Piezo2 电压阻断调节机械痛敏感性。

IF 10.6 1区 医学 Q1 CLINICAL NEUROLOGY Brain Pub Date : 2024-10-03 DOI:10.1093/brain/awae227
Oscar Sánchez-Carranza, Sampurna Chakrabarti, Johannes Kühnemund, Fred Schwaller, Valérie Bégay, Jonathan Alexis García-Contreras, Lin Wang, Gary R Lewin
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We characterized the biophysical properties of three PIEZO2 ion channel mutations at an evolutionarily conserved arginine (R2756). Using genome engineering in mice we generated Piezo2R2756H/R2756H and Piezo2R2756K/R2756K knock-in mice to characterize the physiological consequences of altering PIEZO2 voltage sensitivity in vivo. We measured endogenous mechanosensitive currents in sensory neurons isolated from the dorsal root ganglia and characterized mechanoreceptor and nociceptor function using electrophysiology. Mice were also assessed behaviourally and morphologically. Mutations at the conserved Arginine (R2756) dramatically changed the biophysical properties of the channel relieving voltage block and lowering mechanical thresholds for channel activation. Piezo2R2756H/R2756H and Piezo2R2756K/R2756K knock-in mice that were homozygous for gain-of-function mutations were viable and were tested for sensory changes. 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引用次数: 0

摘要

PIEZO2 是一种三聚体机械门控离子通道,由背根神经节中的大多数感觉神经元表达。小鼠和人类的正常触觉也需要机械敏感的 PIEZO2 通道。我们之前的研究表明,PIEZO2 通道还受到膜电压的强烈调节。具体来说,只有在电压非常正的情况下,所有通道才能通过机械力打开。相反,大多数 PIEZO2 通道在正常负静息膜电位时会被阻断。然而,PIEZO2 通道的这种不寻常的生物物理特性的生理功能仍然未知。我们研究了三个 PIEZO2 离子通道在进化上保守的精氨酸(R2756)突变的生物物理特性。通过小鼠基因组工程,我们产生了 Piezo2R2756H/R2756H 和 Piezo2R2756K/R2756K 基因敲入小鼠,以鉴定改变体内 PIEZO2 电压敏感性的生理后果。我们测量了从背根神经节分离的感觉神经元中的内源性机械敏感电流,并利用电生理学鉴定了机械感受器和痛觉感受器的功能。还对小鼠进行了行为和形态学评估。保守的精氨酸(R2756)突变极大地改变了通道的生物物理特性,缓解了电压阻滞,降低了通道激活的机械阈值。同源功能增益突变的 Piezo2R2756H/R2756H 和 Piezo2R2756K/R2756K 基因敲入小鼠可以存活,并进行了感觉变化测试。令人惊讶的是,在 Piezo2 基因敲入小鼠中,痛觉感受器(检测有害机械刺激的神经元)中的机械敏感电流大幅敏化,但作为触觉基础的大多数机械感受器中的机械敏感电流仅受到相同突变的轻微影响。对支配无毛皮肤的感觉神经元进行的单单元电生理记录显示,在 Piezo2 基因敲入小鼠体内,支配 Meissner 肉团的快速适应机械感受器的机械阈值略有下降。与分离的感觉神经元中机械激活电流的测量结果一致,基本上所有的皮肤痛觉感受器、快速传导的Aδ-机械痛觉感受器和未髓鞘化的C纤维痛觉感受器对机械刺激都更加敏感,并且在Piezo2基因敲入小鼠体内确实获得了类似于超敏触觉感受器的受体特性。在 Piezo2 基因敲除小鼠的皮肤痛觉感受器中,机械刺激也诱导了更强的持续活动,即使在分离的痛觉神经元中,超敏感的 PIEZO2 通道也足以单独驱动持续活动。同样,Piezo2 基因敲入小鼠在行为上对有害机械刺激表现出极大的过敏性。我们的数据表明,人类慢性疼痛综合征中常见的持续活动和痛觉感受器敏感化现象,可以通过解除 PIEZO2 离子通道的电压阻滞来驱动。事实上,多种有害刺激引起的膜去极化可通过缓解 PIEZO2 通道的电压阻滞而使痛觉感受器敏感。
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Piezo2 voltage-block regulates mechanical pain sensitivity.

