Faculty Bibliography

The continued release of neurotransmitters from central projections of nociceptors during chronic pain requires synaptic vesicle (SV) recycling. Mediators of SV endocytosis and recycling are thus pivotal for sustained pain transmission in nociceptive spinal circuits. We hypothesized that disruption of SV endocytosis in dorsal root ganglia (DRG) nociceptors would impede synaptic transmission and thereby provide sustained relief from multimodalities of pain. Synaptojanin 1 (Synj1) and endophilin A1 (EndoA1), which mediate the neck formation of the endocytic pit and subsequent endocytosis, were detected in primary sensory neurons of mouse DRG by immunofluorescence and RNAScope in situ hybridization. Intrathecal injection of Synj1 and EndoA1 siRNA or shRNA successfully knocked down Synj1 and Sh3gl2 (EndoA1) mRNA in DRG neurons and suppressed acute nociception induced by agonists of pronociceptive receptors and ion channels in male mice, without affecting normal motor functions. Synj1 and EndoA1 knockdown inhibited synaptic transmission between primary sensory neurons and neurons in lamina I/II of the spinal cord dorsal horn by suppressing SV release from presynaptic primary afferent neurons. Synj1 and EndoA1 silencing reversed mechanical allodynia and thermal hyperalgesia in preclinical models of postoperative and cancer pain. Knockdown of dynamin 1 (Dnm1) and adaptor-associated protein kinase 1 (AAK1), previously characterized mediators of SV endocytosis in nociceptive spinal circuits, also alleviated pain-like behavior in these models. Thus, Synj1, EndoA1, Dnm1, and AAK1 mediate SV recycling and are thus required for sustained synaptic transmission in nociceptive spinal circuits. Disruption of SV recycling effectively reduces nociceptive transmission, providing a novel strategy for pain relief.

Although many internalized G protein-coupled receptors (GPCRs) continue to signal, the mechanisms and outcomes of intracellular GPCR signaling are uncertain due to the challenges of measuring organelle-specific signals and of selectively antagonizing receptors in intracellular compartments. Herein, genetically encoded biosensors targeted to the plasma membrane and early endosomes were used to analyze compartmentalized signaling of protease-activated receptor 2 (PAR₂); the propensity of nanoparticles (NPs) to accumulate in endosomes was leveraged to preferentially antagonize intracellular PAR₂ signaling of pain. PAR₂ agonists evoked sustained activation of PAR₂, Gαq, and β-arrestin-1 in early endosomes and activated extracellular signal regulated kinase (ERK) in the cytosol and nucleus, measured with targeted biosensors. Fluorescent dendrimer and core-shell polymeric NPs accumulated in endosomes of HEK293T cells, colonic epithelial cells, and nociceptors, detected by confocal microscopy. NPs efficiently encapsulated and slowly released AZ3451, a negative allosteric PAR₂ modulator. NP-encapsulated AZ3451, but not unencapsulated AZ3451, rapidly and completely reversed PAR₂, Gαq, and β-arrestin-1 activation in early endosomes and ERK activation in the cytosol and nucleus. When administered into the mouse colon lumen, fluorescent dendrimer NPs accumulated in endosomes of colonocytes and polymeric NPs accumulated in neurons, sites of PAR₂ expression. Both NP formulations of AZ3451, but not unencapsulated AZ3451, caused long-lasting analgesia and normalized aberrant behavior in preclinical models of inflammatory bowel disease. These results provide evidence that PAR₂ endosomal signaling mediates pain and that nanomedicines that antagonize PAR₂ in endosomes effectively relieve pain. NP-mediated delivery may improve the efficacy of other GPCR antagonists for treatment of diverse diseases.

