Neuropilin-1 inhibition suppresses nerve growth factor signaling and nociception in pain models
Chloe J. Peach, … , Rajesh Khanna, Nigel W. Bunnett
Chloe J. Peach, … , Rajesh Khanna, Nigel W. Bunnett
Published November 26, 2024
Citation Information: J Clin Invest. 2025;135(4):e183873. https://doi.org/10.1172/JCI183873.
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Research Article Cell biology Neuroscience

Neuropilin-1 inhibition suppresses nerve growth factor signaling and nociception in pain models

Abstract

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.

Authors

Chloe J. Peach, Raquel Tonello, Elisa Damo, Kimberly Gomez, Aida Calderon-Rivera, Renato Bruni, Harsh Bansia, Laura Maile, Ana-Maria Manu, Hyunggu Hahn, Alex R.B. Thomsen, Brian L. Schmidt, Steve Davidson, Amedee des Georges, Rajesh Khanna, Nigel W. Bunnett

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Figure 7

TrkA and NRP1 form a heteromeric complex.

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TrkA and NRP1 form a heteromeric complex. (A) HEK293T or CAD cells expre...
(A) HEK293T or CAD cells expressing SnapTag-TrkA and HaloTag-NRP1 simultaneously labeled with membrane-impermeant substrate (SNAPTag-Alexa Fluor 488, HaloTag-Alexa Fluor 660). Representative images from n = 5 independent experiments. (B and C) BRET assays to monitor proximity between NanoLuc-NRP1 or NanoLuc-p75NTR and increasing SnapTag-TrkA DNA. Negative control, NanoLuc-TrkA, and SnapTag-CALCRL. Representative replicate (C) plotting BRET against RFUs. (DG) Cell-surface TrkA in HEK293T imaged in the absence or presence of NRP1 (E). (F and G) Quantified fluorescence without receptor (–), SnapTag-TrkA alone, or SnapTag-TrkA cotransfected with NRP1 in HEK293T (F) or CAD (G) cells. (HJ) BRET between TrkA tagged with Renilla luciferase (Rluc8) and RGFP tagged markers of the plasma membrane (PM, RGFP-CAAX), early endosome (EE, tdRGFP-Rab5a), recycling endosomes (RE, tdRGFP-Rab4a), or the cis-Golgi apparatus (tdRGFP-Giantin). HEK293T cells (I) or CAD cells (J) were transfected with TrkA-Rluc8 in the absence (–) or presence (+) of NRP1. BRET was normalized relative to TrkA-Rluc8 alone (100%). Scale bars: 20 μm. Data from 5–6 independent experiments with triplicate wells. Data are represented as mean ± SEM. **P < 0.01; ***P < 0.001; ****P < 0.0001. (F and G) Paired t test. (I and J) One-way ANOVA with Šídák’s multiple comparisons.