Cloning and characterization of a potassium-coupled amino acid transporter

Active solute uptake in bacteria, fungi, plants, and animals is known to be mediated by cotransporters that are driven by Na+ or H+ gradients. The present work extends the Na+ and H+ dogma by including the H+ and K+ paradigm. Lepidopteran insect larvae have a high K+ and a low Na+ content, and their midgut cells lack Na+/K+ ATPase. Instead, an H+ translocating, vacuolar-type ATPase generates a voltage of approximately -240 mV across the apical plasma membrane of so-called goblet cells, which drives H+ back into the cells in exchange for K+, resulting in net K+ secretion into the lumen. The resulting inwardly directed K+ electrochemical gradient serves as a driving force for active amino acid uptake into adjacent columnar cells. By using expression cloning with Xenopus laevis oocytes, we have isolated a cDNA that encodes a K+-coupled amino acid transporter (KAAT1). We have cloned this protein from a larval lepidopteran midgut (Manduca sexta) cDNA library. KAAT1 is expressed in absorptive columnar cells of the midgut and in labial glands. When expressed in Xenopus oocytes, KAAT1 induced electrogenic transport of neutral amino acids but excludes alpha-(methylamino)isobutyric acid and charged amino acids resembling the mammalian system B. K+, Na+, and to a lesser extent Li+ were accepted as cotransported ions, but K+ is the principal cation, by far, in living caterpillars. Moreover, uptake was Cl(-)-dependent, and the K+/Na+ selectivity increased with hyperpolarization of oocytes, reflecting the increased K+/Na+ selectivity with hyperpolarization observed in midgut tissue. KAAT1 has 634 amino acid residues with 12 putative membrane spanning domains and shows a low level of identity with members of the Na+ and Cl(-)-coupled neurotransmitter transporter family.     

Changes in membrane and surface potential explain the opposite effects of low ionic strength on the two lysine transporters of human erythrocytes

The sucrose-induced stimulation of lysine influx in human erythrocytes has been attributed to the removal of a competitive inhibition exerted by Na+ on system y+ (Young, J. D., Fincham, D. A., and Harvey, C. M. (1991) Biochim. Biophys. Acta 1070, 111-118). We have reexamined this phenomenon separating the contribution of the two cationic amino acid transporters present in these cells (system y+ and system y+L). NaCl replacement with sucrose increased influx through system y+L, but decreased influx through system y+. We conclude that 1) the inhibition of system y+ is a response to the membrane depolarization that results from chloride removal, and 2) the stimulation of system y+L is due to the enhancement of the negative surface potential. Consistently, lysine influx through system y+L (in sucrose medium) was reduced by Na+, K+, Li+, and choline (K0.5 = 25-34 mM), the effect reaching a maximum at 35-40% of the original flux. Divalent cations (Ca2+ and Mg2+) were also inhibitory, but lower concentrations were required (K0.5 1.1-1.8 mM). The finding that sucrose stimulates uptake through changes in the surface potential explains similar effects observed in other cells with various cationic substrates.     

Luminal transport system for choline+ in relation to the other organic cation transport systems in the rat proximal tubule. Kinetics, specificity: alkyl/arylamines, alkylamines with OH, O, SH, NH2, ROCO, RSCO and H2PO4-groups, methylaminostyryl, rhodamine, acridine, phenanthrene and cyanine compounds

