Project description:Reprogramming of mouse fibroblasts toward a myocardial cell fate by forced expression of cardiac transcription factors or microRNAs has recently been demonstrated. The potential clinical applicability of these findings is based on the minimal regenerative potential of the adult human heart and the limited availability of human heart tissue. An initial, but mandatory step toward clinical application of this approach is to establish conditions for conversion of adult human fibroblasts to a cardiac phenotype. Toward this goal, we sought to determine the optimal combination of factors necessary and sufficient for direct myocardial reprogramming of human fibroblasts. Here we show that four human cardiac transcription factors, including Gata4, Hand2, Tbx5, and myocardin, and two microRNAs, miR-1 and miR-133, activated cardiac marker expression in neonatal and adult human fibroblasts. After maintenance in culture for 4-11 weeks, human fibroblasts reprogrammed with these proteins and microRNAs displayed sarcomere-like structures and calcium transients, and a small subset of such cells exhibited spontaneous contractility. These phenotypic changes were accompanied by expression of a broad range of cardiac genes and suppression of non-myocyte genes. These findings indicate that human fibroblasts can be reprogrammed to cardiac-like myocytes by forced expression of cardiac transcription factors with muscle-specific microRNAs and represent a step toward possible therapeutic application of this reprogramming approach. Human foreskin fibroblasts were transduced with 5 transcription factors and total RNA was obtained 4 weeks later. total RNA was also obtained from human foreskin fibroblasts as a negative control and adult human heart tissue as a positive control. The expression level of genes in each sample was compared.

Project description:Conversion of fibroblasts to functional cardiomyocytes represents a potential approach for restoring cardiac function following myocardial injury, but the technique thus far has been slow and inefficient. To improve the efficiency of reprogramming fibroblasts to cardiac-like myocytes (iCMs) by cardiac transcription factors (Gata4, Hand2, Mef2c, and Tbx5=GHMT), we screened 192 protein kinases and discovered that Akt/protein kinase B dramatically accelerates and amplifies this process. Approximately 50% of reprogrammed fibroblasts displayed spontaneous beating after three weeks of induction by Akt plus GHMT. Furthermore, addition of Akt1 to GHMT evoked a more mature cardiac phenotype for iCMs, as seen by enhanced polynucleation, cellular hypertrophy, gene expression, and metabolic reprogramming. Igf1 and Pi3 kinase acted upstream of Akt, whereas mTORC1 and Foxo3a acted downstream of Akt to influence fibroblast-to-cardiomyocyte reprogramming. These findings provide new insights into the molecular basis of cardiac reprogramming and represent an important step toward further application of this technique.

Project description:Background: Direct cardiac reprogramming is currently being investigated for the generation of cells with a true cardiomyocyte (CM) phenotype. Based on the original approach of cardiac transcription factor-induced reprogramming of fibroblasts into CM-like cells, various modifications of that strategy have been developed. However, they uniformly suffer from poor reprogramming efficacy and a lack of translational tools for target cell expansion and purification. Therefore, our group has developed a unique approach to generate proliferative cells with a pre-CM phenotype that can be expanded in vitro to yield substantial cell doses. Methods: Cardiac fibroblasts were reprogrammed toward CM fate using lentiviral transduction of cardiac transcriptions factors (GATA4, MEF2C, TBX5, and MYOCD). The resulting cellular phenotype was analyzed by RNA sequencing and immunocytology. Live target cells were purified based on intracellular CM marker expression using molecular beacon technology and fluorescence-activated cell sorting. CM commitment was assessed using 5-azacytidine–based differentiation assays and the therapeutic effect was evaluated in a mouse model of acute myocardial infarction using echocardiography and histology. The cellular secretome was analyzed using mass spectrometry. Results: We found that proliferative CM precursor-like cells were part of the phenotype spectrum arising during direct reprogramming of fibroblasts toward CMs. These induced CM precursors (iCMPs) expressed CPC- and CM-specific proteins and were selectable via hairpin-shaped oligonucleotide hybridization probes targeting Myh6/7-mRNA–expressing cells. After purification, iCMPs were capable of extensive expansion, with preserved phenotype when under ascorbic acid supplementation, and gave rise to CM-like cells with organized sarcomeres in differentiation assays. When transplanted into infarcted mouse hearts, iCMPs prevented CM loss, attenuated fibrotic scarring, and preserved ventricular function, which can in part be attributed to their substantial secretion of factors with documented beneficial effect on cardiac repair. Conclusions: Fibroblast reprogramming combined with molecular beacon-based cell selection yields an iCMP-like cell population with cardioprotective potential. Further studies are needed to elucidate mechanism-of-action and translational potential.

