Nati Hernando

PDZ-domain interactions and apical expression of type IIa Na/Pi cotransporters

Type IIa Na/Pi cotransporters are expressed in renal proximal brush border and are the major determinants of inorganic phosphate (Pi) reabsorption. Their carboxyl-terminal tail contains information for apical expression, and interacts by means of its three terminal amino acids with several PSD95/DglA/ZO-1-like domain (PDZ)-containing proteins. Two of these proteins, NaPi-Cap1 and Na/H exchanger-regulatory factor 1 (NHERF1), colocalize with the cotransporter in the proximal brush border. We used opossum kidney cells to test the hypothesis of a potential role of PDZ-interactions on the apical expression of the cotransporter. We found that opossum kidney cells contain NaPi-Cap1 and NHERF1 mRNAs. For NHERF1, an apical location of the protein could be documented; this location probably reflects interaction with the cytoskeleton by means of the MERM-binding domain. Overexpression of PDZ domains involved in interaction with the cotransporter (PDZ-1/NHERF1 and PDZ-3/NaPi-Cap1) had a dominant–negative effect, disturbing the apical expression of the cotransporter without affecting the actin cytoskeleton or the basolateral expression of Na/K-ATPase. These data suggest an involvement of PDZ-interactions on the apical expression of type IIa cotransporters.

Regulation of phosphate transport in proximal tubules

Homeostasis of inorganic phosphate (Pi) is primarily an affair of the kidneys. Reabsorption of the bulk of filtered Pi occurs along the renal proximal tubule and is initiated by apically localized Na+-dependent Pi cotransporters. Tubular Pi reabsorption and therefore renal excretion of Pi is controlled by a number of hormones, including phosphatonins, and metabolic factors. In most cases, regulation of Pi reabsorption is achieved by changing the apical abundance of Na+/Pi cotransporters. The regulatory mechanisms involve various signaling pathways and a number of proteins that interact with Na+/Pi cotransporters.

Posttranscriptional regulation of the proximal tubule NaPi-II transporter in response to PTH and dietary Pi

The rate of proximal tubular reabsorption of phosphate (Pi) is a major determinant of Pi homeostasis. Deviations of the extracellular concentration of Piare corrected by many factors that control the activity of Na-Pi cotransport across the apical membrane. In this review, we describe the regulation of proximal tubule Pi reabsorption via one particular Na-Pi cotransporter (the type IIa cotransporter) by parathyroid hormone (PTH) and dietary phosphate intake. Available data indicate that both factors determine the net amount of type IIa protein residing in the apical membrane. The resulting change in transport capacity is a function of both the rate of cotransporter insertion and internalization. The latter process is most likely regulated by PTH and dietary Pi and is considered irreversible since internalized type IIa Na-Picotransporters are subsequently routed to the lysosomes for degradation.The rate of proximal tubular reabsorption of phosphate (P(i)) is a major determinant of P(i) homeostasis. Deviations of the extracellular concentration of P(i) are corrected by many factors that control the activity of Na-P(i) cotransport across the apical membrane. In this review, we describe the regulation of proximal tubule P(i) reabsorption via one particular Na-P(i) cotransporter (the type IIa cotransporter) by parathyroid hormone (PTH) and dietary phosphate intake. Available data indicate that both factors determine the net amount of type IIa protein residing in the apical membrane. The resulting change in transport capacity is a function of both the rate of cotransporter insertion and internalization. The latter process is most likely regulated by PTH and dietary P(i) and is considered irreversible since internalized type IIa Na-P(i) cotransporters are subsequently routed to the lysosomes for degradation.

Studies on the topology of the renal type II NaPi-cotransporter.

Abstract The rat type II sodium/phosphate cotransporter (NaPi-2) is a 85- to 90-kDa glycosylated protein located at the proximal tubular brush border membrane. Hydropathy predictions suggest eight transmembrane domains (sTM) with a large glycosylated loop between sTM 3 and sTM 4. We have studied the membrane topology of NaPi-2 expressed in oocytes. A 33-amino-acid fragment containing the FLAG epitope was inserted into seven loops connecting the sTMs and into the NH2- and COOH-ends of the protein. FLAG-antibody binding suggested that the loops connecting sTM 1 and sTM 2 as well as sTM 3 and sTM 4 are located extracellularly. Based on the lack of FLAG-antibody binding we suggest intracellular locations for the NH2- and COOH-termini and the region connecting sTM 4 and sTM 5. Immunoprecipitation studies of in vitro translated protein also suggest that the NH2-terminus is sited extracellularly. In immunohistochemical studies with NaPi-2-transfected MDCK cells, an interaction with NH2- and COOH- terminal antipeptide antibodies could only be obtained after membrane permeabilization. The presented data are an experimental documentation of the intracellular location of the NH2- and COOH-termini, and of the extracellular location of extracellular loops 1 and 2.