By improving the delivery and tumor retention of chemotherapeutics, nanomedicines hold potential for cancer treatment. The usefulness of nanoparticle (NP)-encapsulated analgesics for the cancer pain treatment is comparatively unexplored. We investigated whether NPs encapsulating olcegepant (OCP), an antagonist of the calcitonin receptor-like receptor (CLR) for the calcitonin gene-related peptide (CGRP), effectively relieved oral cancer pain in mice. Because persistent endosomal CLR signaling in Schwann cells mediates craniofacial pain, we reasoned that the predisposition of NPs to accumulate in endosomes could be leveraged to effectively relieve oral cancer pain. By expressing biosensors for activated CLR, Gα proteins and β-arrestins in HEK293T and Schwann cells, we found that CGRP activates CLR signaling first at the plasma membrane and then in early, late and recycling endosomes and the cis- and trans-Golgi apparatus. We synthesized biocompatible NPs encapsulating OCP and fluorophores by integrating hydrophobic ion pairing nanoformulation with Flash NanoPrecipitation. NPs slowly released OCP and accumulated in early endosomes, leading to sustained inhibition of endosomal CLR signaling in HEK293T and Schwann cells. Oral cancers were established in mice, which led to heightened pain-like responses. After intra-tumoral injection, NPs were retained in tumors for at least one week. OCP-loaded NPs almost completely reversed allodynia and hyperalgesia for a prolonged period, whereas unencapsulated OCP had small and transient effects. The NP accumulation in endosomal sites of pain signaling, the sustained release of antagonist, and the retention of NPs in tumors explain their beneficial actions. Thus, NP-encapsulation holds promise for the relief of painful cancers that are inadequately treated by opioids.

Analgesia by non-steroidal anti-inflammatory drugs (NSAIDs) is ascribed to inhibition of prostaglandin (PG) biosynthesis and ensuing inflammation. However, NSAIDs have life-threatening side effects, and inhibition of inflammation delays pain resolution. Decoupling the mechanisms underlying PG-evoked pain vs. protective inflammation would facilitate pain treatment. Herein, we reveal that selective silencing of the PGE₂ receptor 2 (EP2) in Schwann cells via adeno-associated viral vectors abrogates the indomethacin-sensitive component of pain-like responses in mice elicited by inflammatory stimuli without affecting inflammation. In human Schwann cells and in mice, EP2 activation and optogenetic stimulation of adenylyl cyclase evokes a plasma membrane-compartmentalized cyclic adenosine monophosphate (cAMP) signal that, via A-kinase anchor protein-associated protein kinase A, sustains inflammatory pain-like responses, but does not delay their resolution. Thus, an unforeseen and druggable EP2 receptor in Schwann cells, via specific cAMP nanodomains, encodes PGE₂-mediated persistent inflammatory pain but not PG-dependent protective inflammation.

Chronic pain is common and debilitating, yet is inadequately treated by current therapies, which can have life-threatening side effects. Treatments targeting G protein-coupled receptors (GPCRs) and receptor tyrosine kinases (RTKs), key pain mediators, often fail in clinical trials for unknown reasons. Here, we discuss the recent evidence that GPCRs and RTKs generate sustained signals from multiprotein signaling complexes or signalosomes in intracellular compartments to control chronic pain. We evaluate the evidence that selective antagonism of these intracellular signals provides more efficacious and long-lasting pain relief than antagonism of receptors at the surface of cells. We highlight how the identification of coreceptors and molecular scaffolds that underpin pain signaling by multiple receptors has identified new therapeutic targets for chronic pain, surmounting the redundancy of the pain signaling pathway.

