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Commentary Free access | 10.1172/JCI33859
Institute of Physiology, University of Zurich, Zurich, Switzerland.
Address correspondence to: Jürg Biber, Institute of Physiology, University of Zurich, Winterthurerstrasse 190, CH-8057 Zurich, Switzerland. Phone: 41-044-635-5032; Fax: 41-044-635-5715; E-mail: JuergBiber@access.uzh.ch.
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Institute of Physiology, University of Zurich, Zurich, Switzerland.
Address correspondence to: Jürg Biber, Institute of Physiology, University of Zurich, Winterthurerstrasse 190, CH-8057 Zurich, Switzerland. Phone: 41-044-635-5032; Fax: 41-044-635-5715; E-mail: JuergBiber@access.uzh.ch.
Find articles by Wagner, C. in: JCI | PubMed | Google Scholar
Institute of Physiology, University of Zurich, Zurich, Switzerland.
Address correspondence to: Jürg Biber, Institute of Physiology, University of Zurich, Winterthurerstrasse 190, CH-8057 Zurich, Switzerland. Phone: 41-044-635-5032; Fax: 41-044-635-5715; E-mail: JuergBiber@access.uzh.ch.
Find articles by Biber, J. in: JCI | PubMed | Google Scholar
Institute of Physiology, University of Zurich, Zurich, Switzerland.
Address correspondence to: Jürg Biber, Institute of Physiology, University of Zurich, Winterthurerstrasse 190, CH-8057 Zurich, Switzerland. Phone: 41-044-635-5032; Fax: 41-044-635-5715; E-mail: JuergBiber@access.uzh.ch.
Find articles by Murer, H. in: JCI | PubMed | Google Scholar
Published November 1, 2007 - More info
The pathogenesis of essential hypertension remains unknown, but thiazide diuretics are frequently recommended as first-line treatment. Recently, familial hyperkalemic hypertension (FHHt) was shown to result from activation of the thiazide-sensitive Na-Cl cotransporter (NCC) by mutations in WNK4, although the mechanism for this effect remains unknown. WNK kinases are unique members of the human kinome, intimately involved in maintaining electrolyte balance across cell membranes and epithelia. Previous work showed that WNK1, WNK4, and a kidney-specific isoform of WNK1 interact to regulate NCC activity, suggesting that WNK kinases form a signaling complex. Here, we report that WNK3, another member of the WNK kinase family expressed by distal tubule cells, interacts with WNK4 and WNK1 to regulate NCC in both human kidney cells and Xenopus oocytes, further supporting the WNK signaling complex hypothesis. We demonstrate that physiological regulation of NCC in oocytes results from antagonism between WNK3 and WNK4 and that FHHt-causing WNK4 mutations exert a dominant-negative effect on wild-type (WT) WNK4 to mimic a state of WNK3 excess. The results provide a mechanistic explanation for the divergent effects of WT and FHHt-mutant WNK4 on NCC activity, and for the dominant nature of FHHt in humans and genetically modified mice.
Chao-Ling Yang, Xiaoman Zhu, David H. Ellison
Parathyroid hormone (PTH), via activation of PKC and/or protein kinase A, inhibits renal proximal tubular phosphate reabsorption by facilitating the internalization of the major sodium-dependent phosphate transporter, Npt2a. Herein, we explore the hypothesis that the effect of PTH is mediated by phosphorylation of serine 77 (S77) of the first PDZ domain of the Npt2a-binding protein sodium-hydrogen exchanger regulatory factor–1 (NHERF-1). Using recombinant polypeptides representing PDZ I, S77 of NHERF-1 is phosphorylated by PKC but not PKA. When expressed in primate kidney epithelial cells (BSC-1 cells), however, activation of either protein kinase phosphorylates S77, suggesting that the phosphorylation of PDZ I by PKC and PKA proceeds by different biochemical pathways. PTH and other activators of PKC and PKA dissociate NHERF-1/Npt2a complexes, as assayed using quantitative coimmunoprecipitation, confocal microscopy, and sucrose density gradient ultracentrifugation in mice. Murine NHERF-1–/– renal proximal tubule cells infected with adenovirus-GFP-NHERF-1 containing an S77A mutation showed significantly increased phosphate transport compared with a phosphomimetic S77D mutation and were resistant to the inhibitory effect of PTH compared with cells infected with wild-type NHERF-1. These results indicate that PTH-mediated inhibition of renal phosphate transport involves phosphorylation of S77 of the NHERF-1 PDZ I domain and the dissociation of NHERF-1/Npt2a complexes.
