Role of aromatic transmembrane residues of the organic anion transporter,rOAT3, in substrate recognition

Organic anion transporters (OATs, SLC21) are important in the excretion of endogenous and exogenous compounds in the kidney. The rat organic anion transporter, rOAT3, mediates the transport of organic anions such as p-aminohippurate (PAH) and estrone sulfate as well as the basic compound, cimetidine. In the present study, we examined the role of conserved transmembrane aromatic amino acid residues of rOAT3 in substrate recognition and transport. Alanine scanning followed by amino acid replacements was used to construct mutants of rOAT3. The uptake of model compounds was studied in Xenopus laevis oocytes expressing the mutant transporters. We observed that four mutants in transmembrane domain 7 (TMD 7), W334A, F335A, Y341A, and Y342Q, and one mutant in transmembrane domain 8 (TMD 8), F362S, exhibited a less than 2-fold enhanced uptake of PAH and cimetidine in comparison to wild-type rOAT3, which exhibited a 16-fold enhanced uptake of PAH and an 8-fold enhanced uptake of cimetidine. Estrone sulfate uptake in oocytes expressing any one of these five mutants remained at least 8-fold enhanced. The data suggest that the five residues, W334, F335, Y341, Y342, and F362, contribute differently to the transport of the small hydrophilic organic substrates PAH and cimetidine in comparison to the large hydrophobic organic substrate estrone sulfate. The effects of side chains of these five residues on transporter functions were also evaluated by constructing conservative mutations. We observed that the residues contribute to PAH and cimetidine transport in different ways: the -OH group of Y342, the indole ring of W334, and the aromatic rings of F335, Y341, and F362 are important for PAH and cimetidine transport by rOAT3. These data suggest that there is an aromatic pocket composed mainly of residues in TMD 7 in the translocation pathway of rOAT3, which is important for the transport of PAH and cimetidine. Aromatic residues in this pocket may interact directly with substrates of rOAT3 through hydrogen bonds and pi-pi interactions.     

Oxalate transport via the sulfate/HCO3 exchanger in rabbit renal basolateral membrane vesicles

We evaluated the mechanism of oxalate transport in basolateral membrane vesicles isolated from the rabbit renal cortex. An outward HCO3- gradient induced the transient uphill accumulation of oxalate and sulfate, indicating the presence of oxalate/HCO3- exchange and sulfate/HCO3- exchange. For oxalate, sulfate, or 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid, the K1/2 value for oxalate/HCO3- exchange was nearly identical to that for sulfate/HCO3- exchange, suggesting that both exchange processes occur via the same transport system. This was further supported by the finding of sulfate/oxalate exchange. Thiosulfate/sulfate exchange and thiosulfate/oxalate exchange were also demonstrated, but a variety of other tested anions including Cl-, p-aminohippurate, and lactate did not exchange for sulfate or oxalate. Na+ did not affect sulfate or oxalate transport, indicating that neither anion undergoes Na+ co-transport or Na+-dependent anion exchange in these membrane vesicles. Finally, we found that the stoichiometry of exchange is 1 sulfate or oxalate per 2 HCO3-, or a thermodynamically equivalent process. We conclude that oxalate, but not other organic or inorganic anions of physiologic importance, can share the sulfate/HCO3- exchanger in renal basolateral membrane vesicles. In series with luminal membrane oxalate/Cl- (formate) exchange, exchange of oxalate for HCO3- or sulfate across the basolateral membrane provides a possible transcellular route for oxalate transport in the proximal tubule.     

