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Role of microRNA-335 carried by bone marrow mesenchymal stem cells-derived extracellular vesicles in bone fracture recovery

Haifeng Hu, Dong Wang, Lihong Li, Haiyang Yin, Guoyu He, Yong-Hong Zhang

2021Cell Death and Disease70 citationsDOIOpen Access PDF

Abstract

Abstract Mesenchymal stem cells (MSCs) have the potential to reduce healing time and treat nonunion in fracture patients. In this study, bone marrow MSCs-derived extracellular vesicles (B-EVs) were firstly extracted and identified. CD9 −/− and normal mice were enrolled for the establishment of fracture models and then injected with B-EVs. Osteoblast differentiation and fracture recovery were estimated. The levels of osteoblast-related genes were detected, and differentially expressed microRNAs (miRs) in B-EVs-treated normal fracture mice were screened and verified. The downstream mechanisms of miR were predicted and assessed. The loss-of functions of miR-335 in B-EV and gain-of-functions of VapB were performed in animal and cell experiments to evaluate their roles in bone fracture. Collectively, B-EVs promoted bone fracture recovery and osteoblast differentiation by releasing miR-335. miR-335 downregulation in B-EVs impaired B-EV functions in fracture recovery and osteoblast differentiation. miR-335 could target VapB, and VapB overexpression reversed the effects of B-EVs on osteoblast differentiation. B-EV treatment activated the Wnt/β-catenin pathway in fracture mice and osteoblasts-like cells. Taken together, the study suggested that B-EVs carry miR-335 to promote bone fracture recovery via VapB and the Wnt/β-catenin pathway. This study may offer insights into bone fracture treatment.

Topics & Concepts

OsteoblastMesenchymal stem cellBone healingCell biologyWnt signaling pathwayBone fractureNonunionBone marrowStem cellmicroRNAChemistryBiologyMedicineImmunologySignal transductionAnatomyBiochemistryGeneIn vitroRadiologyExtracellular vesicles in diseaseMicroRNA in disease regulationCircular RNAs in diseases