The impact of HCN4 channels on CNS brain networks as a new target in pain development.

Maximilian Häfele, Silke Kreitz, Andreas Ludwig, Andreas Hess, Isabel Wank
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Abstract

While it is well established that the isoform 2 of the hyperpolarization-activated cyclic nucleotide-gated cation channel (HCN2) plays an important role in the development and maintenance of pain, the role of the closely related HCN4 isoform in the processing of nociceptive signals is not known. HCN4 channels are highly expressed in the thalamus, a region important for stimulus transmission and information processing. We used a brain-specific HCN4-knockout mouse line (HCN4-KO) to explore the role of HCN4 channels in acute nociceptive processing using several behavioral tests as well as a multimodal magnetic resonance imaging (MRI) approach. Functional MRI (fMRI) brain responses were measured during acute peripheral thermal stimulation complemented by resting state (RS) before and after stimulation. The data were analyzed by conventional and graph-theoretical approaches. Finally, high-resolution anatomical brain data were acquired. HCN4-KO animals showed a central thermal, but not a mechanical hypersensitivity in behavioral experiments. The open field analysis showed no significant differences in motor readouts between HCN4-KO and controls but uncovered increased anxiety in the HCN4-KO mice. Thermal stimulus-driven fMRI (s-fMRI) data revealed increased response volumes and response amplitudes for HCN4-KO, most pronounced at lower stimulation temperatures in the subcortical input, the amygdala as well as in limbic/hippocampal regions, and in the cerebellum. These findings could be cross-validated by graph-theoretical analyses. Assessment of short-term RS before and after thermal stimulation revealed that stimulation-related modulations of the functional connectivity only occurred in control animals. This was consistent with the finding that the hippocampus was found to be smaller in HCN4-KO. In summary, the deletion of HCN4 channels impacts on processing of acute nociception, which is remarkably manifested as a thermal hypersensitive phenotype. This was mediated by the key regions hypothalamus, somatosensory cortex, cerebellum and the amygdala. As consequence, HCN4-KO mice were more anxious, and their brain-wide RS functional connectivity could not be modulated by thermal nociceptive stimulation.

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HCN4通道作为疼痛发展的新靶点对中枢神经系统脑网络的影响。
众所周知,超极化激活的环核苷酸门控阳离子通道(HCN2)的异构体2在疼痛的发生和维持中起着重要作用,但密切相关的HCN4异构体在伤害性信号加工中的作用尚不清楚。HCN4通道在丘脑中高度表达,丘脑是刺激传递和信息处理的重要区域。我们使用脑特异性HCN4敲除小鼠品系(HCN4- ko),通过几种行为测试和多模态磁共振成像(MRI)方法来探索HCN4通道在急性伤害性加工中的作用。在急性外周热刺激期间测量脑功能磁共振成像(fMRI)反应,并辅以刺激前后的静息状态(RS)。采用常规方法和图理论方法对数据进行分析。最后,获得高分辨率脑解剖数据。在行为实验中,HCN4-KO动物表现出中枢热反应,但未表现出机械超敏反应。开放场分析显示,HCN4-KO和对照组之间的运动读数没有显著差异,但发现HCN4-KO小鼠的焦虑增加。热刺激驱动的功能磁共振成像(s-fMRI)数据显示,HCN4-KO的反应量和反应幅度增加,在较低的刺激温度下,皮层下输入、杏仁核、边缘/海马区和小脑的反应量和反应幅度增加最为明显。这些发现可以通过图理论分析进行交叉验证。热刺激前后的短期RS评估显示,刺激相关的功能连接调节仅发生在对照动物中。这与HCN4-KO的海马体较小的发现是一致的。综上所述,HCN4通道的缺失影响了急性伤害感觉的加工,其显著表现为热超敏表型。这是由下丘脑、体感皮层、小脑和杏仁核等关键区域介导的。结果,HCN4-KO小鼠更加焦虑,并且它们的全脑RS功能连通性不能被热伤害性刺激调节。
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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