Cellular and subcellular localization of the vasopressin- regulated urea transporter in rat kidney.

Nielsen, Søren; Terris, James; Smith, Craig P.; Hediger, Matthias A.; Ecelbarger, Carolyn A.; Knepper, Mark A.

doi:10.1073/pnas.93.11.5495

Cited by 173 publications

(180 citation statements)

References 23 publications

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“…In these two zones, urea transporters are not expressed homogeneously. In IS, UT-A2 has been localized in the deep but not in the superficial half of thin descending limb (TDL) of short loops of Henle [14,16,18]. In IM, facilitated urea transport has been shown in the terminal but not in the initial inner medullary collecting duct (CD) (IMCD) [19] and UT-A1 mRNA have been localized in IM tip but not in IM base [18].…”

Section: Methodsmentioning

confidence: 99%

“…Both UT-A1 and UT-A2 are expressed exclusively in the kidney and are encoded by differential transcription from the same gene. Both UT-A2 and UT-B1 are present on the luminal and the basolateral membranes along a limited length of thin descending limbs (TDL) for UT-A2 [16] and in the endothelium of descending vasa recta along most of their length for UT-B1 [17].…”

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Aquaporin-2 and urea transporter-A1 are up-regulated in rats with Type I diabetes mellitus

et al. 2001

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In diabetes mellitus, water turnover in the body is enhanced because of the glucose-induced osmotic diuresis and it is usually assumed that the concentrating capacity of the kidney is partially impaired. On the other hand, plasma vasopressin concentration is known to be increased by several fold in patients with Type I (insulin-dependent) diabetes mellitus or Type II (non-insulin-dependent) diabetes mellitus as well as in animal models of experimental or genetic diabetes mellitus [1±6]. This high vasopressin concentration is accompanied by a desensitization of V1 a receptors in liver, kidney and platelets [7,8]. In contrast, renal V2 receptors, responsible for the antidiuretic action of the hormone, are not down-regulated [8].Actually, higher vasopressin in diabetes mellitus probably represents an appropriate adaptation by limiting to some extent the amount of water required Abstract Aims/hypothesis. Although the urine flow rate is considerably higher in diabetes mellitus, water reabsorption is greatly increased to concentrate an increased amount of solutes. Our study evaluated the expression of aquaporins and urea transporters, which are essential to the urinary concentration process. Methods. Northern blot and immunoblot were used to quantify mRNA and proteins for aquaporin-2 (AQP2) as well as urea transporters UT-A1, UT-A2 and UT-B1, in subzones of the renal medulla of rats with streptozotocin-induced diabetes. Results. In these rats, glycaemia, urine flow rate and water reabsorption were respectively fourfold, ninefold and fourfold those of control rats. The AQP2 protein isoforms were significantly up-regulated in outer and inner medulla. In the base and tip of inner medulla, UT-A1 mRNA was significantly up-regulated (three-and 1.3-fold, respectively) as well as the 117 kD protein (ten-and threefold, respectively) whereas the 97 kD protein was not changed or decreased twofold, respectively. This suggests that, in diabetes, the inner medullary collecting duct is endowed with more UT-A1, especially in its initial part. In the case of mRNA and proteins of UT-A2, located in thin descending limbs in the inner stripe of outer medulla, they were respectively not changed and down-regulated in diabetic rats. Conclusion/interpretation. This study shows that in diabetes, the increased expression of AQP2 and UT-A1 in medullary collecting duct is consistent with an improved concentrating activity. In addition, the underexpression of UT-A2 and the overexpression of UT-A1 in the initial medullary collecting duct are reminiscent of the changes seen after experimental reduction of urine concentration or low protein feeding. [Diabetologia (2001) 44: 637±645]

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Section: Methodsmentioning

confidence: 99%

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Aquaporin-2 and urea transporter-A1 are up-regulated in rats with Type I diabetes mellitus

et al. 2001

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“…Several UT-A proteins are derived from the UT-A gene by the process of alternative splicing, including UT-A1 and UT-A3, expressed in the IMCD (12,13), UT-A2, expressed in the thin descending limb of Henle (14), and UT-A5, expressed in testis (15). The UT-B gene encodes only a single protein, and recently UT-B-deficient mice, which manifest a defect in the urinary concentrating mechanism, have been generated (16).…”

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confidence: 99%

Urinary concentrating defect in mice with selective deletion of phloretin-sensitive urea transporters in the renal collecting duct

Fenton

Chou

Stewart

et al. 2004

Proc. Natl. Acad. Sci. U.S.A.