The efflux of [3H] choline+ from the proximal tubular lumen was measured by using the stop-flow microperfusion method. The 2-s efflux of [3H] choline+ follows kinetics with a Michaelis constant, Km = 0.18 mmol x l-1, maximal flux, Jmax = 0.43 pmol x cm-1 x s-1 and a permeability term = 38.0 micron2 small middle dots-1. Replacement of Na+ by N-methyl-D-glucamine+ or Li+, or a change of luminal pH do not alter choline+ efflux. Replacement of Na+ by Cs+ inhibits 2-s choline+ (0. 01 mmol x l-1) efflux by 22% and replacement by K+ inhibits by 49%, indicating that the electrical potential difference across the brush border membrane acts as driving force for choline+ transport. Comparing the apparent luminal inhibitory constant values for choline (app. Ki,l,choline+) with the chemical structure of inhibiting substrates, it was found that the inhibitory potency of amines with high pKa values, i.e. high basicity, and of quaternary ammonium compounds (tetraethyl to tetrahexylammonium) increases with their hydrophobicity in a similar manner as was observed previously against the contraluminal N1-methylnicotinamide (NMeN+) transporter and the luminal H+/organic cation (N-methyl-4-phenylpyridinium) (MPP+) exchanger. Independently of their hydrophobicity, an increase in the inhibitory potency of the homologous series of aminoquinolines against the choline+ transporter was observed with increasing pKa values, i.e. increasing basicity, as was found previously against the two other organic cation transporters. A third parameter influencing the interaction with the choline+ transporter is the presence of two amino groups with high pKa values or one amino group and a permanent positive charge, as is documented with the two-ring aminostyryl and rhodamine compounds, as well as three-ring aminoacridine, aminophenanthrene and cyanine compounds. Thus with the aminostyryl, pyridinium+, rhodamine, phenanthridium+ and cyanine+ dyes app.Ki,l,choline+ values of between 0.01 and 0.07 mmol x l-1 have been found. A fourth parameter influencing the choline+ transporter is the presence of an OH group on the C atom next to that bearing the N atom (as in choline+) or an ester-OCOR group (acetylcholine+, butyrylcholine+) or a thioester-SCOR-group (acetylthiocholine+, butyrylthiocholine+); or an -OP(OH)2(OR) group (glycerylphosphoryl-choline+), resulting in app.Ki,l,choline+ values of 0.3-1.0 mmol x l-1. Thus the substrates for the luminal choline+ transporter have general features in common with the luminal H+/organic cation exchanger and the contraluminal organic cation transporter, i.e. hydrophobicity and basicity. Additional parameters for interaction are an OH (or similar) group positioned a favourable distance from the N atom or a second amino/ammonium group in multi-ring compounds.     

New concepts in anionic and cationic amino acid transport]

In mammalian cells, amino acids are taken up by different transport systems present in the plasma membrane. The transport systems were originally characterized by kinetic and competition studies. However, it was difficult to assign specific amino acids to specific transport systems. With recent advances in molecular biology, it has been possible to identify the specific transporter proteins for specific amino acids. In this review we describe the anionic and cationic amino acid transport systems reported at the molecular level. The anionic amino acids are movilized mainly by the XaG- and Xc- systems which are important in the inactivation of glutamatergic nervous transmission in the brain and for the synthesis of glutathione, respectively. Four isoforms of the XAG- system in the brain belong to the family of Na+ dependent amino acid transporters. Transport systems for cationic amino acids also recognize zwitterionic substrates, and the better characterized systems at the present time are y+, y+L, bo,+ and Bo,+. The regulation of the entrance of cationic amino acid such as arginine, lysine, and ornithine to the cell is important in the biosynthesis of nitric oxide, creatine, carnitine, and polyamines. An inherited defect associated to bo,+ system is cysteinuria.     

A conserved aspartate residue, Asp187, is important for Na+-dependent proline binding and transport by the Na+/proline transporter of Escherichia coli

Asp187 in the Na+/proline transporter of Escherichia coli (PutP) is conserved within the Na+/solute cotransporter family. Information on the role of this residue has been gained by amino acid substitution analysis. PutP with Glu, Asn, or Cys in place of Asp187 catalyzed Na+-coupled proline uptake at 75%, 25%, and 1.5%, respectively, of the Vmax of PutP-wild-type while the apparent Km for proline was only slightly altered. Importantly, acetylation or amidoacetylation of an engineered transporter containing a single Cys at position 187 stimulated proline uptake. Strikingly, PutP-D187C exhibited high-affinity proline binding even at very low Na+ concentrations (2 microM) while proline binding to PutP-wild-type, -D187E, and -D187N was strictly dependent on the Na+ concentration. The apparent independence of proline binding from the Na+ concentration can at least partially be attributed to an enhanced Na+ affinity of PutP-D187C. In addition, reaction of PutP containing a single Cys at position 187 with N-ethylmaleimide was inhibited by Na+ but not by Li+ or proline. The results indicate that electrostatic interactions of the amino acid side chain at position 187 in PutP with other parts of the transporter and/or the coupling ion are crucial for active proline transport. It is suggested that Asp187 is located close to the pathway of the coupling ion through the membrane and may be involved in the release of Na+ on the cytoplasmic side of the membrane.     

