Project description:Quiescent muscle stem cells, commonly known as satellite cells, are crucial for muscle repair and can convert into committed myoblasts capable of proliferation and differentiation upon in vitro culture. However, following prolonged propagation, myoblasts frequently lose myogenic differentiation capacity, limiting their utility in research and clinical applications. Here, we demonstrate that exposing committed mouse myoblasts to a small-molecule cocktail elicits their conversion into expandable and heterogeneous myogenic progenitor cells (MPCs), comprised of muscle stem, progenitor and differentiated cells. Utilizing a new dual-fluorescent reporter for Pax7 and MyoD, we demonstrate that the small molecules de-differentiate Pax7+/MyoD+ myoblasts into Pax7+/MyoD- satellite-like cells within days. This conversion is characterized by upregulation of signaling pathways associated with satellite cells including Notch, Calcitonin and EGFR. Accordingly, genetic ablation of Notch1-expressing cells abrogated MPC cultures but not committed myoblasts. Furthermore, a comparison with in vivo-derived freshly isolated and activated satellite cells through single-cell transcriptomics revealed that the stem cell subset in MPCs shares common features with both cell types, particularly with a sub-population of activated satellite cells. Collectively, our study presents a method to de-differentiate myoblasts into MPCs harboring satellite cell attributes in vitro, offering a new avenue for studying myogenesis and advancing muscle disease therapeutics.

Project description:Direct lineage reprogramming provides a unique system to study cell fate transitions and unearth molecular mechanisms that safeguard cellular identity. We previously reported on direct conversion of mouse fibroblasts into induced myogenic progenitor cells (iMPCs) by transient MyoD overexpression in concert with small molecules treatment. Here we employed integrative multi-omic approaches to delineate the molecular landscape of fibroblast reprogramming into iMPCs in comparison to transdifferentiation into myogenic cells solely by MyoD overexpression. Utilizing bulk RNA-sequencing and mass spectrometry, we uncovered molecular regulators and pathways that endow a myogenic stem cell identity on fibroblasts only in the presence of small molecule treatment. In addition, we demonstrate that Pax7+ cells in iMPCs share molecular attributes with myoblasts, however in addition express unique genes, proteins and pathways that are indicative of a more activated satellite cell-like state in vitro. Collectively, this study charts a molecular blueprint for reprogramming fibroblasts into muscle stem and progenitor cells and further establishes the fidelity of stable iMPC cultures in capturing skeletal muscle regeneration in vitro for disease modeling and basic research applications.

Project description:Direct lineage reprogramming provides a unique system to study cell fate transitions and unearth molecular mechanisms that safeguard cellular identity. We previously reported on direct conversion of mouse fibroblasts into induced myogenic progenitor cells (iMPCs) by means of transient MyoD overexpression in concert with small molecules treatment. Here we employed integrative multi-omic assays to delineate the molecular landscape of fibroblast reprogramming into iMPCs in comparison to transdifferentiation into myogenic cells solely by MyoD overexpression. Utilizing bulk RNA-sequencing and mass spectrometry we characterized molecular regulators and pathways that endow a myogenic stem cell identity on fibroblasts only in the presence of small molecule treatment. We further demonstrate that iMPC reprogramming is a stepwise process, commencing with the appearance of myofibers and committed myogenic progenitors prior to the formation of satellite cell-like myogenic progenitors that express a suite of stem cell markers including Pax7, Dek, Myf5, Sox8, and Dmrt2. To directly compare iMPCs to satellite cell-derived primary myoblasts, we employed a fluorescent Pax7-GFP reporter to purify Pax7+ cells from the heterogenous iMPC cultures and assess their equivalency to FACS-purified Pax7-GFP+ myoblasts. We demonstrate that Pax7+ iMPCs share molecular attributes with myoblasts, however also express genes and signaling pathways that are indicative of activated satellite cells including Carm1, Dlk1, Lgr5, Fos, Dek, Calcr and Pitx3. We further establish that iMPC formation and maintenance is dependent on the Notch pathway, as small molecule inhibition of Notch abrogates iMPC formation and derails stable iMPC cultures via depletion of Pax7 expressing cells. Lastly, using single cell RNA-sequencing we determine the cell populations that comprise iMPCs in addition to reconstructing the differentiation trajectory present in these heterogenous cultures. We demonstrate that a highly proliferative activated satellite cell-like population differentiates into committed myoblasts and myocytes that further give rise to myofibers that express mature muscle markers, thus capturing a dynamic differentiation program in vitro. Collectively, this study charts a molecular blueprint for reprogramming fibroblasts into myogenic stem and progenitor cells and further establishes the fidelity of stable iMPC cultures in capturing skeletal muscle regeneration in vitro for disease modeling and basic research applications.

