Abstract

Abnormal synaptic formation and signaling is one of the key molecular features of autism spectrum disorders (ASD). Cortactin binding protein 2 (CTTNBP2), an ASD-linked gene, is known to regulate the subcellular distribution of synaptic proteins, such as cortactin, thereby controlling dendritic spine formation and maintenance. However, it remains unclear how ASD-linked mutations of CTTNBP2 influence its function. Here, using cultured hippocampal neurons and knockin mouse models, we screen seven ASD-linked mutations in the short form of the Cttnbp2 gene and identify that M120I, R533* and D570Y mutations impair CTTNBP2 protein–protein interactions via divergent mechanisms to reduce dendritic spine density in neurons. R533* mutation impairs CTTNBP2 interaction with cortactin due to lack of the C-terminal proline-rich domain. Through an N–C terminal interaction, M120I mutation at the N-terminal region of CTTNBP2 also negatively influences cortactin interaction. D570Y mutation increases the association of CTTNBP2 with microtubule, resulting in a dendritic localization of CTTNBP2, consequently reducing the distribution of CTTNBP2 in dendritic spines and impairing the synaptic function of CTTNBP2. Finally, we generated heterozygous M120I knockin mice to mimic the genetic variation of patients and found they exhibit reduced social interaction. Our study elucidates that different ASD-linked mutations of CTTNBP2 result in diverse molecular deficits, but all have the similar consequence of synaptic impairment.

Highlights

  • Autism spectrum disorders (ASD) are highly prevalent neurodevelopmental diseases mainly caused by genetic variations [2, 19]

  • These three mutations resulted in prominent dendritic spine defects in cultured hippocampal neurons, as well as in mouse brains

  • The mechanisms underlying the effects of these three mutations on dendritic spine formation differ, representing an illustrative example of how divergent mechanisms contribute to ASD etiology, even for mutations of the same gene, yet result in convergent outcomes

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Summary

Introduction

Autism spectrum disorders (ASD) are highly prevalent neurodevelopmental diseases mainly caused by genetic variations [2, 19]. Hundreds of mutated genes have been associated with ASD (https://gene.sfari.org/database/ human-gene/). One critical feature of ASD-causative or -linked genes is their roles in controlling synapse. Among the various synapse-associated ASD candidate genes, CTTNBP2 was identified as a strong candidate ASD-linked gene based on several human genetic studies [7, 11, 17, 18]. A study of Cttnbp knockout mice has indicated that CTTNBP2 regulates social interaction, ultrasonic vocalization and hyperactivity [20], further strengthening the role of CTTNBP2 in ASD. 38 mutations in the CTTNBP2 gene have been identified in patients with ASD (https://gene.sfari.org/database/ human-gene/CTTNBP2#variants-tab). How ASD-linked mutations of CTTNBP2 alter neuronal function to result in autism-like symptoms remains elusive

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