The binding and translocation steps in transport as related to substrate structure. A study of the choline carrier of erythrocytes.

The relationships between structure, affinity and transport activity in the choline transport system of erythrocytes have been investigated in order to (i) explore the nature of the carrier site and its surroundings, and (ii) determine the dependence of the carrier reorientation process on binding energies and steric restraints due to the substrate molecule. Affinity constants and maximum transport rates for a series of trialkyl derivatives of ethanolamine were obtained by a method that involves measuring the trans effect of unlabeled analogs upon the movement of radioactive choline. The main conclusions are as follows: (1) An analysis of transport kinetics shows that the affinity constants determined experimentally differ from the actual dissociation constants in a predictable way. The better the substrate, the higher the apparent affinity relative to the true value, whereas the affinity of non-transported inhibitiors is underestimated by a constant factor. (2) The carrier-choline complex undergoes far more rapid reorientation (translocation) than the free carrier. (3) The carrier imposes a strict upper limit upon the size of a substrate molecule that can participate in the carrier reorientation process; this limit corresponds to the choline structure. A smaller substrate such as tetramethylammonium, despite relatively weak binding forces , is unhindered in its translocation, suggesting that a carrier conformational change, dependent upon substrate binding energy, is not required for transport. (4) Small increases in the size of the quaternary ammonium head, as in triethylcholine, sharply lower affinity, consistent with a high degree of specificity for the trimethylammonium group. (5) Lengthening the alkyl substituent in derivatives of dimethyl- and diethylaminoethanol causes a regular increase in affinity, suggestive of unspecific hydrophobic bonding in a region very near the substrate site.     

Ligand-protein interaction in biomembrane carriers. The induced transition fit of transport catalysis

Carrier-linked transport through biomembranes is treated under the view of catalysis. As in enzymes, substrate-protein interaction yields catalytic energy in overcoming the activation barrier. At variance with enzymes, catalytic energy is concentrated on structural changes of the carrier rather than on the substrate destabilization for facilitating the global protein rearrangements during transport. A transition state is invoked in which the binding site assumes the best fit to the substrate, whereas in the two ground (internal and external) states, the fit is poor. The maximum binding energy released in the transition state provides catalytic energy to enable the large carrier protein transformations associated with transport. This "induced transition fit" (ITF) of carrier catalysis provides a framework of rules, concerning specificity, unidirectional versus exchange type transport, directing inhibitors to the ground state instead of the transition state, and excluding simultaneous chemical and transport catalysis (vectorial group translocation). The possible role of external energy sources (ATP and Deltapsi) in supplementing the catalytic energy is elucidated. The analysis of the structure-function relationship based on new carrier structures may be challenged to account for the workings of the ITF.     

Interaction of a permeant maleimide derivative of cysteine with the erythrocyte glucose carrier. Differential labelling of an exofacial carrier thiol group and its role in the transport mechanism.

S-(Bismaleimidomethyl ether)cysteine (Cys-Mal) was synthesized as a probe for reactive thiol groups on the erythrocyte glucose carrier. Although Cys-Mal entered cells, its reaction with intracellular GSH prevented alkylation of endofacial membrane proteins, limiting its effect to the cell surface at concentrations below 5 mM. Cys-Mal irreversibly inhibited hexose transport half-maximally at 1.5 mM by decreasing the maximal rate of transport, with no effect on the affinity of substrate for the carrier. Reaction occurred with the outward-facing form of the carrier, but did not affect the ability of the carrier to change orientation. In intact cells, several exofacial proteins were labelled by [35S]Cys-Mal, including the band-4.5 glucose carrier, the labelling of which occurred on a single site sensitive to transport inhibitors. The reactive exofacial group was a thiol group, since both transport inhibition and band-4.5 labelling by Cys-Mal were abolished by the thiol-specific and impermeant compound 5,5'-dithiobis(2-nitrobenzoic acid). Selectivity for carrier labelling in cells was increased by a double differential procedure, which in turn allowed localization of the exofacial thiol group to the Mr 18,000-20,000 membrane-bound tryptic carrier fragment. In protein-depleted ghosts the exofacial thiol group was preferentially labelled at low concentrations of [35S]Cys-Mal, whereas with the reagent at 10 mM the Mr 26,000-45,000 tryptic carrier fragment was also labelled. Cys-Mal should be useful in the study of carrier thiol-group location and function.     

