Portal de Periódicos da CAPES

TRPV4: a new target for the hypertension-related kinases WNK1 and WNK4

2006; American Physical Society; Volume: 290; Issue: 6 Linguagem: Inglês

10.1152/ajprenal.00030.2006

1931-857X

Gerardo Gamba,

Plant Stress Responses and Tolerance

EDITORIAL FOCUSTRPV4: a new target for the hypertension-related kinases WNK1 and WNK4Gerardo GambaGerardo GambaPublished Online:01 Jun 2006https://doi.org/10.1152/ajprenal.00030.2006This is the final version - click for previous versionMoreFiguresReferencesRelatedInformationPDF (39 KB)Download PDF ToolsExport citationAdd to favoritesGet permissionsTrack citations ShareShare onFacebookTwitterLinkedInWeChat the "transient receptor potential" (TRP) super family of ion channel encompasses more than 50 cation-permeable channels that are expressed in many cells and tissues, from yeast to human. Most of the TRP channels are permeable to Ca2+, providing Ca2+ influx mechanisms. Based on structure and homology, the TRP superfamily can be subdivided into seven subfamilies (12), from which the TRPV (vanilloid) subfamily contains at least two members that turned out to be, or are emerging as, very important in renal physiology. TRPV5 is known to play a key role in renal transepithelial Ca2+ transport (11). TRPV4 was identified as the mammalian homolog of OSM-9, the key osmosensory channel in Caenorhabditis elegans. TRPV4 is activated by several stimuli, including thermal stress, the non-PKC-activating PMA analog 4α-phorbol 12,13-didecanoate (4α-PDD), and, most importantly, by hypotonicity (for a review, see Refs. 1 and 13). Because hypotonic stress is accompanied by Ca2+ entry that is required for upregulation of K+ and Cl− efflux, it has been proposed that TRPV4 provides a signaling afferent pathway for cell volume regulation. In the kidney, TRPV4 is absent in the proximal tubule and descending limb, nephron segments with high water permeability, whereas its expression begins in the ascending thin limb and is continuous through the thick ascending limb, distal convoluted tubule, and collecting duct, which are nephron segments exhibiting absolute or conditional water impermeability (15). Interestingly, TRPV4 is absent in the macula densa, the only region of the thick ascending limb that is permeable to water. This nephron distribution, together with recent observations that TRPV4 null mice developed an impairment in osmotic sensing in the central nervous system (7, 9), strongly suggests that TRPV4 plays a central role in systemic osmoregulation. Because TRPV4 along the nephron is polarized to the basolateral membrane, it has been recently proposed that its major role could be to sense the changes in interstitial osmolarity, as it is expected to occur with changes in urine flow rate (1).In this issue of the American Journal of Physiology-Renal Physiology, the study by Fu et al. (3) describes the effect of the serine/threonine kinases "With No Lysine (K) Kinases" (WNK)1 and WNK4 on the activity and surface expression of TRPV4. These kinases are implicated in the pathogenesis of a salt-dependent form of human hypertension known as pseudohypoaldosteronism type II (PHAII) (17). The gene family is known as "With No Lysine (K) Kinases (WNKs)" because of the lack of the invariant catalytic lysine in subdomain II of protein kinases. Mutations in WNK1 resulting in PHAII are due to intronic deletions, producing overexpression of the kinase, whereas PHAII-causing mutations in WNK4 are missense mutations in an acidic domain of 10 residues, highly