Organic cation uptake by a cultured renal epithelium

Uptake properties of lamivudine (3TC) by a continuous renal epithelial cell line

The purpose of this study was to characterize the renal uptake properties of the cytidine analog and antiretroviral agent 3TC. The uptake of radiolabelled 3TC was measured at 37°C in a continuous porcine renal epithelial cell line (i.e., LLC-PK1 cells) grown as a monolayer on an impermeable support. 3TC (5 µM) uptake (37°C) by the monolayer cells was saturable (Km = 1.2 ± 0.2 mM) but not significantly altered by various dideoxynucleoside analog drugs, nucleosides, and nucleoside transport inhibitors, suggesting that a nucleoside transporter is not involved in 3TC uptake. A number of endogenous organic cation probes and inhibitors significantly reduced 3TC uptake by the monolayer cells. Quinine, trimethoprim (TMP), and tetraethylammonium (TEA) inhibited 3TC uptake in a dose dependent manner with IC50 values of 0.6mM, 0.63mM, and 1.9 mM, respectively. In turn, the uptake of the typical organic cation substrate TEA was inhibited by high concentrations of 3TC. An outwardly directed proton gradient significantly increased the uptake of 3TC by the monolayer cells, suggesting the involvement of a proton exchange process. Conversely, in the presence of monensin, a Na+/H+ ionophore, the uptake of 3TC was significantly reduced. These results suggest that the uptake of 3TC by a cultured renal epithelium may be mediated by an organic cation-proton exchanger. The observed clinical interaction between 3TC and trimethoprim may be explained by competition for a common renal organic cation tubular transporter.Key words: 3TC, kidney, uptake, LLC-PK1, tubular elimination.

Functional characterization of ORCTL2--an organic cation transporter expressed in the renal proximal tubules

Chromosome 11p15.5 harbors a gene or genes involved in Beckwith-Wiedemann syndrome that confer(s) susceptibility to Wilms' tumor, rhabdomyosarcoma, and hepatoblastoma. We have previously identified a transcript at 11p15.5 which encodes a putative membrane transport protein, designated organic cation transporter-like 2 (ORCTL2), that shares homology with tetracycline resistance proteins and bacterial multidrug resistance proteins. In this report, we have investigated the transport properties of ORCTL2 and show that this protein can confer resistance to chloroquine and quinidine when overexpressed in bacteria. Immunohistochemistry analyses performed with anti-ORCTL2 polyclonal antibodies on human renal sections indicate that ORCTL2 is localized on the apical membrane surface of the proximal tubules. These results suggest that ORCTL2 may play a role in the transport of chloroquine and quinidine related compounds in the kidney.

Transport of paraquat by a renal epithelial cell line, MDCK

Transport of paraquat (PQ), a herbicidal cation, was previously investigated in a proximal (LLC-PK1), renal epithelial cell line using permeable collagen-coated filters. PQ was actively transported from the basolateral side via a cation transport system by the LLC-PK1 cells. In the present study, the transport of PQ was investigated in a distal renal epithelial cell line, MDCK. PQ was predominantly transported from the basolateral to apical (B to A) side. The basolateral transport of PQ in MDCK cells was not saturable with increasing concentrations and not energy dependent. The flux and uptake of PQ was much lower in the MDCK than LLC-PK1 cells. It is concluded that MDCK, a distal renal tubular cell line, does not have an active transport system for PQ.

Kinetic analysis of tetraethylammonium transport in the kidney epithelial cell line, LLC-PK1

PURPOSE

The aims of this study were to establish a kinetic means of analyzing the membrane transport of organic cations in renal epithelial cells, and to simultaneously evaluate drug interactions in apical and basolateral membranes.

METHODS

Tetraethylammonium (TEA) transport was measured using LLC-PK1 cell monolayers grown on microporous membrane filters. After incubating the cells with unlabeled TEA or other drugs, apical or basolateral medium was changed to that containing labeled TEA, and transcellular transport and cellular accumulation were measured. Clearance from apical medium to cells (CL12), cells to apical medium (CL21), cells to basolateral medium (CL23) and basolateral medium to cells (CL32) were calculated based on a three compartment model.