Statistical models of outcome in malpractice lawsuits involving death or neurologically impaired infants

Synaptosomes prepared from mouse brain possess a Na+-dependent transport system for gamma-hydroxybutyrate displaying saturation kinetics, the transport constant (Kt) for which was calculated as 31 +/- 9 micromol/l. Several gamma-hydroxybutyrate and gamma-aminobutyric acid (GABA) structural analogues were tested as potential inhibitors of gamma-hydroxybutyrate transport. The most effective inhibitor was harmaline (Ki = 94 +/- 21 micromol/l), a known competitive inhibitor of Na+ binding to certain transport proteins. 2-Hydroxycinnamic acid, 3-(2-furyl)acrylic acid and citrazinic acid also inhibited transport and were competitive with respect to gamma-hydroxybutyrate. The least effective gamma-hydroxybutyrate analogues were 3-hydroxypropane sulfonic acid (Ki = 4.1 +/- 0.8 mmol/l) 3,5-dihydroxybenzoic acid (Ki = 6.1 +/- 2. 8 mmol/l) and 3-hydroxybenzoic acid (Ki = 6.9 +/- 3.3 mmol/l), although 2-hydroxypropane sulfonic acid and kynurenic acid had no measurable effects. Four inhibitors of GABA transport - nipecotic acid, guvacine, ketamine and beta-alanine and GABA itself, were without effect on gamma-hydroxybutyrate transport. These results show that certain drugs that structurally resemble gamma-hydroxybutyrate have the capacity to compete with gamma-hydroxybutyrate at its recognition site on the transporter. By examining the structure of such inhibitors, we can learn more about the properties of the substrate binding site on the carrier protein. Moreover, the absence of inhibition by GABA uptake inhibitors shows that gamma-hydroxybutyrate transport is a separate entity from GABA transport.     

Charge translocation by the Na+/K+-ATPase investigated on solid supported membranes: cytoplasmic cation binding and release

In the preceding publication (. Biophys. J. 76:000-000) a new technique was described that was able to produce concentration jumps of arbitrary ion species at the surface of a solid supported membrane (SSM). This technique can be used to investigate the kinetics of ion translocating proteins adsorbed to the SSM. Charge translocation of the Na+/K+-ATPase in the presence of ATP was investigated. Here we describe experiments carried out with membrane fragments containing Na+/K+-ATPase from pig kidney and in the absence of ATP. Electrical currents are measured after rapid addition of Na+. We demonstrate that these currents can be explained only by a cation binding process on the cytoplasmic side, most probably to the cytoplasmic cation binding site of the Na+/K+-ATPase. An electrogenic reaction of the protein was observed only with Na+, but not with other monovalent cations (K+, Li+, Rb+, Cs+). Using Na+ activation of the enzyme after preincubation with K+ we also investigated the K+-dependent half-cycle of the Na+/K+-ATPase. A rate constant for K+ translocation in the absence of ATP of 0.2-0.3 s-1 was determined. In addition, these experiments show that K+ deocclusion, and cytoplasmic K+ release are electroneutral.     

