Project description:Adult tendon stem/progenitor cells (TSPCs) are essential for tendon maintenance, regeneration, and repair, yet they become susceptible to senescence with age, impairing the self-healing capacity of tendons. In this study, we employ a recently developed deep-learning-based efficacy prediction system to screen potential stemness-promoting and senescence-inhibiting drugs from natural products using the transcriptional signatures of stemness. The top-ranked candidate prim-O-glucosylcimifugin (POG), a saposhnikovia root extract, could ameliorate TPSC- senescent phenotypes caused by long-term passage and natural aging in rats and humans, as well as restore self-renewal and proliferation capacities, and tenogenic potential of aged TSPCs. In vivo, the systematic administration of POG or the local delivery of POG nanoparticles functionally rescues endogenous tendon regeneration and repair capacity in aged rats to levels similar to normal animals. Mechanistically, POG protects TSPCs against functional impairment during both passage-induced and natural aging by simultaneously suppressing nuclear factor-κB and downregulating mTOR signaling with induction of autophagy. Together, the strategy by pharmacological intervention with deep learning-predicted compound POG could rejuvenate aged TSPCs and improve the regenerative capacity of aged tendons. We performed mRNA microarray analyses of DMSO-treated and POG-treated Passage 12 TSPCs and identified meaningful genes in down-regulated and up-regulated group

Project description:Adult tendon stem/progenitor cells (TSPCs) are essential for tendon maintenance, regeneration, and repair, yet they become susceptible to senescence with age, impairing the self-healing capacity of tendons. In this study, we employ a recently developed deep-learning-based efficacy prediction system to screen potential stemness-promoting and senescence-inhibiting drugs from natural products using the transcriptional signatures of stemness. The top-ranked candidate prim-O-glucosylcimifugin (POG), a saposhnikovia root extract, could ameliorate TPSC- senescent phenotypes caused by long-term passage and natural aging in rats and humans, as well as restore self-renewal and proliferation capacities, and tenogenic potential of aged TSPCs. In vivo, the systematic administration of POG or the local delivery of POG nanoparticles functionally rescues endogenous tendon regeneration and repair capacity in aged rats to levels similar to normal animals. Mechanistically, POG protects TSPCs against functional impairment during both passage-induced and natural aging by simultaneously suppressing nuclear factor-κB and downregulating mTOR signaling with induction of autophagy. Together, the strategy by pharmacological intervention with deep learning-predicted compound POG could rejuvenate aged TSPCs and improve the regenerative capacity of aged tendons. We performed mRNA microarray analyses of DMSO-treated and POG-treated TSPCs from 18-month-old rats and identified meaningful genes in down-regulated and up-regulated group

Project description:We have compared the gene expression profile of rat Achilles tendon-derived stem cells in post-natal tendon development. Rat tendon stem/progenitor cells (TSPCs) were isolated at different stages of post-natal development: TSPCs-1d, TSPCs-7d and TSPCs-56d. TSPCs at different post-natal development stages (1d, 7d and 56d) were isolated, cultured and used for microarray analyses at passage 2. All TSPCs in this study were of isolated from more than one individual. Total RNA was extracted and fragmented biotin-tagged cRNA was hybridized to Rat Genome 230 2.0 Array.

Project description:N-acetyl-L-cysteine (NAC) is a potent antioxidant. However, how NAC affects the biological functions of tendon stem/progenitor cells (TSPCs) and tendon repair has not been clarified.The effect of NAC on gene transcription in TSPCs was analyzed by transcriptomes and bioinformatics.

Project description:We have compared the gene expression profile of rat Achilles tendon-derived stem cells in post-natal tendon development. Rat tendon stem/progenitor cells (TSPCs) were isolated at different stages of post-natal development: TSPCs-1d, TSPCs-7d and TSPCs-56d.

Project description:Impaired healing of adult tendons with fibrosis remains clinical challenges while neonatal tendons have full functional restoration. However, age-associated cellular and molecular changes in tendon cells and tendon stem/progenitor cells (TSPCs) remain unknown. Here, comparative single cell transcriptomics of early postnatal (2-week-old) and adult (20-week-old) mouse tendons revealed that adult tendons have reduced number of TSPCs, decreased gene expression in tendon and cartilage development, and a greater population of fibro-tenogenic cells. Notably, adult TSPCs and tenocytes exhibit increased expression of immune-response and oxidative-stress genes with higher EGFR but decreased IGF signaling. Adult tendon cells show increased levels of intracellular reactive oxygen species (ROS) in vivo. In contrast, antioxidant treatment of adult tendons significantly reduces intracellular ROS of TSPCs and improves tendon strength in vivo. Hence, these findings suggest that increased inflammation and ROS during tendon aging deteriorates tendon function and regeneration that can be mitigated by antioxidant treatment.

