Project description:Bone regeneration involves skeletal stem/progenitor cells within periosteum and bone marrow, the formation of a fibrous callus followed by the deposition of cartilage and bone matrix to consolidate the fracture. Interactions between bone and skeletal muscle are known to play a role in bone repair but the underlying mechanisms are poorly understood. To better understand the role of skeletal muscle during bone repair, we characterized stem/progenitor cells within skeletal muscle that participate in bone repair. We show that cells originating from bone marrow, periosteum and skeletal muscle are all derived from the Prx1 embryonic lineage. We developed a mouse polytrauma model combining a non-stabilized tibial fracture and mechanical injury to adjacent skeletal muscles. In this polytrauma model, bone fracture healing is impaired. We characterized the Prx1-derived cell population within skeletal muscle in response to fracture and to polytrauma. To do so, we performed fracture and polytrauma in Prx1Cre;Rosa mTmG mice. We harvested skeletal muscle surrounding the tibia at d0 (uninjured), and surrounding the fracture site at d3 and d5 post-fracture or post-polytrauma. Following enzymatic and mechanical digestion of skeletal muscle tissue, we FACS sorted Prx1-derived GFP+ cells and sequenced them using the 10X Chromium technology.

Project description:Previous analysis of Myf5-/-:MyoD-/- mouse fetuses lacking skeletal muscle demonstrated the importance of muscle contraction and static loading in mouse skeletogenesis. Previous analysis of Myf5-/-:MyoD-/- mouse fetuses lacking skeletal muscle demonstrated the importance of muscle contraction and static loading in mouse skeletogenesis. Among abnormal skeletal features, micrognathia (mandibular hypoplasia) was detected: small, bent and posteriorly displaced mandible. As an example of Waddingtonian epigenetics, we suggest that muscle, in addition to acting via mechanochemical signal transduction pathways, networks and promoters, also exerts secretory stimuli on skeleton. Our goal is to identify candidate molecules at that muscle-mandible interface. By employing Systematic Subtractive Microarray Analysis approach, we compared gene expression between mandibles of amyogenic and wild type mouse fetuses. We identified a set of candidate genes with involvement in mandibulardevelopment: Cacna1s, Ckm, Des, Mir300, Myog and Tnnc1. We also performed mouse-to-human translational experiments and found analogies. In the light of our findings we discuss various players in mandibular morphogenesis and make an argument for the need to consider mandibular development as a consequence of reciprocal epigenetic interactions of both skeletal and non-skeletal compartments.

Project description:Distinct skeletal stem/progenitor cells (SSPCs) have been identified in the bone marrow, growth plate, and periosteum, which are indispensable for the maintenance and remodeling of the adult skeleton. However, the decline of which cell types are responsible for age-related bone loss and what characteristic changes of these cells during aging remain to be determined. Here, we constructed premature skeletal aging models by depleting metalloproteinase Zmpste24 (Z24) in mice and found that Prx1-dependent, but not Osx-dependent, Z24 deletion caused significant bone loss. Single-cell RNA sequencing (scRNA-seq) revealed that Prx1-expressing cells in the periosteum (pSSPCs) and growth plate (gpSSPCs) significantly declined in progeria mice. Consistent with aggrecan (Acan) expression in gpSSPCs but not pSSPCs, Acan-linked Z24 depletion only caused trabecular bone loss. Chromatin and transcriptional profiling demonstrate that premature aged SSPCs gain apoptotic signaling pathway and mechanosensation decline. Moreover, SSPCs increased after physical exersice and Z24 depletion’s effects on cellular apoptosis and extracellular matrix expression were reverted by mechanical stimuli. Overall, this study identifies that Z24 deficiency-induced impairment of mechanosensation in SSPCs causes bone loss, shedding new insight on how physical exercise can be used to improve bone quality and prevent bone aging.

Project description:We quantify the effects of FAK inhibition on three-dimensional (3D) cultured human fibroblasts at the cellular and transcriptomic level using single cell RNA-sequencing. We demonstrate that mechanical stress induces pro-fibrotic fibroblast differentiation fates in large organisms, which can effectively be averted by FAK inhibition, which induces discrete fibroblast clusters that promote wound regeneration.

Project description:Disuse osteoporosis (DO) occurs in response to mechanical unloading of the skeleton and results in structural changes that compromise bone strength leading to increased fracture risk. Although skeletal stem cells (SSCs) are the main source of osteoblasts and adipocytes in adult bone marrow, whether DO impacts SSC function has not been established. Here, three-month-old male C57BL/6 mice were subjected to a hindlimb unloading (HU) model of disuse osteoporosis for 8 or 14 weeks by tail suspension. Control mice (ambulatory or AMB) were allowed normal use of their hindlimbs. An additional cohort underwent an 8-week recovery period after 8-weeks of unloading. Bone marrow-derived, LepR+ skeletal stem cells (SSCs) were isolated by FACS (n=3 or 4) and pooled prior to RNA isolation. Where indicated, cultured, immuno-depleted, bone marrow-derived mesenchymal stem cells (MSCs) were also collected (n=3) and pooled prior to RNA isolation. Generated libraries were subjected to NGS RNA-seq analysis on the Illumina NextSeq 500. These data delineate unique physiological adaptations to prolonged unloading, demonstrate that DO results in increased leptin expression and sympathetic signaling within the BM niche.

