activity, 400 bp candidate cardiac enhancers and controls were tested in iPSC-CMs using lentiMPRA.

Project description:Analysis of CHD non-coding DNVs for their impact on cardiac cis-regulatory element activity

Project description:Congenital heart disease (CHD) is the most prevalent structural malformations of the heart affecting ∼1% of live births. To date, both damaging genetic variations and adverse environmental exposure such as maternal diabetes have been found to cause CHD. Clinical studies show ∼fivefold higher risk of CHD in the offspring of mothers with pregestational diabetes. Maternal pregestational diabetes affects the gene regulatory networks key to proper cardiac development in the fetus. However, the cell-type specificity of these gene regulatory responses to maternal diabetes and their association with the observed cardiac defects in the fetuses remains unknown. To uncover the transcriptional responses to maternal diabetes in the early embryonic heart, we used an established murine model of pregestational diabetes. In this model, we have previously demonstrated an increased incidence of CHD. Here, we show maternal hyperglycemia (matHG) elicits diverse cellular responses during heart development by single-cell RNA-sequencing in embryonic hearts exposed to control and matHG environment. Through differential gene-expression and pseudotime trajectory analyses of this data, we identified changes in lineage specifying transcription factors, predominantly affecting Isl1+ second heart field progenitors and Tnnt2+cardiomyocytes with matHG. Using in vivo cell-lineage tracing studies, we confirmed that matHG exposure leads to impaired second heart field-derived cardiomyocyte differentiation. Finally, this work identifies matHG-mediated transcriptional determinants in cardiac cell lineages elevate CHD risk and show perturbations in Isl1-dependent gene-regulatory network (Isl1-GRN) affect cardiomyocyte differentiation. Functional analysis of this GRN in cardiac progenitor cells will provide further mechanistic insights into matHG-induced severity of CHD associated with diabetic pregnancies.

Project description:Inflammation is associated with many cardiovascular pathologies, but the underlying mechanisms remain unclear. To explore this in more detail, we characterized the transcriptome of an immortalized adult human ventricular cardiomyocyte cell line (AC16) in response to tumor necrosis factor (TNFa). Using a combination of genomic approaches, including global nuclear run-on sequencing (GRO-seq) and chromatin immunoprecipitation coupled with sequencing (ChIP-seq), we identified ~30,000 transcribed regions in AC16 cells, which includes a set of RNA polymerases I and III (Pol I and Pol III) transcribed regions revealed in the presence of M-NM-1-amanitin. The set of transcribed regions produces both protein-coding and non-coding RNAs, many of which have not been annotated previously, including enhancer RNAs originating from NF-M-NM-:B binding sites. In addition, we observed that AC16 cells rapidly and dynamically reorganize their transcriptomes in response to TNFa stimulation in an NF-M-NM-:B-dependent manner, switching from a basal state to a proinflammatory state affecting a spectrum of cardiac-associated protein-coding and non-coding genes. Moreover, we observed distinct Pol II dynamics for up- and downregulated genes, with a rapid release of Pol II into productive elongation for TNFa-stimulated genes. Our studies shed new light on the regulation of the cardiomyocyte transcriptome in response to a proinflammatory signal and help to clarify the link between inflammation and cardiomyocyte function at the transcriptional level. Using GRO-seq and ChIP-seq (p65 and RNA Pol II) over a time course of TNFM-NM-1 signaling in AC16 human cardiomyocytes.

Project description:Inflammation is associated with many cardiovascular pathologies, but the underlying mechanisms remain unclear. To explore this in more detail, we characterized the transcriptome of an immortalized adult human ventricular cardiomyocyte cell line (AC16) in response to tumor necrosis factor (TNFa). Using a combination of genomic approaches, including global nuclear run-on sequencing (GRO-seq) and chromatin immunoprecipitation coupled with sequencing (ChIP-seq), we identified ~30,000 transcribed regions in AC16 cells, which includes a set of RNA polymerases I and III (Pol I and Pol III) transcribed regions revealed in the presence of M-NM-1-amanitin. The set of transcribed regions produces both protein-coding and non-coding RNAs, many of which have not been annotated previously, including enhancer RNAs originating from NF-M-NM-:B binding sites. In addition, we observed that AC16 cells rapidly and dynamically reorganize their transcriptomes in response to TNFa stimulation in an NF-M-NM-:B-dependent manner, switching from a basal state to a proinflammatory state affecting a spectrum of cardiac-associated protein-coding and non-coding genes. Moreover, we observed distinct Pol II dynamics for up- and downregulated genes, with a rapid release of Pol II into productive elongation for TNFa-stimulated genes. Our studies shed new light on the regulation of the cardiomyocyte transcriptome in response to a proinflammatory signal and help to clarify the link between inflammation and cardiomyocyte function at the transcriptional level. Using GRO-seq and ChIP-seq (p65 and RNA Pol II) over a time course of TNFM-NM-1 signaling in AC16 human cardiomyocytes.

