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Na<sub>V</sub>1.9 current in muscle afferent neurons is enhanced by substances released during muscle activity.

Khrystyna Yu SukhanovaAnkeeta KoiralaKeith S Elmslie
Published in: Journal of neurophysiology (2022)
Skeletal muscle contraction triggers the exercise pressor reflex (EPR) to regulate the cardiovascular system response to exercise. During muscle contraction, substances are released that generate action potential activity in group III and IV afferents that mediate the EPR. Some of these substances increase afferent activity via G-protein-coupled receptor (GPCR) activation, but the mechanisms are incompletely understood. We were interested in determining if tetrodotoxin-resistant (TTX-R) voltage-dependent sodium channels (Na<sub>V</sub>) were involved and investigated the effect of a mixture of such compounds (bradykinin, prostaglandin, norepinephrine, and ATP, called muscle metabolites). Using whole cell patch-clamp electrophysiology, we show that the muscle metabolites significantly increased TTX-R Na<sub>V</sub> currents. The rise time of this enhancement averaged ∼2 min, which suggests the involvement of a diffusible second messenger pathway. The effect of muscle metabolites on the current-voltage relationship, channel activation and inactivation kinetics support Na<sub>V</sub>1.9 channels as the target for this enhancement. When applied individually at the concentration used in the mixture, only prostaglandin and bradykinin significantly enhanced Na<sub>V</sub> current, but the sum of these enhancements was &lt;1/3 that observed when the muscle metabolites were applied together. This suggests synergism between the activated GPCRs to enhance Na<sub>V</sub>1.9 current. When applied at a higher concentration, all four substances could enhance the current, which demonstrates that the GPCRs activated by each metabolite can enhance channel activity. The enhancement of Na<sub>V</sub>1.9 channel activity is a likely mechanism by which GPCR activation increases action potential activity in afferents generating the EPR.<b>NEW &amp; NOTEWORTHY</b> G-protein-coupled receptor (GPCR) activation increases action potential activity in muscle afferents to produce the exercise pressor reflex (EPR), but the mechanisms are incompletely understood. We provide evidence that Na<sub>V</sub>1.9 current is synergistically enhanced by application of a mixture of metabolites potentially released during muscle contraction. The enhancement of Na<sub>V</sub>1.9 current is likely one mechanism by which GPCR activation generates the EPR and the inappropriate activation of the EPR in patients with cardiovascular disease.
Keyphrases
  • skeletal muscle
  • cardiovascular disease
  • ms ms
  • insulin resistance
  • drinking water
  • high intensity
  • physical activity
  • type diabetes
  • spinal cord
  • human health
  • stem cells
  • bone marrow
  • body composition
  • protein kinase