Alleviation of neuropathic pain with neuropeptide Y requires spinal Npy1r interneurons that coexpress Grp

Neuropeptide Y targets the Y1 receptor (Y1) in the spinal dorsal horn (DH) to produce endogenous and exogenous analgesia. DH interneurons that express Y1 (Y1-INs; encoded by Npy1r) are necessary and sufficient for neuropathic hypersensitivity after peripheral nerve injury. However, as Y1-INs are heterogenous in composition in terms of morphology, neurophysiological characteristics, and gene expression, we hypothesized that a more precisely defined subpopulation mediates neuropathic hypersensitivity. Using fluorescence in situ hybridization, we found that Y1-INs segregate into 3 largely nonoverlapping subpopulations defined by the coexpression of Npy1r with gastrin-releasing peptide (Grp/Npy1r), neuropeptide FF (Npff/Npy1r), and cholecystokinin (Cck/Npy1r) in the superficial DH of mice, nonhuman primates, and humans. Next, we analyzed the functional significance of Grp/Npy1r, Npff/Npy1r, and Cck/Npy1r INs to neuropathic pain using a mouse model of peripheral nerve injury. We found that chemogenetic inhibition of Npff/Npy1r-INs did not change the behavioral signs of neuropathic pain. Further, inhibition of Y1-INs with an intrathecal Y1 agonist, [Leu31, Pro34]-NPY, reduced neuropathic hypersensitivity in mice with conditional deletion of Npy1r from CCK-INs and NPFF-INs but not from GRP-INs. We conclude that Grp/Npy1r-INs are conserved in higher order mammalian species and represent a promising and precise pharmacotherapeutic target for the treatment of neuropathic pain.