Project description:Exposure to per- and polyfluoroalkyl substances (PFASs) such as perfluorooctanesulfonic acid (PFOS) has been associated with congenital heart disease (CHD) and decreased birth weight. PFAS exposure can disrupt signaling pathways relevant for cardiac development in stem cell derived cardiomyocyte assays, including PFOS-induced disruption to in vitro cardiac differentiation into contracting spheroids of cardiomyocytes; the PluriBeat assay. Notably, cell line origin can affect how the assay respond to PFAS exposure. Herein, we examine the effect of PFOS on cardiomyocyte differentiation by transcriptomics profiling of two different human induced pluripotent stem cell (hiPSC) lines, to see if they exhibit a common pattern of disruption. Two stages of differentiation, the cardiac progenitor stage (early) and the cardiomyocyte stage (late), were investigated.

Project description:Alterations in autonomic function are known to occur in cardiac conditions including sudden cardiac death. Cardiac stimulation via sympathetic neurons can potentially trigger arrhythmias. Dissecting direct neural-cardiac interactions at the cellular level is technically challenging and understudied due to the lack of experimental model systems and methodologies. Here we demonstrate the utility of optical interrogation of sympathetic neurons and their effects on macroscopic cardiomyocyte network dynamics to address research targets such as the effects of adrenergic stimulation via the release of neurotransmitters, the effect of neuronal numbers on cardiac wave behaviour and the applicability of optogenetics in mechanistic in vitro studies. We present novel methodologies to study neuron-cardiomyocyte interactions involving optogenetic selective probing and all-optical electrophysiology to measure electrical activity in an automated fashion, illustrating the power and high-throughput capability of such interrogations. We present new findings on how neurons impact cardiac macroscopic wave properties, the links between neuron density and cardiac firing rates as well as the challenges and benefits of macroscopic co-cultures as experimental model systems.

Project description:Background:Femaleinfantswith congenital heart disease (CHD)facesignificantlyhigherpostoperativemortality ratesafter adjusting for cardiac complexity.Sex differences in metabolic adaptation to cardiac stressors maybe an earlycontributor tocardiac dysfunction.In adult diseases, hypoxic/ischemic cardiomyocytesundergo acardioprotectivemetabolicshift fromoxidative phosphorylation to glycolysiswhichappears to be regulated in a sexually dimorphic manner.We hypothesizesex differences incardiacmetabolismare presentincyanotic CHDand detectable asearly as theinfantperiod. Methods:RNA sequencingwas performedon blood samples(cyanotic CHD cases,n=11;controls,n=11)andanalyzedusinggene set enrichment analysis (GSEA). Global plasma metaboliteprofiling(UPLC-MS/MS)was performedusinga larger representative cohort(cyanotic CHD,n = 27;non-cyanotic CHD,n = 11;unaffectedcontrols,n = 12). Results:Hallmark gene sets in glycolysis, fatty acid metabolism, and oxidative phosphorylationwere significantly enrichedincyanotic CHDfemales compared to malecounterparts, which was consistent withmetabolomicdifferences between sexes.Minimalsex differencesinmetabolicpathwayswereobservedinnormoxicpatients(bothcontrols and non-cyanotic CHDcases). Conclusion:These observationssuggestunderlying differences inmetabolicadaptationtochronic hypoxiabetween males and females withcyanotic CHD.

Project description:The adult mammalian heart has little regenerative capacity after myocardial infarction (MI) while neonatal mouse heart regenerates without scarring or dysfunction. However, the underlying pathways are poorly defined. We sought to derive insights into the pathways regulating neonatal development of the mouse heart and cardiac regeneration post-MI. Total RNA-seq of mouse heart through the first 10 days of postnatal life (referred to as P3, P5, P10) revealed a previously unobserved transition in microRNA expression between P3 and P5 associated specifically with altered expression of protein-coding genes on the focal adhesion pathway and cessation of cardiomyocyte cell division. We found profound changes in the coding and non-coding transcriptome after neonatal MI, with evidence of essentially complete healing by P10. Over two thirds of each of the mRNAs, lncRNAs and microRNAs that were differentially expressed in the post-MI heart were differentially expressed during normal postnatal development, suggesting a common regulatory pathway for normal cardiac development and post-MI cardiac regeneration. We selected exemplars of miRNAs implicated in our data set as regulators of cardiomyocyte proliferation. Several of these showed evidence of a functional influence on mouse cardiomyocyte cell division. In addition, a subset of these microRNAs, miR-144-3p, miR-195a-5p, miR-451a and miR-6240 showed evidence of functional conservation in human cardiomyocytes. The sets of mRNAs, miRNAs and lncRNAs that we report here merit further investigation as gatekeepers of cell division in the postnatal heart and as targets for extension of the period of cardiac regeneration beyond the neonatal period.