技术资料

Craniosynostosis is a multigenic congenital condition in which one or more calvarial sutures have prematurely fused during the development of the fetus. Pathogenic variants in FGFR2 are associated with the development of syndromic craniosynostosis,such as Crouzon,Apert and Pfeifer syndromes. Investigation of FGFR2 -linked craniosynostosis is hindered by the lack of appropriate in vitro models. Patient-derived human induced pluripotent stem cell (hiPSC) in vitro disease models provide the opportunity to investigate the disease,identify molecular targets for pharmaceutical treatments,and enable the generation of autologous pluripotent stem cell catalogues. Here,we report three patient-derived hiPSC lines carrying the C342Y,S252W or E565G FGFR2 pathogenic variant. The patient hiPSC lines express characteristic pluripotency markers and display distinct phosphorylation profiles under unstimulated conditions. FGFR2 C342Y showed autophosphorylation in the absence of bFGF ligand,although downstream docking proteins PLCγ and FRS2α were not phosphorylated. FGFR2 S252W and FGFR2 E565G hiPSCs showed increased phosphorylation of docking proteins PLCγ and FRS2α,whereas FGFR2 was not phosphorylated. These patient hiPSC lines provide molecular and cellular options to investigate FGFR2 -linked craniosynostosis in the patient-specific genomic context and develop therapeutic modalities. View Publication

BackgroundDiabetic peripheral neuropathy (DPN) is one of the most prevalent and debilitating complications of diabetes,marked by chronic neuroinflammation,immune dysregulation,and progressive neuronal degeneration. Current treatments offer limited efficacy,largely focusing on symptomatic relief rather than addressing the underlying disease mechanisms. There is a critical need for disease-modifying therapies that target the molecular basis of DPN.ResultsIn this study,we developed a novel targeted nanotherapeutic system—ZH-1c-EVs@SIN—composed of neural stem cell-derived extracellular vesicles (NSC-EVs) modified with the ZH-1c aptamer and loaded with the anti-inflammatory compound sinomenine (SIN). This system was specifically designed to target microglia and inhibit the WNT5a/TRPV1 signaling pathway. Transcriptomic profiling of microglia revealed key gene networks implicated in DPN pathology and responsive to SIN treatment. Functional assays demonstrated that ZH-1c-EVs@SIN facilitated a shift in microglial phenotype from pro-inflammatory M1 to anti-inflammatory M2,significantly reduced inflammatory cytokine expression,and restored levels of neuronal regulatory proteins. Nanoparticle tracking analysis and transmission electron microscopy confirmed optimal vesicle size and morphology,while fluorescence imaging showed efficient uptake by microglia. In vivo studies in a murine model of DPN revealed marked improvements in pain-related behavior and histopathological signs of nerve damage.ConclusionZH-1c-EVs@SIN represents a promising therapeutic strategy for DPN,offering targeted immunomodulation and enhanced neural repair via regulation of the WNT5a/TRPV1 signaling axis. This nano-delivery platform introduces a novel and precise approach to intervening in diabetic neuropathy and may be applicable to other neuroinflammatory conditions.Graphical abstractMechanism of ZH-1c-EVs@SIN Mediating the WNT5a/TRPV1 Pathway to Improve Immune-Inflammatory Homeostasis in the Treatment of DPN in Mice. View Publication