Neuropeptide Y targets the Y1 receptor (Y1) in the spinal dorsal horn (DH) to produce endogenous and exogenous analgesia.DH interneurons that express Y1 (Y1-INs; encoded by Npy1r) are necessary and sufficient for neuropathic hypersensitivity after peripheral nerve injury.However, as Y1-INs are heterogenous in composition in terms of morphology, neurophysiological characteristics, and gene expression, we hypothesized that a more precisely defined subpopulation mediates neuropathic hypersensitivity.Using fluorescence in situ hybridization, we found that Y1-INs segregate into 3 largely nonoverlapping subpopulations defined by the coexpression of Npy1r with gastrinreleasing peptide (Grp/Npy1r), neuropeptide FF (Npff/Npy1r), and cholecystokinin (Cck/Npy1r) in the superficial DH of mice, nonhuman primates, and humans.Next, we analyzed the functional significance of Grp/Npy1r, Npff/Npy1r, and Cck/Npy1r INs to neuropathic pain using a mouse model of peripheral nerve injury.We found that chemogenetic inhibition of Npff/Npy1r-INs did not change the behavioral signs of neuropathic pain.Further, inhibition of Y1-INs with an intrathecal Y1 agonist, [Leu 31 , Pro 34 ]-NPY, reduced neuropathic hypersensitivity in mice with conditional deletion of Npy1r from CCK-INs and NPFF-INs but not from GRP-INs.We conclude that Grp/Npy1r-INs are conserved in higher order mammalian species and represent a promising and precise pharmacotherapeutic target for the treatment of neuropathic pain.JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554However, further questions are raised by the highly heterogenous composition of Y1-INs in terms of morphology, neurophysiological characteristics, and gene expression (25,26,34,35).For example, Y1 immunoreactivity in the rat revealed distinctive morphological and neurochemical Y1-IN subpopulations (25,34,35), our ex vivo lumbar spinal cord slice recordings from a reliable Npy1r eGFP mouse line identified 4 distinct neurophysiological firing patterns of Y1-INs (24,29), and unbiased single-cell transcriptomics in the mouse identified Npy1r expression in 3 excitatory DH neuron clusters (36).The heterogeneity of Y1-INs may suggest the existence of subpopulations with distinct physiological roles.Of particular interest are recent results that segregate excitatory interneurons into largely nonoverlapping populations defined by the expression of CCK, neurotensin, neurokinin B (NKB), neuropeptide FF (NPFF), substance P (SP; encoded by Tac1), enhanced green fluorescent protein (EGFP) or Cre recombinase under control of the gastrin-releasing peptide (Grp) promoter in BAC transgenic mice from the GENSAT project (Grp eGFP and Grp Cre ), and gastrin-releasing peptide receptor (GRPR) (37)(38)(39)(40).
Here, we performed fluorescence in situ hybridization (FISH) to characterize the coexpression of these markers with the Npy1r gene.We found that Y1-INs largely segregated into 3 subpopulations (demarcated by the coexpression of Npy1r with Cck, Grp, and Npff, respectively), which are conserved in the nonhuman primate and human DH.We then determined the functional contribution of the Npy1r/Npff population to the behavioral manifestation of mechanical and cold allodynia after peripheral nerve injury.Further, we asked whether pharmacological inhibition with a NPY Y1 agonist eliminates the signs of neuropathic pain in mice with conditional deletion of Npy1r in GRP-INs, CCK-INs, or NPFF-INs.Together, our results elucidate the molecular makeup and functional role of Y1-IN subpopulations and support Grp/Npy1r-INs as an optimal, evolutionarily conserved, and relatively precise pharmacotherapeutic target for the treatment of neuropathic pain.
Y1-IN subpopulations are conserved across higher order mammalian species.To determine the evolutionary conservation of Y1-IN subpopulations, we evaluated the expression of NPY1R, CCK, NPFF, and GRP in spinal cord tissue from rhesus macaque and human organ donors.As in the mouse, NPY1R-expressing cells were abundantly expressed in the superficial DH of macaque and extensively colocalized with CCK (22.49% ± 3.08%), GRP (27.26% ± 1.63%), and NPFF (41.98% ± 2.20%) (Figure 3, A-F).Similarly, NPY1R-expressing cells were plentiful in the superficial DH of human spinal cord and coexpressed CCK, GRP, and NPFF (acknowledging that NPFF expression is sparse in human DH as compared with mouse or macaque) (Figure 3, G-I).Intense lipofuscin prevented accurate quantification in the human spinal cord.
Light brush of the hind paw in mice with neuropathic hypersensitivity evokes Fos in DH Grp/Npy1r-INs.Next, we determined whether the primary Y1-IN subpopulation(s) are sensitized by nerve injury.We performed JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554spared nerve injury (SNI), a model of peripheral neuropathic pain (50) (Figure 4A), which produced robust mechanical and cold hypersensitivity in the spared nerve (sural) innervation territory (lateral aspect) of the injured hind paw (Figure 4, B and C) (24,25).Two weeks after SNI, we applied light brush stimulation to the plantar hind paw (Figure 4D), and as predicted, we found increased Fos expression (using the immediate early gene Fos as a correlate for neuronal activity) in the ipsilateral superficial DH in Npy1r-expressing neurons (Figure 4E).Fos expression was principally expressed in the Grp/Npy1r subpopulation rather than the Npff/Npy1r or Cck/Npy1r subpopulations (Figure 4, E and F).These results suggest that in the context of peripheral nerve injury, mechanical stimulation predominately activates Y1-INs that coexpress Grp.
Inhibition of Npff/Npy1r-INs does not change neuropathic hypersensitivity.Previously, we demonstrated that chemogenetic inhibition of Y1-INs with designer receptors exclusively activated by designer drugs (DREADDs) abolished SNI-induced neuropathic hypersensitivity (24).Similarly, we sought to determine the functional contribution of the Npff/Npy1r, Grp/Npy1r, and Cck/Npy1r subpopulations to neuropathic hypersensitivity.First, we took advantage of the fact that virtually all Npff-expressing DH interneurons coexpress Npy1r (Figure 2H).This feature of NPFF-INs allowed us to intraspinally administer Cre-dependent inhibitory DREADDs into the left lumbar (targeting L3-L4) DH of our developed Npff Cre mouse line to inhibit the activity of Npff/Npy1r-INs (Figure 5A).As predicted, AAV-mCherry transfection expression with immunohistochemistry and FISH was detected ipsilateral to viral injection (left but not right DH) in superficial DH cells that coexpressed Npff and Npy1r (Figure 5B).We then intraperitoneally administered a 3 mg/kg dose of clozapine N-oxide (CNO, TOC-RIS); this dose is the lowest recommended dose to behave as a DREADD agonist in the absence of off-target effects (51) and is commonly utilized for spinal cord chemogenetics (13,24,52).Chemogenetic inhibition of Npff/Npy1r-INs did not change mechanical or cold responses before or after SNI (Figure 5, C-G).These findings indicate that spinal Npff/Npy1r-INs are not necessary for the behavioral manifestation of mechanical or cold neuropathic hypersensitivity.
The Y1 agonist [Leu 31 , Pro 34 ]-NPY eliminates nerve injury-induced mechanical and cold hypersensitivity in mice with conditional deletion of Cck but not Grp from Npy1r-INs.In contrast to NPFF-INs, many CCK-and GRP-INs do not coexpress Npy1r.As a result, we could not inhibit the Grp Cre or Cck Cre interneuron populations with a chemogenetic approach as we did with our Npff Cre mice because this could also modulate neurons that do not express Npy1r (and there is no currently available Npy1r Flp mouse line to allow a dual recombinase chemogenetic approach).Instead, we pharmacologically inhibited Y1-INs with an intrathecal Y1 agonist in conditional genetic knockout lines.Specifically, we crossed Npy1r loxP/loxP mice (53) with either Grp Cre (54) or Cck Cre (55) mice to selectively knock out Npy1r from Grp Cre or Cck Cre neurons, respectively (Figure 6, A-E).Next, we performed SNI to produce mechanical and cold hypersensitivity (Figure 6, F-I).Two weeks later, we intrathecally administered the Y1-selective agonist, [Leu 31 , Pro 34 ]-NPY, to inhibit spinal Y1-INs (24).[Leu 31 , Pro 34 ]-NPY reduced SNI-induced allodynia in both control Npy1r loxP/loxP and Npy1r loxP/loxP Cck Cre mice but not in Npy1r loxP/loxP Grp Cre mice (Figure 6, F-I).Similarly, intrathecal administration of [Leu 31 , Pro 34 ]-NPY reduced SNI-induced allodynia in Npy1r loxP/loxP mice crossed with Npff Cre mice (Supplemental Figure 2).Conditional genetic knockout of Npy1r was confirmed with FISH and quantified for all 3 mouse crosses (Supplemental Figure 3).These results indicate that NPY Y1 agonists inhibit behavioral signs of neuropathic pain by actions at spinal cord Npy1r-expressing interneurons that coexpress Grp but not Cck or Npff.

