Cellular Neurobiology Laboratory, Centro de Investigación Médica Aplicada (CIMA) and Universidad de Navarra, 31008 Pamplona, Spain.
Cellular Neurobiology Laboratory, Centro de Investigación Médica Aplicada (CIMA) and Universidad de Navarra, 31008 Pamplona, Spain.
Neurobiol Dis. 2016 Sep;93:47-56. doi: 10.1016/j.nbd.2016.04.001. Epub 2016 Apr 9.
Age-inappropriate expression of juvenile NMDA receptors (NMDARs) containing GluN3A subunits has been linked to synapse loss and death of spiny projection neurons of the striatum (SPNs) in Huntington's disease (HD). Here we show that suppressing GluN3A expression prevents a multivariate synaptic transmission phenotype that precedes morphological signs at early prodromal stages. We start by confirming that afferent fiber stimulation elicits larger synaptic responses mediated by both AMPA receptors and NMDARs in SPNs in the YAC128 mouse model of HD. We then show that the enhancement mediated by both is fully prevented by suppressing GluN3A expression. Strong fiber-stimulation unexpectedly elicited robust NMDAR-mediated electrogenic events (termed "upstates" or "NMDA spikes"), and the effective threshold for induction was more than 2-fold lower in YAC128 SPNs because of the enhanced synaptic transmission. The threshold could be restored to control levels by suppressing GluN3A expression or by applying the weak NMDAR blocker memantine. However, the threshold was not affected by preventing glutamate spillover from synaptic clefts. Instead, long-lasting NMDAR responses interpreted previously as activation of extrasynaptic receptors by spilled-over glutamate were caused by NMDA spikes occurring in voltage clamp mode as escape potentials. Together, the results implicate GluN3A reactivation in a broad spectrum of early-stage synaptic transmission deficits in YAC128 mice; question the current concept that NMDAR mislocalization is the pathological trigger in HD; and introduce NMDA spikes as a new candidate mechanism for coupling NMDARs to neurodegeneration.
年龄不当表达包含 GluN3A 亚基的青少年 NMDA 受体 (NMDAR) 已与亨廷顿病 (HD) 纹状体 (SPN) 的棘突投射神经元的突触丧失和死亡有关。在这里,我们表明抑制 GluN3A 表达可防止多维突触传递表型,该表型先于形态学早期前体阶段的迹象。我们首先证实,传入纤维刺激会引发更大的突触反应,这些反应由 AMPA 受体和 NMDAR 在 HD 的 YAC128 小鼠模型中的 SPN 介导。然后,我们表明通过抑制 GluN3A 表达可完全防止两者介导的增强作用。出乎意料的是,强烈的纤维刺激会引发强大的 NMDAR 介导电活动(称为“上状态”或“NMDA spikes”),并且由于突触传递增强,YAC128 SPN 中的诱导有效阈值高 2 倍以上。可以通过抑制 GluN3A 表达或应用弱 NMDAR 阻滞剂美金刚将阈值恢复到对照水平。但是,通过防止谷氨酸从突触小泡溢出,阈值不受影响。相反,以前解释为溢出谷氨酸激活突触外受体的长时 NMDAR 反应是由于在电压钳模式下发生的 NMDA spikes 作为逃逸电位引起的。总而言之,这些结果表明 GluN3A 的再激活与 YAC128 小鼠中广泛的早期突触传递缺陷有关;对 NMDAR 定位错误是 HD 中病理触发因素的当前概念提出质疑;并引入 NMDA spikes 作为将 NMDAR 与神经退行性变偶联的新候选机制。
