Sodium gradient-dependent L-glutamate transport is localized to the canalicular domain of liver plasma membranes. Studies in rat liver sinusoidal and canalicular membrane vesicles

The driving forces for L-glutamate transport were determined in purified canalicular (cLPM) and basolateral (i.e. sinusoidal and lateral; blLPM) rat liver plasma membrane vesicles. Initial rates of L-glutamate uptake in cLPM vesicles were stimulated by a Na+ gradient (Na+o greater than Na+i), but not by a K+ gradient. Stimulation of L-glutamate uptake was specific for Na+, temperature sensitive, and independent of nonspecific binding. Sodium-dependent L-glutamate uptake into cLPM vesicles exhibited saturation kinetics with an apparent Km of 24 microM, and a Vmax of 21 pmol/mg X min at an extravesicular sodium concentration of 100 mM. Specific anionic amino acids inhibited L-[3H]glutamate uptake and accelerated the exchange diffusion of L-[3H]glutamate. An outwardly directed K+ gradient (K+i greater than K+o) further increased the Na+ gradient (Na+o greater than Na+i)-dependent uptake of L-glutamate in cLPM vesicles, resulting in a transient accumulation of L-glutamate above equilibrium values (overshoot). The K+ effect had an absolute requirement for Na+. In contrast, in blLPM the initial rates of L-glutamate uptake were only minimally stimulated by a Na+ gradient, an effect that could be accounted for by contamination of the blLPM vesicles with cLPM vesicles. These results indicate that hepatic Na+ gradient-dependent transport of L-glutamate occurs at the canalicular domain of the plasma membrane, whereas transport of L-glutamate across sinusoidal membranes results mainly from passive diffusion. These findings provide an explanation for the apparent discrepancy between the ability of various in vitro liver preparations to transport glutamate and suggest that a canalicular glutamate transport system may serve to reabsorb this amino acid from bile.     

The kinetics of sulfobromophthalein uptake by rat liver sinusoidal vesicles

The kinetics of bromo[35S]sulfophthalein (35S-BSP) binding by and uptake across the hepatocyte sinusoidal membrane were investigated using isolated rat liver sinusoidal membrane vesicles containing K+ as the principal internal inorganic cation. Uptake of 35S-BSP into vesicles was found to be temperature dependent, with maximum uptake between 35 and 40 degrees C; only binding occurred at or below 15 degrees C. Uptake at 37 degrees C was saturable and resolvable by Eadee-Hofstee analysis into two components: one with high affinity (Km = 53.1 microM) but low capacity, and the second of low affinity (Km = 1150 microM) but high capacity. By pre- or post-incubation, respectively, with unlabelled BSP, trans-stimulation and counter transport of 35S-BSP could also be demonstrated in these vesicles. Uptake was inhibited competitively using 5 microM Rose bengal and 10 microM indocyanine green, and non-competitively using 10 microM DIDS. Taurocholate did not inhibit uptake, and actually enhanced transport at concentrations greater than or equal to 250 microM. Imposition of inwardly directed inorganic ion gradients resulted in the enhancement of 35S-BSP transport when chloride ions were part of this gradient, irrespective of the cation employed whereas there was no apparent cation effect. However, substitution of 10 mM Na+ for 10 mM K+ as the internal cation resulted in a significant increase in uptake in the presence of external K+ as compared to Na+ gradients. This effect was not observed when 10 mM Tris+ was employed as the internal cation. The kinetics of 35S-BSP uptake by isolated sinusoidal membrane vesicles are indicative of facilitated transport. While the observed inorganic ion effects suggest a possible electrogenic component, the driving forces for hepatic BSP uptake remain uncertain. Isolated sinusoidal membrane vesicles provide a useful technique for studying hepatic uptake processes independent of circulatory or subsequent cellular phenomena.     

