Project description:Ankylosing spondylitis (AS) is an osteoimmunology related disease characterized by enthesitis. Previous researches demonstrated that mechanical strain played the evoked role in AS enthesitis, but the detailed cell interaction and molecular mechanism in microenvironment were unclear. Herein, we constructed the hind paw loading/unloading model in SKG mice and revealed the single cell atlas of mechanical strain related enthesitis. Through single cell RNA sequencing, fibroblast was determined as the major mechanotransductive signal converter in AS enthesitis, and a SDC1+ subpopulation was identified to positively relate to both mechanical strain and disease progression. Located at the sheath side of enthesis, SDC1+ fibroblasts converted the physical strain signal into various cytokines signal, forming the interaction network with downstream inflammatory cells in the enthesitis. Furthermore, computational trajectory analysis uncovered a distinct fate branch of mechanical strain responsing SDC1+ sheath fibroblasts under the control of transcriptional factor SOX5 mediated enhancer and super-enhancer. Specifically inhibiting SOX5 expression in enthesis fibroblast using rAAV9.HAP-1 carrying siRNA sequence for Sox5 intercepted mechanical strain responsing SDC1+ sheath fibroblasts generation, and markedly remit AS enthesitis development. This study may not only contribute to the elucidation of AS pathogenesis but also provide insight into clinical therapy for AS.

Project description:Ankylosing spondylitis (AS) is an osteoimmunology related disease characterized by enthesitis. Previous researches demonstrated that mechanical strain played the evoked role in AS enthesitis, but the detailed cell interaction and molecular mechanism in microenvironment were unclear. Herein, we constructed the hind paw loading/unloading model in SKG mice and revealed the single cell atlas of mechanical strain related enthesitis. Through single cell RNA sequencing, fibroblast was determined as the major mechanotransductive signal converter in AS enthesitis, and a SDC1+ subpopulation was identified to positively relate to both mechanical strain and disease progression. Located at the sheath side of enthesis, SDC1+ fibroblasts converted the physical strain signal into various cytokines signal, forming the interaction network with downstream inflammatory cells in the enthesitis. Furthermore, computational trajectory analysis uncovered a distinct fate branch of mechanical strain responsing SDC1+ sheath fibroblasts under the control of transcriptional factor SOX5 mediated enhancer and super-enhancer. Specifically inhibiting SOX5 expression in enthesis fibroblast using rAAV9.HAP-1 carrying siRNA sequence for Sox5 intercepted mechanical strain responsing SDC1+ sheath fibroblasts generation, and markedly remit AS enthesitis development. This study may not only contribute to the elucidation of AS pathogenesis but also provide insight into clinical therapy for AS.

Project description:Single cell atlas of enthesitis reveals a mechanical strain responsing and SOX5 programmed SDC1+ sheath fibroblast in ankylosing spondylitis [CUT&TAG]

Project description:Single cell atlas of enthesitis reveals a mechanical strain responsing and SOX5 programmed SDC1+ sheath fibroblast in ankylosing spondylitis [scRNA-seq]

Project description:Single cell atlas of enthesitis reveals a mechanical strain responsing and SOX5 programmed SDC1+ sheath fibroblast in ankylosing spondylitis [bulk RNA-seq]

Project description:IL-17A plays an important role in the pathology of psoriasis and psoriatic arthritis (PsA). However, the pathogenic association between the skin and joint manifestations in PsA is not completely understood. In this study, we initially observed that IL-17A and fibroblast growth factor (FGF) 7 induced endochondral ossification in the mouse entheseal histoculture. Importantly, the responses of endochondral ossification by IL-17A stimulation were strongly inhibited by the treatment of a blocking antibody to FGF receptor 2IIIb (FGFR2IIIb), which is the receptor of FGF7, suggesting that FGF7 acts as a downstream factor of IL-17A in the endochondral ossification in the culture. Next, using the animal PsA model, the administration of anti-FGFR2IIIb antibody resulted in significant suppression of ankylosing enthesitis but not dermatitis. Collectively, our findings indicate that augmented IL-17A in PsA dermatitis induces the elevation of FGF7 levels in joint enthesis, and results in the development of ankylosing enthesitis via FGF7 signaling in PsA.

