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: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: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: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.

Project description:Cardiomyocytes derived from induced pluripotent stem cells (iPSC-CMs) or directly reprogrammed from non-myocytes (induced cardiomyocytes, iCMs) are promising sources for heart regeneration or disease modeling. However, the similarities and differences between iPSC-CM and iCM are still unknown. Here we performed transcriptome analyses of beating iPSC-CMs and iCMs generated from cardiac fibroblasts (CFs) of the same origin. Although both iPSC-CMs and iCMs establish CM-like molecular features globally, iPSC-CMs exhibit a relatively hyperdynamic epigenetic status while iCMs exhibit maturation status that more resemble adult CMs. Based on gene expression of metabolic enzymes, iPSC-CMs primarily employ glycolysis while iCMs utilize fatty acid oxidation as the main pathway. Importantly, iPSC-CMs and iCMs exhibit different cell cycle status, alteration of which influenced their maturation. Therefore, our study provides a foundation for understanding the pros and cons of different reprogramming approaches.

Project description:RNA-seq data from whole mouse embryos at E3.75 (stage where the three cell types: TE, PrE and EPI are well resolved) and from dissected ICMs in order to identify genes expressed specifically in the ICM We used E3.75 whole mouse embryos at the blastocyst stage and immunosurgically dissected ICMs for RNA extraction and sequencing

Project description:Direct lineage conversion offers a new strategy for tissue regeneration and disease modeling. Despite recent success in directly reprogramming fibroblasts into a wide spectrum of cell types, the precise changes that fibroblasts undergo as they progress to target cell fates remain unclear. The inherent heterogeneity and asynchronous nature of the reprogramming process make it difficult to study using bulk genomic techniques. Therefore, a fundamental and detailed understanding of global transcriptome changes at the single cell level is necessary to better optimize reprogramming for therapeutic purposes and to advance the understanding of cell plasticity and cell identity acquisition. Here, we applied single-cell RNA-seq to analyze global transcriptome changes at early stages of induced cardiomyocyte (iCM) reprogramming. Using unsupervised dimensionality reduction and clustering algorithms, we identified molecularly distinct subpopulations of cells along the reprogramming process from fibroblasts to iCMs, including a novel intermediate state that exhibited molecular signatures of both fibroblast and cardiomyocyte. In summary, our single cell transcriptomics approaches enabled us to construct a reprogramming trajectory and uncover the intermediate cell populations, regulatory pathways and genes putatively involved in iCM induction.

Project description:Direct lineage conversion offers a new strategy for tissue regeneration and disease modeling. Despite recent success in directly reprogramming fibroblasts into a wide spectrum of cell types, the precise changes that fibroblasts undergo as they progress to target cell fates remain unclear. The inherent heterogeneity and asynchronous nature of the reprogramming process make it difficult to study using bulk genomic techniques. Therefore, a fundamental and detailed understanding of global transcriptome changes at the single cell level is necessary to better optimize reprogramming for therapeutic purposes and to advance the understanding of cell plasticity and cell identity acquisition. Here, we applied single-cell RNA-seq to analyze global transcriptome changes at early stages of induced cardiomyocyte (iCM) reprogramming. Using unsupervised dimensionality reduction and clustering algorithms, we identified molecularly distinct subpopulations of cells along the reprogramming process from fibroblasts to iCMs, including a novel intermediate state that exhibited molecular signatures of both fibroblast and cardiomyocyte. In summary, our single cell transcriptomics approaches enabled us to construct a reprogramming trajectory and uncover the intermediate cell populations, regulatory pathways and genes putatively involved in iCM induction.

Project description:Direct lineage conversion offers a new strategy for tissue regeneration and disease modeling. Despite recent success in directly reprogramming fibroblasts into a wide spectrum of cell types, the precise changes that fibroblasts undergo as they progress to target cell fates remain unclear. The inherent heterogeneity and asynchronous nature of the reprogramming process make it difficult to study using bulk genomic techniques. Therefore, a fundamental and detailed understanding of global transcriptome changes at the single cell level is necessary to better optimize reprogramming for therapeutic purposes and to advance the understanding of cell plasticity and cell identity acquisition. Here, we applied single-cell RNA-seq to analyze global transcriptome changes at early stages of induced cardiomyocyte (iCM) reprogramming. Using unsupervised dimensionality reduction and clustering algorithms, we identified molecularly distinct subpopulations of cells along the reprogramming process from fibroblasts to iCMs, including a novel intermediate state that exhibited molecular signatures of both fibroblast and cardiomyocyte. In summary, our single cell transcriptomics approaches enabled us to construct a reprogramming trajectory and uncover the intermediate cell populations, regulatory pathways and genes putatively involved in iCM induction.