ABSTRACT Alzheimer's disease (AD) is the most common form of late-onset dementia. The extents of tau pathology are closely related to memory decline. How pathogenic tau causes cognitive deficits is not clear. While most studies on tau have been focused on direct effects of tau on neurons, compelling human genetic studies linked maladaptive innate immune responses, including microglial responses, to elevated risk of developing late- onset Alzheimer disease. The striking enrichment of innate immune genes as risk alleles for Alzheimer disease supports critical disease-enhancing role of maladaptive microglia in tau-mediated cognitive deficits. Identifying how maladaptive microglial enhances tau toxicity could lead to new therapeutic strategies. In our preliminary studies, we found that tauopathy mice exhibit hyperactive Cyclic GMP-AMP synthase (cGAS)- Stimulator of interferon genes (STING) signaling. As a major sensor of cytosolic DNA, cGAS-STING pathway mobilizes antiviral responses via activation of interferon regulatory factors (IRFs) and expression of cytokine and type I interferon genes. The hyperactive cGAS pathways contributes to tau toxicity since genetic reduction of cGAS protected against tau-mediated spatial learning and memory deficits in a tauopathy mouse model of Alzheimer disease. In addition, the protective effects were associated with reduced interferon-enriched microglial subpopulations and reprogramming of disease-associated microglial states as identified using single nuclei RNA-seq. We hypothesize that microglial cGAS-STING hyperactivation mediates the maladaptive disease-enhancing microglial response in tauopathy. To test this hypothesis, In Aim 1, we will first determine how cGAS activation in microglia enhances tau toxicity (1a). Using a combination of single nuclei RNA-seq, pathological and functional analyses, we will investigate if toxicity from cGAS hyperactivation in microglia or bone marrow-derived monocytes (1b, 1c). In Aim 2, we will dissect if the toxic effects of cGAS activation in tauopathy are mediated by STING-dependent or -independent mechanisms, we will determine if loss of STING phenocopies the effects of cGAS inactivation on tau toxicity and transcriptomic changes (2a). We will then determine STING-independent mechanisms of cGAS activation by assessing how cGAS inactivation affects tau toxicity on Sting null background (2b). The significant protective effects of partial loss of cGAS supports that partial inhibition with pharmacological inhibitors of cGAS could be beneficial for tauopathy. We showed that a specific cGAS inhibitor, TDI6570, is brain permeable and effectively inhibit expression of type 1 interferon target genes in tauopathy mice. We will then optimize the dosing using formulated chow based on PK/PD, and evaluate the beneficial effects of the cGAS inhibitor before or after the onset of cognitive deficit in tauopathy mice in Aim 3. Completion of the proposed study will identify novel disease-enhanc...