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Trafficking of Na-K-ATPase and dopamine receptor molecules induced by changes in intracellular sodium concentration of renal epithelial cells

¹Department of Anatomy and Cell Biology, State University of New York at Brooklyn, Brooklyn, New York; and ²College of Pharmacy, University of Houston, Houston, Texas

Submitted 16 May 2008 ; accepted in final form 7 August 2008

	ABSTRACT

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Most of the transepithelial transport of sodium in proximal tubules occurs through the coordinated action of the apical sodium/proton exchanger and the basolateral Na-K-ATPase. Hormones that regulate proximal tubule sodium excretion regulate the activities of these proteins. We have previously demonstrated that the level of intracellular sodium concentration modulates the regulation of Na-K-ATPase activity by angiotensin II and dopamine. An increase of a few millimolars in intracellular sodium concentration leads to increased Na-K-ATPase activity without a statistically significant increase in the number of plasma membrane Na-K-ATPase molecules, as determined by cell surface protein biotinylation. Using total internal reflection fluorescence, we detected an increased number of Na-K-ATPase molecules in cytosolic compartments adjacent to the plasma membrane, suggesting that the increased intracellular sodium concentration induces a movement of Na-K-ATPase molecules toward the plasma membrane. While intracellular compartments containing Na-K-ATPase molecules are very close to the plasma membrane, compartments containing type 1 dopamine receptors (D1Rs) are distributed in different parts of the cell cytosol. Fluorescence determinations indicate that an increased intracellular sodium concentration induces the increased colocalization of dopamine receptors with Na-K-ATPase molecules in the region of the plasma membrane. We propose that under in vivo conditions, in response to a sodium load in the lumen of proximal tubules, an increased level of intracellular sodium in epithelial cells is an early event that triggers the cellular response that leads to dopamine inhibition of proximal tubule sodium reabsorption.

renal sodium excretion; renal sodium reabsorption; renal sodium regulation; dopamine; angiotensin II; monensin; TIRF; epifluorescence; GFP

Although phosphorylation of Na-K-ATPase-1 is an essential step for dopamine-induced Na-K-ATPase endocytosis, it does not per se inhibit the Na-K-ATPase enzymatic activity. Phosphorylation of Na-K-ATPase-1 constitutes the triggering signal for removal of plasma membrane phosphorylated Na-K-ATPase molecules via clathrin-coated vesicles to intracellular compartments (8, 9). Thus dopamine does not affect the intrinsic activity of the Na-K-ATPase (turnover rate) but the number of Na-K-ATPase molecules that are available at the plasma membrane involved in sodium and potassium transport (37). We have recently described that intracellular compartments containing Na-K-ATPase molecules are located just underneath the plasma membrane (17). We have also shown that the level of intracellular sodium concentration modulates the plasma membrane recruitment of D1Rs and dopamine-induced endocytosis of Na-K-ATPase molecules in proximal tubule epithelial cells (14). In this study, we present evidence of intracellular trafficking of Na-K-ATPase molecules and D1Rs in response to changes in intracellular sodium concentration.

	MATERIALS AND METHODS

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Materials. Ouabain, dopamine, and ExtrAvidin peroxidase were obtained from Sigma (St. Louis, MO). Alexa Fluor 488-tagged anti-mouse and Cy3-tagged anti-rabbit antibodies were purchased from Molecular Probes (Eugene, OR). Sulfo-NHS-biotin was obtained from Pierce (Rockford, IL). Na-K-ATPase-1 antibody (27) was a generous gift from Dr. Michael J. Caplan (Yale University, New Haven, CT). Other reagents were of the highest quality available.

