Efflux of preloaded iodide from the thyroid induced by externally added iodide. A study using a biological model of the thyroid iodide transport system

Efflux of preloaded I- from the thyroid induced by externally added I- was studied using a biological model of the thyroid I- transport system. Phospholipid vesicles (P-vesicles) made from thyroid plasma membranes and soybean phospholipids were capable of accumulating I- in the presence of external Na+. P-vesicles incubated in 136 mM Na+ containing 0.9 microM I- with 125I- for 2 min accumulated I- so that the I- concentration in the vesicles became about 2 microM. Addition of 5-20 microM stable I- to the incubation mixture at 2 min incubation resulted in a dose-dependent decrease in previously loaded 125I- in the vesicles. In other words, a dose-dependent increase in efflux of preloaded 125I- was observed. While the efflux occurred, Na+-dependent I- influx into P-vesicles was preserved. When 2 mM ClO4-, a specific inhibitor of Na+-dependent I- influx, was added together with 10 microM I-, the external I- failed to diminish preloaded 125I- in P-vesicles. The 125I- efflux did not occur when a large amount of stable I- entered P-vesicles independently of Na+ in the presence of ClO4-. Similar 125I- efflux induced by externally added 5 microM SCN- was also blocked by simultaneously added ClO4-. These observations suggest that such I- efflux from the thyroid is a certain type of uphill I- transport which is closely related to Na+-dependent I- transport and that ClO4- and SCN- act on a common site of the I- transport system.     

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.     

Molecular mechanism of iodide transport by thyroid plasmalemmal vesicles: cooperative sodium activation and asymmetrical affinities for the ions on the outside and inside of the vesicles

The 125I- uptake by plasmalemmal vesicles from porcine thyroid was measured by a Millipore filtration method using 2 mM ClO4- as a reaction stopper. Effective uptake occurred in the presence of high concentrations of extravesicular Na+ (Na+o). In the presence of Na-ionophores such as monensin and nigericin, no uptake was observed and the accumulated I- was released. The initial rate of I- uptake increased with the concentration of extravesicular I- (I-o) according to simple saturation kinetics and [I-o] giving a half-maximum rate of about 5 microM. The dependence of the rate on [Na+o] showed cooperativity with a Hill coefficient of 1.8, and a KNa value of 0.0064 M2, suggesting that the binding of at least 2 Na+ ions to a carrier molecule was required to transport an I- ion. Further kinetic data were consistent with a mechanism in which bindings of the ions were rapid and the Na+ binding occurred prior to the I- binding. Intravesicular Na+ inhibited the I- uptake and the inhibition constant (KiNa) was about 4 mM, independently of [I-o] and [Na+o]. Intravesicular I- inhibited the I- uptake with an apparent KiI value of about 100 microM. The results suggest that the differences in the Na+- and I- -binding modes between outside and inside of the vesicles are important factors causing the I- uptake against its concentration gradient.     

The effect of ionic strength on the lipid peroxidation of porcine intestinal brush-border membrane vesicles

The effects of salt concentration gradient (inside to outside) on the lipid peroxidation of porcine intestinal brush-border membrane vesicles have been studied and several interesting features of the peroxidation have been elucidated. The addition of dithiothreitol and Fe2+ is far more effective in induction of the lipid peroxidation than any of the other metal ion species tested (Fe3+, Cu2+, Ni2+, Zn2+ and Cr3+). The peroxidation rate of the membrane vesicles induced by dithiothreitol plus Fe2+ was sensitive for the incubation temperature and was increased with increase of the temperature. Imposition of an inward salt concentration gradient on the membrane vesicles preloaded with 300 mM mannitol by addition of 100 mM chloride of K+, Na+, Li+, Rb+, NH4+ or choline to medium produces a very large reduction of the lipid peroxidation induced by dithiothreitol plus Fe2+. The membrane peroxidation is depressed more with the mannitol (300 mM)-preloaded vesicles than with the K2SO4 (100 mM)-preloaded vesicles when they are incubated in medium containing 20-100 mM of K2SO4. Addition of membrane-permeant anions such as SCN- and I-, but not addition of NO3-, to incubation medium has been found to decrease markedly the lipid peroxidation of the mannitol-preloaded vesicles. From these results it is suggested that the lipid peroxidation of the brush-border membranes by addition of dithiothreitol plus Fe2+ is sensitively changed with change in ionic strength.     

