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Isoforms of the Na-K-2Cl cotransporter in murine TAL I. Molecular characterization and intrarenal localization. , Mount DB., Am J Physiol. March 1, 1999; 276 (3): F347-58.
Serum- and glucocorticoid-dependent kinase, cell volume, and the regulation of epithelial transport. , Fillon S., Comp Biochem Physiol A Mol Integr Physiol. October 1, 2001; 130 (3): 367-76.
Spatially distributed alternative splice variants of the renal Na-K-Cl cotransporter exhibit dramatically different affinities for the transported ions. , Giménez I., J Biol Chem. March 15, 2002; 277 (11): 8767-70.
Barttin increases surface expression and changes current properties of ClC-K channels. , Waldegger S., Pflugers Arch. June 1, 2002; 444 (3): 411-8.
Functional and molecular characterization of the shark renal Na-K-Cl cotransporter: novel aspects. , Gagnon E., Am J Physiol Renal Physiol. November 1, 2002; 283 (5): F1046-55.
Molecular mechanisms of Cl- transport by the renal Na(+)-K(+)-Cl- cotransporter. Identification of an intracellular locus that may form part of a high affinity Cl(-)-binding site. , Gagnon E., J Biol Chem. February 13, 2004; 279 (7): 5648-54.
Proximo- distal specialization of epithelial transport processes within the Xenopus pronephric kidney tubules. , Zhou X , Zhou X ., Dev Biol. July 15, 2004; 271 (2): 322-38.
Global analysis of RAR-responsive genes in the Xenopus neurula using cDNA microarrays. , Arima K., Dev Dyn. February 1, 2005; 232 (2): 414-31.
Pronephric regulation of acid-base balance; coexpression of carbonic anhydrase type 2 and sodium-bicarbonate cotransporter-1 in the late distal segment. , Zhou X ., Dev Dyn. May 1, 2005; 233 (1): 142-4.
Novel insights regarding the operational characteristics and teleological purpose of the renal Na+-K+-Cl2 cotransporter (NKCC2s) splice variants. , Brunet GM., J Gen Physiol. October 1, 2005; 126 (4): 325-37.
WNK3 kinase is a positive regulator of NKCC2 and NCC, renal cation-Cl- cotransporters required for normal blood pressure homeostasis. , Rinehart J., Proc Natl Acad Sci U S A. November 15, 2005; 102 (46): 16777-82.
FGF is essential for both condensation and mesenchymal-epithelial transition stages of pronephric kidney tubule development. , Urban AE ., Dev Biol. September 1, 2006; 297 (1): 103-17.
Odd-skipped genes encode repressors that control kidney development. , Tena JJ., Dev Biol. January 15, 2007; 301 (2): 518-31.
The residues determining differences in ion affinities among the alternative splice variants F, A, and B of the mammalian renal Na-K-Cl cotransporter ( NKCC2). , Giménez I., J Biol Chem. March 2, 2007; 282 (9): 6540-7.
WNK4 kinase is a negative regulator of K+-Cl- cotransporters. , Garzón-Muvdi T., Am J Physiol Renal Physiol. April 1, 2007; 292 (4): F1197-207.
Xenopus Bicaudal-C is required for the differentiation of the amphibian pronephros. , Tran U ., Dev Biol. July 1, 2007; 307 (1): 152-64.
The prepattern transcription factor Irx3 directs nephron segment identity. , Reggiani L., Genes Dev. September 15, 2007; 21 (18): 2358-70.
The cdx genes and retinoic acid control the positioning and segmentation of the zebrafish pronephros. , Wingert RA., PLoS Genet. October 1, 2007; 3 (10): 1922-38.
Organization of the pronephric kidney revealed by large-scale gene expression mapping. , Raciti D ., Genome Biol. January 1, 2008; 9 (5): R84.
Cotransporters, WNKs and hypertension: an update. , Flatman PW., Curr Opin Nephrol Hypertens. March 1, 2008; 17 (2): 186-92.
Surface expression of epithelial Na channel protein in rat kidney. , Frindt G., J Gen Physiol. June 1, 2008; 131 (6): 617-27.
Renal Na+-K+-Cl- cotransporter activity and vasopressin-induced trafficking are lipid raft-dependent. , Welker P., Am J Physiol Renal Physiol. September 1, 2008; 295 (3): F789-802.
A dual requirement for Iroquois genes during Xenopus kidney development. , Alarcón P., Development. October 1, 2008; 135 (19): 3197-207.
Requirement of Wnt/beta-catenin signaling in pronephric kidney development. , Lyons JP., Mech Dev. January 1, 2009; 126 (3-4): 142-59.
Parameter estimation for mathematical models of NKCC2 cotransporter isoforms. , Marcano M., Am J Physiol Renal Physiol. February 1, 2009; 296 (2): F369-81.