Cell culture and transfection. The basic functional unit of Na-K-ATPase is composed of two subunits, and β. Several different isoforms of these subunits are expressed in different mammalian tissues; however, the kidney only expresses the 1- and β1-polypeptides (30). Because of this, in our experiments we only transfected opossum kidney (OK) cells with the 1-isoform. OK cells stably expressing the rat Na-K-ATPase 1-wt or the S18A mutant of this protein were cultured in DMEM containing 10% calf serum and antibiotics. Plasmid preparation, site-directed mutagenesis, and stable expression of Na-K-ATPase-1 were performed as previously described (38, 39). Cells expressing Na-K-ATPase 1-wt or 1-S18A were selected and maintained in a 3 µM ouabain medium. While Na-K-ATPase molecules with the endogenous OK cell 1 are totally inhibited, Na-K-ATPase molecules containing the rodent 1 are resistant to this amount of ouabain (39). Thus Na-K-ATPase molecules containing the OK cell endogenous 1 should not interfere with determinations performed in cells expressing rodent 1 (38, 39). Before treatment with monensin, cells were incubated for 30 min in the same culture medium without serum and buffered with 50 mM HEPES. The optimal concentrations of reagents and the extension of the treatments used in these experiments were as previously determined (12, 13, 19). Antibodies were blocked with 1% milk in PBS before use.

Determination of Rb⁺ uptake. Measurements of Na-K-ATPase-mediated Rb⁺ uptake were performed with attached cells as previously described (38, 39). In short, transfected cells were transferred to serum-free DMEM containing 50 mM HEPES, pH 7.4, and either 3 µM or 5 mM ouabain. Cells were incubated with these concentrations of ouabain for 20 min at 37°C in an air atmosphere and 10 min at 23°C before their treatment with 5 µM monensin at 23°C for 30 min. Then, 1 mM dopamine and a trace amount of [⁸⁶Rb⁺]RbCl were added. After 20-min incubation at 23°C, cells were washed three times with ice-cold saline, dissolved with SDS, and accumulated radioactivity was determined in a gamma counter. Na-K-ATPase-mediated Rb⁺ uptake was estimated from the difference in tracer uptake between samples incubated in 3 µM and 5 mM ouabain.

Biotinylation of plasma membrane proteins. These experiments were performed as previously described (12) using OK cells expressing either 1-wt or 1-S18A and grown to 80% confluence. The cells were treated with monensin and dopamine as indicated above for the Rb⁺ uptake assay. Then, the cell medium was changed to ice-cold 10 mM Tris·HCl (pH 7.5), 2 mM CaCl₂, and 150 mM NaCl, 1.5 mg/ml sulfo-NHS-biotin. The cells were incubated in this medium for 1 h at 4°C.

Following biotin labeling, the cells were scraped in immunoprecipitation buffer (20 mM Tris, 2 mM EDTA, 2 mM EGTA, 30 mM sodium pyrophosphate, pH 7.3) containing a protease inhibitor cocktail, frozen in liquid nitrogen, thawed rapidly, probe-sonicated twice on an ice-water bath, and frozen-thawed again. The cell suspension was centrifuged at 14,000 g at 4°C for 5 min. The supernatants were transferred to clean tubes, and 1% Triton X-100 and 0.2% SDS were added. Protein concentration of the different samples was determined. To tubes containing the same amount of protein, anti-Na-K-ATPase-1 antibody was added and incubated for 1 h at 4°C with end-over-end shaking. The immunoprecipitation was performed under conditions that precipitate all cellular Na-K-ATPase molecules (12). Then, protein A/G-agarose, prewashed three times with PBS and once with immunoprecipitation buffer containing 1% Triton X-100, was added and incubated for 2 h at 4°C with end-over-end shaking. The pellet was washed four times with immunoprecipitation buffer containing 1% Triton X-100 and 0.1% SDS, once with 50 mM Tris·HCl (pH 7.4), and finally resuspended in Laemmli sample buffer (29). Electrophoresis and Western blot analysis with ExtrAvidin peroxidase were performed as previously described (12, 20). The blotted membranes were scanned, and the bands were quantified using an AlphaImager EC camera for gel documentation and analysis (Alpha Innotech, San Leandro, CA).