Expression of the thyroid sodium/iodide symporter in Xenopus laevis oocytes

Poly(A+) RNA isolated from FRTL-5 cells (a continuous line of cultured and fully functional rat thyroid cells (Ambesi-Impiombato, F. S., Parks, L. A. M., and Coons, H. G. (1980) Proc. Natl. Acad. Sci. U. S. A. 77, 3455-3459] was injected into Xenopus laevis oocytes, and the expression of the Na+/I- symporter in the plasma membrane was assayed by measuring the Na+-dependent ClO4--sensitive uptake of 125I. Expression of the Na+/I- symporter was detected as a 7-fold average increase in transport over background, 5-6 days after injection. Poly(A+) RNA was subsequently fractionated by sucrose gradient centrifugation, and fractions were assayed for their ability to induce I- transport activity. The poly(A+) RNA encoding the Na+/I- symporter was found in a fraction containing messages of 2.8-4.0 kilobases in length.     

The electrogenic, Na+-dependent I- transport system in plasma membrane vesicles from thyroid glands

Using vesicles from the plasma membrane of hog thyroid, we have characterized its Na+-dependent I- transport system. We have found it to be totally Na+ dependent; K+ cannot substitute and Li+ can partially substitute for Na+; the Na+:I- flux ratio is larger than one; the system is electrogenic, being stimulated by a delta psi negative inside the vesicles. A number of large, lipophilic anions are fully-competitive inhibitors of Na+-dependent I- uptake; the closer their atomic radii are to that of iodine, the smaller their Ki values.     

Characterization of Na+-dependent phosphate transport in cardiac sarcolemmal vesicles

Pi uptake by purified bovine cardiac sarcolemmal vesicles was stimulated by an inwardly directed Na+ gradient, but not by such gradients of K+, Rb+, Li+, and choline. When Na+ was present both inside and outside the vesicles, or when Na+ gradient was dissipated by monensin, the Na+-dependent Pi uptake increased with time, reached a peak, and then declined approaching a steady state. The initial rate of Na+-dependent Pi uptake was a saturable function of Pi concentration (Km = 0.5 mM). These findings indicate the existence of a Na+,Pi-cotransporter in the sarcolemma. The Na+-activation curve of the Pi uptake exhibited positive cooperativity, suggesting the requirement for multiple Na+ binding to the functional unit of the carrier. The initial rate of Na+-dependent Pi uptake decreased as extra-vesicular pH increased in the range of 5.5-8.7. The uptake rate increased under conditions that are known or expected to generate an inside-negative membrane potential, indicating that Pi uptake is accompanied by the uptake of positive charge. These results suggest the electrogenic cotransports of two Na+ and one H2PO4-. We conclude that this cotransporter catalyzes the secondary active transport of Pi across the cardiac plasma membrane and regulates myocardial energy metabolism. We also suggest that the cotransporter may control intracellular Na+ and thus be involved in the regulation of trans-sarcolemmal Ca2+ movement and cardiac contractility.     

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.     

