Neural circuit and brain system alterations underlying social recognition memory deficits

社会认知记忆缺陷背后的神经回路和大脑系统改变

• 批准号: 10176596
• 负责人: Hala Harony-Nicolas
• 金额: $ 42.31万
• 依托单位: ICAHN SCHOOL OF MEDICINE AT MOUNT SINAI
• 依托单位国家: 美国
• 财政年份: 2019
• 资助国家: 美国
• 起止时间: 2019-08-09 至 2024-05-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/10176596
• 关键词: Address; Affect; Axon; Behavior; Behavior Therapy; Behavioral; Brain; Brain region; Corpus striatum structure; Data; Dendrites; Dense Core Vesicle; Docking; Electron Microscopy; Etiology; Exocytosis; Fiber; Functional disorder; Genes; Genetic; Glutamates; Hippocampus (Brain); Hormones; Hypothalamic structure; Impairment; Individual; Intervention; Knowledge; Lead; Lentivirus; Link; Memory impairment; Mental disorders; Microdialysis; Mission; Modeling; Molecular; Mutation; Neurodevelopmental Disorder; Neurons; Neuropeptides; Outcome; Oxytocin; Peptides; Peripheral; Pharmacological Treatment; Pharmacology; Pharmacology Study; Photometry; Physiological; Play; Population; Process; Public Health; Rattus; Regulation; Research; Rodent; Role; Social Behavior; Social Interaction; Symptoms; System; Testing; Therapeutic; United States National Institutes of Health; Vesicle; Viral; autism spectrum disorder; base; behavior test; behavioral study; cohort; designer receptors exclusively activated by designer drugs; experimental study; glutamatergic signaling; high risk; immunoreactivity; in vivo imaging; individuals with autism spectrum disorder; memory recognition; molecular dynamics; nerve supply; neural circuit; neuronal cell body; paraventricular nucleus; relating to nervous system; risk variant; social; social deficits; supraoptic nucleus; tool; trafficking

Abstract Social deficits are a hallmark feature of several psychiatric and neurodevelopmental disorders and are a core symptom of autism spectrum disorder. To date, behavioral therapies are the first line of intervention for treating impaired social behaviors, whereas pharmacological treatments have been ineffective at addressing this symptom domain. To inform treatment targets, there is an urgent need to understand the pathophysiology underlying social deficits. Several neural circuits and hormones involved in social behaviors have been identified and are conserved across species, e.g., the hypothalamic paraventricular nucleus and the release of the oxytocin peptide. Despite the wealth of behavioral and pharmacological studies implicating the paraventricular nucleus and oxytocin in social behavior, little is known about the effect of autism-associated mutations on the oxytocin system and whether malfunction in this system underlies social deficits in autism. Oxytocin is primarily synthesized by neurons in the paraventricular and supraoptic nuclei of the hypothalamus and is released peripherally to regulate physiological functions and centrally to modulate social behavior. Glutamatergic signaling is involved in the process of oxytocin release. Notably, mutations in the Shank3 gene, a high-risk gene for autism, perturb glutamatergic signaling in the hippocampus and striatum. However, the effect of Shank3 mutations on glutamatergic signaling and oxytocin release in the paraventricular nucleus has never been studied before. In this proposal, we study the effect of Shank3 mutations on the oxytocin system to ask how a Shank3 mutation in rats affect the activity of oxytocin neurons, glutamatergic signaling in the paraventricular nucleus, and the release of oxytocin at brain regions of social behavior. We also investigate whether the effect of Shank3 mutations on the oxytocin system underlies social behavior deficits. Our central hypothesis is that Shank3 mutations impair oxytocin release within the paraventricular nucleus and at brain regions of the social recognition circuit (Aim 1) by interfering with glutamatergic signaling and neural activity of oxytocin neurons in the paraventricular nucleus (Aim 2), leading to social recognition deficits (Aim 3). To this end, we will utilize a rat model with a Shank3 mutation and employ molecular, behavioral, and in vivo imaging experiments to capture alterations in neural activity of oxytocin neurons and identify impairments in oxytocin release during behavior. We will also employ viral-based approaches and chemo-genetic tools for neural-specific manipulations to determine causality between alteration in the oxytocin system and deficits in social behavior, caused by a Shank3 mutation. This study will lead to a clearer understanding of Shank3 function in the hypothalamic oxytocin system, which is part of a larger social brain circuit that could be targeted pharmacologically, genetically, or via circuit-specific non-invasive interventions to treat social behavior deficits in individuals with SHANK3 mutations and in individuals with autism that present similar brain alterations.

摘要 社交缺陷是几种精神和神经发育障碍的显著特征，也是 自闭症谱系障碍症状。到目前为止，行为疗法是治疗的一线干预。 损害社会行为，而药物治疗在解决这一问题上无效 症状域。为了告知治疗目标，迫切需要了解病理生理学。 潜在的社会赤字。已经确定了几种参与社会行为的神经回路和激素 并且在物种间是保守的，例如下丘脑室旁核和催产素的释放 多肽。尽管大量的行为和药理学研究表明室旁核 和催产素在社会行为中的作用，对自闭症相关突变对催产素的影响知之甚少 以及这个系统的故障是否导致了自闭症的社会缺陷。 催产素主要由下丘脑室旁核和视上核神经元合成 并在外围被释放以调节生理功能，并被集中释放以调节社会行为。 谷氨酸能信号参与催产素的释放过程。值得注意的是，Shank3基因的突变，一个 自闭症的高危基因，干扰了海马体和纹状体中的谷氨酸能信号。然而，其效果是 Shank3基因突变对室旁核谷氨酸能信号和催产素释放的影响 已经被研究过了。在这项建议中，我们研究了Shank3突变对催产素系统的影响 Shank3基因突变对大鼠脑内催产素神经元活性、谷氨酸能信号的影响 室旁核，以及社会行为脑区催产素的释放。我们还调查了 是否Shank3突变对催产素系统的影响是社会行为缺陷的基础。我们的中央 假说是，Shank3基因突变损害了室旁核和脑内催产素的释放 通过干扰谷氨酸能信号和神经活动的社会识别回路的区域(目标1) 室旁核中的催产素神经元(目标2)，导致社会认知障碍(目标3)。对这件事 最后，我们将利用带有Shank3突变的大鼠模型，并使用分子、行为和活体成像 捕捉催产素神经元神经活动变化和识别催产素损伤的实验 在行为过程中释放。我们还将使用基于病毒的方法和化学遗传工具来治疗神经特异性 确定催产素系统的改变和社会行为缺陷之间的因果关系的操作， 是由Shank3突变引起的。这项研究将有助于更清楚地了解Shank3在人体内的功能。 下丘脑催产素系统，这是可能成为靶点的更大的社交大脑回路的一部分 从药理学、遗传学或通过电路特异性非侵入性干预来治疗社会行为缺陷 在带有SHANK3突变的个体和表现出类似脑部改变的自闭症个体中。