Project description:Myocardial infarction (MI) leads to cardiomyocyte death, which triggers an immune response that clears debris and restores tissue integrity. In the adult heart, the immune system facilitates scar formation, which repairs the damaged myocardium but compromises cardiac function. In neonatal mice, the heart can regenerate fully without scarring following MI; however, this regenerative capacity is lost by P7. The signals that govern neonatal heart regeneration are unknown. By comparing the immune response to MI in mice at P1 and P14, we identified differences in the magnitude and kinetics of monocyte and macrophage responses to injury. Using a cell-depletion model, we determined that heart regeneration and neoangiogenesis following MI depends on neonatal macrophages. Neonates depleted of macrophages were unable to regenerate myocardia and formed fibrotic scars, resulting in reduced cardiac function and angiogenesis. Immunophenotyping and gene expression profiling of cardiac macrophages from regenerating and nonregenerating hearts indicated that regenerative macrophages have a unique polarization phenotype and secrete numerous soluble factors that may facilitate the formation of new myocardium. Our findings suggest that macrophages provide necessary signals to drive angiogenesis and regeneration of the neonatal mouse heart. Modulating inflammation may provide a key therapeutic strategy to support heart regeneration. Total RNA was isolated from CD11b+Ly6G- cells sorted from hearts 3 days following ligation of LAD. 6 samples total: Triplicates of cells from P1 mice and from P14 mice

Project description:In mammals, the neonatal heart regenerates within a short time after birth, but adults lack this ability. We have shown that metabolic reprogramming is critical for cardiomyocyte proliferation in the neonatal heart. Herein, we revealed that cardiac metabolic reprogramming could be regulated by altering global protein lactylation. 4D label-free proteomics and Kla omics were performed in postnatal Day 1 (P1), 5 (P5), and 7 (P7) mouse hearts, 2297 Kla sites from 980 proteins were identified, and 1262 Kla sites from 409 proteins were quantified. Functional clustering analysis of proteins with altered Kla sites revealed that the proteins were mainly involved in metabolic processes. The Kla levels in several fatty acid oxidation-related proteins showed high expression at P5, while glycolysis and cell cycle-related proteins were sustainedly decreased from P1-P7. Furthermore, we verified the Kla levels of several differentially modified proteins, including ACAT1, ACADL, PKM and NPM1, by coimmunoprecipitation and Western blotting. Overall, we reported the first comprehensive Kla map in the neonatal mouse heart, which will aid in understanding the regulatory network of metabolic reprogramming and cardiac regeneration.

Project description:To identify the potential microRNAs (miRNAs) involved in the regulation of cardiomyocyte (CM) proliferation during homeostasis and injury, RNA sequencing (RNA-seq) in mouse cardiac ventricles was performed on postnatal day 1, 7, and 28 (P1, P7, and P28). Significant upregulation of MiR-128 was found in P7 hearts as compared to P1. To further specify the effect of miR-128 in the heart, RNA-Seq was performed in control mice (Ctrl) and miR-128 overexpression mice (miR-128OE) on P7. These data provide novel insights into the mechanisms by which adult CMs exit the cell cycle arrest and is fundamental for therapeutic manipulation to stimulate endogenous CM proliferate in cardiac regeneration.

Project description:To identify the potential microRNAs (miRNAs) involved in the regulation of cardiomyocyte (CM) proliferation during homeostasis and injury, RNA sequencing (RNA-seq) in mouse cardiac ventricles was performed on postnatal day 1, 7, and 28 (P1, P7, and P28). Significant upregulation of MiR-128 was found in P7 hearts as compared to P1. To further specify the effect of miR-128 in the heart, RNA-Seq was performed in control mice (Ctrl) and miR-128 overexpression mice (miR-128OE) on P7. These data provide novel insights into the mechanisms by which adult CMs exit the cell cycle arrest and is fundamental for therapeutic manipulation to stimulate endogenous CM proliferate in cardiac regeneration.

Project description:Myocardial infarction (MI) leads to cardiomyocyte death, which triggers an immune response that clears debris and restores tissue integrity. In the adult heart, the immune system facilitates scar formation, which repairs the damaged myocardium but compromises cardiac function. In neonatal mice, the heart can regenerate fully without scarring following MI; however, this regenerative capacity is lost by P7. The signals that govern neonatal heart regeneration are unknown. By comparing the immune response to MI in mice at P1 and P14, we identified differences in the magnitude and kinetics of monocyte and macrophage responses to injury. Using a cell-depletion model, we determined that heart regeneration and neoangiogenesis following MI depends on neonatal macrophages. Neonates depleted of macrophages were unable to regenerate myocardia and formed fibrotic scars, resulting in reduced cardiac function and angiogenesis. Immunophenotyping and gene expression profiling of cardiac macrophages from regenerating and nonregenerating hearts indicated that regenerative macrophages have a unique polarization phenotype and secrete numerous soluble factors that may facilitate the formation of new myocardium. Our findings suggest that macrophages provide necessary signals to drive angiogenesis and regeneration of the neonatal mouse heart. Modulating inflammation may provide a key therapeutic strategy to support heart regeneration.