Arginine 454 and lysine 370 are essential for the anion specificity of the organic anion transporter, rOAT3

Organic anion transporters (OATs) and organic cation transporters (OCTs) mediate the flux of xenobiotics across the plasma membranes of epithelia. Substrates of OATs generally carry negative charge(s) whereas substrates of OCTs are cations. The goal of this study was to determine the domains and amino acid residues essential for recognition and transport of organic anions by the rat organic anion transporter, rOAT3. An rOAT3/rOCT1 chimera containing transmembrane domains 1-5 of rOAT3 and 6-12 of rOCT1 retained the specificity of rOCT1, suggesting that residues involved in substrate recognition reside within the carboxyl-terminal half of these transporters. Mutagenesis of a conserved basic amino acid residue, arginine 454 to aspartic acid (R454D), revealed that this amino acid is required for organic anion transport. The uptakes of p-aminohippurate (PAH), estrone sulfate, and ochratoxin A were approximately 10-, approximately 48-, and approximately 32-fold enhanced in oocytes expressing rOAT3 and were only approximately 2-, approximately 6-, and approximately 5-fold enhanced for R454D. Similarly, mutagenesis of the conserved lysine 370 to alanine (K370A) suggested that K370 is important for organic anion transport. Interestingly, the charge specificity of the double mutant, R454DK370A, was reversed in comparison to rOAT3-R454DK370A preferentially transported the organic cation, MPP(+), in comparison to PAH (MPP(+) uptake/PAH uptake = 3.21 for the double mutant vs 0.037 for rOAT3). These data indicate that arginine 454 and lysine 370 are essential for the anion specificity of rOAT3. The studies provide the first insights into the molecular determinants that are critical for recognition and translocation of organic anions by a member of the organic anion transporter family.     

Identification of a novel voltage-driven organic anion transporter present at apical membrane of renal proximal tubule

A novel transport protein with the properties of voltage-driven organic anion transport was isolated from pig kidney cortex by expression cloning in Xenopus laevis oocytes. A cDNA library was constructed from size-fractionated poly(A)+ RNA and screened for p-aminohippurate (PAH) transport in high potassium medium. A 1856-base pair cDNA encoding a 467-amino acid peptide designated as OATV1 (voltage-driven organic anion transporter 1) was isolated. The predicted amino acid sequence of OATV1 exhibited 60-65% identity to those of human, rat, rabbit, and mouse sodium-dependent phosphate cotransporter type 1 (NPT1), although OATV1 did not transport phosphate. The homology of this transporter to known members of the organic anion transporter family (OAT family) was about 25-30%. OATV1-mediated PAH transport was affected by the changes in membrane potential. The transport was Na+-independent and enhanced at high concentrations of extracellular potassium and low concentrations of extracellular chloride. Under the voltage clamp condition, extracellularly applied PAH induced outward currents in oocytes expressing OATV1. The current showed steep voltage dependence, consistent with the voltage-driven transport of PAH by OATV1. The PAH transport was inhibited by various organic anions but not by organic cations, indicating the multispecific nature of OATV1 for anionic compounds. This transport protein is localized at the apical membrane of renal proximal tubule, consistent with the proposed localization of a voltage-driven organic anion transporter. Therefore, it is proposed that OATV1 plays an important role to excrete drugs, xenobiotics, and their metabolites driven by membrane voltage through the apical membrane of the tubular epithelial cells into the urine.     

Specificity of anion exchange mediated by mouse Slc26a6

Recently, CFEX, the mouse orthologue of human SLC26A6, was localized to the brush border membrane of proximal tubule cells and was demonstrated to mediate Cl(-)-formate exchange when expressed in Xenopus oocytes. The purpose of the present study was to examine whether mouse Slc26a6 can mediate one or more of the additional anion exchange processes observed to take place across the apical membrane of proximal tubule cells. Influx of [(14)C]formate into Slc26a6-expressing oocytes was inhibited by sulfate, oxalate, and p-aminohippurate (PAH), indicating affinity for these anions. Measurements of uptake of [(14)C]oxalate, [(14)C]PAH, and [(35)S]sulfate indicated that Slc26a6 can mediate transport of oxalate and sulfate but not PAH. Studies of the effect of external anions on [(14)C]oxalate efflux demonstrated Slc26a6-mediated Cl(-)-oxalate, oxalate-formate, oxalate-oxalate, and oxalate-sulfate exchange. Two-electrode voltage clamp measurements indicated that Slc26a6-mediated Cl(-)-oxalate exchange is electrogenic. Intracellular pH recordings demonstrated that Slc26a6 can mediate Cl(-)-HCO(3)(-) exchange, but Cl(-)-OH(-) exchange was not detected. The presence of 100 microm oxalate inhibited the rate of Cl(-)-HCO(3)(-) exchange by 60%. We conclude that mouse Slc26a6 has affinity for oxalate, sulfate, and HCO(3)(-) in addition to Cl(-) and formate and can function in multiple exchange modes involving pairs of these anions. In the presence of high oxalate concentrations as found in renal tubular fluid and urine, Slc26a6 may largely function as an electrogenic Cl(-)-oxalate exchanger.     