Characteristics of D-alanine transport by luminal membrane vesicles from pars convoluta and pars recta of rabbit proximal tubule

Uptake of D-alanine against a concentration gradient has been shown to occur with isolated luminal-membrane vesicles from pars convoluta or pars recta of rabbit proximal tubule. Renal D-alanine transport systems, displaying the following characteristics, were shown: (1) In vesicles from pars convoluta, the uptake of D-alanine was mediated by both Na+-dependent and Na+-independent transport processes. It was found that an inwardly directed H+-gradient could drive the transport of D-alanine into the vesicles both in the presence and absence of Na+. Thus, in addition to Na+, the transport of D-alanine is influenced by the H+-gradient. (2) In vesicles from pars recta, the transient accumulation of D-alanine was strictly dependent on Na+, since no 'overshoot' was ever observed in the absence of Na+. Although the Na+-dependent uptake of D-alanine was stimulated at acid pH, H+ did not substitute for Na+, as it apparently does in pars convoluta, but instead potentiated the Na+ effect. (3) Addition of L-alanine to vesicle preparations, both from pars convoluta and from pars recta, specifically inhibited renal uptake of D-alanine. A comparison between the transport characteristics of D- and L-alanine indicated that these two isomers of alanine probably share common transport systems located along the proximal tubule of rabbit kidney.     

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.     

The asymmetric effect of lanthanides on Na+-gradient-dependent Ca2+ transport in synaptic plasma membrane vesicles

Lanthanides (La3+, Pr3+ and Tb3+) inhibit Na+-gradient-dependent Ca2+ influx into synaptic plasma membrane vesicles. 50% inhibition is obtained by 7 microM lanthanide concentration. The inhibition of the Na+-gradient-dependent Ca2+ uptake exhibits competitive kinetic behaviour. The apparent Km of the Ca2+ influx is increased from 50 microM in the absence of lanthanides to 118 microM in the presence of La3+, 170 microM in the presence of Pr3+ and 130 microM in the presence of Tb3+. The maximal reaction velocity is not altered (8.35 nmol Ca2+ transported per mg protein per min in the absence of lanthanides and 8.16 nmol/mg per min in the presence of lanthanides). Lanthanides also inhibited Na+-gradient-dependent Ca2+ efflux from synaptic plasma membrane vesicles that were preloaded with Ca2+ in a Na+-gradient-dependent manner. Introduction of La3+ into the interior of the synaptic plasma membrane vesicles by rapid freezing of the vesicles in liquid N2 and slow thawing had no effect on either Na+-gradient-dependent Ca2+ influx or efflux. Synaptic plasma membrane vesicles can be preloaded with Ca2+ also in an ATP-dependent manner. This form of Ca2+ uptake is also inhibited by La3+ though at higher concentrations than the Na+-gradient-dependent Ca2+ uptake. Na+-gradient-dependent efflux from synaptic plasma membrane vesicles preloaded in an ATP-dependent fashion ('inside-out' vesicles) unlike efflux from synaptic plasma membrane vesicles preloaded in a Na+-gradient-dependent manner was not inhibited by La3+. These findings suggest that the inhibition by La3+ is manifested asymmetrically on both sides of the synaptic plasma membrane. Lanthanides are probably not transported via the Na+-Ca2+ exchanger since Tb3+ entry measured by fluorescence of Tb3+-dipicolinic acid complex formation occurred at high Tb3+ concentrations only (1.5 mM or above) and was not Na+-gradient dependent.     

Counterflow of L-glutamate in plasma membrane vesicles and reconstituted preparations from rat brain

Membrane vesicles from rat brain exhibit sodium-dependent uptake of L-[3H]glutamate in the absence of any transmembrane ion gradients. The substrate specificity of the process is identical with (Na+ + K+)-coupled L-glutamate accumulation. Although these vesicles are prepared after osmotic shock and are washed repeatedly, they contain about 1.5 nmol/mg of protein endogenous L-glutamate, apparently located inside the vesicles. The affinity of the process (Km approximately 1 microM) is similar to that of (Na+ + K+)-dependent accumulation by the L-glutamate transporter. Membrane vesicles have been disrupted by the detergent cholate, and the solubilized proteins have been subsequently reconstituted into liposomes. The reconstituted proteoliposomes also exhibit the above uptake--with the same characteristics--provided they contain entrapped cold L-glutamate. Counterflow is optimal when sodium is present on both sides of the membrane, but partial activity is still observed when sodium is present either on the inside or on the outside. Increasing the L-glutamate concentration above the Km results in counterflow completely independent of cis sodium. The initial rate of counterflow is 100-200-fold lower than that of net trans potassium dependent flux. The rate of net flux in the presence of trans sodium or lithium is about 10-fold lower than when choline or Tris are used instead. However, the rate of counterflow (no internal potassium present) was not stimulated by replacing internal sodium or lithium by internal choline. Therefore, optimal functioning of the transporter requires internal potassium while internal sodium and lithium are inhibitory.(ABSTRACT TRUNCATED AT 250 WORDS)     

