Kinetic analysis of simultaneously occurring proton-sorbose symport and passive sorbose transport in Saccharomyces fragilis

Sorbose transport in Saccharomyces fragilis takes place both via an active sugar-H⁺ symport system and via facilitated diffusion.To establish whether the two modes of transport proceed via the same transporter or via two different carriers, the kinetic consequences of both models were investigated. The kinetic equations for initial transport were derived for three possible reaction sequences with respect to sugar and H⁺ binding to the symport carrier: random binding and obligatory ordered binding with either sugar or H⁺ binding first, yielding six sets of kinetic parameters.Analysis of experimental data of sorbose transport in S. fragilis showed the existence of separate carriers for active, sorbose-H⁺ symport and facilitated diffusion. Furthermore, it could be concluded that the symport carrier shows random binding of sugar and H⁺.In recent literature, a similar combination of active and passive sugar transport in Rhodotorula gracilis and Chlorella vulgaris was interpreted as two modes of action of the same carrier, viz., active symport via the protonated, and facilitated diffusion via the unprotonated carrier. Analysis of the experimental data according to the criteria presented in this paper showed, however, that this supposition is untenable and that two different carriers must also be involved in these micro-organisms.     

Secondary active transport

Secondary active transport is defined as the transport of a solute in the direction of its increasing electrochemical potential coupled to the facilitated diffusion of a second solute (usually an ion) in the direction of its decreasing electrochemical potential. The coupling agents are membrane proteins (carriers), each of which catalyzes simultaneously the facilitated diffusion of the driving ion and the active transport of a given solute. The review starts with some considerations on the energetics followed by a presentation of the kinetics of secondary active transport. Examples of information which may be gained by such studies are discussed. In the second part, some examples of secondary transport are given; we also describe the characteristics of the corresponding carriers. The various transport systems presented are: the D-glucose/Na+ symport in brush-border membranes, the lactose/H+ symport in E. coli, the Na+/H+ antiport, the different transport systems in the inner mitochondrial membrane.     

Melibiose permease of Escherichia coli. Characteristics of co-substrates release during facilitated diffusion reactions

The mechanism of melibiose symport by the melibiose permease of Escherichia coli was investigated by further analyzing the Na+ (H+ or Li+)-coupled facilitated diffusion reactions catalyzed by the carrier in de-energized membrane vesicles, with particular emphasis on the reaction of sugar exchange at equilibrium. It is first shown that melibiose exchange at equilibrium proceeds without concomitant movement of Na+, i.e. the coupled cation is kinetically occluded during the melibiose exchange reaction. These results provide further experimental support for the model of Na+ sugar co-transport of the physiological substrate melibiose previously suggested (Bassilana, M., Pourcher, T., and Leblanc, G. (1987) J. Biol. Chem. 262, 16865-16870) in which: 1) the mechanisms of co-substrate binding to (or release from) the carrier are ordered processes on both the outer (Na+ first, sugar last) and inner membrane surfaces (sugar first, Na+ last) and give rise to a mirror-type model; 2) release of Na+ from the carrier on the inner membrane surface is very slow and rate-limiting for carrier cycling but is fast on the opposite side, contributing to the asymmetrical functioning of the permease. On the other hand, analysis of the exchange of identical sugars (homologous exchange) and different sugar analogs (heterologous exchange) indicates that the overall rate of sugar exchange reaction coupled to Na+ or Li+ is limited by the rate of one (or more) partial step(s) associated with the inflow of co-substrates and most probably by the rate of sugar release into the intravesicular medium. It is proposed that the variability of the facilitated diffusion reactions catalyzed by the carrier in the presence of different coupled cations and/or sugar analogs reflects variations in the rate of co-substrate release from the carrier on the inner membrane surface.     