Co-operativity in seminal ribonuclease function. Kinetic studies.

Maltose-maleimide was synthesized as a potential affinity label for the facilitative hexose carrier with selectivity for exofacial sulphydryl groups. This reagent, although probably a mixture of isomers, did not significantly penetrate the plasma membrane of human erythrocytes at concentrations below 5 mM at 37 degrees C. When allowed to react to completion, it irreversibly inhibited the uptake of 3-O-methylglucose, with a half-maximal response at about 1.5-2.0 mM-reagent. The rate of transport inactivation was a saturable function of the maltose-maleimide concentration. Studies of reaction kinetics and effects of known transport inhibitors demonstrated that irreversible reaction occurred on the exofacial outward-facing carrier, although not at a site involved in substrate binding. Reaction of intact erythrocytes with [14C]maltose-maleimide resulted in labelling of a broad band 4.5 protein of Mr (average) 45,000-66,000 in electrophoretic gels. This protein was very likely the hexose carrier, since its labelling was inhibited by cytochalasin B. Exofacial band 4.5 labelling was stoichiometric with respect to transport inhibition, yielding an estimated 300,000 carriers/cell. These results suggest that the exofacial sulphydryl which reacts with maltose-maleimide is distinct from the substrate binding site on the hexose carrier, but that it confers substantial labelling selectivity to impermeant maleimides. Additionally, the high efficiency of carrier labelling obtained with maltose-maleimide is useful in quantifying numbers of carriers in whole cells.     

Canalicular transport of reduced glutathione in normal and mutant Eisai hyperbilirubinemic rats.

We have characterized the transport of GSH and the mechanism for impaired GSH transport in mutant Eisai hyperbilirubinemic rats (EHBR) using isolated canalicular membrane-enriched vesicles (cLPM). In control animals, the transport of GSH is an electrogenic process and is trans-stimulated by preloading the vesicles with GSH and is not enhanced in the presence of ATP. GSH transport in cLPM is saturable with a single component having a Km of approximately 16 mM and a Vmax of 6.7 nmol/mg/15 s. EHBR is a Sprague-Dawley rat with hyperbilirubinemia due to impaired bile secretion of organic anions by the ATP-dependent organic anion/GSH-conjugate transporter. In cLPM from EHBR we confirmed the defective stimulation by ATP of the transport of LTC4 and GSSG. In the mutant cLPM, the characteristics and kinetics of GSH transport were the same as in the controls. 2,4-(dinitrophenyl)-glutathione (DNP-GSH), which is a substrate for the ATP-dependent canalicular organic anion carrier, in the absence of ATP, cis-inhibited the transport of GSH into cLPM vesicles; however, when the vesicles were preloaded with DNP-GSH, there was a dose-dependent trans-stimulation of GSH transport. In contrast, in the presence of ATP, DNP-GSH enhanced GSH transport in cLPM vesicles; at 0.25 mM DNP-GSH, a concentration which did not cis-inhibit GSH, addition of ATP resulted in accelerated GSH transport; at 1.0 mM DNP-GSH, cis-inhibition was completely reversed by the addition of ATP despite a negligible fall in the medium DNP-GSH. Interestingly, sulfobromophthalein-glutathione (BSP-GSH) neither cis-inhibited nor trans-stimulated GSH transport in cLPM. This contrasts with bLPM where BSP-GSH interacts with the GSH carrier. Therefore, GSH is transported into bile by a multispecific low affinity electrogenic carrier which is distinct from the multispecific high affinity ATP-driven organic anion transporter. Although both carriers have overlapping specificities, BSP-GSH and GSH are uniquely specific for only one of the carriers. The near absence of GSH in the bile of mutant rats can be best explained as a secondary defect due to cis-inhibition from retained substrates for the defective carrier and/or loss of trans-stimulation by these same substrates which normally are concentratively transported into the bile. Other possibilities such as change in GSH carrier activity upon isolation or loss of a negative protein regulator during membrane isolation, although theoretical alternatives are less easily reconciled with the defect in the ATP-driven organic anion transporter.     

