A unique neurogenic niche in the adult hippocampus hosts neural-lineage stem cells (NSCs) that generate new neurons in a wide range of adult mammals. This process of adult neurogenesis is essential for optimal hippocampal cognitive-emotional function and suggests an avenue for regenerating tissue in the adult brain. However, adult neurogenesis is sensitive to local niche signals, and depending on local signaling, it can fluctuate dramatically in quantity and net contribution to hippocampal function. Better understanding of the key regulatory components of stem cell-niche interactions is critically needed to advance efforts to support hippocampal function and repair. A major niche signal known to modulate adult neurogenesis in both healthy and diseased or injured states is the neurotransmitter glutamate. Excess glutamate stimulation is common in injuries and illnesses that differentially impact the hippocampus, including trauma, stroke, seizure, and neurodegeneration. Our objective in this application is to examine the mechanisms by which the excitatory neurotransmitter glutamate stimulates adult neurogenesis. Previous work on glutamatergic regulation of adult neurogenesis focuses on the role of glutamate receptor stimulation. Our preliminary data, in contrast, suggest an unexpected role for glutamate transporters from the excitatory amino acid transporter (EAAT) family in glutamate-induced stimulation of NSC proliferation. NSCs are widely known to express large quantities of EAATs yet their functional role has received little attention. The proposed experiments will investigate the central hypothesis that glutamate transport through EAAT1 promotes NSC activation and subsequent neurogenesis via cell depolarization. In Aim 1, we will use novel in vivo knockdown models to test the working hypothesis that NSC EAAT1 facilitates NSC proliferation and thereby stimulates adult neurogenesis. In Aim 2, we will use chemogenetic manipulation of NSC membrane potential and electrophysiology to test the working hypothesis that depolarization via EAAT1 drives NSC activation. These results of the proposed studies are expected to have a positive impact because they will introduce a novel molecular mechanism by which a major niche signal—glutamate—contributes to neurogenesis in the adult brain. The expected findings will have relevance both to fundamental understanding of hippocampal homeostasis and to design of therapeutic approaches that seek to capitalize on NSCs to support tissue repair.