Comparative partial purification of the active dicarboxylate transport system of rat liver, kidney and heart mitochondria

Hydroxylapatite chromatography of Triton-extracted inner-membrane proteins from rat liver mitochondria allowed a ten-fold purification of the dicarboxylate carrier. The purified system, reconstituted into liposomes, displayed all the properties of the dicarboxylate carrier and mediated malonate-malate and malonate-phosphate exchanges. Six protein bands of Mr ranging from 27,000 to 34,000 could be resolved by sodium dodecylsulfate-polyacrylamide gel electrophoresis. The purification of the dicarboxylate carriers of liver, kidney and heart mitochondria were carried out by this method and their properties were compared with respect to transport activity and electrophoresis patterns. Our results demonstrate that the dicarboxylate carrier of rat mitochondria can be obtained in an advanced state of purification and with a high specific activity.     

Purification and reconstitution of two anion carriers from rat liver mitochondria: the dicarboxylate and the 2-oxoglutarate carrier

Two anion-transporting systems, i.e., the dicarboxylate carrier and the 2-oxoglutarate carrier, have been purified from rat liver mitochondria and functionally identified. The dicarboxylate carrier has been isolated in active form by hydroxyapatite chromatography after partial removal of the solubilizing detergent Triton X-114 from the mitochondrial extract. The SDS gel electrophoresis of this preparation consists mainly of one protein band with an apparent Mr of 28,000, identified as the dicarboxylate carrier. Complete purification of the 28 kDa protein in inactive form has been achieved by sequential chromatography on hydroxyapatite and Celite followed by SDS extraction of the retained protein. The 2-oxoglutarate carrier has been purified by hydroxyapatite chromatography after extensive removal of Triton X-114 from the detergent extract. SDS gel electrophoresis of the purified fraction shows a single band with an apparent Mr of 32,500. When reconstituted into liposomes, the functional properties of the two isolated carrier proteins resemble closely those of the dicarboxylate and the 2-oxoglutarate transport systems characterized in mitochondria.     

CORM-3, a water soluble CO-releasing molecule,uncouples mitochondrial respiration via interaction with the phosphate carrier

Carbon monoxide is continuously produced in small quantities in tissues and is an important signaling mediator in mammalian cells. We previously demonstrated that CO delivered to isolated rat heart mitochondria using a water-soluble CO-releasing molecule (CORM-3) is able to uncouple mitochondrial respiration. The aim of this study was to explore more in depth the mechanism(s) of this uncoupling effect. We found that acceleration of mitochondrial O₂ consumption and decrease in membrane potential induced by CORM-3 were associated with an increase in mitochondrial swelling. This effect was independent of the opening of the mitochondrial transition pore as cyclosporine A was unable to prevent it. Interestingly, removal of phosphate from the incubation medium suppressed the effects mediated by CORM-3. Blockade of the dicarboxylate carrier, which exchanges dicarboxylate for phosphate, decreased the effects induced by CORM-3 while direct inhibition of the phosphate carrier with N-ethylmaleimide completely abolished the effects of CORM-3. In addition, CORM-3 was able to enhance the transport of phosphate into mitochondria as evidenced by changes in mitochondrial phosphate concentration and mitochondrial swelling that evaluates the activity of the phosphate carrier in de-energized conditions. These results indicate that CORM-3 activates the phosphate carrier leading to an increase in phosphate and proton transport inside mitochondria, both of which could contribute to the non-classical uncoupling effect mediated by CORM-3. The dicarboxylate carrier amplifies this effect by increasing intra-mitochondrial phosphate concentration.     

Characterization of phosphate efflux pathways in rat liver mitochondria.

