pH modulation of the kinetics of rabbit jejunal,brush-border folate transport

Summary In jejunal brush-border membrane vesicles, an outwardly directed OH^– gradient (in>out) stimulates DIDS-sensitive, saturable folate (F) uptake (Schron, C.M. 1985.J. Clin. Invest. 76:2030–2033), suggesting carrier-mediated folate: OH^– exchange (or phenomenologically indistinguishable H⁺: folate cotransport). In the present study, the precise role of pH in the transport process was elucidated by examining F uptake at varying pH. For pH gradients of identical magnitude, F uptake (0.1 M) was greater at lower (pH_int/pH_ext: 5.5/4.5) compared with higher (6.5/5.5) pH ranges. In the absence of a pH gradient, internal Ftrans stimulated DIDS-sensitive³H-folate uptake only at pH6.0. Since stepwise increments ininternal pH (4.57.5; pH_ext=4.5) stimulated F uptake, an inhibitory effect of higherinternal pH was excluded. In contrast, with increasing external pH (4.356.5; pH_int=7.8), a 50-fold decrement in F uptake was observed (H⁺ K _m =12.8±1.2 M). Hill plots of these data suggest involvement of at least one H⁺ (OH^–) at low pH (monovalent F^– predominates) and at least 2 H⁺ (OH^–) at high pH (divalent F^–2 predominates). Since an inside-negative electrical potential did not affect F uptake at either pH_ext 4.55 or 5.8, transport of F^– and F^–2 is electroneutral. Kinetic parameters for F^– and F^–2 were calculated from uptake data at pH_ext 4.55 and 5.0. Comparison of predictedvs. experimentally determined kinetic parameters at pH_ext5.8 (K _m =1.33vs. 1.70 M;V _max=123.8vs. 58.0 pmol/mg prot min) suggest that increasing external pH lowers theV _max, but does not affect theK _m for carrier-mediated F transport. These data are consistent with similarK _i ^' s for sulfasalazine (competitive inhibitor) at pH_ext 5.35 and 5.8 (64.7 and 58.5 M, respectively). In summary, the jejunal F carrier mediates electroneutral transport of mono- and divalent F and is sensitive to external pH with a H⁺ K _m (or OH^– lC₅₀) corresponding to pH 4.89. External pH effects theV _max, but not theK _m for carriermediated F uptake suggesting a reaction mechanism involving a ternary complex between the outward-facing conformation of the carrier and the transported ions (F and either OH^– or H⁺),rather than competitive binding that is mutually exclusive.     

Anion specificity of the jejunal folate carrier: Effects of reduced folate analogues on folate uptake and efflux

Summary We previously reported that³H-folate uptake by rabbit jejunal brush-border membrane (BBM) vesicles was markedly stimulated by an outwardly directed OH^– gradient (pH_in 7.7, pH_out 5.5), inhibited by anion exchange inhibitors (DIDS, SITS, furosemide), and saturable (folateK _m=0.19 m) suggesting carrier-mediated folate/OH^– exchange (or H⁺/folate cotransport). In the present study, the anion specificity of this transport process was examined. Under conditions of an outwardly directed OH^– gradient, DIDS-sensitive folate uptake wascis inhibited (>90%) by reduced folate analogues: dihydrofolate (IC₅₀=0.40 m), folinic acid (IC₅₀=0.50 m), 5-methyltetrahydrofolate (IC₅₀=0.53 m), and (+)amethopterin (IC₅₀=0.93 M). In contrast, 10 m (–)amethopterin had only a modest effect on folate uptake (18% inhibition) suggesting stereospecificity of the folate/OH^– exchanger. The nonpteridine compounds which are transported by the folate carrier in L1210 leukemic cells (phthalate, thiamine pyrophosphate, and PO ₄ ^–3 ) did not inhibit jejunal folate uptake. Furthermore, folate uptake was not inhibited by SO ₄ ^–2 (4mm) or oxalate (4mm) thereby distinguishing this carrier from the previously described intestinal SO ₄ ^–2 /OH^– and oxalate/Cl^– exchangers. After BBM vesicles were loaded with³H-folate, the initial velocity of³H-folate efflux was stimulated by unlabeled folate in the efflux medium. The transstimulation of³H-folate efflux by unlabeled folate was furosemide (or DIDS) inhibitable and temperature sensitive. Half-maximal stimulation of furosemide-sensitive³H-folate efflux was observed with 0.25±0.05 m unlabeled folate, a concentration similar to theK _m for folate uptake. These data suggest that folate-stimulated³H-folate efflux is mediated by the folate/OH^– exchanger. With the exception of (–) amethopterin, reduced folate analogues also transstimulated furosemide-sensitive³H-folate efflux in a concentration-dependent manner suggesting stereospecific transport of these analogues by the folate/OH^– exchanger. In summary, folate transport by the jejunal folate/OH^– exchanger demonstrates bothcis inhibition and transstimulation by reduced folate analogues, but not by other inorganic or organic anions suggesting bidirectional transport of folate and a high degree of anion specificity.     

