Project description:Neuropathic pain is a highly prevalent condition for which treatments are hampered by low efficacy and dose-limiting side-effects. Injury to the somatosensory nervous system causes maladaptive plasticity that initiates and maintains chronic pain. Emerging evidence suggests that inflammatory cells of the innate immune system shape the injured nervous system and drive pain pathogenesis. Data from preclinical models and human patient biopsies have specifically implicated peripheral macrophage populations for a pro-algesic role, yet how these cell types influence damaged sensory neurons and whether they directly sensitise their neuronal activity is unclear. Here, we have developed an iPSC co-culture system to study the interactions of macrophages and sensory neurons in a fully humanised experimental model. We found that analogous to endogenous counterparts, iPSC-derived macrophages (iMacs) display a dynamic molecular and functional profile that is highly dependent on neuronal context. Co-culture with injured iPSC-derived sensory neurons (iSNs) induces morphological, gene expression, and secretory profile changes in iMacs that are consistent with in vivo nerve injury datasets. iMacs in turn amplify spontaneous firing in damage sensory neurons, implicating macrophages in a cardinal feature of neuropathic pain. These results illustrate the utility of an iPSC-based model to study signalling between these two cell types; supporting a role for macrophages in directly amplifying damaged sensory neuron activity and suggesting that disrupting pathological signalling between these cell types could be a fruitful avenue for analgesic drug development.

Project description:Nerve injury-induced changes in gene expression in primary sensory neurons, such as trigeminal ganglion (TG) neurons, play a critical role in the genesis of neuropathic pain. Therefore, understanding the molecular mechanisms underlying these changes in the TGs following peripheral nerve injury will enable us to develop a new avenue for managing trigeminal-mediated neuropathic pain. Studies have highlighted the involvement of miRNA-mediated modulation in a wide range of diseases, leading to the exploration of miRNA-based therapeutics as a potential treatment strategy. Here, in this RNA-seq database, we have found that microRNA-216a-3p (miR-216a-3p) and miR-32-5p (miR-32-5p), which are downregulated in injured TGs, are novel functional RNAs involved in regulating trigeminal-mediated neuropathic pain. Histone methylation-mediated miRNA downregulation in TG neurons regulates trigeminal neuropathic pain by targeting either STIM1 (H3K27me3/SOX10/miR-216a-3p/STIM1) or Cav3.2 (GR/miR-32-5p/Cav3.2) channels. Moreover, we found that miR-323-3p exhibited the most significant upregulation in the injured TG. Understanding the mechanistic role of the PRMT2/FOXA2/miR-323-3p/Kv2.1 signaling axis in sensory neurons may advance the discovery of novel therapeutic strategies for neuropathic pain.

Project description:In mice, spared nerve injury replicates symptoms of human neuropathic pain and induces upregulation of many genes in somatosensory neurons. Here we used single cell transcriptomics to probe the effects of partial infraorbital transection of the trigeminal nerve at the cellular level. Uninjured neurons were unaffected by transection of major nerve branches, segregating into many different classes. In marked contrast, axotomy rapidly transformed damaged neurons into just two new and closely-related classes where almost all original identity was lost. Remarkably, sensory neurons also adopted this transcriptomic state following various minor peripheral injuries. By genetically marking injured neurons, we showed that the injuryinduced transformation was reversible, with damaged cells slowly reacquiring normal gene expression profiles. Thus, our data expose transcriptomic plasticity, previously thought of as a driver of chronic pain, as a programed response to many types of injury and a potential mechanism for regulating sensation during wound healing.