Fluorescence determinations. Cells attached to glass coverslips and grown to 90% confluence were incubated with monensin and dopamine as described in determination of Rb⁺ uptake. The cells were then washed twice with PBS containing 1.2% sucrose (PBSS), fixed with freshly prepared 4% paraformaldehyde in PBSS for 10 min, washed twice with PBSS, incubated with L-lysine/Na-m-periodate for 20 min, washed with PBSS, permeabilized with 0.2% BSA, 0.2% Triton X-100 in PBSS for 10 min, and washed again twice with PBSS. Cells were blocked with 5% BSA, 1% normal goat serum, 0.2% Tween 20 for 1 h, incubated with mouse anti-Na-K-ATPase-1 and rabbit anti-D1R antibodies and washed with PBSS. In the dark, cells were incubated with anti-mouse-Cy3 and anti-rabbit-Alexa Fluor 488 for 1 h. Then, the coverslips were washed, air dried, and mounted on glass slides using Gel-Mount containing antifading agents (Biomeda, Foster City, CA).

To obtain high-resolution three-dimensional fluorescence images of the cells, the imaging workstation consisted of an Olympus IX-81 inverted fluorescence microscope (Olympus, Tokyo, Japan), equipped with a x60/x100 oil-immersion objective lens, cooled Hamamatsu ORCA-ER CCD camera (Hamamatsu Photonics, Hamamatsu-city, Japan), a halogen 100-W light source, a motorized filter and shutter, and a scan wizard for collection of x/y and z image sequences and wavelength positions over time, all controlled by the SimplePCI software (Compix, Cranberry Township, PA). Images of cells labeled with both Cy3 and Alexa Fluor 488 were acquired sequentially through the two respective channels. To obtain deconvolved images, at least nine z-stacks of the field with a step of 0.3–0.5 µm were acquired, and deconvolution was performed using AutoDeblur software (AutoQuant Imaging, Troy, NY). For colocalization analysis, the two single-channel images of the same field were merged using SimplePCI software.

Total internal reflection fluorescence microscopy. For total internal reflection fluorescence (TIRF) determinations, OK cells expressing Na-K-ATPase molecules containing the fluorescent protein GFP (for green fluorescent protein) fused to the NH₂ terminal of 1 were used (10). The presence of GFP does not affect the level of protein expression, the amount of Na-K-ATPase expressed at the plasma membrane, the level of Rb⁺ transport mediated by the Na-K-ATPase, or the hormone regulation (10). The TIRF setup is based on a modified inverted fluorescence microscope (Olympus, Melville, NY) with a video camera (Pentamax, Princeton Instruments, Trenton, NJ) attached to its video port. Light from a 4-W Argon laser (Lexel 88) was directed through a software-controlled shutter (Univlitz, Vincent Associates, Rochester, NY) that opens during camera exposure. The 488-nm argon line (1,000 mW) was focused into one end of a 2-mm-diameter quartz fiber-optic setup fixed to the optical system attached to the microscope stage and passed through a set of collimation lenses, which focuses the light on the prism surface. An annulus in this path ensures that only central parallel laser rays reached the prism at the critical angle. The use of fiber optics has two main advantages. First, a fiber-optic setup allows the rapid alignment of the experimental chamber and the corresponding prism in the microscope stage with the selected angle of light incidence. Second, it produces uniform illumination, since it was vibrated at 5 kHz so that the typical laser-interfering patterns ("speckles") were cancelled out by their averaging during the exposure time of an image frame. Fluorescence images were detected by the camera after the emitted light was passed through the dichroic mirror and emission filters. The calibration of the evanescent wave depth was performed in a cell culture dish without cells by imaging a fluorescent bead through a calibrated piezoelectric positioning drive (35).

TIRF determinations at different concentrations of sodium were performed by permeabilizing the cell membrane with 10 µM gramicidin D and superfusing the sample with different standard sodium concentrations (13). Alternatively, the cells were treated with monensin and TIRF determinations were performed at different times, before and after the addition of monensin.

Statistical analysis. Each experiment was repeated at least three times. Comparison between two experimental groups was determined by the nonpaired Student's t-test. P < 0.05 was indicated with an "*" in the figures. For the microscopic images, at least eight randomly chosen sets of cells were used in each experimental condition. Figures show representative images for each experiment.