K+-independent active transport of Na+ by the (Na+ and K+)-stimulated adenosine triphosphatase

The (Na+ and K+)-stimulated adenosine triphosphatase (Na+,K+)-ATPase) from canine kidney reconstituted into phospholipid vesicles showed an ATP-dependent, ouabain-inhibited uptake of 22Na+ in the absence of added K+. This transport occurred against a Na+ concentration gradient, was not affected by increasing the K+ concentration to 10 microM (four times the endogenous level), and could not be explained in terms of Na+in in equilibrium Na+out exchange. K+-independent transport occurred with a stoichiometry of 0.5 mol of Na+ per mol of ATP hydrolyzed as compared with 2.9 mol of Na+ per mol of ATP for K+-dependent transport.     

Inhibition of Na+-Ca2+ exchange in heart sarcolemmal vesicles by phosphatidylethanolamine N-methylation

The effect of phosphatidylethanolamine N-methylation on Na+-Ca2+ exchange was studied in sarcolemmal vesicles isolated from rat heart. Phosphatidylethanolamine N-methylation following incubation of membranes with S-adenosyl-L-methionine, a methyl donor for the enzymatic N-methylation, inhibited Nai+-dependent Ca2+ uptake by about 50%. The N-methylation reaction did not alter the passive permeability of the sarcolemmal vesicles to Na+ and Ca2+ and did not modify the electrogenic characteristics of the exchanger. The depressant effect of phosphatidylethanolamine N-methylation on Nai+-dependent Ca2+ uptake was prevented by S-adenosyl-L-homocysteine, an inhibitor of the N-methylation. Pretreatment of sarcolemma with methyl acetimidate hydrochloride, an amino-group-blocking agent, also prevented methylation-induced inhibition of Ca2+ uptake. In the presence of exogenous phospholipid substrate, the phospholipid N-methylation process in methyl-acetimidate-treated sarcolemmal vesicles was restored and the inhibitory effect on Ca2+ uptake was evident. These results suggest that phosphatidylethanolamine N-methylation influences the heart sarcolemmal Na+-Ca2+ exchange system.     

The C-terminally truncated NuoL subunit (ND5 homologue) of the Na+-dependent complex I from Escherichia coli transports Na+

The NADH:quinone oxidoreductase (complex I) from Escherichia coli acts as a primary Na+ pump. Expression of a C-terminally truncated version of the hydrophobic NuoL subunit (ND5 homologue) from E. coli complex I resulted in Na+-dependent growth inhibition of the E. coli host cells. Membrane vesicles containing the truncated NuoL subunit (NuoLN) exhibited 2-4-fold higher Na+ uptake activity than control vesicles without NuoLN. Respiratory proton transport into inverted vesicles containing NuoLN decreased upon addition of Na+, but was not affected by K+, indicating a Na+-dependent increase of proton permeability of membranes in the presence of NuoLN. The His-tagged NuoLN protein was solubilized, enriched by affinity chromatography, and reconstituted into proteoliposomes. Reconstituted His6-NuoLN facilitated the uptake of Na+ into the proteoliposomes along a concentration gradient. This Na+ uptake was prevented by EIPA (5-(N-ethyl-N-isopropyl)-amiloride), which acts as inhibitor against Na+/H+ antiporters.     

