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Scn2a severe hypomorphic mutation decreases excitatory synaptic input and causes autism-associated behaviors
Hong-Gang Wang, … , Anjali M. Rajadhyaksha, Geoffrey S. Pitt
Hong-Gang Wang, … , Anjali M. Rajadhyaksha, Geoffrey S. Pitt
Published June 22, 2021
Citation Information: JCI Insight. 2021;6(15):e150698. https://doi.org/10.1172/jci.insight.150698.
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Research Article Neuroscience

Scn2a severe hypomorphic mutation decreases excitatory synaptic input and causes autism-associated behaviors

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Abstract

SCN2A, encoding the neuronal voltage-gated Na+ channel NaV1.2, is one of the most commonly affected loci linked to autism spectrum disorders (ASDs). Most ASD-associated mutations in SCN2A are loss-of-function mutations, but studies examining how such mutations affect neuronal function and whether Scn2a mutant mice display ASD endophenotypes have been inconsistent. We generated a protein truncation variant Scn2a mouse model (Scn2aΔ1898/+) by CRISPR that eliminates the NaV1.2 channel’s distal intracellular C-terminal domain, and we analyzed the molecular and cellular consequences of this variant in a heterologous expression system, in neuronal culture, in brain slices, and in vivo. We also analyzed multiple behaviors in WT and Scn2aΔ1898/+ mice and correlated behaviors with clinical data obtained in human subjects with SCN2A variants. Expression of the NaV1.2 mutant in a heterologous expression system revealed decreased NaV1.2 channel function, and cultured pyramidal neurons isolated from Scn2aΔ1898/+ forebrain showed correspondingly reduced voltage-gated Na+ channel currents without compensation from other CNS voltage-gated Na+ channels. Na+ currents in inhibitory neurons were unaffected. Consistent with loss of voltage-gated Na+ channel currents, Scn2aΔ1898/+ pyramidal neurons displayed reduced excitability in forebrain neuronal culture and reduced excitatory synaptic input onto the pyramidal neurons in brain slices. Scn2aΔ1898/+ mice displayed several behavioral abnormalities, including abnormal social interactions that reflect behavior observed in humans with ASD and with harboring loss-of-function SCN2A variants. This model and its cellular electrophysiological characterizations provide a framework for tracing how a SCN2A loss-of-function variant leads to cellular defects that result in ASD-associated behaviors.

Authors

Hong-Gang Wang, Charlotte C. Bavley, Anfei Li, Rebecca M. Jones, Jonathan Hackett, Yared Bayleyen, Francis S. Lee, Anjali M. Rajadhyaksha, Geoffrey S. Pitt

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