Low and high affinity amino acid H+-cotransporters for cellular import of neutral and charged amino acids

Amides and acidic amino acids represent the major long distance transport forms of organic nitrogen. Six amino acid permeases (AAPs) from Arabidopsis mediating transport of a wide spectrum of amino acids were isolated. AAPs are distantly related to plasma membrane amino acid transport systems N and A and to vesicular transporters such as VGAT from mammals. A detailed comparison of the properties by electrophysiology after heterologous expression in Xenopus oocytes shows that, although capable of recognizing and transporting a wide spectrum of amino acids, individual AAPs differ with respect to specificity. Apparent substrate affinities are influenced by structure and net charge and vary by three orders of magnitude. AAPs mediate cotransport of neutral amino acids with one proton. Uncharged forms of acidic and basic amino acids are cotransported with one proton. Since all AAPs are differentially expressed, different tissues may be supplied with a different spectrum of amino acids. AAP3 and AAP5 are the only transporters mediating efficient transport of the basic amino acids. In vivo competition shows that the capability to transport basic amino acids in planta might be overruled by excess amides and acidic amino acids in the apoplasm. With the exception of AAP6, AAPs do not recognize aspartate; only AAP6 has an affinity for aspartate in the physiologically relevant range. This property is due to an overall higher affinity of AAP6 for neutral and acidic amino acids. Thus AAP6 may serve a different role either in cooperating with the lower affinity systems to acquire amino acids in the low concentration range, as a system responsible for aspartate transport or as an uptake system from the xylem. In agreement, a yeast mutant deficient in acidic amino acid uptake at low aspartate concentrations was complemented only by AAP6. Taken together, the AAPs transport neutral, acidic and cationic amino acids, including the major transport forms, i.e. glutamine, asparagine and glutamate. Increasing proton concentrations strongly activate transport of amino acids. Thus the actual apoplasmic concentration of amino acids and the pH will determine what is transported in vivo, i.e. major amino acids such as glutamine, asparagine, and glutamate will be mobilized preferentially.     

Amino Acid transport in germinating castor bean seedlings

During germination and early growth of the castor bean (Ricinus communis) nitrogenous constituents from the endosperm are transferred via the cotyledons to the growing embryo. Exudate collected from the cut hypocotyl of 4-day seedlings contained 120 millimolar soluble amino nitrogen and glutamine was the predominant amino acid present, comprising 35 to 40% of the total amino nitrogen. To determine the nature of nitrogen transfer, the endosperm and hypocotyl were removed and glutamine uptake by the excised cotyledons was investigated. Uptake was linear for at least 2 hours and the cotyledons actively accumulated glutamine against a concentration gradient. The uptake was sensitive to respiratory inhibitors and uncouplers and efflux of glutamine from the excised cotyledons was negligible. Transport was specific for the l-isomer. Other neutral amino acids were transported at similar rates to glutamine. Except for histidine, the acidic and basic amino acids were transported at lower rates than the neutral amino acids. For glutamine transport, the K(m) was 11 to 12 millimolar and the V(max) was 60 to 70 micromoles per gram fresh weight per hour. Glutamine uptake was diminished in the presence of other amino acids and the extent of inhibition was greatest for those amino acids which were themselves rapidly transported into the cotyledons. The transport of amino acids, on a per seedling basis, was greatest for cotyledons from 4-to 6-day seedlings, when transfer of nitrogen from the endosperm is also maximal. It is concluded that the castor bean cotyledons are highly active absorptive organs transporting both sucrose and amino acids from the surrounding endosperm at high rates.     

