Heat generates oxidized linoleic acid metabolites that activate TRPV1 and produce pain in rodents
Amol M. Patwardhan, … , Robert C. Murphy, Kenneth M. Hargreaves
Amol M. Patwardhan, … , Robert C. Murphy, Kenneth M. Hargreaves
Published April 26, 2010
Citation Information: J Clin Invest. 2010;120(5):1617-1626. https://doi.org/10.1172/JCI41678.
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Research Article

Heat generates oxidized linoleic acid metabolites that activate TRPV1 and produce pain in rodents

Abstract

The transient receptor potential vanilloid 1 (TRPV1) channel is the principal detector of noxious heat in the peripheral nervous system. TRPV1 is expressed in many nociceptors and is involved in heat-induced hyperalgesia and thermoregulation. The precise mechanism or mechanisms mediating the thermal sensitivity of TRPV1 are unknown. Here, we have shown that the oxidized linoleic acid metabolites 9- and 13-hydroxyoctadecadienoic acid (9- and 13-HODE) are formed in mouse and rat skin biopsies by exposure to noxious heat. 9- and 13-HODE and their metabolites, 9- and 13-oxoODE, activated TRPV1 and therefore constitute a family of endogenous TRPV1 agonists. Moreover, blocking these substances substantially decreased the heat sensitivity of TRPV1 in rats and mice and reduced nociception. Collectively, our results indicate that HODEs contribute to the heat sensitivity of TRPV1 in rodents. Because oxidized linoleic acid metabolites are released during cell injury, these findings suggest a mechanism for integrating the hyperalgesic and proinflammatory roles of TRPV1 and linoleic acid metabolites and may provide the foundation for investigating new classes of analgesic drugs.

Authors

Amol M. Patwardhan, Armen N. Akopian, Nikita B. Ruparel, Anibal Diogenes, Susan T. Weintraub, Charis Uhlson, Robert C. Murphy, Kenneth M. Hargreaves

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Figure 5

Inhibition of oxidized linoleic acid metabolites decreases heat sensitivity of TRPV1.

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Inhibition of oxidized linoleic acid metabolites decreases heat sensitiv...
(A) Effect of applying vehicle or NDGA (30 μM, 15 minutes) on whole-cell heat-evoked inward current (Iheat) in a cultured rat TG neuron. (B) Summary graph shows the effects of NDGA on Iheat in rat TG neurons (n = 19 for vehicle, 9 for NDGA; P = 0.0018). (C) The effect of pre- and cotreatment with NDGA (10 μM), indomethacin (INDO) (2 μM), and I-RTX (200 nM) on heat-evoked iCGRP release from cultured rat TG neurons (n = 8–16 wells/group; P = 0.02 for NDGA and 0.00001 for I-RTX). (D) Effect of an intracellular dialysis (for 5–10 minutes) of either vehicle or a combination of anti–9-HODE and anti–13-HODE antibodies (0.06 and 0.012 μg, respectively) on Iheat in cultured rat TG neurons. (E) Graph summarizing effects of dialysis with antibodies against 9- and 13-HODE on Iheat in cultured rat TG neurons (n = 15 for vehicle and 7 for each antibody mix group, P = 0.007; antibody dose refers to amount in a recording pipette). (F and G) Effect of ipl hind paw injection of vehicle, NDGA (F, n = 6/group; P = 0001), or a mixture of anti–9-HODE and anti–13-HODE antibodies (G, 25 μg each/paw, n = 6/group; P = 0.005) on paw withdrawal latencies to a beam of radiant heat in rats. Observers were blinded to treatment allocation. *P < 0.05; **P < 0.01; ***P < 0.001.