Na+-Ca2+ exchange in squid optic nerve membrane vesicles is activated by internal calcium

The role of intracellular Ca2+ as essential activator of the Na+-Ca2+ exchange carrier was explored in membrane vesicles containing 67% right-side-out and 10% inside-out vesicles, isolated from squid optic nerves. Vesicles containing 100 microM free calcium exhibited a 2-fold increase in the initial rate of Na+i-dependent Ca2+ uptake as compared with vesicles where intravesicular calcium was chelated by 2 mM EGTA or 10 mM HEDTA. The activatory effect exerted by intravesicular Ca2+ on the reverse mode of Na+-Ca2+ exchange (i.e. Na+i-Ca2+o exchange) is saturated at about 100 microM Ca2+i and displays an apparent K 1/2 of 12 microM. Intravesicular Ca2+ produced activation of Na+i-Ca2+i exchange activity rather than an increase in Ca2+ uptake due to Ca2+-Ca2+ exchange. The presence of Ca2+i was essential for the Na+i-dependent Na+ influx, a partial reaction of the Na+-Ca2+ exchanger. In fact, the Na+ influx levels in vesicles loaded with 2 mM EGTA were close to those expected from diffusional leak while in vesicles containing Ca2+i an additional Na+-Na+ exchange was measured. The results suggest that in nerve membrane vesicles Ca2+ at the inner aspect of the membrane acts as an activator of the Na+-Ca2+ exchange system.     

ATP-dependent proton uptake by proteoliposomes reconstituted with purified Na+,K+-ATPase

Proton transport catalyzed by the sodium pump was demonstrated using proteoliposomes reconstituted with purified pig kidney Na+,K+-ATPase. Intravesicular pH was monitored with fluorescence from fluorescein isothiocyanate dextran introduced into the vesicles. An ATP-induced ouabain-sensitive acidification of the intravesicular medium was observed, when the vesicles were incubated with ATP and without Na+. The ATP-induced acidification was blocked by either extravesicular Na+ or pretreatment of the enzyme with ouabain before reconstitution. Protonophores, X-537A or carbonyl cyanide m-chlorophenylhydrazone, abolished the intravesicular acidification. The acidification was not inhibited by 3 mM tetra-n-butylammonium. The initial rate of the H+ uptake was increased with a decrease in pH of the extravesicular medium, and the maximum rate was obtained at pH 5.5-5.6. It is concluded that H+ can be transported in place of Na+ by the sodium pump.     

Interactions of [14C]phosphonoformic acid with renal cortical brush-border membranes. Relationship to the Na+-phosphate co-transporter

Since phosphonoformic acid (PFA) acts as a specific competitive inhibitor of Na+-Pi co-transport across renal brush-border membrane (BBM), we employed the [14C]PFA as a probe to determine the mechanism of its interaction with rat renal BBM. The binding of [14C]PFA to BBM vesicles (BBMV), with Na+ present in extravesicular medium (Na+o), was time- and temperature-dependent. The replacement of Na+o with other monovalent cations reduced the PFA binding by -80%. Cl- was the most effective accompanying monovalent anion as NaCl for maximum PFA binding. The Na+o increased the apparent affinity of BBMV for [14C]PFA binding, but it did not change the maximum binding capacity. The maximum [14C]PFA binding was achieved at Na+o approximately equal to 50 mM. The extent of Na+-dependent [14C]PFA binding correlated (r = 0.98; p less than 0.01) with percent inhibition by an equimolar dose of PFA of the (Na+o greater than Na+i)-dependent BBMV uptake of 32Pi. Intravesicular Na+ (Na+i) decreased [14C]PFA binding, on BBMV, and this inhibition by Na+i was dependent on the presence of Na+o. The increase in Na+i, at constant [Na+]o, decreased the Vmax, but not the Km, for [14C]PFA binding on BBMV. Bound [14C]PFA was displaced from BBMV by phosphonocarboxylic acids proportionally (r = 0.99; p less than 0.05) to their ability to inhibit (Na+o greater than Na+i)-gradient-dependent Pi transport, whereas other monophosphonates, diphosphonates, L-proline, or D-glucose did not influence the [14C]PFA binding. The Na+-dependent binding of [14C]PFA and of [3H]phlorizin by BBMV was 10 times higher than binding of these ligands to renal basolateral membranes and to mitochondria. [14C]PFA probably binds onto the same locus on the luminal surface of BBM, where Pi and Na+ form a ternary complex with the Na+-Pi co-transporter.     