Discussion
In this study, we demonstrate that spinal Npy1r-expressing DH interneurons that coexpress Grp are evolutionarily conserved across rodent, nonhuman primate, and human and are necessary for the efficacy of spinally directed Y1 agonists to inhibit neuropathic pain.The Grp subpopulation of Npy1r-expressing DH INs represent an optimal and precise future pharmacotherapeutic target for the treatment of neuropathic pain.(25,26,36,46), we found that Y1-INs are almost entirely glutamatergic and segregate into 3 largely nonoverlapping excitatory subpopulations.These are demarcated by coexpression of Npy1r with Grp, Npff, or Cck, consistent with the 3 excitatory subpopulations (Glut2, Glut8, and Glut9) that Häring et al. identified using single-cell RNA sequencing (36).In that study, Cck-expressing neurons fell into 3 separate clusters: Glut1, Glut2, and Glut3.The laminar location of these Cck-expressing subpopulations varied with Glut2 neurons scattered in superficial laminae I-II (the same location we found our Cck/Npy1r-INs), Glut3 neurons forming a compact band in laminae IIi-III, and Glut1 Cck-expressing neurons (the largest population) restricted to the deep dorsal horn (laminae III-V) (36,56).Thus, our Cck/Npy1r-INs are likely Glut2 neurons with reference to the Häring et al. data set.In the single-cell results, Npff was found exclusively in the Glut9 population; thus, our Npff/Npy1r-INs likely correspond to the Glut9 cluster in the Häring et al. data set (36,38).In contrast, Grp expression was broadly distributed across the Glut5-12 populations in the Häring et al. data set.However, many of these GRP-INs (~30%) are in the Glut8 cluster (exhibiting Nmur2 and Reln expression but not Npff expression) (36,40).Therefore, by process of elimination (lack of effect in Cck and Npff subpopulations), the Grp/Npy1r-INs that mediate neuropathic pain and its inhibition by Y1 agonists likely correspond to the Glut8 cluster.
Converging pieces of evidence implicate Glut8 neurons (exhibiting Nmur2 and Reln expression but not Npff expression) as both necessary and sufficient for the manifestation of mechanical and thermal hypersensitivity.First, the neuromedin U receptor 2 (encoded by Nmur2) is coupled to Gα q/11 , and intrathecal administration of neuromedin U dose-dependently produces mechanical and heat hypersensitivity (57,58).Second, Häring et al. found immediate early gene expression in Glut8 neurons in response to both noxious heat and cold stimuli (36).Third, Reln-expressing DH neurons also exhibit Fos expression in response to

