Sodium channels Nav1.7, Nav1.8 and pain; two distinct mechanisms for Nav1.7 null analgesia

Q2 Medicine

Neurobiology of Pain Pub Date : 2024-07-01 DOI:10.1016/j.ynpai.2024.100168

Federico Iseppon , Alexandros H. Kanellopoulos , Naxi Tian , Jun Zhou , Gozde Caan , Riccardo Chiozzi , Konstantinos Thalassinos , Cankut Çubuk , Myles J. Lewis , James J. Cox , Jing Zhao , Christopher G. Woods , John N. Wood

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Abstract

Genetic deletion and pharmacological inhibition are distinct approaches to unravelling pain mechanisms, identifying targets and developing new analgesics. Both approaches have been applied to the voltage-gated sodium channels Na_v1.7 and Na_v1.8. Genetic deletion of Na_v1.8 in mice leads to a loss of pain and antagonists are effective analgesics. The situation with Nav1.7 is more complex. Complete embryonic loss of Na_v1.7 in humans or in mouse sensory neurons leads to anosmia as well as profound analgesia as a result of diminished neurotransmitter release. This is mediated by enhanced endogenous opioid signaling in humans and mice. In contrast, anosmia is opioid-independent. Sensory neuron excitability and autonomic function appear to be normal.

Adult deletion of Na_v1.7 in sensory neurons also leads to analgesia, but through diminished sensory and autonomic neuron excitability. There is no opioid component of analgesia or anosmia as shown by a lack of effect of naloxone. Pharmacological inhibition of Na_v1.7 in mice and humans leads both to analgesia and dramatic side-effects on the autonomic nervous system with no therapeutic window. These data demonstrate that specific Na_v1.7 channel blockers will fail as analgesic drugs. The viability of embryonic null mutants suggests that there are compensatory changes to replace the lost Na_v1.7 channel. Here we show that sensory neuron sodium channels Na_v1.1, Na_v1.2 and β4 subunits detected by Mass Spectrometry are upregulated in Na_v1.7 embryonic null neurons and, together with other proteome changes, potentially compensate for the loss of Na_v1.7. Interestingly, many of the upregulated proteins are known to interact with Nav1.7.

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钠通道 Nav1.7、Nav1.8 与疼痛；Nav1.7 空镇痛的两种不同机制

基因缺失和药理抑制是揭示疼痛机制、确定靶点和开发新型镇痛药的不同方法。这两种方法都适用于电压门控钠通道 Nav1.7 和 Nav1.8。在小鼠中遗传性缺失 Nav1.8 会导致疼痛消失，而拮抗剂是有效的镇痛剂。Nav1.7 的情况则更为复杂。人类或小鼠感觉神经元胚胎期完全缺失 Nav1.7，会导致无嗅觉以及因神经递质释放减少而产生的深度镇痛。在人类和小鼠中，这是由内源性阿片信号增强介导的。相比之下，嗅觉缺失则与阿片无关。感觉神经元的兴奋性和自律神经功能似乎正常。成人感觉神经元中 Nav1.7 的缺失也会导致镇痛，但这是通过降低感觉神经元和自律神经元的兴奋性来实现的。纳洛酮（Naloxone）缺乏作用表明，镇痛或嗅觉失灵中没有阿片类成分。在小鼠和人体内对 Nav1.7 进行药理抑制既会导致镇痛，又会对自律神经系统产生剧烈的副作用，而且没有治疗窗口期。这些数据表明，特异性 Nav1.7 通道阻断剂不能作为镇痛药物。胚胎空突变体的存活率表明，存在代偿性变化以替代失去的 Nav1.7 通道。在这里，我们展示了通过质谱法检测到的感觉神经元钠通道 Nav1.1、Nav1.2 和 β4 亚基在 Nav1.7 胚胎无效神经元中上调，连同其他蛋白质组的变化，有可能补偿 Nav1.7 的损失。有趣的是，许多上调的蛋白质已知与 Nav1.7 相互作用。

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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