conserved in the 4 WNKs. The mechanism for the development of both hypertension and hyperkalemia in PHAII patients is beginning to be revealed by the findings that WNK4 regulates the activity of several plasma membrane transport proteins in the kidney, including the thiazide-sensitive Na+-Cl− cotransporter (NCC), the basolateral isoform of the bumetanide-sensitive Na+-K+-2Cl− cotransporter (NKCC1), the Cl−/HCO3− exchanger (CFEX), the inwardly rectifying K+ channel (ROMK), and claudins, tight junction proteins (for a review, see Ref. 4). Moreover, PHAII-like mutations in WNK4 alter the regulation of these transport pathways by WNK4. Other features of the disease, however, remain to be explained. This is the case, for example, of metabolic acidosis and hypercalciuria (8).Fu et al. (3) used a transient expression of the TRPV4 channel in HEK293 cells to study the effect of WNK1 and WNK4 on TRPV4. They first observed that hypotonicity or 4α-PDD resulted in a significant increase in TRPV4 activity, which was remarkably prevented by cotransfection of TRPV4 with WNK4. WNK1 had a similar effect, and WNK1 plus WNK4 did not exhibit synergistic effect. Previous studies have shown that WNK1 is able to regulate the activity of transport systems, such as NCC, NKCC1, or the epithelial sodium channel ENaC, but only through its interactions with other kinases like WNK4 (20), the STE-20-related kinase SPAK (10, 16), or the serum-glucocorticoid kinase SGK1 (19), respectively. Thus the fact that WNK1 by itself is able to downregulate the activity of TRPV4 is interesting. Together with a recent report on WNK1 effects on ROMK (6), these are the first direct evidences of the effects of WNK1 on transport systems. By using biotinylation experiments to assess cell surface expression of the channel, Fu et al. (3) demonstrated that reduction of TRPV4 activity in the presence of WNK1 or WNK4 correlated with a significant decrease in TRPV4 present in the plasma membrane. Puzzling results regarding the requirement of kinase activity in WNK4 and WNK1 were observed. The catalytically inactive WNK4 harboring the mutation D318A loses the inhibitory effect on TRPV4, whereas the catalytically inactive WNK1 mutants K233M or S378A still exhibited the inhibitory effect, suggesting that WNK4, but not WNK1 catalytic activity, is required for TRPV4 inhibition. In contrast, using WNK4 deletion mutants, the authors observed that in absence of the kinase domain, the rest of WNK4 still inhibited TRPV4, whereas in the absence of the regulatory domain, WNK4 loses the inhibitory effect on TRPV4. Thus, although a point mutation that renders WNK4 catalytically inactive abrogated the negative effect of WNK4 on TRPV4, the deletion of the entire kinase domain did not, suggesting the intriguing possibility that the full-length, catalytically inactive WNK4 may be endowed with particular properties. Such a situation has been demonstrated to occur with the catalytically inactive form of WNK3 with reference to the regulation of the cation-coupled Cl− cotransporters (2, 5, 14). Finally, although WNK4 harboring the PHAII missense mutations E599K or Q562E was still able to inhibit TRPV4 activity, the level of inhibition was significantly lower than for wild-type WNK4, suggesting that for TRPV4 inhibition, PHAII mutations behave as a "loss-of-function" type, similar to what occurs with NCC (18). The work of Fu et al. (3) adds a new transport system to the growing list of membrane transporters and channels that are regulated by WNKs and opens a possible