Mechanism of proline transport in Escherichia coli K12. III. Inhibition of membrane potential-driven proline transport by syn-coupled ions and evidence for symmetrical transition states of the 2H+/proline symport carrier

Specific inhibition of 2H+/proline symport by syn-coupled ions (Na+, Li+, and H+) was investigated using cytoplasmic membrane vesicles prepared from the proline carrier-overproducing strain MinS/ pLC4 -45 of Escherichia coli K12. The 2H+/proline symport driven by the membrane potential generated via respiration with 20 mM ascorbate/Tris, 0.1 mM phenazine methosulfate was specifically inhibited by Na+. The inhibition by Na+ was described by a fully noncompetitive mechanism, and the apparent Ki for Na+ was 15 mM. A linear correlation between the apparent Vmax and the apparent Kd was observed. Li+ stimulated the transport activity 2-fold at 10 mM and inhibited it at concentrations above 50 mM. H+ caused fully noncompetitive inhibition of 2H+/proline symport, and its apparent Ki was 0.6 microM. These results indicate that the concentrations of Na+ and H+ strictly and independently regulate the amount of the active C state carrier responsible for 2H+/proline symport driven by the membrane potential by inhibiting the transition from the C* state carrier which exhibits Na+- and H+-dependent binding of proline and is predominant in nonenergized conditions.     

Transport of branched-chain amino acids in membrane vesicles of Streptococcus cremoris.

The kinetics, specificity, and mechanism of branched-chain amino acid transport in Streptococcus cremoris were studied in a membrane system of S. cremoris in which beef heart mitochondrial cytochrome c oxidase was incorporated as a proton motive force (delta p)-generating system. Influx of L-leucine, L-isoleucine, and L-valine can occur via a common transport system which is highly selective for the L-isomers of branched chain amino acids and analogs. The pH dependency of the kinetic constants of delta p-driven L-leucine transport and exchange (counterflow) was determined. The maximal rate of delta p-driven transport of L-leucine (Vmax) increased with increasing internal pH, whereas the affinity constant increased with increasing external pH. The affinity constant for exchange (counterflow) varied in a similar fashion with pH, whereas Vmax was pH independent. Further analysis of the pH dependency of various modes of facilitated diffusion, i.e., efflux, exchange, influx, and counterflow, suggests that H+ and L-leucine binding and release to and from the carrier proceed by an ordered mechanism. A kinetic scheme of the translocation cycle of H+-L-leucine cotransport is suggested.     

The lactose/H+ carrier of Escherichia coli: lac YUN mutation decreases the rate of active transport and mimics an energy-uncoupled phenotype.

The Escherichia coli K12 strain X71-54 carries the lac YUN allele, coding for a lactose/H+ carrier defective in the accumulation of a number of galactosides [Wilson, Kusch & Kashket (1970) Biochem. Biophys. Res. Commun. 40, 1409-1414]. Previous studies proposed that the lower accumulation in the mutant be due to a faulty coupling of H+ and galactoside fluxes via the carrier. Immunochemical characterization of the carriers in membranes from mutant and parent strains with an antibody directed against the C-terminal decapeptide of the wild-type carrier leads to the conclusion that the mutant carrier is similar to the wild-type in terms of apparent Mr, C-terminal sequence, and level of incorporation into the membrane. The pH-dependence of galactoside transport was compared in the mutant and the parent. At pH 8.0-9.0, mutant and parent behave similarly with respect to the accumulation of beta-D-galactosyl 1-thio-beta-D-galactoside and to the ability to grow on the carrier substrate melibiose. At pH 6.0, both the maximal velocity for active transport and the level of accumulation of beta-D-galactosyl-1-thio-beta-D-galactoside are lower in the mutant. The mutant also is unable to grow on melibiose at pH 5.5. However, at pH 6.0 and low galactoside concentrations, the symport stoichiometry is 0.90 H+ per galactoside in the mutant as compared with 1.07 in the parent. These observations suggest that symport is normal in the mutant and that the lower rate of transport in the mutant is responsible for the phenotype. At higher galactoside concentrations, accumulation is determined not only thermodynamically but also kinetically, contrary to a simple interpretation of the chemiosmotic theory. Therefore lower rates of active transport can mimic the effect of uncoupling H+ and galactoside symport. Examination of countertransport in poisoned cells at pH 6.0 reveals that the rate constants for the reorientation of the loaded and unloaded carrier are altered in the mutant. The reorientation of the unloaded carrier is slower in the mutant. However, the reorientation of the galactoside-H+-carrier complex is slower for substrates like melibiose, but faster for substrates like lactose. These findings suggest that lactose-like and melibiose-like substrates interact with the carrier in slightly different ways.     