Na+-H+ exchange in cardiac sarcolemmal vesicles

The transport of Na+ by a purified sarcolemmal vesicular preparation from canine ventricular tissue was studied as a function of both internal and external pH. The uptake of Na+ into sarcolemmal vesicles increased upon raising the extravesicular pH of the reaction medium. Half-maximal uptake of Na+ was observed at a pHo of about 8.1 and maximal uptake occurred at pH 8.6. The uptake of Na+ by sarcolemma was also dependent upon the intravesicular pH. Na+ uptake into sarcolemmal vesicles was greatly attenuated in the absence of a H+ gradient across the membrane. Transport of Na+ was potently inhibited by amiloride, a known blocker of Na+-H+ exchange. LiCl was also an effective inhibitor of Na+ transport. In the presence of optimal H+ gradients, Na+ uptake was linear for the first 5 seconds of the reaction and exhibited a Vmax of 290 nmol Na+/mg per min and a KNa of 3.5 mM. These experiments strongly indicate the presence of a Na+-H+ exchange system in cardiac sarcolemma. This activity appeared to be relatively specific for this membrane fraction. The identification of Na+-H+ exchange activity in a sarcolemmal vesicular fraction from the heart will permit extensive characterization of the regulation and kinetics of this antiporter in future investigations.     

Demonstration of a Na+/H+ exchange activity in purified canine cardiac sarcolemmal vesicles

Purified canine cardiac sarcolemmal membrane vesicles exhibit a sodium ion for proton exchange activity (Na+/H+ exchange). Na+/H+ exchange was demonstrated both by measuring rapid 22Na uptake into sarcolemmal vesicles in response to a transmembrane H+ gradient and by following H+ transport in response to a transmembrane Na+ gradient with use of the probe acridine orange. Maximal 22Na uptake into the sarcolemmal vesicles (with starting intravesicular pH = 6 and extravesicular pH = 8) was approximately 20 nmol/mg protein. The extravesicular Km of the Na+/H+ exchange activity for Na+ was determined to be between 2 and 4 mM (intravesicular pH = 5.9, extravesicular pH = 7.9), as assessed by measuring the concentration dependence of the 22Na uptake rate and the ability of extravesicular Na+ to collapse an imposed H+ gradient. All results suggested that Na+/H+ exchange was reversible and tightly coupled. The Na+/H+ exchange activity was assayed in membrane subfractions and found most concentrated in highly purified cardiac sarcolemmal vesicles and was absent from free and junctional sarcoplasmic reticulum vesicles. 22Na uptake into sarcolemmal vesicles mediated by Na+/H+ exchange was dependent on extravesicular pH, having an optimum around pH 9 (initial internal pH = 6). Although the Na+/H+ exchange activity was not inhibited by tetrodotoxin or digitoxin, it was inhibited by quinidine, quinacrine, amiloride, and several amiloride derivatives. The relative potencies of the various inhibitors tested were found to be: quinacrine greater than quinidine = ethylisopropylamiloride greater than methylisopropylamiloride greater than dimethylamiloride greater than amiloride. The Na+/H+ exchange activity identified in purified cardiac sarcolemmal vesicles appears to be qualitatively similar to Na+/H+ exchange activities recently described in intact cell systems. Isolated cardiac sarcolemmal vesicles should prove a useful model system for the study of Na+/H+ exchange regulation in myocardial tissue.     

