近端小管 DNA 甲基化异常是糖尿病患者肾功能障碍相关表型变化的基础。

Takeshi Marumo, Naoto Yoshida, Noriko Inoue, Masayuki Yamanouchi, Yoshifumi Ubara, Shinji Urakami, Takeshi Fujii, Yutaka Takazawa, Kenichi Ohashi, Wakako Kawarazaki, Mitsuhiro Nishimoto, Nobuhiro Ayuzawa, Daigoro Hirohama, Genta Nagae, Mao Fujimoto, Eri Arai, Yae Kanai, Junichi Hoshino, Toshiro Fujita
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引用次数: 0

摘要

表观遗传机制被认为是导致糖尿病肾病的原因之一,因为它能在糖尿病早期阶段保持对血糖控制不良的记忆。然而,由于缺乏细胞类型特异性分析,人类肾脏中 DNA 甲基化变化的特征还很不清楚。鉴于近端肾小管在肾脏损伤中的关键作用,我们研究了从糖尿病肾病患者体内纯化的近端肾小管的 DNA 甲基化情况,并确定了不同的甲基化 CpG 位点。在糖尿病肾脏中,负责近端肾小管功能基因(包括葡萄糖生成、烟酰胺腺嘌呤二核苷酸合成、葡萄糖、水、磷酸盐和药物转运体)注释的 CpG 位点出现了高甲基化,而参与氧化应激和细胞骨架的基因则出现了去甲基化。注释为 ACTN1、BCAR1、MYH9、UBE4B、AFMID、TRAF2、TXNIP、FOXO3 和 HNF4A 的 CpG 位点的甲基化水平与估计的肾小球滤过率相关,而 RUNX1 的 CpG 位点的甲基化与肾间质纤维化和肾小管萎缩相关。在糖尿病肾脏中,G6PC 和 HNF4A 的高甲基化伴随着表达的降低。在对照组肾脏中观察到的与HNF4A相关的代谢基因近端肾小管特异性低甲基化在糖尿病肾脏中受到影响,这表明DNA甲基化异常在去分化过程中发挥作用。糖尿病患者DNA甲基化异常的多个基因与适应不良的近端肾小管细胞中表达改变的基因重叠,包括转录因子PPARA和RREB1。总之,糖尿病患者近端肾小管中的DNA甲基化失调可能会导致表型改变,表现为炎症和纤维化特征,以及代谢和运输功能受损。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Aberrant proximal tubule DNA methylation underlies phenotypic changes related to kidney dysfunction in patients with diabetes.

Epigenetic mechanisms are considered to contribute to diabetic nephropathy by maintaining memory of poor glycemic control during the early stages of diabetes. However, DNA methylation changes in the human kidney are poorly characterized, because of the lack of cell type-specific analysis. We examined DNA methylation in proximal tubules (PTs) purified from patients with diabetic nephropathy and identified differentially methylated CpG sites, given the critical role of proximal tubules in the kidney injury. Hypermethylation was observed at CpG sites annotated to genes responsible for proximal tubule functions, including gluconeogenesis, nicotinamide adenine dinucleotide synthesis, transporters of glucose, water, phosphate, and drugs, in diabetic kidneys, whereas genes involved in oxidative stress and the cytoskeleton exhibited demethylation. Methylation levels of CpG sites annotated to ACTN1, BCAR1, MYH9, UBE4B, AFMID, TRAF2, TXNIP, FOXO3, and HNF4A were correlated with the estimated glomerular filtration rate, whereas methylation of the CpG site in RUNX1 was associated with interstitial fibrosis and tubular atrophy. Hypermethylation of G6PC and HNF4A was accompanied by decreased expression in diabetic kidneys. Proximal tubule-specific hypomethylation of metabolic genes related to HNF4A observed in control kidneys was compromised in diabetic kidneys, suggesting a role for aberrant DNA methylation in the dedifferentiation process. Multiple genes with aberrant DNA methylation in diabetes overlapped genes with altered expressions in maladaptive proximal tubule cells, including transcription factors PPARA and RREB1. In conclusion, DNA methylation derangement in the proximal tubules of patients with diabetes may drive phenotypic changes, characterized by inflammatory and fibrotic features, along with impaired function in metabolism and transport.NEW & NOTEWORTHY Cell type-specific DNA methylation patterns in the human kidney are not known. We examined DNA methylation in proximal tubules of patients with diabetic nephropathy and revealed that oxidative stress, cytoskeleton, and metabolism genes were aberrantly methylated. The results indicate that aberrant DNA methylation in proximal tubules underlies kidney dysfunction in diabetic nephropathy. Aberrant methylation could be a target for reversing memory of poor glycemic control.

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