Project description:Diabetic kidney disease is a major complication in diabetes mellitus, and the most common reason for end-stage renal disease. Patients suffering from diabetes mellitus encounter glomerular damage by basement membrane thickening, and develop albuminuria. Subsequently, albuminuria can deteriorate the tubular function and impair the renal outcome. The impact of diabetic stress conditions on the metabolome was investigated by untargeted gas chromatography-mass spectrometry (GC-MS) analyses. The results were validated by qPCR analyses. In total, four cell lines were tested, representing the glomerulus, proximal nephron tubule, and collecting duct. Both murine and human cell lines were used. In podocytes, proximal tubular and collecting duct cells, high glucose concentrations led to global metabolic alterations in amino acid metabolism and the polyol pathway. Albumin overload led to the further activation of the latter pathway in human proximal tubular cells. In the proximal tubular cells, aldo-keto reductase was concordantly increased by glucose, and partially increased by albumin overload. Here, the combinatorial impact of two stressful agents in diabetes on the metabolome of kidney cells was investigated, revealing effects of glucose and albumin on polyol metabolism in human proximal tubular cells. This study shows the importance of including highly concentrated albumin in in vitro studies for mimicking diabetic kidney disease.

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:Kidney damage involves the progressive and inexorable destruction of tubular and glomerular system. However, it is known that the patients survive AKI often recover renal structure and function. Correspondingly, previous studies demonstrated tubular regeneration in mice after massive kidney injury and linked mouse Sox9+ renal progenitor cells to this process. Here we show that renal progenitor cells can be cloned from renal needle biopsy sample of CKD patients. Progenitor cells can readily assembly into “kidney organoids” expressing proximal/distal tubular cell markers in 3D culture.

Project description:In this study mice were engineered to specifically delete Twist1 or Snail expression in proximal tubular epithelial cells of the kidney (ggt-cre+;Twist flox/flox and ggt-cre+;Snail flox/flox ). These mice and control mice (ggtcre-;Twist flox/flox: these express Twist1, and ggtcre-;Snail flox/flox:these express Snail) were subjected to unilaterial ureteric obstruction. This experiment allows for the collection and analysis of expression in contralateral healthy (HK) kidney adn obstructed disease (DK) kidney. Total RNA was isolated from the contralateral healthy (HK) and obstructed disease (DK) kidneys of 3 mice with ggt-cre-;Twist flox/flox genotype (Wildtype like) and 4 mice with ggt-cre+;Twist flox/flox genotype (loss of Twist1 in proximal tubular epithelial cells), 3 mice with ggt-cre-;Snail flox/flox genotype (Wildtype like) and 3 mice with ggt-cre+;Snail flox/flox genotype (loss of Snail in proximal tubular epithelial cells). Total RNA was also isolated from kidneys of completely healthy mice: 3 mice ggt-cre-;WT, 3 mice ggt-cre+;WT, 3 mice ggt-cre+;Twist flox/flox and 3 ggt-cre+;Snail flox/flox

Project description:Despite tubular injury being one of the main mechanisms driving acute kidney injury (AKI), clinicians still have a limited diagnostic repertoire to precisely monitor damage to tubular epithelial cells (TEC). In our previous work we used single cell sequencing to identify TEC subsets as main component of the urine signature in AKI. The aim of this study was to establish TEC as a clinical marker for tubular damage. In total 243 patients were analyzed. For sequencing, we collected eight urine samples of patients with AKI and glomerular disease. By aligning urinary single-cell transcriptomes and TEC-surface proteins using Cellular Indexing of Transcriptome and Epitope Sequencing (CITE-Seq), we developed a protocol for flow cytometric quantification of CD10/CD13+ proximal and CD227/CD326+ distal TEC in urine. The marker combinations were confirmed in kidney biopsies. We validated our approach across four cohorts totaling 235 patients, consisting of patients with AKI (n=63), SARS-CoV-2 infection (n=47), ANCA-associated vasculitis (AAV) with active disease and stable remission (n=110) and healthy controls (n=15). Our findings demonstrate that CD10/CD13 and CD227/CD326 adequately identify proximal and distal urinary TEC, respectively. Distal urinary TEC counts correlate with the severity of AKI based on KDIGO stage and acute eGFR loss in two separate cohorts and can successfully discriminate AKI from healthy controls as well as glomerular disease. We propose urinary CD227/CD326+ TEC counts as a specific, non-invasive marker for tubular injury in AKI. Our protocol provides the basis for a deeper phenotypic analysis of urinary TECs