Preservation of sodium-dependent iodide transport activity by methimazole and mercaptoethanol in phospholipid vesicles containing thyroid plasma membranes: with evidence of difference in the action of perchlorate and thiocyanate

The effect of methimazole (MMI) and 2-mercaptoethanol (ME) on I-transport was studied using phospholipid vesicles (P-vesicles) made from porcine thyroid plasma membranes and soybean phospholipids by sonication. 1. When buffer solutions contained either 1 mM MMI or 2 mM ME, I-uptake by P-vesicles in the presence of external Na+ was apparently higher than that in the absence of external Na+. Na+-dependent I- uptake was inhibited by both C1O4- and SCN- added externally. 2. When PM was treated with 4 mM N-ethylmaleimide prior to preparation of P-vesicles, the activity of Na+-dependent I- transport was completely lost even when P-vesicles were incubated in the presence of ME. 3. When neither MMI nor ME was added to buffers, I- uptake in the presence of external Na+ was not at all higher than that in the absence of external Na+. In these instances, however, I- uptake was much higher compared than the baseline uptake in the presence of MMI or ME, and was inhibited by external SCN- and not by C1O4- without relation to external Na+. These data indicate that MMI or ME has two distinct effects on our model system of I- transport. The one is preservation of the Na+-dependent I- transport activity by protecting a sulfhydryl group, and the other is reduction of nonspecific I- binding to P-vesicles. In addition, C1O4- is a more specific inhibitor of thyroid I- transport than SCN-, when non-specific I- oxidation is imperfectly prevented.     

Na+-dependent alkaline earth metal uptake in cardiac sarcolemmal vesicles

The ability of alkaline earth metals (M2+) to substitute for Ca2+ in Na+-Ca2+ exchange was examined in sarcolemmal vesicles isolated from the canine heart. 85Sr2+ and 133Ba2+, in addition to 45Ca2+, were used to determine the characteristics of Na+-M2+ exchange. The Na+i-dependent M2+ uptake was measured as a function of time, with t ranging from 0.5 to 360 s, [Na+]i = 140 mM and [M2+]o = 40 microM. This function was linear for Ca2+ and Sr2+ uptake for approx. 6 s and for Ba2+ for about 60 s. Plateau levels were achieved within 120 s for Ca2+ and Sr2+ but Ba2+ took considerably longer. The Km values for Na+-M2+ exchange, derived from Eadie-Hofstee plots, were 30, 58, and 73 microM for Ca2+, Sr2+ and Ba2+, respectively. The Na+i-dependent uptake of all three ions was stimulated in the presence of 0.36 microM valinomycin. Na+-Ca2+ exchange was also measured in the presence of either 20 microM Sr2+ or 100 microM Ba2+. Both of these ions behaved (at these concentrations) as competitive inhibitors of Na+-Ca2+ exchange with the KI being 32 microM for Sr2+ and 92 microM for Ba2+. Passive efflux was determined by first allowing Na+-M2+ exchange to continue to plateau values and then diluting the loaded vesicles in the presence of EGTA. The rate constants for the passive efflux were 8.4, 6.3 and 4.4 min-1 for Ca2+, Sr2+ and Ba2+, respectively.     

Effect of intravesicular monovalent cations on the steady state of the phosphoenzyme of adenosine triphosphatase dependent on sodium and potassium ions in inside-out plasma-membrane vesicles.

Phosphorylation of the ATPase dependent on Na+ and K+ is promoted through the synergistic action of cations on both sides of the membrane. This phenomenon has been observed in plasma membrane vesicles isolated from sheep-kidney outer medulla which accept ATP from the outside surface (inside-out) and which are tight for sodium ions. In these inside-out vesicles phosphorylating capacity is low even in the presence of 100 mM extravesicular sodium chloride as is turnover of the enzyme. The level of the phosphoenzyme and the transient release of inorganic phosphate from the phosphoenzyme increases several-fold when sodium chloride is allowed to equilibrate over the membrane, 25 mM intravesicular NaCl is necessary to obtain the half-maximum level of the phosphoenzyme. This result shows that intravesicular (= extracellular) low affinity sites are involved in the phosphorylation. Intravesicular potassium ions modify the activating action of Na+ on the phosphorylation by increasing the steady state of the phosphoenzyme at low intravesicular sodium ion concentrations. This suggests that Na+ and K+ compete with each other for the intravesicular cation-binding site.     