rBAT is an Amino Acid Exchanger with Variable Stoichiometry

The rBAT protein, when expressed in Xenopus oocytes, was previously shown to reproduce the selectivity of the Na⁺-independent neutral and basic amino acid transport system called b^o,+. More recently, the capacity of rBAT to generate a transmembrane current was demonstrated when addition of neutral amino acids stimulated the efflux of cations (presumably basic amino acids) in rBAT-injected oocytes. In the present paper, aminoisobutyric acid (AIB), a neutral amino acid analogue, was shown to induce outward currents (efflux of basic amino acids) through rBAT similar to those caused by alanine in terms of affinity, maximal currents and I-V curves. Despite generating similar currents, the AIB transport rate was more than 30 times lower than that of alanine, thus challenging the assumption that rBAT functions as a classical exchanger. Experiments using a cut-open oocyte voltage clamp demonstrated that AIB was capable of stimulating rBAT-mediated currents from either side of the membrane. AIB, like alanine, was able to stimulate the efflux of radiolabeled alanine and arginine while no rBAT-mediated efflux was measurable in the absence of external rBAT substrates. These results demonstrate that (i) the presence of amino acids is required on both sides of the membrane for rBAT to mediate amino acid flux and thus rBAT must be some type of exchanger but (ii) rBAT-mediated amino acid influx is not stoichiometrically related to the efflux. A model of a ``double gated pore' is proposed to account for these properties of rBAT, which contravene standard models of exchangers and other transporters. Received: 15 June 1995/Revised: 21 September 1995     

Characterization and regulation of the gene expression of amino acid transport system A (SNAT2) in rat mammary gland

Amino acid transport via system A plays an important role during lactation, promoting the uptake of small neutral amino acids, mainly alanine and glutamine. However, the regulation of gene expression of system A [sodium-coupled neutral amino acid transporter (SNAT)2] in mammary gland has not been studied. The aim of the present work was to understand the possible mechanisms of regulation of SNAT2 in the rat mammary gland. Incubation of gland explants in amino acid-free medium induced the expression of SNAT2, and this response was repressed by the presence of small neutral amino acids or by actinomycin D but not by large neutral or cationic amino acids. The half-life of SNAT2 mRNA was 67 min, indicating a rapid turnover. In addition, SNAT2 expression in the mammary gland was induced by forskolin and PMA, inducers of PKA and PKC signaling pathways, respectively. Inhibitors of PKA and PKC pathways partially prevented the upregulation of SNAT2 mRNA during adaptive regulation. Interestingly, SNAT2 mRNA was induced during pregnancy and to a lesser extent at peak lactation. beta-Estradiol stimulated the expression of SNAT2 in mammary gland explants; this stimulation was prevented by the estrogen receptor inhibitor ICI-182780. Our findings clearly demonstrated that the SNAT2 gene is regulated by multiple pathways, indicating that the expression of this amino acid transport system is tightly controlled due to its importance for the mammary gland during pregnancy and lactation to prepare the gland for the transport of amino acids during lactation.     

Derepression of amino Acid-h cotransport in developing soybean embryos

The uptake of the unnatural amino acid α-aminoisobutyric acid (AIB) and glutamine by developing soybean (Glycine max Merr. cv Chippewa 64) embryos was investigated. In freshly excised embryos, the accumulation ratio (cytoplasmic concentration/external concentration) of AIB did not exceed 1.0. After an 18-hour preincubation in nitrogen-free medium the accumulation ratio of AIB exceeded 4.5 at an external AIB concentration of 10 micromolar. This indicates the derepression of an active amino acid uptake mechanism operative at low external amino acid concentration. The presence of sucrose, NH₄NO₃, or glutamine during a 21-hour preincubation prior to measuring glutamine uptake inhibited the enhancement of uptake by 43%, 51%, and 96%, respectively. The time course of the decline in free amino acids and the time course of enhancement of amino acid uptake was not consistent with enhanced uptake resulting from relief of transinhibition, but suggested instead the derepression of synthesis of new carriers. The time course of enhancement of amino acid uptake was paralleled by an increase in glutamine-induced depolarization of the membrane potential. The kinetics of glutamine uptake indicated the presence of a saturable and a nonsaturable component of uptake. The saturable component of uptake is attributed to a mechanism of amino acid-H⁺ cotransport which is derepressed by nitrogen and/or carbon starvation. At physiological concentrations of amino acids, uptake through the saturable system in freshly excised embryos is negligible. Thus, uptake through the nonsaturable system is of primary importance in the nitrogen nutrition of developing soybean embryos.     