Sulfate transport in rabbit ileum: Characterization of the serosal border anion exchange process

Summary The preceding paper [30] shows that transepithelial ileal SO₄ transport involves Na-dependent uptake across the ileal brush border, and Cl-dependent efflux across the serosal border. The present study examines more closely the serosal efflux process. Transepithelial mucosa (m)-to-serosa (s) ands-to-m fluxes (J _ms,J _sm) across rabbit ileal mucosa were determined under short-circuit conditions. SO₄ was present at 0.22mm. In standard Cl, HCO₃ Ringer's,J _ms ^SO4 was 81.3±5.3 (1se) andJ _ms ^SO4 was 2.5±0.2 nmol cm^–2 hr^–1 (n=20). Serosal addition of 4-acetamido-4-isothiocyanostilbene-22-disulfonate (SITS), 44-diisothiocyanostilbene-22-disulfonate (DIDS) or 1-anilino-8-naphthalene-sulfonate (ANS) inhibited SO₄ transport, SITS being the most potent. Several other inhibitors of anion exchange in erythrocytes and other cells had no effect on ileal SO₄ fluxes. In contrast to its effect on SO₄ transport, SITS (500 m) did not detectably alter Cl transport.Replacement of all Cl, HCO₃ and PO₄ with gluconate reducedJ _ms ^SO4 by 70% and increasedJ _ms ^SO4 by 400%. A small but significantJ _net ^SO4 remained.J _ms ^SO4 could be increased by addition to the serosal side of Cl, Br, I, NO₃ or SO₄. The stimulatory effect of all these anions was saturable and SITS-inhibitable. The maximalJ _ms ^SO4 in the presence of Cl was considerably higher than in the presence of SO₄ (73.1 and 42.2 nmol. cm^–2 hr^–1, respectively;p<0.001). TheK _1/2 value for Cl was 7.4mm, 10-fold higher than that for SO₄ (0.7mm). Omitting HCO₃ and PO₄ had no measurable effects on SO₄ fluxes.This study shows that (i) SO₄ crosses the serosal border of rabbit ileal mucosa by anion exchange; (ii) the exchange process is inhibited by SITS, DIDS and ANS, but not by several other inhibitors of anion exchange in other systems; (iii) SO₄ may exchange for Cl, Br, I, NO₃ and SO₄ itself, but probably not for HCO₃ or PO₄; (iv) kinetics of the exchange system suggest there is a greater affinity for SO₄ than for Cl, although the maximal rate of exchange is higher in the presence of Cl; and, finally (v) SITS has little or no effect on net Cl transport.     

Multiple transport pathways for neutral amino acids in rabbit jejunal brush border vesicles

Summary Amino acids enter rabbit jejunal brush border membrane vesicles via three major transport systems: (1) simple passive diffusion; (2) Na-independent carriers; and (3) Na-dependent carriers. The passive permeability sequence of amino acids is very similar to that observed in other studies involving natural and artificial membranes. Based on uptake kinetics and cross-inhibition profiles, at least two Na-independent and three Na-dependent carrier-mediated pathways exist. One Na-independent pathway, similar to the classical L system, favors neutral amino acids, while the other pathway favors dibasic amino acids such as lysine. One Na-dependent pathway primarily serves neutrall-amino acids including 2-amino-2-norbornanecarboxylic acid hemihydrate (BCH), but not -alanine or -methylaminoisobutyric acid (MeAIB). Another Na-dependent route favors phenylalanine and methionine, while the third pathway is selective for imino acids and MeAIB. Li is unable to substitute for Na in these systems. Cross-inhibition profiles indicated that none of the Na-dependent systems conform to classical A or ACS paradigms. Other notable features of jejunal brush border vesicles include (1) no -alanine carrier, and (2) no major proline/glycine interactions.     

