NRXN1α is associated with increased excitability in ASD iPSC-derived neurons.

Background: 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.

Methods: 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.

Results: 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.

Conclusions: 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.