RESULTS

TEA was accumulated progressively in the monolayers from the basolateral side and was transported unidirectionally to the apical side. CL32 was greater than CL12 and CL23 was greater than CL21. Therefore, the rate limiting step of TEA transport from the basolateral to the apical medium was the cell-to-apical step. Co-incubation of TEA with procainamide decreased the transport parameters of TEA, CL12, CL21 and CL32, whereas that with levofloxacin decreased only CL12 and CL21, not affecting the parameters in basolateral membranes.

CONCLUSIONS

Using a simple model, we analyzed the transport of organic cation in kidney epithelial cell line, LLC-PK1. This method can be useful for the analysis of cation transport and drug interactions in the apical and basolateral membranes of renal tubules.

Primary structure and functional expression of the apical organic cation transporter from kidney epithelial LLC-PK1 cells

Renal secretion of organic cations involves at least two distinct transporters, located in the basolateral and apical membranes of proximal tubule cells. Whereas the basolateral transporter has recently been cloned, sequence information about the apical type was not yet available. An organic cation transporter, OCT2p, was cloned from LLC-PK1 cells, a porcine cell line with properties of proximal tubular epithelial cells. OCT2p was heterologously expressed and characterized in human embryonic kidney 293 cells. OCT2p-mediated uptake of the prototypical organic cation [14C]tetraethylammonium ([14C]TEA) into 293 cells was saturable. There was a highly significant correlation between the Ki values for the inhibition of apical [14C]TEA uptake into LLC-PK1 cells and 293 cells transfected with OCT2p (r = 0.995; p < 0.001; n = 6). Although OCT2p is structurally related to OCT1r, the basolateral organic cation transporter from rat kidney, the transporters could be clearly discriminated pharmacologically with corticosterone, decynium22, and O-methylisoprenaline. The findings at hand suggest that OCT2 corresponds to the apical type of organic cation transporter. Reverse transcriptase-polymerase chain reaction indicates that mRNA of OCT1r is limited to non-neuronal tissue, whereas OCT2r, the OCT2p homologue from rat, was found in both the kidney and central nervous regions known to be rich in the monoamine transmitter dopamine.

Mediation of cimetidine secretion by P-glycoprotein and a novel H(+)-coupled mechanism in cultured renal epithelial monolayers of LLC-PK1 cells

1. Previous studies have shown that the weak base, cimetidine, is actively secreted by the renal proximal tubule. In this study we have examined the transport of cimetidine by renal LLC-PK1 epithelial cell monolayers. 2. In LLC-PK1 cell monolayers the basal-to-apical flux of cimetidine was significantly greater than the apical-to basal flux, consistent with net secretion of cimetidine in a basal-to-apical direction. 3. Net secretion of cimetidine was significantly (70%) reduced by the addition of either 100 microM verapamil or 100 microM nifedipine to the apical membrane. The reduction in net secretion was the result of an inhibition of basal-to-apical flux; these agents had no effect upon flux in the apical-to-basal direction. These results suggest that cimetidine secretion is mediated primarily by P-glycoprotein located in the apical membrane. In addition we found no evidence of a role for organic cation antiport in the secretion of cimetidine. 4. In the presence of an inwardly directed proton gradient across the apical membrane (pH 6.0), cimetidine secretion was significantly reduced compared to that measured at an apical pH of 7.4. The reduction in net secretion at pH 6.0 was the result of a stimulation of cimetidine uptake across the apical membrane. This pH-dependent uptake mechanism was sensitive to inhibition by DIDS (100 microM). 5. Experiments with BCECF (2',7'-bis(2-carboxyethyl)-5(6)-carboxyfluorescein) loaded monolayers demonstrated that cimetidine influx across the apical membrane was associated with proton flow into the cell and was sensitive to inhibition by DIDS. 6. These results suggest that net secretion of cimetidine across the apical membrane is a function of the relative magnitudes of cimetidine secretion mediated by P-glycoprotein and cimetidine absorption mediated by a novel proton-coupled, DIDS-sensitive transport mechanism.

pH-dependent transport of procainamide in cultured renal epithelial monolayers of OK cells: consistent with nonionic diffusion