Adenine and hypoxanthine transport in human erythrocytes: distinct substrate effects on carrier mobility.

Transport of adenine and hypoxanthine in human erythrocytes proceeds via two mechanisms: (1) a common carrier for both nucleobases and (2) unsaturable permeation 4-5-fold faster for adenine for hypoxanthine. The latter process was resistant to inactivation by diazotized sulfanilic acid. Carrier mediated transport of both substrates was investigated using zero-trans and equilibrium exchange protocols. Adenine displayed a much higher affinity for the carrier (Km approximately 5-8 microM) than hypoxanthine (Km approximately 90-120 microM) but maximum fluxes at 25 degrees C were generally 5-10-fold lower for adenine (Vmax approximately 0.6-1.4 pmol/microliters per s) than for hypoxanthine (Vmax approximately 9-11 pmol/microliters per s). The carrier behaved symmetrically with respect to influx and efflux for both substrates. Adenine, but not hypoxanthine reduced carrier mobility more than 10-fold. The mobility of the unloaded carrier, calculated from the kinetic data of either hypoxanthine or adenine transport, was the same thus providing further evidence that these substrates share a common transporter and that their membrane transport is adequately described by the alternating conformation model of carrier-mediated transport.     

Transport of sugars and amino acids in bacteria. XVIII. Properties of an isoleucine carrier in the cytoplasmic membrane vesicles of Escherichia coli.

The properties of the carrier for isoleucine in Escherichia coli were studied using cytoplasmic membrane vesicles (IM vesicles) prepared by the method of Yamato, Anraku, and Hirosawa (J. Biochem. 77, 705 (1975)). The IM vesicles exhibited respiration-dependent isoleucine transport activity which was more than 30-fold higher than that of "Kaback vesicles" prepared by our hand from the same strains of E. coli K12. The isoleucine carrier activity of IM vesicles was inhibited by norleucine but not by threonine. The carrier was driven by proton motive force. Mutants were isolated which had lost the carrier activity for isoleucine, as judged by assay with IM vesicles. Using these mutants, the effects of binding proteins specific for branched chain amino acids on the translocation of substrate in IM vesicles were studied. Leucine-isoleucine-valine-threonine-binding protein (LIVT-binding protein) stimulated the initial rate of isoleucine uptake by IM vesicles only when the vesicles possessed carrier activity and it did not affect the Kt value for entry of substrate. This evidence suggests the partial reconstitution of the osmotic shock-sensitive transport reaction in which the binding protein seems to affect the carrier activity with turnover ability.     

Coupling in secondary transport. Effect of electrical potentials on the kinetics of ion linked co-transport.

In a previous paper kinetic equations of secondary active transport by cotransport have been derived. In the present paper these equations have been expanded by including the effect of an electrical potential difference in order to make them applicable to the more realistic systems of secondary active transport driven by the gradients of Na+ or H+. Thermodynamically an electrical potential difference is as a driving force fully exchangeable with an equivalent chemical potential difference. This is not necessarily so for the kinetics of co-transport. It is not always the same whether a given difference in electrochemical activity of the driver ion is mainly osmotic, i.e. due to difference in concentration, or electric, i.e. due to a difference in the electrochemical activity coefficient. In most cases a difference in concentration is more effective in driving co-transport than is an equivalent difference in electrical potential leading to the same difference in electrical activity. The effectiveness of the latter highly depends on the model, whether it is of the affinity type or of the velocity type, but also on whether the loaded or the unloaded carrier bears an electrical charge. With the same electrical potential difference co-transport is as a rule faster if the ternary complex rather than the empty carrier is charged. Also the "standard parameters", (see Glossary, page 62) Jmax and Km, of the overall transport respond differently to the introduction of an electrical potential difference, depending on the model. So an electrical potential difference will mostly affect Km if the loaded carrier is ionic, and mostly Jmax if the empty carrier is ionic, provided that the mobility of the loaded carrier is greater than that of the empty one. On the other hand, distinctive criteria between affinity type and velocity type models are partly affected by an electrical potential difference. If the translocation steps of loaded and unloaded carrier are no longer rate limiting for the overall transport, electrical effects on the transport rate are bound to vanish as does the activation by co-transport.     

