Project description:The platelet-derived growth factor receptor alpha (PDGFRα) exhibits divergent effects in skeletal muscle. At physiological levels, signaling through this receptor promotes muscle development in growing embryos and proper angiogenesis in regenerating adult muscle. However, either increased PDGF ligands or enhanced PDGFRα pathway activity causes pathological fibrosis. This excessive collagen deposition, which is seen in aged and diseased muscle, interferes with proper muscle function and limits the effectiveness of gene- and cell-based therapies for muscle disorders. Although compelling evidence exists for the role of PDGFRα in fibrosis, little is known about the cells through which this pathway acts. Here we show that PDGFRα signaling regulates a population of muscle-resident fibro/adipogenic progenitors (FAPs) that play a supportive role in muscle regeneration but may also cause fibrosis when aberrantly regulated. We found that FAPs produce multiple transcriptional variants of PDGFRα with different polyadenylation sites, including an intronic variant that codes for a protein isoform containing a truncated kinase domain. This variant, upregulated during regeneration, acts as a decoy to inhibit PDGF signaling and to prevent FAP over-activation. Moreover, increasing expression of this isoform limits fibrosis in vivo, suggesting both biological relevance and therapeutic potential of modulating polyadenylation patterns in stem cell populations. We used microarrays to explore the biological effects of altering intronic polyadenylation of PDGFRα in FAPs.

Project description:Intronic polyadenylation of PDGFRα in stromal stem cells attenuates muscle fibrosis

Project description:Intronic polyadenylation of PDGFRα in a stromal stem population attenuates muscle fibrosis

Project description:Fibro adipogenic progenitors (FAPs) promote satellite cell differentiation in adult skeletal muscle regeneration. However, in pathological conditions, FAPs are responsible for fibrosis and fatty infiltrations. Here we show that the NOTCH pathway negatively modulates FAP differentiation both in vitro and in vivo. However, FAPs isolated from young dystrophin- deficient mdx mice are insensitive to this control mechanism. An unbiased mass spectrometry-based proteomic analysis of FAPs from muscles of wild type and mdx mice, suggest that the synergistic cooperation between NOTCH and inflammatory signals controls FAP differentiation. Remarkably, we demonstrated that factors released by hematopoietic cells restore the sensitivity to NOTCH adipogenic inhibition in mdx FAPs. These results offer a basis for rationalizing pathological ectopic fat infiltrations in skeletal muscle and may suggest new therapeutic strategies to mitigate the detrimental effects of fat depositions in muscles of dystrophic patients.

Project description:Purpose: To study the requirement of Osr1 expression for FAP function during skeletal muscle regeneration. Methods: We sequenced total mRNAs isolated from adult FAPs FACS sorted from 3 and 7 day post injured hindlimb skeletal muscle of Ctrl (Osr1flox/+ CAGG Cre+) and Osr1 cKO (Osr1flox/flox CAGG Cre+) mice. Results: Loss of Osr1 leads to pro-fibrotic orientation of FAPs and impairs both FAP-macrophage and FAP-MuSCs communication network resulting in impaired regenerative myogenesis and persistent fibrosis. Conclusions: Osr1 is a key transcriptional regulator of FAP regenerative function protecting FAPs from assuming a detrimental pro-fibrotic and anti-myogenic state.

Project description:A trimeric glycoprotein complex on the surface of human cytomegalovirus (CMV) binds to platelet-derived growth factor (PDGF) receptor α (PDGFRα) to mediate host cell recognition and fusion of the viral and cellular membranes. Soluble PDGFRα potently neutralizes CMV in tissue culture, and its potential use as an antiviral therapeutic has the benefit that any escape mutants will likely be attenuated. However, PDGFRα binds multiple PDGF ligands in the human body as part of developmental programs in embryogenesis and continuing through adulthood. Any therapies with soluble receptor therefore come with serious efficacy and safety concerns, especially for the treatment of congenital CMV. Soluble virus receptors that are orthogonal to human biology would reduce safety and efficacy concerns. This engineering problem is solved by deep mutational scanning on the D2-D3 domains of PDGFRα to identify variants that maintain interactions with the CMV glycoprotein trimer in the presence of competing PDGF ligands.