Transport of methotrexate in basolateral membrane vesicles from rat liver.

Transport of the antifolate cancer drug methotrexate was studied in vesicles isolated from the basolateral membrane of rat liver. Transport of methotrexate by basolateral membrane vesicles (BLMVs) was mostly via uptake into an osmotically active intravesicular space, with some binding (approximately 9%), as shown by initial uptake studies and by varying medium osmolarity with increasing concentrations of sucrose. Methotrexate transport was linear for the first 20 s of incubation. Transport was not affected by imposition of a Na+ gradient across the vesicular membrane. Transport of methotrexate displayed a broad pH optimum: at an intravesicular pH of 7.5, the initial rate of uptake was not significantly different at extravesicular pH values ranging from 5.5 to 7.5, but uptake was less at extravesicular pH of 5.0 or 8.0. Methotrexate transport was saturable: Km = 0.15 +/- 0.05 microM and Vmax = 11.4 +/- 1.1 pmol 10 s-1 mg-1 protein. Methotrexate uptake into BLMVs was not inhibited by 5-methyltetrahydrofolate nor by 5-formyltetrahydrofolate but was weakly inhibited by folic acid in a concentration-dependent manner. Uptake was also inhibited by anion-exchange inhibitor 4,4'-diisothio-cyanostilbene-2,2'-disulfonic acid (DIDS), and by the structurally unrelated anions ATP, ADP, Cl-, SO4(2-), and oxalate2-. Adenosine (no negative charge) had no effect on transport. When vesicles were preloaded with anions (ADP, SO4(2-), oxalate2-) such that an anion gradient existed from the intra- to the extravesicular compartment, and methotrexate uptake was measured, no stimulation of uptake was seen. Methotrexate uptake into rat liver BLMVs was electrogenic as shown by stimulation of the initial rate of uptake by a valinomycin-imposed K+ diffusion potential across the vesicular membrane. These results suggest that methotrexate is transported into the hepatocyte across the basolateral membrane by an electrogenic, multispecific anion carrier system.     

High affinity binding of amiloride analogs at an internal site in renal microvillus membrane vesicles.

Amiloride analogs with hydrophobic substitutions on the 5-amino nitrogen atom are relatively high affinity inhibitors of the plasma membrane Na(+)-H+ exchanger. We demonstrated that a high affinity-binding site for [3H]5-(N-methyl-N-isobutyl)amiloride ([3H]MIA) (Kd = 6.3 nM, Bmax = 1.2 pmol/mg of protein) is present in microvillus membrane vesicles but not in basolateral membrane vesicles isolated from rabbit renal cortex, in accord with the known membrane localization of the Na(+)-H+ exchanger in this tissue. The rank order potency for inhibition of microvillus membrane [3H]MIA binding by amiloride analogs was: MIA (I50 approximately 10 nM) greater than amiloride (I50 approximately 200 nM) greater than benzamil (I50 approximately 1200 nM). This correlated with a qualitatively similar rank order potency for inhibition of Na(+)-H+ exchange: MIA (I50 approximately 4 microM) greater than amiloride (I50 approximately 15 microM) greater than benzamil (I50 approximately 100 microM), but did not correlate with the rank order potency for inhibition of the organic cation-H+ exchanger in microvillus membrane vesicles: MIA approximately benzamil (I50 approximately 0.5 microM) greater than amiloride (I50 approximately 10 microM). However, tetraphenylammonium, an inhibitor of organic cation-H+ exchange, inhibited the rate of [3H]MIA binding without an effect on equilibrium [3H]MIA binding; the dissociation of bound [3H]MIA was inhibited by preloading the membrane vesicles with tetraphenylammonium. These findings indicated that high affinity [3H]MIA binding to renal microvillus membrane vesicles takes place at an internal site to which access is rate-limited by the tetraphenylammonium-sensitive organic cation transporter. Equilibrium [3H]MIA binding was inhibited by H+ but was unaffected by concentrations of Na+ or Li+ that saturate the external transport site of the Na(+)-H+ exchanger. Binding of MIA to its high affinity binding site had no effect on the rate of Na(+)-H+ exchange. This study suggests that the renal Na(+)-H+ exchanger has a high affinity internal binding site for amiloride analogs that is distinct from the external amiloride inhibitory site.     