pathway to begin understanding the origin of hypercalciuria in PHAII patients.AUTHOR NOTESAddress for reprint requests and other correspondence: G. Gamba, Vasco de Quiroga No. 15, Tlalpan 14000, Mexico City, Mexico (e-mail: gamba@biomedicas.unam.mx or gamba@quetzal.innsz.mx) Download PDF Previous Back to Top Next FiguresReferencesRelatedInformationREFERENCES1 Cohen DM. TRPV4 and the mammalian kidney. Pflügers Arch 451: 168–175, 2005.Crossref | PubMed | ISI | Google Scholar2 De los Heros P, Kahle KT, Rinehart J, Bobadilla NA, Vázquez N, San Cristobal P, Mount DB, Lifton RP, Hebert SC, and Gamba G. WNK3 bypasses the tonicity requirement for K-Cl cotransporter activation via a phosphatase dependent pathway. Proc Natl Acad Sci USA 103: 1976–1981, 2006.Crossref | PubMed | ISI | Google Scholar3 Fu Y, Subramanya A, Rozansky D, and Cohen DM. WNK kinases influence TRPV4 channel function and localization. Am J Physiol Renal Physiol 290: F1305–F1314, 2006.Link | ISI | Google Scholar4 Gamba G. Role of WNK kinases in regulating tubular salt and potassium transport and in the development of hypertension. Am J Physiol Renal Physiol 288: F245–F252, 2005.Link | ISI | Google Scholar5 Kahle KT, Rinehart J, De Los HP, Louvi A, Meade P, Vazquez N, Hebert SC, Gamba G, Gimenez I, and Lifton RP. WNK3 modulates transport of Cl− in and out of cells: implications for control of cell volume and neuronal excitability. Proc Natl Acad Sci USA 102: 16783–16788, 2005.Crossref | PubMed | ISI | Google Scholar6 Lazrak A, Liu Z, and Huang CL. Antagonistic regulation of ROMK by long and kidney-specific WNK1 isoforms. Proc Natl Acad Sci USA 103: 1615–1620, 2006.Crossref | PubMed | ISI | Google Scholar7 Liedtke W and Friedman JM. Abnormal osmotic regulation in TRPV4−/− mice. Proc Natl Acad Sci USA 100: 13698–13703, 2003.Crossref | PubMed | ISI | Google Scholar8 Mayan H, Vered I, Mouallem M, Tzadok-Witkon M, Pauzner R, and Farfel Z. Pseudohypoaldosteronism type II: marked sensitivity to thiazides, hypercalciuria, normomagnesemia, and low bone mineral density. J Clin Endocrinol Metab 87: 3248–3254, 2002.Crossref | PubMed | ISI | Google Scholar9 Mizuno A, Matsumoto N, Imai M, and Suzuki M. Impaired osmotic sensation in mice lacking TRPV4. Am J Physiol Cell Physiol 285: C96–C101, 2003.Link | ISI | Google Scholar10 Moriguchi T, Urushiyama S, Hisamoto N, Iemura S, Uchida S, Natsume T, Matsumoto K, and Shibuya H. WNK1 regulates phosphorylation of cation-chloride-coupled cotransporters via the STE20-related kinases, SPAK and OSR1. J Biol Chem 280: 42685–42693, 2005.Crossref | PubMed | ISI | Google Scholar11 Nijenhuis T, Hoenderop JG, and Bindels RJ. TRPV5 and TRPV6 in Ca2+ (re)absorption: regulating Ca2+ entry at the gate. Pflügers Arch 451: 181–192, 2005.Crossref | PubMed | ISI | Google Scholar12 Nilius B and Voets T. TRP channels: a TR(I)P through a world of multifunctional cation channels. Pflügers Arch 451: 1–10, 2005.Crossref | PubMed | ISI | Google Scholar13 Nilius B, Vriens J, Prenen J, Droogmans G, and Voets T. TRPV4 calcium entry channel: a paradigm for gating diversity. Am J Physiol Cell Physiol 286: C195–C205, 2004.Link | ISI | Google Scholar14 Rinehart J, Kahle KT, De Los HP, Vazquez N, Meade P, Wilson FH, Hebert SC, Gimenez I, Gamba G, and Lifton RP. WNK3 kinase is a positive regulator of NKCC2 and NCC, renal cation-Cl− cotransporters required for normal blood pressure homeostasis. Proc Natl Acad Sci USA 102: 16777–16782, 2005.Crossref | PubMed | ISI | Google Scholar15 Tian W, Salanova M, Xu H, Lindsley JN, Oyama TT, Anderson