Project description:Here we show that importin alpha (α) 3 (KPNA4) controls pain responsiveness in peripheral sensory neurons. An importin α3 knockout mouse showed reduced responsiveness to noxious heat or chemical pain, as well as greater tolerance to neuropathic pain. Similar findings were obtained upon acute knockdown of importin α3 in peripheral sensory neurons. Transcriptome analyses and immunohistochemistry indicated that importin α 3 deficient neurons were impaired in nuclear import of c-Fos. Forty days after spared nerve injury acute down-regulation of importin α3, c-FOS, Jun and the dominat negative AAV9 viruses rescue the neuropathic pain phenotype. In silico screens identified importin α3 deficiency mimicking drug leads that attenuated neuropathic pain and reduced c-Fos nuclear localization. Hence, perturbing c-Fos nuclear import by importin α3 can provide analgesia at peripheral loci in the nervous system

Project description:Although miRNA-mediated epigenetic regulation has been investigated as a potential therapeutic strategy for diseases, its exact functional regulatory contributions to neuropathic pain have not yet been fully elucidated. Herein, we revealed miR-323-3p as a key functional noncoding RNA in modulating trigeminal neuropathic pain. Through combined high-throughput sequencing and qPCR analysis, we revealed that miR-323-3p was most significantly upregulated in the injured trigeminal ganglion (TG). The administration of a miR-323-3p antagomir via intra-TG injection or blockade of miR-323-3p through lentiviral delivery specifically targeting neurons in injured TGs suppressed established trigeminal neuropathic pain. While miR-323-3p inhibition had no effect on inflammatory pain, local induction of miR-323-3p in naive TGs directly elicited pain hypersensitivity. Mechanistically, nerve injury caused upregulated protein expression of arginine methyltransferase 2 (PRMT2), which promotes asymmetric demethylation of H3R8 (H3R8me2a), thereby facilitating the binding of the forkhead box A2 (FOXA2) transcription factor to the miR-323-3p promoter and resulting in the upregulation of miR-323-3p expression. Furthermore, the increase in miR-323-3p expression induced significant reductions in Kv2.1 protein expression and channel currents, resulting in TG neuronal hyperexcitability. Conversely, downregulation of miR-323-3p in the injured TG reversed the decrease in Kv2.1 expression and attenuated nerve injury-induced mechanical allodynia. Thus, miR-323-3p upregulation is causally involved in the development of trigeminal neuropathic pain through the regulation of Kv2.1 channels in the TG. The mechanistic understanding of the PRMT2/FOXA2/miR-323-3p/Kv2.1 signaling axis in sensory neurons may enable the discovery of new therapeutic targets for neuropathic pain management.

Project description:Maladaptive changes of nerve injury–associated genes in dorsal root ganglia (DRGs) are critical for neuropathic pain genesis. Emerging evidence supports the role of long noncoding RNAs (lncRNAs) in regulating gene transcription. Here we identified a conserved lncRNA, named nerve injury–specific lncRNA (NIS-lncRNA) for its upregulation in injured DRGs exclusively in response to nerve injury. This upregulation was triggered by nerve injury–induced increase in DRG ELF1, a transcription factor that bound to the NIS-lncRNA promoter. Blocking this upregulation attenuated nerve injury–induced CCL2 increase in injured DRGs and nociceptive hypersensitivity during the development and maintenance periods of neuropathic pain. Mimicking NIS-lncRNA upregulation elevated CCL2 expression, increased CCL2-mediated excitability in DRG neurons, and produced neuropathic pain symptoms. Mechanistically, NIS-lncRNA recruited more binding of the RNA-interacting protein FUS to the Ccl2 promoter and augmented Ccl2 transcription in injured DRGs. Thus, NIS-lncRNA participates in neuropathic pain likely by promoting FUS-triggered DRG Ccl2 expression and may be a potential target in neuropathic pain management.