Electrogenic transport of 5-oxoproline in rabbit renal brush-border membrane vesicles Effect of intravesicular potassium

The Na⁺-dependent transport of 5-oxoproline into rabbit renal brush-border vesicles was stimulated by a K⁺ diffusion potential (interior-negative) induced by valinomycin. Na⁺ salts of two anions of different epithelial permeabilities also affected 5-oxoproline transport. These results show that the Na⁺-dependent 5-oxoproline transport in renal brush-border vesicles is an electrogenic process which results in a net transfer of positive charge. Maximum transport of 5-oxoproline occurred at an extravesicular pH of 6.0 to 8.0 and over that pH range, 5-oxoproline exists completely as an anion with a negative charge. The simplest stoichiometry consistent with this process is, therefore, the cotransport of one 5-oxoproline anion with two sodium ions. The presence of K⁺ inside the vesicles stimulated the Na⁺-dependent transport of 5-oxoproline. This stimulatory effect was specific for K⁺ and required the presence of Na⁺. The presence of Na⁺ gradient was not mandatory for the K⁺ action. The stimulation by the intravesicular K⁺ was seen in the presence as well as in the absence of a K⁺ gradient. Therefore, the increased influx of 5-oxoproline was not coupled to the simultaneous efflux of K⁺. The presence of K⁺ in the extravesicular medium alone did not affect the Na⁺-dependent transport of 5-oxoproline, showing that the site of K⁺ action was intravesicular. Glutamate did not interact with the Na⁺-dependent 5-oxoproline transport even in the presence of an outward K⁺ gradient.     

Potassium/proton exchange in brush-border membrane of rat ileum

Summary These experiments were designed to determine whether proton-driven⁸⁶Rb uptake was present in apical membrane vesicles prepared from rat ileum. The uptake of⁸⁶Rb was approximately 300 to 350% greater in the presence of a 100-fold H⁺ gradient than in its absence and was greater at 1, 2 and 5 minutes (overshoot) than that at 90 minutes. Proton-driven⁸⁶Rb uptake was decreased by 20% in TMA-nitrate compared to that in TMA-gluconate. 0.3mm amiloride did not significantly inhibit proton-driven⁸⁶Rb uptake; in contrast, proton-driven²²Na uptake was significantly inhibited by 0.3mm amiloride by 34%. Similarly, 25mm KCl inhibited proton-driven⁸⁶Rb uptake more than that of²²Na, while the inhibition of proton-driven²²Na uptake by 25mm NaCl was greater than that of⁸⁶Rb. In additional studies intravesicular acidification measured by acridine orange fluorescence was demonstrated in the presence of an out-wardly directed K gradient. These studies demonstrate that a proton gradient stimulates⁸⁶Rb uptake and a K gradient induces intravesicular acidification; and that these fluxes are mediated by a K/H exchange distinct from Na/H exchange which is also present in this membrane. We conclude that a specific exchange process for K/H is located in ileal apical membrane vesicles.     

Studies of the kinetics of Na+ gradient-coupled glucose transport as found in brush-border membrane vesicles from rabbit jejunum

The Na⁺-dependent d-glucose transport reaction in rabbit jejunal brush-border vesicles was studied. Initial rate data were obtained by fitting a polynomial equation to progress curves at different d-glucose concentrations and extracting the slope of the tangent at zero-time. Kinetic replots of the initial rate values produced biphasic Hofstee patterns indicative of two pathways for transport distinguished by their $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ values for glucose. Neither was dependent on the presence of a membrane potential. Both were dependent on Na⁺ and both were inhibited by phlorizin. Increasing external sodium was found to elevate the apparent $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ for both pathways. Internal sodium was inhibitory. Pulsed progress curve analysis indicated that the effect of internal sodium was best characterized as carrier sequestration by a sodium-carrier binary complex. Inhibition by internal sodium was completely reversed by the presence, internally, of d-glucose. The presence of two pathways and the kinetic constants for these pathways do not agree with the conclusions of Hopfer and Groseclose (1980) J. Biol. Chem. 255, 4453–4462). Experiments are presented which bear on the reason for the disagreement.     