Sugar binding properties of the melibiose permease in Escherichia coli membrane vesicles. Effects of Na+ and H+ concentrations

The substrate binding reaction of the melibiose carrier was analyzed by studying [3H]p-nitrophenyl-alpha-D-galactopyranoside (Np alpha Gal) binding to de-energized membrane vesicles from Escherichia coli RA11 as a function of H+ and Na+ (or Li+) concentrations. The data indicate first that Na+ (or Li+) activates Np alpha Gal binding at all pH values tested between 5.5 and 7.5 and second that H+ inhibits the Na+ (or Li+)-dependent activating effect on Np alpha Gal binding. Similar conclusions were drawn for melibiose and methyl-1-thio-beta-D-galactoside binding activities. Unexpectedly, Np alpha Gal, melibiose, and methyl-1-thio-beta-D-galactoside binding activities are insensitive to a variety of SH reagents which completely block transport activity. Quantitative analysis of the effects of H+ and Na+ ions on the parameters of Np alpha Gal binding show that 1) the maximal number of binding sites is constant irrespective of the concentration of Na+ or Li+ in the range of pH between 6 and 7.5 and 2) the apparent dissociation constant for Np alpha Gal binding varies with both Na+ and H+ according to a relation described by a linear combination of the concentration of H+ and the reciprocal of Na+ concentration. These results can be accounted for by a model which assumes sequential binding of the cation and substrate in this order and competition between Na+ and H+ for a common cationic binding site on the porter. Predictions of the proposed binding model for a carrier mechanism catalyzing sugar transport according to a Na+ symport mode or a H+ symport mode are discussed.     

Glucose uptake and metabolism in the Trichinella spiralis nurse cell

Isolated Trichinella spiralis nurse cells transport a significantly greater amount of glucose/mg of protein than the normal skeletal muscle cell line (L6). V(max) and K(m) estimations revealed that nurse cells have a much higher saturation point than L6 cells for glucose. The effects of numerous physiological conditions (Na(+) concentration, pH, and temperature) on nurse cell glucose uptake were investigated. It was determined that sodium concentration had no effect on glucose uptake. Low (<6.5) and high (>7.3) pH and low (5 degrees C) temperatures significantly effected glucose uptake. The two hormones, insulin and epinephrine, appeared to have little, if any, influence on the rate of glucose uptake by nurse cells. Glucose uptake was inhibited in the presence of 6-carbon carbohydrates. The H(+)/glucose symport inhibitors, dicyclohexylcarbodiimide (DCCD) and Carbonyl cyanide 4-trifluoromethoxyphenlhydrazone (FCCP), and the facilitated diffusion inhibitor phloretin also inhibited glucose uptake. Oubain, a Na(+)/glucose symport inhibitor, did not inhibit glucose uptake. These data, in conjunction with Western blot analyses, revealed that the transport of glucose occurs via H(+)/glucose symport and facilitated diffusion, perhaps through the glucose transport proteins GLUT 1 and/or 4. It was also demonstrated that nurse cells are capable of synthesising glycogen. It appears that glycogen is in a constant state of flux and physiological conditions, such as glucose concentration, significantly influence the synthesis of this macromolecule. We conclude that these results are consistent with the hypothesis that nurse cells, at least maintained in vitro, are metabolically highly active but show significant divergence from normal muscle cells in several fundamental aspects of sugar metabolism.     