Edward J. Weinman, Rajat S. Biswas, Quihong Peng, Lily Shen, Christina L. Turner, Xiaofei E, Deborah Steplock, Shirish Shenolikar, Rochelle Cunningham
Protein kinases catalyze the phosphorylation of serine/threonine or tyrosine residues, which may directly alter a protein’s functional properties. Kinases can also regulate protein functions indirectly, for example, by controlling the composition and/or subcellular localization of members of multiprotein complexes that associate with the regulated protein. In this issue of the JCI, two separate studies by Weinman et al. and Yang et al. examine the second of these two modes of kinase-mediated regulation and demonstrate the effects of kinases on two Na+-driven renal cotransporters (see the related articles beginning on pages 3403 and 3412). Their results reveal important implications for phosphate and salt homeostasis, respectively.
Homeostatic control of body fluids is achieved by, among other mechanisms, a variety of solute transporters that operate according to the body’s needs. Thus, the function of these transporters is modulated by diverse regulatory systems. Frequently, the final event in a hormonally stimulated signaling cascade involves activation of protein kinases that modify transporter activities by changing the characteristics or the subcellular localization of the transporters. Such alterations can be achieved by direct phosphorylation of the transporter itself or via phosphorylation of proteins that are part of heteromultimeric complexes.
Protein kinase–mediated activation or inhibition of many hormonally controlled transporters have been described, yet the final targets in these signaling pathways and/or the underlying regulatory mechanisms have not yet been identified. The work presented in this issue of the JCI in the articles by Weinman et al. (1) and Yang et al. (2) now sheds some mechanistic light on how the activity and/or abundance of ion transporters are hormonally controlled by protein complexes that contain protein kinases. These two reports respectively address the regulation of two ion transporters that are predominantly expressed in kidney: the parathyroid hormone–regulated (PTH-regulated) Na+-Pi cotransporter type IIa (Npt2a; encoded by SLC34A1 and also known as NaPi-IIa) (3) and the thiazide-sensitive Na-Cl cotransporter (NCC; encoded by SLC12A3 and also known as TSC) (4). The NCC is located on the luminal side of distal convoluted tubule (DCT) cells, whereas Npt2a associates with the brush border membranes (BBMs) of proximal tubules (PTs) (3, 5). Apical expression of NCC and Npt2a is under the control of kinases such as WNK kinases (with no lysine [K] in their catalytic domain II) and PKA/PKC, respectively. Interestingly, neither WNK nor PKA/PKC have been reported to phosphorylate these transporters directly (3, 6–8).
Npt2a mediates Na+-coupled, electrogenic reabsorption of inorganic phosphate (Pi). The abundance of the Npt2a protein is regulated by dietary phosphate intake, by phosphaturic PTH, and by different phosphatonins (3, 8, 9). The importance of Npt2a in phosphate homeostasis was documented in an Npt2–/– mouse model that is characterized by hypophosphatemia (abnormally decreased level of phosphate in the blood) and hyperphosphaturia (increased excretion of phosphate in the urine) due to reduced Pi reabsorption (10). Npt2a expression is reduced in animal models of X-linked hypophosphatemia, and a similar defect may also be implicated in human hypophosphatemic syndromes (9). However, Npt2a downregulation is secondary to alterations in different regulatory factors (e.g. FGF23, one of the so-called phosphatonins) (9, 11).
NCC belongs to the SLC12 electroneutral cation–Cl–coupled cotransporter family (4), mediates reabsorption of NaCl, and is the target of widely used thiazide diuretics, which due to their vasodilator properties are often used to treat hypertension. Inactivating mutations in NCC cause Gitelman disease, an autosomal recessive salt-wasting (NaCl, K+, Mg2+) disorder characterized by hypotension (4, 5). Autosomal dominant Gordon disease, a consequence of increased NCC activity, is characterized by hypertension, hyperkalemia, and hyperchloremic metabolic acidosis. The NCC overactivity is due to increased expression of NCC in the apical membrane and hypertrophy of the DCT, secondary to mutations in the regulatory WNK1 and/or WNK4 kinases (4, 5, 6, 12).
PTH binds to its G protein–coupled receptor in the PT and, through activation of PKA and PKC, modulates the apical abundance of Npt2a by controlling the rate of endocytotic Npt2a retrieval (Figure 1, left). PTH-induced Npt2a internalization does not involve phosphorylation of the cotransporter itself; therefore, it has been postulated that PTH-induced kinase activity indirectly affects the positioning of the Npt2a protein within the BBM (8, 13).
