Site-specific decreases in DNA methylation in replicating cells following exposure to oxidative stress

Site-specific decreases in DNA methylation in replicating cells following exposure to oxidative stress

Oxidative stress is a common feature of inflammation-driven cancers, and it promotes genomic instability and aggressive tumour phenotypes. It is known that oxidative stress transiently modulates gene expression through the oxidation of transcription factors and associated regulatory proteins. Neutro...

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Bibliographic Details
Published in:Human molecular genetics Vol. 32; no. 4; pp. 632 - 648
Main Authors: Seddon, Annika R, Das, Andrew B, Hampton, Mark B, Stevens, Aaron J
Format: Journal Article
Language:English
Published: England Oxford University Press 27-01-2023
Subjects:
CpG Islands - genetics
DNA Methylation - genetics
Epigenesis, Genetic
Oligonucleotide Array Sequence Analysis
Original
Oxidation-Reduction
Oxidative Stress - genetics
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Summary:Oxidative stress is a common feature of inflammation-driven cancers, and it promotes genomic instability and aggressive tumour phenotypes. It is known that oxidative stress transiently modulates gene expression through the oxidation of transcription factors and associated regulatory proteins. Neutrophils are our most abundant white blood cells and accumulate at sites of infection and inflammation. Activated neutrophils produce hypochlorous acid and chloramines, which can disrupt DNA methylation by oxidizing methionine. The goal of the current study was to determine whether chloramine exposure results in sequence-specific modifications in DNA methylation that enable long-term alterations in transcriptional output. Proliferating Jurkat T-lymphoma cells were exposed to sublethal doses of glycine chloramine and differential methylation patterns were compared using Illumina EPIC 850 K bead chip arrays. There was a substantial genome-wide decrease in methylation 4 h after exposure that correlated with altered RNA expression for 24 and 48 h, indicating sustained impacts on exposed cells. A large proportion of the most significant differentially methylated CpG sites were situated towards chromosomal ends, suggesting that these regions are most susceptible to inhibition of maintenance DNA methylation. This may contribute to epigenetic instability of chromosomal ends in rapidly dividing cells, with potential implications for the regulation of telomere length and cellular longevity.
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ISSN:0964-6906
1460-2083
DOI:10.1093/hmg/ddac232