What question did this study set out to answer?

The study aims to clarify the synaptic mechanisms involved in neurodevelopmental disorders induced by valproic acid exposure through the investigation of Dlgap2.

February 14, 2026Open Access

Dlgap2 deficiency disrupts synaptic homeostasis by promoting ubiquitin-mediated Itsn1 degradation in a valproic acid-induced autism-like model

Key Points

The study aims to clarify the synaptic mechanisms involved in neurodevelopmental disorders induced by valproic acid exposure through the investigation of Dlgap2.
Multi-omics analyses to identify dysregulated proteins in valproic acid models
Dlgap2 knockdown in mice to observe effects on synaptic deficits and behaviors
Proteomics of postsynaptic density to assess changes following Dlgap2 deficiency.
Dlgap2 knockdown leads to synaptic deficits and autism-like behaviors in mice
Identification of disrupted synaptic organization following Dlgap2 deficiency
Reduction in Itsn1 levels due to ubiquitin-mediated degradation linked to Dlgap2.

Abstract

Prenatal valproic acid (VPA) exposure increases the risk of neurodevelopmental disorders, though its synaptic mechanisms remain unclear. Using multi-omics analyses, we identified Dlgap2 as a consistently dysregulated protein in VPA models. Mice with Dlgap2 knockdown exhibited synaptic deficits and autism-like behaviors, including social and cognitive impairments. Proteomics of postsynaptic density following Dlgap2 knockdown revealed disruption of synaptic organization and a specific reduction in Intersectin-1 (Itsn1), which interacts with Dlgap2 and undergoes ubiquitin-mediated degradation upon Dlgap2 deficiency. Our study defines a Dlgap2-Itsn1 regulatory axis that underlies VPA-induced synaptic dysfunction.

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Dlgap2 deficiency disrupts synaptic homeostasis by promoting ubiquitin-mediated Itsn1 degradation in a valproic acid-induced autism-like model

Key Points

Abstract

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