Project description:The adult kidney has a remarkable capacity for self-renewal upon damage. Whether this regeneration is mediated by dedifferentiating surviving cells or as recently suggested by stem cells has not been unequivocally settled. The stem cell concept is however hampered by lack of consensus regarding the histological localization of and defining markers for these cells. Here, we demonstrate that aldehyde dehydrogenase (ALDH) activity may be used for isolation of cells with progenitor-like characteristics from adult human renal cortical tissue. Gene expression profiling of the isolated ALDHhigh and ALDHlow cell fractions followed by immunohistochemical interrogation of renal tissues enabled us to delineate a tentative progenitor cell population with a scattered distribution in the epithelial layer of the proximal tubules (PT). The cells differed from the surrounding cells by expression of CD133, CD24, vimentin, KRT7, KRT19, and BCL2, and were negative for PT-specific markers. Based on functional and bioinformatic analyses as well as an immunophenotypical resemblance to cells of regenerating tubules we suggest that these cells are endowed with a more robust phenotype, allowing increased resistance to acute renal injury, enabling rapid repopulation of the tubules. The rare intratubular cells also displayed marked transcriptional and immunophenotypical similarities to that of cortical adenomas and papillary renal cell carcinomas, indicating that these renal neoplasms arise through oncogenic transformation of this subset of PT cells. Total RNA extracted from three pairs of ALDH-high and ALDH-low cell fractions were hybridized to Illumina humanHT-12 v3.0 Expression BeadChips (Illumina Inc) at the SCIBLU Genomics Centre at Lund University Sweden (http://www.lth.se/sciblu).

Project description:The adult kidney has a remarkable capacity for self-renewal upon damage. Whether this regeneration is mediated by dedifferentiating surviving cells or as recently suggested by stem cells has not been unequivocally settled. The stem cell concept is however hampered by lack of consensus regarding the histological localization of and defining markers for these cells. Here, we demonstrate that aldehyde dehydrogenase (ALDH) activity may be used for isolation of cells with progenitor-like characteristics from adult human renal cortical tissue. Gene expression profiling of the isolated ALDHhigh and ALDHlow cell fractions followed by immunohistochemical interrogation of renal tissues enabled us to delineate a tentative progenitor cell population with a scattered distribution in the epithelial layer of the proximal tubules (PT). The cells differed from the surrounding cells by expression of CD133, CD24, vimentin, KRT7, KRT19, and BCL2, and were negative for PT-specific markers. Based on functional and bioinformatic analyses as well as an immunophenotypical resemblance to cells of regenerating tubules we suggest that these cells are endowed with a more robust phenotype, allowing increased resistance to acute renal injury, enabling rapid repopulation of the tubules. The rare intratubular cells also displayed marked transcriptional and immunophenotypical similarities to that of cortical adenomas and papillary renal cell carcinomas, indicating that these renal neoplasms arise through oncogenic transformation of this subset of PT cells.

Project description:A novel method of isolation of cells from rabbit kidney proximal tubules by using an intracellular-like solution (ICS) and gentle mechanical agitation in the absence of enzymes or chelators is described. Metabolic and functional characteristics of these cells were studied after washing and resuspension in modified Hanks medium, and the results were compared with those obtained in cells similarly prepared in extra-cellular-like solution (ECS). Trypan Blue exclusion and protein content were not different between the two preparations. However, oxygen consumption, ATP content and time- and concentration-dependent rates of uptake of phosphate, alpha-methyl glucoside and L-alanine were severalfold higher in cells prepared in ICS. Na+-dependent uptake of these solutes was 95% and 80% of total uptake in cells prepared in ICS and ECS respectively. Maximum transport rates (Tmax.) of phosphate, alpha-methyl glucoside and L-alanine were significantly higher in cells prepared in ICS. We propose that the use of ICS in the isolation procedure would yield a functionally more viable cell preparation, and therefore provides an ideal model for transport and metabolic studies at a cellular level.