Role of chloride on carrier-mediated transport of p-aminohippurate in rat renal basolateral membrane vesicles

Effect of inorganic anions on p-amino[3H]hippurate transport in renal basolateral membranes has been studied using the vesicles preloaded with unlabeled p-aminohippurate (countertransport condition). The uptake of p-amino[3H]hippurate was stimulated by the outward gradient of unlabeled p-aminohippurate and the labeled substrate was accumulated into the vesicles against its concentration gradient in the presence of Cl-. The substitution of SCN- and SO4(2-) for Cl- in both sides of the vesicles depressed the initial rate and the overshoot magnitude of p-amino[3H]hippurate uptake. These results suggest that Cl- may play an important role for the carrier-mediated transport system of organic anion in renal basolateral membranes.     

Identification of a new urate and high affinity nicotinate transporter, hOAT10 (SLC22A13)

The orphan transporter hORCTL3 (human organic cation transporter like 3; SLC22A13) is highly expressed in kidneys and to a weaker extent in brain, heart, and intestine. hORCTL3-expressing Xenopus laevis oocytes showed uptake of [(3)H]nicotinate, [(3)H]p-aminohippurate, and [(14)C]urate. Hence, hORCTL3 is an organic anion transporter, and we renamed it hOAT10. [(3)H]Nicotinate transport by hOAT10 into X. laevis oocytes and into Caco-2 cells was saturable with Michaelis constants (K(m)) of 22 and 44 microm, respectively, suggesting that hOAT10 may be the molecular equivalent of the postulated high affinity nicotinate transporter in kidneys and intestine. The pH dependence of hOAT10 suggests p-aminohippurate(-)/OH(-), urate(-)/OH(-), and nicotinate(-)/OH(-) exchange as possible transport modes. Urate inhibited [(3)H]nicotinate transport by hOAT10 with an IC(50) value of 759 microm, assuming that hOAT10 represents a low affinity urate transporter. hOAT10-mediated [(14)C]urate uptake was elevated by an exchange with l -lactate, pyrazinoate, and nicotinate. Surprisingly, we have detected urate(-)/glutathione exchange by hOAT10, consistent with an involvement of hOAT10 in the renal glutathione cycle. Uricosurics, diuretics, and cyclosporine A showed substantial interactions with hOAT10, of which cyclosporine A enhanced [(14)C]urate uptake, providing the first molecular evidence for cyclosporine A-induced hyperuricemia.     

Functional expression of pig renal organic anion transporter 3 (pOAT3)

With the cloning of pig renal organic anion transporter 1 (pOAT1) (Biochimie 84 (2002) 1219) we set up a model system for comparative studies of cloned and natively isolated membrane located transport proteins. Meanwhile, another transport protein involved in p-aminohippurate (PAH) uptake on the basolateral side of the proximal tubule cells was identified, designated organic anion transporter 3 (OAT3). To explore the contribution of pOAT1 to the PAH clearance in comparison to OAT3, it was the aim of this study to extend our model by cloning of the pig ortholog of OAT3. Sequence comparisons of human organic anion transporter 3 (hOAT3) with the expressed sequence tag (EST) database revealed a clone and partial sequence of the pig renal organic anion transporter 3 (pOAT3) ortholog. Sequencing of the entire open reading frame resulted in a protein of 543 amino acid residues encoded by 1632 base pairs (EMBL Acc. No. AJ587003). It showed high homologies of 81%, 80%, 76%, and 77% to the human, rabbit, rat, and mouse OAT3, respectively. A functional characterization of pOAT3 in Xenopus laevis oocytes yielded an apparent Km (Kt) for [3H]estrone sulfate of 7.8 +/- 1.3 microM. Moreover, pOAT3 mediated [3H]estrone sulfate uptake was almost abolished by 0.5 mM of glutarate, dehydroepiandosterone sulfate, or probenecid consistent with the hallmarks of OAT3 function.     