Taurine transport by rabbit kidney brush-border membranes: Coupling to sodium,chloride, and the membrane potential

Summary Ion dependence and electrogenicity of taurine uptake were studied in rabbit renal outer cortical brush-border membrane vesicles isolated by differential precipitation. Na⁺-d-glucose cotransport was followed in parallel to monitor changes in the membrane potential. Concentrative taurine flux was dependent on a chemical and/or an electrical Na⁺ gradient (K⁺ diffusion potential) and could be completely inhibited by other -amino acids. It displayed a specific anion requirement (Cl^–Br^–SCN^–>I^–>NO ₃ ^– ). At chemical Na⁺ equilibrium, Cl^– gradients, depending on their orientation, stimulated or inhibited taurine uptake more than could be attributed solely to electrical anion effects, although a Cl^– gradient alone could not energize an overshoot. Furthermore, taurine tracer exchange was significantly stimulated by Cl^– as well as Br^–. The Cl^– stoichiometry was found to be one, whereas taurine transport, in the presence of Cl^–, was sigmoidally related to the Na⁺ concentration, resulting in a coupling ratio of 2 to 3 Na⁺: 1 taurine. Upon Cl^– replacement with gluconate, taurine uptake showed a reduced potential sensitivity and was no longer detectably affected by the Na⁺ concentration (up to 150mm). These results suggest a 2 to 3 Na⁺:1 Cl^–:1 taurine cotransport mechanism driven mainly by the Na⁺ gradient, which is sensitive to the membrane potential due to a negatively charged empty carrier. Cl^– appears to stimulate taurine flux primarily by facilitating the formation of the translocated solute-carrier complex.     

Transport in halobacterium halobium: Light-induced cation-gradients,amino acid transport kinetics,and properties of transport carriers

Cell envelope vesicles prepared from H. halobium contain bacteriorhodopsin and upon illumination protons are ejected. Coupled to the proton motive force is the efflux of Na⁺. Measurements of ²²Na flux, exterior pH change, and membrane potential, ΔΨ (with the dye 3,3′-dipentyloxadicarbocyanine) indicate that the means of Na⁺ transport is sodium/proton exchange. The kinetics of the pH changes and other evidence suggests that the antiport is electrogenic (H⁺/Na⁺ > 1). The resulting large chemical gradient for Na⁺ (outside > inside), as well as the membrane potential, will drive the transport of 18 amino acids. The 19th, glutamate, is unique in that its accumulation is indifferent to ΔΨ: this amino acid is transported only when a chemical gradient for Na⁺ is present. Thus, when more and more NaCl is included in the vesicles glutamate transport proceeds with longer and longer lags. After illumination the gradient of H⁺ collapses within 1 min, while the large Na⁺ gradient and glutamate transporting activity persists for 10–15 min, indicating that proton motive force is not necessary for transport. A chemical gradient of Na⁺, arranged by suspending vesicles loaded with KCl in NaCl, drives glutamate transport in the dark without other sources of energy, with V_max and K_m comparable to light-induced transport. These and other lines of evidence suggest that the transport of glutamate is facilitated by symport with Na⁺, in an electrically neutral fashion, so that only the chemical component of the Na⁺ gradient is a driving force. The transport of all amino acids but glutamate is bidirectional. Actively driven efflux can be obtained with reversed Na⁺ gradients (inside > outside), and passive efflux is considerably enhanced by intravesicle Na⁺. These results suggest that the transport carriers are functionally symmetrical. On the other hand, noncompetitive inhibition of transport by cysteine (a specific inhibitor of several of the carriers) is only obtained from the vesicle exterior and only for influx: these results suggest that in some respects the carriers are asymmetrical. A protein fraction which binds glutamate has been found in cholate-solubilized H. halobium membranes, with an apparent molecular weight of 50,000. When this fraction (but not the others eluted from an Agarose column) is reconstituted with soybean lipids to yield lipoprotein vesicles, facilitated transport activity is regained. Neither binding nor reconstituted transport depend on the presence of Na⁺. The kinetics of the transport and of the competitive inhibition by glutamate analogs suggest that the protein fraction responsible is derived from the intact transport system.     

