Basic amino acid transport in plasma membrane vesicles of Penicillium chrysogenum.

The characteristics of the basic amino acid permease (system VI) of the filamentous fungus Penicillium chrysogenum were studied in plasma membranes fused with liposomes containing the beef heart mitochondrial cytochrome c oxidase. In the presence of reduced cytochrome c, the hybrid membranes accumulated the basic amino acids arginine and lysine. Inhibition studies with analogs revealed a narrow substrate specificity. Within the external pH range of 5.5 to 7.5, the transmembrane electrical potential (delta psi) functions as the main driving force for uphill transport of arginine, although a low level of uptake was observed when only a transmembrane pH gradient was present. It is concluded that the basic amino acid permease is a H+ symporter. Quantitative analysis of the steady-state levels of arginine uptake in relation to the proton motive force suggests a H+-arginine symport stoichiometry of one to one. Efflux studies demonstrated that the basic amino acid permease functions in a reversible manner.     

Sodium-dependent neutral amino acid transport by human liver plasma membrane vesicles

The activities of several selected Na(+)-dependent amino acid transporters were identified in human liver plasma membrane vesicles by testing for Na(+)-dependent uptake of several naturally occurring neutral amino acids or their analogs. Alanine, 2-(methylamino)isobutyric acid, and 2-aminoisobutyric acid were shown to be almost exclusively transported by the same carrier, system A. Kinetic analysis of 2-(methylamino)isobutyric acid uptake by the human hepatic system A transporter revealed an apparent Km of 0.15 mM and a Vmax of 540 pmol.mg-1 protein.min-1. Human hepatic system A accepts a broad range of neutral amino acids including cysteine, glutamine, and histidine, which have been shown in other species to be transported mainly by disparate carriers. Inhibition analysis of Na(+)-dependent cysteine transport revealed that the portion of uptake not mediated by system A included at least two saturable carriers, system ASC and one other that has yet to be characterized. Most of the glutamine and histidine uptake was Na(+)-dependent, and the component not mediated by system A constituted system N. The largest portion of glycine transport was mediated through system A and the remainder by system ASC with no evidence for system Gly activity. Our examination of Na(+)-dependent amino acid transport documents the presence of several transport systems analogous to those described previously but with some notable differences in their functional activity. Most importantly, the results demonstrate that liver plasma membrane vesicles are a valuable resource for transport analysis of human tissue.     

Maintenance of glucagon-stimulated system A amino acid transport activity in rat liver plasma membrane vesicles

Plasma membrane vesicles prepared from intact rat liver or isolated hepatocytes retain transport activity by systems A, ASC, N, and Gly. Selective substrates for these systems showed a Na+-dependent overshoot indicative of energy-dependent transport, in this instance, driven by an artificially-imposed Na+ gradient. Greater than 85% of Na+-dependent 2-aminoisobutyric acid (AIB) uptake was blocked by an excess of 2-(methylamino)isobutyric acid (MeAIB) with an apparent Ki of 0.6 mM. Intact hepatocytes obtained from glucagon-treated rats exhibited a stimulation of system A activity and plasma membrane vesicles isolated from those same cells partially retained the elevated activity. Transport activity induced by substrate starvation of cultured hepatocytes was also evident in membrane vesicles prepared from those cells. The membrane-bound glucagon-stimulated system A activity decays rapidly during incubation of vesicles at 4 degrees C (t1/2 = 13 h), but not at -75 degrees C. Several different inhibitors of proteolysis were ineffective in blocking the decay of transport activity. Hepatic system N transport activity was also elevated in plasma membrane vesicles from glucagon-treated rats, whereas system ASC was essentially unchanged. The results indicate that both glucagon and adaptive regulation cause an induction of amino acid transport through a plasma membrane-associated protein.     

