Project description:We have demonstrated previously that adult cardiomyocytes can dedifferentiate and proliferate when cultured in vitro. To determine if cardiomyocyte dedifferentiation and cell cycling/proliferation happens in vivo, we applied here a novel multi-reporter transgenic mouse model (aMH-CMerCreMer;mT/MG;aMHC-H2BBFP) carrying reporter genes for permanent cardiomyocyte lineage mapping and maturity (dedifferentiation) reporting. With this new model, we deciphered the cellular sources and processes of cardiomyocyte dedifferentiation and proliferation in adult hearts. In this study, we used single-nucleus RNA-sequencing to tackle the challenges in analyzing the highly heterogeneous heart cell populations, and obtained datasets for a large number of cardiac single nuclei (both myocytes and non-myocytes) for control and post-infarct hearts. We identified specific cell populations in the heart using distinct transcriptomic clusters, transgenic reporters for ACM lineage and dedifferentiation, as well as cell cycle markers. The results demonstrated that the dedifferentiation and cell cycle progression of pre-existing CMs was augmented in post-infarct hearts, with a number of signaling pathways and gene sets affected. This is the first study dissecting the transcriptomic profiles and signaling pathways associated with cardiomyocyte dedifferentiation and cycling/proliferation in vivo using unbiased high-throughput single-nucleus RNA-Seq analysis, in junction with novel cell lineage (e.g. cardiomyocyte) and phenotyping (e.g. dedifferentiation) transgenic model systems.

Project description:In highly regenerative animals, cardiac regeneration occurs innately through cardiomyocyte dedifferentiation and proliferation, although the regenerative mechanisms remain unclear. This project contains processed data sets that were used to identify that klf1, a Kruppel-like transcription factor essential for red blood cell development, is also necessary and sufficient in the myocardium for the induction of cardiomyocyte dedifferentiation and proliferation in adult zebrafish hearts. Raw data has been deposited to PRJNA551130

Project description:The RNA-sequence analysis of cardiomyocyte-specific deletion of STAT3 mice hearts showed that comparing with WT mice hearts, the STAT3cKO mice hearts showed reduced cardiac function by affecting some key pathways.

Project description:Rationale: In virtually all models of heart failure, prognosis is determined by right ventricular (RV) function; thus, understanding the cellular mechanisms contributing to RV dysfunction is critical. Whole organ remodeling is associated with cell-specific changes, including cardiomyocyte dedifferentiation and activation of cardiac fibroblasts (Cfib) which in turn is linked to disorganization of cytoskeletal proteins and loss of sarcomeric structures. However, how these cellular changes contribute to RV function remains unknown. We’ve previously shown significant organ-level RV dysfunction in a large animal model of pulmonary hypertension (PH) which was not mirrored by reduced function of isolated cardiomyocytes. We hypothesized that factors produced by the endogenous Cfib contribute to global RV dysfunction by generating a heterogeneous cellular environment populated by dedifferentiated cells. Objective: To determine the effect of Cfib conditioned media (CM) from the PH calf (PH-CM) on adult rat ventricular myocytes (ARVM) in culture. Methods and Results: Brief exposure (<2 days) to PH-CM results in rapid, marked dedifferentiation of ARVM to a neonatal-like phenotype exhibiting spontaneous contractile behavior. Dedifferentiated cells maintain viability for over 30 days with continued expression of cardiomyocyte proteins including TnI and α-actinin yet exhibit myofibroblast characteristics including expression of α-smooth muscle actin. Using a bioinformatics approach to identify factor(s) that contribute to dedifferentiation, we found activation of the PH Cfib results in a unique transcriptome correlating with factors both in the secretome and with activated pathways in the dedifferentiated myocyte. Further, we identified upregulation of periostin in the Cfib and CM, and demonstrate that periostin is sufficient to drive cardiomyocyte dedifferentiation. Conclusions: These data suggest that paracrine factor(s) released by Cfib from the PH calf signal a phenotypic transformation in a population of cardiomyocytes that likely contributes to RV dysfunction. Therapies targeting this process, such as inhibition of periostin, have the potential to prevent RV dysfunction.

Project description:The Right Ventricular Fibroblast Secretome Drives Cardiomyocyte Dedifferentiation

Project description:We carried out Massive Parallel Sequencing (MPS) to reveal circulating miRNA profiles of 96 patients to distinguish the radiographic and non-radiographic axial spondyloarthritis. The sequencing platform identified 1900 miRNA species, out of which 432 miRNAs were present with the base mean, computed by DESeq2, more than 10. We identified 48 miRNAs, which were different in PBMCs in patients with axial spondyloarthritis compared to healthy controls.

Project description:Near-complete reversal of ERBB2-driven cardiomyocyte dedifferentiation is driven by the Hippo pathway, restoring contractility whilst long-lasting conferring cardioprotection.

Project description:The formation of new and functional cardiomyocytes requires a 3-step process: dedifferentiation, proliferation, and redifferentiation, but the critical genes required for efficient dedifferentiation, proliferation, and redifferentiation remain unknown. In our study, a circular trajectory using single-nucleus RNA sequencing of the pericentriolar material 1 positive (PCM1+) cardiomyocyte nuclei from hearts 1 and 3 days after surgery-induced myocardial infarction (MI) at postnatal day (P) 1 was reconstructed and demonstrated that actin remodeling contributed to the dedifferentiation, proliferation, and redifferentiation of cardiomyocytes after injury. We identified four top actin-remodeling regulators, namely Tmsb4x, Tmsb10, Dmd, and Ctnna3, which we collectively referred to as 2D2P. Transiently expressed changes of 2D2P, using a polycistronic non-integrating lentivirus driven by Tnnt2 (cardiac-specific troponin T) promoters (Tnnt2-2D2P-NIL), efficiently induced transiently proliferative activation and actin remodeling in P7 cardiomyocytes and adult hearts. Furthermore, the intramyocardial delivery of Tnnt2-2D2P-NIL resulted in a sustained improvement in cardiac function without ventricular dilatation, thickened septum, or fatal arrhythmia for at least 4 months. In conclusion, this study highlights the importance of actin remodeling in cardiac regeneration and provides a foundation for new gene-cocktail-therapy approaches to improve cardiac repair and treat heart failure using a novel transient and cardiomyocyte-specific viral construct.

Project description:Single-Cell Imaging and Transcriptomic Analyses of Endogenous Cardiomyocyte Dedifferentiation and Cycling

Project description:We found that cardiomyocyte-specific PRMT1-deficient (PRMT1-cKO) mice showed dilated cardiomyopathy and aberrant cardiac alternative splicing. To identify novel cardiac splicing events, we performed a comprehensive analysis of gene expression changes in hearts of wildtype (WT) and PRMT1-cKO mice using RNA sequencing (RNA-Seq). To investigate differentially expressed genes (false discovery rate (FDR) p<0.05, fold change >2) between control and PRMT1-cKO mice, we performed pairwise comparisons of RNA-Seq data using the CLC Genomics Workbench software.