Mechanism of amino Acid uptake by sugarcane suspension cells

The amino acid carriers in sugarcane suspension cells were characterized for amino acid specificity and the stoichiometry of proton and potassium flux during amino acid transport.

Amino acid transport by sugarcane cells is dependent upon three distinct transport systems. One system is specific for neutral amino acids and transports all neutral amino acids including glutamine, asparagine, and histidine. The uptake of neutral amino acids is coupled to the uptake of one proton per amino acid; one potassium ion leaves the cells for charge compensation. Histidine is only taken up in the neutral form so that deprotonation of the charged imidazole nitrogen has to occur prior to uptake. The basic amino acids are transported by another system as uniport with charge-compensating efflux of protons and potassium. The acidic amino acids are transported by a third system. Acidic amino acids bind to the transport site only if the distal carboxyl group is in the dissociated form (i.e. if the acidic amino acid is anionic). Two protons are withdrawn from the medium and one potassium leaves the cell for charge compensation during the uptake of acid amino acids. Common to all three uptake systems is a monovalent positively charged amino acidproton carrier complex at the transport site.

     

Cloning of an amino acid transporter with functional characteristics and tissue expression pattern identical to that of system A

We report here on the cloning and functional characterization of the protein responsible for the system A amino acid transport activity that is known to be expressed in most mammalian tissues. This transporter, designated ATA2 for amino acid transporter A2, was cloned from rat skeletal muscle. It is distinct from the neuron-specific glutamine transporter (GlnT/ATA1). Rat ATA2 consists of 504 amino acids and bears significant homology to GlnT/ATA1 and system N (SN1). ATA2-specific mRNA is ubiquitously expressed in rat tissues. When expressed in mammalian cells, ATA2 mediates Na(+)-dependent transport of alpha-(methylamino)isobutyric acid, a specific model substrate for system A. The transporter is specific for neutral amino acids. It is pH-sensitive and Li(+)-intolerant. The Na(+):amino acid stoichiometry is 1:1. When expressed in Xenopus laevis oocytes, transport of neutral amino acids via ATA2 is associated with inward currents. The substrate-induced current is Na(+)-dependent and pH-sensitive. The amino acid transport system A is particularly known for its adaptive and hormonal regulation, and therefore the successful cloning of the protein responsible for this transport activity represents a significant step toward understanding the function and expression of this transporter in various physiological and pathological states.     

Evidence for the transport of neutral as well as cationic amino acids by ATA3, a novel and liver-specific subtype of amino acid transport system A

We report here on the cloning and functional characterization of the third subtype of amino acid transport system A, designated ATA3 (amino acid transporter A3), from a human liver cell line. This transporter consists of 547 amino acids and is structurally related to the members of the glutamine transporter family. The human ATA3 (hATA3) exhibits 88% identity in amino acid sequence with rat ATA3. The gene coding for hATA3 contains 16 exons and is located on human chromosome 12q13. It is expressed almost exclusively in the liver. hATA3 mediates the transport of neutral amino acids including α-(methylamino)isobutyric acid (MeAIB), the model substrate for system A, in a Na⁺-coupled manner and the transport of cationic amino acids in a Na⁺-independent manner. The affinity of hATA3 for cationic amino acids is higher than for neutral amino acids. The transport function of hATA3 is thus similar to that of system y⁺L. The ability of hATA3 to transport cationic amino acids with high affinity is unique among the members of the glutamine transporter family. hATA1 and hATA2, the other two known members of the system A subfamily, show little affinity toward cationic amino acids. hATA3 also differs from hATA1 and hATA2 in exhibiting low affinity for MeAIB. Since liver does not express any of the previously known high-affinity cationic amino acid transporters, ATA3 is likely to provide the major route for the uptake of arginine in this tissue.     