Molecular mechanisms in proximal tubular and small intestinal phosphate reabsorption (Plenary Lecture)

Renal and small intestinal (re-)absorption contribute to overall phosphate(Pi)-homeostasis. In both epithelia, apical sodium (Na+)/Pi-cotransport across the luminal (brush border) memi brane is rate limiting and the target for physiological/pathophysiological alterations. Three different Na/Pi-cotransporters have been identified: (i) type I cotransporter(s) - present in the proximal tubule - also show anion channel function and may play a role in secretion of organic anions; in the brain, it may serve vesicular glutamate uptake functions; (ii) type II cotransporter(s) seem to serve rather specific epithelial functions; in the renal proximal tubule (type IIa)and in the small intestine (type IIb), isoform determines Na+-dependent transcellular Pi-movements; (iii) type III cotransporters are expressed in many different cells/tissues where they could serve housekeeping functions. In the small intestine, alterations in Pi-absorption and, thus, apical expression of IIb protein are mostly in response to longer term (days) situations (altered Pi-intake, levels of 1.25 (OH2) vitamin D3, growth, etc), whereas in renal proximal tubule, in addition, hormonal effects (e.g. Parathyroid Hormone, PTH) acutely control (minutes/hours) the expression of the IIa cotransporter. The type II Na/Pi-cotransporters operate (as functional monomers) in a 3 Na+:1 Pi stoichiometry, including transfer of negatively charged (-1) empty carriers and electroneutral transfers of partially loaded carriers (1 Na+, slippage)and of the fully loaded carriers (3 Na+, 1 Pi). By a chimera (IIa/IIb) approach, and by site-directed mutagenesis (including cysteine-scanning), specific sequences have been identified contributing to either apical expression, PTH-induced membrane retrieval, Na+-interaction or specific pH-dependence of the IIa and IIb cotransporters. For the COOH-terminal tail of the IIa Na/Pi -cotransporter, several interacting PDZ-domain proteins have been identified which may contribute to either its apical expression (NaPi-Cap1) or to its subapical/lysosomal traffic (NaPi-Cap2).

Electrophysiological Characterization of the Flounder Type II Na+/Pi Cotransporter (NaPi-5) Expressed in Xenopus laevis Oocytes

Abstract: The two electrode voltage clamp technique was used to investigate the steady-state and presteady-state kinetic properties of the type II Na+/Pi cotransporter NaPi-5, cloned from the kidney of winter flounder (Pseudopleuronectes americanus) and expressed in Xenopus laevis oocytes. Steady-state Pi-induced currents had a voltage-independent apparent Km for Pi of 0.03 mm and a Hill coefficient of 1.0 at neutral pH, when superfusing with 96 mm Na+. The apparent Km for Na+ at 1 mm Pi was strongly voltage dependent (increasing from 32 mm at −70 mV to 77 mm at −30 mV) and the Hill coefficient was between 1 and 2, indicating cooperative binding of more than one Na+ ion. The maximum steady-state current was pH dependent, diminishing by 50% or more for a change from pH 7.8 to pH 6.3. Voltage jumps elicited presteady-state relaxations in the presence of 96 mm Na+ which were suppressed at saturating Pi (1 mm). Relaxations were absent in non-injected oocytes. Charge was balanced for equal positive and negative steps, saturated at extremes of potential and reversed at the holding potential. Fitting the charge transfer to a Boltzmann relationship typically gave a midpoint voltage (V0.5) close to zero and an apparent valency of approximately 0.6. The maximum steady-state transport rate correlated linearly with the maximum Pi-suppressed charge movement, indicating that the relaxations were NaPi-5-specific. The apparent transporter turnover was estimated as 35 sec−1. The voltage dependence of the relaxations was Pi-independent, whereas changes in Na+ shifted V0.5 to −60 mV at 25 mm Na+. Protons suppressed relaxations but contributed to no detectable charge movement in zero external Na+. The voltage dependent presteady-state behavior of NaPi-5 could be described by a 3 state model in which the partial reactions involving reorientation of the unloaded carrier and binding of Na+ contribute to transmembrane charge movement.