ATP hydrolysis catalysed by the H+-ATPase of intact mitochondria can be induced by addition of ATP in the presence of valinomycin and KCl. This leads to an increase in intramitochondrial Pi and therefore allows investigation of potential Pi efflux pathways in intact mitochondria. Combining this approach with the direct measurement of both internal and external Pi, we have attempted to determine whether Pi efflux occurs via an atractyloside-sensitive transporter, by the classical operation of the Pi/H+ and Pi/dicarboxylate carriers, and/or by other mechanisms. Initial experiments re-examined the evidence that led to the current view that one efflux pathway for Pi is an atractyloside-sensitive ATP/ADP,0.5Pi transporter. No evidence was found in support of this efflux pathway. Rather, atractyloside-sensitivity of the low rate of Pi efflux observed in previous studies (oligomycin present) was accounted for by ATP entry on the well known ATP/ADP transport system followed by hydrolysis of ATP and subsequent Pi efflux. Thus, under these conditions, where ATP hydrolysis is not completely inhibited, Pi efflux becomes atractyloside sensitive most likely because this inhibitor blocks ATP entry, not because it directly inhibits Pi efflux. Substantial efflux of Pi from rat liver mitochondria is observed on generation of high levels of matrix Pi by ATP hydrolysis induced by valinomycin and K+ (oligomycin absent). A portion of this efflux can be inhibited by thiol-specific reagents at concentrations that normally inhibit the Pi/H+ and Pi/dicarboxylate carriers. However, a significant fraction of efflux continues even in the presence of p-chloromercuribenzoate, N-ethylmaleimide plus n-butylmalonate or mersalyl. The mersalyl-insensitive Pi efflux, which is also insensitive to carboxyatractyloside, is a saturable process, thus suggesting carrier mediation. During this efflux the mitochondrial inner membrane retains considerable impermeability to other low-molecular-weight anions (i.e., malate, 2-oxoglutarate). In conclusion, results presented here rule out an atractyloside-sensitive ATP/ADP,0.5Pi transport system as a mechanism for Pi efflux in rat liver mitochondria. Rather Pi efflux appears to occur on the classical Pi/H+ transport system as well as via a mersalyl-insensitive saturable process. The inhibitor-insensitive Pi efflux may occur on a portion of the Pi/H+ carrier molecules that exist in a state different from that normally catalysing Pi influx. Alternatively, a separate Pi efflux carrier may exist.     

Effects of 3,5-Dibromo-4-Hydroxybenzonitrile (Bromoxynil) on Bioenergetics of Higher Plant Mitochondria (Pisum sativum)

The herbicide bromoxynil (3,5-dibromo-4-hydroxybenzonitrile) was tested on mitochondria from etiolated pea (Pisum sativum L. cv Alaska) stems. This compound when used at micromolar concentrations ([almost equal to]20 [mu]M) inhibited malate- and succinate-dependent respiration by intact mitochondria but not oxidation of exogenously added NADH. Bromoxynil did not affect the activities of the succinic and the internal NADH dehydrogenases. Analyses of the effects induced by this herbicide on the membrane potential, [delta]pH, matrix Ca2+ movements, and dicarboxylate transport demonstrated that bromoxynil is likely to act as an inhibitor of the dicarboxylate carrier. In addition, bromoxynil caused a mild membrane uncoupling at concentrations [greater than or equal to]20 [mu]M. No effect on the ATPase activity was observed.     

Enrichment and functional reconstitution of glutathione transport activity from rabbit kidney mitochondria: further evidence for the role of the dicarboxylate and 2-oxoglutarate carriers in mitochondrial glutathione transport

In previous studies, we provided evidence for uptake of glutathione (GSH) by the dicarboxylate and the 2-oxoglutarate carriers in rat kidney mitochondria. To investigate further the role of these two carriers, GSH transport activity was enriched from rabbit kidney mitochondria and functionally reconstituted into phospholipid vesicles. Starting with 200 mg of mitoplast protein, 2 mg of partially enriched proteins were obtained after Triton X-114 solubilization and hydroxyapatite chromatography. The reconstituted proteoliposomes catalyzed butylmalonate-sensitive uptake of [(14)C]malonate, phenylsuccinate-sensitive uptake of [(14)C]2-oxoglutarate, and transport activity with [(3)H]GSH. The initial rate of uptake of 5 mM GSH was approximately 170 nmol/min per mg protein, with a first-order rate constant of 0.3 min(-1), which is very close to that previously determined in freshly isolated rat kidney mitochondria. The enrichment procedure resulted in an approximately 60-fold increase in the specific activity of GSH transport. Substrates and inhibitors for the dicarboxylate and the 2-oxoglutarate carriers (i.e., malate, malonate, 2-oxoglutarate, butylmalonate, phenylsuccinate) significantly inhibited the uptake of [(3)H]GSH, whereas most substrates for the tricarboxylate and monocarboxylate carriers had no effect. GSH uptake exhibited an apparent K(m) of 2.8 mM and a V(max) of 260 nmol/min per mg protein. Analysis of mutual inhibition between GSH and the dicarboxylates suggested that the dicarboxylate carrier contributes a somewhat higher proportion to overall GSH uptake and that both carriers account for 70 to 80% of total GSH uptake. These results provide further evidence for the function of the dicarboxylate and 2-oxoglutarate carriers in the mitochondrial transport of GSH.     

