Project description:Hnf4a is specifically expressed in developing proximal tubule cells in the newborn mouse kidney. In order to identify direct target genes of Hnf4a in the developing proximal tubules, we performed ChIP-Seq of Hnf4a in the mouse kidneys at P0.

Project description:We report novel epigenetic mechanisms of epigenetic memory and its role in regulation of transporter genes in diabetic renal proximal tubules. We have generated RNA-seq, ATAC-seq and Infinium EPIC methylation array datasets from human primary proximal tubule epithelial cells from non-diabetic healthy controls and from patients with history of Type II Diabetes.

Project description:We report novel epigenetic mechanisms of epigenetic memory and its role in regulation of transporter genes in diabetic renal proximal tubules. We have generated RNA-seq, ATAC-seq and Infinium EPIC methylation array datasets from human primary proximal tubule epithelial cells from non-diabetic healthy controls and from patients with history of Type II Diabetes. Analyses of RNA-seq, ATAC-seq and Methylaiton EPIC array data.

Project description:Dent disease has multiple defects attributed to proximal tubule malfunction including low molecular weight proteinuria, aminoaciduria, phosphaturia and glycosuria. In order to understand the changes in kidney function of the Clc5 transporter gene knockout mouse model of Dent disease, we examined gene expression profiles from proximal tubules of mouse kidneys. Overall 720 genes are expressed differentially in the proximal tubules of the Dent Clcn5 knockout mouse model compared to those of control wild type mice. The fingerprint of these gene changes may help us to understand the phenotype of Dent disease. Experiment Overall Design: Renal proximal tubules were dissected from wild type and Clcn5 knockout mice. Mice were anesthetized with halothane, the abdominal aorta of each animal was accessed and the left kidney was perfused with an ice-cold salt. Proximal tubule dissection was performed in an ice-cold salt solution. After dissection of approximately 80-100 segments of 2 mm in length per kidney, the RNA for 3-4 mice was combined to have enough RNA per chip. Experiment Overall Design: 3 microarrays each of wild type and knockout mouse proximal tubule were processed

Project description:Sex differences have been increasingly recognized to play an important role in kidney physiology and pathophysiology, but limited resources are available for comprehensive interrogation of sex differences. Here, we coupled renal tubule microdissection with RNA-seq and ATAC-seq with a focus on proximal tubules that exhibited the greatest sex differences and carried out whole-kidney proteomics to build a comprehensive sex difference landscape between male and female mouse kidneys. The transcriptomic data indicate that the major sex differences are in S2 and S3 of proximal tubule segments, where signaling pathways including monocarboxylic acid metabolic process, organic anion transport, and organic acid transport display the greatest differences. We develop an ATAC-seq method on microdissected tubules to capture chromatin accessibility differences between sexes. The analysis reveals that major sex differences are in autosomes instead of sex chromosomes, and many of them are in S2/S3 segments related to the signaling pathways identified by transcriptomic analysis. Motif analysis identifies several transcription factors (Tead1, Nfia/b, and Pou3f3) whose interplay with other transcription factors (e.g. Hnf1b, Hnf4a) may contribute to sex differences. Finally, whole-kidney quantitative proteomics analysis correlates with the transcriptome analysis and identifies a large number of proteins (Cyp2e1, Acsm2/3) that are sex-dependent. We develop a knowledge portal to promote our understanding of sex differences in kidneys in kidneys at https://esbl.nhlbi.nih.gov/MRECA/PT/.

Project description:The transcriptional regulation of drug-metabolizing enzymes and transporters (here collectively referred to as DMEs) in the developing proximal tubule is not well understood. As in the liver, DME regulation in the PT may be mediated through nuclear receptors which are thought to “sense” deviations from homeostasis by being activated by ligands, some of which are handled by DMEs, including drug transporters. Systems analysis of transcriptomic data during kidney development predicted a set of upstream transcription factors, including Hnf4a and Hnf1a, as well as Nr3c1 (Gr), Nfe2l2 (Nrf2), Ppara, and Tp53. Motif analysis of cis-regulatory further suggested that Hnf4a and Hnf1a are the main transcriptional regulators in the PT. Available expression data from tissue-specific Hnf4a KO tissues revealed that distinct subsets of DMEs were regulated by Hnf4a in a tissue-specific manner. ChIP-seq was performed to characterize the PT-specific binding sites of Hnf4a in rat kidneys at three developmental stages (prenatal, immature, adult), which further supported a major role for Hnf4a in regulating PT gene expression, including DMEs. In ex vivo kidney organ culture, an antagonist of Hnf4a (but not a similar inactive compound) led to predicted changes in DME expression, including among others Fmo1, Cyp2d2, Cyp2d4, Nqo2, as well as organic cation transporters and organic anion transporters Slc22a1(Oct1), Slc22a2 (Oct2), Slc22a6 (Oat1), Slc22a8(Oat3), and Slc47a1(Mate1). Conversely, overexpression of Hnf1a and Hnf4a in primary mouse embryonic fibroblasts (MEFs), sometimes considered a surrogate for mesenchymal stem cells, induced expression of several of these proximal tubule DMEs, as well as epithelial markers and a PT-specific brush border marker Ggt1. These cells had organic anion transporter function. Taken together, the data strongly supports a critical role for HNF4a and Hnf1a in the tissue-specific regulation of drug handling and differentiation toward a PT cellular identity. Hnf4a binding was examined in rat kidneys at three timepoints (E20, P13 and Adult) and p300 binding was examined in adult rat kidney cortex tissue using ChIP-seq. Four corresponding input DNA samples were used as controls for peak calling.

Project description:Dent disease has multiple defects attributed to proximal tubule malfunction including low molecular weight proteinuria, aminoaciduria, phosphaturia and glycosuria. In order to understand the changes in kidney function of the Clc5 transporter gene knockout mouse model of Dent disease, we examined gene expression profiles from proximal tubules of mouse kidneys. Overall 720 genes are expressed differentially in the proximal tubules of the Dent Clcn5 knockout mouse model compared to those of control wild type mice. The fingerprint of these gene changes may help us to understand the phenotype of Dent disease. Keywords: gene knockout, mouse, Clcn5, Dent's disease

Project description:To establish the role of proximal tubular hypoxia in diabetic kidney disease, we use a mouse line with a specific deletion of von-Hippel-Lindau (VHL) in the proximal tubule and treat them with streptozotocin (STZ) to induce a type I diabetes mellitus. 10 weeks after induction of diabetes mellitus samples were collected.

Project description:Adult-onset knockout of HNF4A resulted in decreased expression levels of brush border genes. We find a robust shift in the transcriptome away from proximal tubule transcripts and towards distal tubule transcripts in the kidney upon HNF4A loss.

Project description:Little is known about the contribution of the epigenome to the pathophysiology of type 2 diabetes (T2D). Here we have used genome-wide DNA methylation profiling to obtain the first comprehensive DNA methylation data set for human T2D pancreatic islets. Therefore, we analyzed the methylation profile of 27,578 CpG sites affiliated to more than 14,000 genes in 16 samples of pancreatic islets, 11 normal and 5 type 2-diabetic. Keywords: DNA methylation Keywords: Methylation profiling by array We measured the methylation status of the 27,578 CpG sites (Human Methylation27 DNA BeadChip array) in genomic DNA obtained from pnacreatic islets of 11 non-diabetic and 5 type-2-diabetic male human donors to identify genes that are differentially methylated in T2D.