Isolation of a 5,300-dalton peptide containing a pyridoxal phosphate binding site from the 38,000-dalton domain of band 3 of human erythrocyte membranes

A hydrophobic 5,300-dalton peptide was isolated from the 38,000-dalton domain of Band 3 by sodium dodecyl sulfate polyacrylamide gel electrophoresis and reversed-phase high-performance liquid chromatography. The peptide was affinity labeled with pyridoxal phosphate and sodium [3H]borohydride when erythrocytes were incubated in vitro. The peptide was not labeled with these agents when cells were incubated in the presence of a specific inhibitor of anion transport, suggesting that the peptide contains at least a part of the active center for the anion transport system in the cell membrane. The peptide was eluted from a reversed-phase high-performance liquid chromatography column with a high concentration of acetonitrile (more than 65%), although the elution pattern of the hydrophobic peptide was not as sharp as that of the soluble peptides. However, a satisfactory separation was achieved when this procedure was employed in combination with sodium dodecyl sulfate polyacrylamide gel electrophoresis.     

Characterization of mouse organic anion transporter 5 as a renal steroid sulfate transporter

A family of organic anion transporters (OAT) recently identified has important roles for the excretion or reabsorption of endogenous and exogenous compounds, and several new isoforms have been reported in this decade. Although the transepithelial transport properties of organic anions are gradually being understood, many portions of their functional characteristics in functions remain to be elucidated. A recently reported new cDNA encoding a mouse OAT5 (mOAT5) was constructed, using 3'-RACE PCR, with the total RNA isolated from a mouse kidney. When mOAT5 was expressed in Xenopus oocytes, mOAT5 transported estrone sulfate, dehydroepiandrosterone sulfate and ochratoxin A. Estrone sulfate uptake by mOAT5 displayed a time-dependent and sodium-independent manner. The Km values of estrone sulfate and dehydroepiandrosterone sulfate were 2.2 and 3.8 microM, respectively. mOAT5 interacted with chemically heterogeneous steroid or organic sulfates, such as nitrophenyl sulfate, methylumbelliferyl sulfate and estradiol sulfates. In contrast to the sulfate conjugates, mOAT5-mediated estrone sulfate uptake was not inhibited by the steroid or organic glucuronides. The mOAT5 protein having about 85 kDa molecular weight was shown to be mainly localized in the apical membrane of the proximal tubules of the outer medulla. These results suggest an important role of mOAT5 for the excretion or reabsorption of steroid sulfates in the kidney.     

Inorganic anions and the renal organic cation transport system

During renal secretion, organic cations (OC) have to pass two hydrophobic membranes (basolateral and luminal) and the intervening aqueous cytoplasm. Furthermore, an uptake in intracellular endosomes may also occur. OC transport critically depends on the presence or absence of certain inorganic anions, such as Cl-, HCO3-, and others. The interaction between inorganic anions and OC may occur during the transport across the membranes or uptake by endosomes, by alterations of the transport protein or the substrate and by changes of the intracellular pH.     

Characterization of anion permeability in AH-66 hepatoma ascites cells

The sulfate transport in AH-66 hepatoma ascites cells was examined under various controlled conditions using 35SO42- as a tracer. The sulfate efflux rate was dependent on temperature, pH and anion species of the cell suspending medium. The efflux rate became saturated as the concentration of extracellular anions was increased. The efflux of anion was inhibited by some chemical reagents specifically reactive with amino or sulfhydryl groups. The results obtained in this study suggest that sulfate anions were transported by a facilitated transport system(s), and that some membrane protein(s) is involved in the anion transport system(s) of AH-66 cells. Both amino and sulfhydryl groups are thought to play a determinant role at the sulfate transport site in AH-66 cells.     