Uptake of 14C-α-aminoisobutyric acid by Phaseolus vulgaris

Specific uptake (S.U.) of α-aminoisobutyric acid ([1-¹⁴C]AIB), a non-metabolizable neutral amino acid analog, by dwarf bush bean plants (Phaseolus vulgaris cv Top Crop) demonstrated wide differences in active transport between various plant organs. The kinetic and timed uptake data reported were expressed as S.U. because this corrects for the diffusion of AIB which is part of the total AIB uptake process. Roots accumulated AIB to concentrations up to 18 times and leaf disks to twice those of the incubation medium. Stem tissue showed very little uptake, if any, that could not be accounted for by simple diffusion or water free space. Although initial rate kinetic studies demonstrated the presence of a normal transport system, timed uptake studies revealed greatly decreased transport by etiolated plants, suggesting a relationship between active transport and the lack of photosynthate. The reproducibility of the AIB uptake pattern by mature roots strongly supports the concept that the transport of neutral amino acids is biphasic and suggested one or more carrier systems are inducible by either low intracellular concentrations or repressed by high intracellular concentrations of the amino acid.     

Human LAT1, a subunit of system L amino acid transporter: molecular cloning and transport function

We report here on the cloning and functional characterization of human LAT1, a subunit of the amino acid transport system L. The hLAT1 cDNA, obtained from a human placental cDNA library, codes for a protein of 507 amino acids. When functionally expressed in mammalian cells together with the heavy chain of the rat 4F2 antigen (r4F2hc), hLAT1 induces the transport of neutral amino acids. When expressed independently, neither hLAT1 nor r4F2hc was capable of amino acid transport to any significant extent. Thus, the hLAT1-r4F2hc heterodimeric complex is responsible for the observed amino acid transport. The transport process induced by the heterodimer is Na+ independent and is not influenced by pH. It recognizes exclusively neutral amino acids with high affinity. LAT1-specific mRNA is expressed in most human tissues with the notable exception of the intestine.     

Derepression of amino acid transport by amino acid starvation in rat hepatoma cells.

Amino acid starvation causes an adaptive increase in the initial rate of transport of selected neutral amino acids in an established line of rat hepatoma cells in tissue culture. After a lag of 30 min, the initial rate of transport of alpha-aminoisobutyric acid (AIB) increases to a maximum after 4 to 6 h starvation of 2 to 3 times that seen in control cells. The increased rate of transport is accompanied by an increase in the Vmax and a modest decrease in the Km for this transport system, and is reversed by readdition of amino acids. The enhancement is specific for amino acids transported by the A or alanine-preferring system (AIB, glycine, proline); uptake of amino acids transported by the L or leucine-preferring system (threonine, phenylalanine, tyrosine, leucine) or the Ly+ system for dibasci amino acids (lysine) is decreased under these conditions. Amino acids which compete with AIB for transport also prevent the starvation-induced increase in AIB transport; amino acids which do not compete fail to prevent the enhancement. Paradoxically threonine, phenylalanine, tryptophan, and tyrosine, which do not compete with AIB for transport, block the enhancement of transport upon amino acid starvation. The starvation-induced enhancement of amino acid transport does not appear to be the result of a release from transinhibition. After 30 min of amino acid starvation, AIB transport is either unchanged or slightly decreased even though amino acid pools are already depleted. Furthermore, loading cells with high concentrations of a single amino acid following a period of amino acid starvation fails to prevent the enhancement of AIB transport, whereas incubation of the cells with the single amino acid for the entire duration of amino acid starvation prevents the enhancement; intracellular amino acid pools are similar under both conditions. The enhancement of amino acid transport requires concomitant RNA and protein synthesis, consistent with the view that the adaptive increase reflects an increased amount of a rate-limiting protein involved in the transport process. Dexamethasone, which dramatically inhibits AIB transport in cells incubated in amino acid-containing medium, both blocks the starvation-induced increase in AIB transport, and causes a time-dependent decrease in transport velocity in cells whose transport has previously been enhanced by starvation.     