Project description:Direct lineage reprogramming provides a unique system to study cell fate transitions and unearth molecular mechanisms that safeguard cellular identity. We previously reported on direct conversion of mouse fibroblasts into induced myogenic progenitor cells (iMPCs) by means of transient MyoD overexpression in concert with small molecules treatment. Here we employed integrative multi-omic assays to delineate the molecular landscape of fibroblast reprogramming into iMPCs in comparison to transdifferentiation into myogenic cells solely by MyoD overexpression. Utilizing bulk RNA-sequencing and mass spectrometry we characterized molecular regulators and pathways that endow a myogenic stem cell identity on fibroblasts only in the presence of small molecule treatment. We further demonstrate that iMPC reprogramming is a stepwise process, commencing with the appearance of myofibers and committed myogenic progenitors prior to the formation of satellite cell-like myogenic progenitors that express a suite of stem cell markers including Pax7, Dek, Myf5, Sox8, and Dmrt2. To directly compare iMPCs to satellite cell-derived primary myoblasts, we employed a fluorescent Pax7-GFP reporter to purify Pax7+ cells from the heterogenous iMPC cultures and assess their equivalency to FACS-purified Pax7-GFP+ myoblasts. We demonstrate that Pax7+ iMPCs share molecular attributes with myoblasts, however also express genes and signaling pathways that are indicative of activated satellite cells including Carm1, Dlk1, Lgr5, Fos, Dek, Calcr and Pitx3. We further establish that iMPC formation and maintenance is dependent on the Notch pathway, as small molecule inhibition of Notch abrogates iMPC formation and derails stable iMPC cultures via depletion of Pax7 expressing cells. Lastly, using single cell RNA-sequencing we determine the cell populations that comprise iMPCs in addition to reconstructing the differentiation trajectory present in these heterogenous cultures. We demonstrate that a highly proliferative activated satellite cell-like population differentiates into committed myoblasts and myocytes that further give rise to myofibers that express mature muscle markers, thus capturing a dynamic differentiation program in vitro. Collectively, this study charts a molecular blueprint for reprogramming fibroblasts into myogenic stem and progenitor cells and further establishes the fidelity of stable iMPC cultures in capturing skeletal muscle regeneration in vitro for disease modeling and basic research applications.

Project description:Direct lineage reprogramming provides a unique system to study cell fate transitions and unearth molecular mechanisms that safeguard cellular identity. We previously reported on direct conversion of mouse fibroblasts into induced myogenic progenitor cells (iMPCs) by means of transient MyoD overexpression in concert with small molecules treatment. Here we employed integrative multi-omic assays to delineate the molecular landscape of fibroblast reprogramming into iMPCs in comparison to transdifferentiation into myogenic cells solely by MyoD overexpression. Utilizing bulk RNA-sequencing and mass spectrometry we characterized molecular regulators and pathways that endow a myogenic stem cell identity on fibroblasts only in the presence of small molecule treatment. We further demonstrate that iMPC reprogramming is a stepwise process, commencing with the appearance of myofibers and committed myogenic progenitors prior to the formation of satellite cell-like myogenic progenitors that express a suite of stem cell markers including Pax7, Dek, Myf5, Sox8, and Dmrt2. To directly compare iMPCs to satellite cell-derived primary myoblasts, we employed a fluorescent Pax7-GFP reporter to purify Pax7+ cells from the heterogenous iMPC cultures and assess their equivalency to FACS-purified Pax7-GFP+ myoblasts. We demonstrate that Pax7+ iMPCs share molecular attributes with myoblasts, however also express genes and signaling pathways that are indicative of activated satellite cells including Carm1, Dlk1, Lgr5, Fos, Dek, Calcr and Pitx3. We further establish that iMPC formation and maintenance is dependent on the Notch pathway, as small molecule inhibition of Notch abrogates iMPC formation and derails stable iMPC cultures via depletion of Pax7 expressing cells. Lastly, using single cell RNA-sequencing we determine the cell populations that comprise iMPCs in addition to reconstructing the differentiation trajectory present in these heterogenous cultures. We demonstrate that a highly proliferative activated satellite cell-like population differentiates into committed myoblasts and myocytes that further give rise to myofibers that express mature muscle markers, thus capturing a dynamic differentiation program in vitro. Collectively, this study charts a molecular blueprint for reprogramming fibroblasts into myogenic stem and progenitor cells and further establishes the fidelity of stable iMPC cultures in capturing skeletal muscle regeneration in vitro for disease modeling and basic research applications.

