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多沙普仑对本体感觉神经元的影响:无脊椎动物模型

The Effect of Doxapram on Proprioceptive Neurons: Invertebrate Model.

作者信息

Ison Bethany J, Abul-Khoudoud Maya O, Ahmed Sufia, Alhamdani Abraham W, Ashley Clair, Bidros Patrick C, Bledsoe Constance O, Bolton Kayli E, Capili Jerone G, Henning Jamie N, Moon Madison, Phe Panhavuth, Stonecipher Samuel B, Tanner Hannah N, Turner Logan T, Taylor Isabelle N, Wagers Mikaela L, West Aaron K, Cooper Robin L

机构信息

Department of Biology, University of Kentucky, Lexington, KY 40506, USA.

出版信息

NeuroSci. 2022 Oct 23;3(4):566-588. doi: 10.3390/neurosci3040041. eCollection 2022 Dec.

DOI:10.3390/neurosci3040041
PMID:39483770
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11523696/
Abstract

The resting membrane potential enables neurons to rapidly initiate and conduct electrical signals. K2p channels are key in maintaining this membrane potential and electrical excitability. They direct the resting membrane potential toward the K equilibrium potential. Doxapram is a known blocker for a subset of K2p channels that are pH sensitive. We assessed the effects of 0.1 and 5 mM doxapram on the neural activity within the propodite-dactylopodite (PD) proprioceptive sensory organ in the walking legs of blue crabs (). Results indicate that 0.1 mM doxapram enhances excitation, while the higher concentration 5 mM may over-excite the neurons and promote a sustained absolute refractory period until the compound is removed. The effect of 5 mM doxapram mimics the effect of 40 mM K exposure. Verapamil, another known K2p channel blocker as well as an L-type Ca channel blocker, reduces neural activity at both 0.1 and 5 mM. Verapamil may block stretch activated channels in sensory endings, in addition to reducing the amplitude of the compound action potential with whole nerve preparations. These findings are notable as they demonstrate that doxapram has acute effects on neurons of crustaceans, suggesting a targeted K2p channel. The actions of verapamil are complex due to the potential of affecting multiple ion channels in this preparation. Crustacean neurons can aid in understanding the mechanisms of action of various pharmacological agents as more information is gained.

摘要

静息膜电位使神经元能够快速启动和传导电信号。K2p通道在维持这种膜电位和电兴奋性方面起着关键作用。它们将静息膜电位导向钾离子平衡电位。多沙普仑是一种已知的对一部分pH敏感的K2p通道的阻滞剂。我们评估了0.1 mM和5 mM多沙普仑对青蟹步足中掌节-指节(PD)本体感觉感觉器官内神经活动的影响。结果表明,0.1 mM多沙普仑增强兴奋作用,而较高浓度的5 mM可能会使神经元过度兴奋,并导致持续的绝对不应期,直到该化合物被清除。5 mM多沙普仑的作用类似于40 mM钾暴露的作用。维拉帕米是另一种已知的K2p通道阻滞剂以及L型钙通道阻滞剂,在0.1 mM和5 mM时均会降低神经活动。除了降低全神经标本复合动作电位的幅度外,维拉帕米还可能阻断感觉末梢的牵张激活通道。这些发现值得注意,因为它们表明多沙普仑对甲壳类动物的神经元有急性作用,提示存在靶向的K2p通道。由于在该标本中可能影响多个离子通道,维拉帕米的作用较为复杂。随着获得更多信息,甲壳类动物神经元有助于理解各种药理剂的作用机制。

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