Project description:The repair of injured enthesis remains a challenging clinical issue in sports medicine due to dysregulated inflammation and limited regenerative capability. Nevertheless, the mechanisms through which this dysregulated inflammation deteriorates the regenerative niche of enthesis remain unclear. Here, we found that Nlrp3 inflammasomes were activated in macrophages after enthesis injury and subsequently suppressed the regeneration. Nlrp3 inflammasomes generated a proinflammatory niche through an imbalance between the pro-inflammatory factor IL-1β and anti-inflammatory factors including IL-10 and IL-13. Mechanistically, IL-1β was identified as an inhibitory inflammation signaling in proinflammatory niche, reducing the differentiation and migration of stem cells. Moreover, the P2rx7 receptors were verified as an activation signal for Nlrp3 inflammasome post-injury, and conditional knockout of P2rx7 receptors on myeloid cells promoted enthesis regeneration. Together, these results illustrate that Nlrp3 inflammasome generates a proinflammatory niche to suppress enthesis regeneration, and demonstrate that the P2rx7/Nlrp3 inflammasome axis and IL-1β are promising niche-directed regenerative therapeutic targets for enthesis injury treatment.

Project description:Our studies used scRNA-seq analysis to get a full map of transcriptional profiles of enthesis cells and also a seprate Gli1-lineage enthesis stem cells. By harvesting enthesis cells from different development stages for scRNA-seq analysis, we revealed enthesis cell heterogeneity and identified six cell sub-populations using scRNA-seq. We infered cell differentiation trajectories for enthesis stem cells differentiating into mineralizing chondrocytes. A gene regulatory network analysis combined fluorescent in situ hybridization were then used to identify a number of transcription factors coordinating tenogenesis, chondrogenesis, and osteogenesis to form an enthesis with spatially graded mineralization.To further define the enthesis stem cell population, enthesis Gli1-lineage cells were isolated and their transcriptomes were characterized at single cell resolution. These specific Gli1-responsive cells had a linear trajectory and a capacity of chondrogenesis and osteogenesis. The full characterization of transcriptional landscape of tendon enthesis stem cells demonstrates a promising therapeutic strategies using this cell source for enthesis regeneration.

Project description:Syndecans are cell surface proteoglycans that are involved in many physiopathological processes. To unveil the known signaling effects of shed Syndecan-1 (SDC1) in oral squamous cell carcinoma (OSCC), we overexpressed SDC1 ectodomain and its bioactive peptide and performed immunoaffinity purification followed by mass spectrometry analysis. Follistatin-related protein 1 (FSTL1) was identified with both overexpressed SDC1 forms, and their interaction was confirmed by the solid-phase binding, dot-blotting, confocal co-immunolocalization and selected reaction monitoring (SRM). We have also identified Activin A (ActA) in the SDC1 and pepSDC1 complexes. To further investigate the cross talk between these proteins, singled or doubled silenced SDC1 and FSTL1 OSCC cells were evaluated in an orthotopic mouse model. Tumor tissues showed an opposite epithelial-mesenchymal transition factors regulation, in which singled shSDC1 tissue showed decreased, while singled shFSTL1 and doubled shSDC1-FSTL1 tissues showed increased mRNA levels compared with the control. By Ki-67 immunoreactivity, shFSTL1 showed a higher proliferation than control, which can be explained by the increase in ActA and its receptors mRNA levels. These findings indicate that SDC1 and FSTL1 coordinate individually these two signaling events, acting more strongly on cell invasion and proliferation, respectively. To translate these effects on patient outcome based on their mRNA expression levels, we demonstrated that patients who have individual expression of SDC1 showed higher experience of metastasis than SDC1 and FSTL1 co-expression. This study underscores for the first time the close relationship between SDC1 and FSTL1, signaling, improving our understanding of the role of syndecan-1 in cancer progression.

Project description:The repair of injured enthesis remains clinically challenging in sports medicine. We have proved that the activation of Nlrp3 inflammasomes suppressed enthesis regeneration. So we used single cell RNA-seq to uncover the mechanisms by which Nlrp3 inflammasomes modulate enthesis regeneration