通过齿状回的药物遗传学抑制来抑制对模糊线索的条件作用。
Suppression of conditioning to ambiguous cues by pharmacogenetic inhibition of the dentate gyrus.
作者信息
Tsetsenis Theodoros, Ma Xiao-Hong, Lo Iacono Luisa, Beck Sheryl G, Gross Cornelius
机构信息
European Molecular Biology Laboratory (EMBL), Mouse Biology Unit, Via Ramarini 32, 00015 Monterotondo, Italy.
出版信息
Nat Neurosci. 2007 Jul;10(7):896-902. doi: 10.1038/nn1919. Epub 2007 Jun 3.
Abstract
Serotonin receptor 1A knockout (Htr1a(KO)) mice show increased anxiety-related behavior in tests measuring innate avoidance. Here we demonstrate that Htr1a(KO) mice show enhanced fear conditioning to ambiguous conditioned stimuli, a hallmark of human anxiety. To examine the involvement of specific forebrain circuits in this phenotype, we developed a pharmacogenetic technique for the rapid tissue- and cell type-specific silencing of neural activity in vivo. Inhibition of neurons in the central nucleus of the amygdala suppressed conditioned responses to both ambiguous and nonambiguous cues. In contrast, inhibition of hippocampal dentate gyrus granule cells selectively suppressed conditioned responses to ambiguous cues and reversed the knockout phenotype. These data demonstrate that Htr1a(KO) mice have a bias in the processing of threatening cues that is moderated by hippocampal mossy-fiber circuits, and suggest that the hippocampus is important in the response to ambiguous aversive stimuli.
摘要
血清素受体1A基因敲除(Htr1a(KO))小鼠在测量先天回避的测试中表现出与焦虑相关行为增加。在此我们证明,Htr1a(KO)小鼠对模糊条件刺激表现出增强的恐惧条件反射,这是人类焦虑的一个标志。为了研究特定前脑回路在该表型中的作用,我们开发了一种用于在体内快速对神经活动进行组织和细胞类型特异性沉默的药物遗传学技术。抑制杏仁核中央核中的神经元可抑制对模糊和明确线索的条件反应。相比之下,抑制海马齿状回颗粒细胞可选择性地抑制对模糊线索的条件反应并逆转基因敲除表型。这些数据表明,Htr1a(KO)小鼠在威胁线索的处理上存在偏差,这种偏差由海马苔藓纤维回路调节,并表明海马在对模糊厌恶刺激的反应中很重要。
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