Regulation of glucose transport in Candida utilis

The transport systems for glucose present in Candida utilis cells, growing in batch and continuous cultures on several carbon sources, have been studied. Two different systems were found: a proton symport and a facilitated diffusion system. The high-affinity symport (Km for glucose about 15 microM) transported one proton per mole of glucose and was partially constitutive, appearing in cells grown on gluconeogenic substrates such as lactate, ethanol and glycerol. It was also induced by glucose concentrations up to 0.7 mM and repressed by higher ones. The level of repression depended on the external glucose concentration at which cells had grown in a way similar to that shown by the maltose-uptake system, so both systems seem to be under a common glucose control. Initial uptake by facilitated diffusion, the only transport system present in cells growing at glucose concentrations higher than 10 mM, showed a complex kinetic dependence on the extracellular glucose concentration. This could be explained either by the presence of at least two different systems simultaneously active, one with a Km around 2 mM and the other with a Km of about 1 M, or by the allosteric or hysteretic behaviour of a single carrier whose apparent Km would oscillate between 2 and 70 mM.     

Variable H+/substrate stoicheiometries in Rhodotorula gracilis are caused by a pH-dependent protonation of the carrier(s).

Two carrier-mediated systems transport sugars in the yeast Rhodotorula gracilis depending on the pH. One system, with higher affinity for sugars, catalyses a symport of protons with sugar, whereas the other system, having lower affinity, is independent of protons. This was shown in three different ways. (1) At low pH, where only the high-affinity system works, a H+/sugar stoicheiometry of 1 was found. An increase of the pH and of the sugar concentration, which allowed the low-affinity system to operate, brought about a drop of the stoicheiometry to values below 1. (2) During H+ symport the influx of positive charge was electrically compensated by an equivalent efflux of K+ from the cells. At high pH and high sugar concentrations this stoicheiometry of K+ and sugar decreased concomitant with the H+/sugar stoicheiometry. (3) At pH 7.5 both transport systems were operating, as shown by biphasic saturation kinetics. Under these conditions only the high-affinity transport was found to be electrogenic. These results agree with the theory of an electrogenic H+/sugar symport where changes in the affinity for substrate are brought about by reversible protonation and deprotonation of the carrier.     

Kinetic analysis of L-lactate transport in human erythrocytes via the monocarboxylate-specific carrier system

Three parallel pathways of L-lactate transport across the membrane of human red blood cells can be discriminated: (a) by nonionic diffusion; (b) via the band 3 anion exchange protein; and (c) via a specific monocarboxylate carrier system. Influx of lactate via the latter system leads to alkalinization of the medium, suggesting lactate-proton symport. Kinetic analysis of initial lactate influx via the monocarboxylate carrier indicates a symport system with ordered binding of the two ligands, in the sense that a proton binds first to the translocator, followed by lactate binding to the protonated carrier. The influence of varying trans-pH under conditions of net (zero-trans) flux with constant cis-pH indicates that the monocarboxylate translocator should be considered as a mobile carrier, with the ligand-binding sites exposed alternatively to the outside and the inside of the membrane.     

Kinetic analysis of l-lactate transport in human erythrocytes via the monocarboxylate-specific carrier system

Three parallel pathways of l-lactate transport across the membrane of human red blood cells can be discriminated: (a) by nonionic diffusion; (b) via the band 3 anion exchange protein; and (c) via a specific monocarboxylate carrier system. Influx of lactate via the latter system leads to alkalinization of the medium, suggesting lactate-proton symport. Kinetic analysis of initial lactate influx via the monocarboxylate carrier indicates a symport system with ordered binding of the two ligands, in the sense that a proton binds first to the translocator, followed by lactate binding to the protonated carrier. The influence of varying trans-pH under conditions of net (zero-trans) flux with constant cis-pH indicates that the monocarboxylate translocator should be considered as a mobile carrier, with the ligand-binding sites exposed alternately to the outside and the inside of the membrane.     

