1Department of Physiology, Mahidol University, Bangkok, 10700 Thailand; and 2Department. of Physiology, University of Arizona, Tucson, Arizona 85724
Submitted 21 March 2003 ; accepted in final form 23 August 2003
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ABSTRACT |
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organic cation; transport; tetraethylammonium; cimetidine; kidney
Efforts to understand the cellular and molecular basis of OC secretion in RPT have been substantially advanced by the cloning of several members of a group of related transport proteins now referred to as the organic cation transporter (OCT) family of proteins (designated as 2.A.1.19 by the transport panel of the nomenclature committee of the International Union of Biochemistry and Molecular Biology) (25). Of the several OCTs that have been cloned, three of them, OCT1 (13), OCT2 (22), and OCT3 (17), have physiological characteristics consistent with those observed for the basolateral OC entry step, including an electrogenic mode of operation (see Ref. 4) and the capacity to accept a diverse range of cationic compounds as transported substrates (see Ref. 11). Immunocytochemical localization has generally shown that OCT1 and OCT2 are effectively restricted to the basolateral membrane of cells in which they are expressed (16, 21, 31). Importantly, there are marked differences in tissue distribution for these different OCTs. Of particular relevance to the issue addressed in the present study, in both humans and rats OCT2 mRNA expression in the kidney greatly exceeds that for OCT1 and OCT3 (21, 30). In fact, in the human kidney, immunocytochemistry failed to show any evidence for OCT1 expression in RPT, although OCT2 expression in the basolateral membrane was clearly evident (OCT3 localization has not been examined) (21). However, in the rat kidney both OCT1 and OCT2 are expressed in the basolateral membrane of RPT and are coexpressed in the S2 segment (16). It is not clear whether other common animal models of renal tubular function share characteristics of OCT distribution similar to that of the human and the rat or, instead, display a different distribution. In no species is it clear to what extent tubule localization of transporters by mRNA expression and immunocytochemistry is correlated with actual transport activity.
In the present study, we set out to develop a strategy for the functional mapping
of OCT1 and OCT2 transport activity in a physiologically intact model of renal OC secretion. We elected to use the rabbit kidney because of its utility in studies of intact tubule function. The approach involved use of the cloned rabbit orthologs of each transporter, expressed in at least two separate expression systems, to identify
discriminatory inhibitors,
i.e., compounds that preferentially interact with one or the other of the target transporters. The IC50 values obtained for each of these compounds against each transporter were then compared with IC50 values obtained in studies of basolateral OC transport activity in isolated, nonperfused single S2 segments of rabbit RPT. The inhibitory profiles obtained for both OCT1-selective and OCT2-selective inhibitors were consistent with the conclusion that OC transport in the S2 segment of rabbit RPT is dominated by OCT2. The functional mapping strategy, as outlined here, underscored both the importance of making quantitative comparisons between the results obtained with cloned transporters to those obtained in native tissue preparations and the need to exercise suitable caution when making such comparisons.
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METHODS |
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Transient expression of rbOCT1 and rbOCT2 in COS-7 cells and CHO-K1 cells. COS-7 and CHO-K1 cells were grown in F-12-Ham's-Kaighn's Modification (F12K) medium supplemented with 10% fetal bovine serum, 100 U/ml of penicillin, and 100 µg/ml of streptomycin. Cells were kept in a humidified atmosphere supplied with 5% CO2-95% air. Cells were transfected with pcDNA3.1 containing rbOCT1 or rbOCT2 (38), using electroporation (BTX model ECM 630 rev.E, Genetronics, San Diego, CA) and a method described elsewhere (2). Briefly, cells were mixed with 10 µg of desired plasmid DNA and 10 µg of salmon sperm DNA and pulsed at 260 V and 1,050 F for 2030 ms. The cells were dispersed with a plastic transfer pipette and then plated in 12-well plates at 320,000 cells/well. The medium was changed 24 h after plating. Experiments were performed after the cells had reached confluence (normally, 48 h after plating).
