AUTHOR=Mount Rebecca A. , Athif Mohamed , O’Connor Margaret , Saligrama Amith , Tseng Hua-an , Sridhar Sudiksha , Zhou Chengqian , Bortz Emma , San Antonio Erynne , Kramer Mark A. , Man Heng-Ye , Han Xue
TITLE=The autism spectrum disorder risk gene NEXMIF over-synchronizes hippocampal CA1 network and alters neuronal coding
JOURNAL=Frontiers in Neuroscience
VOLUME=17
YEAR=2023
URL=https://www.frontiersin.org/journals/neuroscience/articles/10.3389/fnins.2023.1277501
DOI=10.3389/fnins.2023.1277501
ISSN=1662-453X
ABSTRACT=
Mutations in autism spectrum disorder (ASD) risk genes disrupt neural network dynamics that ultimately lead to abnormal behavior. To understand how ASD-risk genes influence neural circuit computation during behavior, we analyzed the hippocampal network by performing large-scale cellular calcium imaging from hundreds of individual CA1 neurons simultaneously in transgenic mice with total knockout of the X-linked ASD-risk gene NEXMIF (neurite extension and migration factor). As NEXMIF knockout in mice led to profound learning and memory deficits, we examined the CA1 network during voluntary locomotion, a fundamental component of spatial memory. We found that NEXMIF knockout does not alter the overall excitability of individual neurons but exaggerates movement-related neuronal responses. To quantify network functional connectivity changes, we applied closeness centrality analysis from graph theory to our large-scale calcium imaging datasets, in addition to using the conventional pairwise correlation analysis. Closeness centrality analysis considers both the number of connections and the connection strength between neurons within a network. We found that in wild-type mice the CA1 network desynchronizes during locomotion, consistent with increased network information coding during active behavior. Upon NEXMIF knockout, CA1 network is over-synchronized regardless of behavioral state and fails to desynchronize during locomotion, highlighting how perturbations in ASD-implicated genes create abnormal network synchronization that could contribute to ASD-related behaviors.