Sulphate transport by H+ symport and by the dicarboxylate carrier in mitochondria.

1. Swelling of mitochondria was induced in non-respiring mitochondria by 30 mM or more Na2SO4 or by respiration in the presence of K2SO4. Respiration-drive swelling resulted in loss of respiratory control. Sulphate, when present at 10 mM concentration, promoted the release of accumulated Ca2+. 2. Swelling was prevented by N-ethylmaleimide and formaldehyde, known inhibitors of the phosphate carrier. Sulphate-induced swelling was more sensitive to the inhibitors than was phosphate-induced swelling. At lower concentration of sulphate, 5 mM, an alkalinisation of the medium was observed in addition of sulphate, indicating H+-sulphate symport. There was competition between sulphate and phosphate for transport by this mechanism. It is suggested that sulphate may be transported, though at a comparatively slow rate, by the phosphate carrier. 3. Uptake of sulphate was stimulated when preceded by energy-dependent accumulation of Ba2+, especially when acetate was also present, indicating precipitation of BaSO4 in the matrix. Using this system the influx of sulphate was studied at lower concentrations, 10 mM or less. the contributions of the H+ symporter (sensitive to N-ethylmaleimide) and the dicarboxylate carrier (sensitive to butylmalonate) could then be studied. The dicarboxylate carrier had a lower Km and was mainly responsible for sulphate transport at lower concentration range. At 10 mM-sulphate the transport rates by the two systems appeared to be similar; at still higher concentrations the H+ symporter may become more important.     

Anion transporters in plant mitochondria

The swelling of potato (Solanum tuberosum L.) mitochondria in isosmotic ammonium salts of phosphate, chloride, malate, succinate, and citrate was investigated by measuring light scattering. Potato mitochondria swell spontaneously in ammonium phosphate, and this swelling can be inhibited in N-ethylmaleimide. They swell in ammonium malate or succinate only after the addition of inorganic phosphate and in ammonium citrate only after the addition of both phosphate and a dicarboxylic acid. Pentylmalonate inhibits swelling in ammonium citrate solutions by competing for dicarboxylate entry. The results indicate that potato mitochondria possess a phosphate-hydroxyl carrier, a dicarboxylate carrier, and a tricarboxylate carrier.     

Kinetics of the reconstituted dicarboxylate carrier from rat liver mitochondria

The dicarboxylate carrier from rat liver mitochondria was purified by the Amberlite/hydroxyapatite procedure and reconstituted in egg yolk phospholipid vesicles by removing the detergent with Amberlite. The efficiency of reconstitution was optimized with respect to the ratio of detergent/phospholipid, the concentration of phospholipid and the number of Amberlite column passages. In the reconstituted system the incorporated dicarboxylate carrier catalyzed a first-order reaction of malate/phosphate exchange. V of the reconstituted malate/phosphate exchange was determined to be 6000 mumol/min per g protein at 25 degrees C. This value was independent of the type of substrate present at the external or internal space of the liposomes (malate, phosphate or malonate). The half-saturation constant was 0.49 mM for malate, 0.54 mM for malonate and 1.41 mM for phosphate. The activation energy of the exchange reaction was determined to be 95.8 kJ/mol. The transport was independent of the external pH in the range between pH 6 and 8.     

Kinetic discrimination of two substrate binding sites of the reconstituted dicarboxylate carrier from rat liver mitochondria

The kinetic interaction of various substrates and inhibitors with the dicarboxylate carrier from rat liver mitochondria was investigated using the isolated and reconstituted carrier protein. Due to their inhibitory interrelation the ligands could be divided into two classes: dicarboxylates, sulphate, sulphite and butylmalonate on the one hand and phosphate, thiosulphate and arsenate on the other. The mutual inhibition of substrates or inhibitors taken from one single class was found to be competitive, whereas the kinetic interaction of ligands when taken from the two different classes could be described as purely non-competitive. The half-saturation transport constants Km and the corresponding inhibition constants Ki of one single ligand, either used as substrate or as inhibitor, respectively, were found to be very similar. These kinetic data strongly support the presence of two different binding sites at the dicarboxylate carrier for the two different classes of substrates considering the external side of the reconstituted protein. When these two sites were saturated simultaneously with malate and phosphate, the turnover of the carrier was considerably reduced, hence indicating that a non-catalytic ternary complex is formed by the two substrates and the carrier molecule.     

