AMPA/kainate glutamate receptor antagonists prevent posttraumatic osteoarthritis
Cleo S. Bonnet, … , Anwen S. Williams, Deborah J. Mason
Cleo S. Bonnet, … , Anwen S. Williams, Deborah J. Mason
Published June 16, 2020
Citation Information: JCI Insight. 2020;5(13):e134055. https://doi.org/10.1172/jci.insight.134055.
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Research Article Bone biology Therapeutics

AMPA/kainate glutamate receptor antagonists prevent posttraumatic osteoarthritis

Abstract

Musculoskeletal disorders represent the third greatest burden in terms of death and disability in the developed world. Osteoarthritis is the single greatest cause of chronic pain, has no cure, and affects 8.5 and 27 million people in the UK and US, respectively. Osteoarthritis is most prevalent in older people, but as it commonly occurs after joint injury, young people with such injuries are also susceptible. Painful joints are often treated with steroid or hyaluronic acid (HA) injections, but treatments to prevent subsequent joint degeneration remain elusive. In animals, joint injury increases glutamate release into the joint, acting on nerves to cause pain, and joint tissues to cause inflammation and degeneration. This study investigated synovial fluid glutamate concentrations and glutamate receptor (GluR) expression in injured human joints and compared the efficacy of GluR antagonists with current treatments in a mouse model of injury-induced osteoarthritis (ACL rupture). GluRs were expressed in the ligaments and meniscus after knee injury, and synovial fluid glutamate concentrations ranged from 19 to 129 μM. Intra-articular injection of NBQX (GluR antagonist) at the time of injury substantially reduced swelling and degeneration in the mouse ACL rupture model. HA had no effect, and Depo-Medrone reduced swelling for 1 day but increased degeneration by 50%. Intra-articular administration of NBQX modified both symptoms and disease to a greater extent than current treatments. There is an opportunity for repurposing related drugs, developed for CNS disorders and with proven safety in humans, to prevent injury-induced osteoarthritis. This could quickly reduce the substantial burden associated with osteoarthritis.

Authors

Cleo S. Bonnet, Sophie J. Gilbert, Emma J. Blain, Anwen S. Williams, Deborah J. Mason

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Figure 4

GluR expression in bone, cartilage, and ligament in the ACL rupture model.

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GluR expression in bone, cartilage, and ligament in the ACL rupture mode...
Strong AMPAR2 staining of synovial lining after NBQX (C) and vehicle (G) treatment was less abundant in intact ACL (K). AMPAR2 stained chondrocytes throughout cartilage under all conditions (A, B, E, F, I, and J). AMPAR2 stained osteocytes after NBQX (D) and vehicle (H) treatment, but fewer osteocytes were positive in intact ACL (L). AMPAR2 stained bone-lining cells after vehicle treatment (H) but was less abundant after NBQX treatment (D) and in intact ACL (L). KA1 stained synovial lining after vehicle treatment (S) but was not detected after NBQX treatment (O) or in intact ACL (W). KA1 stained chondrocytes after NBQX treatment (M and N) and in intact ACL (U and V) but not after vehicle treatment (Q and R). KA1 was not expressed in osteocytes (P, T, and X). KA1 weakly stained bone-lining cells after NBQX (P) and vehicle (T) treatment but was less abundant in intact ACL (X). AMPAR2 and KA1 staining was abundant in ACL fibroblasts from vehicle-treated ACL ruptured mice (CCFF) but was less abundant in NBQX-treated mice (YBB) and almost absent in intact ACL (GGJJ). Positive staining is indicated by black arrows. FC, femoral condyle; TP, tibial plateau; M, meniscus. Scale bars: 50 μm (BD, FH, JL, NP, RT, VX, AA, BB, EE, FF, II, and JJ); 100 μm (A, E, I, M, Q, U, Y, Z, CC, DD, GG, and HH).