Kinase signaling networks regulating ion transport in the kidney. Left: Regulation of the PT cell Na+-Pi cotransporter Npt2a by PTH, via apical and basolateral PTH receptors. As reported in this issue by Weinman et al. (1), phosphorylation at Ser77 of NHERF-1 results in a dissociation of Npt2a from NHERF-1, consequent Npt2a internalization, and an increased excretion of phosphate in the urine. Right: DCT cells express the Na+-Cl– cotransporter NCC, which is inhibited by thiazides. The study by Yang et al. (2) in this issue of the JCI reports that WNK3, a member of the WNK kinase family, interacts with WNK1 and WNK4 to regulate the phosphorylation and activity of NCC. WNK kinases are regulated by stimuli such as changes in aldosterone or extracellular potassium levels. Dotted arrows indicate that the nature of interaction between kinases (direct or indirect) is not known to date. KS-WNK1, kidney-specific WNK1.
A major issue in protein kinase signaling is how these enzymes achieve their spatial-substrate specificity. More than 30 A kinase–anchoring proteins (AKAPs) and several receptors for activated kinase C (RACKs), with different tissue distribution and subcellular locations, are responsible for subcellular compartmentalization of protein kinases and phosphatases (14, 15). These anchoring proteins are part of heteromultimeric protein networks that place the kinases and/or phosphatases in close proximity to their substrates. In the case of Npt2a, such networks are built around the sodium-hydrogen exchanger regulatory factor–1 (NHERF-1) family (16, 17).
NHERF-1 was identified as a cofactor required for PKA-mediated inhibition of the Na+/H+ exchanger NHE3, due to its ability to simultaneously bind to NHE3 and ezrin, an AKAP expressed in epithelia (for review, see ref. 16). The NHERF family consists of 4 related proteins that contain either 2 (NHERF-1/2) or 4 (NHERF-3/4) PSD95/DlgA/ZO-1 (PDZ) domains for protein-protein interaction. NHERF-1/2 can also bind to several other transporters, G protein–coupled receptors (including the PTH receptor), and phospholipase C (PLC) (18). PDZ-based interactions can be regulated by phosphorylation of either protein partner involved in the protein-protein interaction. Several kinases, including cell division cycle 2 kinase and G protein–coupled receptor kinase 6, phosphorylate NHERF-1 in vitro (19).
Npt2a interacts via its C terminus with several PDZ-containing proteins located in or in close proximity to the BBM, including the 4 members of the NHERF family (20). Npt2a binds to PDZ1 of NHERF-1/2 and to PDZ3 of NHERF3/4. The last 3 amino acids of Npt2a are critical for these interactions. Npt2a expression is only minimally impacted in NHERF3-deficient mice. However NHERF-1 deficiency is manifested by a reduced expression of Npt2a in the BBM and by an impaired regulation by PTH via the PKC pathway (17, 21, 22). This suggests an important role of NHERF-1 in the apical stabilization of Npt2a and in scaffolding components of the PKC signaling pathway.
The abundance and subcellular localization of NHERF-1, in contrast to Npt2a is not affected by PTH, suggesting that an alternative mechanism is necessary for the dissociation of the Npt2a/PDZ complex. In their study in this issue of the JCI, Weinman and coworkers show that in renal PT, PKA and PKC phosphorylate NHERF-1 on Ser77, a residue located within the first PDZ domain (1) (Figure 1, left). From studies performed with renal PT cells derived from NHERF-1–deficient mice and infected with several adenovirus–NHERF-1 constructs, the authors conclude that phosphorylation of Ser77 is responsible for the PTH-induced dissociation of the NHERF-1/Npt2a complex, allowing for the retrieval of the Npt2a cotransporter from the BBM, whereas NHERF-1 remains attached to the apical cytoskeleton (Figure 1, left). Thus, phosphorylation of Ser77 of NHERF-1 may represent the long-sought “off switch” that determines the lifespan of Npt2a within the apical membrane, whereby the off signal could be a conformational change within the PDZ1 domain of NHERF-1. Interestingly, the authors report that the mechanisms of phosphorylation of Ser77 by PKC and PKA differ. Whereas PKC appears to directly phosphorylate NHERF-1 at position Ser77, PKA-mediated NHERF-1 phosphorylation seems to require a phosphatase. This latter finding indicates the presence of a rather complex phosphorylation machinery within the apical heteromultimeric network that contains Npt2a. Future work will undoubtedly uncover the full composition of this network and thereby help to unravel other mechanisms involved in the regulation of Npt2a, such as those involving cGMP and MAPK kinases and phosphatonins (8, 9, 11).
