Meteorin resolves nociceptive hypersensitivity by reducing connexin-mediated coupling in satellite glial cells

Neuropathic pain, a persistent condition arising from injury to the nervous system, involves complex interactions between neurons and non-neuronal cells, including satellite glial cells (SGCs) in the dorsal root ganglia (DRG). In this study, we examined the glial-targeting effects of meteorin, a neurotrophic protein with gliogenic properties, using mouse models of neuropathic and inflammatory pain. Systemic meteorin administration reversed mechanical hypersensitivity across diverse neuropathic and inflammatory pain models, with therapeutic effects persisting beyond the treatment period. We identified SGCs as the principal site of meteorin expression and action in the DRG, where it selectively activated SGCs and altered their functional state. Proteomic profiling revealed meteorin-mediated downregulation of gap junction proteins in SGCs, particularly connexin 43, which was corroborated by immunohistochemical analyses. Functional assessments demonstrated that meteorin treatment normalized injury-induced increases in intercellular coupling between SGCs, establishing a mechanistic link between glial network modulation and pain resolution. These findings identify meteorin as a regulator of SGC communication through connexin-dependent mechanisms. The sustained therapeutic effects and multi-model efficacy highlight meteorin as a potential intervention for neuropathic pain while advancing our understanding of SGC plasticity in sensory processing.