PROJECT SUMMARY/ABSTRACT A watershed moment in decades of research in Alzheimer's disease (AD) is the discovery that targeting certain molecules in microglial cells can improve a hitherto unknown functional mechanism in these cells, and arrest cognitive decline. The first in class of microglial molecular targets for AD therapy is TREM2. TREM2 expression is upregulated in microglia in the AD brain, the microglia changes from a homeostatic state to something known as damage-associated microglia (DAMs) as defined by transcriptomics, and the loss of TREM2 prevents DAM transition while accelerating disease progression. Notably, the loss of TREM2 prevents the upregulation of another microglial molecule - AXL. Whether AXL has a critical effector function in the DAM-mediated thwarting of cognitive decline remained heretofore unknown. We have discovered that augmenting AXL leads to the arrest of cognitive decline in a mouse model of AD. There is a potential third player in this axis - MERTK. MERTK has been implicated by an independent study (Huang et al., Nature Immunology, 2021) in the phagocytic engulfment of filamentous A[l by microglia and its eventual compaction into harmless dense core plaques. Here we propose a systematic approach to understand this still nebulous process of microglia-mediated arrest of cognitive decline. First, we will use mouse genetics to investigate the requirement of sequential involvement of TREM2, followed by AXL and likely subsequently by MERTK in microglia-mediated arrest of cognitive decline in mouse models of AD through behavioral tests and electrophysiological assessment of learning and memory. Second, we will correlate these genetic epistasis-associated functional changes in learning and memory to corresponding transcriptional state of microglia as assessed by single nucleus RNA sequencing. Our third aim is to evaluate cellular, subcellular, morphological and neuronal network level brain functional changes, including AD neuropathological hallmarks such as amyloid plaques and tau phosphorylation, as well as microglial functions such as phagocytosis and/or plaque barrier formation. We hypothesize that a TREM2, AXL and MERTK triad functions sequentially to engineer a beneficial microglia state, which in turn counters AD-associated ill-effects that manifest as cognitive decline. Therefore, augmenting the function of this triad would restrain cognitive decline and preserve brain health in AD. Our study could lead to the development of multivalent engagement of microglial molecules TREM2, AXL and MERTK, for novel therapeutics in AD.