Project description:Transcriptional profiling of new born mouse kidney collecting duct (CD) cells comparing the infuence of gestational high salt stress on gene expression remolding of BdkrB2 receptor knockout CD cells with that of BdkrB2 receptor wild type CD cells. The BdkrB2 receptor has been shown to be playing a role in renal vascular tone, kidney secretion and reabsorption function, normal kidney development, while impaired BdkrB2 receptor in kidney shown being associated with renal agenesis and renal dysplasia. Goal was to determine the effects of BdkrB2 receptor knockout together with gestational high salt stress on collecting duct gene expression pattern. Single color microarray experiment, BdkrB2 knockout new born mouse CD cells vs. BdkrB2 WT mosue CD cells with both on gestational high salt stress. Biological replicates: 3 BdkrB2 null replicates, 3 BdkrB2 WT replicates. Expression level of each sample was normalized to WT1 replicate.

Project description:Transcriptional profiling of new born mouse kidney collecting duct (CD) cells comparing the infuence of gestational high salt stress on gene expression remolding of BdkrB2 receptor knockout CD cells with that of BdkrB2 receptor wild type CD cells. The BdkrB2 receptor has been shown to be playing a role in renal vascular tone, kidney secretion and reabsorption function, normal kidney development, while impaired BdkrB2 receptor in kidney shown being associated with renal agenesis and renal dysplasia. Goal was to determine the effects of BdkrB2 receptor knockout together with gestational high salt stress on collecting duct gene expression pattern.

Project description:Current renal organoid models derived from embryonic or induced pluripotent stem cells mimic development. Yet, few studies have attempted to generate organoids from human adult kidney to recapitulate regeneration or pathological dysregulation in vitro. Here, we report a novel expanding regenerative organoids culture system from renal cortex and medulla. Transcriptomic sequencing and immunostaining identified that these organoids share similar molecular features with kidney injury-responsive regeneration. Heterogeneous populations in organoids including cycling epithelial progenitors and differentiated cell types were identified by single cell sequencing including proximal tubules, principal cells and collecting duct (CD) progenitors that can be induced into functional CD system. Furthermore, we established polycystic organoids derived from patients that represent an advanced platform for polycystic kidney disease (PKD) modeling. By drug screening, QNZ, GSK2193874 and AMPK activators were shown to significantly reduce polycystic growth. Our results demonstrated a novel in vitro renal organoid model to study regenerating adult renal cells and PKD mechanism, providing tools for discovery of therapeutic targets.

Project description:Current renal organoid models derived from embryonic or induced pluripotent stem cells mimic development. Yet, few studies have attempted to generate organoids from human adult kidney to recapitulate regeneration or pathological dysregulation in vitro. Here, we report a novel expanding regenerative organoids culture system from renal cortex and medulla. Transcriptomic sequencing and immunostaining identified that these organoids share similar molecular features with kidney injury-responsive regeneration. Heterogeneous populations in organoids including cycling epithelial progenitors and differentiated cell types were identified by single cell sequencing including proximal tubules, principal cells and collecting duct (CD) progenitors that can be induced into functional CD system. Furthermore, we established polycystic organoids derived from patients that represent an advanced platform for polycystic kidney disease (PKD) modeling. By drug screening, QNZ, GSK2193874 and AMPK activators were shown to significantly reduce polycystic growth. Our results demonstrated a novel in vitro renal organoid model to study regenerating adult renal cells and PKD mechanism, providing tools for discovery of therapeutic targets.

Project description:Analysis of expression changes in renal collecting duct epithelial cells by adenoviral mediated Krüppel like transcription factor 5 (KLF5) overexpression. KLF5 is a key regulator of static and inflammatory stage in renal collecting duct epithelial cells. We thought these results provide insights into downstream genes of KLF5 in renal collecting duct epithelial cells.

