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Spatial single-cell analysis of somatic mutation in human brain during aging and neurodegeneration

$1,507,500DP2FY2023AGNIH

Univ Of Massachusetts Med Sch Worcester, Worcester MA

Investigators

Abstract

Alzheimer’s disease and related dementias display an age-related onset, misfolded protein aggregates such as β-amyloid and tau tangles, increased oxidative DNA damage, and ultimately neuron cell death. Mendelian progeroid diseases caused by mutations in DNA repair genes show early-onset neurodegeneration resembling Alzheimer’s, suggesting that compromised genomic integrity can accelerate aging and directly cause neuron loss. DNA damage can be repaired but may result in permanent changes to the genome called somatic mutations, leading to the hypothesis that increased somatic mutation burden may be common across age-related neurodegenerative disorders. Direct support for this hypothesis has remained elusive in the Alzheimer’s disease brain because standard DNA-sequencing experiments are underpowered to characterize somatic mutations that occur in postmitotic human neurons comprehensively. Such experiments are underpowered because a mutation arising in a postmitotic neuron would be unique to only the single cell in which it occurred and thus it would be indistinguishable from background noise when analyzing DNA isolated from millions of brain cells. We recently developed methods to study somatic mutations in human neurons at single-cell resolution, including methods for single-cell, whole genome sequencing (scWGS). We used scWGS to show that permanent somatic mutations accompany aging in human neurons, with specific mutation signatures nominating discrete pathways generating DNA damage in the human brain. Mutation counts and signatures differ in neurons from donors with genetic early-onset neurodegenerative diseases, specifically Cockayne syndrome and Xeroderma Pigmentosum, and in the late-onset sporadic Alzheimer’s donors, suggesting neurodegeneration is associated with specific patterns of somatic mutation. We found no evidence for mutational hotspots in known Alzheimer’s genes such as APOE, PSEN1, PSEN2, or APP, instead finding that somatic mutations in Alzheimer’s neurons represent a stochastic assault on the genome in each cell. The goal of this New Innovator Award proposal is to develop and apply new scWGS methods to study somatic mutations during neurodegeneration in unprecedented detail. We will focus on neurons from late-stage Alzheimer’s disease donors and from donors with late-stage Parkinson’s disease, another age-associated neurodegenerative disorder characterized by increased DNA damage, aggregates of misfolded protein, and neuron cell death. We will focus on those neurons with known pathological hallmarks of these diseases, for example, β-amyloid and tau aggregates, to test the hypothesis that these neurons experience increased DNA damage and thus increased somatic mutations. This work will have broad impacts in the fields of single-cell genomics, aging, neurodegeneration, and human development.

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