The kinetics of fructose utilization byS. cerevisiae IGC 4261 in sucrose adjunct brewers wort fermentations

Summary Fructose utilization in laboratory-scale sucrose adjunct brewers wort fermentations, using the brewing strainS. cerevisiae IGC 4261, is predicted by a mathematical model based on the kinetic parameters of the membrane transport proteins which affect fructose uptake into the cell. These include biphasic fructose transport via a proton symport and the constitutive hexose facilitated diffusion system, plus the competitive inhibitory effect that glucose has on this latter component. Also the non-competitive inhibitory effects of a) maltose on fructose uptake via its proton symport and b) ethanol on biphasic fructose transport are incorporated within the model, as well as the inoculum size.     

Mechanism of proline transport in Escherichia coli K12. I. Effect of a membrane potential on the kinetics of 2H+/proline symport in cytoplasmic membrane vesicles

The stoichiometric coupling mechanism of the membrane potential (delta psi) in the reaction of H+/proline symport was investigated kinetically, using cytoplasmic membrane vesicles of the proline carrier-overproducing strain of Escherichia coli MinS/ pLC4 -45. When a delta psi was imposed across the cytoplasmic membrane by respiration, the Michaelis constant of transport (Kt) was lowered to about 1 microM, which was 2 orders of magnitude smaller than that of passive influx and efflux, and the maximum velocity (Vmax) was concomitantly enhanced as an exponential function of delta psi. Thermodynamically, the carrier translocated proline with a stoichiometry of 2 mol of protons versus 1 mol of substrate when driven by a delta psi at pH 8.0. Data on the delta psi dependence of Vmax of proline transport could be explained quantitatively by the Geck-Heinz hypothesis (Geck, P., and Heinz, E. (1976) Biochim, Biophys. Acta 443, 49-63). A symmetrical model of the 2H+/proline symport via formation of a carrier/H+/substrate (CH+H+S) intermediate is proposed. In this model, the effect of delta psi on the Kt was resolved as stimulation of formation of a transport intermediate, whereas the effect of delta psi on the Vmax was explained by enhancement of translocation of loaded carriers between the two sides of the membrane.     

Mechanisms for the facilitated diffusion of substrates across cell membranes

Two classes of theoretical mechanisms for protein-mediated, passive, transmembrane substrate transport (facilitated diffusion) are compared. The simple carrier describes a carrier protein that exposes substrate influx and efflux sites alternately but never both sites simultaneously. Two-site models for substrate transport describe carrier proteins containing influx and efflux sites simultaneously. Velocity equations describing transport by these mechanisms are derived. These equations take the same general form, being characterized by five experimental constants. Simple carrier-mediated transport is restricted to hyperbolic kinetics under all conditions. Two-site carrier-mediated transport may deviate from hyperbolic kinetics only under equilibrium exchange conditions. When both simple- and two-site carriers display hyperbolic kinetics under equilibrium exchange conditions, these models are indistinguishable by using steady-state transport data alone. Seven sugar transport systems are analyzed. Five of these systems are consistent with both models for sugar transport. Uridine, leucine, and cAMP transport by human red cells are consistent with both simple- and two-site models for transport. Human erythrocyte sugar transport can be modeled by simple- and two-site carrier mechanisms, allowing for compartmentalization of intracellular sugars. In this instance, resolution of the intrinsic properties of the human red cell sugar carrier at 20 degrees C requires the use of submillisecond transport measurements.     