Effect of zinc on L-threonine transport across the jejunum of rabbit

Zinc is an essential trace element for life. Many metalloenzymes involved in the metabolism of carbohydrates, lipids, protein, and nucleic acids require zinc for their functions. The aim of this study was to characterize how zinc acts on the intestinal amino acid absorption in rabbit. Results obtained show that zinc inhibits both L-threonine accumulation in the jejunum tissue, and mucosal-to-serosal transepithelial flux of this amino acid in a dose-dependent way. The inhibition does not increase by a 10-min previous intestinal exposure of the mucosa to the heavy metal, and is not reversed by washing the intestinal tissue with saline solution or 10mM EDTA, but is appreciably reversed with 10mM dithioerythritol. Zinc seems not to modify amino acid diffusion across the intestinal epithelium. The inhibition of intestinal amino acid transport by zinc seems to be of a competitive type, and appears to be a result of impairment of the active transport that is altered by its binding to proteins (prevailing to thiol groups) of the brush-border membrane of enterocytes.     

L-Carnitine transport in mouse renal and intestinal brush-border and basolateral membrane vesicles

We characterized the uptake of carnitine in brush-border membrane (BBM) and basolateral membrane (BLM) vesicles, isolated from mouse kidney and intestine. In kidney, carnitine uptake was Na⁺-dependent, showed a definite overshoot and was saturable for both membranes, but for intestine, it was Na⁺-dependent only in BLM. The uptake was temperature-dependent in BLM of both kidney and intestine. The BBM transporter in kidney had a high affinity for carnitine: apparent K_m=18.7 μM; V_max=7.85 pmol/mg protein/s. In kidney BLM, similar characteristics were obtained: apparent K_m=11.5 μM and V_max=3.76 pmol/mg protein/s. The carnitine uptake by both membranes was not affected within the physiological pH 6.5-8.5. Tetraethylammonium, verapamil, valproate and pyrilamine significantly inhibited the carnitine uptake by BBM but not by BLM. By Western blot analysis, the OCTN2 (a Na⁺-dependent high-affinity carnitine transporter) was localized in the kidney BBM, and not in BLM. Strong OCTN2 expression was observed in kidney and skeletal muscle, with no expression in intestine in accordance with our functional study. We conclude that different polarized carnitine transporters exist in kidney BBM and BLM. L-Carnitine uptake by mouse renal BBM vesicles involves a carrier-mediated system that is Na⁺-dependent and is inhibited significantly by specific drugs. The BBM transporter is likely to be OCTN2 as indicated by a strong reactivity with the anti-OCTN2 polyclonal antibody.     

Phosphate transport in human red blood cells: Concentration dependence and pH dependence of the unidirectional phosphate flux at equilibrium conditions

Summary The concentration dependence and the pH dependence of the phosphate transport across the red cell membrane were investigated. The unidirectional phosphate fluxes were determined by measuring the³²P-phosphate self-exchange in amphotericin B (5 mol/liter) treated erythrocytes at 25°C.The flux/concentration curves display anS-shaped increase at low phosphate concentrations, a concentration optimum in the range of 150 to 200mm phosphate and a self-inhibition at high phosphate concentrations. The apparent half-saturation concentrations,P _(0.5), range from 50 to 70mm and are little affected by pH. The self-inhibition constants, as far as they can be estimated, range from 400 to 600mm. The observed maximal phosphate fluxes exhibit a strong pH dependence. At pH 7.2, the actual maximal flux is 2.1×10^–6 moles·min^–1·g cells^–1. The ascending branches of the flux/concentration curves were fitted to the Hill equation. The apparent Hill coefficients were always in the range of 1.5–2.0. The descending branches of the flux/concentration curves appear to follow the same pattern of concentration response.The flux/pH curves were bell-shaped and symmetric with regard to their pH dependence. The pH optimum is at approximately pH 6.5–6.7. The apparent pK of the activator site is in the range of 7.0 to 7.2, while the apparent pK for the inactivating site is in the range of 6.2 to 6.5. The pK-values were not appreciably affected by the phosphate concentration.According to our studies, the transport system possesses two transport sites and probably two modifier sites as indicated by the apparent Hill coefficients. In addition, the transport system has two proton binding sites, one with a higher pK that activates and one with a lower pK that inactivates the transport system. Since our experiments were executed under self-exchange conditions, they do not provide any information concerning the location of these sites at the membrane surfaces.     