Mutational analysis of ionizable residues proximal to the cytoplasmic interface of membrane spanning domain 3 of the multidrug resistance protein, MRP1 (ABCC1): glutamate 1204 is important for both the expression and catalytic activity of the transporter

The multidrug resistance protein MRP1 is an ATP-dependent transporter of organic anions and chemotherapeutic agents. A significant number of ionizable amino acids are found in or proximal to the 17 transmembrane (TM) helices of MRP1, and we have investigated 6 of these at the cytoplasmic interface of TM13-17 for their role in MRP1 expression and transport activity. Opposite charge substitutions of TM13 Arg(1046) and TM15 Arg(1131) did not alter MRP1 expression nor did they substantially affect activity. In contrast, opposite charge substitutions of TM16 Arg(1202) and Glu(1204) reduced protein expression by >80%; however, MRP1 expression was not affected when Arg(1202) and Glu(1204) were replaced with neutral or same-charge residues. In addition, organic anion transport levels of the R1202L, R1202G, and R1202K mutants were comparable with wild-type MRP1. In contrast, organic anion transport by E1204L was substantially reduced, whereas transport by E1204D was comparable with wild-type MRP1, with the notable exception of GSH. Opposite charge substitutions of TM16 Arg(1197) and TM17 Arg(1249) did not affect MRP1 expression but substantially reduced transport. Mutants containing like-charge substitutions of Arg(1197) or Arg(1249) were also transport-inactive and no longer bound leukotriene C(4). In contrast, substrate binding by the transport-compromised E1204L mutant remained intact. Furthermore, vanadate-induced trapping of azido-ADP by E1204L was dramatically increased, indicating that this mutation may cause a partial uncoupling of the catalytic and transport activities of MRP1. Thus, Glu(1204) serves a dual role in membrane expression of MRP1 and a step in its catalytic cycle subsequent to initial substrate binding.     

A positively charged region is a determinant of the orientation of cytoplasmic membrane proteins in Escherichia coli

Basic amino acid residues were introduced into an extracellular (periplasmic) domain, preceding a membrane-spanning hydrophobic domain, of SecY, an integral cytoplasmic membrane protein. The localization of the domain was monitored as to the alkaline phosphatase activity of TnPhoA fused adjacent to the domain. The alkaline phosphatase activity of such Escherichia coli cells drastically decreased when positive charges were introduced, indicating that on the introduction the SecY domain showed a change in localization from the periplasm to the cytoplasm. In another experiment, positive charges were introduced to the same periplasmic domain of another SecY-PhoA fusion protein, in which PhoA is fused to the cytoplasmic domain of SecY following the particular hydrophobic domain. The alkaline phosphatase activity increased drastically when positive charges were introduced, indicating that the SecY domain fused to PhoA showed a change in localization from the cytoplasm to the periplasm. In both experiments, the removal of a large amino-terminal portion of the SecY domain did not alter the effect of the positive charge introduction. Changes in localization of SecY domains thus demonstrated were also supported by a protease accessibility test on spheroplasts. It is proposed that a positively charged region adjacent to a membrane-embedded hydrophobic region tends to be stabilized on the cytoplasmic surface of the membrane, which in turn endows the hydrophobic region with the ability to act as a stop-transfer sequence or a signal sequence and consequently determines the orientation of the hydrophobic region in the membrane.     

A special role of phosphate in the stability of lactate dehydrogenase against destruction by a polyelectrolyte

It has been shown by X-ray structure analysis that proteins have specific anion-binding sites for sulfate, citrate, and phosphate ions; however, the functional role of these anions is not always clear. Thus, it is unknown which of two phosphate anions, mono- or divalent, determines the stability of cellular proteins under stress conditions. In the present work, the influence of phosphate, sulfate, and chloride on the stability of lactate dehydrogenase (LDH) in the presence of poly(styrenesulfonate) (PSS) has been investigated by the methods of steady-state kinetics and intrinsic protein fluorescence. The study is based on the analysis of differences between the influence of phosphate and sulfate ions on the process at two pH values, 6.2 and 7.0, at which the ratio of the concentrations of mono- and bivalent phosphate forms differs, whereas sulfate remains in the bivalent form. It was shown that the differences between the influence of phosphate and sulfate ions at pH 7.0 were greater; divalent phosphate ions much more effectively stabilized LDH against destruction by a polyelectrolyte compared with sulfate and monovalent phosphate. It was concluded that, of two anion-binding sites of the LDH molecule, the intersubunit center plays the most important role in its stabilization against destruction by polyelectrolyte, and, of two forms of phosphate anions, its bivalent form HPO ₄ ^?2 plays the stabilizing role.     

