抑制性神经元中神经蛋白酶 2 表达失调会损害海马环路发育,导致自闭症-癫痫表型

Vijjayalakshmi Santhakumar, Deepak Subramanian, C. Eisenberg, Andrew Huang, Jiyeon Baek, Haniya Naveed, Samiksha Komatireddy, Michael Shiflett, Tracy Tran
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摘要

摘要 神经元间的发育、迁移和功能失调(统称为神经元间疾病)已被认为是自闭症谱系障碍(ASD)和儿童癫痫的共同机制。神经胶质蛋白-2(Nrp2)是自闭症谱系障碍的候选基因之一,它是中间神经元从正中神经节突起(MGE)向包括海马在内的丘脑迁移的关键调节因子。虽然临床研究发现了 ASD 患者的 Nrp2 多态性,但尚未检测依赖 Nrp2 的神经元间迁移失调是否会导致 ASD 和癫痫的发病。我们测试了这样一个假设:MGE衍生的中间神经元前体中缺乏Nrp2会破坏海马回路中的兴奋/抑制平衡,从而使该网络容易出现癫痫发作和与ASD相关的行为模式。在MGE衍生的中间神经元前体迁移的发育阶段,胚胎期删除Nrp2(iCKO)会显著减少海马CA1中的副发光素、神经肽Y和体节素阳性神经元。因此,与对照组相比,iCKO 小鼠 CA1 锥体细胞中抑制性突触电流的频率降低,而兴奋性突触电流的频率升高。虽然CA1锥体细胞的被动和主动膜特性没有变化,但iCKO小鼠对化学诱发癫痫发作的敏感性增强。此外,iCKO 小鼠在社会新奇事物偏好和目标定向学习方面都表现出选择性行为缺陷,这与 ASD 类表型一致。综上所述,我们的研究结果表明,发育过程中 Nrp2 对中间神经元回路建立的调控被破坏,会产生类似 ASD 的行为并增加癫痫风险。这些结果支持了 ASD 癫痫合并症的发育性中间神经元病变假说。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dysregulation of Neuropilin-2 Expression in Inhibitory Neurons Impairs Hippocampal Circuit Development Leading to Autism-Epilepsy Phenotype
Abstract Dysregulation of development, migration, and function of interneurons, collectively termed interneuronopathies, have been proposed as a shared mechanism for autism spectrum disorders (ASDs) and childhood epilepsy. Neuropilin-2 (Nrp2), a candidate ASD gene, is a critical regulator of interneuron migration from the median ganglionic eminence (MGE) to the pallium, including the hippocampus. While clinical studies have identified Nrp2 polymorphisms in patients with ASD, whether dysregulation of Nrp2-dependent interneuron migration contributes to pathogenesis of ASD and epilepsy has not been tested. We tested the hypothesis that the lack of Nrp2 in MGE-derived interneuron precursors disrupts the excitation/inhibition balance in hippocampal circuits, thus predisposing the network to seizures and behavioral patterns associated with ASD. Embryonic deletion of Nrp2 during the developmental period for migration of MGE derived interneuron precursors (iCKO) significantly reduced parvalbumin, neuropeptide Y, and somatostatin positive neurons in the hippocampal CA1. Consequently, when compared to controls, the frequency of inhibitory synaptic currents in CA1 pyramidal cells was reduced while frequency of excitatory synaptic currents was increased in iCKO mice. Although passive and active membrane properties of CA1 pyramidal cells were unchanged, iCKO mice showed enhanced susceptibility to chemically evoked seizures. Moreover, iCKO mice exhibited selective behavioral deficits in both preference for social novelty and goal-directed learning, which are consistent with ASD-like phenotype. Together, our findings show that disruption of developmental Nrp2 regulation of interneuron circuit establishment, produces ASD-like behaviors and enhanced risk for epilepsy. These results support the developmental interneuronopathy hypothesis of ASD epilepsy comorbidity.
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