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JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554noxious thermal or mechanical stimulation (59).Fourth, recently uncovered ErbB4 + neurons that participate in spinal heat signaling are exclusively represented in a Nmur2-expressing excitatory neuron subpopulation (60).Last, SST-INs are necessary and sufficient for neuropathic pain (19,20), and Sst expression is also detected in Glut8 neurons (albeit also in other excitatory populations) (36).Thus, we believe that the Reln/Nmur2/Sst/Grp/Npy1r population in all these studies converges on the Glut8 population and that it is a specific subpopulation that is necessary for neuropathic pain.Therefore, future studies could further investigate the contribution to neuropathic pain of Npff-Glut8 neurons (Reln + , Nmur2 + ).Future experiments may perhaps synthesize an Nmur2 Cre mouse or use an intersectional approach that develops and utilizes a Npy1r Flp mouse crossed with a Grp Cre mouse to perform more advanced analyses on the Glut8 neuron subpopulation to better define its role in neuropathic pain.
Grp/Npy1r-expressing DH interneurons mediate the antiallodynic actions of spinally directed NPY Y1 agonists.Our results establish GRP-INs (specifically those that coexpress Npy1r) as a mediator of neuropathic allodynia.In contrast with our conclusions, GRP-INs were previously described to be exclusively involved in pruritis and not pain-like behavior (52,(61)(62)(63).However, previous Grp conclusions were made using a GENSAT BAC transgenic Grp Cre mouse line, which only labeled about 25% of DH GRP-INs (40,62) and prevented the functional interrogation of the entire GRP-IN population.By contrast, in this study we utilized a high-fidelity Grp Cre mouse line, which labels approximately 90% of the DH GRP-INs (54).Additionally, for the first time to our knowledge we probed the role of GRP-INs in a chronic pain model (SNI) rather than acute pain modalities (i.e.heat, von Frey, pinprick) (54,62).With these results, we conclude that GRP-INs are the target of intrathecal Y1 agonists to inhibit SNI-induced mechanical and cold hypersensitivity.
Mechanical allodynia is hypothesized to occur via a polysynaptic DH microcircuit that allows A-fibers to transmit innocuous mechanical input to "pain circuits" (15).Y1-INs and GRP-INs have both been

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JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554characterized as "transient central cells" (neurons in lamina II outer with a central morphology that discharge action potentials transiently during a depolarizing step; ref. (64) in this circuit (24,62,65).We theorize that in the context of nerve injury, GRP-specific Y1-IN transient central cells drive both mechanical allodynia and pathological itch (66-68) via activation of GRPR-INs (Figure 7).Indeed, intrathecal administration of NPY inhibits not only the behavioral signs of neuropathic pain but also chemical and mechanical itch (26,69,70).

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JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554Thus, our results support the idea that neuropathic pain and itch share a spinal circuitry that includes GRP/ Y1-INs.Accordingly, a pharmacotherapeutic approach to inhibit GRP/Y1-INs could potentially reduce both chronic neuropathic pain-induced hypersensitivity as well as neuropathic itch (26).
Net DH excitation/inhibition balance or a subpopulation-specific effect.In addition to our interpretation that intrathecal Y1 agonists act at GRP-INs to inhibit neuropathic pain, an alternative interpretation relates to the appropriate balance of excitation and inhibition (E/I) in the DH, which is critical for appropriate somatosensory processing (2).Peripheral nerve injury produces an enduring shift in the E/I balance of the DH toward an excitatory and pro-nociceptive state (13,(71)(72)(73)(74)(75)(76); consequently, inhibition of pain-facilitatory excitatory Y1-INs could restore E/I balance and dampen pathogenic hyperexcitation.In this scenario, it is the total number of glutamatergic pro-nociceptive Y1-INs that are inhibited that is critical for the reduction of neuropathic pain.Therefore, loss of Npyr in the Grp/Npy1r-INs, the largest subpopulation of Y1-INs (~60%) in the superficial DH (Figure 2), might prevent intrathecal NPY from being able to inhibit enough pro-nociceptive Y1-INs to reduce neuropathic hypersensitivity.While this alternative interpretation may be valid, there is evidence to the contrary.For example, inhibition of the larger and predominately excitatory calretinin DH interneuron population (~30% of all superficial dorsal horn neurons are calretinin-immunoreactive, ref. 77; as opposed to ~25% expressing Npy1r, Figure 1) did not reduce peripheral nerve injury-induced allodynia (14).Therefore, we believe that neuronal subpopulation specificity, rather than total neuronal number, underlies the loss of Y1 agonist-induced antiallodynia following conditional knockout of Npy1r in GRP-INs.
Evolutionary conservation of Y1-IN subpopulations.NPY binding sites were previously reported in the superficial laminae of the DH of mouse, rat, and monkey (29,34,(78)(79)(80)(81)(82).Here, using FISH, we expanded these results to demonstrate Y1-IN subpopulations are conserved across the rodent, rhesus macaque, and human (Figure 3).This evolutionary conservation supports their translational relevance.One caveat is that we evaluated human cervical spinal cord as opposed to lumbar spinal cord in macaque and mouse, and we cannot rule out variance in RNA expression between cervical and lumbar spinal cord.However, a single-nucleosome RNA-sequencing database has recently emerged for the adult human lumbar spinal cord (82), and our FISH results obtained in cervical tissue recapitulate many of the single-cell results.Interestingly, in contrast to the mouse, RNA sequencing showed that We posit that NPY Y1 agonists act by inhibiting a key neuron population implicated in the transduction of mechanical allodynia.Briefly, non-noxious mechanical stimuli activate Aß/Aδ myelinated afferents (shown in red) that project into the deeper laminae of the dorsal horn and synapse onto interneurons marked by the expression of CCK (purple) and PKCγ (yellow).Normally, feed-forward inhibition prevents the activation of these interneurons, and as a result light touch is perceived as nonpainful.For example, inhibitory NPY interneurons (light gray) may "gate" Npy1r/Grp-INs to prevent these neurons from being activated and driving pain-like behaviors.However, in the context of neuropathic pain, feed-forward inhibition is lost, and innocuous light touch inputs activate a theorized dorsally directed microcircuit to allow innocuous mechanical sensory information to be perceived as painful.In this theorized circuit, activated CCK and PKCγ interneurons excite transient central cells (theorized here as Npy1r/Grp-INs), which in turn synapse onto GRPR-INs (vertical cells), which then activate ascending projection neurons (PNs) that travel via the spinothalamic and spinoparabrachial tracts to be processed via higher order pain centers, such as the lateral parabrachial nucleus.Image is updated from our circuit diagrams previously published under CC BY license (24,26).