Project description:Background: The adult mammalian heart has limited capacity for regeneration following injury, whereas the neonatal heart can readily regenerate within a short period after birth. To uncover the molecular mechanisms underlying neonatal heart regeneration, we compared the transcriptomes and epigenomes of regenerative and non-regenerative mouse hearts over a 7-day time period following myocardial infarction. Methods: RNA-Seq, H3K27ac ChIP-Seq and H3K27me3 ChIP-Seq were performed on ventricular samples from regenerative P1 or non-regenerative P8 mouse hearts at +1.5d, +3d and +7d after MI or Sham surgery to assemble the transcriptome, active chromatin and repressed chromatin landscapes during neonatal heart regeneration. Dynamic enhancer landscapes from mouse hearts during cardiac development were analyzed using data from ENCODE. Effects on cardiomyocyte proliferation and cardiac function from selected factors identified in this study were tested using BrdU/EdU pulse-labeling or mouse models coupled with immunohistochemistry and echocardiography. Results: By integrating gene expression profiles with histone marks associated with active or repressed chromatin, we identified transcriptional programs underlying neonatal heart regeneration and the blockade to regeneration in later life. Our results reveal a unique immune response in regenerative hearts and an embryonic cardiogenic gene program that remains active during neonatal heart regeneration. Among the unique immune factors and embryonic genes associated with cardiac regeneration, we identified Ccl24, which encodes a cytokine, and Igf2bp3, which encodes an RNA-binding protein, as previously unrecognized regulators of cardiomyocyte proliferation. Conclusions: Our data provide insights into the molecular basis of neonatal heart regeneration and identify genes that might be modulated to promote heart regeneration.

Project description:Background: The adult mammalian heart has limited capacity for regeneration following injury, whereas the neonatal heart can readily regenerate within a short period after birth. To uncover the molecular mechanisms underlying neonatal heart regeneration, we compared the transcriptomes and epigenomes of regenerative and non-regenerative mouse hearts over a 7-day time period following myocardial infarction. Methods: RNA-Seq, H3K27ac ChIP-Seq and H3K27me3 ChIP-Seq were performed on ventricular samples from regenerative P1 or non-regenerative P8 mouse hearts at +1.5d, +3d and +7d after MI or Sham surgery to assemble the transcriptome, active chromatin and repressed chromatin landscapes during neonatal heart regeneration. Dynamic enhancer landscapes from mouse hearts during cardiac development were analyzed using data from ENCODE. Effects on cardiomyocyte proliferation and cardiac function from selected factors identified in this study were tested using BrdU/EdU pulse-labeling or mouse models coupled with immunohistochemistry and echocardiography. Results: By integrating gene expression profiles with histone marks associated with active or repressed chromatin, we identified transcriptional programs underlying neonatal heart regeneration and the blockade to regeneration in later life. Our results reveal a unique immune response in regenerative hearts and an embryonic cardiogenic gene program that remains active during neonatal heart regeneration. Among the unique immune factors and embryonic genes associated with cardiac regeneration, we identified Ccl24, which encodes a cytokine, and Igf2bp3, which encodes an RNA-binding protein, as previously unrecognized regulators of cardiomyocyte proliferation. Conclusions: Our data provide insights into the molecular basis of neonatal heart regeneration and identify genes that might be modulated to promote heart regeneration.

Project description:To gain an integrated view of the dynamic changes in gene expression during postnatal heart development at the organ level, time-series transcriptome analyses of the postnatal hearts of neonatal through adult mice (P1, P7, P14, P30, and P60) were performed using a newly developed bioinformatics pipeline. Additionally, the role of the transcription factor Sox6 in the postnatal maturation of cardiac muscle was investigated by differential transcriptome analyses between Sox6 knockout (KO) and control hearts.

Project description:Little is known about the expression patterns and functions of circular RNAs (circRNAs) in the heart of large mammals. In this study, we examined the expression profiles of circRNAs, microRNAs (miRNAs), and messenger RNAs (mRNAs) in neonatal pig hearts. Pig heart samples collected on postnatal days 1 (P1), 3 (P3), 7 (P7) and 28 (P28) were sent for total RNA sequencing. Our data revealed a total of 7000 circRNAs in the 24 pig hearts. Pathway enrichment analysis of hallmark gene sets demonstrated that differentially expressed circRNAs are engaged in different pathways. The most significant difference was observed between P1 and the other three groups (P3, P7 and P28) in pathways related to cell cycle and muscle development. Out of the ten circRNAs that were validated through real-time quantitative polymerase chain reaction (qRT-PCR) to confirm their expression, six exhibited significant effects on cell cycle activity in human induced pluripotent stem cells-derived cardiomyocytes (hiPSC-CMs) following small interfering RNA-mediated knockdown. The circRNA-miRNA-mRNA networks were constructed to understand the potential mechanisms of circRNAs in the heart. In conclusion, our study provided a dataset for exploring the roles of circRNAs in pig hearts. In addition, we identified several circRNAs that regulate cardiomyocyte cell cycle.

Project description:The goal of this study is to examine transcriptomic changes in the left ventricles during the transition from a regenerative to a non-regenerative state in the pig neonatal heart. RNA was isolated from pig left ventricular tissue at postnatal day (P)0, P7, and P15, to compare the regeneration-capable P0 cardiac transcriptomic environment to the non-regenerative timepoints of P7 and P15, in pig hearts.