Litcius/Paper detail

EZH2 inhibition reduces cartilage loss and functional impairment related to osteoarthritis

Lyess Allas, Sybille Brochard, Quitterie Rochoux, Jules Ribet, Cléo Dujarrier, A. Veyssière, Juliette Aury‐Landas, Ophélie Grard, S. Leclercq, Denis Vivien, Hang‐Korng Ea, Eric Maubert, Martine Cohen‐Solal, Karim Boumédiene, Véronique Agin, Catherine Baugé

2020Scientific Reports25 citationsDOIOpen Access PDF

Abstract

Histone methyltransferase EZH2 is upregulated during osteoarthritis (OA), which is the most widespread rheumatic disease worldwide, and a leading cause of disability. This study aimed to assess the impact of EZH2 inhibition on cartilage degradation, inflammation and functional disability. In vitro, gain and loss of EZH2 function were performed in human articular OA chondrocytes stimulated with IL-1β. In vivo, the effects of EZH2 inhibition were investigated on medial meniscectomy (MMX) OA mouse model. The tissue alterations were assayed by histology and the functional disabilities of the mice by actimetry and running wheel. In vitro, EZH2 overexpression exacerbated the action of IL-1β in chondrocytes increasing the expression of genes involved in inflammation, pain (NO, PGE2, IL6, NGF) and catabolism (MMPs), whereas EZH2 inhibition by a pharmacological inhibitor, EPZ-6438, reduced IL-1β effects. Ex vivo, EZH2 inhibition decreased IL-1β-induced degradation of cartilage. In vivo, intra-articular injections of the EZH2 inhibitor reduced cartilage degradation and improved motor functions of OA mice. This study demonstrates that the pharmacological inhibition of the histone methyl-transferase EZH2 slows the progression of osteoarthritis and improves motor functions in an experimental OA model, suggesting that EZH2 could be an effective target for the treatment of OA by reducing catabolism, inflammation and pain.

Topics & Concepts

OsteoarthritisEZH2In vivoCartilageInflammationMedicineHistone methyltransferaseCancer researchPharmacologyChemistryImmunologyHistoneBiologyPathologyBiochemistryGeneBiotechnologyAnatomyAlternative medicineOsteoarthritis Treatment and MechanismsCancer-related molecular mechanisms researchBone and Joint Diseases