Stable expression of rbOCT1 or rbOCT2 in CHO-K1 cells. CHO-K1 cells were transiently transfected with cDNAs for either rbOCT1 or rbOCT2 and after 24 h placed in culture medium supplemented with 1 mg/ml of G418 (GIBCO BRL). Surviving cells were tested for the functional expression of OC transport activity by using the fluorescent organic cation NBD-TMA, which has been shown to be a substrate for peritubular OC transport in single isolated rabbit RPT (3). Single colonies that accumulated 20 µM NBD-TMA were selected from 96-well plates. Stable clonal cell lines that expressed either rbOCT1 or rbOCT2 were grown in the selection medium and used for subsequent experiments.
Transport assays. Uptake of [3H]TEA into cells expressing either rbOCT1 or rbOCT2 was measured at 25°C. After removal of the culture media, cells were washed twice with Waymouth's buffer [WB; (in mM) 135 NaCl, 13 HEPES, 28 D-glucose, 5 KCl, 1.2 MgCl2, 2.5 CaCl2, 0.8 MgSO4, pH adjusted to 7.4 with NaOH] and then preincubated for a total of 30 min in WB (2 x 15 min). Uptake was stopped by removing the transport buffer and then rinsing the cells with three successive washes with 1 ml of ice-cold WB containing 250 µM tetrapentylammonium (TPeA). The cells were solubilized with 1% SDS in 0.2 N NaOH, neutralized with 0.4 N HCl, and transferred to scintillation vials for measurement of accumulated radioactivity (Beckman LS 3801, Beckman Instruments, Irvine, CA). Uptake rates are expressed as moles per square centimeter of surface area of the confluent monolayer.
Transport in isolated S2 segment of RPT. New Zealand White rabbits were euthanized by intravenous injection with pentobarbital sodium. The kidneys were flushed via the renal artery with an oxygenated ice-cold HEPES-sucrose solution, pH 7.4 (10 mM HEPES and 250 mM sucrose, pH adjusted with Tris base). Transverse slices of an isolated kidney were placed in a dish containing ice-chilled dissection buffer (in mM: 110 NaCl, 25 NaHCO3, 5 KCl, 2Na2HPO4, 1.8 CaCl2, 1 MgSO4, 10 sodium acetate, 8.3 D-glucose, 5 L-alanine, 4 lactate, and 0.9 glycine; pH adjusted to 7.4 with HCl or NaOH and gassed continuously with 95% O2-5% CO2 to maintain the pH; osmolarity of 290 mosmol/kgH2O). The S2 segments were manually dissected from a kidney slice at 4°C without use of enzymatic digestion. To select the S2 portion of rabbit proximal tubule, a 1- to 1.5-mm length of straight tubule was teased from a slice, starting at the cortical surface of the kidney (27). The ends of each tubule were trimmed to an average length of
1 mm. The inhibition studies were performed in a temperature-controlled chamber at 37°C. Uptakes were measured by transferring each tubule into an oil-covered well in the chamber containing dissection buffer and radiolabeled substrate, with/without inhibitors of interest. After a 1-min incubation, uptake was stopped by transferring the tubule into microwells (60-well plate, Nunc, Naperville, IL) containing 10 µl of 1 N NaOH covered with light mineral oil. The tubules were solubilized for at least 30 min, after which the tubule extracts were transferred into small scintillation vials containing 200 µl of distilled water. The scintillation cocktail (3 ml) was added to each vial, and the radioactivity was determined using liquid scintillation spectroscopy (Beckman LS 6000 IC). At least three tubules were used to determined transport for each experimental condition tested. Transport rates were normalized to tubule length based on measurements determined from photomicrographs taken of each tubule before the experiment.