Mitochondrial glutathione transport: physiological, pathological and toxicological implications

Although most cellular glutathione (GSH) is in the cytoplasm, a distinctly regulated pool is present in mitochondria. Inasmuch as GSH synthesis is primarily restricted to the cytoplasm, the mitochondrial pool must derive from transport of cytoplasmic GSH across the mitochondrial inner membrane. Early studies in liver mitochondria primarily focused on the relationship between GSH status and membrane permeability and energetics. Because GSH is an anion at physiological pH, this suggested that some of the organic anion carriers present in the inner membrane could function in GSH transport. Indeed, studies by Lash and colleagues in isolated mitochondria from rat kidney showed that most of the transport (>80%) in that tissue could be accounted for by function of the dicarboxylate carrier (DIC, Slc25a10) and the oxoglutarate carrier (OGC, Slc25a11), which mediate electroneutral exchange of dicarboxylates for inorganic phosphate and 2-oxoglutarate for other dicarboxylates, respectively. The identity and function of specific carrier proteins in other tissues is less certain, although the OGC is expressed in heart, liver, and brain and the DIC is expressed in liver and kidney. An additional carrier that transports 2-oxoglutarate, the oxodicarboxylate or oxoadipate carrier (ODC; Slc25a21), has been described in rat and human liver and its expression has a wide tissue distribution, although its potential function in GSH transport has not been investigated. Overexpression of the cDNA for the DIC and OGC in a renal proximal tubule-derived cell line, NRK-52E cells, showed that enhanced carrier expression and activity protects against oxidative stress and chemically induced apoptosis. This has implications for development of novel therapeutic approaches for treatment of human diseases and pathological states. Several conditions, such as alcoholic liver disease, cirrhosis or other chronic biliary obstructive diseases, and diabetic nephropathy, are associated with depletion or oxidation of the mitochondrial GSH pool in liver or kidney.     

Isolation and reconstitution of the n-butylmalonate-sensitive dicarboxylate transporter from rat liver mitochondria

The mitochondrial dicarboxylate carrier has been substantially purified from rat liver mitoplasts by extraction with Triton X-114 in the presence of cardiolipin followed by chromatography on hydroxylapatite. Upon incorporation of the hydroxylapatite eluate into phospholipid vesicles, an n-butylmalonate-sensitive malonate/malate exchange has been demonstrated. This exchange activity is enhanced 226-fold relative to the starting material (i.e. detergent-extracted mitoplasts). Silver-stained sodium dodecyl sulfate-polyacrylamide gradient gels verify the high purity of this fraction relative to the starting material. Nonetheless, the banding pattern indicates that several protein species are still present. As isolated, the dicarboxylate transporter is rather unstable but can be stabilized either by the addition of 10% ethylene glycol and subsequent storage at -20 degrees C or by incorporation into phospholipid vesicles in the presence of malate followed by freezing in liquid nitrogen. Such proteoliposomes catalyze a [14C]malonate uptake which is characterized by a first order rate constant of 1.02 min-1 and a t 1/2 of 41 s. This uptake can be inhibited by dicarboxylates (e.g. succinate, malate, unlabeled malonate) but not by either alpha-ketoglutarate or by tricarboxylates (e.g. citrate, threo-Ds-isocitrate). Furthermore, the reconstituted malonate transport is dependent on internal malate and can be inhibited by n-butylmalonate, mersalyl, p-chloromercuribenzoate, and Pi, but not by N-ethylmaleimide. It is concluded that this highly purified fraction contains a reconstitutively active dicarboxylate transporter which, based on its substrate specificity and inhibitor sensitivity, appears to be identical to the native dicarboxylate transport system found in intact rat liver mitochondria.     

