We hypothesize that amyloid ?-protein (A?) assembly into neurotoxic oligomers and polymers is a seminal neuropathogenetic process in Alzheimer's disease (AD). If so, assembly inhibition or dissociation of existing assemblies could be effective therapeutic approaches. To test our hypothesis, the structural biology of A? must be elucidated in detail. What conformers form oligomers? By what mechanism? What are the structures of the oligomers thus formed? What is the relative toxicity of each oligomer species? Many, including ourselves, have striven to correlate structure with measures of biological activity. Recent work has suggested that dimeric or trimeric assemblies are important neurotoxins, but hexameric, nonameric, dodecameric, and larger oligomers also have been shown to be potent neurotoxins. The long-term goal of this proposal is to move past simple quaternary structure determination to elucidation of A? monomer secondary and tertiary structure dynamics and the determination of mechanisms of monomer oligomerization. This means eventually understanding the interatomic interactions that control the dynamics, and in doing so, identifying therapeutic targets at atomic resolution. This """"""""knowledge-based"""""""" approach is distinct from, but complementary to, high-throughput screening strategies. Both approaches should be executed to maximize the chances for identifying efficacious, disease-modifying therapeutic agents. We propose here to: (1) elucidate the physical biochemistry of A? monomer folding and self-assembly;and (2) establish structure-neurotoxicity relationships of the A? assemblies thus formed. To do so, we will chemically synthesize A? peptides in which specific amino acids and chemical bonds are altered and then study the conformational dynamics and assembly of these peptides. The positions of these alterations, and the alterations themselves, have been chosen carefully so as to reveal the key structural features of the A? molecule that control its assembly into structures that damage or kill neurons. We will identify, isolate, and structurally characterize specific types of assemblies and then determine quantitatively the toxic activity of each assembly by treating primary neurons in culture. The depth of understanding of the structures of the assemblies obtained in the first aim will be unprecedented. Thus the knowledge gained through this """"""""structure-activity correlation"""""""" process is expected to provide the most accurate assessment of which assemblies, and which structures (at atomic resolution) on these assemblies, should be targeted therapeutically. In addition to its contributions to an improved understanding of AD and its treatment, results of the proposed project should have relevance for studies of other neurodegenerative diseases linked to aberrant protein assembly. These include Parkinson's, Huntington's, amyotrophic lateral sclerosis, familial amyloid polyneuropathy, and the prionoses.

Public Health Relevance

This project will advance our understanding of how a protein, the amyloid-protein, causes Alzheimers disease. This understanding can be translated directly into the development of a new class of drugs that have the potential to modify or cure the disease. The project also will be of relevance to Parkinsons, Huntingtons, amyotrophic lateral sclerosis, familial amyloid polyneuropathy, the prionoses, and other neurodegenerative diseases of aging.

Agency
National Institute of Health (NIH)
Institute
National Institute of Neurological Disorders and Stroke (NINDS)
Type
Research Project (R01)
Project #
5R01NS038328-11
Application #
8233417
Study Section
Special Emphasis Panel (ZRG1-MDCN-C (02))
Program Officer
Corriveau, Roderick A
Project Start
1998-12-10
Project End
2015-02-28
Budget Start
2012-03-01
Budget End
2013-02-28
Support Year
11
Fiscal Year
2012
Total Cost
$330,138
Indirect Cost
$115,763
Name
University of California Los Angeles
Department
Neurology
Type
Schools of Medicine
DUNS #
092530369
City
Los Angeles
State
CA
Country
United States
Zip Code
90095
Yu, Xinke; Hayden, Eric Y; Xia, Ming et al. (2018) Surface enhanced Raman spectroscopy distinguishes amyloid ?-protein isoforms and conformational states. Protein Sci 27:1427-1438
Hayden, Eric Y; Conovaloff, Joseph L; Mason, Ashley et al. (2017) Preparation of pure populations of covalently stabilized amyloid ?-protein oligomers of specific sizes. Anal Biochem 518:78-85
Yamin, Ghiam; Teplow, David B (2017) Pittsburgh Compound-B (PiB) binds amyloid ?-protein protofibrils. J Neurochem 140:210-215
Do, Thanh D; LaPointe, Nichole E; Nelson, Rebecca et al. (2016) Amyloid ?-Protein C-Terminal Fragments: Formation of Cylindrins and ?-Barrels. J Am Chem Soc 138:549-57
Yamin, Ghiam; Coppola, Giovanni; Teplow, David B (2016) Design, Characterization, and Use of a Novel Amyloid ?-Protein Control for Assembly, Neurotoxicity, and Gene Expression Studies. Biochemistry 55:5049-60
Kim, Bongkeun; Do, Thanh D; Hayden, Eric Y et al. (2016) Aggregation of Chameleon Peptides: Implications of ?-Helicity in Fibril Formation. J Phys Chem B 120:5874-83
Bilousova, Tina; Miller, Carol A; Poon, Wayne W et al. (2016) Synaptic Amyloid-? Oligomers Precede p-Tau and Differentiate High Pathology Control Cases. Am J Pathol 186:185-98
Hayden, Eric Y; Yamin, Ghiam; Beroukhim, Shiela et al. (2015) Inhibiting amyloid ?-protein assembly: Size-activity relationships among grape seed-derived polyphenols. J Neurochem 135:416-30
Yamin, Ghiam; Huynh, Tien-Phat Vuong; Teplow, David B (2015) Design and Characterization of Chemically Stabilized A?42 Oligomers. Biochemistry 54:5315-21
Roychaudhuri, Robin; Zheng, Xueyun; Lomakin, Aleksey et al. (2015) Role of Species-Specific Primary Structure Differences in A?42 Assembly and Neurotoxicity. ACS Chem Neurosci 6:1941-55

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