227

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To investigate the role of inner medullary collecting duct (IMCD) urea transporters in the renal concentrating mechanism, we deleted 3 kb of the UT-A urea transporter gene containing a single 140-bp exon (exon 10). Deletion of this segment selectively disrupted expression of the two known IMCD isoforms of UT-A, namely UT-A1 and UT-A3, producing UT-A1͞3 ؊/؊ mice. In isolated perfused IMCDs from UT-A1͞3 ؊/؊ mice, there was a complete absence of phloretin-sensitive or vasopressin-stimulated urea transport. On a normal protein intake (20% protein diet), UT-A1͞ 3 ؊/؊ mice had significantly greater fluid consumption and urine flow and a reduced maximal urinary osmolality relative to wildtype controls. These differences in urinary concentrating capacity were nearly eliminated when urea excretion was decreased by dietary protein restriction (4% by weight), consistent with the 1958 Berliner hypothesis stating that the chief role of IMCD urea transport in the concentrating mechanism is the prevention of ureainduced osmotic diuresis. Analysis of inner medullary tissue after water restriction revealed marked depletion of urea in UT-A1͞3 ؊/؊ mice, confirming the concept that phloretin-sensitive IMCD urea transporters play a central role in medullary urea accumulation. However, there were no significant differences in mean inner medullary Na ؉ or Cl ؊ concentrations between UT-A1͞3 ؊/؊ mice and wild-type controls, indicating that the processes that concentrate NaCl were intact. Thus, these results do not corroborate the predictions of passive medullary concentrating models stating that NaCl accumulation in the inner medulla depends on rapid vasopressin-regulated urea transport across the IMCD epithelium.UT-A ͉ isolated perfused tubule ͉ vasopressin ͉ concentrating mechanism F or survival remote from water sources, terrestrial animals require effective water-conservation mechanisms. In birds and mammals, water conservation depends on specialized urinary concentrating mechanisms that reduce water excretion while maintaining solute excretion. This concentrating function is carried out in the renal medulla. In mammals, the medulla is divided into two regions, the outer medulla and the inner medulla (IM), both of which manifest increased tissue osmolality relative to the blood plasma (1). In these regions, high interstitial osmolality draws water from the renal collecting duct via aquaporin water channels, resulting in a concentrated final urine. In the outer medulla, the interstitial space is concentrated through the classic countercurrent multiplication mechanism (2) in which water and solute are separated by active NaCl transport from the water-impermeable thick ascending limb of Henle (3, 4). However, in the IM the ascending portion of Henle's loop is incapable of high rates of active transport (5, 6), implying that solute concentration in the IM occurs by a different, yet unknown mechanism.One important feature of the IM that distinguishes it from the outer medulla is its ability to accumulate large amounts of urea. Berliner ...

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“…Although we could not identify functional differences between strUT-1 and strUT-2, the finding that the expression of only strUT-2c was lower in rays exposed to a 50% reduction in salinity (discussed below) indicates that the two transporter isoforms could play different roles in tubular reabsorption of urea. Different roles of strUT-1 and strUT-2 in renal urea reabsorption might arise from expression in different nephron segments, which is the case for various isoforms of the UT-A transporters within the mammalian kidney (25,38) or trafficking to different membrane domains in polarized epithelia. Further, similar regulatory mechanisms could contribute to the selective expression of one or more of the 3ЈUTR variants of the strUT-1 and strUT-2 isoforms at different sites along the nephron.…”

Section: Discussionmentioning

confidence: 99%

Cloning and functional characterization of a second urea transporter from the kidney of the Atlantic stingray,Dasyatis sabina

Janech¹,

Fitzgibbon²,

Nowak³

et al. 2006

American Journal of Physiology-Regulatory, Integrative and Comp

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. Cloning and functional characterization of a second urea transporter from the kidney of the Atlantic stingray, Dasyatis sabina. Am J Physiol Regul Integr Comp Physiol 291: R844 -R853, 2006. First published April 13, 2006; doi:10.1152/ajpregu.00739.2005.-The cloning of cDNAs encoding facilitated urea transporters (UTs) from the kidneys of the elasmobranchs indicates that in these fish renal urea reabsorption occurs, at least in part, by passive processes. The previously described elasmobranch urea transporter clones from shark (shUT) and stingray (strUT-1) differ from each other primarily because of the COOHterminus of the predicted strUT-1 translation product being extended by 51-amino acid residues compared with shUT. Previously, we noted multiple UT transcripts were present in stingray kidney. We hypothesized that a COOH terminally abbreviated UT isoform, homologous to shUT, would also be present in stingray kidney. Therefore, we used 5Ј/3Ј rapid amplification of cDNA ends to identify a 3ЈUTR-variant (strUT-1a) of the cDNA that encodes (strUT-1), as well as three, 3ЈUTR-variant cDNAs (strUT-2a,b,c) that encode a second phloretinsensitive, urea transporter (strUT-2). The 5ЈUTR and the first 1,132 nucleotides of the predicted coding region of the strUT-2 cDNAs are identical to the strUT-1 cDNAs. The remainder of the coding region contains only five novel nucleotides. The strUT-2 cDNAs putatively encode a 379-amino acid protein, the first 377 amino acids identical to strUT-1 plus 2 additional amino acids. We conclude that 1) a second UT isoform is expressed in the Atlantic stingray and that this isoform is similar in size to the UT previously cloned from the kidney of the dogfish shark, and 2) at least five transcripts encoding the 2 stingray UTs are derived from a single gene product through alternative splicing and polyadenylation. elasmobranch; euryhaline; alternative splicing; osmoregulation MARINE ELASMOBRANCHS (sharks, skates, and rays) use a unique volume-and osmoregulatory strategy; in general, they maintain their body fluids hyperosmotic to the ambient environment (for a review, see Ref. 15; see also 29,42). The high body fluid osmolality is achieved, in large part, by the retention of urea. At ocean salinities, plasma urea concentrations average 350 mmol/l, and urea contributes 30 -50% of the plasma osmolality (for a review, see Ref. 15). The use of this strategy for body fluid volume regulation necessitates the efficient reabsorption of most of the filtered load of urea by the kidneys. For marine elasmobranchs maintained at ocean salinities, fractional urea reabsorption is 90 -98% (9, 14, 34).

show abstract

Cellular and subcellular localization of the vasopressin- regulated urea transporter in rat kidney.

Cited by 173 publications

References 23 publications

Aquaporin-2 and urea transporter-A1 are up-regulated in rats with Type I diabetes mellitus

Aquaporin-2 and urea transporter-A1 are up-regulated in rats with Type I diabetes mellitus

Urinary concentrating defect in mice with selective deletion of phloretin-sensitive urea transporters in the renal collecting duct

Cloning and functional characterization of a second urea transporter from the kidney of the Atlantic stingray,Dasyatis sabina

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