Amyloid-beta precursor protein contributes to brain aging and learning decline

Abstract

Abstract Brain aging is a key risk factor for many neurodegenerative diseases, yet its molecular and cellular mechanisms remain elusive. Amyloid-beta precursor protein (APP) is among the most studied proteins linked to brain pathology; however, its role in non-pathological brain aging remains poorly characterized. Here, we investigate the natural impact of APP on normal brain aging using the short-lived turquoise killifish ( Nothobranchius furzeri ), which exhibits rapid and spontaneous age-related decline. We found that a pyroglutamated APP derivative (APP pE11 ) accumulates intra-neuronally in an age-dependent manner, co-localizing with a marker of cell death. We found that intraneuronal APP pE11 is also present in brains from healthy elderly humans, suggesting deep evolutionary conservation. To determine APP’s role in spontaneous brain aging, we knock-out “amyloid precursor protein a” ( appa ) in killifish via CRISPR/Cas9. The lack of appa mitigated brain aging from a proteome-wide perspective, reduced age-related cell death and inflammation, and improved neuronal activity and learning capacity in aged individuals. Our findings show an ancestral and previously unrecognized role of amyloid-beta precursor protein in non-pathological brain aging, making it an ideal target for anti-aging interventions.