Isolation of RNA and RT-PCR. Total RNA was prepared from isolated rabbit kidney tubules following the method of Sambrook et al. (26). Immediately after euthanasia, kidneys were perfused with cold, sterile HEPES-sucrose solution (pH 7.4), removed, and placed in the same solution on ice. Slices were taken from the kidneys and kept in the same solution on ice while S2 segments were dissected. Typically, four equal groups of four to five tubule segments were transferred, along with 2 µl of buffer, to separate microfuge tubes each containing 4 µl of 2% Triton mix (89 µl sterile water, 4 µl RNase inhibitor, 5 µl 0.1 M DTT, and 2.4 µl Triton X-100). After 5 min at room temperature, the segments were frozen in liquid nitrogen and stored at 20°C until ready for RT.
Standard RT was performed on the solubilized samples, using both random primers and Oligo(dT)1218 base pairs. Two samples had Superscript II, and the other two had water in place of Superscript II to serve as a negative control. After inactivation of the RT reaction, RNase H was added, and the samples were incubated at 37°C for 20 min to remove any remaining complementary RNA. PCR tubes were set up (50 µl total volume) using all 20 µl of RT product/PCR sample. The amount of 10x PCR buffer was adjusted to compensate for the substantial amount of first-strand buffer and to provide an appropriate concentration of MgCl2. PCR tubes were also set up for rbOCT1 and rbOCT2 plasmid samples to be run as positive controls. The primers (Integrated Technologies) were as follows: for rbOCT1, a 525-bp fragment was derived from 5'-AGCTGGATGTCCGGCTA-3' (sense) and 5'-TGGTGACCAGGATGACGA-3' (antisense); and for rbOCT2, a 361-bp fragment was derived from 5'-GGAAGCACACCTGCATCTTG-3' (sense) and 5'-GAGATTCCTGATGAACGTGG-3' (antisense). All PCR samples were run simultaneously, using identical parameters, on a thermal cycler for 35 cycles. Amplified products were concentrated as needed and then separated and visualized with ethidium bromide on a 1.5% agarose gel.
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RESULTS AND DISCUSSION |
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Time course of rbOCT1- and rbOCT2-mediated [3H]TEA uptake in CHO-K1 and COS-7 cells. The first requirement was to establish the quantitative characteristics of rbOCT1 and rbOCT2 transport in the two cell lines. As shown in Fig. 1, both transporters supported time-dependent [3H]TEA uptake when expressed in either cell type. In clonal lines of CHO-K1 cells in which the transporters were stably expressed, the rates of OCT1- and OCT2-mediated transport of 0.05 µM [3H]TEA were approximately equivalent and comparatively rapid, with steady-state accumulation being approached within 10 min (Fig. 1A). Transport in the COS-7 cells (in which the transporters were transiently transfected) was not as rapid, with transport continuing to be nearly linear for at least 20 min (Fig. 1B). The presence of 2.5 mM unlabeled TEA reduced the 10-min uptake of labeled substrate by 60% (OCT1 in COS-7) and by >95% (both OCT1 and OCT2 in CHO-K1 cells). Importantly, uptake of TEA into wild-type CHO-K1 and COS-7 cells was <2% of that measured in cells transfected with the cDNAs for OCT1 and OCT2 (data not shown). Thus the transport that was observed in cells transfected with OC transporter cDNAs reflected activity of those proteins. Given the profile of time-dependent transport in these cells (Fig. 1), estimates of the initial rate of TEA transport for the measurement of kinetics were typically based on 2-min uptakes in CHO-K1 cells and 5-min uptakes in COS-7 cells.
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Kinetics of OCT1- and OCT2-mediated TEA transport in CHO-K1 and COS-7 cells. Figure 2A shows the effect of increasing concentrations of unlabeled TEA on the rate of uptake of 0.05 µM[3H]TEA into a clonal line of CHO-K1 cells (clone 7) that stably expressed rbOCT1 or rbOCT2. The hyperbolic inhibition of [3H]TEA transport was described by Michaelis-Menten kinetics of competitive interaction between labeled and unlabeled TEA (19)
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Figure 2A also shows the kinetics of rbOCT2-mediated TEA uptake in a clonal line of CHO-K1 cells that stably expressed the transporter. The Kt for this transport was 34.5 ± 6.9 µM (n = 2) with a Jmax of 7.9 ± 0.9 pmol · cm2 · min1. The Kt for rbOCT2-mediated transport in transiently transfected CHO-K1 cells, 34.1 ± 0.4 µM (with a Jmax of 1.3 ± 0.25 pmol · cm2 · min1), was virtually identical to that measured in the stably expressing clonal cell line and, in both cases, was slightly higher than that observed for rbOCT1.