	RESULTS

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Experiments were performed with OK cells, which are widely used as a cell culture model of proximal tubule epithelial cells (24, 31, 34). Cells were grown in DMEM containing calf serum and antibiotics. Under these conditions, OK cells attach to the bottom of cell culture flasks and form a monolayer. In animal models, the dopamine natriuretic effect was only observed under conditions of sodium load (1, 4, 26). Consistently, we and other researchers have observed that a slight increase in the level of intracellular sodium concentration is essential for dopamine-induced endocytosis of Na-K-ATPase molecules and the concomitant reduced capacity of the cell to transport sodium (13, 41). The use of the ionophore monensin allows us to change the intracellular sodium concentration in a stepwise manner and maintain the electrogenic gradient across the plasma membrane (13). The elevated intracellular sodium concentration elicited by 5 µM monensin produced a stimulation of Na-K-ATPase-mediated Rb⁺ uptake (Fig. 1). Using fluorescence microscopy, we have previously determined that OK cells have a basal level of intracellular sodium concentration of 9 mM and that 5 µM monensin doubles the basal intracellular sodium concentration (13). Subsequent addition of dopamine results in a 25% reduction of Na-K-ATPase-mediated Rb⁺ uptake (Fig. 1).

View larger version (17K): [in this window] [in a new window]   Fig. 1. Effect of monensin (Mon) and dopamine (DA) on Na-K-ATPase-mediated Rb+ uptake. Opposum kidney (OK) cells expressing the wild-type (WT, left) or S18A mutant form of Na-K-ATPase-1 (right) were treated with 5 µM monensin for 30 min and 1 µM dopamine for 5 min before Rb+ uptake assay. *P < 0.05.

Increased intracellular sodium concentration does not affect the abundance of plasma membrane Na-K-ATPase. To determine whether monensin changes the size of the Na-K-ATPase plasma membrane pool, we used the technique of cell membrane protein biotinylation (12, 14, 15, 18, 23, 28, 47, 48). Sulfo-NHS-biotin reacts with primary amino groups and does not permeate the plasma membrane; thus, proteins containing primary amines exposed to the extracellular medium are the only ones that are biotinylated. As the reaction is performed at 4°C, intracellular protein trafficking does not occur and there is no exchange between the intracellular compartments and plasma membrane pool of Na-K-ATPase molecules. For determination of the absolute number of plasma membrane Na-K-ATPase molecules using cell surface protein biotinylation, the efficiency of reaction between the protein amino groups and the biotinylation reagent is very critical since the intent is to label optimally 100% of the Na-K-ATPase molecules present at the plasma membrane (23). This is not the case when biotinylation is used to determine a change in the size of the plasma membrane pool of Na-K-ATPase molecules. In this case, the critical consideration is that the labeling efficiency is the same in treated samples and controls. Although we may not have labeled all of the Na-K-ATPase molecules at the plasma membrane, care was taken to produce the biotinylation reaction in the same conditions in treated samples and controls.

Consistent with results presented in Fig. 1, there was no significant difference in the amount of plasma membrane Na-K-ATPase of cells expressing 1-wt and 1-S18A (Fig. 2). The same level of biotinylation was observed in cells treated or not with monensin, which suggests that increased intracellular sodium does not affect the size of the plasma membrane Na-K-ATPase pool. Subsequent addition of dopamine reduced the plasma membrane Na-K-ATPase abundance in cells expressing 1-wt, but had no effect on cells expressing the 1-S18A mutant. Results illustrated in Figs. 1 and 2 are consistent with previous observations by other investigators, in different cell types, showing that an acute increase in intracellular sodium concentration does not affect the number of plasma membrane Na-K-ATPase molecules (3, 40, 43, 47–49).