Sodium and lithium interactions with the Na+/Dicarboxylate cotransporter

The two-electrode voltage clamp was used to study the currents associated with transport of succinate by the cloned Na+/dicarboxylate cotransporter, NaDC-1, expressed in Xenopus oocytes. The presence of succinate induced inward currents which were dependent on the concentrations of succinate and sodium, and on the membrane potential. At -50 mV, the K0.5succinate was 180 microM and the K0.5Na+ was 19 mM. The Hill coefficient was 2.3, which is consistent with a transport stoichiometry of 3 Na+:1 divalent anion substrate. Currents were induced in NaDC-1 by a range of di- and tricarboxylates, including citrate, methylsuccinate, fumarate, and tricarballylate. Although Na+ is the preferred cation, Li+ was also able to support transport. The K0.5succinate was approximately 10-fold higher in Li+ compared with Na+. In the presence of Na+, however, Li+ was a potent inhibitor of transport. Millimolar concentrations of Li+ resulted in decreases in apparent succinate affinity and in the Imaxsuccinate. Furthermore, lithium inhibition under saturating sodium concentrations showed hyperbolic kinetics, suggesting that one of the three cation binding sites in NaDC-1 has a higher affinity for Li+ than Na+. We conclude that NaDC-1 is an electrogenic anion transporter that accepts either Na+ or Li+ as coupling cations. However, NaDC-1 contains a single high affinity binding site for Li+ that, when occupied, results in transport inhibition, which may account for its potent inhibitory effects on renal dicarboxylate transport.     

Transporters for cationic amino acids in animal cells: discovery, structure, and function

The structure and function of the four cationic amino acid transporters identified in animal cells are discussed. The systems differ in specificity, cation dependence, and physiological role. One of them, system y+, is selective for cationic amino acids, whereas the others (B[0,+], b[0,+], and y+ L) also accept neutral amino acids. In recent years, cDNA clones related to these activities have been isolated. Thus two families of proteins have been identified: 1) CAT or cationic amino acid transporters and 2) BAT or broad-scope transport proteins. In the CAT family, three genes encode for four different isoforms [CAT-1, CAT-2A, CAT-2(B) and CAT-3]; these are approximately 70-kDa proteins with multiple transmembrane segments (12-14), and despite their structural similarity, they differ in tissue distribution, kinetics, and regulatory properties. System y+ is the expression of the activity of CAT transporters. The BAT family includes two isoforms (rBAT and 4F2hc); these are 59- to 78-kDa proteins with one to four membrane-spanning segments, and it has been proposed that these proteins act as transport regulators. The expression of rBAT and 4F2hc induces system b[0,+] and system y+ L activity in Xenopus laevis oocytes, respectively. The roles of these transporters in nutrition, endocrinology, nitric oxide biology, and immunology, as well as in the genetic diseases cystinuria and lysinuric protein intolerance, are reviewed. Experimental strategies, which can be used in the kinetic characterization of coexpressed transporters, are also discussed.     

Effect of extracellular pH on the myo-inositol transporter SMIT expressed in Xenopus oocytes

The myo-inositol transporter SMIT is expressed particularly at high extracellular osmolarity and serves to accumulate the osmolyte myo-inositol. Transport of myo-inositol is coupled to the cotransport of Na+ and is electrogenic. In Xenopus oocytes injected with mRNA encoding SMIT but not in water-injected oocytes, myo-inositol creates an inward current that is dependent on the ambient Na+ concentration. The present study has been performed to elucidate the pH dependence of myo-inositol-induced currents. Therefore, Xenopus oocytes were injected with mRNA encoding SMIT and two-electrode voltage-clamp studies were performed. The myo-inositol-induced currents in oocytes expressing SMIT were found to have a sigmoidal dependence on the ambient pH between pH 5.5 and 8.5 with an apparent Ki of 0.21+/-001 microM H+ and a Hill coefficient of 1.80+/-0.16. Kinetic analysis of the myo-inositol-induced currents at pH 8.0 and -90 mV holding potential revealed a Hill coefficient of 0.93+/-0.07 and an apparent Km for myo-inositol of 0.031+/-0.003 mM as well as a Hill coefficient of 1. 64+/-0.24 and an apparent Km of 38.8+/-4.1 mM for Na+. A decrease of the Na+ concentra-tion from 150 mM to 50 mM significantly altered the maximal observed current and increased the apparent Km for myo-inositol. Acidification to pH 6.5 significantly increased the apparent Km for myo-inositol and for Na+ to 0.057+/-0.005 mM and 73. 9+/-4.8 mM, respectively. The Hill coefficients for myo-inositol and Na+ were not affected and remained close to 1 for myo-inositol and 2 for Na+. In summary, acidification impedes SMIT-mediated myo-inositol transport at least partially by decreasing the affinity of the carrier for Na+. The impaired Na+ binding subsequently decreases binding and transport of myo-inositol.     

