Effects of cold temperatures on the excitability of rat trigeminal ganglion neurons that are not for cold sensing

Aside from a small population of primary afferent neurons for sensing cold, which generate sensations of innocuous and noxious cold, it is generally believed that cold temperatures suppress the excitability of primary afferent neurons not responsible for cold sensing. These not‐for‐cold‐sensing neur...

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Published in:Journal of neurochemistry 2017-05, Vol.141 (4), p.532-543
Main Authors: Kanda, Hirosato, Gu, Jianguo G.
Format: Article
Language:English
Subjects:
Action Potentials - physiology
Animals
Carbamates - pharmacology
Cell Membrane - physiology
cold
Cold Temperature
In Vitro Techniques
KCNQ channels
Membrane Transport Modulators - pharmacology
M‐currents
Neurons - drug effects
Neurons - physiology
Nociceptors - drug effects
Nociceptors - physiology
pain
Patch-Clamp Techniques
Phenylenediamines - pharmacology
Potassium Channels - drug effects
Potassium Channels - genetics
Potassium Channels - physiology
Rats
Rats, Sprague-Dawley
retigabine
Sensory Receptor Cells
Thermosensing - drug effects
Trigeminal Ganglion - cytology
Trigeminal Ganglion - drug effects
Trigeminal Ganglion - physiology
trigeminal ganglion neurons
TRPM Cation Channels - genetics
TRPM Cation Channels - physiology
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description Aside from a small population of primary afferent neurons for sensing cold, which generate sensations of innocuous and noxious cold, it is generally believed that cold temperatures suppress the excitability of primary afferent neurons not responsible for cold sensing. These not‐for‐cold‐sensing neurons include the majority of non‐nociceptive and nociceptive afferent neurons. In this study we have found that the not‐for‐cold‐sensing neurons of rat trigeminal ganglia (TG) change their excitability in several ways at cooling temperatures. In nearly 70% of not‐for‐cold‐sensing TG neurons, a cooling temperature of 15°C increases their membrane excitability. We regard these neurons as cold‐active neurons. For the remaining 30% of not‐for‐cold‐sensing TG neurons, the cooling temperature of 15°C either has no effect (cold‐ineffective neurons) or suppress their membrane excitability (cold‐suppressive neurons). For cold‐active neurons, the cold temperature of 15°C increases their excitability as is evidenced by increases in action potential (AP) firing numbers and/or the reduction in AP rheobase when these neurons are depolarized electrically. The cold temperature of 15°C significantly inhibits M‐currents and increases membrane input resistance of cold‐active neurons. Retigabine, an M‐current activator, abolishes the effect of cold temperatures on AP firing, but not the effect of cold temperature on AP rheobase levels. The inhibition of M‐currents and the increases of membrane input resistance are likely two mechanisms by which cooling temperatures increase the excitability of not‐for‐cold‐sensing TG neurons. This article is part of the special article series “Pain”. It is generally thought that cold temperatures suppress the excitability of primary afferent neurons that are not for the perception of cold. Here, we show that cooling temperatures increase excitability of many nociceptive‐like trigeminal ganglion neurons that are not for the perception of cold. We demonstrate that inhibition of M‐currents and increase in membrane input resistance by cooling temperatures are two mechanisms by which cooling temperatures enhance the excitability of these sensory neurons. This article is part of the special article series “Pain”.
doi_str_mv 10.1111/jnc.13511
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The cold temperature of 15°C significantly inhibits M‐currents and increases membrane input resistance of cold‐active neurons. Retigabine, an M‐current activator, abolishes the effect of cold temperatures on AP firing, but not the effect of cold temperature on AP rheobase levels. The inhibition of M‐currents and the increases of membrane input resistance are likely two mechanisms by which cooling temperatures increase the excitability of not‐for‐cold‐sensing TG neurons. This article is part of the special article series “Pain”. It is generally thought that cold temperatures suppress the excitability of primary afferent neurons that are not for the perception of cold. Here, we show that cooling temperatures increase excitability of many nociceptive‐like trigeminal ganglion neurons that are not for the perception of cold. 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The cold temperature of 15°C significantly inhibits M‐currents and increases membrane input resistance of cold‐active neurons. Retigabine, an M‐current activator, abolishes the effect of cold temperatures on AP firing, but not the effect of cold temperature on AP rheobase levels. The inhibition of M‐currents and the increases of membrane input resistance are likely two mechanisms by which cooling temperatures increase the excitability of not‐for‐cold‐sensing TG neurons. This article is part of the special article series “Pain”. It is generally thought that cold temperatures suppress the excitability of primary afferent neurons that are not for the perception of cold. Here, we show that cooling temperatures increase excitability of many nociceptive‐like trigeminal ganglion neurons that are not for the perception of cold. We demonstrate that inhibition of M‐currents and increase in membrane input resistance by cooling temperatures are two mechanisms by which cooling temperatures enhance the excitability of these sensory neurons. 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The cold temperature of 15°C significantly inhibits M‐currents and increases membrane input resistance of cold‐active neurons. Retigabine, an M‐current activator, abolishes the effect of cold temperatures on AP firing, but not the effect of cold temperature on AP rheobase levels. The inhibition of M‐currents and the increases of membrane input resistance are likely two mechanisms by which cooling temperatures increase the excitability of not‐for‐cold‐sensing TG neurons. This article is part of the special article series “Pain”. It is generally thought that cold temperatures suppress the excitability of primary afferent neurons that are not for the perception of cold. Here, we show that cooling temperatures increase excitability of many nociceptive‐like trigeminal ganglion neurons that are not for the perception of cold. 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ispartof Journal of neurochemistry, 2017-05, Vol.141 (4), p.532-543
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source Wiley:Jisc Collections:Wiley Read and Publish Open Access 2024-2025 (reading list); Free Full-Text Journals in Chemistry
subjects Action Potentials - physiology
Animals
Carbamates - pharmacology
Cell Membrane - physiology
cold
Cold Temperature
In Vitro Techniques
KCNQ channels
Membrane Transport Modulators - pharmacology
M‐currents
Neurons - drug effects
Neurons - physiology
Nociceptors - drug effects
Nociceptors - physiology
pain
Patch-Clamp Techniques
Phenylenediamines - pharmacology
Potassium Channels - drug effects
Potassium Channels - genetics
Potassium Channels - physiology
Rats
Rats, Sprague-Dawley
retigabine
Sensory Receptor Cells
Thermosensing - drug effects
Trigeminal Ganglion - cytology
Trigeminal Ganglion - drug effects
Trigeminal Ganglion - physiology
trigeminal ganglion neurons
TRPM Cation Channels - genetics
TRPM Cation Channels - physiology
title Effects of cold temperatures on the excitability of rat trigeminal ganglion neurons that are not for cold sensing
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