Literature DB >> 19240212

Angiotensin II signaling increases activity of the renal Na-Cl cotransporter through a WNK4-SPAK-dependent pathway.

Pedro San-Cristobal1, Diana Pacheco-Alvarez, Ciaran Richardson, Aaron M Ring, Norma Vazquez, Fatema H Rafiqi, Divya Chari, Kristopher T Kahle, Qiang Leng, Norma A Bobadilla, Steven C Hebert, Dario R Alessi, Richard P Lifton, Gerardo Gamba.   

Abstract

Mutations in the kinase WNK4 cause pseudohypoaldosteronism type II (PHAII), a syndrome featuring hypertension and high serum K(+) levels (hyperkalemia). WNK4 has distinct functional states that regulate the balance between renal salt reabsorption and K(+) secretion by modulating the activities of renal transporters and channels, including the Na-Cl cotransporter NCC and the K(+) channel ROMK. WNK4's functions could enable differential responses to intravascular volume depletion (hypovolemia) and hyperkalemia. Because hypovolemia is uniquely associated with high angiotensin II (AngII) levels, AngII signaling might modulate WNK4 activity. We show that AngII signaling in Xenopus oocytes increases NCC activity by abrogating WNK4's inhibition of NCC but does not alter WNK4's inhibition of ROMK. This effect requires AngII, its receptor AT1R, and WNK4, and is prevented by the AT1R inhibitor losartan. NCC activity is also increased by WNK4 harboring mutations found in PHAII, and this activity cannot be further augmented by AngII signaling, consistent with PHAII mutations providing constitutive activation of the signaling pathway between AT1R and NCC. AngII's effect on NCC is also dependent on the kinase SPAK because dominant-negative SPAK or elimination of the SPAK binding motif in NCC prevent activation of NCC by AngII signaling. These effects extend to mammalian cells. AngII increases phosphorylation of specific sites on SPAK and NCC that are necessary for activation of each in mpkDCT cells. These findings place WNK4 in the signaling pathway between AngII and NCC, and provide a mechanism by which hypovolemia maximizes renal salt reabsoprtion without concomitantly increasing K(+) secretion.

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Year:  2009        PMID: 19240212      PMCID: PMC2647339          DOI: 10.1073/pnas.0813238106

Source DB:  PubMed          Journal:  Proc Natl Acad Sci U S A        ISSN: 0027-8424            Impact factor:   11.205


  40 in total

1.  Affinity-defining domains in the Na-Cl cotransporter: a different location for Cl- and thiazide binding.

Authors:  Erika Moreno; Pedro San Cristóbal; Manuel Rivera; Norma Vázquez; Norma A Bobadilla; Gerardo Gamba
Journal:  J Biol Chem       Date:  2006-04-19       Impact factor: 5.157

2.  WNK4 kinase is a negative regulator of K+-Cl- cotransporters.

Authors:  Tomas Garzón-Muvdi; Diana Pacheco-Alvarez; Kenneth B E Gagnon; Norma Vázquez; José Ponce-Coria; Erika Moreno; Eric Delpire; Gerardo Gamba
Journal:  Am J Physiol Renal Physiol       Date:  2006-12-19

3.  WNK4 regulates activity of the epithelial Na+ channel in vitro and in vivo.

Authors:  Aaron M Ring; Sam X Cheng; Qiang Leng; Kristopher T Kahle; Jesse Rinehart; Maria D Lalioti; Heather M Volkman; Frederick H Wilson; Steven C Hebert; Richard P Lifton
Journal:  Proc Natl Acad Sci U S A       Date:  2007-02-26       Impact factor: 11.205

4.  Angiotensin II inhibits the ROMK-like small conductance K channel in renal cortical collecting duct during dietary potassium restriction.

Authors:  Yuan Wei; Beth Zavilowitz; Lisa M Satlin; Wen-Hui Wang
Journal:  J Biol Chem       Date:  2006-12-28       Impact factor: 5.157

5.  WNK1 and OSR1 regulate the Na+, K+, 2Cl- cotransporter in HeLa cells.

Authors:  Anthony N Anselmo; Svetlana Earnest; Wei Chen; Yu-Chi Juang; Sung Chan Kim; Yingming Zhao; Melanie H Cobb
Journal:  Proc Natl Acad Sci U S A       Date:  2006-07-10       Impact factor: 11.205

6.  Regulation of the expression of the Na/Cl cotransporter by WNK4 and WNK1: evidence that accelerated dynamin-dependent endocytosis is not involved.

Authors:  Amir P Golbang; Georgina Cope; Abbas Hamad; Meena Murthy; Che-Hsiung Liu; Alan W Cuthbert; Kevin M O'shaughnessy
Journal:  Am J Physiol Renal Physiol       Date:  2006-06-20

7.  Wnk4 controls blood pressure and potassium homeostasis via regulation of mass and activity of the distal convoluted tubule.