The miR-30 miRNA family regulates Xenopus pronephros development and targets the transcription factor Xlim1/ Lhx1. , Agrawal R ., Development. December 1, 2009; 136 (23): 3927-36.
Functional expression of the Na-K-2Cl cotransporter NKCC2 in mammalian cells fails to confirm the dominant-negative effect of the AF splice variant. , Hannemann A., J Biol Chem. December 18, 2009; 284 (51): 35348-58.
Localization and functional characterization of the human NKCC2 isoforms. , Carota I., Acta Physiol (Oxf). July 1, 2010; 199 (3): 327-38.
Inversin relays Frizzled-8 signals to promote proximal pronephros development. , Lienkamp S ., Proc Natl Acad Sci U S A. November 23, 2010; 107 (47): 20388-93.
Downregulation of NCC and NKCC2 cotransporters by kidney-specific WNK1 revealed by gene disruption and transgenic mouse models. , Liu Z., Hum Mol Genet. March 1, 2011; 20 (5): 855-66.
WNK2 kinase is a novel regulator of essential neuronal cation-chloride cotransporters. , Rinehart J., J Biol Chem. August 26, 2011; 286 (34): 30171-80.
Xenopus as a model system for the study of GOLPH2/ GP73 function: Xenopus GOLPH2 is required for pronephros development. , Li L., PLoS One. January 1, 2012; 7 (6): e38939.
A minor role of WNK3 in regulating phosphorylation of renal NKCC2 and NCC co-transporters in vivo. , Oi K., Biol Open. February 15, 2012; 1 (2): 120-7.
Cotransport of water by Na⁺-K⁺-2Cl⁻ cotransporters expressed in Xenopus oocytes: NKCC1 versus NKCC2. , Zeuthen T., J Physiol. March 1, 2012; 590 (5): 1139-54.
HNF1B controls proximal-intermediate nephron segment identity in vertebrates by regulating Notch signalling components and Irx1/2. , Heliot C., Development. February 1, 2013; 140 (4): 873-85.
Regulation of G-protein signaling via Gnas is required to regulate proximal tubular growth in the Xenopus pronephros. , Zhang B., Dev Biol. April 1, 2013; 376 (1): 31-42.
ANKS6 is a central component of a nephronophthisis module linking NEK8 to INVS and NPHP3. , Hoff S., Nat Genet. August 1, 2013; 45 (8): 951-6.
Regulation of NKCC2 activity by inhibitory SPAK isoforms: KS- SPAK is a more potent inhibitor than SPAK2. , Park HJ., Am J Physiol Renal Physiol. December 15, 2013; 305 (12): F1687-96.
Differential expression of arid5b isoforms in Xenopus laevis pronephros. , Le Bouffant R ., Int J Dev Biol. January 1, 2014; 58 (5): 363-8.
MicroRNAs are critical regulators of tuberous sclerosis complex and mTORC1 activity in the size control of the Xenopus kidney. , Romaker D., Proc Natl Acad Sci U S A. April 29, 2014; 111 (17): 6335-40.
The Wnt/ JNK signaling target gene alcam is required for embryonic kidney development. , Cizelsky W., Development. May 1, 2014; 141 (10): 2064-74.
Sterol carrier protein 2 regulates proximal tubule size in the Xenopus pronephric kidney by modulating lipid rafts. , Cerqueira DM., Dev Biol. October 1, 2014; 394 (1): 54-64.
Short forms of Ste20-related proline/alanine-rich kinase ( SPAK) in the kidney are created by aspartyl aminopeptidase ( Dnpep)-mediated proteolytic cleavage. , Markadieu N., J Biol Chem. October 17, 2014; 289 (42): 29273-84.
Pax8 and Pax2 are specifically required at different steps of Xenopus pronephros development. , Buisson I ., Dev Biol. January 15, 2015; 397 (2): 175-90.
Structure-activity relationships of bumetanide derivatives: correlation between diuretic activity in dogs and inhibition of the human NKCC2A transporter. , Lykke K., Br J Pharmacol. September 1, 2015; 172 (18): 4469-4480.
ROMK expression remains unaltered in a mouse model of familial hyperkalemic hypertension caused by the CUL3Δ403-459 mutation. , Murthy M., Physiol Rep. July 1, 2016; 4 (13):
Renal localization and regulation by dietary phosphate of the MCT14 orphan transporter. , Knöpfel T., PLoS One. June 29, 2017; 12 (6): e0177942.
lrpap1 as a specific marker of proximal pronephric kidney tubuli in Xenopus laevis embryos. , Neuhaus H ., Int J Dev Biol. January 1, 2018; 62 (4-5): 319-324.
Polycystin 1 loss of function is directly linked to an imbalance in G-protein signaling in the kidney. , Zhang B., Development. March 22, 2018; 145 (6):
Mutations in PRDM15 Are a Novel Cause of Galloway-Mowat Syndrome. , Mann N., J Am Soc Nephrol. March 1, 2021; 32 (3): 580-596.