Unaltered Network Activity and Interneuronal Firing During Spontaneous Cortical Dynamics In Vivo in a Mouse Model of Severe Myoclonic Epilepsy of Infancy

A. M. De Stasi, P. Farisello, Iacopo Marcon, Stefano Cavallari, Angelo Forli, Dania Vecchia, G. Losi, M. Mantegazza, S. Panzeri, G. Carmignoto, A. Bacci, Tommaso Fellin
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引用次数: 53

Abstract

Severe myoclonic epilepsy of infancy (SMEI) is associated with loss of function of the SCN1A gene encoding the NaV1.1 sodium channel isoform. Previous studies in Scn1a−/+ mice during the pre-epileptic period reported selective reduction in interneuron excitability and proposed this as the main pathological mechanism underlying SMEI. Yet, the functional consequences of this interneuronal dysfunction at the circuit level in vivo are unknown. Here, we investigated whether Scn1a−/+ mice showed alterations in cortical network function. We found that various forms of spontaneous network activity were similar in Scn1a−/+ during the pre-epileptic period compared with wild-type (WT) in vivo. Importantly, in brain slices from Scn1a−/+ mice, the excitability of parvalbumin (PV) and somatostatin (SST) interneurons was reduced, epileptiform activity propagated more rapidly, and complex synaptic changes were observed. However, in vivo, optogenetic reduction of firing in PV or SST cells in WT mice modified ongoing network activities, and juxtasomal recordings from identified PV and SST interneurons showed unaffected interneuronal firing during spontaneous cortical dynamics in Scn1a−/+ compared with WT. These results demonstrate that interneuronal hypoexcitability is not observed in Scn1a−/+ mice during spontaneous activities in vivo and suggest that additional mechanisms may contribute to homeostatic rearrangements and the pathogenesis of SMEI.
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婴儿期严重肌阵挛性癫痫小鼠模型体内自发皮质动力学过程中未改变的网络活动和神经元间放电
婴儿严重肌阵挛性癫痫(SMEI)与编码NaV1.1钠通道亚型的SCN1A基因功能丧失有关。先前对癫痫前期Scn1a−/+小鼠的研究报道了神经元间兴奋性的选择性降低,并提出这是SMEI的主要病理机制。然而,这种神经元间功能障碍在体内回路水平上的功能后果尚不清楚。在这里,我们研究了Scn1a−/+小鼠是否表现出皮层网络功能的改变。我们发现,与野生型(WT)相比,Scn1a−/+在癫痫前时期的各种形式的自发网络活动在体内是相似的。重要的是,在Scn1a−/+小鼠的脑切片中,小白蛋白(PV)和生长抑素(SST)中间神经元的兴奋性降低,癫痫样活动传播更快,并且观察到复杂的突触变化。然而,在体内,WT小鼠PV或SST细胞放电的光遗传减少改变了正在进行的网络活动,经鉴定的PV和SST中间神经元的近点记录显示,与WT相比,Scn1a−/+小鼠在自发皮层动态过程中神经元间放电未受影响。这些结果表明,在体内自发活动中,Scn1a−/+小鼠未观察到神经元间低兴奋性,这表明可能有其他机制参与了稳态重排和SMEI的发病机制。
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