Lead (Pb) exposure and its effect on APP proteolysis and Aβ aggregation

Alzheimer's disease (AD) is a progressive neurodegenerative disorder with clinical manifestations appearing in old age, however, the initial stages of this disease may begin early in life. AD is characterized by the presence of excessive deposits of aggregated β‐amyloid (Aβ) peptides, which are derived from the β‐amyloid precursor protein (APP) following processing by β‐secretase and γ‐secretase. Recently, we have reported that developmental exposure of rats to Pb resulted in latent elevation of APP mRNA, APP, and Aβ in old age. Here we examined whether latent up‐regulation in APP expression and Aβ levels is exacerbated by concurrent disturbances in APP processing or Aβ aggregation. Among the environmental metals tested, only Aβ solutions containing Pb promoted the formation of Aβ aggregates at nanomolar concentrations. The lifetime profiles of α‐, β‐, and γ‐secretases remained constant in adult and aging animals, and developmental exposure to Pb did not alter them. Furthermore, the addition of various concentrations of Pb (0.1 to 50 µM) to cerebral cortical extracts derived from control animals also did not affect the proteolytic activities of these enzymes. Therefore, we propose that amyloidogenesis is promoted by a latent response to developmental reprogramming of the expression of the APP gene by early exposure to Pb, as well as enhancement of Aβ aggregation in old age. In rodents, these events occur without Pb‐induced disturbances to the enzymatic processing of APP. The aforementioned results provide further evidence for the developmental basis of amyloidogenesis and late‐life disturbances in AD‐associated proteins by environmental agents.