PROJECT SUMMARY Genetic variants in the TRIO gene increase risk for neurodevelopmental disorders (NDDs) including schizophrenia, autism, and related disorders. TRIO encodes a large protein with two guanine nucleotide exchange factor (GEF) domains for Rho family GTPases: GEF1 activates Rac1 and RhoG, and GEF2 activates RhoA. We found a cluster of variants associated with autism and intellectual disability that selectively activate or inhibit TRIO GEF1 activity. While our findings highlight the central importance of this enzyme activity for proper brain development, the molecular mechanisms by which TRIO GEF1 activity is regulated, the downstream targets of TRIO GEF1 signaling, and how these processes are disrupted by GEF1-targeting variants remain fundamental, yet unresolved questions. Answering them will reveal how variants in TRIO lead to NDDs and may inform new therapeutic interventions. Our proposal will address these questions in three Aims: Aim 1. To elucidate the mechanism of TRIO GEF1 activation. We discovered that spectrin repeats 6-9 in TRIO bind and autoinhibit its GEF1 activity and that NDD-associated variants in spectrin repeat 8 relieve this autoinhibition. A short list of receptors and kinases has been identified as known or likely TRIO GEF1 regulators, but the mechanisms by which these activators engage TRIO to activate GEF1 activity are unclear. We will use purified recombinant proteins to test how these receptors’ cytoplasmic domains and kinases impact TRIO GEF1 activity. We will also use a FRET-based activity biosensor and morphological measurements to reveal how these mechanisms contribute to Rac1/RhoG activation and neuronal development induced by receptor activation. Aim 2. To identify and characterize the neuronal signaling events regulated by TRIO GEF1 activity. We have generated mice bearing TRIO variant alleles with reduced (K1431M) or elevated (R1078Q) TRIO GEF1 activity. We will use comparative proteomics and phospho-proteomics in samples from wild-type mice versus those bearing TRIO GEF1-inhibiting or activating alleles to identify proteins, signaling events, and TRIO- interaction partners impacted by changes in TRIO GEF1 activity. We will systematically test how manipulation of these GEF1-mediated events impacts neuronal development and synaptic connectivity. Aim 3. To measure how selective changes in TRIO GEF1 activity impact neuronal development and synaptic transmission. Heterozygosity for the GEF1-defective TRIOK1431M allele causes reduced brain size and behavioral defects, consistent with our hypothesis that selective alterations in TRIO GEF1 activity compromise normal neuronal development and synaptic function. We will use quantitative histopathology and electron microscopy in mice bearing the K1431M and R1078Q variants to reveal how altered TRIO GEF1 activity impacts axon, dendritic arbor, and synapse development. Whole-cell electrophysiology and optogenetic manipulation will enable us to identify the consequen...