Functional methylome analysis of human diabetic kidney disease
Jihwan Park, … , Matthew Palmer, Katalin Susztak
Jihwan Park, … , Matthew Palmer, Katalin Susztak
Published June 6, 2019
Citation Information: JCI Insight. 2019;4(11):e128886. https://doi.org/10.1172/jci.insight.128886.
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Research Article Genetics

Functional methylome analysis of human diabetic kidney disease

Abstract

In patients with diabetes mellitus, poor metabolic control has a long-lasting impact on kidney disease development. Epigenetic changes, including cytosine methylation, have been proposed as potential mediators of the long-lasting effect of adverse metabolic events. Our understanding of the presence and contribution of methylation changes to disease development is limited because of the lack of comprehensive base-resolution methylome information of human kidney tissue samples and site-specific methylation editing. Base resolution, whole-genome bisulfite sequencing methylome maps of human diabetic kidney disease (DKD) tubule samples, and associated gene expression measured by RNA sequencing highlighted widespread methylation changes in DKD. Pathway analysis highlighted coordinated (methylation and gene expression) changes in immune signaling, including tumor necrosis factor alpha (TNF). Changes in TNF methylation correlated with kidney function decline. dCas9-Tet1–based lowering of the cytosine methylation level of the TNF differentially methylated region resulted in an increase in the TNF transcript level, indicating that methylation of this locus plays an important role in controlling TNF expression. Increasing the TNF level in diabetic mice increased disease severity, such as albuminuria. In summary, our results indicate widespread methylation differences in DKD kidneys and highlights epigenetic changes in the TNF locus and its contribution to the development of nephropathy in patients with diabetes mellitus.

Authors

Jihwan Park, Yuting Guan, Xin Sheng, Caroline Gluck, Matthew J. Seasock, A. Ari Hakimi, Chengxiang Qiu, James Pullman, Amit Verma, Hongzhe Li, Matthew Palmer, Katalin Susztak

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Figure 2

Association between DNA methylation and gene expression in human kidney tubules.

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Association between DNA methylation and gene expression in human kidney ...
(A) Heatmap showing relative gene expression of control and DKD samples (yellow/blue); the differential methylation is shown in the first column (red/green). Association between gene expression and promoter DMRs. The genes that contain DMRs in their promoter region (TSS ± 3 kb) were clustered based on gene expression patterns. Each row is 1 DMR/gene and each column is 1 sample. (B) Heatmap showing relative gene expression of control and DKD samples (yellow/blue); the differential methylation is shown in the first column (red/green). Association between gene expression and the enhancer DMRs. Enhancers that are outside of promoter regions were linked to the nearest genes. Genes were clustered based on gene expression patterns. Each row is 1 DMR/gene and each column is 1 sample. (C) The methylation of cg00768487 was associated with interstitial fibrosis, kidney function (eGFR), and CD52 gene expression. (D) Screenshot of UCSC genome browser for the probe shown in C and the target gene CD52. The y axis shows WGBS DNA methylation level (control and DKD) followed by DMR highlight, human kidney H3K27ac ChIP-seq, ChromHMM data, and RNA expression (by RNA sequencing) and ChIA-PET data from K562 and MCF7 cells. ChromHMM color code as shown in A. (E) The expression of Cd52 in mouse kidney cells as identified by single-cell RNA sequencing (28).