Project description:Direct cardiac reprogramming of fibroblasts into induced cardiac-like myocytes (iCMs) has emerged as a promising therapeutic strategy to remuscularize injured myocardium. However, the intrinsic metabolic demands that drive the iCM program and maturity remain unclear. Here, we induce efficient iCM production and maturation through metabolic pathway modulations. We show that the knockdown of Stearoyl-CoA desaturase 1 (Scd1) facilitates cardiac reprogramming and functional maturation of iCM. Through Bulk-RNAseq analysis, we found that compared with control group, fibrosis and inflammatory response pathway were significantly down-regulated, while cardiac related features and fatty acid metabolism related genes were up-regulated in shscd1 group. We further observed the expression level of PGC1α which serves as a master regulator of mitochondrial biogenesis and function was significantly increased in shScd1 group from RNA-seq. Mechanistically, we proved that Scd1 knockdown activates PGC1α/PPARβ transcription signal, which further promotes cardiac reprogramming, and induced cardiomyocytes demonstrated more frequent beating, calcium oscillation, and higher energy metabolism as evidenced by increased mitochondrial respiration and gene expression associated with FAO, which provides a new strategy and theoretical basis for cardiac regeneration and repair

Project description:Direct cardiac reprogramming of cardiac fibroblasts (CFs) into induced cardiomyocytes (iCMs) has emerged as a promising potential therapeutic for preserving cardiac function after ischemic injury. Remaining barriers to clinical translation include low conversion efficiency and relative immaturity of iCMs. A major phenotypic distinction between CFs and native CMs is the latter’s reliance on mitochondrial energetics facilitated by their high mitochondrial fusion (joining) activity relative to fission (dividing) activity. However, how mitochondria reorganize during reprogramming remains understudied. We combined metabolic flux assays with novel microscopy techniques to characterize mitochondrial energetics and morphology over a time course of cardiac reprogramming with Mef2c, Gata4 and Tbx5 (MGT). We found that MGT reprogramming induces increased mitochondrial respiration and fusion. However, this reorganization occurs only at later reprogramming time points. Hypothesizing that mitochondrial reorganization represents a rate-limiting step in reprogramming, we then performed a loss of function screen for a panel of genes known to regulate mitochondrial morphology. We found that the fusion apparatus is essential for successful iCM conversion and identified the fission regulator Mtfr1l as a powerful barrier to reprogramming. Using transcriptomic analysis and concomitant knockdown of the Mtfr1l target Opa1, the effector of inner membrane fusion, we showed that loss of Mtfr1l dramatically improves reprogramming efficiency and the maturity of nascent iCMs by facilitating a metabolic switch toward more interconnected and energetically active mitochondria. This study represents a major step forward in understanding reprogramming mechanisms and is the first report of Mtfr1l as a significant barrier to iCM conversion and maturation.

Project description:Recent studies have been successful at utilizing ectopic expression of transcription factors to generate induced cardiomyocytes (iCMs) from fibroblasts, albeit at a low frequency in vitro. This work investigates the influence of small molecules that have been previously reported to improve differentiation to cardiomyocytes as well as reprogramming to iPSCs in conjunction with ectopic expression of the transcription factors Hand2, Nkx2.5, Gata4, Mef2C, and Tbx5 on the conversion to functional iCMs. We utilized a reporter system in which the calcium indicator GCaMP is driven by the cardiac Troponin T promoter to quantify iCM yield. The TGFβ inhibitor, SB431542 (SB), was identified as a small molecule capable of increasing the conversion of both mouse embryonic fibroblasts and adult cardiac fibroblasts to iCMs up to ~5 fold. Further characterization revealed that inhibition of TGFβ by SB early in the reprogramming process led to the greatest increase in conversion of fibroblasts to iCMs in a dose-responsive manner. Global transcriptional analysis at Day 3 post-induction of the transcription factors revealed an increased expression of genes associated with the development of cardiac muscle in the presence of SB compared to the vehicle control. Incorporation of SB in the reprogramming process increases the efficiency of iCM generation, one of the major goals necessary to enable the use of iCMs for discovery-based applications and for the clinic. Mouse embryonic fibroblasts (MEFs) and adult mouse cardiac fibroblasts (CFs) were transfected with an empty vector (0F) or the combination of Hand2, Nkx2.5, Gata4, Mef2C, and Tbx5 (5F). Samples were exposed to the vehicle control (D, DMSO), SB431542 (SB, 0.5 uM MEF, 5 uM CF), or TGFb1 (T, 2 ng/mL) during culture. Transcription factor expression was induced at Day 0 and samples were isolated at Day 3 post-induction.