We were under no illusion that the quantitative characteristics of OCT transport expressed in CHO-K1 cells, particularly the apparent Michaelis constants of expressed transporters, would necessarily mirror those of these processes when expressed in native renal tubules. Consequently, we considered it prudent to compare the characteristics of rbOCT1 and rbOCT2 in at least one other expression system, and we chose COS-7 cells for this purpose. Figure 2B presents the results of representative experiments that measured the kinetics of rbOCT1 and rbOCT2 in transiently transfected COS-7 cells. For rbOCT1 the Kt was 121.0 ± 3.9 µM, with a Jmax of 3.1 ± 0.9 pmol · cm2 · min1. For rbOCT2 the Kt was 75.6 ± 8.7 µM, with a Jmax of 3.1 ± 0.8 pmol · cm2 · min1. For both transporters, the apparent affinity for TEA when expressed in COS-7 cells was less than that observed in CHO-K1 cells. The lower affinity for substrate of these transporters when expressed in COS-7 cells was a characteristic routinely observed for other putative OC substrates, as expanded on below. Comparison of these values to those reported for OCT1 and OCT2 orthologs from other species is difficult, in large part because of the large variability reported for these values, as noted earlier. However, in general, the apparent affinities of these rabbit OCTs for TEA expressed in both CHO-K1 and COS-7 cells were typically on the low side of the values reported for orthologs from other species (e.g., 6, 8, 37).
We noted previously that it is difficult to judge the extent to which quantitative differences in kinetic characteristics of cloned transporters in the literature reflect different expression systems employed or differences in technique or methodology employed to make the measurements. To this end, it is instructive to note that the Kt values for rbOCT1- and rbOCT2-mediated TEA transport in COS-7 cells reported here differ from those we reported in a previous study (38). As noted above, for OCT1, the Kt was 121.0 ± 3.9 µM; in our previous study, the Kt in transiently transfected COS-7 cells was measured as 188 ± 20 µM. For OCT2, the present value was 75.6 ± 8.7 µM, whereas it was 125 ± 22 µM in our previous study. Although these differences are comparatively small, they were measured (in some cases) on the same day, using the same cells, and the same experimental and analytic methodology; the only evident differences were those arising from a different person conducting the mechanical actions associated with the measurements. It is likely, therefore, that quantitative differences of this size and larger will occur when different research groups, employing more substantial technical differences than those in our identical
experiments, report the results of measurements of the kinetics of substrate/inhibitor interactions with cloned transport proteins.
Discriminating inhibitors for rbOCT1 and rbOCT2. Functional mapping of OCT distribution within a defined segment of rabbit proximal tubules required identification of inhibitors for which OCT1 and OCT2 have markedly different apparent affinities. For this purpose, we examined the inhibition of TEA transport by rabbit OCT1 and OCT2 expressed in CHO-K1 and COS-7 cells. Using a similar approach, Arndt et al. (1) identified several compounds that effectively discriminated between rat OCT1 and OCT2 when expressed in X. laevis oocytes. For example, rOCT1 displayed a 25-fold higher apparent affinity for guanidine than did rOCT2 (IC50 values of 171 vs. 4,470 µM, respectively). rOCT2-selective inhibitors included procainamide and mepiperphenidol, for which OCT2 displayed 25- to 65-fold higher apparent affinities than OCT1 (IC50 values of 20 and 7.1 compared with 445 and 474 µM, respectively).