Uptake of [3H]serotonin into plasma membrane vesicles from mouse cerebral cortex

Preparations of plasma membrane vesicles were used as a tool to study the properties of the serotonin transporter in the central nervous system. The vesicles were obtained after hypotonic shock of synaptosomes purified from mouse cerebral cortex. Uptake of [3H]serotonin had a Na+-dependent and Na+-independent component. The Na+-dependent uptake was inhibited by classical blockers of serotonin uptake and had a Km of 63-180 nM, and a Vmax of 0.1-0.3 pmol mg-1 s-1 at 77 mM Na+. The uptake required the presence of external Na+ and internal K+. It required a Na+ gradient ([Na+]out greater than [Na+]in) and was stimulated by a gradient of K+ ([K+]in greater than [K+]out). Replacement of Cl- by other anions (NO2-, S2O3-(2-)) reduced uptake appreciably. Gramicidin prevented uptake. Although valinomycin increased uptake somewhat, the membrane potential per se could not drive uptake because no uptake was observed when a membrane potential was generated by the SCN- ion in the absence of internal K+ and with equal [Na+] inside and outside. The increase of uptake as a function of [Na+] indicated a Km for Na+ of 118 mM and a Hill number of 2.0, suggesting a requirement of two sodium ions for serotonin transport. The present results are accommodated very well by the model developed for porcine platelet serotonin transport (Nelson, P. J., and Rudnick, G. (1979) J. Biol. Chem. 254, 10084-10089), except for the number of sodium ions that are required for transport.     

Na+/Ca2+ exchange in plasma membrane vesicles from a glucose-responsive insulinoma.

Plasma membrane vesicles from a glucose-responsive insulinoma exhibited properties consistent with the presence of a membrane Na+/Ca2+ exchange. The exchange was rapid, reversible, and was dependent on the external Ca2+ concentration (Km = 4.1 +/- 1.1 microM). External Na+ inhibited the uptake in a dose-dependent manner (IC50 = 15 mM). Dissipation of the Na+ gradient by 10 microM monensin decreased Na+/Ca2+ exchange from 0.74 +/- 0.17 nmoles/mg protein/s to 0.11 +/- 0.05 nmoles/mg protein/s. Exchange was not influenced by veratridine, tetrodotoxin and ouabain, or by modifiers of cAMP. No effect was seen using the calcium channel blockers, nitrendipine or nifedipine. Glucose had no direct effect on Na+/Ca2+ exchange, while glyceraldehyde, glyceraldehyde-3-phosphate and dihydroxyacetone inhibited the exchange. Na+ induced efflux of calcium was seen in Ca2+ loaded vesicles and was half maximal at [Na+] of 11.1 +/- 0.75 mM. Ca2+ efflux was dependent on [Na+], with a Hill coefficient of 2.7 +/- 0.07 indicating that activation of Ca2+ release involves a minimum of three sites. The electrogenicity of this exchange was demonstrated using the lipophilic cation tetraphenylphosphonium [( 3H]-TPP), a membrane potential sensitive probe. [3H]-TPP uptake increased transiently during Na+/Ca2+ exchange indicating that the exchange generated a membrane potential. These results show that Na+/Ca2+ exchange operates in the beta cell and may be an important regulator of intracellular free Ca2+ concentrations.     