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JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554NPY1R is broadly expressed in human dorsal horn across all glutamatergic subpopulations (Ex-Dorsal 1-12) (Supplemental Figure 4).However, like the mouse, specific subpopulations coexpress CCK (most densely Ex-Dorsal 2 and 4) or GRP (most densely Ex-Dorsal 11-12) (Supplemental Figure 4).One stark contrast with the mouse and macaque is that NPFF expression was not detected in the human single-nucleosome RNA-sequencing database (Supplemental Figure 4) (82).However, the lack of NPFF expression result further supports the integrity of our cervical FISH results (Figure 3H) and reveals the sparse to nondetectable expression of NPFF in the adult human spinal cord DH.Importantly, the GRP/NPY1R-IN population, the subpopulation that we believe is fundamental to the manifestation of neuropathic pain, is conserved in the macaque and human spinal cord.
NPY Y1/GRP interneurons -a new therapeutic target?A rich 30-year history of preclinical research implicates NPY at the spinal cord as a potent inhibitor of acute and chronic pain (26), thereby prompting further investigation of Y1-selective therapeutics.Future investigations might test spinally directed NPY Y1 agonists in increasingly more translatable animal models (i.e., macaque, ref. 83) to perform pain behavioral testing as well as side effect profiling analyses.We are optimistic that Y1 agonism will safely and potently reduce the behavioral signs of neuropathic pain in larger mammalian species, and ultimately, humans with chronic pain.Further, our results suggest that GRP/NPY1R-INs are particularly well positioned in the spinal cord to modulate clinical neuropathic pain and thus represent a promising and refined therapeutic target for future drug development.In fact, the human RNA-sequencing data suggest that NPY1R expression is rather nonspecific across excitatory interneurons in humans, and a GRP/NPY1R-selective approach may therefore be optimal.
If GRP/NPY1R-INs are indeed a specific neuronal subpopulation within the human spinal cord that play a crucial role in pain transmission and perception, then the next challenge is to target them effectively and specifically with the delivery of therapeutic agents.A promising future approach is promoter-specific gene therapy (84).Promoters are DNA sequences that determine when and where a gene is expressed.Thus, viral vectors, nanoparticles, or CRISPR/Cas9 gene-editing techniques can be used to introduce GRP promoter-specific therapeutic genes into DH neurons, allowing functional modifications to reduce pain signals.The human single-nucleosome RNA sequencing suggests that NPY1R is broadly expressed across all excitatory neuronal subpopulations and therefore may not represent a precise therapeutic target.Rather, by using the promoter-specific gene therapy approach, we may specifically target the smaller GRP neuronal population and thereby minimize potential side effects of targeting all NPY1R neurons.For example, virally expressed genes could produce proteins that modulate pain signaling, reduce neuronal hyperexcitability, or enhance endogenous pain relief mechanisms.Promoter-specific gene therapy for pain is a promising avenue in the development of novel and effective treatments for chronic pain conditions.Long-term safety and efficacy will need to be thoroughly assessed through preclinical and clinical studies to determine its full potential and applicability in clinical settings.

