DNA methyltransferase inhibition restores erythropoietin production in fibrotic murine kidneys
Yu-Ting Chang, … , Yung-Ming Chen, Shuei-Liong Lin
Yu-Ting Chang, … , Yung-Ming Chen, Shuei-Liong Lin
Published January 5, 2016
Citation Information: J Clin Invest. 2016;126(2):721-731. https://doi.org/10.1172/JCI82819.
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Research Article Nephrology

DNA methyltransferase inhibition restores erythropoietin production in fibrotic murine kidneys

Abstract

Renal erythropoietin-producing cells (REPCs) remain in the kidneys of patients with chronic kidney disease, but these cells do not produce sufficient erythropoietin in response to hypoxic stimuli. Treatment with HIF stabilizers rescues erythropoietin production in these cells, but the mechanisms underlying the decreased response of REPCs in fibrotic kidneys to anemic stimulation remain elusive. Here, we show that fibroblast-like FOXD1+ progenitor-derived kidney pericytes, which are characterized by the expression of α1 type I collagen and PDGFRβ, produce erythropoietin through HIF2α regulation but that production is repressed when these cells differentiate into myofibroblasts. DNA methyltransferases and erythropoietin hypermethylation are upregulated in myofibroblasts. Exposure of myofibroblasts to nanomolar concentrations of the demethylating agent 5-azacytidine increased basal expression and hypoxic induction of erythropoietin. Mechanistically, the profibrotic factor TGF-β1 induced hypermethylation and repression of erythropoietin in pericytes; these effects were prevented by 5-azacytidine treatment. These findings shed light on the molecular mechanisms underlying erythropoietin repression in kidney myofibroblasts and demonstrate that clinically relevant, nontoxic doses of 5-azacytidine can restore erythropoietin production and ameliorate anemia in the setting of kidney fibrosis in mice.

Authors

Yu-Ting Chang, Ching-Chin Yang, Szu-Yu Pan, Yu-Hsiang Chou, Fan-Chi Chang, Chun-Fu Lai, Ming-Hsuan Tsai, Huan-Lun Hsu, Ching-Hung Lin, Wen-Chih Chiang, Ming-Shiou Wu, Tzong-Shinn Chu, Yung-Ming Chen, Shuei-Liong Lin

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Figure 3

Myofibroblast transition represses EPO.

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Myofibroblast transition represses EPO. (A) Hematocrit of UUO mice with ...
(A) Hematocrit of UUO mice with or without phlebotomy 1 day before analyses at the indicated time points. n = 10 per group per time point. (B) Expression of Epo and Phd3 in CL and UUO kidneys. n = 10 per group per time point. (C) Expression of Epo, Vegfa, and Phd3 of Col1a1-GFP+PDGFRβ+ pericytes and myofibroblasts isolated from CL kidneys and kidneys 7 days after UUO surgery from Col1a1-GFPTg mice, respectively. n = 4 per cell group. (D) Epo expression of pericytes and myofibroblasts cultured in the presence of IOX2 for 24 hours. n = 4 per group. (E) Plasma levels of BUN and creatinine in mice fed with regular chow or chow containing 0.25% adenine for 21 days. n = 10 per group. (FH) Hematocrit, renal Epo expression, and plasma EPO levels of mice fed with regular or adenine chows. n = 10 per group. (I) Epo expression of Col1a1-GFP+PDGFRβ+ pericytes and myofibroblasts isolated from kidneys of Col1a1-GFPTg mice fed with regular and adenine chows, respectively. n = 4 per cell group. One-way ANOVA was used for analyses of data in AC and EH, and Student’s t test was used for analyses of data in D. *P < 0.05, P < 0.01, P < 0.001.