School of Medicine, Regenerative Medicine Institute, Biomedical Science Building BMS-1021, National University of Ireland Galway, Dangan, Ireland.
Physiology and Cellular Physiology Research Laboratory, School of Medicine, CÚRAM SFI Centre for Research in Medical Devices, National University of Ireland (NUI), Galway, Ireland.
BMC Neurosci. 2021 Sep 15;22(1):56. doi: 10.1186/s12868-021-00661-0.
NRXN1 deletions are identified as one of major rare risk factors for autism spectrum disorder (ASD) and other neurodevelopmental disorders. ASD has 30% co-morbidity with epilepsy, and the latter is associated with excessive neuronal firing. NRXN1 encodes hundreds of presynaptic neuro-adhesion proteins categorized as NRXN1α/β/γ. Previous studies on cultured cells show that the short NRXN1β primarily exerts excitation effect, whereas the long NRXN1α which is more commonly deleted in patients involves in both excitation and inhibition. However, patient-derived models are essential for understanding functional consequences of NRXN1α deletions in human neurons. We recently derived induced pluripotent stem cells (iPSCs) from five controls and three ASD patients carrying NRXN1α and showed increased calcium transients in patient neurons.
In this study we investigated the electrophysiological properties of iPSC-derived cortical neurons in control and ASD patients carrying NRXN1α using patch clamping. Whole genome RNA sequencing was carried out to further understand the potential underlying molecular mechanism.
NRXN1α cortical neurons were shown to display larger sodium currents, higher AP amplitude and accelerated depolarization time. RNASeq analyses revealed transcriptomic changes with significant upregulation glutamatergic synapse and ion channels/transporter activity including voltage-gated potassium channels (GRIN1, GRIN3B, SLC17A6, CACNG3, CACNA1A, SHANK1), which are likely to couple with the increased excitability in NRXN1α cortical neurons.
Together with recent evidence of increased calcium transients, our results showed that human NRXN1α isoform deletions altered neuronal excitability and non-synaptic function, and NRXN1α patient iPSCs may be used as an ASD model for therapeutic development with calcium transients and excitability as readouts.
NRXN1 缺失被认为是自闭症谱系障碍 (ASD) 和其他神经发育障碍的主要罕见风险因素之一。ASD 有 30%与癫痫共病,后者与过度神经元放电有关。NRXN1 编码数百种分类为 NRXN1α/β/γ 的突触前神经粘附蛋白。之前在培养细胞上的研究表明,短 NRXN1β 主要发挥兴奋作用,而长 NRXN1α 在患者中更常见缺失,涉及兴奋和抑制作用。然而,患者衍生模型对于理解 NRXN1α 缺失在人类神经元中的功能后果至关重要。我们最近从五名对照和三名携带 NRXN1α 的 ASD 患者中获得诱导多能干细胞 (iPSC),并显示患者神经元中的钙瞬变增加。
在这项研究中,我们使用膜片钳技术研究了携带 NRXN1α 的对照和 ASD 患者来源的 iPSC 衍生皮质神经元的电生理特性。进行全基因组 RNA 测序以进一步了解潜在的分子机制。
NRXN1α 皮质神经元显示出更大的钠电流、更高的 AP 幅度和更快的去极化时间。RNASeq 分析显示转录组发生变化,谷氨酸能突触和离子通道/转运体活性显著上调,包括电压门控钾通道 (GRIN1、GRIN3B、SLC17A6、CACNG3、CACNA1A、SHANK1),这可能与 NRXN1α 皮质神经元的兴奋性增加有关。
结合最近钙瞬变增加的证据,我们的结果表明,人类 NRXN1α 异构体缺失改变了神经元的兴奋性和非突触功能,NRXN1α 患者 iPSC 可能作为 ASD 模型用于治疗开发,以钙瞬变和兴奋性作为读出。