Phosphate Transporters and Their Function

Plasma phosphate concentration is maintained within a relatively narrow range by control of renal reabsorption of filtered inorganic phosphate (P(i)). P(i) reabsorption is a transcellular process that occurs along the proximal tubule. P(i) flux at the apical (luminal) brush border membrane represents the rate-limiting step and is mediated by three Na(+)-dependent P(i) cotransporters (members of the SLC34 and SLC20 families). The putative proteins responsible for basolateral P(i) flux have not been identified. The transport mechanism of the two kidney-specific SLC34 proteins (NaPi-IIa and NaPi-IIc) and of the ubiquitously expressed SLC20 protein (PiT-2) has been studied by heterologous expression to reveal important differences in kinetics, stoichiometry, and substrate specificity. Studies on the regulation of the abundance of the respective proteins highlight significant differences in the temporal responses to various hormonal and nonhormonal factors that can influence P(i) homeostasis. The phenotypes of mice deficient in NaPi-IIa and NaPi-IIc indicate that NaPi-IIa is responsible for most P(i) renal reabsorption. In contrast, in the human kidney, NaPi-IIc appears to have a relatively greater role. The physiological relevance of PiT-2 to P(i) reabsorption remains to be elucidated.

Molecular determinants for apical expression of the renal type IIa Na+/Pi-cotransporter

Abstract. Type IIa and IIb Na+/Pi-cotransporters have different patterns of expression in vivo: IIa is expressed in apical membranes of renal proximal tubules, and IIb in intestinal and lung epithelia. They are found in different subcellular locations when transfected in epithelial cells: IIa is apically expressed in renal proximal cells (OK), but mostly intracellularly in intestinal cells (CaCo2); IIb is apical in both cell types. To identify the domains responsible for the different expression of both cotransporters (in CaCo2), as well as those responsible for the apical expression of IIa (in OK), mutated cotransporters were fused to the Enhanced Green Fluorescent Protein (EGFP), and their expression analyzed by confocal microscopy. We conclude that the apical expression information for CaCo2 is contained within the C-terminal tail of IIb, but is not contained within IIa. From analysis of mutated IIa cotransporters we identified residues, within the C-terminal tail, involved in the apical expression of these cotransporters in OK cells: internal PR-residues and terminal TRL-residues. These signals are functional in OK but not in CaCo2-cells, supporting the concept that polarized targeting can be protein and cell specific.

Expression and regulation of the renal Na/phosphate cotransporter NaPi-IIa in a mouse model deficient for the PDZ protein PDZK1

Inorganic phosphate (Pi) is reabsorbed in the renal proximal tubule mainly via the type-IIa sodium-phosphate cotransporter (NaPi-IIa). This protein is regulated tightly by different factors, among them dietary Pi intake and parathyroid hormone (PTH). A number of PDZ-domain-containing proteins have been shown to interact with NaPi-IIa in vitro, such as Na+/H+ exchanger-3 regulatory factor-1 (NHERF1) and PDZK1. PDZK1 is highly abundant in kidney and co-localizes with NaPi-IIa in the brush border membrane of proximal tubules. Recently, a knock-out mouse model for PDZK1 (Pdzk1−/−) has been generated, allowing the role of PDZK1 in the expression and regulation of the NaPi-IIa cotransporter to be examined in in vivo and in ex vivo preparations. The localization of NaPi-IIa and other proteins interacting with PDZK1 in vitro [Na+/H+ exchanger (NHE3), chloride-formate exchanger (CFEX)/putative anion transporter-1 (PAT1), NHERF1] was not altered in Pdzk1−/− mice. The abundance of NaPi-IIa adapted to acute and chronic changes in dietary Pi intake, but steady-state levels of NaPi-IIa were reduced in Pdzk1−/− under a Pi rich diet. This was paralleled by a higher urinary fractional Pi excretion. The abundance of the anion exchanger CFEX/PAT1 (SLC26A6) was also reduced. In contrast, NHERF1 abundance increased in the brush border membrane of Pdzk1−/− mice fed a high-Pi diet. Acute regulation of NaPi-IIa by PTH in vivo and by PTH and activators of protein kinases A, C and G (PKA, PKC and PKG) in vitro (kidney slice preparation) was not altered in Pdzk1−/− mice. In conclusion, loss of PDZK1 did not result in major changes in proximal tubule function or NaPi-IIa regulation. However, under a Pi-rich diet, loss of PDZK1 reduced NaPi-IIa abundance indicating that PDZK1 may play a role in the trafficking or stability of NaPi-IIa under these conditions.

Functional Characterization of Two Naturally Occurring Mutations in the Human Sodium-Phosphate Cotransporter Type IIa

Mutations in the gene encoding the human sodium‐phosphate cotransporter (NPT2), causing reduced phosphate affinity and dominant‐negative behavior, were described. (1) We found no evidence of altered kinetics or dominant‐negative effects. Thus, the mutations cannot account for the clinical phenotype.