Glutamate uptake stimulates Na+,K+-ATPase activity in astrocytes via activation of a distinct subunit highly sensitive to ouabain

The excitatory amino acid glutamate was previously shown to stimulate aerobic glycolysis in astrocytes by a mechanism involving its uptake through an Na+-dependent transporter. Evidence had been provided that Na+,K+-ATPase might be involved in this process. We have now measured the activity of Na+,K+-ATPase in cultured astrocytes, using ouabain-sensitive 86Rb uptake as an index. L-Glutamate increases glial Na+,K+-ATPase activity in a concentration-dependent manner with an EC50 = 67 microM. Both L- and D-aspartate, but not D-glutamate, produce a similar response, an observation that is consistent with an uptake-related effect rather than a receptor-mediated one. Under basal conditions, concentration-dependent inhibition of Na+,K+-ATPase activity in astrocytes by ouabain indicates the presence of a single catalytic site with a low affinity for ouabain (K0.5 = 113 microM), compatible with the presence of an alpha1 isozyme. On stimulation with glutamate, however, most of the increased activity is inhibited by low concentrations of ouabain (K0.5 = 20 nM), thus revealing a high-affinity site akin to the alpha2 isozyme. These results suggest that astrocytes possess a glutamate-sensitive isoform of Na+,K+-ATPase that can be mobilized in response to increased neuronal activity.     

Solute transport across the tonoplast of barely mesophyll vacuoles: Mg2+ determines the specificity, and ATP lipophilic amino acids the activity of the amino acid carrier

After stimulation with ATP and in the absence of divalent cations, isolated barely mesophyll vacuoles exhibited massive solute fluxes across the tonoplast, measured either as efflux of endogenous solutes or as uptake of radioactive-labeled compounds. Transported solutes were ions (particularly K+, NO3-, Cl-) and amino acids (for example, ala, arg, asp, gln, leu, met). Addition of Mg2+ in excess of added ATP inhibited fluxes of inorganic ions and of positively charged amino acids, but not, or to a smaller extent, those of neutral amino acids. Thus, Mg2+ increased the specificity of the carrier for amino acids such as alanine and glutamine. All ATP-stimulated transport processes were sensitive towards inhibition by lipophilic amino acids, for example by leucine and phenylalanine. After stimulation with sulfhydryl reagents, the inhibitory properties of Mg2+ and lipophilic amino acids were lost. These data concur with the hypothesis of a single transporter which exhibits a channel-like structure with a low degree of substrate selectivity in the absence of Mg2+, and which functions as a neutral amino acid carrier in the presence of Mg2+.     

Cations affect [3H]mazindol and [3H]WIN 35,428 binding to the human dopamine transporter in a similar fashion

The present study addresses the possibility that there are different cocaine-related and mazindol-related binding domains on the dopamine transporter (DAT) that show differential sensitivity to cations. The effects of Zn2+, Mg2+, Hg2+, Li+, K+, and Na+ were assessed on the binding of [3H]mazindol and [3H]WIN 35,428 to the human (h) DAT expressed in C6 glioma cells under identical conditions for intact cell and membrane assays. The latter were performed at both 0 and 21 degrees C. Zn2+ (30-100 microM) stimulated binding of both radioligands to membranes, with a relatively smaller effect for [3H]mazindol; Mg2+ (0.1-100 microM) had no effect; Hg2+ at approximately 3 microM stimulated binding to membranes, with a relatively smaller effect for [3H]mazindol than [3H]WIN 35,428 at 0 degrees C, and at 30-100 microM inhibited both intact cell and membrane binding; Li+ and K+ substitution (30-100 mM) inhibited binding to membranes more severely than to intact cells; and Na+ substitution was strongly stimulatory. With only a few exceptions, the patterns of ion effects were remarkably similar for both radioligands at both 0 and 21 degrees C, suggesting the involvement of common binding domains on the hDAT impacted similarly by cations. Therefore, if there are different binding domains for WIN 35,428 and mazindol, these are not affected differentially by the cations studied in the present experiments, except for the stimulatory effect of Zn2+ at 0 and 21 degrees C and Hg2+ at 0 degrees C.     

