Our central goal is to determine neuroprotective mechanism conferred by microglia and autophagy, and understand how dysfunctional autophagy in microglia contributes to the pathogenesis of Alzheimer's disease (AD). Emerging evidence from human genetic and pathological studies has demonstrated the significance of microglia pathophysiology in the pathogenesis of AD. Microglia are the resident innate immune cells in the brain. The exact role for microglia in AD pathogenesis, however, remains poorly understood. Multiple lines of studies revealed the protective function of microglia that restrain the toxic accumulation of β-amyloid and prevent disease progression. However, evidence also exists suggesting excessive microglial activation can harm the neurons by releasing inflammatory factors and engulfing neuronal synapses. Microglia may phagocytose Aβ, the main component of plaques as a hallmark of AD pathology; single-cell RNAseq analysis showed the disease-associated microglia (DAM), which localizes at plaques in AD animal models, consistent with a role of TREM2 as a critical regulator of DAM activation. Autophagy is a lysosome clearance pathway that plays an important role in maintaining homeostasis under metabolic stress and neuroprotection. Little is known about glial autophagy. Previous studies from peripheral immune cells demonstrate a significant role of autophagy in immunity and inflammation. Whether microglial autophagy plays such a role, however, remains poorly understood. We recently analyzed AD mouse model and observed the activation of microglial autophagy. We found that DAM is associated with a robust increase of autophagic activity. We also showed that inactivation of microglial autophagy causes reduced number of microglia associated with Aβ plagues and enhanced neurotoxicity in AD models, which phenocopied the effect of the loss of Trem2 in AD models. Therefore, our overall hypothesis is that autophagy activation is required for DAM metabolic fitness to degrade Aβ and protect neurons in the AD brains. We also hypothesize that microglial autophagy controls inflammation by selective degradation of inflammasomes via protein receptors that are neuroprotective in AD. Our specific aims are to (1) determine the role for microglial autophagy in neuroprotection by clearing phagocytosed Aβ and maintaining metabolic fitness in AD mouse models; (2) dissect the mechanism of microglial autophagy that controls inflammation in AD mouse model; (3) determine that autophagy is an integral part of TREM2-mediated neuroprotection mechanism in microglia of AD mouse model.