Project description:Skeletal muscle harbors quiescent stem cells termed satellite cells and proliferative progenitors termed myoblasts, which play pivotal roles during muscle regeneration. However, current technology does not allow permanent capture of these cell populations in vitro. Here, we show that ectopic expression of the myogenic transcription factor MyoD, combined with exposure to small molecules, reprograms mouse fibroblasts into expandable induced myogenic progenitor cells (iMPCs). iMPCs express key skeletal muscle stem and progenitor cell markers including Pax7 and Myf5 and give rise to Dystrophin-expressing myofibers upon transplantation, a subset of which maintain Pax7 expression in vivo and sustain serial regenerative responses. Similar to satellite cells, iMPCs originate from Pax7+ cells and require Pax7 itself for maintenance. Finally, we show that iMPCs can be established from muscle tissue following small molecule exposure alone. This study thus reports on a robust approach to derive expandable myogenic stem/progenitor-like cells from multiple differentiated cell types.

Project description:Skeletal muscle harbors quiescent stem cells termed satellite cells and proliferative progenitors termed myoblasts, which play pivotal roles during muscle regeneration. However, current technology does not allow permanent capture of these cell populations in vitro. Here, we show that ectopic expression of the myogenic transcription factor MyoD, combined with exposure to small molecules, reprograms mouse fibroblasts into expandable induced myogenic progenitor cells (iMPCs). iMPCs express key skeletal muscle stem and progenitor cell markers including Pax7 and Myf5 and give rise to Dystrophin-expressing myofibers upon transplantation, a subset of which maintain Pax7 expression in vivo and sustain serial regenerative responses. Similar to satellite cells, iMPCs originate from Pax7+ cells and require Pax7 itself for maintenance. Finally, we show that iMPCs can be established from muscle tissue following small molecule exposure alone. This study thus reports on a robust approach to derive expandable myogenic stem/progenitor-like cells from multiple differentiated cell types.

Project description:Muscle satellite cells are a self-renewing pool of stem cells that give rise to daughter myogenic precursor cells in adult skeletal muscle. Published and preliminary data indicated that MyoD and p53 genes are involved in satellite cell differentiation. We would like to know what downstream genes of both transcription factors are affected in satellite cell-derived myoblasts (MyoD-/-, p53 -/-). Experiment Overall Design: this experiment include 3 samples and 25 replicates

Project description:Muscle satellite cells are a self-renewing pool of stem cells that give rise to daughter myogenic precursor cells in adult skeletal muscle. Published and preliminary data indicated that MyoD and p53 genes are involved in satellite cell differentiation. We would like to know what downstream genes of both transcription factors are affected in satellite cell-derived myoblasts (MyoD-/-, p53 -/-). Keywords: other

Project description:Numerous studies have been conducted to improve the supply of myogenic stem cells for patients with muscle disease, including Duchenne muscular dystrophy. Collecting muscle samples from patients in order to obtain myoblasts or satellite cells is very invasive. Thus, a new method for obtaining myogenic stem cells is required. Here, we established stably expandable induced myogenic stem cells (iMSCs) with defined factors. The iMSCs showed high expression levels of Pax7, Myf5, and MyoD. Also, the iMSCs differentiate into myotubes which are multinucleated fiber. Additionally, the iMSCs differentiated into myotubes, which are multinucleated fibers. We confirmed its myogenic differentiation capacity in mdx mice by detecting dystrophin-positive cells in iMSCs-injected TA muscles. The iMSCs showed higher proliferation capacity than MDSCs in both in vitro and vivo. This study suggests the possibility to apply directly converted expandable myogenic stem cells to muscle disease patients.