Neutral amino acid transport in human synovial cells: substrate specificity of adaptative regulation and transinhibition

Neutral amino acid transport was characterized in human synovial cells. The amino acids tested are transported by all three major neutral amino acid transport systems, that is, A, L, and ASC. The model amino acid 2-aminoisobutyric acid (AIB) was found to be a strong specific substrate for system A in synovial cells. When cells were starved of amino acids, the activity of AIB transport increased, reaching a maximum within 1 h. The stimulation of transport activity was not blocked by cycloheximide and would thus appear to be related to a release from transinhibition. Similarly, the decrease in the activity of AIB transport observed after the addition of alpha-methyl-aminoisobutyric acid (meAIB) appeared to be related to transinhibition. However, using a different approach, that is, amino acid starvation followed by incubation with 10 mM meAIB and transfer to an amino acid-free medium with or without cycloheximide supplementation, a clear increase in AIB uptake, due both to derepression and a release from transinhibition, was observed. Unlike human fibroblasts, the depression of system A in these synovial cells was not serum-dependent. The process of derepression was observed only after preloading with meAIB. Neither AIB nor alanine produced this phenomenon. Moreover, alanine preloading led to a large increase in AIB transport activity due to a release from transinhibition. These observations indicate that the process of derepression and release from transinhibition are specific to the substrates present in the culture medium prior to amino acid starvation.     

Uterine uptake of amino acids and placental glutamine--glutamate balance in the pregnant ewe

The uterine uptake of amino acids was studied in 10 pregnant sheep with gestational ages of 114-146 days. After recovery from surgery, arterial and uterine venous samples were drawn simultaneously via indwelling catheters and analysed for amino acid and oxygen content. In seven ewes, amino acid concentrations were measured by a chromatographic technique. In four ewes, glutamate and glutamine arterio-venous differences across the uterine and umbilical circulations were measured by an enzymatic method. The uptake of neutral and basic amino acids was 66 mumol/mmol O2 and 17.3 mumol/mmol O2, respectively. Comparison of uterine and umbilical uptake shows that the bulk of the neutral and basic amino acids taken up by the pregnant uterus are transferred to the fetus. there was no significant uptake of acidic amino acids (i.e. glutamate, aspartate and taurine). glutamate was delivered from the fetus to the placenta but excretion of glutamate into the uterine circulation was negligible. Glutamine and asparagine were delivered to the fetus in amount which were two to three times larger than the placental uptake of glutamate and aspartate. Therefore placental conversion of exogenous glutamate and aspartate to glutamine and asparagine cannot account entirely for the fetal uptake of these amino acids.     

The 4F2 antigen heavy chain induces uptake of neutral and dibasic amino acids in Xenopus oocytes.

The 4F2 cell surface antigen is a disulfide-linked heterodimer induced during the process of cellular activation and expressed widely in mammalian tissues (Parmacek, M. S., Karpinski, B. A., Gottesdiener, K. M., Thompson, C. B., and Leiden, J. M. (1989) Nucleic Acids Res. 17, 1915-1931). The human heavy chain component, a type II membrane glycoprotein, has 29% identity to the amino acid transport-related protein encoded by the recently cloned rat D2 cDNA. We have demonstrated that Xenopus oocytes injected with in vitro transcribed cRNA from D2 take up cystine and dibasic and neutral amino acids (Wells, R. G., and Hediger, M. A. (1992) Proc. Natl. Acad. Sci. U. S. A. 89, 5596-5600). In the present study, we examine the role of the human 4F2 heavy chain in amino acid transport. In vitro transcribed 4F2 cRNA was injected into Xenopus oocytes which were assayed for the uptake of radiolabeled amino acids. Our results show that cRNA from 4F2 stimulates the uptake of dibasic and neutral amino acids into oocytes at levels up to 3-fold higher than for water-injected control oocytes. There is no demonstrable uptake of cystine. Uptake is saturable, with characteristics of high affinity transport, and inhibition data suggest that uptake occurs via a single transporter. Dibasic amino acids are taken up by both 4F2 and D2 cRNA-injected oocytes in a sodium-independent manner. In contrast, 4F2-induced but not D2-induced neutral amino acid uptake has a significant component of sodium dependence. Likewise, neutral amino acids in excess inhibit the 4F2-induced uptake of radiolabeled arginine but not leucine in a sodium-dependent manner. The 4F2-induced uptake we observe most likely represents the activity of a single transport system with some characteristics of systems y+, b0,+, and B0,+. We suggest that 4F2 and D2 represent a new family of proteins which induce amino acid transport with distinct characteristics, possibly functioning as transport activators or regulators.     