Animals
Adult C57BL/6NCrl (Charles River, 027), Npy1r loxP/loxP (courtesy of Herbert Herzog, Garvan Institute, Sydney, New South Wales, Australia; ref. 53), Grp Cre (courtesy of Zhou-Feng Chen; Department of Anesthesiology, Washington University School of Medicine, St. Louis, Missouri, USA ref. 85), Cck Cre (Jackson Laboratory, 012706), and Npff Cre (see below; ref. 86) mice were group-housed; provided access to food and water ad libitum; and maintained on a 12-hour light/12-hour dark cycle (lights on at 7 am) in temperatureand humidity-controlled rooms.Male and female mice were used in all experiments.Although we were not powered to detect significant sex differences, no major/obvious trends in sex differences were observed; means from both sexes were pooled.
The Npff Cre knockin mouse line (86) was generated by Taconic Biosciences GmbH (Leverkusen, Germany), using a conventional embryonic stem cell targeting strategy and homologous recombination.Briefly, the sequence for the T2A peptide and the open reading frame of improved Cre recombinase (iCre) were inserted between the last amino acid and the translation termination codon in exon 3 of the NPFF gene.A positive selection marker (puromycin resistance) flanked by FRT sites was removed by crossing Npff Cre mice with germline Flpe mice.The presence of the T2A sequence should result in cotranslational cleavage between the NPFF and iCre proteins, resulting in coexpression of both proteins, under control of the Npff promoter.

Pharmacological testing
[Leu 31 , Pro 34 ]-NPY (human, rat) (TOCRIS catalog 1176) was diluted in 0.9% sterile sodium chloride (Medline catalog 63323-186-10) and stored at -20°C.Intrathecal injections of [Leu 31 , Pro 34 ]-NPY were performed in lightly restrained, unanesthetized mice.Briefly, a 30G needle attached to a Hamilton microsyringe was inserted between the L5/L6 vertebrae at the cauda equina, puncturing the dura (confirmed by presence of reflexive tail flick).We then injected a 5 μL volume of saline or [Leu 31 , Pro 34 ]-NPY (10 μg/5 μL).Animals were injected twice using a crossover design with 3 to 7 days of separation between the 2 injections.For example, animals receiving saline for the first injection received [Leu 31 , Pro 34 ]-NPY for the second, and animals receiving [Leu 31 , Pro 34 ]-NPY for the first injection received saline for the second.In all cases, group means of saline and [Leu 31 , Pro 34 ]-NPY did not differ on either injection day and so were combined for final analysis.
CNO (TOCRIS catalog 4936) was diluted in 0.9% sterile sodium chloride and stored at room temperature.Intraperitoneal injections of CNO (3 mg/kg) or saline were performed in lightly restrained, unanesthetized mice with a 27G permanently attached needle BD Tuberculin Syringe (catalog 305620).Animals were injected using a crossover design with at least 3 days of separation between saline and CNO injections.In all cases, group means of saline and CNO did not differ on either injection day and so were combined for final analysis.

Surgeries
SNI. SNI was performed as previously described (23,24).Briefly, mice were anesthetized with inhaled isoflurane (5% induction and 2% maintenance), and the left hind limb was shaved with trimmers and asepticized with 70% ethanol and a ChloraPrep swabstick (BD catalog 260100).A small incision was made in the skin of the hind left leg, and the underlying muscle was spread via blunt dissection to expose the underlying branches of the sciatic nerve.The peroneal and tibial nerves were then ligated with 6-0 silk sutures (Butler Schein Animal Health catalog NC0049524) and transected while carefully avoiding the sural nerve.The muscle tissue was then loosely sutured with 5-0 vicryl sutures (Med Vet International catalog 50-118-0847), and the skin was closed with 9 mm wound clips (Braintree Scientific catalog NC9281117).Topical triple antibiotic ointment (Neosporin Neomycin Sulfate/Bacitracin Zinc/Polymycin Ointment; Hanna Pharmaceutical Supply Co. catalog NC0100117) was applied to the wound.Wound clips were removed 7-10 days postsurgery, and behavioral experiments began 14 days after surgery.
Intraspinal AAV injections.Mice were anesthetized with inhaled isoflurane (5% induction and 2% maintenance), and the skin of the back was shaved with trimmers and asepticized with 70% ethanol and a ChloraPrep swabstick.A midline incision was carefully made to allow visualization of the underlying L1 vertebrae.The L1 vertebrae was then removed by laminectomy, exposing the L4 segment of the spinal cord.A glass microelectrode was inserted into 3 separate locations along the rostral caudal axis of the L4 segment: in the middle and near the boundary with L3 and L5.At each injection site, the glass microelectrode was lowered to a depth of 250 μm below the dura using a stereotaxic frame (David Kopf Instruments Model 940).A total of 333.3 nL of virus (AAV8-hSyn-DIO-mCherry, Addgene catalog 50459-AAV8, or AAV8-hSyn-DIO-hM4Di-mCherry, Addgene catalog 44362-AAV8) was slowly injected into each of the 3 spots (5 nL/s) using a Nanoject III (Drummond catalog 3-000-207) with a 3-minute wait time after completion of each injection to permit adequate infusion.The lassimus dorsi was sutured with 5-0 nylon sutures to protect the exposed spinal cord, and the overlying skin was closed with 9 mm wound clips (Braintree Scientific catalog NC9281117).Topical triple antibiotic ointment (Neosporin Neomycin Sulfate/Bacitracin Zinc/Polymycin Ointment; Hanna Pharmaceutical Supply Co. catalog NC0100117) was applied to the wound.Ethiqa XR buprenorphine extended-release injectable suspension (Fidelis Pharmaceuticals catalog FP-001 072117, 3.25 mg/kg, subcutaneous injection) was utilized as a postoperative analgesic.Behavioral experiments began 21 days after surgery.