Ion specificity of cardiac sarcolemmal Na+/H+ antiporter

In bovine cardiac sarcolemmal vesicles, an outward H+ gradient stimulated the initial rate of amiloride-sensitive uptake of 22Na+, 42K+, or 86Rb+. Release of H+ from the vesicles was stimulated by extravesicular Na+, K+, Rb+, or Li+ but not by choline or N-methylglucamine. Uptakes of Na+ and Rb+ were half-saturated at 3 mM Na+ and 3 mM Rb+, but the maximal velocity of Na+ uptake was 1.5 times that of Rb+ uptake. Na+ uptake was inhibited by extravesicular K+, Rb+, or Li+, and Rb+ uptake was inhibited by extravesicular Na+ or Li+. Amiloride-sensitive uptake of Na+ or Rb+ increased with increase in extravesicular pH and decrease in intravesicular pH. In the absence of pH gradient, there were stimulations of Na+ uptake by intravesicular Na+ and K+ and of Rb+ uptake by intravesicular Rb+ and Na+. Similarly, there were trans stimulations of Na+ and Rb+ efflux by extravesicular alkali cations. The data suggest the existence of a nonselective antiporter catalyzing either alkali cation/H+ exchange or alkali cation/alkali cation exchange. Since increasing Na+ caused complete inhibition of Rb+/H+ exchange, but saturating K+ caused partial inhibitions of Na+/H+ exchange and Na+/Na+ exchange, the presence of a Na(+)-selective antiporter is also indicated. Although both antiporters may be involved in pH homeostasis, a role of the nonselective antiporter may be in the control of Na+/K+ exchange across the cardiac sarcolemma.     

Inhibition of the Na+/I- symporter by harmaline and 3-amino-1-methyl-5H-pyrido(4,3-b)indole acetate in thyroid cells and membrane vesicles

Novel inhibitors of the Na+/I- symporter were identified using rat-thyroid-derived FRTL-5 cells and sealed vesicles from calf thyroid as model systems. Na(+)-dependent 125I- uptake was inhibited by the hallucinogenic drug harmaline and by a chemically related convulsive agent, 3-amino-1-methyl- 5H-pyrido(4,3-b)indole acetate (TRP-P-2). TRP-P-2 (Ki = 0.25 mM) was tenfold more effective as an inhibitor than harmaline (Ki = 4.0 mM). Inhibition by TRP-P-2 was competitive with respect to Na+ and was fully reversible. Although TRP-P-2 is a relatively low-affinity inhibitor, its affinity for the Na+ site of the Na+/I- symporter is over 100 times higher than that of Na+ (Km = 50 mM). 45Ca(2+)-efflux rates in calf thyroid membrane vesicles were not affected by TRP-P-2, indicating that membrane integrity is not disrupted by the drug. These findings show that TRP-P-2 may be a potentially useful tool for the identification and characterization of the Na+/I- symporter.     

Spermine uptake by rat intestinal brush-border membrane vesicles

The uptake of spermine by isolated rat intestinal brush-border membrane vesicles was studied. Uptake was biphasic, with an initial rapid uptake followed by a prolonged slower phase. Spermine uptake was not affected by a Na+ electrochemical gradient. The equilibrium uptake of spermine was considerably dependent upon the medium pH. At pH 7.5 the degree of uptake was higher than that at pH 6.5 and was inversely proportional to the extravesicular osmolarity with a relatively high binding, which was estimated by extraporation to infinite extravesicular osmolarity (zero intravesicular space), while the uptake at pH 6.5 was not altered under the various medium osmolarities. A kinetic analysis of the initial uptake rate of spermine at 37 degrees C gave a Km of 24.2 microM and Vmax of 206.1 pmol/mg protein per min. Furthermore, the uptake at 4 degrees C was nonlinear, providing evidence for saturability. These findings suggest that spermine was associated with intestinal brush-border membrane vesicles in two ways, by binding to the outside and inside of membrane vesicles. The interaction of spermine and the apical membrane can be a contributory factor in the accumulation of this polyamine in the intestine of the intact animal.     

