Abstract
Systemic lupus erythematosus (SLE) is a chronic, multisystem, autoimmune inflammatory disease with genomic and non-genomic contributions to risk. We hypothesize that epigenetic factors are a significant contributor to SLE risk and may be informative for identifying pathogenic mechanisms and therapeutic targets. To test this hypothesis while controlling for genetic background, we performed an epigenome-wide analysis of DNA methylation in genomic DNA from whole blood in three pairs of female monozygotic (MZ) twins of European ancestry, discordant for SLE. Results were replicated on the same array in four cell types from a set of four Danish female MZ twin pairs discordant for SLE. Genes implicated by the epigenetic analyses were then evaluated in 10 independent SLE gene expression datasets from the Gene Expression Omnibus (GEO). There were 59 differentially methylated loci between unaffected and affected MZ twins in whole blood, including 11 novel loci. All but two of these loci were hypomethylated in the SLE twins relative to the unaffected twins. The genes harboring these hypomethylated loci exhibited increased expression in multiple independent datasets of SLE patients. This pattern was largely consistent regardless of disease activity, cell type, or renal tissue type. The genes proximal to CpGs exhibiting differential methylation (DM) in the SLE-discordant MZ twins and exhibiting differential expression (DE) in independent SLE GEO cohorts (DM-DE genes) clustered into two pathways: the nucleic acid-sensing pathway and the type I interferon pathway. The DM-DE genes were also informatically queried for potential gene–drug interactions, yielding a list of 41 drugs including a known SLE therapy. The DM-DE genes delineate two important biologic pathways that are not only reflective of the heterogeneity of SLE but may also correlate with distinct IFN responses that depend on the source, type, and location of nucleic acid molecules and the activated receptors in individual patients. Cell- and tissue-specific analyses will be critical to the understanding of genetic factors dysregulating the nucleic acid-sensing and IFN pathways and whether these factors could be appropriate targets for therapeutic intervention.
Highlights
Systemic lupus erythematosus (SLE) is a chronic and severe systemic autoimmune disease characterized by the over-production of autoantibodies and heterogeneous clinical manifestations
The Lupus Family Registry and Repository (LFRR) MZ twins were all females of European ancestry, and the SLE-diagnosed twins exhibited a range of SLE clinical conditions (Supplemental Table S2)
Eleven genes are novel to our study and have not been previously reported as SLE-related in a genome-wide methylation study, five of which are unrelated to the typical interferon signature (LY6G5C, CXCR1, Atonal bHLH transcription factor 8 (ATOH8), calcium voltage-gated channel subunit alpha1 D (CACNA1D), MECOM)
Summary
Systemic lupus erythematosus (SLE) is a chronic and severe systemic autoimmune disease characterized by the over-production of autoantibodies and heterogeneous clinical manifestations. Several studies have investigated DNA methylation in SLE patients on a genome-wide scale. The earliest of these genome-wide studies interrogated 27,578 CpG sites in 12 SLE patients and 12 healthy controls using the Illumina Infinium HumanMethylation Beadchip, and identified 336 differentially methylated genes, the majority of which were hypomethylated in the cases relative to the controls [11]. The primary and consistent finding across all these studies has been hypomethylation of interferon-regulated genes across various cell types in cases, regardless of SLE disease activity [27]
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