Project description:Heart failure (HF) is a leading cause of morbidity and mortality. As adult cardiomyocytes (CMs) have little regenerative capacity, after myocardial infarction (MI), resident cardiac fibroblasts (CFs) synthesize extracellular matrix to form scar tissues, resulting in myocardial remodeling and HF. Thus, both cardiac regeneration and fibrosis are therapeutic targets for chronic MI. We previously reported that fibroblasts were directly reprogrammed into induced CMs (iCMs) by overexpression of cardiogenic transcription factors in vitro and in vivo in acute MI. Here we show that in vivo cardiac reprogramming generated iCMs from resident CFs, improved cardiac function, and reversed fibrosis in chronic MI using a novel transgenic mouse system. Transcriptome analysis revealed that in vivo cardiac reprogramming altered the interstitial cell landscape, suppressed signs of fibrosis and inflammation, and activated the angiogenic program. Thus, in vivo cardiac reprogramming may be a promising approach for chronic HF.

Project description:Heart failure (HF) is a leading cause of morbidity and mortality. As adult cardiomyocytes (CMs) have little regenerative capacity, after myocardial infarction (MI), resident cardiac fibroblasts (CFs) synthesize extracellular matrix to form scar tissues, resulting in myocardial remodeling and HF. Thus, both cardiac regeneration and fibrosis are therapeutic targets for chronic MI. We previously reported that fibroblasts were directly reprogrammed into induced CMs (iCMs) by overexpression of cardiogenic transcription factors in vitro and in vivo in acute MI. Here we show that in vivo cardiac reprogramming generated iCMs from resident CFs, improved cardiac function, and reversed fibrosis in chronic MI using a novel transgenic mouse system. Single-cell transcriptome analysis revealed that cardiac reprogramming shifted matrix-producing CFs, matrifibrocytes, to a quiescent state and changed the interstitial cell landscape, suppressing fibrotic and inflammatory signatures and activating angiogenic program. Thus, in vivo cardiac reprogramming may be a promising approach for chronic HF.

Project description:Reprogramming of human fibroblasts toward a cardiac fate

Project description:FGF2, FGF10, and VEGF greatly promote cardiac reprogramming under defined serum-free conditions by enhancing the conversion of partially reprogrammed cells into fully reprogrammed functional iCMs. Fibroblasts can be directly reprogrammed into cardiomyocyte-like cells (iCMs) by overexpression of cardiac transcription factors, including Gata4, Mef2c, and Tbx5; however, this process is inefficient under serum-based culture conditions, in which the conversion of partially reprogrammed cells into fully reprogrammed functional iCMs has been a major hurdle. Here, we report that a combination of fibroblast growth factor (FGF) 2, FGF10, and vascular endothelial growth factor (VEGF), termed FFV, promoted cardiac reprogramming under defined serum-free conditions, increasing spontaneously beating iCMs by 100-fold compared with those under conventional serum-based conditions. Mechanistically, FFV activated multiple cardiac transcriptional regulators and converted partially reprogrammed cells into functional iCMs through the p38 mitogen-activated protein kinase and phosphoinositol 3-kinase/AKT pathways. Moreover, FFV enabled cardiac reprogramming with only Mef2c and Tbx5 through the induction of cardiac reprogramming factors, including Gata4. Thus, defined culture conditions promoted the quality of cardiac reprogramming, and this finding provides new insights into the mechanism of cardiac reprogramming.