Project description:The platelet-derived growth-factor receptors alpha and beta (PDGFRα and PDGFRβ) mark fibroblasts and pericytes in skeletal muscle, respectively. While the role that these cells play in muscle growth has been evaluated, it was not known whether the receptors that mark these cells play a role in controlling transcriptional and functional changes during skeletal muscle hypertrophy. To evaluate this, we inhibited PDGFR signaling in mice subjected to a synergist ablation muscle growth procedure, and measured changes 3 and 10 days later. The results indicated that PDGF signaling was required for fiber hypertrophy and ECM production that occur during muscle growth.

Project description:Epicardial cells undergo an epithelial-to-mesenchymal transtion (EMT) to generate coronary vascular smooth muscle cells (VSMC) and cardiac fibroblasts. Little is known about the mechanisms regulating EMT or the in vivo signals directing epicardial-derived cell (EPDC) fate. Here, we show that loss of PDGF signaling leads to a disruption in Sox9 expression, and when Sox9 expression was restored in mutant hearts, the EMT defect was rescued. Interestingly, mutants lacking only one of the PDGF genes exhibited a lineage specific requirement for the individual receptors. Loss of PDGFRα resulted in a deficit in cardiac fibroblast formation, while cVSMC development was unperturbed. Conversely, PDGFRβ was required for cVSMC development but not cardiac fibroblast development. Combined, our data demonstrate a novel role for PDGF receptors in epicardial EMT and EPDC development. GSM671723-GSM671724: Total RNA was isolated from E12.5 control and PDGF receptor epicardial knockout hearts using the Trizol reagent. RNA was processed as per manufacturer's instructions (Illumina Gene expression array, Illumina, inc. San Diego, CA, USA) GSM671877-GSM671882: Total RNA was isolated from E12.5 control and PDGF receptor epicardial knockout primary epicardial cultures using the Trizol reagent. RNA was processed as per manufacturer's instructions (Illumina Gene expression array, Illumina, inc. San Diego, CA, USA)

Project description:Platelet-derived growth factor-C (PDGF-C) is one of three known ligands for the tyrosine kinase receptor PDGFRα. Analysis of Pdgfc null mice has demonstrated roles for PDGF-C in palate closure and the formation of cerebral ventricles, but redundancy with other PDGFRα ligands might hide additional functions. In search of further developmental roles for PDGF-C, we generated mice that were double mutants for Pdgfc -/- and Pdgfra GFP/+. These mice display a range of severe phenotypes including cerebellar malformation, neuronal over-migration in the cerebral cortex, spina bifida and lung emphysema. We focused our analysis on the central nervous system (CNS), where PDGF-C was identified as a critical factor for the formation of meninges and assembly of the glia limitans basement membrane.

Project description:Skeletal muscle repair and maintenance are directly and indirectly supported by stromal populations such as vascular cells and fibro-adiopgenic progenitors (FAPs), a subset of which express Twist2 and possess direct myogenic potential in rodents. However, less is understood of the complexity and heterogeneity of human skeletal muscle stromal cells. To this end, we performed single-cell RNA-sequencing on ~2000 cells isolated from the human semitendinosus muscle of young individuals. This demonstrated the presence of two poorly described cell populations. First, we detected a vascular-related cell type that expressed pericyte and pan-endothelial genes that we localized to large blood vessels within skeletal muscle cross-sections and termed endothelial-like pericytes (ELPCs). RNA velocity analysis demonstrated that ELPCs may represent a "transition state" between endothelial cells and pericytes. Analysis of published single-cell RNA-seq datasets revealed evidence for ELPCs in trunk and heart musculature, which showed transcriptional similarity. Additionally, we identified a subset of FAPs expressing TWIST2 mRNA and protein. Human TWIST2-expressing cells were anatomically and transcriptionally comparable to mouse Twist2 cells as they were restricted to the myofiber interstitium, expressed fibrogenic genes but lacked satellite cell markers and colocalized with the FAPs marker PDGFRα in human muscle cross-sections. Taken together, these results highlight the complexity of stromal cells residing in human skeletal muscle and support the utility of single-cell RNA-sequencing for discovery and characterization of poorly described cell populations.