The kinetics of glutamine transport in bovine lymphocytes.

The transport of glutamine was examined in bovine peripheral lymphocytes which had been cultured in the presence or absence of Concanavalin A (Con A). Glutamine transport was mediated by a triphasic transport system in both cell populations. The calculated kinetic parameters were: Km 1.0, 4.7 and 12.7 mM and Vmax 4.5, 6.0 and 9.0 nmol/min per mg protein respectively. Con A augmented the capacity rather than the affinity of the glutamine transport systems (Vmax rates being 8.0, 12.2 and 38.0 nmol/min per mg protein respectively). Transporter I displayed Michaelis-Menton kinetics, while transporters II and III were co-operative carriers possessing Hill coefficients of 2.3 and 9.5 respectively. Preliminary studies using amino acid and ion inhibition studies suggested that transporter I was a system ASC-type carrier, transporter III a system L carrier, while the nature of transporter II was unclear.     

The mitochondrial carnitine carrier: characterization of SH-groups relevant for its transport function.

The transport function of the purified and reconstituted carnitine carrier from rat liver mitochondria was correlated to modification of its SH-groups by various reagents. The exchange activity and the unidirectional transport, both catalyzed by the carnitine carrier, were effectively inhibited by N-ethylmaleimide and submicromolar concentrations of mercurial reagents, e.g., mersalyl and p-(chloromercuri)benzenesulfonate. When 1 microM HgCl2 or higher concentrations of the above mentioned mercurials were added, another transport mode of the carrier was induced. After this treatment, the reconstituted carnitine carrier catalyzed unidirectional substrate-efflux and -influx with significantly reduced substrate specificity. Control experiments in liposomes without carrier or with inactivated carrier protein proved the dependence of this transport activity on the presence of active carnitine carrier. The mercurial-induced uniport correlated with inhibition of the 'physiological' functions of the carrier, i.e., exchange and substrate specific unidirectional transport. The effect of consecutive additions of various reagents including N-ethylmaleimide, mercurials, Cu(2+)-phenanthroline and diamide on the transport function revealed the presence of at least two different classes of SH-groups. N-Ethylmaleimide blocked the carrier activity by binding to SH-groups of one of these classes. At least one of these SH-groups could be oxidized by the reagents forming S-S bridges. Besides binding to the class of SH-groups to which N-ethylmaleimide binds, mercurials also reacted with SH-groups of the other class. Modification of the latter led to the induction of the efflux-type of carrier activity characterized by loss of substrate specificity.     

Intracellular transport in axonal microtubular domains II. Velocity profile and energetics of circumtubular flow

Summary The microtubule is a highly efficient vectorial structure that could orient a transport force generating mechanism and also absorb the recoil produced by vectorial force generation. We have assumed that a nonspecific shear force is generated in a narrow annulus around the microtubule and have calculated the velocity profiles in the shear flow and drag flow regions that result from such a mechanism. This circumtubular flow of low visocosity cytoplasm is thought to be the basic carrier stream that produces the observed axoplasmic transport phenomena. These carrier streams are devoid of neurofilaments and form the halos or exclusion zones seen around microtubules in electron micrographs. Individual carrier streams may merge hydrodynamically to produce transport domains that are capable of moving large organelles in a saltatory manner. Exchange of material between the low viscosity transport domains and the high macroviscosity neurofilament regions produces mass fluxes akin to those found in chromatographic columns. Calculations of energy required to maintain streaming and of the energy available to the transport system show a close correspondence and demonstrate that a continuous carrier stream activity is energetically feasible.     

Kinetics of Ca2+ carrier in rat liver mitochondria.