1. Previous studies suggest that procainamide is a substrate for organic cation/proton antiport. In order to study the coupling between procainamide flux and proton flux in greater detail we investigated the effects of extracellular procainamide addition upon intracellular pH in cultured monolayers of renal OK cells. Intracellular pH was monitored by use of BCECF as a probe. 2. Apical addition of procainamide (10 mM) caused a significant alkalinisation of intracellular pH. Basolateral addition of procainamide was equally effective in raising intracellular pH. A similar alkalinisation was found in two other renal cell lines: MDCK strain 1 and LLCPK1. 3. In contrast, both tetraethylammonium and N-methylnicotinamide, archetypal substrates for organic cation/proton antiport were without effect upon intracellular pH. 4. At physiological pH values, procainamide exists as a neutral weak base (B) and its conjugate weak acid (BH+). To test which species of procainamide was responsible for the alkalinisation, experiments in which [B] was kept constant whilst [BH+] was varied from 1.15 mM to 7.25 mM were performed. The results suggested that the neutral weak base (B) was the permeant species. 5. Procainamide efflux from procainamide-loaded cell monolayers resulted in a significant acidification of intracellular pH. As with procainamide uptake, this result could be ascribed to the movement of neutral weak base. 6. These effects of procainamide upon intracellular pH are consistent with nonionic diffusion of procainamide rather than an interaction of procainamide with the organic cation/proton antiporter. In addition, the results suggest that organic cation/proton antiport is not highly expressed in OK cells.

Dopamine receptor agonists and antagonists both inhibit dopamine secretion in LLC-PK1 cells

A series of dopamine receptor agonists and antagonists were tested in a renal epithelial cell line (LLC-PK1) for their ability to alter renal dopamine synthesis and secretion. LLC-PK1 cells were incubated with L-3,4-dihydroxyphenylalanine (L-dopa) (250 microM) in the presence and absence of dopaminergic drugs known to be selective for dopamine receptor subtypes and total dopamine synthesis and dopamine secretion into the media were measured directly by high performance liquid chromatography (HPLC). Both dopamine receptor agonists and antagonist significantly inhibited dopamine secretion from LLC-PK1 cells at concentrations between 10-100 microM. The phenothiazines, chlorpromazine and trifluoperazine, also significantly inhibited aromatic amino acid decarboxylase activity at 100 microM. The mechanism of action for these dopaminergic drugs appeared to involve the inhibition of dopamine secretion from LLC-PK1 cells by direct competition for outward transport by an organic cation transporter. Inhibition of dopamine secretion by these drugs was usually accompanied by significant elevations of the intracellular stores of dopamine. The results of this study suggest that caution should be exhibited in the interpretation of experiments that employ high concentrations of dopamine drugs, in order to account for the potential interaction of these agents with the renal cation transport system.

1,1'-diethyl-2,2'-cyanine (decynium22) potently inhibits the renal transport of organic cations

The excretion of cationic compounds by renal proximal tubule cells involves at least two distinct transporters: the basolateral type which transports organic cations from the plasma into the proximal tubule cell, and the apical type which secretes the organic cations into the lumen of the tubule. However, potent inhibitors were known for neither type of transporter. Here we introduce a compound, decynium22, that potently, competitively, and selectively inhibits the apical type of the renal organic cation transporter. The transport of the prototypical organic cation 14C-tetraethylammonium through the apical plasma membrane of clonal proximal tubule cells (LLC-PK1) was used as experimental system. Initial rates of 14C-tetraethylammonium transport into LLC-PK1 cells were saturable, the Km and Vmax being 27 mumol/l and 200 pmol/(mg protein.min), respectively. Decynium22 competitively and potently inhibited 14C-tetraethylammonium transport (Ki = 5.6 nmol/l). Moreover, the effect of decynium22 on basolateral to apical directed transepithelial transport of 14C-tetraethylammonium through a confluent monolayer of LLC-PK1 cells was determined. Decynium22 (30 nmol/l) applied to the apical medium, reduced transepithelial transport by 76% and increased intracellular accumulation of 14C-tetraethylammonium 1.5-fold. In contrast, application of 30 nmol/l decynium22 to the basolateral medium failed to affect transepithelial transport and intracellular accumulation of 14C-tetraethylammonium. Decynium22 is the most potent inhibitor of the renal transport of organic cations known so far. With decynium22 it is now possible to distinguish precisely between a decynium22-sensitive apical type and a decynium22-resistant basolateral type of renal organic cation transporter in renal proximal tubule cells.

