Inhibitory modulation of action potentials in crayfish motor axons by fluoxetine.

IF 1.6 4区 医学 Q4 NEUROSCIENCES
Synapse Pub Date : 2024-07-01 DOI:10.1002/syn.22304
Selene Wang, Si Seng Lam, Anisah Aguilar, Stephanie Anakwe, Katherine Barahona, Hani Haider, Olivia Hunyadi, Kaahini Jain, Derek Kolodziejski, Anindita Lal, Man Li, Frank MacKenzie, John Miller, Oliviero Nardin, Emily Nguyen, Jaii Pappu, Melissa Rodriguez, Jen-Wei Lin
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引用次数: 0

Abstract

The goal of this report is to explore how K2P channels modulate axonal excitability by using the crayfish ventral superficial flexor preparation. This preparation allows for simultaneous recording of motor nerve extracellular action potentials (eAP) and intracellular excitatory junctional potential (EJP) from a muscle fiber. Previous pharmacological studies have demonstrated the presence of K2P-like channels in crayfish. Fluoxetine (50 µM) was used to block K2P channels in this study. The blocker caused a gradual decline, and eventually complete block, of motor axon action potentials. At an intermediate stage of the block, when the peak-to-peak amplitude of eAP decreased to ∼60%-80% of the control value, the amplitude of the initial positive component of eAP declined at a faster rate than that of the negative peak representing sodium influx. Furthermore, the second positive peak following this sodium influx, which corresponds to the after-hyperpolarizing phase of intracellularly recorded action potentials (iAP), became larger during the intermediate stage of eAP block. Finally, EJP recorded simultaneously with eAP showed no change in amplitude, but did show a significant increase in synaptic delay. These changes in eAP shape and EJP delay are interpreted as the consequence of depolarized resting membrane potential after K2P channel block. In addition to providing insights to possible functions of K2P channels in unmyelinated axons, results presented here also serve as an example of how changes in eAP shape contain information that can be used to infer alterations in intracellular events. This type of eAP-iAP cross-inference is valuable for gaining mechanistic insights here and may also be applicable to other model systems.

氟西汀对小龙虾运动轴突动作电位的抑制性调节。
本报告旨在利用小龙虾腹侧浅屈肌制备方法,探讨 K2P 通道如何调节轴突兴奋性。这种制备方法可同时记录来自肌纤维的运动神经胞外动作电位(eAP)和胞内兴奋交界电位(EJP)。之前的药理学研究已经证明了小龙虾体内存在 K2P 样通道。本研究使用氟西汀(50 µM)阻断 K2P 通道。阻断剂导致运动轴突动作电位逐渐下降,最终完全阻断。在阻滞的中间阶段,当 eAP 的峰-峰振幅下降到对照值的∼60%-80% 时,eAP 初始正分量的振幅下降速度快于代表钠流入的负峰值。此外,钠流入后的第二个正峰值(对应于细胞内记录的动作电位(iAP)的超极化后阶段)在 eAP 阻滞的中间阶段变得更大。最后,与 eAP 同时记录的 EJP 在振幅上没有变化,但在突触延迟上有显著增加。eAP 形状和 EJP 延迟的这些变化被解释为 K2P 通道阻滞后静息膜电位去极化的结果。除了深入了解 K2P 通道在无髓鞘轴突中可能发挥的功能外,本文介绍的结果还可作为一个实例,说明 eAP 形状的变化所包含的信息可用于推断细胞内事件的改变。这种 eAP-iAP 交叉推论对于深入了解这里的机理很有价值,也可能适用于其他模型系统。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Synapse
Synapse 医学-神经科学
CiteScore
3.80
自引率
0.00%
发文量
38
审稿时长
4-8 weeks
期刊介绍: SYNAPSE publishes articles concerned with all aspects of synaptic structure and function. This includes neurotransmitters, neuropeptides, neuromodulators, receptors, gap junctions, metabolism, plasticity, circuitry, mathematical modeling, ion channels, patch recording, single unit recording, development, behavior, pathology, toxicology, etc.
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