We determined IC50 values for these and several other OCs as inhibitors of TEA transport by rabbit OCT1 and OCT2 expressed in CHO-K1 cells (Table 1). Uptake of [3H]TEA was measured in the presence of increasing concentrations of inhibitor, and the data were analyzed using a suitable modification of Eq. 1 (12). Although the rabbit orthologs generally showed qualitative similarities with respect to their relative interactions with the test compounds used in the study of rat transporters by Arndt et al. (1), substantial quantitative, and sometimes, qualitative differences were noted. For example, whereas rOCT2 showed a 65-fold higher apparent affinity for mepiperphenidol than rOCT1 (1), rbOCT1 displayed a 5-fold higher affinity for mepiperphenidol than did rbOCT2 (IC50 values of 1.2 and 6.3 µM, respectively). Particularly striking was the very low mepiperphenidol IC50 for rbOCT1 (1.2 µM) (Table 1) compared with that measured for rOCT1 (474 µM) (1). rbOCT1 did show a 2-fold preference
for procainamide over rbOCT2 (i.e., IC50 values of 10.8 vs. 23.0 µM) (Table 1), but this contrasted sharply with the 20-fold difference observed in the rat (1). Guanidine, on the other hand, displayed a rather similar profile of IC50 values for the OCT1 and OCT2 homologs in the rabbit (Table 1) and rat (1). These observations underscored the inappropriateness of assuming that substrate/inhibitor interactions measured in one species will apply in another.
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In addition to guanidine, we found several compounds for which rbOCT2 had a much higher apparent affinity than rbOCT1. Figure 3 compares the inhibitor profiles for two of these, i.e., CIM and NBD-TMA. In three separate experiments, the IC50 values for CIM inhibition of TEA transport by rbOCT1 and rbOCT2 were 97.3 ± 3.3 and 1.3 ± 0.2 µM. In other words, when expressed in CHO-K1 cells the apparent affinity of rbOCT2 for CIM was 75 times higher than that of rbOCT1. This result is qualitatively similar to that we reported previously in a study that compared CIM interaction with rbOCT1 and rbOCT2 expressed in COS-7 cells (38). In that study the IC50 values for CIM inhibition of TEA transport by OCT1 and OCT2 were 916 and 5.7 µM, respectively, representing a 160-fold difference in apparent affinity of the two homologues for CIM. The second compound that displayed a marked preference for OCT2 was the fluorescent cation NBD-TMA (Fig. 3B). In three separate experiments, the IC50s for NBD-TMA's inhibition of TEA transport by rbOCT1 and rbOCT2 were 108.4 ± 7.2 and 1.4 ± 0.2 µM, respectively; i.e., the apparent affinity of rbOCT2 for NBD-TMA was
75 times higher than that of rbOCT1 (Table 1).
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rbOCT1 displayed a markedly higher apparent affinity for several test agents than did rbOCT2 (Table 1). Figure 4 compares the inhibitor profiles for two of these, pindolol and tyramine. In three separate experiments, the IC50 values for pindolol's inhibition of TEA transport by rbOCT1 and rbOCT2 were 2.4 ± 0.1 and 50.0 ± 10.5 µM, respectively. For tyramine, the IC50 values for rbOCT1 and rbOCT2 were 21.2 ± 2.3 and 360.9 ± 21.9 µM, respectively. Thus for these two substrates, the apparent affinity of rbOCT1 was 1720-times higher than that of rbOCT2 (Table 1). Figure 5 compares the ratios of rbOCT1 and rbOCT2 IC50 values for six of the test compounds. Although the transporters do show preferential interaction with selected compounds, they interact with other molecules, e.g., TEA and ephedrine, with virtually identical kinetics (Fig. 5 and Table 1). The existence of such
nondiscriminating
substrates is of particular value with respect to identifying fractional contribution of different transport proteins to total substrate uptake by intact tubules, as discussed below.