Asymmetry of the Na+-succinate cotransporter in rabbit renal brush-border membranes

We have investigated the symmetry of Na⁺-succinate cotransport in rabbit renal brush-border membrane vesicles. Succinate influx and efflux kinetics were measured under voltage-clamped conditions using [¹⁴C]succinate and a rapid filtration procedure. Both influx and efflux were Na⁺-dependent, saturable, temperature-sensitive, and influenced by the trans Na⁺ and succinate concentrations. The system was judged to be asymmetric, since the maximal velocity for influx was 3-fold higher than that for efflux, and trans Na⁺ inhibited influx more than efflux. This may be due to the asymmetrical insertion of the transporter in the brush-border membrane, which leads to differences in either the forward and backward translocation rates of the fully loaded carrier or the Na⁺ and succinate binding constants at the inner and outer faces of the membrane.     

Effect of pH on the kinetics of Na+-dependent phosphate transport in rat renal brush-border membranes

The kinetics of Na+-dependent phosphate uptake in rat renal brush-border membrane vesicles were studied under zero-trans conditions at 37 degrees C and the effect of pH on the kinetic parameters was determined. When the pH was lowered it turned out to be increasingly difficult to estimate initial rates of phosphate uptake due to an increase in aspecific binding of phosphate to the brush border membrane. When EDTA or beta-glycerophosphate was added to the uptake medium this aspecific binding was markedly reduced. At pH 6.8, initial rates of phosphate uptake were measured between 0.01 and 3.0 mM phosphate in the presence of 100 mM Na+. Kinetic analysis resulted in a non-linear Eadie-Hofstee plot, compatible with two modes of transport: one major low-affinity system (Km approximately equal to 1.3 mM), high-capacity system (Vmax approximately equal to 1.1 nmol/s per mg protein) and one minor high-affinity (Km approximately equal to 0.03 mM), low-capacity system (Vmax approximately equal to 0.04 nmol/s per mg protein). Na+-dependent phosphate uptake studied far from initial rate conditions i.e. at 15 s, frequently observed in the literature, led to a dramatic decrease in the Vmax of the low-affinity system. When both the extra- and intravesicular pH were increased from 6.2 to 8.5, the Km value of the low-affinity system increased, but when divalent phosphate is considered to be the sole substrate for the low-affinity system then the Km value is no longer pH dependent. In contrast, the Km value of the high-affinity system was not influenced by pH but the Vmax decreased dramatically when the pH is lowered from 8.5 to 6.2. These results suggest that the low-affinity, high-capacity system transports divalent divalent phosphate only while the high-affinity, low-capacity system may transport univalent as well as divalent phosphate. Raising medium sodium concentration from 100 to 250 mM increased Na+-dependent phosphate uptake significantly but the pH dependence of the phosphate transport was not influenced. This observation makes it rather unlikely that pH changes only affect the Na+ site of the Na+-dependent phosphate transport system.     

Substrate specificity of the intestinal brush-border proline/sodium (IMINO) transporter

Summary l-proline uptake via the intestinal brush-borderIMINO carrier was tested for inhibition by 41 compounds which included sugars, N-methylated, -,-, - and -amino and imino acids, and heterocyclic analogs of pyrrolidine, piperidine and pyridine. Based on competitive inhibitor constants (apparentK/'s) we find that theIMINO carrier binding site interacts with molecules which possess a well-defined set of structural prerequisites. The ideal inhibitor must 1) be a heterocyclic nitrogen ring, 2) have a hydrophobic region, 3) be thel-stereoisomer of 4) an electronegative carbonyl group which is 5) separated by a one-carbon atom spacer from 6) an electropositive tetrahedral imino nitrogen with two H atoms. Finally, 7) the inhibitor conformation determined by dynamic ring puckering must position all these features within a critical domain. The two best inhibitors arel-pipecolate (apparentK/0.2mm) andl-proline (apparentK/0.3mm).     

Kinetic analysis of L-glutamine transport into porcine jejunal enterocyte brush-border membrane vesicles