Solubilization and reconstitution of the Na(+)-dependent citrate carrier of Klebsiella pneumoniae

The citrate carrier of Klebsiella pneumoniae fermenting this substrate has been solubilized from the bacterial membranes with Triton X-100. The transport function was reconstituted by incorporation of the carrier into proteoliposomes using a freeze-thaw sonication procedure. Citrate uptake into these proteoliposomes required the presence of Na+ ions on the outside; the amount of citrate accumulated increased as the external Na+ concentration increased from 0 to 100 mM. Proteoliposomes preloaded with citrate catalyzed citrate counterflow when added to external [14C] citrate. Sodium ions were required for counterflow activity. The kinetics of citrate uptake, counterflow, or efflux were not influenced by an inside negative membrane potential, and the presence of the uncoupler carbonyl cyanide p-trifluoromethoxyphenylhydrazone was without effect on citrate uptake. The data therefore suggest an electroneutral Na(+)-citrate symport mechanism for the transport of this tricarboxylic acid into K. pneumoniae.     

Phosphate transport into brush-border membrane vesicles isolated from rat small intestine.

Uptake of Pi into brush-border membrane vesicles isolated from rat small intestine was investigated by a rapid filtration technique. The following results were obtained. 1. At pH 7.4 in the presence of a NaCl gradient across the membrane (sodium concentration in the medium higher than sodium concentration in the vesicles), phosphate was taken up by a saturable transport system, which was competitively inhibited by arsenate. Phosphate entered the same osmotically reactive space as D-glucose, which indicates that transport into the vesicles rather than binding to the membranes was determined. 2. The amount of phosphate taken up initially was increased about fourfold by lowering the pH from 7.4 to 6.0.3. When Na+ was replaced by K+, Rb+ or Cs+, the initial rate of uptake decreased at pH 7.4 but was not altered at pH 6.0.4. Experiments with different anions (SCN-,Cl-, SO42-) and with ionophores (valinomycin, monactin) showed that at pH 7.4 phosphate transport in the presence of a Na+ gradient is almost independent of the electrical potential across the vesicle membrane, whereas at pH 6.0 phosphate transport involves the transfer of negative charge. It is concluded that intestinal brush-border membranes contain a Na+/phosphate co-transport system, which catalyses under physiological conditions an electroneutral entry of Pi and Na+ into the intestinal epithelial cell. In contrast with the kidney, probably univalent phosphate and one Na+ ion instead of bivalent phosphate and two Na+ ions are transported together.     

L-Glutamate effects on electrical potentials of synaptic plasma membrane vesicles

The electrogenic nature of the L-glutamate-stimulated Na+ flux was examined by measuring the distribution of the lipophilic anion [35S]thiocyanate (SCN-) into synaptic membrane vesicles that were incubated in a NaCl medium. Concentrations of L-glutamate from 10(-7) to 10(-4) M added to the incubation medium caused an enhanced intravesicular accumulation of SCN-. Based on the SCN- distribution in synaptic membrane vesicles it was calculated that 10 microM L-glutamate induced an average change in the membrane potential of + 13 mV. L-Glutamate enhanced both the Na+ and K+ conductance of these membranes as determined by increases in SCN- influx. Other neuroexcitatory amino acids and amino acid analogs (D-glutamate, L-aspartate, L-cysteine sulfinate, kainate, ibotenate, quisqualate, N-methyl-D-aspartate, and DL-homocysteate) also increased SCN- accumulation in synaptic membrane vesicles. These observations are indicative of the activation by L-glutamate and some of its analogs of excitatory amino acid receptor ion channel complexes in synaptic membranes.     

