DNA methylation changes associated with Parkinson’s disease progression: outcomes from the first longitudinal genome-wide methylation analysis in blood

Henderson-Smith, Adrienne; Fisch, Kathleen M.; Jiang, Hua; Liu, Ganqiang; Ricciardelli, Eugenia; Jepsen, Kristen; Huentelman, Mathew; Stalberg, Gabriel; Edland, Steven D.; Scherzer, Clemens R.; Dunckley, Travis; Desplats, Paula

doi:10.1080/15592294.2019.1588682

Cited by 66 publications

(116 citation statements)

References 49 publications

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“…To further explore the significance of identified human DNMT1-dependent genes, we evaluated the recent literature on potential blood biomarkers in Parkinson's disease (PD) patients. Encouragingly, we observed five differentially methylated genes in these studies within our conserved human regions [29,75]. They are COL9A2, SCNN1A, AMICA1, SLC16A3, and DLK1.…”

Section: Five Dnmt1-dependent Genes Are Represented In Genes For Potementioning

confidence: 62%

“…They are COL9A2, SCNN1A, AMICA1, SLC16A3, and DLK1. One of these genes, COL9A2, was also found to be differentially expressed in our rotenone treated cells [29] (described below). Given that candidate PD biomarkers and our DNMT1-dependent genes were selected by differing criteria, we consider five overlapping genomic regions to be promising toward our hypothesis.…”

Section: Five Dnmt1-dependent Genes Are Represented In Genes For Potementioning

confidence: 70%

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The conserved DNMT1-dependent methylation regions in human cells are vulnerable to neurotoxicant rotenone exposure

Freeman

Lou

et al. 2020

Epigenetics & Chromatin

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Background: Allele-specific DNA methylation (ASM) describes genomic loci that maintain CpG methylation at only one inherited allele rather than having coordinated methylation across both alleles. The most prominent of these regions are germline ASMs (gASMs) that control the expression of imprinted genes in a parent of origin-dependent manner and are associated with disease. However, our recent report reveals numerous ASMs at non-imprinted genes. These non-germline ASMs are dependent on DNA methyltransferase 1 (DNMT1) and strikingly show the feature of random, switchable monoallelic methylation patterns in the mouse genome. The significance of these ASMs to human health has not been explored. Due to their shared allelicity with gASMs, herein, we propose that non-traditional ASMs are sensitive to exposures in association with human disease. Results:We first explore their conservancy in the human genome. Our data show that our putative non-germline ASMs were in conserved regions of the human genome and located adjacent to genes vital for neuronal development and maturation. We next tested the hypothesized vulnerability of these regions by exposing human embryonic kidney cell HEK293 with the neurotoxicant rotenone for 24 h. Indeed,14 genes adjacent to our identified regions were differentially expressed from RNA-sequencing. We analyzed the base-resolution methylation patterns of the predicted non-germline ASMs at two neurological genes, HCN2 and NEFM, with potential to increase the risk of neurodegeneration. Both regions were significantly hypomethylated in response to rotenone. Conclusions:Our data indicate that non-germline ASMs seem conserved between mouse and human genomes, overlap important regulatory factor binding motifs, and regulate the expression of genes vital to neuronal function. These results support the notion that ASMs are sensitive to environmental factors such as rotenone and may alter the risk of neurological disease later in life by disrupting neuronal development.

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Section: Five Dnmt1-dependent Genes Are Represented In Genes For Potementioning

confidence: 62%

Section: Five Dnmt1-dependent Genes Are Represented In Genes For Potementioning

confidence: 70%

The conserved DNMT1-dependent methylation regions in human cells are vulnerable to neurotoxicant rotenone exposure

Freeman

Lou

et al. 2020

Epigenetics & Chromatin

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“…Clinical features of PD such as the delayed age of disease onset, low concordance rate (11%) between monozygotic twins 2, 3 , symptomatic fluctuations over disease course, including a unilateral to bilateral symptom presentation in most individuals (85%) 4,5 , and prominent sex differences in disease risk 6,7 , collectively suggest the contribution of the modifiable epigenome to disease origins and progression [8][9][10] . Although recent candidate-gene and array-based studies support that epigenetic abnormalities occur in PD tissues [10][11][12][13][14] , thus far, the epigenomes of PD patients remain largely unexplored and there has yet to be an epigenetic study of neurons from the PD brain.…”