Authors:  Maria D Lalioti; Junhui Zhang; Heather M Volkman; Kristopher T Kahle; Kristin E Hoffmann; Hakan R Toka; Carol Nelson-Williams; David H Ellison; Richard Flavell; Carmen J Booth; Yin Lu; David S Geller; Richard P Lifton
Journal:  Nat Genet       Date:  2006-09-10       Impact factor: 38.330

8.  Molecular pathogenesis of pseudohypoaldosteronism type II: generation and analysis of a Wnk4(D561A/+) knockin mouse model.

Authors:  Sung-Sen Yang; Tetsuji Morimoto; Tatemitsu Rai; Motoko Chiga; Eisei Sohara; Mayuko Ohno; Keiko Uchida; Shih-Hua Lin; Tetsuo Moriguchi; Hiroshi Shibuya; Yoshiaki Kondo; Sei Sasaki; Shinichi Uchida
Journal:  Cell Metab       Date:  2007-05       Impact factor: 27.287

9.  An SGK1 site in WNK4 regulates Na+ channel and K+ channel activity and has implications for aldosterone signaling and K+ homeostasis.

Authors:  Aaron M Ring; Qiang Leng; Jesse Rinehart; Frederick H Wilson; Kristopher T Kahle; Steven C Hebert; Richard P Lifton
Journal:  Proc Natl Acad Sci U S A       Date:  2007-02-22       Impact factor: 11.205

10.  ANG II provokes acute trafficking of distal tubule Na+-Cl(-) cotransporter to apical membrane.

Authors:  Monica B Sandberg; Anne D M Riquier; Kaarina Pihakaski-Maunsbach; Alicia A McDonough; Arvid B Maunsbach
Journal:  Am J Physiol Renal Physiol       Date:  2007-05-16
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  119 in total

Review 1.  WNK kinases and the kidney.

Authors:  Ewout J Hoorn; David H Ellison
Journal:  Exp Cell Res       Date:  2012-03-03       Impact factor: 3.905

2.  SPAK-knockout mice manifest Gitelman syndrome and impaired vasoconstriction.

Authors:  Sung-Sen Yang; Yi-Fen Lo; Chin-Chen Wu; Shu-Wha Lin; Chien-Ju Yeh; Pauling Chu; Huey-Kang Sytwu; Shinichi Uchida; Sei Sasaki; Shih-Hua Lin
Journal:  J Am Soc Nephrol       Date:  2010-09-02       Impact factor: 10.121

Review 3.  Multigene kinase network, kidney transport, and salt in essential hypertension.

Authors:  Paul A Welling; Yen-Pei C Chang; Eric Delpire; James B Wade
Journal:  Kidney Int       Date:  2010-04-14       Impact factor: 10.612

4.  Regulated endocytosis of NCC.

Authors:  David B Mount
Journal:  Am J Physiol Renal Physiol       Date:  2010-05-26

5.  γ-Adducin stimulates the thiazide-sensitive NaCl cotransporter.

Authors:  Henrik Dimke; Pedro San-Cristobal; Mark de Graaf; Jacques W Lenders; Jaap Deinum; Joost G J Hoenderop; René J M Bindels
Journal:  J Am Soc Nephrol       Date:  2010-12-16       Impact factor: 10.121

Review 6.  Maintaining K+ balance on the low-Na+, high-K+ diet.

Authors:  Ryan J Cornelius; Bangchen Wang; Jun Wang-France; Steven C Sansom
Journal:  Am J Physiol Renal Physiol       Date:  2016-01-06

Review 7.  The WNK signaling pathway and salt-sensitive hypertension.

Authors:  Taisuke Furusho; Shinichi Uchida; Eisei Sohara
Journal:  Hypertens Res       Date:  2020-04-14       Impact factor: 3.872

Review 8.  Kidney and epigenetic mechanisms of salt-sensitive hypertension.

Authors:  Wakako Kawarazaki; Toshiro Fujita
Journal:  Nat Rev Nephrol       Date:  2021-02-24       Impact factor: 28.314

9.  Aldosterone modulates thiazide-sensitive sodium chloride cotransporter abundance via DUSP6-mediated ERK1/2 signaling pathway.

Authors:  Xiuyan Feng; Yiqian Zhang; Ningjun Shao; Yanhui Wang; Zhizhi Zhuang; Ping Wu; Matthew J Lee; Yingli Liu; Xiaonan Wang; Jieqiu Zhuang; Eric Delpire; Dingying Gu; Hui Cai
Journal:  Am J Physiol Renal Physiol       Date:  2015-03-11

Review 10.  Electroneutral absorption of NaCl by the aldosterone-sensitive distal nephron: implication for normal electrolytes homeostasis and blood pressure regulation.

Authors:  Dominique Eladari; Régine Chambrey; Nicolas Picard; Juliette Hadchouel
Journal:  Cell Mol Life Sci       Date:  2014-02-21       Impact factor: 9.261
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