NCC activity is directly associated with regulation of blood pressure and thus must be tightly controlled. Analysis of the underlying mechanisms leading to Gordon syndrome (pseudohypoaldosteronism type II) offers insights into the regulation of NCC and blood pressure. Hypertension, a symptom of Gordon syndrome, is very sensitive to treatment with thiazide diuretics (12), suggesting an important role of NCC as part of the pathomechanism. Gordon syndrome is caused by mutations in the kinases WNK1 and WNK4 (21). Four members of the WNK kinase family are known in humans, and several studies in the past years have uncovered an important role for these kinases in the regulation of epithelial cell transport of potassium, sodium, and chloride via the regulation of several ion channels (e.g., renal outer medullary potassium channel [ROMK], epithelial sodium channel [ENaC], and claudins) and electrolyte transporters (Na+-K+-2Cl cotransporter 1 [NKCC1], NKCC2, NCC, K+-Cl– cotransporters 1–4 [KCC1–4]) (23). The emerging picture indicates that WNK kinases may interact with each other and with other kinases such as serum/glucocorticoid-regulated kinase 1 (SGK1) to directly and indirectly phosphorylate target proteins and thereby alter their activity. The stimulatory effect of WNK3 and the inhibitory effect of WNK4 on NCC activity had been shown (7, 24), but the underlying mechanisms of these effects as well as that of the interplay of WNK kinases with other kinases remained elusive. In this issue of the JCI, Yang et al. (2) analyze the role of WNK3 in the network of NCC regulation, which also involves WNK1 and WNK4, using heterologous expression in Xenopus oocytes. The major finding is that WNK1, as well as the short, kidney-specific isoform of WNK1 known as KS-WNK1, WNK3, and WNK4 form a regulatory complex of physically interacting and mutually regulating kinases (Figure 1, right). These interactions do not always require the kinase-active domains, suggesting that in some instances WNK kinases may also act as scaffolding proteins for other (WNK) kinases. More interestingly, the effect of coexpression of WNK kinase isoforms with NCC showed a graded response depending on the actual stoichiometry of kinases present. Thus, WNK kinases are not providing a simple on-off switch; instead, the data imply that the presence of several WNK kinase isoforms that regulate each other in the renal DCT allows for the fine tuning of NCC over a wide range of transport activity. Expression of WNK kinase isoforms is influenced by factors such a dietary potassium intake or aldosterone and may therefore integrate these inputs into the differential regulation of transport mechanisms for potassium and NaCl. In addition, Yang et al. also offer a new interpretation of the pathomechanism of Gordon syndrome. Mutations in WNK4 (i.e. WNK4 Q562E) cause hypertension by disinhibiting NCC activity, a trait inherited in an autosomal dominant manner (25), which cannot be easily reconciled with the direct inhibitory effect of WNK4 on NCC activity. In their current study, Yang et al. (2) show that WNK4 Q562E acts as a dominant-negative inhibitor of normal WNK4 function and thereby releases the inhibition of NCC, causing hyperactivity of this important transporter.
The studies by Weinman et al. (1) and Yang et al. (2) described here provide compelling evidence for the emerging view that the regulation of membrane transporter function is not a linear cascade of events but the result of the integration of various signals that requires a complex machinery of receptors, kinases, phosphatases, and scaffolding proteins and allows for the graded and fine-tuned adaptation of transporter function to cellular or whole-body needs. We are only just beginning to understand how such macromolecular complexes are built and regulated.
The authors are supported by grants 31-065397 (to H. Murer) and 31-109677 (to C.A. Wagner) of the Swiss National Fonds and the EuReGene project of the 6th European Union framework program to H. Murer and C.A. Wagner.
Address correspondence to: Jürg Biber, Institute of Physiology, University of Zurich, Winterthurerstrasse 190, CH-8057 Zurich, Switzerland. Phone: 41-044-635-5032; Fax: 41-044-635-5715; E-mail: JuergBiber@access.uzh.ch.
Nonstandard abbreviations used: BBM, brush border membrane; DCT, distal convoluted tubule; NCC, thiazide-sensitive Na-Cl cotransporter; NHERF-1, sodium-hydrogen exchanger regulatory factor–1; Npt2a, Na+-Pi cotransporter type IIa; PDZ, PSD95/DlgA/ZO-1; Pi, inorganic phosphate; PT, proximal tubule; PTH, parathyroid hormone; WNK, with no lysine (K).
Conflict of interest: The authors have declared that no conflict of interest exists.
Reference information: J. Clin. Invest.117:3179–3182 (2007). doi:10.1172/JCI33859.
See the related articles at Parathyroid hormone inhibits renal phosphate transport by phosphorylation of serine 77 of sodium-hydrogen exchanger regulatory factor–1 and The thiazide-sensitive Na-Cl cotransporter is regulated by a WNK kinase signaling complex.