Project description:Direct reprogramming of fibroblasts into induced cardiomyocytes (iCMs) holds great promise for heart regeneration. Although great progress has been made in understanding the transcriptional and epigenetic mechanisms of iCM reprogramming, its translational regulation remains largely unexplored. Here we characterized the translational landscape of iCM reprogramming using integrative ribosome and transcriptomic profiling, and showed extensive translatome re-patterning during fibroblast conversion into iCM. Loss of function screening for translational regulators uncovered Ybx1 as a critical barrier to iCM induction. Knockdown of Ybx1 dramatically improved the efficiency and quality of iCM reprogramming. Mechanistically, Ybx1 directly bound the transcripts of Srf and Baf60c, both of which mediated, at least partially, the repressive effect of Ybx1 on iCM generation.and Depletion of Ybx1 de-repressed the translation of its targets including SRF and Baf60c. Interestingly, upon removing Ybx1, Tbx5 alone could reprogram fibroblasts into iCMs that exhibit classic iCM molecular features and reprogramming trajectories revealed by our single cell dual-omics. In sum, we presented here a global view of translatome dynamics of cardiac reprogramming and identified a novel translational barrier, Ybx1, to iCM generation. Removing this barrier allowed the single factor mediated iCM reprogramming.

Project description:Direct reprogramming of fibroblasts into induced cardiomyocytes (iCMs) holds great promise for heart regeneration. Although great progress has been made in understanding the transcriptional and epigenetic mechanisms of iCM reprogramming, its translational regulation remains largely unexplored. Here we characterized the translational landscape of iCM reprogramming using integrative ribosome and transcriptomic profiling, and showed extensive translatome re-patterning during fibroblast conversion into iCM. Loss of function screening for translational regulators uncovered Ybx1 as a critical barrier to iCM induction. Knockdown of Ybx1 dramatically improved the efficiency and quality of iCM reprogramming. Mechanistically, Ybx1 directly bound the transcripts of Srf and Baf60c, both of which mediated, at least partially, the repressive effect of Ybx1 on iCM generation.and Depletion of Ybx1 de-repressed the translation of its targets including SRF and Baf60c. Interestingly, upon removing Ybx1, Tbx5 alone could reprogram fibroblasts into iCMs that exhibit classic iCM molecular features and reprogramming trajectories revealed by our single cell dual-omics. In sum, we presented here a global view of translatome dynamics of cardiac reprogramming and identified a novel translational barrier, Ybx1, to iCM generation. Removing this barrier allowed the single factor mediated iCM reprogramming.

Project description:Direct reprogramming of fibroblasts into induced cardiomyocytes (iCMs) holds great promise for heart regeneration. Although great progress has been made in understanding the transcriptional and epigenetic mechanisms of iCM reprogramming, its translational regulation remains largely unexplored. Here we characterized the translational landscape of iCM reprogramming using integrative ribosome and transcriptomic profiling, and showed extensive translatome re-patterning during fibroblast conversion into iCM. Loss of function screening for translational regulators uncovered Ybx1 as a critical barrier to iCM induction. Knockdown of Ybx1 dramatically improved the efficiency and quality of iCM reprogramming. Mechanistically, Ybx1 directly bound the transcripts of Srf and Baf60c, both of which mediated, at least partially, the repressive effect of Ybx1 on iCM generation.and Depletion of Ybx1 de-repressed the translation of its targets including SRF and Baf60c. Interestingly, upon removing Ybx1, Tbx5 alone could reprogram fibroblasts into iCMs that exhibit classic iCM molecular features and reprogramming trajectories revealed by our single cell dual-omics. In sum, we presented here a global view of translatome dynamics of cardiac reprogramming and identified a novel translational barrier, Ybx1, to iCM generation. Removing this barrier allowed the single factor mediated iCM reprogramming.

Project description:iPSC-derived iCMs represent a potential therapy for ischemic cardiomyopathy. Previous studies demonstrated enhanced cardiac function following injection of iCMs into the peri-infarct region in mice models. Cardioprotection despite poor engraftment suggests that iCMs may modulate their therapeutic activity by secreted molecules. Exosomes are discrete packages of secreted molecules that are readily taken up by target cells. iCM and iCM-Ex treatment of acute myocardial infarctions (Mis) significantly improved cardiac function in SCID mice. We used microarrays to identify differentially-regulated genes in iCM- or iCM-Ex treated mice and control mice.