Project description:Background: Tendon is a major component of musculoskeletal system connecting the muscles to the bone. Tendon injuries are very common orthopedics problems leading to impeded motion. Up to now, there still lacks effective treatments for tendon diseases. Methods: Tendon stem/progenitor cells (TSPCs) were isolated from the patellar tendons of SD rats. The expression levels of genes were evaluated by quantitative RT-PCR. Immunohistochemistry staining was performed to confirm the presence of tendon markers in tendon tissues. Bioinformatics analysis of data acquired by RNA-seq was used to find out the differentially expressed genes. Rat patellar tendon injury model was used to evaluate the effect of U0126 on tendon injury healing. Biomechanical testing was applied to evaluate the mechanical properties of newly formed tendon tissues. Results: In this study, we have shown that ERK inhibitor U0126 rather PD98059 could effectively increase the expression of tendon-related genes and promote the tenogenesis of TSPCs in vitro. To explore the underlying mechanisms, RNA sequencing was performed to identify the molecular difference between U0126-treated and control TSPCs. The result showed that GDF6 was significantly increased by U0126, which is an important factor of the TGFβ superfamily regulating tendon development and tenogenesis. In addition, NBM (nonwoven-based gelatin/polycaprolactone membrane) which mimics the native microenvironment of the tendon tissue was used as an acellular scaffold to carry U0126. The results demonstrated that when NBM was used in combination with U0126, tendon healing was significantly promoted with better histological staining outcomes and mechanical properties. Conclusion: Taken together, we have found U0126 promoted tenogenesis in TSPCs through activating GDF6, and NBM loaded with U0126 significantly promoted tendon defect healing, which provides a new treatment for tendon injury.

Project description:We here report Reln-VLDLR receptor-ligand interactions are the primary mechanism for communication between lymphatic endothelial cells (LECs) and tendon stem/progenitor cells (TSPCs). The depletion of Vldlr results in impaired tendon regeneration.Specifically, lymphoangiocrine Reelin interacts with Col1α1+Vldlr+TSPCs to activate Notch1-Srebf2 mediated cholesterol metabolism loop, maintaining TSPC stemness and enhancing tendon regeneration.

Project description:Here, we investigated the effect of conditioned media (CM) obtained from cultured mouse DRG neurons on Tppp3+ cells, mainly on proliferation and differentiation potential. Peripheral afferent neurons terminate at the surfaces of tendons, yet their role after injury beyond nociceptive functions remain unclear. Using transgenic animal models, sensory neurons were found to sprout after Achilles tendon injury in domains of Nerve growth factor (NGF) expression. Conditional deletion of Ngf in either myeloid or mesenchymal cell types led to tendon repair defects – findings phenocopied by inactivation of TrkA (Tropomyosin receptor kinase A) using a knockin mouse model. A combination of spatial and single cell transcriptomics revealed dysregulated inflammatory and TGF signaling upon lack of neural input. Utilizing sural nerve transection in reporter animals, we identified that neural input is required for proper expansion of Tppp3+ tendon sheath progenitor cells (TSPCs) after injury, and in vitro approaches implicated TGF signaling activation in Tppp3+ TSPC neural response. Finally, in a translational approach, activation of TrkA+ sensory neurons using a partial agonist led to a significant increase in TGF signaling, TSPC expansion, and improved tendon repair. Collectively, these data implicate peripheral afferent neural networks in the coordinated acute tendon injury response, and identify candidate molecules to speed the reparative process.

Project description:Tendinopathy, the most common disorder affecting tendons, is characterized by chronic disorganization of the tendon matrix, which eventually leads to tendon tear and rupture. The goal of this study was to identify a rational molecular target whose blockade can serve as a potential therapeutic intervention for tendinopathy. We identified C1q/TNF-related protein-3 (CTRP3) as a markedly upregulated cytokine in human and rodent tendinopathy. Overexpression of CTRP3 enhanced the progression of tendinopathy by accumulating cartilaginous proteoglycans and degenerating collagenous fibers in the mouse tendon, whereas CTRP3 knockdown suppressed the tendinopathy pathogenesis. Functional blockade of CTRP3 using a neutralizing antibody ameliorated overuse-induced tendinopathy of the Achilles and rotator cuff tendons. Mechanistically, CTRP3 elicited a transcriptomic pattern that stimulates abnormal differentiation of tendon stem/progenitor cells (TSPCs) and ectopic chondrification in tendons, as an effect linked to activation of Akt signaling. Collectively, we reveal an essential role for CTRP3 in tendinopathy and propose a potential therapeutic strategy for the treatment of tendinopathy.