Physical Biochemistry and Biology of Amyloid Beta-Protein
University Of California Los Angeles, Los Angeles CA
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Abstract
DESCRIPTION (provided by applicant): Alzheimer's disease (AD) is a devastating disease of the aged. Two amyloid-forming proteins are associated with AD, the amyloidß-protein (Aß) and tau. Recent evidence supports an hypothesis, the amyloid cascade hypothesis, that posits that Aß oligomers are the seminal neuropathogenetic agents in AD. The overall goal of this proposal is to understand the structural biology of Aß, and fragments thereof, and to establish formal structure-activity relationships. In the long run, we seek to obtain an atomic-resolution determination of the structure of the proximate neurotoxins formed by Aß, and in doing so, enable the development, for the first time, of disease-modifying AD treatments. A multidisciplinary strategy, employing complementary experimental and computational approaches, will be employed. This strategy has been used very successfully in the past, providing novel insights into the Aß system. Three specific aims are proposed that systematically and logically progress from in vitro biophysical studies of Aß and its oligomeric assemblies (Aim 1), to in vitro and in vivo studies of the biological activity of selected such assemblies (Aim 2), to determination of the effects of selected assemblies on differential gene expression in neurons (Aim 3). Taken together, these studies will provide the theoretical and experimental foundation for subsequent therapeutic compound development and clinical testing in humans. Aim 1. To determine the structural dynamics of Aß and tau assembly. a. To use scanning Tyr mutagenesis to elucidate mechanisms of Aß oligomerization. b. To determine the dynamics of intramolecular turn formation and its effects on Aß assembly. c. To determine the effects of primary structure changes on the conformations and assembly dynamics of biologically relevant and theoretically important Aß peptides. Aim 2. To determine the biological effects of Aß assemblies. a. To determine the cytotoxic effects of Aß assemblies on cultured neuronal cell lines and primary neurons. b. To determine the effects of Aß assemblies on Drosophila eye development, locomotion, and longevity. Aim 3. To identify and validate AD-relevant genes using a bioinformatics approach that considers Aß assembly structure, neuron type, and neuron senescence.
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