View larger version (20K): [in this window] [in a new window]   Fig. 2. Effect of monensin and dopamine on plasma membrane Na-K-ATPase-1 abundance. OK cells expressing the wild-type or S18A mutant form of Na-K-ATPase-1 were treated with 5 µM monensin for 30 min and 1 µM dopamine for 5 min. The abundance of Na-K-ATPase molecules at the plasma membrane was determined by biotinylation, as described in MATERIALS AND METHODS. After biotinylation, the cells were dissolved and, from samples containing the same amount of protein, Na-K-ATPase molecules were precipitated using a specific antibody. The amount of biotin present in the immunoprecipitated Na-K-ATPase molecules was determined by Western blot analysis. Top: representative Western blots. Bottom: quantitation of Western blots. *P < 0.05 with respect to cells treated with monensin alone.

A brightfield image, a fluorescence image, and a TIRF image of the same cell are illustrated in Fig. 3, A, B, and C, respectively. Both epifluorescence and TIRF images were acquired at a 490-nm excitation wavelength. The evanescent wave depth was determined to be 247 ± 8.8 nm (mean ± SD; n = 8) by imaging a fluorescent bead through a calibrated piezoelectric positioning drive, as described by Oheim et al. (35). This determination was performed using a free-cell system, and it may reflect the maximum evanescent wave thickness under optimal conditions. Other researchers estimated that the evanescent wave may extend 100–150 nm from the surface containing the trapped laser beam (2, 42, 44). Considering that the plasma membrane has an average thickness of 50 nm, the evanescent wave extends beyond the plasma membrane and has the capacity to excite GFP-tagged Na-K-ATPase molecules that are just underneath the plasma membrane. We have determined that the attached OK cells have a depth of 9 µm (17).

View larger version (40K): [in this window] [in a new window]   Fig. 3. Images of cells expressing green fluorescent protein (GFP)-tagged 1 observed under epifluorescence and total internal reflection fluorescence (TIRF) illumination. A: brightfield image of a typical OK cell taken using Hoffman modulation contrast optics. B and C: fluorescence images of the same cell acquired using epi- and evanescent wave illumination, respectively. Bar = 5 µm.

View larger version (70K): [in this window] [in a new window]   Fig. 4. Increased TIRF level of GFP-tagged Na-K-ATPase-1 in response to increased intracellular sodium concentration. A: control fluorescence image and corresponding pixel-by-pixel fluorescence determination of an OK cell obtained by evanescent wave illumination. Bar = 5 µm. B: TIRF images obtained at different sodium concentrations after the cell membrane was permeabilized with 10 µM gramicidin D. C: percentage of signal changes (means ± SD) observed in relation to control fluorescence levels from 18 different cells. Under basal conditions, these cells have an average of 9 mM intracellular sodium (10). Numbers on the abscissa indicate the increase of intracellular sodium with respect to the control basal intracellular sodium concentration level.

View larger version (69K): [in this window] [in a new window]   Fig. 5. Fluorescence light changes under evanescent wave illumination evoked in OK cells by monensin and dopamine. TIRF determinations were performed in cells expressing either Na-K-ATPase-1 (A and B) or the S18A mutant of this protein (C and D), both fused to GFP. Determinations illustrated in the histograms were performed every 2 min (B and D), and arrows indicate the times images illustrated in A and C were captured. Times of application of monensin and dopamine are indicated. Fluorescence increases were coded in pseudocolors and overlapped on a brightfield image of the corresponding OK cell acquired using Hoffman modulation contrast. Blue, green, yellow, and red represent signal increases equivalent to 1, 1.5, 2, 2.5, and 3 SD of the pixel variability in the image background, respectively. Bar = 5 µm.

