Acetylcholinesterase (AChE), an important component of cholinergic synapses, colocalizes with amyloid-beta peptide (A beta) deposits of Alzheimer's brain. We report here that bovine brain AChE, as well as the human and mouse recombinant enzyme, accelerates amyloid formation from wild-type A beta and a mutant A beta peptide, which alone produces few amyloid-like fibrils. The action of AChE was independent of the subunit array of the enzyme, was not affected by edrophonium, an active site inhibitor, but it was affected by propidium, a peripheral anionic binding site ligand. Butyrylcholinesterase, an enzyme that lacks the peripheral site, did not affect amyloid formation. Furthermore, AChE is a potent amyloid-promoting factor when compared with other A beta-associated proteins. Thus, in addition to its role in cholinergic synapses, AChE may function by accelerating A beta formation and could play a role during amyloid deposition in Alzheimer's brain.
ChileAlzheimer's disease (AD) is a progressive neurodegenerative disorder, which is probably caused by the cytotoxic effect of the amyloid b-peptide (Ab). We report here molecular changes induced by Ab, both in neuronal cells in culture and in rats injected in the dorsal hippocampus with preformed Ab fibrils, as an in vivo model of the disease. Results indicate that in both systems, Ab neurotoxicity resulted in the destabilization of endogenous levels of b-catenin, a key transducer of the Wnt signaling pathway. Lithium chloride, which mimics Wnt signaling by inhibiting glycogen synthase kinase-3b promoted the survival of post-mitotic neurons against Ab neurotoxicity and recovered cytosolic b-catenin to control levels. Moreover, the neurotoxic effect of Ab fibrils was also modulated with protein kinase C agonists/inhibitors and reversed with conditioned medium containing the Wnt-3a ligand. We also examined the spatial memory performance of rats injected with preformed Ab fibrils in the Morris water maze paradigm, and found that chronic lithium treatment protected neurodegeneration by rescuing b-catenin levels and improved the deficit in spatial learning induced by Ab. Our results are consistent with the idea that Ab-dependent neurotoxicity induces a loss of function of Wnt signaling components and indicate that lithium or compounds that mimic this signaling cascade may be putative candidates for therapeutic intervention in Alzheimer's patients.
Brain acetylcholinesterase (AChE) forms stable complexes with amyloid- peptide (A) during its assembly into filaments, in agreement with its colocalization with the A deposits of Alzheimer's brain. The association of the enzyme with nascent A aggregates occurs as early as after 30 min of incubation. Analysis of the catalytic activity of the AChE incorporated into these complexes shows an anomalous behavior reminiscent of the AChE associated with senile plaques, which includes a resistance to low pH, high substrate concentrations, and lower sensitivity to AChE inhibitors. Furthermore, the toxicity of the AChE-amyloid complexes is higher than that of the A aggregates alone. Thus, in addition to its possible role as a heterogeneous nucleator during amyloid formation, AChE, by forming such stable complexes, may increase the neurotoxicity of A fibrils and thus may determine the selective neuronal loss observed in Alzheimer's brain.
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