BACKGROUND AND PURPOSE/OBJECTIVE:Tolerance to the analgesic effects of opioids and resultant dose escalation is associated with worsening of side effects and greater addiction risk. Here, we compare the development of tolerance to the conventional opioid fentanyl with a novel pH-sensitive μ-opioid receptor (MOR) agonist, (±)-N-(3-fluoro-1-phenethylpiperidine-4-yl)-N-phenyl propionamide (NFEPP) that is active only in acidic inflammatory microenvironments. EXPERIMENTAL APPROACH/METHODS:An opioid tolerance model was developed in male C57BL/6 mice, with and without dextran sulphate sodium colitis, using increasing doses of either fentanyl or NFEPP over 5 days. Visceral nociception was assessed in vivo by measuring visceromotor responses (VMRs) to noxious colorectal distensions and in vitro measuring colonic afferent nerve activity of mesenteric nerves and performing patch-clamp recordings from isolated dorsal root ganglia neurons. Somatic thermal nociception was tested using a tail immersion assay. Cardiorespiratory effects were analysed by pulse oximeter experiments. KEY RESULTS/RESULTS:VMRs and tail immersion tests demonstrated tolerance to fentanyl, but not to NFEPP in colitis mice. Cross-tolerance also occurred to fentanyl, but not to NFEPP. The MOR agonist DAMGO inhibited colonic afferent nerve activity in colitis mice exposed to chronic NFEPP, but not those from fentanyl-treated mice. Similarly, in patch-clamp recordings from isolated dorsal root ganglia neurons, DAMGO inhibited neurons from NFEPP-, but not fentanyl-treated mice. CONCLUSION AND IMPLICATIONS/CONCLUSIONS:NFEPP did not exhibit tolerance in an inflammatory pain model, unlike fentanyl. Consequently, dose escalation to maintain analgesia during an evolving inflammation could be avoided, mitigating the potential risk of side effects.

INTRODUCTION/UNASSIGNED:Patients with oral cancer often experience intense functional pain due to mechanical stimulation at the cancer site. The role of mechanosensitive ion channels in oral cancer pain, such as TRPV4, is not fully understood. OBJECTIVES/UNASSIGNED:Our objective was to investigate the role of Schwann cell TRPV4 in oral cancer pain. METHODS/UNASSIGNED:imaging, and patch-clamp electrophysiology. The effect of TRPV4 activation on Schwann cell responses to mechanical stimulation was evaluated using a piezo stimulator. Conditioned media (CM) from TRPV4-activated Schwann cells were injected into the mouse paw to evaluate the contribution of TRPV4 in Schwann cells to mechanical hypersensitivity. RESULTS/UNASSIGNED:responses and whole-cell membrane currents in human Schwann cells. Mechanoactivated currents in human Schwann cells were inhibited by the TRPV4 antagonist HC-067047. Schwann cell CM induced mechanical hypersensitivity in mice, which was blocked by pre-treatment with HC-067047. CONCLUSION/UNASSIGNED:TRPV4 activation plays a role in mediating mechanically induced pain of oral cancer.

Nerve growth factor (NGF) monoclonal antibodies inhibit chronic pain, yet failed to gain approval due to worsened joint damage in osteoarthritis patients. We report that neuropilin-1 (NRP1) is a coreceptor for NGF and tropomyosin-related kinase A (TrkA) pain signaling. NRP1 was coexpressed with TrkA in human and mouse nociceptors. NRP1 inhibitors suppressed NGF-stimulated excitation of human and mouse nociceptors and NGF-evoked nociception in mice. NRP1 knockdown inhibited NGF/TrkA signaling, whereas NRP1 overexpression enhanced signaling. NGF bound NRP1 with high affinity and interacted with and chaperoned TrkA from the biosynthetic pathway to the plasma membrane and endosomes, enhancing TrkA signaling. Molecular modeling suggested that the C-terminal R/KXXR/K NGF motif interacts with the extracellular "b" NRP1 domain within a plasma membrane NGF/TrkA/NRP1 of 2:2:2 stoichiometry. G α interacting protein C-terminus 1 (GIPC1), which scaffolds NRP1 and TrkA to myosin VI, colocalized in nociceptors with NRP1/TrkA. GIPC1 knockdown abrogated NGF-evoked excitation of nociceptors and pain-like behavior. Thus, NRP1 is a nociceptor-enriched coreceptor that facilitates NGF/TrkA pain signaling. NRP binds NGF and chaperones TrkA to the plasma membrane and signaling endosomes via the GIPC1 adaptor. NRP1 and GIPC1 antagonism in nociceptors offers a long-awaited nonopioid alternative to systemic antibody NGF sequestration for the treatment of chronic pain.