We have previously observed that while most of the Na-K-ATPase molecules are in the area of the plasma membrane (17), under basal conditions, D1Rs are mainly localized in the cell interior (14). Brismar et al. (5) have shown that there is some colocalization of Na-K-ATPase molecules with D1Rs. We wanted to determine whether this colocalization depended on or was affected by the level of intracellular sodium concentration. Thus we performed experiments using nontransfected OK cells and determined the possible colocalization of the endogenous proteins. Figure 6 shows that in cells treated with monensin, the colocalization between the fluorophores attached to Na-K-ATPase and D1Rs is significantly increased (Fig. 6, 2nd row, right). These results are consistent with our previous observations that an increase in intracellular sodium (elicited by monensin) produces the recruitment of D1Rs to the plasma membrane (14), inducing an increased colocalization of D1Rs with Na-K-ATPase molecules. Subsequent treatment of the cells with dopamine further increased the colocalization of Na-K-ATPase and D1R molecules (Fig. 6, 3rd row, right).

View larger version (73K): [in this window] [in a new window]   Fig. 6. Colocalization of Na-K-ATPase-1 and type 1 dopamine receptor (D1R). Images of OK cells expressing Na-K-ATPase wild-type 1 treated with vehicle (top), 5 µM monensin for 30 min (middle), and 5 µM monensin for 30 min, and then with 1 µM dopamine for 5 min (bottom) are shown. Fluorescence images were acquired through the Cy3 channel (Na-K-ATPase-1) and the Alexa Fluor 488 channel (D1R). Merged images (right) were obtained using SimplePCI software. Cells were treated and images acquired as described in MATERIALS AND METHODS. Arrows point to the sites of colocalization.

	DISCUSSION

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Because of the limited availability of sodium that occurs at the basal level of intracellular sodium concentration (10 mM), at any given time, most of the plasma membrane Na-K-ATPase molecules are not working (maximal activity is observed at 120 mM sodium) (22). In cells treated with monensin, the increased intracellular sodium concentration induces that more Na-K-ATPase molecules, already present at the plasma membrane, participate in sodium transport and this is expressed as increased Na-K-ATPase activity. Through this mechanism, the cell can handle small increases in intracellular sodium concentration and does not need an increased plasma membrane pool of Na-K-ATPase to reduce the intracellular sodium concentration. Consistently, using cell surface protein biotinylation, we could not detect any significant change in the size of the plasma membrane pool of Na-K-ATPase molecules (Fig. 2). The biotinylation technique seems to have worked properly since we could detect reductions in the plasma membrane pool of Na-K-ATPase induced by dopamine (Fig. 2), which corresponds to a reduction in the level of TIRF (Fig. 5). However, it can be argued that the increased intracellular sodium concentration promotes the delivery of Na-K-ATPase molecules to the plasma membrane and that these molecules participate in sodium transport, but they are not accessible to labeling by sulfo-NHS-biotin. Several lines of evidence suggest that this is not a likely explanation to the results of cell surface protein biotinylation. Our observation that an increase in intracellular sodium concentration does not produce an acute increase in the size of the plasma membrane pool of Na-K-ATPase molecules has been previously reported by other researchers (3, 40, 43, 47–49). In several cell types, it was described that an increase in intracellular sodium concentration produces an increase in the plasma membrane pool of Na-K-ATPase molecules that is dependent on protein synthesis (40, 43, 49). Thus there is a lag of several hours between the increase in intracellular sodium concentration and the increase in the plasma membrane pool of Na-K-ATPase molecules. Besides these effects that depend on protein expression, it has also been described that an increase in intracellular sodium concentration in cortical collecting tubule cells produces the recruitment of Na-K-ATPase molecules to the plasma membrane from an intracellular latent pool (3, 47, 48). This effect was observed after 1–2 h of intracellular sodium increase. These reports indicate that an increased intracellular sodium concentration induces the delivery of Na-K-ATPase molecules to the plasma membrane and that the just-delivered Na-K-ATPase molecules could be determined using different techniques: binding of an anti-Na-K-ATPase antibody, ouabain binding, and cell surface protein biotinylation. However, this is not an acute response to the increased level of intracellular sodium.