The inhibition of mitochondrial dicarboxylate transport by inorganic phosphate, some phosphate esters and some phosphonate compounds

1. P(i) competitively inhibited succinate oxidation by intact uncoupled mitochondria in the presence of sufficient N-ethylmaleimide to block the phosphate carrier, with a K(i) of 2.5mm. 2. Of a large number of phosphate esters and phosphonate compounds, phenyl phosphate and phenylphosphonate were found to inhibit competitively uncoupled succinate oxidation by intact but not broken mitochondria. By comparison, benzoate was a relatively weak competitive inhibitor of succinate oxidation by intact mitochondria but a relatively potent inhibitor of succinate dehydrogenase. 3. Phenyl phosphate and phenylphosphonate were non-penetrant, and inhibited P(i)-dependent swelling of mitochondria suspended in isosmolar ammonium malate in a manner non-competitive with P(i). The inhibitors did not affect mitochondrial swelling when tested with P(i) alone. 4. It is concluded that: (i) phenyl phosphate and phenylphosphonate behaved as non-penetrant analogues of P(i), since their inhibitory properties were in strict contrast with those of benzoate; (ii) phenyl phosphate and phenylphosphonate interacted with the dicarboxylate carrier but not with the phosphate carrier; (iii) P(i) was effective as a competitive inhibitor of succinate oxidation because of its being either an alternative substrate for the dicarboxylate carrier or competitive with succinate for the intramitochondrial cations as proposed by Harris & Manger (1968).     

Phosphate-induced efflux of adenine nucleotides from rat-heart mitochondria: evaluation of the roles of the phosphate/hydroxyl exchanger and the dicarboxylate carrier

Upon the addition of inorganic phosphate, isolated rat-heart mitochondria released endogenous adenine nucleotides. To elucidate the mechanism of this phosphate-induced efflux, we evaluated the relative roles of three inner mitochondrial membrane carriers: the adenine nucleotide translocase, the phosphate/hydroxyl exchanger, and the dicarboxylate carrier. Atractyloside (a specific inhibitor of the adenine nucleotide translocase) prevented this efflux, but did not inhibit mitochondrial swelling. Inhibitors of the phosphate/hydroxyl exchanger (200 microM n-ethylmaleimide and 10 microM mersalyl) did not inhibit phosphate-induced efflux. 200 microM mersalyl (which inhibited both the phosphate/hydroxyl exchanger and the dicarboxylate carrier) inhibited the rate of efflux approx. 65% Phenylsuccinate and 2-n-butylmalonate (inhibitors of the dicarboxylate carrier) partially inhibited phosphate-induced efflux and adenine nucleotide translocase activity. Mersalyl (200 microM) had no effect on adenine nucleotide translocase activity. Partial inhibition of the adenine nucleotide translocase by phenylsuccinate and butylmalonate could not explain the extent of inhibition of phosphate-efflux by these agents. Moreover, the rates of adenine nucleotide efflux in the presence of phenylsuccinate, butylmalonate, or mersalyl correlated well with the ability of these agents to inhibit succinate-supported respiration. We conclude that phosphate-induced efflux of adenine nucleotides from rat heart mitochondria occurs over the adenine nucleotide translocase, and that the site of action of the phosphate is not the phosphate/hydroxyl exchanger, but is likely the dicarboxylate carrier.     

The transport of inorganic phosphate by the mitochondrial dicarboxylate carrier

1. N-Ethylmaleimide inhibited the influx and efflux of P(i) in rat liver mitochondria. 2. The efflux was stimulated by either succinate or malate in the presence of N-ethylmaleimide, and this stimulation was reversed by 2-n-butylmalonate. 2-Oxoglutarate and citrate, even in the presence of low concentrations of malate, were relatively ineffective in stimulating efflux of P(i) under these conditions, as was glutamate. 3. By using radioactively labelled P(i) and dicarboxylate ions an exchange was demonstrated, the stoicheiometry of which was 1.3+/-0.5 dicarboxylate ions:1 P(i) (n=10). 4. An exchange between unlabelled and labelled P(i) in the presence of N-ethylmaleimide was found which was sensitive to 2-n-butylmalonate. 5. It is concluded that the mitochondrial dicarboxylate carrier can transport phosphate by an exchange diffusion with certain penetrant dicarboxylic acids or with phosphate itself. The exchange mechanism is sensitive to 2-n-butylmalonate but is unaffected by N-ethylmaleimide; the action of mersalyl in this context is commented on.     

Dicarboxylate transport across the inner membrane of the chloroplast envelope.