Project description:Functionally distinct subtypes/clusters of dorsal root ganglion (DRG) neurons may play different roles in nerve regeneration and pain. However, details about their transcriptomic changes under neuropathic pain conditions remain unclear. Chronic constriction injury (CCI) of the sciatic nerve represents a well-established model of neuropathic pain, and we conducted single-cell RNA-sequencing (scRNA-seq) to characterize subtype-specific perturbations of transcriptomes in lumbar DRG neurons on day 7 post-CCI. By using PirtEGFPf mice that selectively express an enhanced green fluorescent protein in DRG neurons, we established a highly efficient purification process to enrich neurons for scRNA-seq. We observed the emergence of four prominent CCI-induced clusters and a loss of marker genes in injured neurons. Importantly, a portion of injured neurons from several clusters were spared from injury-induced identity loss, suggesting subtype-specific transcriptomic changes in injured neurons. Moreover, uninjured neurons, which are necessary for mediating the evoked pain, also demonstrated cell-type-specific transcriptomic perturbations in these clusters, but not in others. Notably, male and female mice showed differential transcriptomic changes in multiple neuronal clusters after CCI, suggesting transcriptomic sexual dimorphism in DRG neurons after nerve injury. Using Fgf3 as a proof-of-principle, RNAscope study provided further evidence of increased Fgf3 in injured neurons after CCI, supporting scRNA-seq analysis, and calcium imaging study unraveled a functional role of Fgf3 in neuronal excitability. These findings may contribute to the identification of new target genes and the development of DRG neuron cell-type-specific therapies for optimizing neuropathic pain treatment and nerve regeneration.

Project description:Severe peripheral nerve injury (PNI) often causes significant movement disorders and intractable pain. Therefore, promoting nerve regeneration while avoiding neuropathic pain, a problem that remains unsolved, is key to the clinical treatment of PNI patients. Here, we establish a novel spared nerve crush (SNC) rat model that successfully reproduces axonal regeneration and neuropathic pain after PNI. Subsequently, we obtained single-cell RNA sequencing (scRNA-seq) data from rat directly injured and indirectly injured rat dorsal root ganglion (DRG) neurons at various time points after SNC and found that the PEP1 neuronal subtype in directly injured DRG is of particular interest. Through experimental design, sc-RNA sequence processing (EDSSP) and functional verification, we identified a potential key gene, Adcyap1, that encodes a key molecule linking nerve regeneration and pain after PNI. Our study sheds new light on the intrinsic link between axonal regeneration and neuropathic pain following PNI and provides new molecular targets and ideas for therapeutic intervention.

Project description:Chronic neuropathic pain is a major morbidity of neural injury, yet its mechanisms are incompletely understood. Hypersensitivity to previously non-noxious stimuli (allodynia) is a common symptom. Here, we demonstrate that the onset of cold hypersensitivity precedes tactile allodynia and this temporal divergence was associated with major differences in global gene expression in dorsal root ganglia. Transcripts whose expression correlate with the onset of cold allodynia were nociceptor-related whereas those correlating with tactile hypersensitivity were enriched for immune cell activity. Selective ablation of TrpV1 lineage nociceptors resulted in mice that did not acquire cold allodynia but developed normal tactile hypersensitivity. Whereas depletion of macrophages or T cells reduced neuropathic tactile allodynia but not cold hypersensitivity. We conclude that neuropathic pain is contributed to by reactive processes of sensory neurons and immune cells, each leading to distinct forms of pain hypersensitivity, potentially allowing effective drug development targeted to each pain modality.

Project description:Neuropathic pain causes severe suffering and most patients are resilient to current therapies. A core element of neuropathic pain is the loss of inhibitory tone in the spinal cord. Previous studies have shown that foetal GABAergic neuron precursors can provide relief from pain. However, the source of these precursor cells and their multipotent status make them unsuitable for therapeutic use. Here we extend these findings by showing, for the first time, that spinally transplanted, terminally differentiated hiPSC-derived GABAergic (iGABAergic) neurons provide significant, long-term and safe relief from neuropathic pain induced by peripheral nerve injury in mice. Furthermore, iGABAergic Neuron transplants survive long term in the injured spinal cord and show evidence of synaptic integration. Together, this provides the proof in principle for the first viable GABAergic transplants to treat human neuropathic pain patients.