Matrix free Ca2+ in isolated chromaffin vesicles

Isolated secretory vesicles from bovine adrenal medulla contain 80 nmol of Ca2+ and 25 nmol of Mg2+ per milligram of protein. As determined with a Ca2+-selective electrode, a further accumulation of about 160 nmol of Ca2+/mg of protein can be attained upon addition of the Ca2+ ionophore A23187. During this process protons are released from the vesicles, in exchange for Ca2+ ions, as indicated by the decrease of the pH in the incubation medium or the release of 9-aminoacridine previously taken up by the vesicles. Intravesicular Mg2+ is not released from the vesicles by A23187, as determined by atomic emission spectroscopy. In the presence of NH4Cl, which causes the collapse of the secretory vesicle transmembrane proton gradient (delta pH), Ca2+ uptake decreases. Under these conditions A23187-mediated influx of Ca2+ and efflux of H+ cease at Ca2+ concentrations of about 4 microM. Below this concentration Ca2+ is even released from the vesicles. At the Ca2+ concentration at which no net flux of ions occurs the intravesicular matrix free Ca2+ equals the extravesicular free Ca2+. In the absence of NH4Cl we determined an intravesicular pH of 6.2. Under these conditions the Ca2+ influx ceases around 0.15 microM. From this value and the known pH across the vesicular membrane an intravesicular matrix free Ca2+ concentration of about 24 microM was calculated. This is within the same order of magnitude as the concentration of free Ca2+ in the vesicles determined in the presence of NH4Cl.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fe2+ uptake by intestinal brush-border membrane vesicles from normal and hypoxic mice

Fe2+ uptake by mouse intestinal brush-border membrane vesicles consists of two components: a rapid, high affinity (Kd less than 1 microM), low capacity binding (less than 2 nmol/mg protein), presumably to the outside of the vesicles, and a second, large capacity component with an initial rate showing a hyperbolic dependence on medium Fe2+ (Km 35-90 microM). The latter, predominant process is relatively independent of medium ascorbate: Fe2+ ratio, is inhibited by Co2+ and Mn2+ but varies greatly from one membrane preparation to another. This component is strongly inhibited by large extravesicular NaCl and KCl concentrations and may represent transport into the vesicles. No significant change in uptake could be observed in vesicles prepared from hypoxic mice.     

Mechanisms of taurocholate transport in canalicular and basolateral rat liver plasma membrane vesicles. Evidence for an electrogenic canalicular organic anion carrier

The driving forces for taurocholate transport were determined in highly purified canalicular (cLPM) and basolateral rat liver plasma membrane (LPM) vesicles. Alanine transport was also examined for comparison. Inwardly directed Na+ but not K+ gradients transiently stimulated [3H]taurocholate (1 microM) and [3H]alanine (0.2 mM) uptake into basolateral LPM 3-4- fold above their respective equilibrium values (overshoots). Na+ also stimulated [3H]taurocholate countertransport and tracer exchange in basolateral LPM whereas valinomycin-induced inside negative K+ diffusion potentials stimulated alanine uptake but had no effect on taurocholate uptake. In contrast, in the "right-side out" oriented cLPM vesicles, [3H]taurocholate countertransport and tracer exchange were not dependent on Na+. Efflux of [3H]taurocholate from cLPM was also independent of Na+ and could be trans-stimulated by extra-vesicular taurocholate. Furthermore, an inside negative valinomycin-mediated K+ diffusion potential inhibited taurocholate uptake into and stimulated taurocholate efflux from the cLPM vesicles. These studies provide direct evidence for a "carrier mediated" and potential-sensitive conductive pathway for the canalicular excretion of taurocholate. In addition, they confirm the presence of a possibly electroneutral Na+-taurocholate cotransport system in basolateral membranes of the hepatocyte.