N-system amino acid transport at the blood--CSF barrier

Despite L-glutamine being the most abundant amino acid in CSF, the mechanisms of its transport at the choroid plexus have not been fully elucidated. This study examines the role of L-, A-, ASC-, and N-system amino acid transporters in L-[14C]glutamine uptake into isolated rat choroid plexus. In the absence of competing amino acids, approximately half the glutamine uptake was via a Na(+)-dependent mechanism. The Na(+)-independent uptake was inhibited by 2-amino-2-norbornane carboxylic acid, indicating that it is probably via an L-system transporter. Na(+)-dependent uptake was inhibited neither by the A-system substrate alpha-(methylamino)isobutyric acid nor by the ASC-system substrate cysteine. It was inhibited by histidine, asparagine, and L-glutamate gamma-hydroxamate, three N-system substrates. Replacement of Na+ with Li+ had little effect on uptake, another feature of N-system amino acid transport. These data therefore indicate that N-system amino acid transport is present at the choroid plexus. The Vmax and Km for glutamine transport by this system were 8.1 +/- 0.3 nmol/mg/min and 3.3 +/- 0.4 mM, respectively. This system may play an important role in the control of CSF glutamine, particularly when the CSF glutamine level is elevated as in hepatic encephalopathy.     

The low-affinity dihydropyridine receptor and Na+/Ca2+ exchanger are associated in adrenal medullary mitochondria

The effect of Ca2+ channel-acting drugs on bovine adrenal mitochondria Ca2+ movements was investigated. Mitochondrial Ca2+ uptake is performed by an energy-driven Ca2+ uniporter with a Km of 20.9 +/- 3.2 microM and Vmax of 148.1 +/- 7.2 nmol 45Ca2+ min-1 mg-1. Ca2+ release is performed through an Na+/Ca2+ antiporter with a Km for Na+ of 4.2 +/- 0.5 mM, a Vmax of 7.5 +/- 0.4 nmol 45Ca2+ min-1 mg-1, and a Hill coefficient of 1.4 +/- 0.2 Ca2+ efflux through the mitochondrial Na+/Ca2+ exchanger was inhibited by several dihydropyridines (nitrendipine, felodipine, nimodipine, (+)isradipine) and by the benzothiazepine diltiazem with similar potencies. In contrast, neither CGP 28392, Bay-K-8644, amlodipine, nor verapamil had any effect on Ca2+ efflux. Nitrendipine at 20 microM modified neither the Km nor the Hill coefficient for Na+, whereas the Vmax was reduced to 2.9 nmol 45Ca2+ min-1 mg-1, thus demonstrating noncompetitive modulation of the Na+/Ca2+ exchanger. None of the Ca2+ channel-acting drugs assayed at 100 microM affected Ca2+ influx through the uniporter. Ca2+ channel blockers inhibited the Na+/Ca2+ antiporter and displaced the specific binding of [3H]nitrendipine to intact mitochondria with Ki values similar to the IC50s obtained for the inhibition of the Ca2+ efflux. Ca2+ channel-acting drugs that did not inhibit the Na+/Ca2+ exchanger (amlodipine, CGP 28392, Bay-K-9644, and verapamil, at concentrations of 100 microM or higher) had no effect on [3H]nitrendipine binding. These results suggest that the adrenomedullary mitochondrial dihydropyridine receptor is associated with the Na+/Ca2+ exchanger.     