While the experiments reported above were performed with final concentrations of intracellular sodium of 100 mM and higher, our experiments were performed at a final concentration of 19 mM (a change in intracellular sodium of 10 mM). This is very important to consider because the Na-K-ATPase molecules that are already present at the plasma membrane can easily handle small changes in intracellular sodium concentrations. Furthermore, our experiments were done during the lag period in which the references described above did not observe any increase in the plasma membrane pool of Na-K-ATPase. On the other hand, we have evidence that if there were Na-K-ATPase molecules delivered to the plasma membrane in response to the increased intracellular sodium, we would have determined them. Using the same biotinylation technique described in this manuscript, we determined an increased plasma membrane pool of Na-K-ATPase molecules in cells treated with angiotensin II (14), PMA (12), or the serotonin agonist 8-OH-DPAT (6). Furthermore, while the increased intracellular sodium concentration did not promote an increase in the plasma membrane pool of Na-K-ATPase molecules, it did increase the plasma membrane pool of D1Rs, which we determined using the same biotinylation method described in this manuscript (14). Thus the experimental results from us and other researchers support our conclusion that an increased intracellular sodium concentration does not produce an acute increase in the plasma membrane pool of Na-K-ATPase molecules.

We considered the possibility that the changes in TIRF were not the result of the movement of GFP-tagged Na-K-ATPase molecules inside the evanescent wave field, but due to a change in the intrinsic fluorescence of GFP in response to conformational changes in the Na-K-ATPase molecule. Since the Na-K-ATPase cellular activity is limited by the availability of intracellular sodium (4, 21, 22), treatment with monensin increases the number of Na-K-ATPase molecules that are involved in sodium transport. This is reflected in the increased Na-K-ATPase activity illustrated in Fig. 1. During the process of sodium transport, the Na-K-ATPase that is in the basal E2 conformation switches to the E1 conformation (22). However, the change of conformation E2 E1 E2 is very fast, so that most of the time the Na-K-ATPase is in the E2 conformation. Since the molecules under turnover are not synchronized, some of the Na-K-ATPase molecules would be in E1 while others are in the E2 conformation. Even assuming that GFP attached to Na-K-ATPase-1 in the E1 conformation has more fluorescence than when GFP is attached to the E2 conformation, this would not explain the TIRF increase we observed because the enzyme is only transiently in the E1 conformation. It is important to notice that while the E2 E1 E2 conformational change occurs in the millisecond range, we observed a steady increased in TIRF over 20–30 min. Furthermore, we have specifically determined that treating the cells with monensin does not produce any change in the level of fluorescence of a fluorophore attached to the Na-K-ATPase-1 NH₂ terminal (16).

Using fluorescence resonance energy transfer, we have demonstrated that dopamine-induced phosphorylation of 1-Ser-18 results in a conformational change in the 1 NH₂ terminal such that this part of the protein is closer to the plasma membrane (16). However, this is not responsible for the changes in TIRF we describe in this report because the TIRF increase was also observed in cells expressing the 1-S18A mutant, which cannot be phosphorylated by the action of dopamine and consequently does not display any conformational change. Furthermore, the TIRF increase is produced by increased concentration of intracellular sodium, which we observed does not produce any conformational change in the Na-K-ATPase-1 (16). It may be argued that the increased level of TIRF is not produced by an increased level of intracellular sodium concentration but to other undetermined effects of monensin, such as changes in the membrane potential. The experiments with gramicidin suggest that this is not the case. The only characteristic that these experiments have in common with those with monensin is the increased level of intracellular sodium concentration. However, the mechanism to increase intracellular sodium is different, and in the experiments with gramicidin there is no sodium concentration gradient across the plasma membrane.