Project description:Cell based bone regeneration strategies offer promise for traumatic bone injuries, congenital defects, non-union fractures and other skeletal pathologies. Postnatal bone remodeling and fracture healing provide evidence that an osteochondroprogenitor cell is present in adult life which can differentiate to remodel or repair the fractured bone. However, cell based skeletal repair in the clinic is still in its infancy mostly due to poor characterization of progenitor cells and lack of knowledge about their in vivo behavior. Here we took a combined approach of high throughput screening, flow based cell sorting and in vivo transplantation to identify markers that identify osteochondroprogenitor cells. We show that the presence of tetraspanin CD9 enriches for osteochondroprogenitors within CD105+vemesenchymal cells and these cells readily form bone upon transplantation. In addition we have used Thy1.2 (CD90) and the ectonucleotidase CD73 to identify subsets within the CD9+ve population that lead to endochondral or intramembranous-like bone formation. Utilization of this unique cell surface phenotype to enrich for osteochondroprogenitor cells will allow for further characterization of the molecular mechanisms that regulate their osteogenic properties. Osteochondroprogenitor sub-populations were arrayed for differentially expressed genes. Osteochondroprogenitor cells were FACS sorted from E16.5 mouse embryonic limb suspension after staining with Flurochrome conjuigated antibodies

Project description:The outer coverings of the skeleton, or periosteum, are arranged in concentric layers and act as a reservoir for tissue specific bone progenitors. Cellular heterogeneity within this tissue depot is increasingly recognized. Here, Pdgfra reporter animals were used to highlight a subset of periosteal progenitor cells with high osteogenic potential. Pdgfra+ periosteal progenitor cells enhanced osteogenic differentiation in vitro and improved fracture healing and bone regeneration in vivo. Depletion of Pdgfra-expressing progenitor cells interferes with cortical appositional bone, periosteal bone formation in response to mechanical load, and during fracture repair. Pdgfra+ periosteal progenitors give rise to Nestin+ periosteal cells overtime, after fracture and upon transplantation.

Project description:Cell based bone regeneration strategies offer promise for traumatic bone injuries, congenital defects, non-union fractures and other skeletal pathologies. Postnatal bone remodeling and fracture healing provide evidence that an osteochondroprogenitor cell is present in adult life which can differentiate to remodel or repair the fractured bone. However, cell based skeletal repair in the clinic is still in its infancy mostly due to poor characterization of progenitor cells and lack of knowledge about their in vivo behavior. Here we took a combined approach of high throughput screening, flow based cell sorting and in vivo transplantation to identify markers that identify osteochondroprogenitor cells. We show that the presence of tetraspanin CD9 enriches for osteochondroprogenitors within CD105+vemesenchymal cells and these cells readily form bone upon transplantation. In addition we have used Thy1.2 (CD90) and the ectonucleotidase CD73 to identify subsets within the CD9+ve population that lead to endochondral or intramembranous-like bone formation. Utilization of this unique cell surface phenotype to enrich for osteochondroprogenitor cells will allow for further characterization of the molecular mechanisms that regulate their osteogenic properties.

Project description:In newborn humans, and up to approximately 2 y of age, calvarial bone defects can naturally regenerate. This remarkable regeneration potential is also found in newborn mice and is absent in adult mice. Since previous studies showed that the mouse calvarial sutures are reservoirs of calvarial skeletal stem cells (cSSCs), which are the cells responsible for calvarial bone regeneration, here we hypothesized that the regenerative potential of the newborn mouse calvaria is due to a significant amount of cSSCs present in the newborn expanding sutures. Thus, we tested whether such regenerative potential can be reverse engineered in adult mice by artificially inducing an increase of the cSSCs resident within the adult calvarial sutures.First, we analyzed the cellular composition of the calvarial sutures in newborn and in older mice, up to 14-mo-old mice, showing that the sutures of the younger mice are enriched in cSSCs. Then, we demonstrated that a controlled mechanical expansion of the functionally closed sagittal sutures of adult mice induces a significant increase of the cSSCs. Finally, we showed that if a calvarial critical size bone defect is created simultaneously to the mechanical expansion of the sagittal suture, it fully regenerates without the need for additional therapeutic aids. Using a genetic blockade system, we further demonstrate that this endogenous regeneration is mediated by the canonical Wnt signaling.This study shows that controlled mechanical forces can harness the cSSCs and induce calvarial bone regeneration. Similar harnessing strategies may be used to develop novel and more effective bone regeneration autotherapies.

Project description:Transposable elements (TEs) are mobile genetic modules of viral derivation that have been co-opted to become modulators of mammalian gene expression. TEs are a major source of endogenous dsRNAs, signaling molecules able to coordinate inflammatory responses in various physiological processes. Here, we provide evidence for a positive involvement of TEs in inflammation-driven bone repair and mineralization. In newly fractured mice bone, we observed an early transient upregulation of repeats occurring concurrently with the initiation of the inflammatory stage. In humans, bone biopsies analysis revealed a significant correlation between repeats expression, mechanical stress and bone mineral density. We investigated a potential link between LINE-1 (L1) expression and bone mineralization by delivering a synthetic L1 RNA to osteoporotic patient-derived mesenchymal stem cells and observed a dsRNA-triggered protein kinase (PKR)-mediated stress response, leading to dramatically increased mineralization. This response was associated with a strong, transient, inflammatory induction, accompanied by a global translation attenuation induced by eif2a phosphorylation. We demonstrated that L1 transfection reshaped the secretory profile of osteoblasts, triggering a paracrine activity that stimulated the mineralization of recipient cells.