Bivalent probes of the human multidrug transporter P-glycoprotein

A small library of bivalent agents was designed to probe the substrate binding sites of the human multidrug transporter P-glycoprotein (P-gp). The bivalent agents were composed of two copies of the P-gp substrate emetine, linked by tethers of varied composition. An optimum distance between the emetine molecules of approximately 10 A was found to be necessary for blocking transport of the known fluorescent substrate rhodamine 123. Additionally, it was determined that hydrophobic tethers were optimal for bridging the bivalent compounds; hydrophilic or cationic moieties within the tether had a detrimental effect on inhibition of transport. In addition to acting as probes of P-gp's drug binding sites, these agents were also potent inhibitors of P-gp. One agent, EmeC5, had IC50 values of 2.9 microM for inhibiting transport of rhodamine 123 and approximately 5 nM for inhibiting the binding of a known P-gp substrate, [125I]iodoarylazidoprazosin. Although EmeC5 is an inhibitor of P-gp and was shown to interact directly with P-gp in one or more of the substrate binding sites, our data suggest that it is either not a P-gp transport substrate itself or a poor one. Most significantly, EmeC5 was shown to reverse the MDR phenotype of MCF-7/DX1 cells when co-administered with a cytotoxic agent, such as doxorubicin.     

Sulfhydryl groups are essential for organic anion exchange in canine renal brush-border membranes

The effect of several sulfhydryl-modifying reagents (HgCl2, p-chloromercuribenzenesulfonic acid (PCMBS), N-ethylmaleimide) on the renal organic anion exchanger was studied. The transport of p-amino[3H]hippurate, a prototypic organic anion, was examined employing brush-border membrane vesicles isolated from the outer cortex of canine kidneys. HgCl2, PCMBS and N-ethylmaleimide inactivated p-aminohippurate transport with IC50 values of 38, 78 and 190 microM. The rate of p-aminohippurate inactivation by N-ethylmaleimide followed apparent pseudo-first-order reaction kinetics. A replot of the data gave a linear relationship between the apparent rate constants and the N-ethylmaleimide concentration with a slope of 0.8. The data are consistent with a simple bimolecular reaction mechanism and imply that one molecule of N-ethylmaleimide inactivates one essential sulfhydryl group per active transport unit. Substrate (1 mM p-aminohippurate) affected the rate of the N-ethylmaleimide (1.3 mM) inactivation: the t1/2 values for inactivation in the presence and absence of p-aminohippurate were 7.4 and 3.7 min, respectively. The results demonstrate that there are essential sulfhydryl groups for organic anion transport in the brush-border membrane. Moreover, the ability of substrate to alter sulfhydryl reactivity suggests that the latter may play a dynamic role in the transport process.     

Identification of an allosteric anion-binding site on O-acetylserine sulfhydrylase: structure of the enzyme with chloride bound

A new crystal structure of O-acetylserine sulfhydrylase (OASS) has been solved with chloride bound at an allosteric site and sulfate bound at the active site. The bound anions result in a new "inhibited" conformation, that differs from the "open" native or "closed" external aldimine conformations. The allosteric site is located at the OASS dimer interface. The new inhibited structure involves a change in the position of the "moveable domain" (residues 87-131) to a location that differs from that in the open or closed forms. Formation of the external aldimine with substrate is stabilized by interaction of the alpha-carboxyl group of the substrate with a substrate-binding loop that is part of the moveable domain. The inhibited conformation prevents the substrate-binding loop from interacting with the alpha-carboxyl group, and hinders formation of the external Schiff base and thus subsequent chemistry. Chloride may be an analog of sulfide, the physiological inhibitor. Finally, these results suggest that OASS represents a new class of PLP-dependent enzymes that is regulated by small anions.