Section: Introductionmentioning

confidence: 99%

“…The conversion of DNA methylation to hydroxymethylation (and eventual demethylation) is catalyzed by ten-eleven translocation (TET) enzymes, which have also been shown to impact neurodevelopment and synaptic transmission 18,[23][24][25] . Despite their roles in healthy neuronal functions, there have been relatively few genome-wide studies of DNA methylation in the PD brain [11][12][13] . These have focused on bulk brain tissue with a heterogeneous mixture of neurons and glial cells, using platforms that examine primarily CpG sites within coding regions (exons) and CpG islands [11][12][13] .…”

Section: Introductionmentioning

confidence: 99%

“…Despite their roles in healthy neuronal functions, there have been relatively few genome-wide studies of DNA methylation in the PD brain [11][12][13] . These have focused on bulk brain tissue with a heterogeneous mixture of neurons and glial cells, using platforms that examine primarily CpG sites within coding regions (exons) and CpG islands [11][12][13] . However, it is now established that DNA modification profiles strongly diverge between neurons and glial cell types, and a large proportion of DNA methylation in neurons occurs at non-CpG (CpH) sites 18,26,27 .…”

Section: Introductionmentioning

confidence: 99%

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Epigenomic analysis of Parkinson’s disease neurons identifies Tet2 loss as neuroprotective

Marshall¹,

Bryan²,

Li³

et al. 2019

Preprint

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PD pathogenesis may involve the epigenetic control of enhancers that modify neuronal functions. Here, we comprehensively profile DNA methylation at enhancers, genome-wide, in neurons of 57 PD patients and 48 control individuals. We found a widespread increase in cytosine modifications at enhancers in PD neurons, which is partly explained by elevated hydroxymethylation levels. Epigenetic dysregulation of enhancers in PD converge on transcriptional abnormalities affecting neuronal signaling and immune activation pathways. In particular, PD patients exhibit an epigenetic and transcriptional upregulation of TET2, a masterregulator of cytosine modification status. TET2 inactivation in a neuronal cell line results in cytosine modification changes that are reciprocal to those observed in PD neurons.Furthermore, Tet2 inactivation in mice fully prevents dopaminergic neuronal loss in the substantia nigra induced by prior inflammation. Tet2 loss in mice also attenuates transcriptional immune responses to an inflammatory trigger. Thus, widespread epigenetic dysregulation of enhancers in PD neurons may, in part, be mediated by increased TET2 expression. Decreased Tet2 activity is neuroprotective, in vivo, and may be a novel therapeutic target for PD.

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DNA Methylation Age Acceleration as a Potential Biomarker for Early Onset of Rapid Eye Movement Sleep Behavior Disorder

Senkevich,

Pelletier,

Sato

et al. 2023

Annals of Neurology

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REM sleep behavior disorder (RBD) is the strongest prodromal marker for α‐synucleinopathies. The Horvath DNA‐methylation‐age (DNAm‐age) is an epigenetic clock reflecting biological aging. We found an association of DNAm‐age‐acceleration with RBD age‐at‐onset at baseline (N=162; B=‐0.68; SE=0.12; P=2.59e‐08) and follow‐up (N=45; B=‐1.07; SE=0.21; P=9.73e‐06). The result remains similar after accounting for genetic risk‐factors (e.g., RBD polygenic risk score). On average, RBD patients with faster vs slow/normal epigenetic aging had a 5.2‐year earlier phenoconversion, and the cox‐regression analysis revealed a trend towards significance (N=53; HR=1.05 (0.99–1.11); P=0.06). Our findings suggest that DNAm‐age‐acceleration is a potential biomarker for earlier RBD onset.This article is protected by copyright. All rights reserved.

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DNA methylation changes associated with Parkinson’s disease progression: outcomes from the first longitudinal genome-wide methylation analysis in blood

Cited by 66 publications

References 49 publications

The conserved DNMT1-dependent methylation regions in human cells are vulnerable to neurotoxicant rotenone exposure

The conserved DNMT1-dependent methylation regions in human cells are vulnerable to neurotoxicant rotenone exposure

Epigenomic analysis of Parkinson’s disease neurons identifies Tet2 loss as neuroprotective

DNA Methylation Age Acceleration as a Potential Biomarker for Early Onset of Rapid Eye Movement Sleep Behavior Disorder

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