Dopamine induced a reduction in the TIRF level, which is consistent with the decrease in Na-K-ATPase abundance at the plasma membrane (Fig. 2) and the level of reduction of Na-K-ATPase activity (Fig. 1) elicited by the dopamine treatment. The specificity of this effect for Na-K-ATPase is demonstrated by the fact that none of the three dopamine effects (reduction of TIRF, reduction of plasma membrane Na-K-ATPase, and reduction of Na-K-ATPase activity) were observed when the experiments were performed in OK cells expressing the S18A mutant of 1. The fact that dopamine treatment induced a TIRF reduction and a corresponding decrease in the plasma membrane Na-K-ATPase pool suggests that the Na-K-ATPase molecules withdrawn from the plasma membrane are translocated to intracellular compartments that are beyond the reach of the evanescent field. However, these intracellular compartments are still very close to the plasma membrane (17). As the resolution of fluorescence microscopy is not enough to clearly separate Na-K-ATPase molecules in intracellular compartments from Na-K-ATPase molecules in the plasma membrane, the endocytosis of Na-K-ATPase molecules induced by dopamine is not evident in the results presented in Fig. 6.

Under basal conditions, most of the proximal tubule epithelial cell D1Rs are located in intracellular compartments (5, 14, 26), and treatment with dopamine induces the recruitment of the D1Rs to the plasma membrane (5, 26, 46). We have previously demonstrated that the plasma membrane recruitment of D1Rs can also be induced by increasing the intracellular sodium concentration (14). In this report, using fluorescence microscopy, we show that the colocalization of Na-K-ATPase and D1Rs was greatly increased in cells with higher intracellular sodium concentration. Because Na-K-ATPase molecules are in intracellular compartments just beneath the plasma membrane (17) or at the plasma membrane, the increased colocalization between D1Rs and Na-K-ATPase occurs because the D1Rs are being recruited to the plasma membrane. Thus it is possible that in their transit toward the plasma membrane, vesicles containing D1Rs fuse with intracellular compartments containing Na-K-ATPase, and then these vesicles move toward the plasma membrane to discharge D1Rs.

In vivo, dopamine inhibition of proximal tubule sodium reabsorption is only observed under conditions of sodium load (1, 26, 41, 45). Consistent with this, for dopamine to inhibit the Na-K-ATPase, the intracellular sodium concentration of proximal tubule epithelial cultured cells should be increased by a few millimolars above basal levels (13, 41). Thus we propose that a small increase in intracellular sodium is an early signal that triggers the proximal tubule cell to respond to a sodium load. When the proximal tubule cell identifies that an increase in intracellular sodium has occurred, a series of processes are initiated to counteract the increased sodium reabsorption: the recruitment of D1Rs from intracellular storage compartments to the plasma membrane with a parallel decrease of type 1 angiotensin II receptors (7, 14), activation of the dopaminergic intracellular signaling cascade of second messengers, the synthesis by the proximal tubule cells of dopamine, and its facilitated transport to the cell exterior (1), where the hormone binds to the just-recruited receptors. Activation of D1Rs promotes inhibition of proximal tubule sodium reabsorption. Then it is possible that as part of this cellular response, intracellular compartments move toward the plasma membrane to receive the Na-K-ATPase molecules that will be endocytosed in response to activation of D1Rs. After the endocytosed Na-K-ATPase molecules are received by the intracellular compartments, they move back toward the inside of the cell. This would correspond to the reduction of TIRF observed after treatment with dopamine.

	GRANTS

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This research was supported by National Institute of Diabetes and Digestive and Kidney Diseases Grant DK-62195 to C. H. Pedemonte.

	ACKNOWLEDGMENTS

 
The authors thank Dr. Enrique Torre (Emory University) for advice on fluorescence microscopy, Dr. Mustafa Lokhandwala (University of Houston) for helpful discussions, and Dr. Samina Salim (University of Houston) for critically reading the manuscript.

	FOOTNOTES

 

Address for reprint requests and other correspondence: R. Efendiev, Univ. of Texas Health Science Center at Houston, Medical School, Dept. of Integrative Biology and Pharmacology, 6431 Fannin, MSB-4.218, Houston, TX 77030 (e-mail: Riad.Efendi{at}uth.tmc.edu)

The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

^* A. R. Cinelli and R. Efendiev contributed equally to this work.

	REFERENCES

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1. Aperia AC. Intrarenal dopamine: a key signal in the interactive regulation of Na⁺ metabolism. Annu Rev Physiol 62: 621–647, 2000.[CrossRef][Web of Science][Medline]
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