Effects of ecotropic murine retroviruses on the dual-function cell surface receptor/basic amino acid transporter

The widely expressed Na(+)-independent transporter for basic amino acids (system y+) is the cell surface receptor (ecoR) for ecotropic host-range mouse retroviruses (murine leukemia viruses (MuLVs)), a class of retroviruses that naturally infects only mice or rats. Accordingly, expression of mouse ecoR cDNA in mink CCL64 fibroblasts yields cells (CEN cells) that have y+ transporter activity above the endogenous background and that bind and are infected by ecotropic MuLVs. The effect of ecotropic MuLV infection on expression of y+ transporter was analyzed in mouse and in mink CEN fibroblasts. Chronic infection with ecotropic MuLVs caused 50-70% loss (down-modulation) of mouse y+ transporter in plasma membranes, detected as a reduced Vmax for uptake and outflow of L-[3H]arginine with no effect on Km values. Down-modulation was specific for mouse y+ and did not affect other transporters or the endogenous mink y+, suggesting that it results from specific interaction between mouse y+ and the viral envelope glycoprotein gp70 in the infected cells. Because this partial loss of mouse y+ from cell surfaces is insufficient to explain the complete interference to superinfection that occurs in cells chronically infected with ecotropic MuLVs, alternative explanations for interference are proposed. In contrast to the y+ down-modulation caused by chronic infection, binding of extracellular envelope glycoprotein gp70 at 37 degrees C resulted in noncompetitive inhibition of amino acid import by mouse y+ but had no effect on export through this same transporter or on any transporter properties of mink y+. The effects of gp70 on transport kinetics suggest that it slows the rate-limiting step of the amino acid import cycle, a conformational transition of the empty transporter in which the binding site moves from the inside back to the outside of the cell, and that gp70 has no effect on the rate-limiting step of the amino acid export cycle. Infected cells retain substantial y+ activity. Moreover, the virus binding site on ecoR is in a mobile region that changes conformation during the amino acid transport cycle.     

电渗析法从磷酸铁生产母液中分离杂质金属离子

以各种回收的资源(磷酸铁锂正极粉、钛白副产品硫酸亚铁等)为原料生产磷酸铁时,产生的磷酸母液会逐渐富集Li⁺、Na⁺、Ca²⁺、Mg²⁺、Mn²⁺、Ni²⁺、Al³⁺等金属离子杂质,需要分离金属离子,以便磷酸回用。采用电渗析法对磷酸母液进行净化除杂,并探索了电流密度对除杂效率的影响。结果表明,在较合理的工艺参数长期运行的条件下,各杂质离子的去除率为(%):Li⁺41.18、Na⁺54.55、Ca²⁺64.29、Mg²⁺54.02、Mn²⁺35.71、Ni²⁺46.38、Al³⁺16.67,除杂后的磷酸母液可重新用于磷酸铁的生产,避免了磷资源的损失。电流密度的增加会增加电耗,降低电流效率,而在电解液替换流量与电流量的比相同的条件下,杂质去除率也会降低。较优的运行电流密度为2 A/dm     

Interrelationship between the transport of L-aspartate and potassium ions into the cell (author's transl)

The mechanisms involved in active transport and intracellular accumulation of amino acids have been reviewed. In particular, the frequently observed interrelationship between the transport of acidic amino acids and potassium ions was discussed. Kinetic studies on the uptake of radioactive L-aspartate and K+ in the microorganism Streptomyces hydrogenans were performed. The following results were obtained:1. L-Aspartate was actively transported into the cells. However, only a part of the aspartate taken up from the medium remained in the pool as free amino acid. Within 60 min, up to 35% of the label was incorporated into protein. By thin-layer chromatography of cell extracts several radioactive metabolites of aspartate were detected. 2. Aspartate was transported by a t least two different uptake systems exhibiting moderate specificity. At neutral pH , the amino acid was transported as anion; its uptake was inhibited by L-glutamate as well as by dicarboxylic acids, whereas neutral amino acids did not have a significant effect. 3. The influx of aspartate into K+-rich cells was stimulated specifically by extracellular Rb+ and K+, whereas Ki+ and Na+ inhibited aspartate transport. 4. Kinetic analysis of the aspartate influx showed that extracellular K+ increased the affinity of the transport systems for aspartate by a factor of three. These results suggest that K+ is bound by the aspartate carrier and is cotransported together with the amino acid across the membrane. 5. Kinetic measurements of the uptake of 42K+ revealed that the influx of K+ as well was stimulated by extracellular aspartate. Likewise the rate of 28Mg2+ uptake was increased by aspartate.