Peripherally targeted analgesia via AAV-mediated sensory neuron–specific inhibition of multiple pronociceptive sodium channels
Seung Min Shin, … , Quinn H. Hogan, Hongwei Yu
Seung Min Shin, … , Quinn H. Hogan, Hongwei Yu
Published May 9, 2024
Citation Information: J Clin Invest. 2024;134(13):e170813. https://doi.org/10.1172/JCI170813.
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Research Article Neuroscience

Peripherally targeted analgesia via AAV-mediated sensory neuron–specific inhibition of multiple pronociceptive sodium channels

Abstract

This study reports that targeting intrinsically disordered regions of the voltage-gated sodium channel 1.7 (NaV1.7) protein facilitates discovery of sodium channel inhibitory peptide aptamers (NaViPA) for adeno-associated virus–mediated (AAV-mediated), sensory neuron–specific analgesia. A multipronged inhibition of INa1.7, INa1.6, INa1.3, and INa1.1 — but not INa1.5 and INa1.8 — was found for a prototype and named NaViPA1, which was derived from the NaV1.7 intracellular loop 1, and is conserved among the TTXs NaV subtypes. NaViPA1 expression in primary sensory neurons (PSNs) of dorsal root ganglia (DRG) produced significant inhibition of TTXs INa but not TTXr INa. DRG injection of AAV6-encoded NaViPA1 significantly attenuated evoked and spontaneous pain behaviors in both male and female rats with neuropathic pain induced by tibial nerve injury (TNI). Whole-cell current clamp of the PSNs showed that NaViPA1 expression normalized PSN excitability in TNI rats, suggesting that NaViPA1 attenuated pain by reversal of injury-induced neuronal hypersensitivity. IHC revealed efficient NaViPA1 expression restricted in PSNs and their central and peripheral terminals, indicating PSN-restricted AAV biodistribution. Inhibition of sodium channels by NaViPA1 was replicated in the human iPSC-derived sensory neurons. These results summate that NaViPA1 is a promising analgesic lead that, combined with AAV-mediated PSN-specific block of multiple TTXs NaVs, has potential as a peripheral nerve–restricted analgesic therapeutic.

Authors

Seung Min Shin, Brandon Itson-Zoske, Fan Fan, Yucheng Xiao, Chensheng Qiu, Theodore R. Cummins, Quinn H. Hogan, Hongwei Yu

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Figure 2

Confirmation of INa1.7 inhibition by 1.7iPA1, 4, and 6 and gating kinetics.

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Confirmation of INa1.7 inhibition by 1.7iPA1, 4, and 6 and gating kineti...
(A) Representative traces of INa1.7 by whole-cell patch-clamp recording from naive (transfection without plasmid), GFP, 1.7iPA3 (NP), 1.7iPA1, 1.7iPA4, and 1.7iPA6-transfected HEK1.7 cells. Inserts: recording protocol and current/time scales. (B) Summary of the confirmation tests of candidate iPAs expression in HEK1.7 cells (C) in comparison with corresponding mean peak current density-voltage (I/V) relationship from different constructs, as indicated and quantitative analysis of averaged peak INa1.7 density; **P < 0.01, ***P < 0.001, 1-way ANOVA and Tukey’s post hoc. (D)No effects of expression of GFPiPA1, GFPiPA4, and GFPiPA6 were observed on steady-state activation (inset: V1/2 activation) and (E) fast inactivation (inset: V1/2 inactivation), compared with naive and GFP or NP-transfected HEK1.7 cells. (F) NaViPA1 is highly conserved in rat, mouse, and human. Black and yellow asterisks at the bottom denote positively and negatively charged aa; the red and blue asterisks on the top denote known lysine acetylation and serine phosphorylation sites, and IDR scores and percent of positively (+) and negatively (–) charged aa were shown at the right sides of the alignment.