Abstract
Chronic pain is a major concern for patients with osteoarthritis (OA). Current treatments for OA-related pain often fail and may worsen the disease. The sodium channel subtype NaV1.8 has emerged as a potential target for treating pain, leading to the development of NaV1.8 inhibitors in clinical trials. We previously identified Magi-1, a WW domain-containing scaffold protein, as a regulator of NaV1.8 at the plasma membrane of nociceptive neurons. Disrupting the interaction between NaV1.8 and Magi-1 facilitated channel degradation in neurons, reducing pain behavior in multiple animal models. In this study, we investigated the impact of disrupting NaV1.8 scaffolding on an animal model of OA pain using genetic and pharmacological approaches. Genetic Magi-1 knockdown effectively attenuated established OA pain in mice. Pharmacological targeting of the NaV1.8-Magi-1 interaction in rats with a lipidated NaV1.8 WW binding domain decoy peptide inhibited pain behavior for multiple weeks. MicroCT imaging revealed minimal alterations in subchondral bone remodeling in animals injected with the lipidated decoy peptide compared to those receiving scrambled peptide-control animals. This suggested that the NaV1.8 peptidomimetic not only alleviated OA pain but also delayed joint degeneration. Our preclinical studies indicate that intraarticular injection of lipidated peptides capable of disrupting ion channel scaffolding in neurons can provide effective and sustained analgesia for several weeks after a single administration.
Competing Interest Statement
AB is a co-founder of Channavix Therapeutics, LLC and Mimetic Medicines, INC. A Patent Cooperation Treaty (PCT) application (serial number PCT/US2018/65545) was filed on the use of lipidated peptidomimetics targeting NaV1.8 to induce local analgesia and to treat pain by the University at Buffalo. RR is interning at Mimetic Medicines, INC. All other authors declare no competing interests.