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As noted earlier, we routinely compared the characteristics of OCT1 and OCT2 observed in CHO-K1 cells with those observed in COS-7 cells. Table 1 lists the IC50 values for the test agents examined in this study, as inhibitors of TEA transport by rbOCT1 and rbOCT2 when expressed (stably) in CHO-K1 cells or (transiently) in COS-7 cells. Importantly, the profile of inhibition observed in CHO-K1 was also observed, at least qualitatively, in COS-7 cells. In other words, compounds that were potent inhibitors of the transporters in CHO-K1 cells were also comparatively potent inhibitors of these processes when expressed in COS-7 cells. This is graphically emphasized in Fig. 6, which plots for each transporter the measured IC50 or Kt values for six different compounds as determined in the present study for both CHO-K1 and COS-7. Both transporters consistently displayed higher apparent affinities for substrates or inhibitors in CHO-K1 cells. The lower affinity of the transporters in COS-7 cells was quite consistent, with IC50 values being 2.6 ± 0.25 times higher in COS-7 cells than in CHO-K1 cells over the full range of affinities observed (Fig. 6).
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Effect of OCT-homologue-specific inhibitors on TEA transport in single rabbit S2 proximal tubule segments. There are clear species differences in the distribution and expression level of different OCTs in the RPT. Whereas OCT expression in the human RPT appears to be dominated by OCT2 (21), OCT1 and OCT2 are both expressed in rat RPT (16). Indeed, OCT1 and OCT2 appear to be coexpressed in the S2 segment of the rat RPT, with the S1 segment being dominated by OCT1 expression and the S3 segment being dominated by OCT2 expression. The fact that we cloned both OCT1 and OCT2 from mRNA isolated from rabbit renal cortex suggests that both homologues are expressed in the rabbit RPT. However, the relative expression level and functional distribution of these processes in the rabbit are not clear.
In developing a map of functional OCT expression in rabbit RPT, we elected to first focus on the S2 segment. In addition to being less technically challenging (than working with isolated S1 and S3 segments), the S2 segment, based on the results obtained with rat kidney noted above (16), was considered the most likely site for coexpression of OCT1 and OCT2. Therefore, to establish the relative contribution of OCT1 and OCT2 to basolateral OC transport in S2 segments of rabbit RPT, we determined the effect of several discriminating inhibitors of OCT transport on TEA uptake into isolated single S2 proximal tubule segments (Table 2). Recall that, as a nondiscriminating substrate, TEA displayed comparatively equal affinity for rbOCT1 and rbOCT2 (Fig. 5). Figure 7 shows the inhibition profiles produced by NBD-TMA (selective inhibitor of rbOCT2) and by pindolol and tyramine (selective inhibitors of rbOCT1). Figure 8 compares the intact tubule IC50 values for these discriminating inhibitors (Table 2) with those obtained for the cloned transporters in heterologous expression systems (Table. 1).
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As noted earlier, there is no a priori basis for assuming that the kinetic characteristics observed in CHO-K1 cells will be more representative of those expressed in native proximal tubules than the kinetic characteristics observed in COS-7 cells (or any other heterologous expression system). The Kt for basolateral TEA uptake measured in isolated single rabbit RPT is on the order of 110 µM (12). Although this value is closer to those measured here in COS-7 cells (121 and 75.6 µM for rbOCT1 and rbOCT2, respectively) than in CHO-K1 cells (19.9 and 34.5 µM, respectively), we considered it prudent to compare the IC50 values measured in intact tubules to those measured in both heterologous expression systems.