The rate of aerobic Ca2+ transport is limited by the rate of the H+ pump rather than by the Ca2+ carrier. The kinetics of the Ca2+ carrier has therefore been studied by using the K+ diffusion potential as the driving force. The apparent Vmax of the Ca2+ carrier is, at 20 degrees C, about 900 nmol (mg of protein)-1 min-1, more than twice the rate of the H+ pump. The apparent Vmax is depressed by Mg2+ and Li+. This supports the view that the electrolytes act as noncompetitive inhibitors of the Ca2+ carrier. The degree of sigmoidicity of the kinetics of Ca2+ transport increases with the lowering of the temperature and proportionally with the concentration of impermeant electrolytes such as Mg2+ and Li+ but not choline. The effects of temperature and of electrolyte do not support the view that the sigmoidicity is due to modifications of the surface potential. Rather, they suggest that Ca2+ transport occurs through a multisubunit carrier, where cooperative phenomena are the result of ligand-induced conformational changes due to the interaction of several allosteric effectors with the carrier subunits. In contrast with La3+ which acts as a competitive inhibitor, Ruthenium Red affects the kinetics by inducing phenomena both of positive and of negative cooperativity. The Ruthenium Red induced kinetics has been reproduced through curve-fitting procedures by applying the Koshland sequential interaction hypothesis to a four-subunit Ca2+ carrier model.     

The binding and translocation steps in transport as related to substrate structure. A study of the choline carrier of erythrocytes

The relationships between structure, affinity and transport activity in the choline transport system of erythrocytes have been investigated in order to (i) explore the nature of the carrier site and its surroundings, and (ii) determine the dependence of the carrier reorientation process on binding energies and steric restraints due to the substrate molecule. Affinity constants and maximum transport rates for a series of trialkyl derivatives of ethanolamine were obtained by a method that involves measuring the trans effect of unlabeled analogs upon the movement of radioactive choline. The main conclusions are as follows: (1) An analysis of transport kinetics shows that the affinity constants determined experimentally differ from the actual dissociation constants in a predictable way. The better the substrate, the higher the apparent affinity relative to the true value, whereas the affinity of non-transported inhibitors is underestimated by a constant factor. (2) The carrier-choline complex undergoes far more rapid reorientation (translocation) than the free carrier. (3) The carrier imposes a strict upper limit upon the size of a substrate molecule that can participate in the carrier reorientation process; this limit corresponds to the choline structure. A smaller substrate such as tetramethylammonium, despite relatively weak binding forces, is unhindered in its translocation, suggesting that a carrier conformational change, dependent upon substrate binding energy, is not required for transport. (4) Small increases in the size of the quaternary ammonium head, as in triethylcholine, sharply lower affinity, consistent with a high degree of specificity for the trimethylammonium group. (5) Lengthening the alkyl substituent in derivatives of dimethyl- and diethylaminoethanol causes a regular increase in affinity, suggestive of unspecific hydrophobic bonding in a region very near the substrate site.     

Thymidine transport in cultured mammalian cells. Kinetic analysis, temperature dependence and specificity of the transport system.

The transport of thymidine has been characterized kinetically and thermodynamically in Novikoff rat hepatoma cells grown in culture and, less extensively, in mouse L cells, Chinese hamster ovary cells, P388 murine leukemia cells and HeLa cells. That the characterizations pertained to the transport system per se was ensured, (i) by employing recently developed methods for rapid sampling of cell/substrate mixtures in order to follow isotope movements within a few seconds after initial exposure of cells to substrate; (ii) by utilizing cells rendered, by genetic or chemical means, incapable of metabolizing thymidine; and (iii) by demonstrating conformity of the transport data to an integrated rate equation derived for a simple, carrier-mediated system. The results indicate that thymidine is transported into mammalian cells by a functionally symmetrical, non-concentrative system for which the carrier : substrate dissociation constant ranges from about 100 microM in Chinese hamster ovary cells, to 230 microM in Novikoff hepatoma cells. In all cell lines investigated, the velocity of transport was sufficient to nearly completely equilibrate low concentration of thymidine across the membrane membrane within 15 s. Temperature dependence of transport velocity and substrate : carrier dissociation were continuous (EA = 18.3 kcal/mol, delta H0' = 9.3 kcal/mol, respectively), and showed no evidence of abrupt transitions. Several natural and artificial nucleosides and nucleic acid bases inhibited influx of radiolabeled thymidine, apparently by competing with thymidine for the transport carrier.     