Project description:Vasopressin, the antidiuretic hormone, acts on the renal collecting duct. In this experiment both vasopressin (AVP) and the V2R specific agonist dDAVP were infused into Aquaporin 1 knockout animals for 7 days. The aim of the experiment was to identify genes increased by vasopressin receptors in the renal medullary collecting ducts, in the absence of an increase in renal medullary osmolarity (the AQP1 knockouts are concentrating mechanism knockouts). All experiments used inner medulla tissue for the RNA isolation. Hybridizations were performed that compared kidney inner medulla total RNA from three control mice against kidney medulla total RNA from 3 mice infused with either arginine vasopressin (AVP) or des-amino-D-arginine vasopressin (dDAVP).

Project description:Analysis of expression changes in renal collecting duct epithelial cells by adenoviral mediated Krüppel like transcription factor 5 (KLF5) overexpression. KLF5 is a key regulator of static and inflammatory stage in renal collecting duct epithelial cells. We thought these results provide insights into downstream genes of KLF5 in renal collecting duct epithelial cells. Total RNAs were isolated from adenovirally-mediated KLF5 over expressed cultured mIMCD-3 cells or control adenovirus infected mIMCD-3. We analyzed these two gene expression profiles after 24 hours after infection.

Project description:Grb2 is a small SH2-SH3 adaptor molecule that interacts with activated tyrosine kinase receptors (RTKs), providing a crucial link towards downstream activation of pro-proliferative and pro-survival ERK and Akt signaling pathways. Ret and FGFR2, two RTKs that interact with Grb2, play important roles in ureteric branching and the proper establishment of the renal collecting duct system, but it is unclear whether Grb2 is required in this process. In this study, we selectively ablated a conditional floxed allele of the Grb2 gene within the ureteric epithelial lineage in mice and demonstrate that Grb2 signaling is essentially required for proper collecting duct development. Ureteric Grb2 deficiency results in perinatal lethality and severe renal hypodysplasia closely reminiscent of the rudimentary kidney phenotypes observed in Ret-null mutant mice. Grb2 loss attenuates ERK and Akt activation in the ureteric epithelia resulting in pronounced impairment of ureteric branching. Gene expression analysis reveals that Grb2 deficiency results in defective induction of genes implicated in both ureteric branching and reciprocal mesenchymal metanephric induction. Our findings therefore strongly indicate that Grb2 is a physiologically-relevant major RTK signaling relay partner that promotes renal branching morphogenesis and the proper development of the collecting duct system and the urogenital tract. Microarray was used to profile and compare the transcriptomes of developing kidneys of E14.5 Grb2 conditional knockout (ureteric-bud specific) and wild-type embryos

Project description:All-trans retinoic acid (tRA) is the bioactive derivative of vitamin A that regulates gene expression by activating RA receptors (RAR). By using a reporter mouse model, we recently showed that endogenous tRA/RAR signaling was present in kidney collecting duct cells, and in mouse inner medullary collecting duct cell line (mIMCD-3). In order to unveil target genes of endogenous tRA/RAR signaling in kidney collecting duct cells, whole genome microarray analysis was performed on mIMCD-3 cells treated with AGN193109, a pan-RAR antagonist, and 4-diethylaminobenzaldehyde (DEAB), an inhibitor of tRA synthesizing enzyme. Specificity of gene expression regulation was confirmed by determining the reversibility of the regulation by simultaneous addition of exogenous tRA.

Project description:Ureteric bud (UB) is the embryonic kidney progenitor tissue that gives rise to the collecting duct and lower urinary tract. UB-like structures generated from human pluripotent stem cells by previously reported methods show limited developmental ability and limited branching. Here we report a new method to generate UB organoids that possess epithelial polarity and tubular lumen and repeat branching morphogenesis. We also succeeded in monitoring UB tip cells by utilizing the ability of tip cells to uptake very-low-density lipoprotein, cryopreserving UB progenitor cells and expanding UB tip cells that can reconstitute the organoids and differentiate into collecting duct progenitors. Moreover, we successfully reproduced some phenotypes of multicystic dysplastic kidney (MCDK) using the UB organoids. These methods will help elucidate the developmental mechanisms of UB branching and develop a selective differentiation method for collecting duct cells, contributing to the creation of disease models for congenital renal abnormalities.