Heterozygosity for neurodevelopmental disorder-associatedvariants yields distinct deficits in behavior, neuronal development, and synaptic transmission in mice.

Abstract

Genetic variants inare associated with neurodevelopmental disorders (NDDs) including schizophrenia (SCZ), autism spectrum disorder (ASD), and intellectual disability. TRIO uses its two guanine nucleotide exchange factor (GEF) domains to activate GTPases (GEF1: Rac1 and RhoG; GEF2: RhoA) that control neuronal development and connectivity. It remains unclear how discretevariants differentially impact these neurodevelopmental events. Here, we investigate how heterozygosity for NDD-associatedvariants -(ASD),(SCZ)and(bipolar disorder, BPD) - impacts mouse behavior, brain development, and synapse structure and function. Heterozygosity for differentvariants impacts motor, social, and cognitive behaviors in distinct ways that model clinical phenotypes in humans.variants differentially impact head and brain size, with corresponding changes in dendritic arbors of motor cortex layer 5 pyramidal neurons (M1 L5 PNs). Although neuronal structure was only modestly altered in thevariant heterozygotes, we observe significant changes in synaptic function and plasticity. We also identified distinct changes in glutamate synaptic release inandcortico-cortical synapses. The TRIO K1431M GEF1 domain has impaired ability to promote GTP exchange on Rac1, butmice exhibit increased Rac1 activity, associated with increased levels of the Rac1 GEF Tiam1. Acute Rac1 inhibition with NSC23766 rescued glutamate release deficits invariant cortex. Our work reveals that discrete NDD-associatedvariants yield overlapping but distinct phenotypes in mice, demonstrates an essential role for Trio in presynaptic glutamate release, and underscores the importance of studying the impact of variant heterozygosity in vivo.