Active-site-directed inhibition of the plasma-membrane carrier transporting short-chain, neutral amino acids into Trypanosoma brucei.

1. Glycine chloromethyl inhibited the active-transport of L-serine into bloodstream forms of Trypanosoma brucei. 2. Substrates of the short-chain, neutral amino acid transport system (N1), but not of other amino acid transport systems, protected the carrier protein from inhibition. 3. Inhibition was never more than 80% complete. The residual activity might have due to a proportion of N1 carrier active sites which had not reacted with the inhibitor. 4. The inhibition was highly selective for the N1 amino acid transport system. Other amino acid transport systems were not affected and the rate of respiration was only slightly affected. 5. The inhibition was first-order with respect to concentration, indicating that one molecule of the inhibitor reacted with each carrier active-site. 6. The high selectivity of this inhibitor should make it a useful labelling agent during the isolation and purification of the N1 amino acid transport carrier protein(s).     

Temperature-dependent effects of cholesterol on sodium transport through lipid membranes by an ionizable mobile carrier.

Temperature-jump relaxation experiments on Na+ transport by (221)C10-cryptand were carried out in order to study the influence of cholesterol and its temperature-dependence on ion transport through thin lipid membranes. The experiments were performed on large, negatively charged unilamellar vesicles (LUV) prepared from mixtures of dioleoylphosphatidylcholine, phosphatidic acid and cholesterol (mole fractions 0-0.43), at various temperatures and carrier concentrations. The initial rates of Na+ transport and the apparent rate constants of its translocation by (221)C10 increased with the carrier concentration and the temperature. The incorporation of cholesterol into the membranes significantly reduced the carrier concentration- and temperature-dependence of these two parameters. The apparent energy required to activate the transport decreased significantly with increasing carrier concentrations at any given cholesterol molar fraction, and increased significantly with the cholesterol molar fraction at any given carrier concentration. Our interpretation of the action of cholesterol on this transport system is based on the assumption that the binding cavity of cryptands is likely to be located towards the aqueous side of the dipole layer. The results are discussed in terms of the structural, physico-chemical and electrical characteristics of carriers and complexes, and of the interactions occurring between an ionizable mobile carrier and the membrane.     

Kinetics of nucleoside transport in human erythrocytes. Alterations during blood preservation

The transmembrane equilibration of radiolabeled uridine was measured by rapid kinetic techniques in human erythrocytes from freshly drawn blood and in the same cells during conventional storage of the blood as well as in cells from outdated blood. Our results confirm earlier reports that the maximum velocity of uridine equilibrium exchange (Vee) at 25 degrees C is about 30% lower in outdated than fresh red cells, whereas the opposite is the case for the Michaelis-Menten constant for equilibrium exchange (Kee), and that maximum zero-trans efflux (Vzt21) is about 4-times greater than maximum zero-trans influx (Vzt12) in outdated cells (directional asymmetry), whereas they are about the same in fresh red cells. At 25 degrees C, the nucleoside-loaded carrier of fresh cells moves on the average 6-times more rapidly than the empty carrier, whereas the differential mobility of loaded and empty carrier from outdated cells is about 15-fold. Our results also show that greater efflux than influx in outdated cells is not due to a general leakiness of outdated cells, that the differences in kinetic properties of the transporter developed during the first two weeks of blood storage and that the differences are greatly amplified when transport is measured at 5 degrees C rather than 25 degrees C. At 5 degrees C, the loaded carrier from outdated red cells moves about 325-times more rapidly than the empty carrier and maximum zero-trans efflux exceeds maximum zero-trans influx about 14-times, whereas the transport of fresh cells exhibits directional symmetry just as at 25 degrees C. The changes in kinetic properties of transport induced by temperature and storage are probably related to structural alterations in the plasma membrane and suggest that the operation of carrier is subject to modification by the membrane environment. Other results show that the kinetics of the sugar transport of human red cells is not affected in the same manner by blood storage as those of the nucleoside transporter.     

