氯胺酮在神经发育障碍相关2p16.3缺失小鼠模型中恢复丘脑-前额叶皮质功能连接

Rebecca B Hughes, Jayde Whittingham-Dowd, Rachel E. Simmons, S. Clapcote, S. Broughton, N. Dawson
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引用次数: 12

摘要

2p16.3缺失,包括杂合子NEUREXIN1 (NRXN1)缺失,显著增加发生神经发育障碍的风险,包括自闭症和精神分裂症。我们对NRXN1杂合性如何增加发生这些疾病的风险知之甚少,特别是在对大脑和神经递质系统功能以及大脑网络连接的影响方面。因此,本研究表征了Nrxn1α杂合小鼠(Nrxn1α+/ -小鼠)的脑代谢和功能性脑网络连接,并评估了氯胺酮和右苯丙胺对这些动物脑代谢的影响。我们发现,杂合的Nrxn1α缺失改变了与自闭症和精神分裂症有关的神经系统的脑代谢,包括丘脑、中边缘系统和部分皮质区域。Nrxn1α杂合性还通过丘脑“富俱乐部”和前额叶皮质(PFC)中枢连通性的丧失,以及丘脑-PFC和丘脑“富俱乐部”区域互联性的降低,降低了功能性脑网络的效率。亚麻醉氯胺酮给药可使Nrxn1α+/−小鼠的丘脑高代谢正常化,并部分使丘脑失联正常化,而右旋安非他明的脑代谢反应未发生改变。这些数据为杂合Nrxn1α缺失的系统水平影响以及它如何增加发生神经发育障碍的风险提供了新的见解。这些数据还表明,杂合Nrxn1α缺失引起的丘脑功能障碍可能是NMDA受体依赖的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ketamine Restores Thalamic-Prefrontal Cortex Functional Connectivity in a Mouse Model of Neurodevelopmental Disorder-Associated 2p16.3 Deletion
Abstract 2p16.3 deletions, involving heterozygous NEUREXIN1 (NRXN1) deletion, dramatically increase the risk of developing neurodevelopmental disorders, including autism and schizophrenia. We have little understanding of how NRXN1 heterozygosity increases the risk of developing these disorders, particularly in terms of the impact on brain and neurotransmitter system function and brain network connectivity. Thus, here we characterize cerebral metabolism and functional brain network connectivity in Nrxn1α heterozygous mice (Nrxn1α+/− mice), and assess the impact of ketamine and dextro-amphetamine on cerebral metabolism in these animals. We show that heterozygous Nrxn1α deletion alters cerebral metabolism in neural systems implicated in autism and schizophrenia including the thalamus, mesolimbic system, and select cortical regions. Nrxn1α heterozygosity also reduces the efficiency of functional brain networks, through lost thalamic “rich club” and prefrontal cortex (PFC) hub connectivity and through reduced thalamic-PFC and thalamic “rich club” regional interconnectivity. Subanesthetic ketamine administration normalizes the thalamic hypermetabolism and partially normalizes thalamic disconnectivity present in Nrxn1α+/− mice, while cerebral metabolic responses to dextro-amphetamine are unaltered. The data provide new insight into the systems-level impact of heterozygous Nrxn1α deletion and how this increases the risk of developing neurodevelopmental disorders. The data also suggest that the thalamic dysfunction induced by heterozygous Nrxn1α deletion may be NMDA receptor-dependent.
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