S, Bachmann S, and Cohen DM. Renal expression of osmotically responsive cation channel TRPV4 is restricted to water-impermeant nephron segments. Am J Physiol Renal Physiol 287: F17–F24, 2004.Link | ISI | Google Scholar16 Vitari AC, Deak M, Morrice NA, and Alessi DR. The WNK1 and WNK4 protein kinases that are mutated in Gordon's hypertension syndrome, phosphorylate and active SPAK and OSR1 protein kinases. Biochem J 391: 17–24, 2005.Crossref | PubMed | ISI | Google Scholar17 Wilson FH, Disse-Nicodeme S, Choate KA, Ishikawa K, Nelson-Williams C, Desitter I, Gunel M, Milford DV, Lipkin GW, Achard JM, Feely MP, Dussol B, Berland Y, Unwin RJ, Mayan H, Simon DB, Farfel Z, Jeunemaitre X, and Lifton RP. Human hypertension caused by mutations in WNK kinases. Science 293: 1107–1112, 2001.Crossref | PubMed | ISI | Google Scholar18 Wilson FH, Kahle KT, Sabath E, Lalioti MD, Rapson AK, Hoover RS, Hebert SC, Gamba G, and Lifton RP. Molecular pathogenesis of inherited hypertension with hyperkalemia: the Na-Cl cotransporter is inhibited by wild-type but not mutant WNK4. Proc Natl Acad Sci USA 100: 680–684, 2003.Crossref | PubMed | ISI | Google Scholar19 Xu BE, Stippec S, Chu PY, Lazrak A, Li XJ, Lee BH, English JM, Ortega B, Huang CL, and Cobb MH. WNK1 activates SGK1 to regulate the epithelial sodium channel. Proc Natl Acad Sci USA 102: 10315–10320, 2005.Crossref | PubMed | ISI | Google Scholar20 Yang CL, Zhu X, Wang Z, Subramanya AR, and Ellison DH. Mechanisms of WNK1 and WNK4 interaction in the regulation of thiazide-sensitive NaCl cotransport. J Clin Invest 115: 1379–1387, 2005.Crossref | PubMed | ISI | Google Scholar Cited ByNCC regulation by WNK signal cascade4 January 2023 | Frontiers in Physiology, Vol. 13CFTR plays an important role in the regulation of vascular resistance and high-fructose/salt-diet induced hypertension in miceJournal of Cystic Fibrosis, Vol. 20, No. 3A Functional Kinase Short Interfering Ribonucleic Acid Screen Using Protease-Activated Receptor 2-Dependent Opening of Transient Receptor Potential Vanilloid-4ASSAY and Drug Development Technologies, Vol. 16, No. 1Regulation of blood pressure and renal electrolyte balance by Cullin-RING ligasesCurrent Opinion in Nephrology and Hypertension, Vol. 23, No. 5Regulation of with‐no‐lysine kinase signaling by Kelch‐like proteins10 January 2014 | Biology of the Cell, Vol. 106, No. 2The Molecular Mechanism of Multifunctional Mechano-Gated Channel TRPV45 December 2012Expression and Physiological Roles of TRP Channels in Smooth Muscle Cells24 December 2010Mechanosensitive Channel TRPV4Regulation of activity and localization of the WNK1 protein kinase by hyperosmotic stress26 December 2006 | The Journal of Cell Biology, Vol. 176, No. 1 More from this issue > Volume 290Issue 6June 2006Pages F1303-F1304 Copyright & PermissionsCopyright © 2006 the American Physiological Societyhttps://doi.org/10.1152/ajprenal.00030.2006PubMed16467131History Published online 1 June 2006 Published in print 1 June 2006 Metrics Downloaded 257 times 9 CITATIONS 9 Total citations 1 Recent citation 1.36 Field Citation Ratio 0.14 Relative Citation Ratio publications9supporting0mentioning6contrasting0Smart Citations9060Citing PublicationsSupportingMentioningContrastingView CitationsSee how this article has been cited at scite.aiscite shows how a scientific paper has been cited by providing the context of the citation, a classification describing whether it supports, mentions, or contrasts the cited claim, and a label indicating in which section the citation was made.