The Role of Myeloid Cells in Parkinson's Disease
Icahn School Of Medicine At Mount Sinai, New York NY
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Abstract
Parkinsonâs disease (PD) is a progressive, neurodegenerative disorder of aging that affects both motor and cognitive function. Despite more than fifty years of research, no cures exist and the standard of treatment remains unsatisfactory. Genome-Âwide association studies (GWAS) have identified many regions harboring variants associated with PD. The next challenge in translational research is to identify the causal variants underlying the association signals, the affected genes, molecular pathways and their functional consequences. Because genetic variants can mediate effects on higher-Âorder phenotypes through effects on gene expression, the integration of transcriptomics into the study of disease associated variants has already proven to be a useful strategy, and indeed disease associated loci have been shown to be enriched for variants regulating gene expression. We have recently shown that genetic variants that affect gene expression in myeloid cells underlie a substantial fraction of the genetic associations to PD. We have also accumulated compelling data suggesting that many genes involved in autophagy-Âlysosomal pathways and mitochondrial function are differentially expressed in monocytes and in microglia of PD cases compared to controls and in some cases, are genetically regulated by PD-Âassociated genetic variants. Here, in aim 1, we will generate bulk and single cell transcriptome and proteome profiles from 250 peripheral monocytes of early-Âstage PD (with no medication, within 2 years from the onset of the symptoms), mid- to late-Âstage PD, and age-Âmatched controls from a well-Âcharacterized PD cohort. The sample collection and transcriptome profiles will be done longitudinally (at baseline and follow up within 2 years). In aim 2, will characterize the transcriptome of primary microglia from multiple regions of autopsied brains of PD cases and age-Âmatched controls and explore the consequences on the transcriptome of PD susceptibility variants. We will conduct state-Âof-Âthe-Âart analyses that will integrate multi-Âomic and clinical data sets to generate patient derived, data-Âdriven, multi-Âscale models of disease, enabling the generation of hypotheses around protein interactions specific to disease states and subgroups. In aim 3, we will functionally characterize monocytes and microglia in order to investigate the effects that gene expression, protein abundance and network connectivity changes may have on immune functions of interest such as: 1) phagocytic capacity;; 2) lysosomal function;; and 3) mitochondrial activity. This project will have a large overall impact by: 1) providing key information bridging PD genetics to molecular mechanisms in monocytes and microglia, setting the stage for future mechanistic studies;; and (2) generating large-Âscale, multi-Âomic datasets, together with systems level analyses of these datasets in innate immune cells, which is an urgently needed resource.
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