Figure 8 includes a graphical representation of the range of IC50 values for both homologues determined in CHO-K1 and COS-7 cells. The light gray-shaded bars indicate the range of OCT2 IC50 values obtained for the two cell types, and the dark gray bars indicate the range of OCT1 IC50 values. The open circles represent the mean ± SD IC50 for inhibition of basolateral TEA uptake in S2 segments of rabbit RPTs by each discriminating inhibitor, including data obtained in a previous study that compared the IC50 value for CIM inhibition of TEA transport in intact S2 segments of rabbit RPTs with that measured for rbOCT1- or rbOCT2-mediated transport of TEA into transiently transfected COS-7 cells (38). The comparatively low median IC50 value for CIM inhibition of tubular transport of 12 µM measured in that study was sufficiently similar to that measured for OCT2-mediated transport (6 µM), and sufficiently different from that measured for OCT1-mediated transport (700900 µM), to support the conclusion that basolateral TEA transport in the S2 segment of rabbit proximal tubules is probably dominated by OCT2 activity (38). Here we extend those observations to include the inhibitory profiles of another OCT2-selective inhibitor (NBD-TMA) and, importantly, two OCT1-selective inhibitors (tyramine and pindolol). If our previous conclusion was correct, low concentrations of NBD-TMA should block tubular TEA transport, whereas comparatively high concentrations of tyramine and pindolol will be required to block TEA uptake. In fact, as shown in Figure 8, both CIM and NBD-TMA blocked tubular TEA uptake to a degree consistent with uptake activity being dominated by OCT2. The inhibitor profiles produced by tyramine and pindolol, each comparatively poor inhibitors of tubular TEA transport, were also consistent with basolateral OC transport's being dominated by OCT2, rather than OCT1.
TEA is not a discriminating substrate, i.e., it is handled with comparatively equal facility by rbOCT1 and rbOCT2 (Fig. 2). Consequently, it was of interest to determine whether expression of OCT1, albeit at low levels, in the S2 segment could be rendered evident by examining transport of the OCT1 distinguishing substrate, tyramine. We first confirmed that, as suggested by tyramine's inhibition of TEA transport, OCT1 displays a substantially higher apparent affinity for tyramine than OCT2: Kt of 23.1 ± 10.5 (n = 4) and 590 ± 175 µM (n = 3), respectively (Jmax of 12.1 ± 4.8 and 92 ± 36.4 pmol · cm2 · min1). If OCT1 is expressed at very low levels in the S2 segment, then it is likely that half-saturation of basolateral tyramine uptake would reflect the influence of a low-affinity interaction with OCT2, rather than a high-affinity interaction with OCT1. In fact, the half-saturation constant for basolateral tyramine uptake was 122 ± 49.6 µM (n = 3) (Fig. 9A), intermediate in value to the apparent Kt for uptake mediated by rabbit OCT1 and OCT2 (in CHO cells). Although this intermediate value could reflect the influence of expression in the native tubule, compared with CHO cells, it could also be explained by the influence of coexpression of OCT1 and OCT2 in the S2 segment, with the former at much lower levels than the latter. Thus OCT2 activity would dominate uptake of a nondistinguishing substrate, such as TEA, whereas OCT1 activity would become evident during uptake of an OCT1-selective substrate, such as tyramine. Although, in principle, computational methods can be used to establish the parallel activity of high- and low-affinity pathways, it was impractical to devise experiments with single tubules that cover with high precision a sufficiently broad range of substrate concentrations. Nevertheless, the profile of CIM's inhibition of tyramine transport did provide a profile that was qualitatively consistent with the presence of a modest level of expression of OCT1 in parallel with a comparatively large expression of OCT2. Figure 9B shows the profile of CIM's inhibition of tyramine uptake into single S2 segments. The solid line was derived using the mean IC50 as determined assuming that mediated (i.e., saturable) tyramine uptake involved a single process. Recalling that CIM blocks OCT2 with an IC50 of 110 µM, the high IC50 value for inhibition of tyramine uptake is strong evidence that OCT1 is expressed in the S2 segment. However, what of the influence of OCT2 to tyramine transport? Its low affinity for tyramine suggests it would play a modest role in tracer tyramine transport, but the fraction of total tyramine transport that is mediated by OCT2, albeit modest, should be blocked efficiently by CIM. Inspection of the CIM inhibition profile reveals that the one-pathway
model provided a comparatively poor fit to the data at both high and low concentrations of CIM (see Fig. 9B, inset). The dashed line in the inset was calculated using a model that included two mediated avenues for tyramine transport, one of high affinity (apparent IC50 of
10 µM) for CIM and responsible for
25% of tracer tyramine uptake; and one of low affinity (IC50 of
1 mM) responsible for the other 75% of mediated tracer tyramine uptake. We suggest that the first of these represents the activity of OCT2, whereas the second represents the activity of OCT1.
