The heterogeneous pathologies of Alzheimer's disease and related dementias (ADRD) are still incompletely understood. There is no perfect animal model to study these diseases. Four known aberrantly misfolded proteins are commonly detected via neuropathologic examination of brains with ADRD: A?, Tau, TDP-43, and/or ?-Synuclein. Our preliminary data indicate that there are more pathogenic protein species awaiting identification. Characterization of these proteins may be relevant to the development of both diagnostic and therapeutic strategies for ADRD. The goals of this research project are to identify previously uncharacterized, misfolded, and aberrantly processed proteins in ADRD; to resolve gene variants that modulate the severity and heterogeneity of dementia through the novel misfolded proteins; and, to perform clinical-pathological correlation, focusing on these novel proteins, to identify new disease-associated pathologic biomarkers. We will leverage the resources of the University of Kentucky AD Center (UK-ADC) biobank and the University of Kentucky Proteomics Core Facility, to execute the following Specific Aims:
Specific Aim 1. Analyse detergent-insoluble protein extracts from human amygdala (snap-frozen at autopsy) to investigate whether as yet uncharacterized misfolded proteins are detectable in ADRD. Polypeptides from the detergent-insoluble, urea-soluble protein fractions of amygdala will be interrogated using mass spectrometry. We have on-hand amygdalae from 40 UK-ADC subjects which incorporate a spectrum of clinical and pathologic features. Immunohistochemistry and biochemical studies will be performed to determine the best candidate proteins for additional studies (Aims 2 and 3).
Specific Aim 2. Construct a robust and harmonized database with exonic sequencing to localize genetic regions associated with novel misfolded proteins in ADRD. We will test the association between dementia and rare, exonic (`mis-sense') genetic variants in genes that encode candidate misfolded proteins (Aim 1). Genetics data augmented with rich neuropathologic endophenotypes and longitudinal clinical data will enable insights into novel mechanisms that drive dementia. Large-scale datasets (NACC, ADGC, ADSP) will be aggregated and harmonized to test the genetic drivers of clinical and neuropathology-based endophenotypes focusing on novel candidate genes. Candidate target genes have already been identified.
Specific Aim 3. Establish the clinical-pathologic correlation for the novel misfolded proteinopathies in ADRD. We will test the association between the potential novel proteinopathies (from Aim 1) with cognitive impairment, factoring in known markers A?, tau, ?-Synuclein, and TDP-43, as well as cerebrovascular pathologies. We have 370 samples available for analyses (both sexes) from the UK-ADC, which should be statistically powered to test our hypothesis that the presence and severity of novel misfolding protein pathologies are associated with cognitive impairment.
Alzheimer's disease and related dementias are an enormous public health problem. It is challenging to develop optimal diagnostic or therapeutic strategies because we have not yet identified the full spectrum of misfolded proteins that commonly underlie the clinical state of dementia. Here we plan to perform a study that identifies a list of misfolded proteins in dementia that is more comprehensive than ever before, as a necessary prerequisite for future work aimed at finding cures.