Transport of procainamide in a kidney epithelial cell line LLC-PK1

Transport of procainamide, an anti-arrhythmic drug, was investigated in LLC-PK1 kidney epithelial cell line. The uptake of procainamide by LLC-PK1 monolayers cultured in plastic dishes was temperature-dependent, saturable and inhibited by organic cations such as cimetidine and N-acetylprocainamide. An aminocephalosporin antibiotic, cephalexin, also inhibited procainamide uptake, but an organic anion, p-aminohippurate, did not. The uptake of procainamide was greater at an alkaline external pH than at an acidic pH. In addition, procainamide uptake increased when intracellular pH was decreased and the uptake decreased when the intracellular pH was increased by ammonium chloride treatment, indicating the involvement of an H+/procainamide antiport system in apical membrane. The basolateral to apical flux of procainamide across LLC-PK1 monolayers cultured on permeable supports was 2.5-times larger than the apical to basolateral flux, and only the former process was inhibited by other organic cations. These findings suggest that LLC-PK1 cells can transport procainamide by the organic cation transport system and that procainamide is transported unidirectionally from basolateral to apical side across the cell monolayers.

Renal tubular epithelial cells express osteonectin in vivo and in vitro

Osteonectin (SPARC, culture shock protein, BM-40) is a widely distributed glycoprotein which binds calcium and several extracellular matrix proteins, including interstitial collagens and thrombospondin, but whose physiologic role remains undefined. In the present studies, we have demonstrated that immunoreactive osteonectin is present in the distal cortical tubule and medullary tubules of murine kidney. We surveyed the renal epithelial cell lines LLC-PK1, MDCK, and OK for the expression of mRNA encoding osteonectin. We found that osteonectin mRNA is expressed by LLC-PK1 and OK cells but not by MDCK cells, as well as by adult kidney from several species. Calcitonin and vasopressin, agents which increase cAMP in these cells, were found to decrease steady-state osteonectin mRNA concentrations. We found that LLC-PK1 cells produced osteonectin protein, that the protein was localized to intracellular granules, and that the protein bound hydroxyapatite in vitro. Pulse-chase analysis revealed that osteonectin was secreted from the cell layer to the medium after a lag time of four to six hours and was secreted preferentially from the basolateral domain of the cell. The preferential secretion of the calcium-binding protein osteonectin from the renal epithelial cell is consistent with several possible functions, including a structural extracellular matrix protein, a participant in transepithelial ion transport, and an inhibitor of extracellular calcification.

Transcellular transport of organic cation across monolayers of kidney epithelial cell line LLC-PK

Transcellular transport and the accumulation of [14C]tetraethylammonium, a typical organic cation, by LLC-PK1 cell monolayers grown on microporous membrane filters were studied. Tetraethylammonium was accumulated progressively in the monolayers from the basolateral side and was transported unidirectionally to the apical side. The transcellular transport of tetraethylammonium was saturable, temperature dependent, and sensitive to the pH of the apical side of the monolayers. The apparent Michaelis constant and maximum velocity values for the transport were 67 microM and 222 pmol.mg protein-1.min-1, respectively. Unlabeled tetraethylammonium, amiloride, procainamide, cimetidine, and choline inhibited the basolateral uptake and transcellular transport of [14C]tetraethylammonium. The development of tetraethylammonium transport activity was observed in the differentiating cells. A sulfhydryl reagent inhibited the tetraethylammonium transport at both the basolateral and apical membranes of the LLC-PK1 cells. These findings suggest that these monolayers possess unidirectional transport systems for organic cations, corresponding to the secretion in the renal proximal tubules.

Renal proximal tubular cells in suspension or in primary culture as in vitro models to study nephrotoxicity

The kidney forms a frequent target for xenobiotic toxicity. The complex biochemical mechanisms underlying nephrotoxicity are best studied in vitro provided that reliable and relevant in vitro models are available. Since most nephrotoxicants affect primarily the cells of the proximal tubules (PTC), much effort has been directed towards the development of in vitro models of PTC. This review focuses on the preparation of PTC and the use of these cells. Discussed are important criteria such as the viability (survival time) of the cells and the parameters to assess toxicity. Recent studies have shown that isolated PTC in suspension are especially suitable for studies on the biochemical mechanisms of 'acute' nephrotoxicity, whereas PTC in primary culture may be used to investigate mechanisms of nephrotoxic damage at very low concentrations, upon prolonged exposure. PTC cultured on porous filter membranes provide new possibilities to study toxicity in relation to cell and transport polarity. Primary cell cultures of human PTC have been set up. Although a further characterization of these systems is needed, recent data indicate their usefulness.