[HTML][HTML] Genome-wide DNA methylation analysis of systemic lupus erythematosus reveals persistent hypomethylation of interferon genes and compositional changes …

DM Absher, X Li, LL Waite, A Gibson, K Roberts… - PLoS …, 2013 - journals.plos.org
DM Absher, X Li, LL Waite, A Gibson, K Roberts, J Edberg, WW Chatham, RP Kimberly
PLoS genetics, 2013journals.plos.org
Systemic lupus erythematosus (SLE) is an autoimmune disease with known genetic,
epigenetic, and environmental risk factors. To assess the role of DNA methylation in SLE, we
collected CD4+ T-cells, CD19+ B-cells, and CD14+ monocytes from 49 SLE patients and 58
controls, and performed genome-wide DNA methylation analysis with Illumina
Methylation450 microarrays. We identified 166 CpGs in B-cells, 97 CpGs in monocytes, and
1,033 CpGs in T-cells with highly significant changes in DNA methylation levels (p< 1× 10 …
Systemic lupus erythematosus (SLE) is an autoimmune disease with known genetic, epigenetic, and environmental risk factors. To assess the role of DNA methylation in SLE, we collected CD4+ T-cells, CD19+ B-cells, and CD14+ monocytes from 49 SLE patients and 58 controls, and performed genome-wide DNA methylation analysis with Illumina Methylation450 microarrays. We identified 166 CpGs in B-cells, 97 CpGs in monocytes, and 1,033 CpGs in T-cells with highly significant changes in DNA methylation levels (p<1×10−8) among SLE patients. Common to all three cell-types were widespread and severe hypomethylation events near genes involved in interferon signaling (type I). These interferon-related changes were apparent in patients collected during active and quiescent stages of the disease, suggesting that epigenetically-mediated hypersensitivity to interferon persists beyond acute stages of the disease and is independent of circulating interferon levels. This interferon hypersensitivity was apparent in memory, naļve and regulatory T-cells, suggesting that this epigenetic state in lupus patients is established in progenitor cell populations. We also identified a widespread, but lower amplitude shift in methylation in CD4+ T-cells (>16,000 CpGs at FDR<1%) near genes involved in cell division and MAPK signaling. These cell type-specific effects are consistent with disease-specific changes in the composition of the CD4+ population and suggest that shifts in the proportion of CD4+ subtypes can be monitored at CpGs with subtype-specific DNA methylation patterns.
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