L-Glutamine transport into porcine jejunal enterocyte brush border membrane vesicles was studied. Uptake was mediated by a Na(+)-dependent and a Na(+)-independent pathway as well as by diffusion. The initial rates of glutamine uptake over a range of concentrations is both Na(+)-gradient and Na(+)-free conditions were analyzed and kinetic parameters were obtained. Na(+)-dependent glutamine transport had a K(m) of 0.77 +/- 0.16 mM and a Jmax of 70.7 +/- 5.8 pmol mg protein-1 s-1; Na(+)-independent glutamine transport had a K(m) of 3.55 +/- 0.78 mM and a Jmax of 55.1 +/- 6.6 pmol mg protein-1 s-1. The non-saturable component measured with HgCl2-poisoned brush border membrane vesicles in the Na(+)-free condition contained passive diffusion and non-specific membrane binding and was defined to be apparent glutamine diffusion and the glutamine permeability coefficient (Kdiff) was estimated to be Kdiff = 3.78 +/- 0.06 pmol 1 mg protein-1 mmol-1 s-1. Results of inhibition experiments showed that Na(+)-dependent glutamine uptake occurred primarily through the brush border system-B degree transporters, whereas Na(+)-independent glutamine uptake occurred via the system-L transporters. Furthermore, the kinetics of L-leucine and L-cysteine inhibition of L-glutamine uptake demonstrated that neutral amino acids sharing the same brush border transporters can effectively inhibit each other in their transport.     

Role of substrate binding forces in exchange-only transport systems: II. Implications for the mechanism of the anion exchanger of red cells

Summary The transition-state theory of exchange-only membrane transport is applied to experimental results in the literature on the anion exchanger of red cells. Two central features of the system are in accord with the theory: (i) forming the transition state in translocation involves a carrier conformational change; (ii) substrate specificity is expressed in transport rates rather than affinities. The expression of specificity is consistent with other evidence for a conformational intermediate (not the transition state) formed in the translocation of all substrates. The theory, in conjunction with concepts derived from the chemistry of macrocyclic ion inclusion complexes, prescribes certain essential properties in the transport site. Separate substites are required for the preferred substrates. Cl^– and HCO ₃ ^– , to account for tight binding in the transition state (K _diss1m). Further, the following mechanism is suggested. A substrate anion initially forms a loose surface complex at one subsite, but in the transition state the subsites converge to form an inclusion complex in which the binding forces are greatly increased through a chelation effect. The conformational change at the substrate site, which is driven by the mounting forces of binding, sets in train a wider conformational change that converts the carrier from an immobile to a mobile form. Though simple, this composite-site mechanism explains many unsual features of the system. It accounts for substrate inhibition, partially noncompetitive inhibition of one substrate by another, and tunneling, which is net transport under conditions where exchange should prevail, according to other models. All three types of behavior result from the formation of a ternary complex in which substrate anions are bound at both subsites. The mechanism also accounts for the enormous range of substrate structures accepted by the system, for the complex inhibition by the organic sulfate NAP-taurine, and for the involvement of several cationic side chains and two different protein domains in the transport site.     

Membrane potential dependency of glutamic acid transport in rabbit jejunal brush-border membrane vesicles: K+ and H+ effects

We have applied our recently developed approach for quantitative generation and estimation of membrane potential differences (Berteloot, A. (1986) Biochim. Biophys. Acta 857, 180-188) to the reevaluation of glutamic acid transport rheogenicity in rabbit jejunal brush-border membrane vesicles. Membrane diffusion-potentials were created by altering iodide concentrations in the intra- and extravesicular compartments while keeping isosmolarity, isotonicity and ionic strength constant by chloride replacement. The known value of ion permeabilities relative to sodium in this preparation also allows calculation of membrane potential differences using the Goldman-Hodgkin-Katz equation. This strategy appears superior to more classical methods involving ionophore-induced membrane diffusion-potentials of protons or potassium as both cations have been shown to participate in the transport mechanism. In this paper, we demonstrate that this approach is perfectly suitable for the investigation of membrane potential dependency of glutamic acid transport as our results showed that chloride replacement by iodide did not affect uptake in vesicles with membrane potential clamped to zero by gramicidin D (sodium conditions) or by gramicidin D plus valimonycin (sodium + potassium conditions). The method thus allows to dissociate membrane potential effects from possible effects that might be introduced by altering the anion species. In these conditions, our studies clearly demonstrate that glutamic acid uptake, whether analyzed over a 1 min time scale or under initial rate conditions, was sensitive to membrane potential differences. However, our results also show that the electrogenicity of the transport system varied depending upon the intravesicular presence or absence of potassium, its presence stimulating the membrane potential dependency of uptake. This effect is modulated by the internal pH and it is concluded that inside H+ and K+ are not equivalent as countertransported cations. The external pH also seems to modulate the response to potential by acting on the fully loaded form(s) of the transporter. The possibility that outside H+ competes for (an) external Na+ binding site(s) and/or precludes the attachment of (an) extra sodium ion(s) should be considered.