Project Summary The legal status and widespread use of alcohol among the US population is associated with adverse health outcomes in both adolescents and adults. Nearly 88% of the US population have used alcohol at least once during their lifetime and rates of binge drinking and heavy alcohol use continue to be of concern. Pharmacological treatments for alcohol abuse show limited effectiveness and only three medications are FDA approved for treating alcohol dependence. One factor that underlies this problem is a lack of understanding of the mechanisms that contribute to excessive drinking. Recent results from our previous studies show that knock-in mice expressing ethanol resistant GluN2A N-methyl-D-aspartate receptors (NMDARs) drink the same as wild-type mice under baseline conditions but, unlike their wild-type counterparts, fail to escalate their drinking following repeated cycles of chronic intermittent ethanol exposure. These findings suggest that GluN2A NMDARs play a key role for in the loss of control over drinking observed in alcohol dependent subjects. Importantly, a similar lack of escalated drinking is observed following administration of inhibitors of zinc-dependent matrix metalloproteinases (MMPs) either i.c.v. or directly into the central nucleus of the amygdala (CeA). MMPs are key mediators of NMDA-mediated forms of synaptic plasticity where they remodel the extracellular matrix to support new growth and enlargement of glutamatergic dendritic spines. In this proposal we test the overarching hypothesis that MMPs and ethanol-sensitive GluN2A NMDARs in the CeA are critically involved in the transition to heavy drinking that is a hallmark of alcohol dependence. In Aim 1, we use slice electrophysiology, in vivo zymography and western blot analysis to test the hypothesis that CIE-induced changes in CeA neural signaling and MMP activity are absent in the GluN2A knock-in mice. In Aim 2, we use Crispr expressing AAVs and guide RNAs targeting the GluN2A gene to test the hypothesis that the CIE-induced increases in drinking and MMP activity requires functional GluN2A NMDARs in the CeA. The findings from these novel studies will provide critical data to support a future R01 grant application focused on determining which CeA cell types drive the altered drinking phenotype of the GluN2A knock-in mice and whether their expression in other key addiction-related brain areas contribute to this effect.