Abstract P412: Mitochondrial Metabolic Transcriptome Profiles During Cardiomyocyte Differentiation From Mouse And Human Pluripotent Stem Cells

Simultaneous increase of myofibrils and mitochondria is a key process of cardiomyocyte differentiation from pluripotent stem cells (PSCs). Specifically, development of mitochondrial oxidative energy metabolism in cardiomyocytes is essential to providing the beating function. Although previous studies reported that mitochondrial oxidative metabolism have some correlation with the differentiation of cardiomyocytes, the mechanism by which mitochondrial oxidative metabolism is regulated and the link between cardiomyogenesis and mitochondrial function are still poorly understood. In the present study, we performed transcriptome analysis on cells at specific stages of cardiomyocyte differentiation from mouse embryonic stem cells (mESCs) and human induced PSCs (hiPSCs). We selected highly upregulated mitochondrial metabolic genes at cardiac lineage commitment and time-dependent manner during cardiomyocyte differentiation and identified the protein-protein interaction network connecting between mitochondrial metabolic and cardiac developmental genes. We found several mitochondrial metabolic regulatory genes at cardiac lineage commitment (Cck, Bdnf, Fabp4, Cebpa, Cdkn2a in mESC-derived cells and CCK, NOS3 in hiPSC-derived cells) and time-dependent manner during cardiomyocyte differentiation (Eno3, Pgam2, Cox6a2, Fabp3 in mESC-derived cells and PGAM2, SLC25A4 in hiPSC-derived cells). Notably, mitochondrial metabolic proteins are highly interacted with cardiac developmental proteins time-dependent manner during cardiomyocyte differentiation rather than cardiac lineage commitment. Furthermore, mitochondrial metabolic proteins are mainly interacted with cardiac muscle contractile proteins rather than cardiac transcription factors in cardiomyocyte. Therefore, mitochondrial metabolism is critical at cardiac maturation rather than cardiac lineage commitment.

Abstract MP245: Tet Proteins Regulate Second Heart Field Multipotent Progenitors Differentiating To Myocytes

DNA methylation and demethylation play an important role in shaping the epigenetic landscape and chromatin accessibility to control gene expression during development in mammals. Ten-eleven Translocation (Tet1, Tet2 and Tet3) is a family of dioxygenases that catalyze DNA methylation oxidation with ultimate DNA demethylation. Our previous study showed that cardiac-specific deletion of Tet2 and Tet3 could disrupt YY1-mediated long range chromatin interactions during heart development and lead to ventricular non-compaction cardiomyopathy. However, it is still unclear whether and how Tet protein mediated epigenetic modifications contribute to cardiac lineage specification during embryonic development. In this study, we generated cardiac specific Tet1-3 triple deficient (Tet-TKO) mouse lines using various cardiac specific Cres to evaluate the function of Tet protein in regulating cardiac lineage specification. We observed developmental defects at outflow tract (OFT) in Tet-TKO embryos, suggesting that Tet deficiency affects the second heart field (SHF) development. Single cell RNA-seq analysis further revealed the accumulation of multipotent SHF progenitors and subsequent halt of myocyte differentiation upon Tet depletion. At the molecular level, we found that Tet ablation perturbs the transcriptional network of Islet1, a transcription factor that is crucial for cardiac development in embryos. Overall, our study demonstrates a critical role of Tet-mediated epigenetic regulation for embryonic cardiac development.

Epigenetic Regulation of Cardiomyocyte Differentiation from Embryonic and Induced Pluripotent Stem Cells

With the intent to achieve the best modalities for myocardial cell therapy, different cell types are being evaluated as potent sources for differentiation into cardiomyocytes. Embryonic stem cells and induced pluripotent stem cells have great potential for future progress in the treatment of myocardial diseases. We reviewed aspects of epigenetic mechanisms that play a role in the differentiation of these cells into cardiomyocytes. Cardiomyocytes proliferate during fetal life, and after birth, they undergo permanent terminal differentiation. Upregulation of cardiac-specific genes in adults induces hypertrophy due to terminal differentiation. The repression or expression of these genes is controlled by chromatin structural and epigenetic changes. However, few studies have reviewed and analyzed the epigenetic aspects of the differentiation of embryonic stem cells and induced pluripotent stem cells into cardiac lineage cells. In this review, we focus on the current knowledge of epigenetic regulation of cardiomyocyte proliferation and differentiation from embryonic and induced pluripotent stem cells through histone modification and microRNAs, the maintenance of pluripotency, and its alteration during cardiac lineage differentiation.

