Inhibition mediated by group III mGluRs regulates habenula activity and defensive behaviors

Anna Maria Ostenrath, Nicholas Faturos, Yagnur Isik Ciftci Cobanoglu, Bram Serneels, Inyoung Jeong, Anja Enz, Francisca Hinrichsen, Aytac Kadir Mutlu, Ricarda Bardenhewer, Suresh Kumar Jetti, Stephan C. F. Neuhauss, Nathalie Jurisch-Yaksi, Emre Yaksi
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Abstract

Inhibition contributes to various brain computations from sensory motor transformations to cognitive operations. While most studies on inhibition focus on GABA, the main excitatory neurotransmitter of the brain, glutamate, can also elicit inhibition via metabotropic glutamate receptors (mGluRs). The function of mGluR-mediated inhibition remains largely elusive. Here, we investigated the role of group III mGluR-dependent inhibition in the habenula. This primarily glutamatergic and conserved forebrain region acts as a hub between multiple forebrain inputs and neuromodulatory mid- and hindbrain targets that regulate adaptive behaviors. We showed that both zebrafish and mice habenula express group III mGluRs. We identified that group III mGluRs regulate the membrane potential and calcium activity of zebrafish dorsal habenula. Pharmacological and genetic perturbation of group III mGluRs increased sensory-evoked excitation and reduced selectivity of habenular neurons to different sensory modalities. We also observed that inhibition is the main channel of communication between primarily glutamatergic habenula neurons. Blocking group III mGluRs reduced inhibition within habenula and increased correlations during spontaneous activity. In line with such inhibition within habenula, we identified that multi-sensory information is integrated mainly through competition and suppression across habenular neurons, which in part relies on group III mGluRs. Finally, genetic perturbation of a habenula-specific group III mGluR, mGluR6a, amplified neural responses and defensive behaviors evoked by sensory stimulation and environmental changes. Altogether, our results revealed that mGluR driven inhibition is essential in encoding, integration, and communication of information between Hb neurons, ultimately playing a critical role in regulating defensive and adaptive behaviors.
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由第 III 组 mGluRs 介导的抑制作用可调控大脑后叶的活动和防御行为
抑制有助于从感官运动转换到认知操作的各种大脑计算。虽然有关抑制的研究大多集中在 GABA 上,但大脑的主要兴奋性神经递质谷氨酸也能通过代谢型谷氨酸受体(mGluRs)引起抑制。mGluR 介导的抑制功能在很大程度上仍然难以捉摸。在这里,我们研究了第 III 组 mGluR 依赖性抑制在哈氏脑中的作用。这个主要由谷氨酸能和保守的前脑区域是多个前脑输入和调节适应行为的中脑和后脑神经调节靶点之间的枢纽。我们发现斑马鱼和小鼠的哈文鱼都表达第 III 组 mGluRs。我们发现 III 组 mGluRs 可调控斑马鱼背侧哈氏神经节的膜电位和钙离子活性。药理和基因扰乱 III 组 mGluRs 会增加感觉诱发的兴奋,并降低背神经元对不同感觉模式的选择性。我们还观察到,抑制是主要是谷氨酸能神经元之间交流的主要渠道。阻断第三组 mGluRs 可减少哈氏神经元内部的抑制作用,并增加自发活动期间的相关性。与这种抑制作用相一致,我们发现多感觉信息主要是通过不同神经元之间的竞争和抑制来整合的,而这在一定程度上依赖于III群mGluRs。最后,通过基因扰乱一种兔神经元特异的第三组 mGluR(mGluR6a),可以放大由感觉刺激和环境变化引起的神经反应和防御行为。总之,我们的研究结果表明,mGluR驱动的抑制作用在哈贝神经元之间的信息编码、整合和交流中至关重要,最终在调节防御和适应行为中发挥关键作用。
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