Targeting of subcellular metabotropic glutamate receptor 5 signaling to modulate pain transmission

Metabotropic glutamate receptor 5 (mGlu5) is a class C GPCR crucial for neuronal development and synaptic transmission. mGlu5 is a potential therapeutic target in pain management and modulates pain-associated gene expression and signaling pathways. Although mGlu5 inhibitors have shown promise in treating pain, none have translated to the clinic. Up to 90% of neuronal mGlu5 expression is intracellular, although the precise locations and function of different mGlu5 intracellular pools remains unclear. Building on recent evidence showing the importance of endosome-mediated nociceptive signaling by other GPCRs, we hypothesized that endosomal pools of mGlu5 contribute to pain transmission, and that targeted inhibition of intracellular mGlu5 signaling results in superior analgesia. Using calcium mobilization assays and genetically encoded resonance energy transfer biosensors, we report that upon its activation mGlu5 recruits Gq/11 and Gs to the plasma membrane. Conversely, internalized mGlu5 in endosomes recruits only Gq/11 proteins. mGlu5 signaling is highly dependent on receptor trafficking to endosomes, with sustained nuclear ERK1/2 signaling requiring both receptor internalization and active glutamate transport into the cell. We generated pH responsive nanoparticles loaded with the mGlu5 negative allosteric modulator VU0366058 (DIPMA-VU058), enabling endosome-targeted inhibition of mGlu5. Nanoparticle encapsulation of VU0366058 enhanced inhibition of both acute and sustained nuclear ERK1/2 signaling, and significantly reduced neuronal excitability in nociceptive circuits in spinal cord slices from rats with neuropathic pain. Intrathecal administration of DIPMA-VU058 achieved superior analgesia in both inflammatory and neuropathic models of pain in mice compared to free VU0366058 and the reference compound fenobam. These studies demonstrate the importance of endosome-associated receptors for the complete mGlu5 signaling response. Furthermore, we show that manipulating the cellular distribution of an allosteric modulator can engender location-biased pharmacological effects. Together, we have revealed new and unappreciated roles for endosome-specific mGlu5 signaling and demonstrate that endosome-selective targeting may offer an alternative therapeutic approach for modulating mGlu5 activity.