Hormonal regulation of hepatic amino acid transport

The transport of 2-aminoisobutyric acid (AIB) into liver tissue was increased by both insulin and glucagon. We have now shown that these hormones do not stimulate the same transport system. Glucagon, possibly via cAMP, increased the hepatic uptake of AIB by a mechanism which resembled system A. This glucagon-sensitive system could be monitored by the use of the model amino acid MeAIB. In contrast, the insulin-stimulated system exhibited little or no affinity for MeAIB and will be referred to as system B. On the basis of other reports that the hepatic transport of AIB is almost entirely Na⁺ dependent and the present finding that the uptake of 2-aminobicyclo [2,2,1] heptane-2-carboxylic acid (BCH) was not stimulated by either hormone, we conclude that system B is Na⁺ dependent. Furthermore, insulin added to the perfusate of livers from glucagon-pretreated donors suppressed the increase in AIB or MeAIB uptake. Depending upon the specificities of systems A and B, both of which are unknown for liver tissue, the insulin/glucagon ratio may alter the composition of the intracellular pool of amino acids.     

Transport and Compartmentation of 1-Aminocyclopropane-1-Carboxylic Acid and Its Structural Analog, alpha-Aminoisobutyric Acid, in Tomato Pericarp Slices

The uptakes of 1-aminocyclopropane-1-carboxylic acid (ACC), the immediate precursor to ethylene, and its structural analog, α-aminoisobutyric acid (αAIB) by tomato pericarp slices were investigated. Both uptakes show a biphasic (saturable-linear) dependence on external concentration of the transported amino acid. At low concentrations, ACC uptake is competitively inhibited by αAIB and vice versa. Both uptakes also are inhibited by other neutral amino acids but not by acidic or basic amino acids. ACC and αAIB uptakes are metabolically dependent and are increased with time of tissue incubation. αAIB efflux patterns from pericarp slices indicated three distinct αAIB compartments having efflux kinetics consistent with those for cell wall, cytoplasm, and vacuole. The bulk of the αAIB taken up by pericarp tissue is sequestered into the vacuole. The ability of pericarp tissue to accumulate αAIB in the vacuole declines with fruit development.     

The effect of prostaglandin E2 (PGE2) on amino acid uptake and protein formation by lung fibroblasts

The effect of prostaglandin E2 (PGE2) on the utilization of extracellular amino acids by fetal lung fibroblasts was examined. PGE2 decreased the uptake of proline and aminoisobutyric acid (AIB) by quiescent fibroblasts in culture. The uptake of AIB by serum-activated cultures was also dramatically decreased by PGE2. The PGE2-induced decrease in the uptake of AIB was first observed at 4 h following the addition of the effector molecule to the cultures. PGE2 did not affect the uptake of leucine. The addition of cycloheximide also resulted in a decrease in the uptake of proline, similar to that induced by PGE2 at 5 X 10(-8) M. The combination of cycloheximide and PGE2 resulted in a further decrease in proline uptake. Kinetic analysis of AIB uptake following a 24-h PGE2 treatment showed an increase in the apparent Km as compared with untreated cultures. The prostaglandin remained active for at least 72 h after the addition of the molecule. Removal of the PGE2 was followed by an influx of proline into the cells. The decrease in proline uptake was associated with a decrease in the amount of intracellular free proline and an overall decrease in the amount of cell-associated protein. While PGE2 is known to increase intracellular protein degradation, the effect of PGE2 on amino acid uptake was not the result of an increase in the intracellular concentration of amino acids (transinhibition).     

