GLIS3: A novel transcriptional regulator of mitochondrial functions and metabolic reprogramming in postnatal kidney and polycystic kidney disease

IF 7 2区 医学 Q1 ENDOCRINOLOGY & METABOLISM
Justin B. Collier , Hong Soon Kang , Yun-Gil Roh , Chitrangda Srivastava , Sara A. Grimm , Alan K. Jarmusch , Anton M. Jetten
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引用次数: 0

Abstract

Objectives

Deficiency in the transcription factor (TF) GLI-Similar 3 (GLIS3) in humans and mice leads to the development of polycystic kidney disease (PKD). In this study, we investigate the role of GLIS3 in the regulation of energy metabolism and mitochondrial functions in relation to its role in normal kidney and metabolic reprogramming in PKD pathogenesis.

Methods

Transcriptomics, cistromics, and metabolomics were used to obtain insights into the role of GLIS3 in the regulation of energy homeostasis and mitochondrial metabolism in normal kidney and PKD pathogenesis using GLIS3-deficient mice.

Results

Transcriptome analysis showed that many genes critical for mitochondrial biogenesis, oxidative phosphorylation (OXPHOS), fatty acid oxidation (FAO), and the tricarboxylic acid (TCA) cycle, including Tfam, Tfb1m, Tfb2m, Ppargc1a, Ppargc1b, Atp5j2, Hadha, and Sdha, are significantly suppressed in kidneys from both ubiquitous and tissue-specific Glis3-deficient mice. ChIP-Seq analysis demonstrated that GLIS3 is associated with the regulatory region of many of these genes, indicating that their transcription is directly regulated by GLIS3. Cistrome analyses revealed that GLIS3 binding loci frequently located near those of hepatocyte nuclear factor 1-Beta (HNF1B) and nuclear respiratory factor 1 (NRF1) suggesting GLIS3 regulates transcription of many metabolic and mitochondrial function-related genes in coordination with these TFs. Seahorse analysis and untargeted metabolomics corroborated that mitochondrial OXPHOS utilization is suppressed in GLIS3-deficient kidneys and showed that key metabolites in glycolysis, TCA cycle, and glutamine pathways were altered indicating increased reliance on aerobic glycolysis and glutamine anaplerosis. These features of metabolic reprogramming may contribute to a bioenergetic environment that supports renal cyst formation and progression in Glis3-deficient mice kidneys.

Conclusions

We identify GLIS3 as a novel positive regulator of the transition from aerobic glycolysis to OXPHOS in normal early postnatal kidney development by directly regulating the transcription of mitochondrial metabolic genes. Loss of GLIS3 induces several features of renal cell metabolic reprogramming. Our study identifies GLIS3 as a new participant in an interconnected transcription regulatory network, that includes HNF1B and NRF1, critical in the regulation of mitochondrial-related gene expression and energy metabolism in normal postnatal kidneys and PKD pathogenesis in Glis3-deficient mice.
GLIS3:出生后肾脏和多囊肾病中线粒体功能和代谢重编程的新型转录调节因子。
背景和目的:人类和小鼠体内转录因子(TF)GLI-相似3(GLIS3)的缺陷会导致多囊肾病(PKD)的发生。在这项研究中,我们研究了GLIS3在能量代谢和线粒体功能调控中的作用,以及它在正常肾脏中的作用和在PKD发病机制中的代谢重编程:利用转录组学、表观组学和代谢组学,通过GLIS3缺陷小鼠深入了解GLIS3在正常肾脏和PKD发病机制中调控能量平衡和线粒体代谢的作用。转录组分析表明,许多对线粒体生物生成、氧化磷酸化(OXPHOS)、脂肪酸氧化(FAO)和三羧酸(TCA)循环至关重要的基因,包括Tfam、Tfb1m、Tfb2m、Ppargc1a、Ppargc1b、Atp5j2、Hadha和Sdha,在无处不在的和组织特异性Glis3缺陷小鼠的肾脏中都受到显著抑制。ChIP-Seq 分析表明,GLIS3 与这些基因中的许多基因的调控区相关,表明它们的转录直接受 GLIS3 的调控。Cistrome分析表明,GLIS3的结合位点经常位于肝细胞核因子1-Beta(HNF1B)和核呼吸因子1(NRF1)的结合位点附近,这表明GLIS3与这些TFs共同调控许多代谢和线粒体功能相关基因的转录。海马分析和非靶向代谢组学证实,线粒体 OXPHOS 的利用在 GLIS3 基因缺陷的肾脏中受到抑制,并表明糖酵解、TCA 循环和谷氨酰胺途径中的关键代谢物发生了改变,这表明对有氧糖酵解和谷氨酰胺合成的依赖性增加。代谢重编程的这些特征可能有助于形成一种生物能环境,支持 Glis3 缺陷小鼠肾囊肿的形成和发展:我们发现 GLIS3 是一种新型的正向调控因子,它通过直接调控线粒体代谢基因的转录,在正常的出生后早期肾脏发育过程中从有氧糖酵解向 OXPHOS 过渡。缺失 GLIS3 会诱导肾细胞代谢重编程的几个特征。我们的研究发现,GLIS3是一个相互关联的转录调控网络的新参与者,该网络包括HNF1B和NRF1,在正常出生后肾脏线粒体相关基因表达和能量代谢以及Glis3缺陷小鼠PKD发病机制的调控中起着关键作用。
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来源期刊
Molecular Metabolism
Molecular Metabolism ENDOCRINOLOGY & METABOLISM-
CiteScore
14.50
自引率
2.50%
发文量
219
审稿时长
43 days
期刊介绍: Molecular Metabolism is a leading journal dedicated to sharing groundbreaking discoveries in the field of energy homeostasis and the underlying factors of metabolic disorders. These disorders include obesity, diabetes, cardiovascular disease, and cancer. Our journal focuses on publishing research driven by hypotheses and conducted to the highest standards, aiming to provide a mechanistic understanding of energy homeostasis-related behavior, physiology, and dysfunction. We promote interdisciplinary science, covering a broad range of approaches from molecules to humans throughout the lifespan. Our goal is to contribute to transformative research in metabolism, which has the potential to revolutionize the field. By enabling progress in the prognosis, prevention, and ultimately the cure of metabolic disorders and their long-term complications, our journal seeks to better the future of health and well-being.
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