Behavioral testing
Mechanical withdrawal threshold.Testing was performed as previously described (24,87,88).Mice were habituated to plexiglass chambers with opaque walls (15 × 4 × 4 cm) on a raised wire mesh platform for 30-60 minutes 1 day before and immediately prior to behavioral testing.Testing was performed using a calibrated set of logarithmically increasing von Frey monofilaments (Stoelting catalog 58011) that range in gram force from 0.007 to 6.0 g.Beginning with a 0.4 g filament, these were applied perpendicular to the lateral hind paw surface with sufficient force to cause a slight bending of the filament.A positive response was JCI Insight 2023;8 (22):e169554 https://doi.org/10.1172/jci.insight.169554denoted as a rapid withdrawal of the paw within 4 seconds of application and was followed by application of the next lower filament.A negative response was followed by application of the next higher filament.An up-down method (89) was used to calculate the 50% withdrawal threshold for each mouse.
Cold withdrawal duration.Immediately following von Frey testing, cold sensitivity testing was performed on mice in the same plexiglass chambers on a raised wire mesh platform.Using a syringe connected to PE-90 tubing, flared at the tip to a diameter of 3.5 mm, we applied a drop of acetone (VWR catalog BDH1101-1LP) to the lateral side of the hind plantar paw (sural nerve innervation territory).Surface tension maintained the volume of the drop to ~10 μL.The duration of time the animal lifted or shook its paw was recorded for 30 seconds.Three observations were averaged.
Hind paw brush for Fos.To produce Fos activation, a light-touch stimulation protocol was initiated on the ipsilateral hind paw of SNI mice 14 days after nerve injury.Mice were anesthetized with isoflurane (5% induction, 2% maintenance), and the lateral surface of the left hind paw was gently stroked in the longitudinal plane with a cotton-tipped applicator for 3 seconds every 5 seconds, for 5 minutes.After an additional 60-minute awake and freely moving wait time in their home cage, mice received an overdose injection of sodium pentobarbital (Fatal-Plus, Vortech catalog 9373, 0.25 mL, intraperitoneal injection) and were transcardially perfused.
Rhesus macaques.Two rhesus macaques (male, 4 years at time of death; and female, 4 years at time of death) were provided by David Lewis (University of Pittsburgh) and cared for under the guidelines of the NIH and as approved by the Institutional Animal Care and Use Committee of the University of Pittsburgh.No prior manipulations to the spinal cord were conducted in the macaques.At the time of tissue harvest, macaques were perfused with artificial cerebrospinal fluid, and L5-L7 spinal cord tissue was removed, placed in OCT, and immediately frozen on dry ice.Tissue sections were cut 20 μm thick using a cryostat and mounted onto Superfrost-charged slides, then stored at -80°C.After a 30-minute fixation step with cold 4% paraformaldehyde, the fresh-frozen FISH protocol for RNAscope Multiplex Fluorescent Detection Kit v2 Assay (Advanced Cell Diagnostics catalog 323100) was followed for hybridization to the marker probes described in Table 1.Signal amplification was carried out using TSA Fluorescein, Cyanine 3, and Cyanine 5 reagents (1:1500; Akoya Biosciences).All sections were costained for DAPI and coverslipped at the end of the assay.
Human donor spinal cord tissue.Two human cervical spinal cord tissues were obtained freshly frozen from the NeuroBioBank, NIH (project no.063772), and provided by Jill Glausier (University of Pittsburgh).All available evidence indicated that these individuals (male, 45 years at time of accidental death; female, 44 years at time of natural death) were not afflicted with any major psychiatric or neuropathological illnesses at the time of death.All procedures were approved by the Committee for the Oversight of Research and Clinical Training Involving Decedents at University of Pittsburgh, Pittsburgh, Pennsylvania.The fresh-frozen FISH protocol for RNAscope Fluorescent Multiplex Reagent Assay (Advanced Cell Diagnostics catalog 320850) was followed for hybridization to the marker probes described in Table 1.Briefly, 16 μm-thick, fresh-frozen human spinal cord sections were fixed in 4% paraformaldehyde, dehydrated, treated with protease for 15 minutes, and hybridized with geneand species-specific probes.