Adaptive regulation of neutral amino acid transport System A in rat H4 hepatoma cells

Substrate regulation of System A transport activity in rat H4 hepatoma cells is described. The uptake of several amino acids was tested in the presence of system-specific inhibitors. System A activity was increased in a RNA- and protein synthesis-dependent manner by amino acid deprivation of the cells (adaptive regulation), whereas transport by Systems ASC, N, y+, and L was unaffected. Unlike human fibroblasts, the H4 cells did not require serum to exhibit the depression of System A. At cell densities between 88 X 10(3) and 180 X 10(3) cells/cm2, the degree of adaptive regulation was inversely related to cell density. Both transport of AIB and adaptive regulation of System A were nearly abolished if either K+ or Li+ was substituted for Na+ in the medium. The presence of cycloheximide or tunicamycin blocked further increases in starvation-induced activity within 1 hr of addition, suggesting the involvement of a plasma membrane glycoprotein. In contrast, if the medium was supplemented with actinomycin after the stimulation of System A had begun, the activity continued to increase for an additional 2 hr before being slowed by the inhibitor. The contributions of trans-inhibition and repression to the amino acid-induced decay of System A activity were estimated for several representative amino acids. In general, the System A activity in normal rat hepatocytes was much less sensitive to trans-inhibition than the corresponding activity in H4 hepatoma cells. The half-life values for the amino acid-dependent decay of System A ranged from 0.5 to 2.0 hr.     

Energization of amino acid transport in energy-depleted Ehrlich cells and plasma membrane vesicles

We redirect attention to contributions to the energization of the active transport of amino acids in the Ehrlich cell, beyond the known energization by down-gradient comigration of Na⁺, beyond possible direct energization by coupling to ATP breakdown, and beyond known energization by exchange with prior accumulations of amino acids. We re-emphasize the uphill operation of System L, and by prior depletion of cellular amino acids show that this system must receive energy beyond that made available by their coupled exodus. After this depletion the Na⁺-independent accumulation of the norbornane amino acid, 2-aminobicycloheptane-2-carboxylic acid becomes strongly subject to stimulation by incubation with glucose. Energy transfer between Systems A and L through the mutual substrate action of ordinary amino acids was minimized although not entirely avoided by the use of amino acid analogs specific to each system.When 2,4-dinitrophenol was included in the depleting treatment, and pyruvate, phenazine methosulfate, or glucose used for restoration, recovery of uptake of the norbornane amino acid was independent of external Na⁺ or K⁺ levels. Restoration of the uptake of 2-(methylamino)isobutyric acid was, however, decreased by omission of external K⁺. Contrary to an earlier finding, restoration of uptake of each of these amino acids was associated with distinct and usually correlated rises in cellular ATP levels. ATP addition failed to stimulate exodus of the norbornane amino acid from plasma membrane vesicles, although either NADH or phenazine methosulfate did stimulate exodus. ATP production and use is thus associated with transport energization, although evidence for a direct role failed to appear.     

Derepression of amino acid transport by amino acid starvation in rat hepatoma cells.

Amino acid starvation causes an adaptive increase in the initial rate of transport of selected neutral amino acids in an established line of rat hepatoma cells in tissue culture. After a lag of 30 min, the initial rate of transport of alpha-aminoisobutyric acid (AIB) increases to a maximum after 4 to 6 h starvation of 2 to 3 times that seen in control cells. The increased rate of transport is accompanied by an increase in the Vmax and a modest decrease in the Km for this transport system, and is reversed by readdition of amino acids. The enhancement is specific for amino acids transported by the A or alanine-preferring system (AIB, glycine, proline); uptake of amino acids transported by the L or leucine-preferring system (threonine, phenylalanine, tyrosine, leucine) or the Ly+ system for dibasci amino acids (lysine) is decreased under these conditions. Amino acids which compete with AIB for transport also prevent the starvation-induced increase in AIB transport; amino acids which do not compete fail to prevent the enhancement. Paradoxically threonine, phenylalanine, tryptophan, and tyrosine, which do not compete with AIB for transport, block the enhancement of transport upon amino acid starvation. The starvation-induced enhancement of amino acid transport does not appear to be the result of a release from transinhibition. After 30 min of amino acid starvation, AIB transport is either unchanged or slightly decreased even though amino acid pools are already depleted. Furthermore, loading cells with high concentrations of a single amino acid following a period of amino acid starvation fails to prevent the enhancement of AIB transport, whereas incubation of the cells with the single amino acid for the entire duration of amino acid starvation prevents the enhancement; intracellular amino acid pools are similar under both conditions. The enhancement of amino acid transport requires concomitant RNA and protein synthesis, consistent with the view that the adaptive increase reflects an increased amount of a rate-limiting protein involved in the transport process. Dexamethasone, which dramatically inhibits AIB transport in cells incubated in amino acid-containing medium, both blocks the starvation-induced increase in AIB transport, and causes a time-dependent decrease in transport velocity in cells whose transport has previously been enhanced by starvation.     