Neutral amino acid absorption by the rat epididymis

The technique of stopped-flow/split-drop microperfusion was used to study the absorption of the neutral amino acid alpha-aminoisobutyric acid (AIB) from different epididymal regions of the rat. Absorption of AIB from the lumen of the caput, corpus, and cauda was saturable and time-dependent. The apparent Km values for each of the regions studied were similar (approximately 6 mM), whereas the Vmax values were progressively higher from caput, corpus, and cauda, respectively. Absorption of AIB from the lumina of the caput, corpus, and cauda epididymidis was linear over 60 min. The absorption of AIB from the lumen of the caput was sodium-dependent and inhibitable by 2-methyl-alpha-aminoisobutyric acid (MeAIB), a specific inhibitor of neutral amino acid transport. Similarly, absorption of AIB from the lumen of the corpus epididymidis was sodium-dependent; however, uptake was not significantly reduced in the presence of MeAIB. Absorption of AIB from the lumen of the cauda epididymidis was neither sodium-dependent nor inhibitable by MeAIB. It is suggested that neutral amino acid absorption involves different transport carriers in different epididymal regions. These findings also support our previous observations that there exists a selective permeability barrier from lumen to blood along the epididymal duct.     

Aspartate-444 is essential for productive substrate interactions in a neuronal glutamate transporter

In the central nervous system, electrogenic sodium- and potassium-coupled glutamate transporters terminate the synaptic actions of this neurotransmitter. In contrast to acidic amino acids, dicarboxylic acids are not recognized by glutamate transporters, but the related bacterial DctA transporters are capable of transporting succinate and other dicarboxylic acids. Transmembrane domain 8 contains several residues that differ between these two types of transporters. One of these, aspartate-444 of the neuronal glutamate transporter EAAC1, is conserved in glutamate transporters, but a serine residue occupies this position in DctA transporters. When aspartate-444 is mutated to serine, cysteine, alanine, or even to glutamate, uptake of D-[(3)H]-aspartate as well as the inwardly rectifying steady-state currents induced by acidic amino acids is impaired. Even though succinate was not capable of inducing any steady-state transport currents, the dicarboxylic acid inhibited the sodium-dependent transient currents by the mutants with a neutral substitution at position 444. In the neutral substitution mutants inhibition of the transients was also observed with acidic amino acids. In the D444E mutant, acidic amino acids were potent inhibitors of the transient currents, whereas the apparent affinity for succinate was lower by at least three orders of magnitude. Even though L-aspartate could bind to D444E with a high apparent affinity, this binding resulted in inhibition rather than stimulation of the uncoupled anion conductance. Thus, a carboxylic acid-containing side chain at position 444 prevents the interaction of glutamate transporters with succinate, and the presence of aspartate itself at this position is crucial for productive substrate binding compatible with substrate translocation.     

Characteristics of an Uptake System for α-Aminoisobutyric Acid in Leishmania tropica Promastigotes1

ABSTRACT. Leishmania tropica promastigotes transport α-aminoisobutyric acid (AIB), the nonmetabolizable analog of neutral amino acids, against a substantial concentration gradient. AIB is not incorporated into cellular material but accumulates within the cells in an unaltered form. Intracellular AIB exchanges with external AIB. Various energy inhibitors (amytal, HOQNO, KCN, DNP, CCCP, and arsenate) and sulfhydryl reagents (NEM, pCMB, and iodoacetate) severely inhibit uptake. The uptake system is saturable with reference to AIB-and the Lineweaver-Burk plots show biphasic kinetics suggesting the involvement of two transport systems. AIB shares a common transport system with alanine, cysteine, glycine, methionine, serine, and proline. Uptake is regulated by feedback inhibition and transinhibition.