Immunohistochemistry
Immediately following the RNAscope V2 protocol, mouse spinal cord sections were washed 3 times in PBS and then pretreated with blocking solution (3% normal goat serum and 0.3% Triton X-100 in PBS) for 1 hour.Sections were then incubated overnight on a slow rocker at 4°C in blocking solution containing the primary antibody (1:2,000, Anti-mCherry; Invitrogen catalog M11217).The sections were washed 3 times in 1× PBS and then incubated in secondary antibody (1:1,000, Alexa Fluor 568 Goat anti-Rat; Invitrogen catalog A11077) for 60 minutes.Finally, sections were washed in 3 times in 1× PBS and then 2 times in 0.01 M phosphate buffer without saline before mounting the tissue to Fisherbrand Superfrost Plus microscope slides (Thermo Fisher Scientific catalog 12-550-15) and coverslipping with VECTASHIELD HardSet Antifade Mounting Medium with DAPI (VECTOR Laboratories catalog H-1500-10).

Microscopy and quantification
All images were captured on a Nikon Eclipse Ti2 microscope using a 20× or 40× objective and analyzed using NIS-Elements Advanced Research software v5.02 (Nikon).Cells with at least 3 puncta associated with a DAPI + nucleus were considered positive.In mouse, positive cells within the superficial 100 μm of the DH were quantified in 3-5 sections and averaged to yield 1 data point for each mouse.In macaque,s positive cells within the substantia gelatinosa (translucent area in the superficial DH) were quantified, and 1 spinal cord section represents 1 individual data point.Intense lipofuscin prevented quantification in the human spinal cord.

Masking procedures
Experimenter masking (blinding) was employed to promote research rigor.In all cases the experimenter was masked to drug treatments and transgenic mouse genotype.Intrathecal injections were performed by a laboratory colleague, thus providing complete anonymity of drug agent for each animal.In the chemogenetic experiments the experimenter was masked both at the time of surgery to virus (DREADD vs. control) and at the time of behavior to drug agent (CNO vs. saline).The code key was kept hidden in a notebook and not revealed until after the completion of each experiment.

Figure 7 .
Figure 7. Schematized model for NPY Y1 agonists to inhibit Grp/Npy1r-INs and dampen neuropathic pain, silencing a key component of the ascending circuit in the dorsal horn that mediates mechanical allodynia.In the context of nerve injury, aberrant hyperexcitation of Npy1r/Grp-INs may drive allodynia.Exogenous administration of NPY or Y1 agonist binding to the G i -coupled NPY Y1 receptor on Npy1r/Grp-INs results in cellular inhibition and the abolishment of peripheral nerve injury-induced mechanical allodynia.We posit that NPY Y1 agonists act by inhibiting a key neuron population implicated in the transduction of mechanical allodynia.Briefly, non-noxious mechanical stimuli activate Aß/Aδ myelinated afferents (shown in red) that project into the deeper laminae of the dorsal horn and synapse onto interneurons marked by the expression of CCK (purple) and PKCγ (yellow).Normally, feed-forward inhibition prevents the activation of these interneurons, and as a result light touch is perceived as nonpainful.For example, inhibitory NPY interneurons (light gray) may "gate" Npy1r/Grp-INs to prevent these neurons from being activated and driving pain-like behaviors.However, in the context of neuropathic pain, feed-forward inhibition is lost, and innocuous light touch inputs activate a theorized dorsally directed microcircuit to allow innocuous mechanical sensory information to be perceived as painful.In this theorized circuit, activated CCK and PKCγ interneurons excite transient central cells (theorized here as Npy1r/Grp-INs), which in turn synapse onto GRPR-INs (vertical cells), which then activate ascending projection neurons (PNs) that travel via the spinothalamic and spinoparabrachial tracts to be processed via higher order pain centers, such as the lateral parabrachial nucleus.Image is updated from our circuit diagrams previously published under CC BY license(24,26).