Glucocorticoid regulation of amino acid transport in anucleate rat hepatoma (HTC) cells

The transport of alpha-aminoisobutyric acid (AIB) by rat hepatoma tissue culture (HTC) cells is rapidly and reversibly inhibited by dexamethasone and other glucocorticoids. To investigate the role of the nucleus in the regulation of transport and to determine whether steroid hormones or steroid-receptor complexes may have direct effects on cytoplasmic or membrane functions, we have examined the regulation of transport by dexamethasone in anucleate HTC cells. Cytoplasts prepared from suspension cultures of HTC cells fully retain active transport of AIB with the same kinetic properties as intact cells. However, the uptake of AIB is not inhibited by dexamethasone or other corticosteroids. Neither is the inhibited rate of transport, manifested by cytoplasts prepared from dexamethasone-treated cells, restored to normal upon removal of the hormone. Anucleate cells exhibit specific, saturable binding of [3H]dexamethasone; however, the binding is reduced compared with that of intact cells. The nucleus is thus required for the glucocorticoid regulation of amino acid transport in HTC cells.     

Ontogeny of glutamine transport by rat liver plasma membrane vesicles.

Glutamine metabolism in the liver is essential for gluconeogenesis and ureagenesis. During the suckling period there is high hepatic protein accretion and the portal vein glutamine concentration is twice that in the adult, whereas hepatic vein glutamine concentration is similar between adult and suckling rats. Therefore, we hypothesized that glutamine uptake by the liver could be greater in the suckling period compared to the adult period. The present studies were, therefore, designed to investigate the transport of glutamine by plasma membranes of rat liver during maturation (suckling--2-week old, weanling--3-week old and adult--12-week old). Glutamine uptake by the plasma membranes of the liver represented transport into an osmotically sensitive space in all age groups. Inwardly directed Na+ gradient resulted in an "overshoot" phenomenon compared to K+ gradient. The magnitude of the overshoot was greater in suckling rats plasma membranes compared to adult membranes. Glutamine uptake under Na+ gradient was electrogenic and maximal at pH 7.5, whereas uptake under K+ gradient was electroneutral. Glutamine uptake with various concentrations of glutamine under Na+ gradient was saturable in all age groups with a Vmax of 1.5 +/- 0.1, 0.7 +/- 0.1 and 0.5 +/- 0.06 nmoles/mg protein/10 seconds in suckling, weanling and adult rats, respectively (P < 0.01). Km values were 0.6 +/- 0.1, 0.5 +/- 0.1 and 0.5 +/- 0.1 mM respectively. Vmax for Na(+)-independent glutamine uptake were 0.6 +/- 0.1, 0.55 +/- 0.07 and 0.54 +/- 0.06 nmoles/mg protein with Km values of 0.54 +/- 0.2, 0. +/- 0.1 and 0.5 +/- 0.2 mM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sodium ion-dependent amino acid transport in membrane vesicles of Bacillus stearothermophilus.