Project description:Three-dimensional models of kidney tissue that recapitulate human responses are needed for drug screening, disease modeling, and, ultimately, kidney organ engineering. Here, we report a bioprinting method for creating 3D human renal proximal tubules in vitro that are fully embedded within an extracellular matrix and housed in perfusable tissue chips, allowing them to be maintained for greater than two months. Their convoluted tubular architecture is circumscribed by proximal tubule epithelial cells and actively perfused through the open lumen. These engineered 3D proximal tubules on chip exhibit significantly enhanced epithelial morphology and functional properties relative to the same cells grown on 2D controls with or without perfusion. Upon introducing the nephrotoxin, Cyclosporine A, the epithelial barrier is disrupted in a dose-dependent manner. Our bioprinting method provides a new route for programmably fabricating advanced human kidney tissue models on demand.

Project description:Fibrosis is the final common pathway in the pathophysiology of most forms of chronic kidney disease (CKD). As treatment of renal fibrosis still remains largely supportive, a refined understanding of the cellular and molecular mechanisms of kidney fibrosis and the development of novel compounds are urgently needed. Whether arginases play a role in the development of fibrosis in CKD is unclear. We hypothesized that endothelial arginase-2 (Arg2) promotes the development of kidney fibrosis induced by unilateral ureteral obstruction (UUO). Arg2 expression and arginase activity significantly increased following renal fibrosis. Pharmacologic blockade or genetic deficiency of Arg2 conferred kidney protection following renal fibrosis, as reflected by a reduction in kidney interstitial fibrosis and fibrotic markers. Selective deletion of Arg2 in endothelial cells (Tie2Cre/Arg2fl/fl) reduced the level of fibrosis after UUO. In contrast, selective deletion of Arg2 specifically in proximal tubular cells (Ggt1Cre/Arg2fl/fl) failed to reduce renal fibrosis after UUO. Furthermore, arginase inhibition restored kidney nitric oxide (NO) levels, oxidative stress, and mitochondrial function following UUO. These findings indicate that endothelial Arg2 plays a major role in renal fibrosis via its action on NO and mitochondrial function. Blocking Arg2 activity or expression could be a novel therapeutic approach for prevention of CKD.

Project description:The proximal convoluted tubule is the primary site of renal fluid, electrolyte, and nutrient reabsorption, processes that consume large amounts of adenosine-5'-triphosphate. Previous proteomic studies have profiled the adaptions that occur in this segment of the nephron in response to the onset of metabolic acidosis. To extend this analysis, a proteomic workflow was developed to characterize the proteome of the mitochondrial inner membrane of the rat renal proximal convoluted tubule. Separation by LC coupled with analysis by MS/MS (LC-MS/MS) confidently identified 206 proteins in the combined samples. Further proteomic analysis identified 14 peptides that contain an N-?-acetyl-lysine, seven of which are novel sites. This study provides the first proteomic profile of the mitochondrial inner membrane proteome of this segment of the rat renal nephron. The MS data have been deposited in the ProteomeXchange with the identifier PXD000121.

