Abstract
Although there are no effective therapies to block or reverse Alzheimer's disease (AD) progression at present, a promising therapeutic strategy is to reduce levels of amyloid-β (Aβ) proteins, which drive the formation of amyloid plaque, a primary hallmark in AD brains. Herein, we report that amphiphilic lipid-DNA molecules (LD) were designed by incorporating a long alkyl chain into the nucleotide base. It significantly down-regulated Alzheimer's Aβ levels in vivo and in vitro. In contrast to small-molecule chemical drugs and antibody therapies, the assembled DNA nanoparticles allowed them to effectively cross the blood-brain barrier (BBB) and accumulate in the brain, increasing the therapeutic effects. Notably, lipid-DNA downregulated the levels of Aβ peptides significantly in vitro. AD mice model experiments demonstrated that the LD-treated groups exhibited a rapid cognition behavioral improvement, which was associated with brain engagement of LD and reduced Aβ levels. Thus, the molecularly engineered DNA nanomaterials effectively regulated Aβ peptides. This work might provide a promising DNA engineering strategy for AD treatment.