Project description:Mutations in ClC-5 cause Dent's disease, a disorder associated with low molecular weight proteinuria, hyperphosphaturia and kidney stones. ClC-5 is a Cl /H+-exchanger predominantly expressed in the kidney, where it facilitates the acidification of proximal tubular endosomes. The reduction in proximal tubular endocytosis resulting from a lack of ClC-5 raises the luminal concentration of filtered proteins and peptides like PTH.<br><br> We used gene expression profiling to identify possible signaling pathways that might be changed in ClC-5 KO kidneys, bones and intestines.<br%gt;<br> Mouse model described in Piwon et al, ClC-5 Cl--channel disruption impairs endocytosis in a mouse model for Dent's disease, Nature 408, 369-373 (16 November 2000),doi: 10.1038/35042597

Project description:Kidney damage involves the progressive and inexorable destruction of tubular and glomerular system. However, it is known that the patients survive AKI often recover renal structure and function. Correspondingly, previous studies demonstrated tubular regeneration in mice after massive kidney injury and linked mouse Sox9+ renal progenitor cells to this process. Here we show that progenitor cells can be cloned from mouse medulla and cortex. Clones can be grown from a single cell and indefinitely passaged. Progenitor cells derived from renal medulla can readily assembly into “kidney organoids” expressing proximal/distal tubular cell markers in 3D culture.

Project description:Mammalian kidney has very limited ability to repair or regenerate after acute kidney injury (AKI). The maladaptive repair of AKI promotes the progression to chronic kidney disease (CKD). Therefore, it is extremely urgent to explore new strategies to promote the repair/regeneration of injured renal tubules after AKI. It has been shown that hypoxia induces heart regeneration in adult mice. However, it is unknown whether hypoxia can induce kidney regeneration after AKI. In this study, we used a prolyl hydroxylase domain inhibitor (PHDI), MK-8617, to mimic hypoxia condition and found that MK-8617 significantly ameliorates ischemia reperfusion injury (IRI) induced acute kidney injury. We then showed that MK-8617 dramatically facilitates renal regeneration via promoting the proliferation of injured renal proximal tubular cells (RPTCs) after IRI-induced AKI. We then performed bulk mRNA sequencing and discovered that multiple nephrogenesis- related genes were significantly upregulated with MK-8617 pretreatment. Furthermore, we showed that MK-8617 may alleviate proximal tubule injury via stabilizing HIF-1α protein specifically in renal proximal tubular cells. We also demonstrated that MK-8617 promotes the reprogramming of renal proximal tubular cells to Sox9+ renal progenitor cells, and the regeneration of renal proximal tubules. In summary, we discovered that inhibition of prolyl hydroxylase improves renal proximal tubule regeneration after IRI-induced AKI via promoting the reprogramming of renal proximal tubular cells to Sox9+ renal progenitor cells.

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:Kidney is a vital organ which help maintain body homeostasis. Three related processes including glomerular filtration, tubular reabsorption and secretion are precisely regulated in the kidney in response to changes in the amount of both water and various solutes. To understand how the kidney can achieve this challenging goal, it is important to know the protein composition in the kidney. However, unlike other solid organs, kidney has a very intricate architecture, including at least 14 distinct tubule segments. This reason limits the interpretibility of experiments perfomred using whole kidney homegenate samples. To mitigate this problem, we combined kidney tubule microdissection technique with protein mass spectrometry to study the proteome of 14 individual rat kidney tubule segment.