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The profile of transport function in the S2 segment of rabbit RPT is consistent with quantitatively significant roles for both OCT1 and OCT2. The comparatively high level of OCT2 expression makes it likely to dominate tubular uptake of substrates that can share either process (as well as those that show a marked selectivity for OCT2, of course). However, OCT1 appears to be expressed at sufficient levels to make it the predominant pathway for entry of substrates that are transported by both processes but show a marked degree of selectivity for OCT1.
Distribution of OCT1 and OCT2 mRNA in S2 segments of rabbit RPT. In a previous study we compared levels of expression of mRNA for OCT1 and OCT2 in single S2 segments of RPT using the method of RT-PCR (38). In that study, whereas an OCT2-specific product was amplified in all the individual segments tested, we failed to amplify an OCT1-specific product. In the light of the present observations that argue for the expression, albeit at functionally low levels, of OCT1 as well as OCT2 in the rabbit S2 segment, we reexamined the expression of transporter mRNA in isolated tubule segments. Whereas OCT2 mRNA was noted in eight of the nine rabbits tested for OCT2, OCT1 mRNA was found in only two of the eight rabbits tested for OCT1 (the identity of the amplified product was confirmed by sequence analysis). These data are consistent with the contention that OCT2 is expressed at consistently higher levels in the S2 segment of rabbit RPT than is OCT1.
The typically low expression level of OCT1 in the S2 segment of the rabbit RPT should not be interpreted as evidence for similarly low levels of expression in other segments of the RPT or, possibly, other regions of the nephron. There is also evidence of mediated TEA transport in isolated rat distal, as well as proximal, renal tubules (9), and the expression of OCT2 in rabbit distal tubules cannot be excluded. Gourbelov et al. (10) suggested that the low level of OCT1 expression in the human kidney, compared with OCT2 expression, was consistent with a general housekeeping role for this process.
The present data do not allow a conclusion to be drawn about the possible contribution of OCT3 to TEA uptake in the S2 segment. OCT3 is expressed in both human and rat kidney (21, 30), and it does accept TEA as a substrate (17, 35). However, OCT3 mRNA is expressed at much lower levels than OCT2 mRNA in both the human (21) and the rat (30). In addition, the affinity of rat and mouse OCT3 for TEA is much lower than that of either OCT1 or OCT2 (17, 35). Consequently, we consider it unlikely that OCT3 plays a major role in mediating transport of TEA (or other OCs) in the rabbit RPT.
In conclusion, the present study used the profile of transport inhibition in isolated rabbit RPT to show that basolateral TEA uptake in isolated single S2 segments is dominated by the activity of OCT2 and that functional expression of OCT1 is typically very low. Nevertheless, sufficient levels of OCT1 activity were noted to make it likely that it can play a major role in tubular transport of those substrates that show a marked selectivity for OCT1 over OCT2. Differential expression of these two transporters (or expression of their polymorphic variants) (18, 29) could result in marked changes in patterns of tubular secretion of cationic substrates. This study was also used to establish a functional mapping strategy that can be used to examine the physiological distribution of homologous transport proteins within defined segments of the RPT. The method depends on the identification of discriminating substrates/inhibitors that clearly distinguish between the activities of the different homologous processes under study. In addition, the demonstration of systematic differences in the kinetic profile of cloned transport proteins when expressed in different heterologous systems serves as a cautionary warning. The present results argue that functional mapping of transport activity in renal tubules is most prudently based on comparisons of activity of cloned transporters that are expressed in several different expression systems with the activity of those processes expressed in the native tissue of the same species. To that end, the rabbit offers an excellent experimental system for such studies because the availability of cloned transport proteins is readily matched with the comparative ease of study of single defined RPT segments.
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DISCLOSURES |
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FOOTNOTES |
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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.
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REFERENCES |
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