Project description:Hyperglycemia/diabetes appears to be accompanied by the state of hypoxia, which especially affects kidneys. The aim of the study was to elucidate the mechanism of high glucose action on HIF-1α expression in renal proximal tubule epithelial cells. The research hypotheses included: (1) the participation of transcription factor ChREBP; and (2) the involvement of the effects resulting from pseudohypoxia, i.e., lowered intracellular NAD+/NADH ratio. The experiments were performed on HK-2 cells and primary cells: D-RPTEC (Diseased Human Renal Proximal Tubule Epithelial Cells-Diabetes Type II) and RPTEC (Renal Proximal Tubule Epithelial Cells). Protein and mRNA contents were determined by Western blot and RT-qPCR, respectively. ChREBP binding to DNA was detected applying chromatin immunoprecipitation, followed by RT-qPCR. Gene knockdown was performed using siRNA. Sirtuin activity and NAD+/NADH ratio were measured with commercially available kits. It was found that high glucose in HK-2 cells incubated under normoxic conditions: (1) activated transcription of HIF-1 target genes, elevated HIF-1α and ChREBP content, and increased the efficacy of ChREBP binding to promoter region of HIF1A gene; and (2), although it lowered NAD+/NADH ratio, it affected neither sirtuin activity nor HIF-1α acetylation level. The stimulatory effect of high glucose on HIF-1α expression was not observed upon the knockdown of ChREBP encoding gene. Experiments on RPTEC and D-RPTEC cells demonstrated that HIF-1α content in diabetic proximal tubular cells was lower than that in normal ones but remained high glucose-sensitive, and the latter phenomenon was mediated by ChREBP. Thus, it is concluded that the mechanism of high glucose-evoked increase in HIF-1α content in renal proximal tubule endothelial cells involves activation of ChREBP, indirectly capable of HIF1A gene up-regulation.

Project description:Long non-coding RNA (lncRNA) play an important role in several biological processes including some renal diseases. Nevertheless, little is known on lncRNAs that are expressed in healthy kidney and involved in renal cell homeostasis and development and even less is known about lncRNA involved in the maintenance of human adult renal stem/progenitor cells (ARPCs). ARPCs have been shown to be very important for renal homeostasis and repair processes thanks to their self-renewal and differentiative ability as well as their capacity to secrete different reparative factors depending on the type of damage. Through a whole genome transcriptome screening, we found that the HOTAIR lncRNA is highly expressed in renal progenitors and potentially involved cell cycle and senescence biological processes. We then generated HOTAIR knock-out ARPC lines by CRISPR/Cas9 genome editing and showed that this lncRNA limits the apoptotic process of ARPCs and sustains their proliferative capacity, thus resulting responsible of their self-renewal properties. In addition, we found that the knockout of HOTAIR led to the ARPC senescence and to a significant decrease of the CD133 stem cell marker expression that is an inverse marker of ARPC senescence and can regulate renal tubular repair after the damage. Moreover, we found that ARPCs expressed high levels of the α-Klotho anti-aging protein and especially 2.6 fold higher levels compared to that secreted by RPTECs. The HOTAIR knockout in ARPCs leads to lower α-Klotho levels, comparable to that of RPTECs. Finnally we showed that HOTAIR induces epigenetic silencing of the cell cycle inhibitor p15 through the trimethylation of the histone H3K27. Altogether, these results shed new light on these important renal cells and may support the future development of precision therapies for kidney diseases.

Project description:BackgroundA good in vitro model should approximate an in vivo-like behavior as closely as possible in order to reflect most likely the in vivo situation. Regarding renal physiology of different species, humans are more closely related to pigs than to rodents, therefore primary porcine kidney cells (PKC) and their subsequent cell strain could be a valid alternative to primary human cells for renal in vitro toxicology. For this PKC must display inherent characteristics (e.g. structural organization) and functions (e.g. transepithelial transport) as observed under in vivo conditions within the respective part of the kidney.ResultsWe carried out a comprehensive characterization of PKC and their subsequent cell strain, including morphology and growth as well as transporter expression and functionality. The data presented here demonstrate that PKC express various transporters including pMrp1 (abcc1), pMrp2 (abcc2), pOat1 (slc22a6) and pOat3 (slc22a8), whereas pMdr1 (abcb1) and pOatp1a2 (slco1a2) mRNA could not be detected in either the PKCs or in the porcine cortical tissue. Functionality of the transporters was demonstrated by determining the specific PAH transport kinetics.ConclusionsOn the basis of the presented results it can be concluded that PKC and to some extent their subsequent cell strain represent a valuable model for in vitro toxicology, which might be used as an alternative to human primary cells.

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/.