The uptake of radioactively labeled dicarboxylates into the sorbitol-impermeable 3H2O space (the space surrounded by the inner envelope membrane) of spinach chloroplasts has been studied by means of silicone layer filtering centrifugation. 1. Malate, aspartate and a number of other dicarboxylates are rapidly transported across the envelope leading to an accumulation in the chloroplasts. This uptake proceeds mainly by a counterexchange with the dicarboxylates present there. 2. The dicarboxylate transport shows saturation characteristics allowing the determination of Km and V. 3. All dicarboxylates transported act as competitive inhibitors of the transport. 4. The activation energy of the transport as determined from the temperature dependency is evaluated to be 7 kcal/mol. 5. The rate of dicarboxylate transport is influenced by illumination, the countertransported molecules and the pH in the medium. These changes effect the transport velocity, whereas the corresponding Km values are not altered. 6. It is discussed whether there is more than one carrier involved in dicarboxylate transport in spinach chloroplasts.     

Redistribution of the flux-control coefficients in mitochondrial oxidative phosphorylations in the course of brain edema

This work describes the control exerted by dicarboxylate carrier and succinate dehydrogenase activities on the oxidative phosphorylations in rabbit brain mitochondria as an edema develops. Vasogenic edema leads to an uncompetitive inhibition of succinate dehydrogenase activity and to a large decrease of oxidative phosphorylations linked to succinate utilisation. Naftidrofuryl treatment in vivo restores both a high succinate dehydrogenase activity and a normal respiratory rate. In order to quantify the control of oxidative phosphorylations by the succinate dehydrogenase step, we applied the control analysis (Kacser, H. and Burns, J.A. (1973) in Rate Control of Biological Processes (Davies, D.D., ed.), pp. 65-104, Cambridge University Press, London; Heinrich, R. and Rapoport, T.A. (1974) Eur. J. Biochem. 42, 89-95). By using two inhibitors, one (phenylsuccinate) acting only on the dicarboxylate carrier and another (malonate) acting on both the dicarboxylate carrier and the succinate dehydrogenase, a method was developed to calculate the control coefficients of these two steps. The main result is that in mitochondria isolated from normal tissue succinate dehydrogenase exerted no control, but in the course of edema this enzymatic step became a controlling one: a transition from zero to a high control coefficient (0.5) was observed from the onset of intracellular edema for the threshold value of water/dry-weight tissue of 4.6.     

Transport of glutamine into isolated pea chloroplasts

Abstract. Uptake of [¹⁴C] glutamine into isolated pea chloroplasts has been examined by using a centrifugal filtration technique. Competition experiments showed that glutamine uptake is mediated by a dicarboxylate carrier with K_m 1.10 mM and V _max. 118 nmol of glutamine min⁻¹ per mg of chlorophyll. Isolated pea chloroplasts accumulated glutamine in the sucrose-impermeable space to concentrations higher than that present in the external solution when the latter was below 0.5 mM. It is suggested that glutamine accumulation is driven by exchange (utilizing the dicarboxylate carrier) with the endogenous pool of dicarboxylates in the chloroplasts. Increasing pH stimulated glutamine uptake but inhibited that of glutamate and 2-oxoglu-tarate. The hypothesis is advanced that when molecules of different charge are exchanged across the chloroplast envelope via the dicarboxylate carrier, electroneutrality is maintained by transport of protons, and that this explains the observed effects of increasing pH. The low rates of glutamine transport coupled with the strong competition of other dicarboxylates for the carrier suggest that export in vivo from the chloroplast of nitrogen in the form of glutamine is not of major importance.     

Functional characterization of a Na(+)-coupled dicarboxylate carrier protein from Staphylococcus aureus

We have cloned and functionally characterized a Na(+)-coupled dicarboxylate transporter, SdcS, from Staphylococcus aureus. This carrier protein is a member of the divalent anion/Na(+) symporter (DASS) family and shares significant sequence homology with the mammalian Na(+)/dicarboxylate cotransporters NaDC-1 and NaDC-3. Analysis of SdcS function indicates transport properties consistent with those of its eukaryotic counterparts. Thus, SdcS facilitates the transport of the dicarboxylates fumarate, malate, and succinate across the cytoplasmic membrane in a Na(+)-dependent manner. Furthermore, kinetic work predicts an ordered reaction sequence with Na(+) (K(0.5) of 2.7 mM) binding before dicarboxylate (K(m) of 4.5 microM). Because this transporter and its mammalian homologs are functionally similar, we suggest that SdcS may serve as a useful model for DASS family structural analysis.