Evidence for separate carriers for purine nucleosides and for pyrimidine nucleosides in the renal brush border membrane.

The aim of the present study was to test if the transport of all nucleosides in rat renal brush border membranes occurs via a common carrier or if specific carriers exist for various groups of nucleosides. We measured the inward transport of radiolabeled nucleosides into brush border vesicles. The effect of unlabeled nucleosides present inside of the vesicles (trans-stimulation) or outside of the vesicles (cis-inhibition) was studied. Uphill influx of a nucleoside into the vesicles could be driven by the efflux of another nucleoside (trans-stimulation) if they were both purines or both pyrimidines but not if one nucleoside was a purine and the other one a pyrimidine. Thus, there exist a carrier that transports various purine nucleosides, and a carrier that transports various pyrimidine nucleosides, but the tested purine nucleosides and the tested pyrimidine nucleosides do not appear to be transported by the same carrier. Uridine and thymidine were similarly potent for the inhibition of cytidine transport whereas uridine was much more potent than thymidine for the inhibition of adenosine transport. This suggests that cytidine and adenosine can use different carriers. Preincubation of the vesicles with N-ethylmaleimide resulted in a marked decrease of the rate of transport of purine nucleosides but it had little effect on the transport of pyrimidine nucleosides. These data are best explained by the presence in the renal brush border membrane of two carriers, one for purine nucleosides, the other one for pyrimidine nucleosides.(ABSTRACT TRUNCATED AT 250 WORDS)     

A kinetic study of mitochondrial calcium transport.

This report describes a kinetic analysis of energy-linked Ca2+ transport in rat liver mitochondria, in which a ruthenium red/EGTA [ethanedioxy-bis(ethylamine)-tetraacetic acid] quenching technique has been used to measure rates of 45Ca2+ transport. Accurately known concentrations of free 45Ca2+ were generated with Ca2+/nitrilotriacetic acids buffers for the determination of substrate/velocity relationships. The results show that the initial velocity of transport is a sigmoidal function of Ca2+ concentration (Hill coefficient = 1.7), the Km being 4 muM Ca4 at 0 degrees C and pH 7.4. These values for the Hill coefficient and the Km remain constant in the presence of up to 2 mM phosphate, but with 10 mM acetate both parameters are increased slightly. Both permeant acids increase the maximum velocity to an extent dependent on their concentration. The Ca2+-binding site(s) of the carrier contains a group ionizing at pH approximately 7.5 at 0 degrees C, which is functional in the dissociated state. The stimulatory effect of permeant acids is ascribed to their facilitating the release of Ca2+ from the carrier to the internal phase, an interpretation which is strengthened by the lack of effect of the permeant anion SCN- on Ca2+ transport. Studies on the time-course of Ca2+ uptake and of EFTA-induced Ca2+ efflux from pre-loaded mitochondria demonstrate the reversibility of the carrier in respiring mitochondria and the extent to which this property is influenced by permeant acids. These data are accommodated in a carrier mechanism based on electrophoretic transport of Ca2+ bound to pairs of interacting acidic sites.     

The choline transport system of erythrocytes. Distribution of the free carrier in the membrane

A method is described, based on the kinetics of transport, for determining the equilibrium distribution of the carrier site on the inner and outer surfaces of the cell membrane, and this method is applied to the choline carrier of human erythrocytes. This method depends on measurement of flux ratios for both entry and exit, i.e., the transport rates of a low concentration of labeled substrate into a solution which contains either no substrate or a saturating concentration of unlabeled substrate. The concentrations of inward-facing and outward-facing carrier are found to be nearly equal, and therefore the 5-fold difference in choline affinity on the inner and outer surfaces of the membrane cannot be explained by an unequal carrier distribution. It is also shown that both reorientation and dissociation of the carrier-substrate complex are far more rapid than reorientation of the free carrier.