Single mechanically-gated cation channel currents can trigger action potentials in neocortical and hippocampal pyramidal neurons

Single mechanically-gated cation channel currents can trigger action potentials in neocortical and hippocampal pyramidal neurons

Abstract The mammalian brain is a mechanosensitive organ that responds to different mechanical forces ranging from intrinsic forces implicated in brain morphogenesis to extrinsic forces that can cause concussion and traumatic brain injury. However, little is known of the mechanosensors that transduc...

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Veröffentlicht in:Brain research 2015-05, Vol.1608, p.1-13
Hauptverfasser: Nikolaev, Yury A, Dosen, Peter J, Laver, Derek R, van Helden, Dirk F, Hamill, Owen P
Format: Artikel
Sprache:eng
Schlagworte:
Action potentials
Action Potentials - physiology
Animals
Animals, Newborn
Biomechanical Phenomena - physiology
Brain
Cation channels
Cesium - pharmacology
Chlorides - pharmacology
Female
Hippocampus - cytology
In Vitro Techniques
Ion Channel Gating - drug effects
Ion Channel Gating - physiology
Male
Mechanically-gated
Mice
Neocortex - cytology
Neurology
Patch-Clamp Techniques
Physical Stimulation
Pyramidal Cells - drug effects
Pyramidal Cells - physiology
Triggered
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Zusammenfassung:Abstract The mammalian brain is a mechanosensitive organ that responds to different mechanical forces ranging from intrinsic forces implicated in brain morphogenesis to extrinsic forces that can cause concussion and traumatic brain injury. However, little is known of the mechanosensors that transduce these forces. In this study we use cell-attached patch recording to measure single mechanically-gated (MG) channel currents and their affects on spike activity in identified neurons in neonatal mouse brain slices. We demonstrate that both neocortical and hippocampal pyramidal neurons express stretch-activated MG cation channels that are activated by suctions of ~25 mm Hg, have a single channel conductance for inward current of 50–70 pS and show weak selectivity for alkali metal cations (i.e., Na+
ISSN:0006-8993
1872-6240
DOI:10.1016/j.brainres.2015.02.051