PIEZO2 is a trimeric mechanically-gated ion channel expressed by most sensory neurons in the dorsal root ganglia. Mechanosensitive PIEZO2 channels are also genetically required for normal touch sensation in both mice and humans. We previously showed that PIEZO2 channels are also strongly modulated by membrane voltage. Specifically, it is only at very positive voltages that all channels are available for opening by mechanical force. Conversely, most PIEZO2 channels are blocked at normal negative resting membrane potentials. The physiological function of this unusual biophysical property of PIEZO2 channels, however, remained unknown. We characterized the biophysical properties of three PIEZO2 ion channel mutations at an evolutionarily conserved arginine (R2756). Using genome engineering in mice we generated Piezo2R2756H/R2756H and Piezo2R2756K/R2756K knock-in mice to characterize the physiological consequences of altering PIEZO2 voltage sensitivity in vivo. We measured endogenous mechanosensitive currents in sensory neurons isolated from the dorsal root ganglia and characterized mechanoreceptor and nociceptor function using electrophysiology. Mice were also assessed behaviourally and morphologically. Mutations at the conserved Arginine (R2756) dramatically changed the biophysical properties of the channel relieving voltage block and lowering mechanical thresholds for channel activation. Piezo2R2756H/R2756H and Piezo2R2756K/R2756K knock-in mice that were homozygous for gain-of-function mutations were viable and were tested for sensory changes. Surprisingly, mechanosensitive currents in nociceptors, neurons that detect noxious mechanical stimuli, were substantially sensitized in Piezo2 knock-in mice, but mechanosensitive currents in most mechanoreceptors that underlie touch sensation were only mildly affected by the same mutations. Single-unit electrophysiological recordings from sensory neurons innervating the glabrous skin revealed that rapidly-adapting mechanoreceptors that innervate Meissner's corpuscles exhibited slightly decreased mechanical thresholds in Piezo2 knock-in mice. Consistent with measurements of mechanically activated currents in isolated sensory neurons essentially all cutaneous nociceptors, both fast conducting Aδ-mechanonociceptors and unmyelinated C-fibre nociceptors were substantially more sensitive to mechanical stimuli and indeed acquired receptor properties similar to ultrasensitive touch receptors in Piezo2 knock-in mice. Mechanical stimuli also induced enhanced ongoing activity in cutaneous nociceptors in Piezo2 knock-in mice and hyper-sensitive PIEZO2 channels were sufficient alone to drive ongoing activity, even in isolated nociceptive neurons. Consistently, Piezo2 knock-in mice showed substantial behavioural hypersensitivity to noxious mechanical stimuli. Our data indicate that ongoing activity and sensitization of nociceptors, phenomena commonly found in human chronic pain syndromes, can be driven by relieving the voltage-block of PIEZO2 ion channels. Indeed, membrane depolarization caused by multiple noxious stimuli may sensitize nociceptors by relieving voltage-block of PIEZO2 channels.

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来源期刊
Brain
Brain 医学-临床神经学
CiteScore
20.30
自引率
4.10%
发文量
458
审稿时长
3-6 weeks
期刊介绍: Brain, a journal focused on clinical neurology and translational neuroscience, has been publishing landmark papers since 1878. The journal aims to expand its scope by including studies that shed light on disease mechanisms and conducting innovative clinical trials for brain disorders. With a wide range of topics covered, the Editorial Board represents the international readership and diverse coverage of the journal. Accepted articles are promptly posted online, typically within a few weeks of acceptance. As of 2022, Brain holds an impressive impact factor of 14.5, according to the Journal Citation Reports.
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