Novel tricyclic pyrone compounds prevent intracellular APP C99-induced cell death.

Abstract

Alzheimer's disease (AD) is an age-related neurodegenerative disorder characterized by the progressive and global loss of cognitive functions. Pathological features include a loss of neurons in vulnerable brain regions and the extracellular deposition of abnormal protein aggregates known as amyloid plaques. Amyloid-beta protein (A beta is the major component of amyloid plaques and is derived from a larger transmembrane glycoprotein, termed amyloid beta protein precursor (APP), by proteolysis. The AD research has focused on A beta production and metabolism, its extracellular deposition, and its cellular toxicity. Recent evidence, however, suggests that A beta as well as the C-terminal fragments (CTF) of APP can accumulate intraneuronally. The neuronal loss and synaptic transmission deficit in AD may therefore depend on intraneuronal accumulation of A beta/CTF rather than on extracellular plaque formation. Accordingly, we propose that one of the primary targets of therapeutic intervention should be intracellular A beta/CTF and its toxic cellular effect. We have established a cell-culture model in which the neurons degenerate on induction of endogenous expression of A beta/CTF of APP. These cultures have been used to test whether tricyclic pyrone (TP) compounds may prevent A beta/CTF-mediated neuronal death. The results to date have been encouraging. Lead compounds will now be selected for their abilities to ameliorate A beta/CTF-mediated pathology in transgenic mice. Our hope is that these compounds may eventually prove beneficial for the prevention and treatment of AD.