Project description:Fibroblasts can be directly reprogrammed toward a cardiac fate by introducing cardiogenic transcription factors (TFs), although the underlying mechanisms of the cardiac reprogramming process remain unclear. Three cardiac TFs, GATA4, MEF2C, and Tbx5 (referred to as GMT) can activate cardiac genes in fibroblasts and their cardiogenic activity is enhanced by the Hand2 TF and the Akt1 kinase. To understand the mechanistic basis of cardiac reprogramming, we performed a genome-wide analysis of cardiogenic TF binding sites and active enhancers, which were annotated by H3K27ac histone modification, during the reprogramming process. We found that cardiogenic TFs rapidly co-occupy core regulatory elements of cardiac genes and activate myriad cardiac enhancers that are enriched predominantly in Mef2 binding sites. Addition of Hand2 and Akt1 to the GMT reprogramming cocktail expands the spectrum of co-occupied active cardiac enhancers. As reprogramming proceeds over time, reprogramming TFs continue to activate additional cardiac enhancers, which are also enriched for Mef2 motifs, while fibroblast enhancers are silenced. This transition of the enhancer landscape strongly correlated with changes in the fibroblast and cardiac transcriptome. To test the relevance of cardiac reprogramming enhancers to the regulation of cardiogenesis in vivo, we assayed a collection of reprogramming enhancers in transgenic mouse embryos and found that they directed highly specific expression patterns in the developing heart. Our findings demonstrate that Hand2 and Akt1 enhance reprogramming by facilitating cardiac enhancer occupancy and identify Mef2 as a central effector of cardiac reprogramming, which coordinates the actions of accessory factors across a broad landscape of cardiac enhancers.

Project description:Fibroblasts can be directly reprogrammed toward a cardiac fate by introducing cardiogenic transcription factors (TFs), although the underlying mechanisms of the cardiac reprogramming process remain unclear. Three cardiac TFs, GATA4, MEF2C, and Tbx5 (referred to as GMT) can activate cardiac genes in fibroblasts and their cardiogenic activity is enhanced by the Hand2 TF and the Akt1 kinase. To understand the mechanistic basis of cardiac reprogramming, we performed a genome-wide analysis of cardiogenic TF binding sites and active enhancers, which were annotated by H3K27ac histone modification, during the reprogramming process. We found that cardiogenic TFs rapidly co-occupy core regulatory elements of cardiac genes and activate myriad cardiac enhancers that are enriched predominantly in Mef2 binding sites. Addition of Hand2 and Akt1 to the GMT reprogramming cocktail expands the spectrum of co-occupied active cardiac enhancers. As reprogramming proceeds over time, reprogramming TFs continue to activate additional cardiac enhancers, which are also enriched for Mef2 motifs, while fibroblast enhancers are silenced. This transition of the enhancer landscape strongly correlated with changes in the fibroblast and cardiac transcriptome. To test the relevance of cardiac reprogramming enhancers to the regulation of cardiogenesis in vivo, we assayed a collection of reprogramming enhancers in transgenic mouse embryos and found that they directed highly specific expression patterns in the developing heart. Our findings demonstrate that Hand2 and Akt1 enhance reprogramming by facilitating cardiac enhancer occupancy and identify Mef2 as a central effector of cardiac reprogramming, which coordinates the actions of accessory factors across a broad landscape of cardiac enhancers.

Project description:Reprogramming of cardiac fibroblasts into induced cardiomyocyte-like cells (iCMs) in situ represents a promising strategy for cardiac regeneration. A combination of three cardiac transcription factors, Gata4, Mef2c and Tbx5 (GMT), can convert fibroblasts into iCMs, albeit with low efficiency in vitro. Here, we screened 5,500 compounds in primary cardiac fibroblasts and found that a combination of the transforming growth factor (TGF)-β inhibitor SB431542 and the WNT inhibitor XAV939 increased reprogramming efficiency eight-fold when added to GMT-overexpressing cardiac fibroblasts. The small-molecules also enhanced the speed and the quality of cell conversion, as we observed beating cells as early as 1 week after reprogramming compared to 6–8 weeks with GMT alone. In vivo, mice exposed to GMT, SB431542, and XAV939 for 2 weeks after myocardial infarction showed significantly improved reprogramming and cardiac function compared to those exposed to only GMT. Human cardiac reprogramming was similarly enhanced upon TGF-b and WNT inhibition and was achieved most efficiently with GMT plus Myocardin. Thus, TGF-β and WNT inhibitors jointly enhance GMT-induced direct cardiac reprogramming from cardiac fibroblasts in vitro and in vivo and provide a more robust platform for cardiac regeneration.