Enhancing microglial antioxidant capacity via the ascorbate transporter SVCT2 delays onset and modifies disease progression in mouse models of Alzheimer's disease.

Despite clear evidence that vitamin C levels are depleted in the brains of Alzheimer's disease (AD) patients, dietary supplementation has consistently failed in clinical trials, suggesting a critical bottleneck not in systemic supply, but in its transport into brain cells. Here, we identify this bottleneck as a progressive downregulation of the ascorbate transporter, Slc23a2, also known as SVCT2, in microglia. Then we hypothesized that bypassing this cellular deficiency via targeted SVCT2 overexpression in microglia could either prevent the onset of pathology or rescue established functional deficits. Indeed, overexpressing SVCT2 in microglia before disease onset in 5xFAD mice triggered a profound redox reprogramming, resulting in a unique "hybrid" neuroprotective microglial phenotype that co-expressed both homeostatic and disease-associated markers. Functionally, this leads to decreased amyloid plaque burden and strengthens the synaptic bioenergetic capacity, which consequently prevents the development of synaptic and memory deficits. Strikingly, when employed after disease establishment, SVCT2 overexpression rescued synaptic plasticity and memory performance despite not affecting the existing amyloid burden. This rescue was driven by changes in the microglial secretory pathways. Collectively, these findings resolve a long-standing clinical paradox by establishing that neuroprotection depends not on systemic vitamin C intake but on the brain's cellular uptake machinery. This offers a mechanistic explanation for the failure of dietary supplementation in AD and identifies SVCT2 as a promising therapeutic target against the neurodegenerative process in AD.