Myocyte-specific enhancer factor 2c triggers transdifferentiation of adipose tissue-derived stromal cells into spontaneously beating cardiomyocyte-like cells

Cardiomyocyte regeneration is limited in adults. The adipose tissue-derived stromal vascular fraction (Ad-SVF) contains pluripotent stem cells that rarely transdifferentiate into spontaneously beating cardiomyocyte-like cells (beating CMs). However, the characteristics of beating CMs and the factors that regulate the differentiation of Ad-SVF toward the cardiac lineage are unknown. We developed a simple culture protocol under which the adult murine inguinal Ad-SVF reproducibly transdifferentiates into beating CMs without induction. The beating CMs showed the striated ventricular phenotype of cardiomyocytes and synchronised oscillation of the intracellular calcium concentration among cells on day 28 of Ad-SVF primary culture. We also identified beating CM-fated progenitors (CFPs) and performed single-cell transcriptome analysis of these CFPs. Among 491 transcription factors that were differentially expressed (≥ 1.75-fold) in CFPs and the beating CMs, myocyte-specific enhancer 2c (Mef2c) was key. Transduction of Ad-SVF cells with Mef2c using a lentiviral vector yielded CFPs and beating CMs with ~ tenfold higher cardiac troponin T expression, which was abolished by silencing of Mef2c. Thus, we identified the master gene required for transdifferentiation of Ad-SVF into beating CMs. These findings will facilitate the development of novel cardiac regeneration therapies based on gene-modified, cardiac lineage-directed Ad-SVF cells.

TMT-based quantitative proteome profiles reveal the memory function of whole heart decellularized matrix for neural stem cells trans-differentiation into cardiac lineage

Whole organ or tissue decellularized matrix is a promising scaffold for tissue engineering because of maintaining the specific memory of the original organ or tissue. Whole organ or tissue decellularized...

AMPKβ1 and AMPKβ2 define an isoform-specific gene signature in human pluripotent stem cells, differentially mediating cardiac lineage specification

AMP-activated protein kinase (AMPK) is a key regulator of energy metabolism that phosphorylates a wide range of proteins to maintain cellular homeostasis. AMPK consists of three subunits: α, β, and γ. AMPKα and β are encoded by two genes, the γ subunit by three genes, all of which are expressed in a tissue-specific manner. It is not fully understood, whether individual isoforms have different functions. Using RNA-Seq technology, we provide evidence that the loss of AMPKβ1 and AMPKβ2 lead to different gene expression profiles in human induced pluripotent stem cells (hiPSCs), indicating isoform-specific function. The knockout of AMPKβ2 was associated with a higher number of differentially regulated genes than the deletion of AMPKβ1, suggesting that AMPKβ2 has a more comprehensive impact on the transcriptome. Bioinformatics analysis identified cell differentiation as one biological function being specifically associated with AMPKβ2. Correspondingly, the two isoforms differentially affected lineage decision toward a cardiac cell fate. Although the lack of PRKAB1 impacted differentiation into cardiomyocytes only at late stages of cardiac maturation, the availability of PRKAB2 was indispensable for mesoderm specification as shown by gene expression analysis and histochemical staining for cardiac lineage markers such as cTnT, GATA4, and NKX2.5. Ultimately, the lack of AMPKβ1 impairs, whereas deficiency of AMPKβ2 abrogates differentiation into cardiomyocytes. Finally, we demonstrate that AMPK affects cellular physiology by engaging in the regulation of hiPSC transcription in an isoform-specific manner, providing the basis for further investigations elucidating the role of dedicated AMPK subunits in the modulation of gene expression.

Abstract 210: Reprogramming Mouse Fibroblasts Into Cardiac Progenitor Cells Using Crispr Technique Targeting Endogenic Genes

Background and Objective: CRISPR tools that allow for precise manipulation of individual loci have not been used in generation of i nduced c ardiac p rogenitor c ells ( iCPC s). This study was designed to determine the feasibility and effectiveness of reprogramming fibroblasts into iCPC using CRISPR activation (CRISPRa) system. Methods: Tail-tip fibroblasts (TTFs) were isolated from Nkx2-5 cardiac enhancer GFP reporter mice. A gRNA pool targeting 17 progenitor genes was synthesized and transduced with dCas9-VP64 lentivirus into TTFs ( Fig.1A ). The phenotype of iCPCs was then characterized by immunostaining and FACS of progenitor markers. Finally, the cardiac-lineage differentiation potential of iCPCs was determined by immunostaining and electrophysiological assay under defined induction mediums. Results: iCPCs with GFP expression were formed in TTFs after transduction of CRISPRa targeting Isl1, Gata4, Baf60c, Tbx5 and Nkx2-5 (Fig.1B), while GFP was not activated by control virus. Cardiac progenitor markers were activated in iCPCs as shown by immunostaining (Fig.1C). The generation efficiency of Flk1-postive iCPCs induced by CRISPRa was ~60% as showed by FACS. iCPCs can be differentiated into cardiomyocytes as identified by immunostaining of cardiac-specific markers (Fig.1D). The iCPC-derived cardiomyocytes displayed spontaneous beating and showed cardiac action potentials (Fig.1E). Conclusion: The CRISPRa system is an efficient and specific way to generate iCPCs, which could provide a novel source of cells for cardiac regenerative medicine. Conversion of fibroblasts into cardiac progenitors poses a novel therapeutic option for repair of myocardial infarction.