Project description:Background: Direct cardiac reprogramming of fibroblasts into cardiomyocytes has emerged as one of the promising strategies to remuscularize the injured myocardium. Yet, it is still insufficient to generate functional induced cardiomyocytes (iCMs) from human fibroblasts using conventional reprogramming cocktails, such as our previously published combination consisting of MEF2C, GATA4, TBX5 and microRNA miR-133 (MGT133). Results: To discover potential missing factors for human direct reprogramming, we performed transcriptomic comparison between human iCMs and functional cardiomyocytes (CMs). We identified T-box transcription factor TBX20 as the top CM gene that is unable to be activated by MGT133. TBX20 is required for normal heart development and cardiac function in adult CMs but its role on cardiac reprogramming remains undefined. Here, we found that transduction of MGT133+TBX20 in human cardiac fibroblasts resulted in enhanced reprogramming featured with significantly activated contractility gene programs and signatures more similar to ventricular CMs. Human iCMs produced with MGT133+TBX20 more frequently demonstrated beating and calcium oscillation in co-culture with pluripotent stem cell derived CMs. More mitochondria and higher mitochondrial respiration were also detected in iCMs after TBX20 overexpression. Mechanistically, comprehensive transcriptomic, chromatin occupancy and epigenomic integration revealed that TBX20 localized to the cis-regulatory enhancers of under-expressed cardiac genes, such as MYBPC3, MYH7 and MYL4, to activate gene expression via strengthening the occupancy and co-occupancy of transcription factors. Furthermore, we identified TBX20-regulated enhancers and confirmed the synergistic effect of MGT and TBX20 on enhancer activation. Conclusions: TBX20 promotes cardiac cell fate conversion via direct activating cardiac enhancers. Human iCMs generated with TBX20 showed enhanced cardiac function in terms of contractility and mitochondrial respiration.

Project description:Background: Direct cardiac reprogramming of fibroblasts into cardiomyocytes has emerged as one of the promising strategies to remuscularize the injured myocardium. Yet, it is still insufficient to generate functional induced cardiomyocytes (iCMs) from human fibroblasts using conventional reprogramming cocktails, such as our previously published combination consisting of MEF2C, GATA4, TBX5 and microRNA miR-133 (MGT133). Results: To discover potential missing factors for human direct reprogramming, we performed transcriptomic comparison between human iCMs and functional cardiomyocytes (CMs). We identified T-box transcription factor TBX20 as the top CM gene that is unable to be activated by MGT133. TBX20 is required for normal heart development and cardiac function in adult CMs but its role on cardiac reprogramming remains undefined. Here, we found that transduction of MGT133+TBX20 in human cardiac fibroblasts resulted in enhanced reprogramming featured with significantly activated contractility gene programs and signatures more similar to ventricular CMs. Human iCMs produced with MGT133+TBX20 more frequently demonstrated beating and calcium oscillation in co-culture with pluripotent stem cell derived CMs. More mitochondria and higher mitochondrial respiration were also detected in iCMs after TBX20 overexpression. Mechanistically, comprehensive transcriptomic, chromatin occupancy and epigenomic integration revealed that TBX20 localized to the cis-regulatory enhancers of under-expressed cardiac genes, such as MYBPC3, MYH7 and MYL4, to activate gene expression via strengthening the occupancy and co-occupancy of transcription factors. Furthermore, we identified TBX20-regulated enhancers and confirmed the synergistic effect of MGT and TBX20 on enhancer activation. Conclusions: TBX20 promotes cardiac cell fate conversion via direct activating cardiac enhancers. Human iCMs generated with TBX20 showed enhanced cardiac function in terms of contractility and mitochondrial respiration.

Project description:Background: Direct cardiac reprogramming of fibroblasts into cardiomyocytes has emerged as one of the promising strategies to remuscularize the injured myocardium. Yet, it is still insufficient to generate functional induced cardiomyocytes (iCMs) from human fibroblasts using conventional reprogramming cocktails, such as our previously published combination consisting of MEF2C, GATA4, TBX5 and microRNA miR-133 (MGT133). Results: To discover potential missing factors for human direct reprogramming, we performed transcriptomic comparison between human iCMs and functional cardiomyocytes (CMs). We identified T-box transcription factor TBX20 as the top CM gene that is unable to be activated by MGT133. TBX20 is required for normal heart development and cardiac function in adult CMs but its role on cardiac reprogramming remains undefined. Here, we found that transduction of MGT133+TBX20 in human cardiac fibroblasts resulted in enhanced reprogramming featured with significantly activated contractility gene programs and signatures more similar to ventricular CMs. Human iCMs produced with MGT133+TBX20 more frequently demonstrated beating and calcium oscillation in co-culture with pluripotent stem cell derived CMs. More mitochondria and higher mitochondrial respiration were also detected in iCMs after TBX20 overexpression. Mechanistically, comprehensive transcriptomic, chromatin occupancy and epigenomic integration revealed that TBX20 localized to the cis-regulatory enhancers of under-expressed cardiac genes, such as MYBPC3, MYH7 and MYL4, to activate gene expression via strengthening the occupancy and co-occupancy of transcription factors. Furthermore, we identified TBX20-regulated enhancers and confirmed the synergistic effect of MGT and TBX20 on enhancer activation. Conclusions: TBX20 promotes cardiac cell fate conversion via direct activating cardiac enhancers. Human iCMs generated with TBX20 showed enhanced cardiac function in terms of contractility and mitochondrial respiration.