Abstract
Alterations in excitation/inhibition (E/I) balance and changes in motor neurons (MN) activity may contribute to MN vulnerability in ALS. The balance of pathogenic versus adaptive changes occurring in inhibitory synapses and affecting E/I balance remain unclear. Confocal microscopy of MN from P45 male SOD1G93A mice reveal downregulated GlyR but upregulated GABAR clusters at inhibitory synapses. GlyR and GABAR respond to PSAM and DREADD chemogenetic alterations of MN excitability, with increased activity driving increase in inhibitory clusters. An E3 ligase-conjugated intrabody (GFE3) degrades Gephyrin, decreases GABAR and GlyR clusters, increases net activity, and downregulates disease markers. However, simultaneous decrease of inhibition and increased activity by actPSAM and GFE3 shows no net beneficial effects on disease markers. Thus inhibitory synapses are involved in the early phases of ALS pathogenesis and respond to persistent homeostatic loops, and their suppression delivers a net activity increase, offering potential benefits on disease pathways.