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GPR160 de-orphanization reveals critical roles in neuropathic pain in rodents
Gina L.C. Yosten, Caron M. Harada, Chris Haddock, Luigino Antonio Giancotti, Grant R. Kolar, Ryan Patel, Chun Guo, Zhoumou Chen, Jinsong Zhang, Timothy M. Doyle, Anthony H. Dickenson, Willis K. Samson, Daniela Salvemini
Gina L.C. Yosten, Caron M. Harada, Chris Haddock, Luigino Antonio Giancotti, Grant R. Kolar, Ryan Patel, Chun Guo, Zhoumou Chen, Jinsong Zhang, Timothy M. Doyle, Anthony H. Dickenson, Willis K. Samson, Daniela Salvemini
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Concise Communication Neuroscience

GPR160 de-orphanization reveals critical roles in neuropathic pain in rodents

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Abstract

Treating neuropathic pain is challenging and novel non–opioid-based medicines are needed. Using unbiased receptomics, transcriptomic analyses, immunofluorescence, and in situ hybridization, we found that the expression of the orphan GPCR Gpr160 and GPR160 increased in the rodent dorsal horn of the spinal cord following traumatic nerve injury. Genetic and immunopharmacological approaches demonstrated that GPR160 inhibition in the spinal cord prevented and reversed neuropathic pain in male and female rodents without altering normal pain response. GPR160 inhibition in the spinal cord attenuated sensory processing in the thalamus, a key relay in the sensory discriminative pathways of pain. We also identified cocaine- and amphetamine-regulated transcript peptide (CARTp) as a GPR160 ligand. Inhibiting endogenous CARTp signaling in spinal cord attenuated neuropathic pain, whereas exogenous intrathecal CARTp evoked painful hypersensitivity through GPR160-dependent ERK and cAMP response element–binding protein (CREB). Our findings de-orphanize GPR160, identify it as a determinant of neuropathic pain and potential therapeutic target, and provide insights into its signaling pathways. CARTp is involved in many diseases including depression and reward and addiction; de-orphanization of GPR160 is a major step forward understanding the role of CARTp signaling in health and disease.

Authors

Gina L.C. Yosten, Caron M. Harada, Chris Haddock, Luigino Antonio Giancotti, Grant R. Kolar, Ryan Patel, Chun Guo, Zhoumou Chen, Jinsong Zhang, Timothy M. Doyle, Anthony H. Dickenson, Willis K. Samson, Daniela Salvemini

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Figure 1

Gpr160 and GPR160 upregulation in the spinal cord following CCI.

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Gpr160 and GPR160 upregulation in the spinal cord following CCI.
(A) Qu...
(A) Quantitative real-time PCR analysis of oGPCR mRNA expression in the dorsal and ventral horns of the spinal cord from rats with CCI on day 7 (n = 5). (B and C) RNA-Seq analyses of rat DH-SC ipsilateral to CCI on day 9. (B) Differential expression of 60 GPCRs between CCI and sham (n = 3/group). (C) Gpr160 in CCI and SHAM. TPMs, total reads per million. (D) Immunolabeled GPR160 (red) in lamina I/II spinal cord of rats with CCI. Ipsilateral (Ipsi), contralateral (Contra), GFAP (green), and NeuN (blue). (E–G) RNAScope analyses of the rat DH-SC on day 10 after CCI. (E) Quantitation of total Gpr160. (F and G) Association (white arrows; F) of Gpr160 (magenta) and Aif1 (microglia; yellow) increased ipsilateral to CCI (G). Nuclei were stained with DAPI (cyan). Scale bars: 100 μm (D) or 10 μm (F). Data are expressed as (A) median, interquartile range, and minimum/maximum values or (E and G) mean ± SD. (A–C, E, and G) Data analyzed by 2-tailed Student’s t test; (B and C) adjusted by Benjamini-Hochberg false discovery rate. *P < 0.05 versus Contra and #P < 0.05 and q < 0.05 versus sham.

Copyright © 2026 American Society for Clinical Investigation
ISSN: 0021-9738 (print), 1558-8238 (online)

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