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ESC-sEVs alleviate non-early-stage osteoarthritis progression by rejuvenating senescent chondrocytes via FOXO1A-autophagy axis but not inducing apoptosis

Kai Feng, Teng Ye, Xuetao Xie, Jiashuo Liu, Liangzhi Gong, Zhengsheng Chen, Juntao Zhang, Haiyan Li, Qing Li, Yang Wang

2024Pharmacological Research12 citationsDOIOpen Access PDF

Abstract

Osteoarthritis (OA) is a common joint degenerative disease which currently lacks satisfactory disease-modifying treatments. Oxidative stress-mediated senescent chondrocytes accumulation is closely associated with OA progression, which abrogates cartilage metabolism homeostasis by secreting senescence-associated secretory phenotype (SASP) factors. Numerous studies suggested mesenchymal stem cells-derived small extracellular vesicles (MSC-sEVs) have been regarded as promising candidates for OA therapy. However, MSC-sEVs were applied before the occurrence of cartilage degeneration or at early-stage OA, while in clinical practice, most OA patients who present with pain are already in non-early-stage. Recently, embryonic stem cells-derived sEVs (ESC-sEVs) have been reported to possess powerful anti-aging effects. However, whether ESC-sEVs could attenuate non-early-stage OA progression remains unknown. In this study, we demonstrated ESC-sEVs ameliorated senescent phenotype and cartilage destruction in both mechanical stress-induced non-early-stage posttraumatic OA and naturally aged mice. More importantly, we found ESC-sEVs alleviated senescent phenotype by rejuvenating aged chondrocytes but not inducing apoptosis. We also provided evidence that the FOXO1A-autophagy axis played an important role in the anti-aging effects of ESC-sEVs. To promote clinical translation, we confirmed ESC-sEVs reversed senescent phenotype in ex-vivo cultured human end-stage OA cartilage explants. Collectively, our findings reveal that ESC-sEVs-based therapy is of high translational value in non-early-stage OA treatment. Preparation of ESC-sEVs and the therapeutic mechanism in OA. • ESC-sEVs reversed senescent phenotype in posttraumatic OA, naturally aged mice, and cultured human OA cartilage • ESC-sEVs attenuated senescent phenotype by rejuvenating chondrocytes but not inducing apoptosis • The FOXO1A-autophagy axis played an important role in the anti-aging effects of ESC-sEVs • ESC-sEVs-based therapy is of high translational value in intervention for non-early-stage OA.

Topics & Concepts

AutophagyApoptosisOsteoarthritisStage (stratigraphy)Cancer researchMedicineCell biologyBiologyPathologyGeneticsAlternative medicinePaleontologyOsteoarthritis Treatment and MechanismsExtracellular vesicles in diseaseCancer-related molecular mechanisms research