Mid-Infrared Photons Alleviate Tinnitus by Activating the KCNQ2 Channel in the Auditory Cortex.

IF 3.5 2区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY ACS Chemical Biology Pub Date : 2024-09-18 DOI:10.34133/research.0479
Peng Liu,Xinmiao Xue,Chi Zhang,Hanwen Zhou,Zhiwei Ding,Li Wang,Yuke Jiang,Zhixin Zhang,Weidong Shen,Shiming Yang,Fangyuan Wang
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Abstract

Tinnitus is a phantom auditory sensation often accompanied by hearing loss, cognitive impairments, and psychological disturbances in various populations. Dysfunction of KCNQ2 and KCNQ3 channels-voltage-dependent potassium ion channels-in the cochlear nucleus can cause tinnitus. Despite the recognized significance of KCNQ2 and KCNQ3 channels in the auditory cortex, their precise relationship and implications in the pathogenesis of tinnitus remain areas of scientific inquiry. This study aimed to elucidate the pathological roles of KCNQ2 and KCNQ3 channels within the auditory cortex in tinnitus development and examine the therapeutic potential of mid-infrared photons for tinnitus treatment. We utilized a noise-induced tinnitus model combined with immunofluorescence, electrophysiological recording, and molecular dynamic simulation to investigate the morphological and physiological alterations after inducing tinnitus. Moreover, in vivo irradiation was administered to verify the treatment effects of infrared photons. Tinnitus was verified by deficits of the gap ratio with similar prepulse inhibition ratio and auditory brainstem response threshold. We observed an important enhancement in neuronal excitability in the auditory cortex using patch-clamp recordings, which correlated with KCNQ2 and KCNQ3 channel dysfunction. After irradiation with infrared photons, excitatory neuron firing was inhibited owing to increased KCNQ2 current resulting from structural alterations in the filter region. Meanwhile, deficits of the acoustic startle response in tinnitus animals were alleviated by infrared photons. Furthermore, infrared photons reversed the abnormal hyperexcitability of excitatory neurons in the tinnitus group. This study provided a novel method for modulating neuron excitability in the auditory cortex using KCNQ2 channels through a nonthermal effect. Infrared photons effectively mitigated tinnitus-related behaviors by suppressing abnormal neural excitability, potentially laying the groundwork for innovative therapeutic approaches for tinnitus treatment.
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中红外线光子通过激活听皮层中的 KCNQ2 通道缓解耳鸣。
耳鸣是一种幻听,在不同人群中常常伴有听力损失、认知障碍和心理障碍。耳蜗核中的 KCNQ2 和 KCNQ3 通道--电压依赖性钾离子通道--功能障碍可导致耳鸣。尽管 KCNQ2 和 KCNQ3 通道在听觉皮层中的重要性已得到公认,但它们在耳鸣发病机制中的确切关系和影响仍是科学探索的领域。本研究旨在阐明听皮层中的 KCNQ2 和 KCNQ3 通道在耳鸣发生中的病理作用,并研究中红外光子治疗耳鸣的潜力。我们利用噪声诱导耳鸣模型,结合免疫荧光、电生理记录和分子动力学模拟,研究了诱导耳鸣后的形态学和生理学改变。此外,还进行了体内照射,以验证红外光子的治疗效果。耳鸣是通过间隙比值的缺陷与相似的前脉冲抑制比值和听性脑干反应阈值来验证的。我们通过贴片钳记录观察到听皮层神经元兴奋性显著增强,这与 KCNQ2 和 KCNQ3 通道功能障碍有关。经红外光子照射后,兴奋性神经元的发射受到抑制,原因是滤波器区域的结构改变导致 KCNQ2 电流增加。同时,红外光子缓解了耳鸣动物的声学惊吓反应缺陷。此外,红外光子还逆转了耳鸣组兴奋性神经元的异常过度兴奋。这项研究提供了一种利用 KCNQ2 通道通过非热效应调节听皮层神经元兴奋性的新方法。红外光子通过抑制异常的神经兴奋性有效缓解了耳鸣相关行为,为耳鸣治疗的创新疗法奠定了基础。
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来源期刊
ACS Chemical Biology
ACS Chemical Biology 生物-生化与分子生物学
CiteScore
7.50
自引率
5.00%
发文量
353
审稿时长
3.3 months
期刊介绍: ACS Chemical Biology provides an international forum for the rapid communication of research that broadly embraces the interface between chemistry and biology. The journal also serves as a forum to facilitate the communication between biologists and chemists that will translate into new research opportunities and discoveries. Results will be published in which molecular reasoning has been used to probe questions through in vitro investigations, cell biological methods, or organismic studies. We welcome mechanistic studies on proteins, nucleic acids, sugars, lipids, and nonbiological polymers. The journal serves a large scientific community, exploring cellular function from both chemical and biological perspectives. It is understood that submitted work is based upon original results and has not been published previously.
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