Project description:The distal convoluted tubule (DCT) plays a key role in the fine-tuning of renal Mg2+ reabsorption. In recent years, hereditary magnesium (Mg2+) transport disorders have helped to identify important players in DCT Mg2+ homeostasis. Here, we report the Mg2+-sensitive transcriptional expression of the DCT transcriptome using gene expression microarray analysis. Mice expressing eGFP under a DCT-specific promoter were subjected to Mg2+-deficient or Mg2+-enriched diets. Subsequently, the Complex Object Parametric Analyzer and Sorter (COPAS) allowed isolation of eGFP-positive DCT cells. RNA extracts were subjected to pair-wise microarray analysis, high vs. low Mg2+. Of all genes in the genome, 46 were shown to be differentially expressed with a minimal fold-change of 2. Several known magnesiotropic genes, such as Trpm6 and Parvalbumin, were upregulated in the low Mg2+ fraction. Moreover, new genes were identified that are potentially involved in renal Mg2+ homeostasis. To confirm that the selected candidate genes are regulated by dietary Mg2+ availability, the expression levels of Slc41a3, Pcbd1, Tbc1d4 and Umod were determined by RT-PCR analysis. Indeed, all four genes were shown to be significantly upregulated in mice fed the Mg2+-deficient diet. In conclusion, by elucidating the Mg2+-sensitive DCT transcriptome, new candidate players in renal Mg2+ homeostasis were identified. RNA samples were isolated from PV-eGFP-positive tubules from mice fed on a low (L-samples) or high (H-samples) magnesium diet. Littermate H and L samples were labeled and put on mouse microarrays together. Two of the four sample sets were analyzed in dye-swap to compensate for dye-biases.

Project description:The renal distal convoluted tubule DCT is a short part of the distal nephron with specific functions transporting ions and thereby modifying Na, Ca, Mg, K balance A transcriptomic analysis of the DCT was performed to identify specific gene expression which would implicate those genes in specific DCT function

Project description:The renal distal convoluted tubule DCT is a short part of the distal nephron with specific functions transporting ions and thereby modifying Na, Ca, Mg, K balance A transcriptomic analysis of the DCT was performed to identify specific gene expression which would implicate those genes in specific DCT function Fluorescent DCT (EGFP+) were sorted out from a renal tubule suspension by a COPAS (Complex Object Parametric analyser and sorter). EGFP- and the total (ALL) fractions were also sorted by COPAS. Gene expression for each fractions (EGFP+, EGFP-, ALL) was performed in 4 mice

Project description:The transient receptor potential melastatin type 6 (TRPM6) is a divalent cation channel pivotal for gatekeeping Mg2+ balance. To study the role of TRPM6 in the intestine, we generated mice lacking intestinal TRPM6 (Vill1-TRPM6-/-). In this study, the distal colon of Vill1-TRPM6-/- mice and of the control mice (TRPM6fl/fl) was subjected to RNA sequencing.

Project description:The distal convoluted tubule (DCT) and the cortical collecting ducts (CCD) are portions of renal tubule that are partly responsible for maintaining the systemic concentrations of potassium, sodium, calcium and magnesium. Despite being structurally similar, DCT and CCD cells have different transport capabilities due to a variety of different membrane-associated transport proteins. However, DCT and CCD cells appear to be modulated via the same hormones. The objective of this study was assess the differential response of DCT and CCD cells to long-term exposure to the hormones vasopressin or angiotensin II, both of which modulate DCT and CCD cells differently. Mass spectrometry based quantitative proteomics was used to profile the differential proteome between DCT and CCD.

Project description:Distal convoluted tubule (DCT) cells display a remarkable ability to adapt to the dietary potassium intake. We applied single-nucleus RNA-seq to map the plasticity of enriched mouse DCT cells in response to dietary potassium restriction

Project description:The “aldosterone paradox” is a poorly understood physiological mechanism in which increases in the hormone aldosterone either serve to stabilize blood pressure by increasing sodium-chloride (NaCl) reabsorption or to excrete potassium (K+). Under low NaCl intake, abundance and activity of the thiazide-sensitive NaCl cotransporter NCC, expressed in the distal convoluted tubule (DCT), is high, whereas it is low during high K+ intake - leading to increased delivery of NaCl to downstream segments and increased electrogenic K+ secretion. Despite a critical role in blood pressure and K+ homeostasis, little is known about the molecular alterations in the DCT during the aldosterone paradox, and how they control NCC levels. The objective of this study was to define the proteome of the DCT and how it is modified by increased circulating aldosterone levels subsequent to long-term low dietary NaCl or high K+ intake.

Project description:Kidney distal convoluted tubules (DCT) are important for regulation of urinary salt excretion. Aldosterone is known to exert long-term effects in this segment, and regulate sodium reabsorption via increasing abundance of the Na+-Cl- cotransporter (NCC) and the epithelial Na channel ENaC. Whether acute effects of aldosterone occur in the DCT and the potential signaling networks remain unknown. Here in this study, we aim to identify the acute aldosterone-mediated signaling (rapid effects) in the DCT.

Project description:In vitro studies identified TBC1D4 as an regulator of renal ion and water transporting proteins. However, TBC1D4-deficient mice did not show a defective renal salt and water homeostasis. With microarray analysis we aimed to decipher compensatory mechanisms in TBC1D4-deficient mice which might mask the renal phenotype already on transciptomic levels. We used and compared mRNA of COPAS-sorted and -enriched distal convoluted tubule (DCT)-cells, known to express TBC1D4 at high levels, of 8-week old male homogenous C57/Bl6 mice of TBC1D4-deficient and wild-type mice.

Project description:The sympathetic nervous system (SNS) plays a central role in blood pressure regulation. Recent studies have shown that cells of the distal convoluted tubule (DCT) can be stimulated directly via the beta-adrenergic receptor resulting in activation of the NaCl cotransporter NCC. Whether these effects are mediated by the beta1- or beta2-adrenergic receptor is unclear, and the acute signaling cascades rapidly activated by beta-adrenergic receptor stimulation in the DCT are unknown. Here in this study, we aim to identify the rapid salbutamol-mediated (beta2-adrenergic receptor) signaling in the DCT by looking at global protein phosphorylation changes in the mpkDCT cells.