We used a systems biology-based approach to investigate the basis of cell-specific expression of the water channel aquaporin-2 (AQP2) in the renal collecting duct. Computational analysis of the 5-flanking region of the AQP2 gene (Genomatix) revealed 2 conserved clusters of putative transcriptional regulator (TR) binding elements (BEs) centered at ؊513 bp (corresponding to the SF1, NFAT, and FKHD TR families) and ؊224 bp (corresponding to the AP2, SRF, CREB, GATA, and HOX TR families). Three other conserved motifs corresponded to the ETS, EBOX, and RXR TR families. To identify TRs that potentially bind to these BEs, we carried out mRNA profiling (Affymetrix) in mouse mpkCCDc14 collecting duct cells, revealing expression of 25 TRs that are also expressed in native inner medullary collecting duct. One showed a significant positive correlation with AQP2 mRNA abundance among mpkCCD subclones (Ets1), and 2 showed a significant negative correlation (Elf1 and an orphan nuclear receptor Nr1h2). Transcriptomic profiling in native proximal tubules (PT), medullary thick ascending limbs (MTAL), and IMCDs from kidney identified 14 TRs (including Ets1 and HoxD3) expressed in the IMCD but not PT or MTAL (candidate AQP2 enhancer roles), and 5 TRs (including HoxA5, HoxA9 and HoxA10) expressed in PT and MTAL but not in IMCD (candidate AQP2 repressor roles). In luciferase reporter assays, overexpression of 3 ETS family TRs transactivated the mouse proximal AQP2 promoter. The results implicate ETS family TRs in cell-specific expression of AQP2 and point to HOX, RXR, CREB and GATA family TRs as playing likely additional roles.aquaporin 2 ͉ kidney ͉ microarrays ͉ transcription ͉ vasopressin R enal water excretion is tightly regulated chiefly through effects of vasopressin on the molecular water channel, aquaporin-2 (AQP2) (1). AQP2 gene expression in the kidney is restricted to collecting duct principal cells and connecting tubule cells (2, 3). Aside from control of trafficking of AQP2-containing vesicles (1), AQP2 is regulated through changes in the total abundance of the AQP2 protein in collecting duct cells. Vasopressin increases the renal abundance of the AQP2 protein (4) via changes in AQP2 mRNA levels (5), in part by transcriptional regulation. Studies in transgenic mice in which 14-15 kb of the 5Ј-flanking region of the AQP2 gene was coupled to reporters established that cell-specific expression of the AQP2 gene in the collecting duct is dependent on cis-elements in this region (6, 7). Altered AQP2 protein abundance in the renal collecting duct is largely responsible for water balance abnormalities associated with diverse clinical states including lithium-induced diabetes insipidus, congestive heart failure, and the syndrome of inappropriate antidiuresis (1). Understanding the roles of AQP2 in these clinical states hinges largely on understanding the mechanism of cell-specific expression of the AQP2 gene.Sequencing of the 5Ј-flanking region of the AQP2 gene revealed several putative cis-binding element (BE) motifs including a c...
pressin acts on the inner medullary collecting duct (IMCD) in the kidney to regulate water and urea transport. To obtain a "parts list" of gene products expressed in the IMCD, we carried out mRNA profiling of freshly isolated rat IMCD cells using Affymetrix Rat 230 2.0 microarrays with ϳ31,000 features; 7,913 annotated transcripts were found to be expressed above background in the IMCD cells. We have created a new online database (the "IMCD Transcriptome Database;" http://dir.nhlbi.nih.gov/papers/lkem/imcdtr/) to make the results publicly accessible. Among the 30 transcripts with the greatest signals on the arrays were 3 water channels: aquaporin-2, aquaporin-3, and aquaporin-4, all of which have been reported to be targets for regulation by vasopressin. In addition, the transcript with the greatest signal among members of the solute carrier family of genes was the UT-A urea transporter (Slc14a2), which is also regulated by vasopressin. The V2 vasopressin receptor was strongly expressed, but the V1a and V1b vasopressin receptors did not produce signals above background. Among the 200 protein kinases expressed, the serumglucocorticoid-regulated kinase (Sgk1) had the greatest signal intensity in the IMCD. WNK1 and WNK4 were also expressed in the IMCD with a relatively high signal intensity, as was protein kinase A (-catalytic subunit). In addition, a large number of transcripts corresponding to A kinase anchoring proteins and 14-3-3 proteins (phospho-S/T-binding proteins) were expressed. Altogether, the results combine with proteomics studies of the IMCD to provide a framework for modeling complex interaction networks responsible for vasopressin action in collecting duct cells. oligonucleotide array; vasopressin; aquaporin-2; urea transport; kinases THE INNER MEDULLARY COLLECTING DUCT (IMCD) is the terminal portion of the collecting duct system of the kidney. The collecting duct system represents the final site of adjustment of urinary composition and volume and therefore is critical for extracellular fluid homeostasis. An important regulator of collecting duct transport function is vasopressin, which controls both water and urea transport (21,53).To address the mechanisms of vasopressin signaling in the renal IMCD, we have been following a "systems-biology" approach consisting of identification of the component proteins via protein mass spectrometry-based analysis (2,29,30,62,71,102) and antibody-based quantification of protein abundance (41) coupled to computational analysis of the identified proteins to discover signaling networks involved in IMCD regulation (30).
Hypercalcemia can cause renal dysfunction such as nephrogenic diabetes insipidus (NDI), but the mechanisms underlying hypercalcemia-induced NDI are not well understood. To elucidate the early molecular changes responsible for this disorder, we employed mass spectrometry-based proteomic analysis of inner medullary collecting ducts (IMCD) isolated from parathyroid hormone-treated rats at onset of hypercalcemia-induced NDI. Forty-one proteins, including the water channel aquaporin-2, exhibited significant changes in abundance, most of which were decreased. Bioinformatic analysis revealed that many of the downregulated proteins were associated with cytoskeletal protein binding, regulation of actin filament polymerization, and cell-cell junctions. Targeted LC-MS/MS and immunoblot studies confirmed the downregulation of 16 proteins identified in the initial proteomic analysis and in additional experiments using a vitamin D treatment model of hypercalcemia-induced NDI. Evaluation of transcript levels and estimated half-life of the downregulated proteins suggested enhanced protein degradation as the possible regulatory mechanism. Electron microscopy showed defective intercellular junctions and autophagy in the IMCD cells from both vitamin D- and parathyroid hormone-treated rats. A significant increase in the number of autophagosomes was confirmed by immunofluorescence labeling of LC3. Colocalization of LC3 and Lamp1 with aquaporin-2 and other downregulated proteins was found in both models. Immunogold electron microscopy revealed aquaporin-2 in autophagosomes in IMCD cells from both hypercalcemia models. Finally, parathyroid hormone withdrawal reversed the NDI phenotype, accompanied by termination of aquaporin-2 autophagic degradation and normalization of both nonphoshorylated and S256-phosphorylated aquaporin-2 levels. Thus, enhanced autophagic degradation of proteins plays an important role in the initial mechanism of hypercalcemic-induced NDI.
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