Vasopressin, insulin and peroxide(s) of vanadate (pervanadate) influence Na+ transport mediated by (Na+, K+)ATPase or Na+/H+ exchanger of rat liver plasma membrane vesicles

Uptake of 22Na+ by liver plasma membrane vesicles, reflecting Na+ transport by (Na+, K+)ATPase or Na+/H+ exchange was studied. Membrane vesicles were isolated from rat liver homogenates or from freshly prepared rat hepatocytes incubated in the presence of [Arg8]vasopressin or pervanadate and insulin. The ATP dependence of (Na+, K+)ATPase-mediated transport was determined from initial velocities of vanadate-sensitive uptake of 22Na+, the Na(+)-dependence of Na+/H+ exchange from initial velocities of amiloride-sensitive uptake. By studying vanadate-sensitive Na+ transport, high-affinity binding sites for ATP with an apparent Km(ATP) of 15 +/- 1 microM were observed at low concentrations of Na+ (1 mM) and K+ (1mM). At 90 mM Na+ and 60 mM K+ the apparent Km(ATP) was 103 +/- 25 microM. Vesiculation of membranes and loading of the vesicles prepared from liver homogenates in the presence of vasopressin increased the maximal velocities of vanadate-sensitive transport by 3.8-fold and 1.9-fold in the presence of low and high concentrations of Na+ and K+, respectively. The apparent Km(ATP) was shifted to 62 +/- 7 microM and 76 +/- 10 microM by vasopressin at low and high ion concentrations, respectively, indicating that the hormone reduced the influence of Na+ and K+ on ATP binding. In vesicles isolated from hepatocytes preincubated with 10 nM vasopression the hormone effect was conserved. Initial velocities of Na+ uptake (at high ion concentrations and 1 mM ATP) were increased 1.6-1.7-fold above control, after incubation of the cells with vasopressin or by affinity labelling of the cells with a photoreactive analogue of the hormone. The velocity of amiloride-sensitive Na+ transport was enhanced by incubating hepatocytes in the presence of 10 nM insulin (1.6-fold) or 0.3 mM pervanadate generated by mixing vanadate plus H2O2 (13-fold). The apparent Km(Na+) of Na+/H+ exchange was increased by pervanadate from 5.9 mM to 17.2 mM. Vesiculation and incubation of isolated membranes in the presence of pervanadate had no effect on the velocity of amiloride-sensitive Na+ transport. The results show that hormone receptor-mediated effects on (Na+, K+)ATPase and Na+/H+ exchange are conserved during the isolation of liver plasma membrane vesicles. Stable modifications of the transport systems or their membrane environment rather than ionic or metabolic responses requiring cell integrity appear to be involved in this regulation.     

Regulation of pantothenic acid transport in the heart. Involvement of a Na+-cotransport system

Pantothenic acid transport was studied in the isolated perfused rat heart and isolated sheep cardiac sarcolemmal vesicles. In the perfused heart, pantothenic acid transport was significantly greater if hearts were perfused as working hearts rather than Langendorff hearts, but was unaffected by the perfusion substrates used (11 mM glucose or 1.2 mM palmitate). Uptake rates of pantothenic acid in working hearts are dependent on perfusate concentrations of pantothenic acid (a Vmax of 418 nmol/g dry weight/30 min and a Km for pantothenic acid of 10.7 mircoM were obtained). Reduction in perfusate Na+ concentration from 145 to 105 mM (the Na+ was replaced with 40 mM choline) resulted in a small but significant decrease in pantothenic acid uptake. At 145 mM Na+, addition of a mixture of amino acids, whose uptake is Na+-dependent, resulted in a significant decrease in pantothenic acid uptake by the heart (173 +/- 5 to 132 +/- 12 nmol/g dry weight). If an inward Na+ gradient in isolated, purified sarcolemmal vesicles, was imposed, a rapid uptake of pantothenic acid was observed. Uptake rates are markedly reduced if Na+ was replaced by equimolar concentrations of K+ or if external Na+ was reduced below 40 mM. In the presence of Na+, increasing pantothenic acid concentrations resulted in an increase in pantothenic acid uptake by the vesicles. Combined, these data demonstrate that pantothenic acid is transported across the myocardial sarcolemmal membrane by a Na+-dependent mechanism, which may be common to a number of small molecules.