Na(+)-dependent, active and Na(+)-independent, facilitated transport of formycin B in mouse spleen lymphocytes

Na(+)-dependent, active and Na(+)-independent facilitated nucleoside transport were characterized in mouse spleen cells using rapid kinetic techniques and formycin B, a metabolically inert analog of inosine, as substrate. The Michaelis-Menten constants for formycin B transport by the two transporters were about 30 and 400 microM, respectively. The first-order rate constant for Na(+)-dependent transport was about 4-times higher than that for facilitated formycin B transport. The Na(+)-dependent carrier is specific for uridine and purine nucleosides and accumulates formycin B concentratively in an unmodified form. Concentrative accumulation was inhibited by ATP depletion and gramicidin and ouabain treatment of the cells. Our data indicate a single Na(+)-binding site on the Na(+)-dependent nucleoside carrier and a Michaelis-Menten constant for Na+ of about 10 mM. This transporter was not significantly inhibited by dipyridamole and nitrobenzylthioinosine, inhibitors of the facilitated transporter. The Na(+)-independent, facilitated nucleoside transporter of spleen cells exhibits properties comparable to those of the carriers present in mammalian cells in general. The B lymphocytes remaining after depletion of spleen cell populations of T lymphocytes by incubation with a combination of T-cell specific monoclonal antibodies plus complement exhibited about the same activities of active and facilitated nucleoside transport as the original suspension.     

Analysis of the H+/sugar symport in yeast under conditions of depolarized plasma membrane

H⁺/sugar symport in the obligatory aerobic yeastRhodotorula glutinis was analyzed under conditions where the plasma membrane was selectively depolarized by the lipophilic cation tetraphenylphosphonium (TPP⁺). Control experiments showed that this treatment did not impair the transmembrane pH, the cell energy charge, and the function of plasma membrane H⁺-ATPase. The kinetic data were fitted to elementary functions derived from a model constructed on the basis of some simplifying premises for ordered (either C + H⁺ + S or C + S + H⁺) and random reaction mechanisms. In addition, the comparison of the kinetic parameters in fully energized and depolarized cells provided information about the free carrier charge. It was concluded that the binding sequence of formation of the ternary carrier/H⁺/substrate complex follows a random mechanism and that the carrier bears a negative charge.     

Inactivation of active glucose transport in Candida wickerhamii is triggered by exocellular glucose

Abstract Under conditions of derepression the yeast Candida wickerhamii formed a high-affinity glucose proton symport. Glucose and glucose analogues induced inactivation of the glucose proton symport and its interconversion into a low-affinity facilitated diffusion system. The specific inactivation rate increased with the concentration of the inactivating sugar and did not obey saturation kinetics. This dependence was still pronounced at sugar concentrations far above saturation of the glucose transport systems. This suggested that the inactivation and interconversion mechanism was triggered by interaction of the inactivating sugar with receptor sites located on the cell surface.     

Glucose transport in crabtree-positive and crabtree-negative yeasts

The kinetic parameters of glucose transport in four Crabtree-positive and four Crabtree-negative yeasts were determined. The organisms were grown in aerobic glucose-limited chemostats at a dilution rate of 0.1 h-1. The results show a clear correlation between the presence of high-affinity glucose transport systems and the absence of aerobic fermentation upon addition of excess glucose to steady-state cultures. The presence of these H+-symport systems could be established by determination of intracellular accumulation of 6-deoxy-[3H]glucose and alkalinization of buffered cell suspensions upon addition of glucose. In contrast, the yeasts that did show aerobic alcoholic fermentation during these glucose pulse experiments had low-affinity facilitated-diffusion carriers only. In the yeasts examined the capacity of the glucose transport carriers was higher than the actual glucose consumption rates during the glucose pulse experiments. The relationship between the rate of sugar consumption and the rate of alcoholic fermentation was studied in detail with Saccharomyces cerevisiae. When S. cerevisiae was pulsed with low amounts of glucose or mannose, in order to obtain submaximal sugar consumption rates, fermentation was already occurring at sugar consumption rates just above those which were maintained in the glucose-limited steady-state culture. The results are interpreted in relation with the Crabtree effect. In Crabtree-positive yeasts, an increase in the external glucose concentration may lead to unrestricted glucose uptake by facilitated diffusion and hence, to aerobic fermentation. In contrast, Crabtree-negative yeasts may restrict the entry of glucose by their regulated H+-symport systems and thus prevent the occurrence of overflow metabolism.