Background: Social withdrawal is a core symptom of schizophrenia(SCZ), but its underlying molecular mechanisms remain unclear. Gα13(GNA13), a G protein alpha subunit, has been implicated in SCZ susceptibility. This study investigated the role of Gα13 in social behavior by overexpressing it in the medial prefrontal cortex(mPFC) pyramidal neurons of mice. Methods: In this study, we first constructed CRE recombinase overexpressing Gα13 gene mice using CRISPR/Cas9 technology, tested the social behaviors by three-box socialization test, detected the changes of neuronal activities during social activities in mice by calcium signal fiber-optic recordings, and observed the changes of dendritic spines by Golgi staining, and applied RNA sequencing to find the relevant targets, and observed whether it could reverse the abnormalities by pharmacological experiments social behavior. The electrophysiological characteristics of Gα13 overexpression were investigated using the wholecell membrane clamp technique, followed by assessment of the severity of schizophrenic patients and social withdrawal using the PANSS scale, and measurement of human plasma Gα13 protein levels using the ELISA technique, and the clinical correlation between the two was assessed. Results: Gα13 overexpression(Gα13-OE) mice exhibited significant social deficits in the three-chamber test, showing reduced sociability but normal social novelty recognition. Fiber photometry recordings revealed decreased neuronal activity during social interactions, and Golgi staining showed reduced dendritic spine density in mPFC pyramidal neurons. RNA sequencing identified downregulation of Adcyap1, affecting the c AMP/PKA signaling pathway and NMDA receptor(NMDAR) function. Pharmacological activation of Adcyap1 with PACAP-38 or NMDAR with D-cycloserine rescued the social deficits and restored synaptic function. Conversely, knockdown of Gα13 in an MK-801–induced SCZ mouse model ameliorated social behavior abnormalities. Clinically, patients with SCZ exhibited elevated plasma levels of Gα13, which positively correlated with the severity of social withdrawal symptoms measured by the PANSS G16 item. Conclusion: These findings suggest that overexpression of Gα13 in the mPFC impairs social behavior by disrupting neuronal function and synaptic plasticity via the Adcyap1/cAMP/PKA/NMDAR Pathway. Targeting Gα13 may offer a novel therapeutic strategy for addressing social deficits in SCZ.