Amino acid transport in membrane vesicles of Bacillus stearothermophilus was studied. A relatively high concentration of sodium ions is needed for uptake of L-alanine (Kt = 1.0 mM) and L-leucine (Kt = 0.4 mM). In contrast, the Na(+)-H(+)-L-glutamate transport system has a high affinity for sodium ions (Kt less than 5.5 microM). Lithium ions, but no other cations tested, can replace sodium ions in neutral amino acid transport. The stimulatory effect of monensin on the steady-state accumulation level of these amino acids and the absence of transport in the presence of nonactin indicate that these amino acids are translocated by a Na+ symport mechanism. This is confirmed by the observation that an artificial delta psi and delta mu Na+/F but not a delta pH can act as a driving force for uptake. The transport system for L-alanine is rather specific. L-Serine, but not L-glycine or other amino acids tested, was found to be a competitive inhibitor of L-alanine uptake. On the other hand, the transport carrier for L-leucine also translocates the amino acids L-isoleucine and L-valine. The initial rates of L-glutamate and L-alanine uptake are strongly dependent on the medium pH. The uptake rates of both amino acids are highest at low external pH (5.5 to 6.0) and decline with increasing pH. The pH allosterically affects the L-glutamate and L-alanine transport systems. The maximal rate of L-glutamate uptake (Vmax) is independent of the external pH between pH 5.5 and 8.5, whereas the affinity constant (Kt) increases with increasing pH. A specific transport system for the basic amino acids L-lysine and L-arginine in the membrane vesicles has also been observed. Transport of these amino acids occurs most likely by a uniport mechanism.     

Sodium-dependent amino acid transport in reconstituted membrane vesicles from Ehrlich ascites cell plasma membranes

Plasma membranes, isolated from Ehrlich ascites tumor cells, were dissolved in 2% cholate, 4 M urea and then reformed into liposomes upon dialysis at 4 degrees with exogenous phospholipids. Reconstituted vesicles regain the ability to transport amino acids. Na+ was shown to accelerate the uptake of alpha-aminoisobutyrate, phenylalanine, and methionine, but not leucine or epsilon-aminohexanoic acid. With the reconstituted vesicles, methionine, but not leucine, inhibited the uptake of alpha-aminoisobutyrate. An apparent Km value for alpha-aminoisobutyrate uptake of 3.0 mM was obtained. This value is close to that observed with the intact cells and the native membrane vesicles. A Na+ gradient (high Na+ outside) increased alpha-aminoisobutyrate uptake, whereas a reversed gradient (high Na+ inside) increased alpha-aminoisobutyrate efflux. The latter flux was increased by valinomycin, suggesting electrogenic transport. A modest extent of coupling between a Na+ gradient and uphill flow of alpha-aminoisobutyrate was observed.     

Amino acid transport in plasma membrane vesicles from isolated rat liver parenchymal cells

Plasma membrane vesicles were prepared from isolated rat liver parenchymal cells. The transport of several amino acids was studied and found to be identical to that in membrane vesicles from whole liver tissue.     

Gllcocorticoid inhibition of amino acid transport in rat hepatoma cells

Dexamethasone rapidly and reversibly inhibits the initial rate of transport of α-aminoisobutyric acid in rat hepatoma cells in tissue culture. Colcemid and cytochalasin B neither inhibit transport nor interfere with its inhibition by dexamethasone, arguing that microtubules and microfilaments are not involved in this hormonal effect. Continuous protein synthesis is required both for the dexamethasone inhibition of transport and for its reversal, although cycloheximide alone inhibits transport in control cells by less than 25%. A model for the dexamethasone inhibition of amino acid transport is presented suggesting that glucocorticoids either block the synthesis or enhance the degradation of a rate-limiting protein in the transport system.     

Neutral amino acid transport by membrane vesicles of Streptococcus cremoris is subject to regulation by internal pH.

The pH dependence of transport of the neutral amino acids L-serine and L-alanine by membrane vesicles of Streptococcus cremoris have been studied in detail. The rates of four modes of facilitated diffusion (e.g., influx, efflux, exchange, and counterflow) of L-serine and L-alanine increase with increasing H+ concentration. Rates of artificially imposed electrical potential across the membrane (delta psi)-driven transport of L-serine and L-alanine show an optimum at pH 6 to 6.5. Under similar conditions, delta psi- and pH gradient across the membrane (delta pH)-driven transport of L-leucine is observed within the pH range studied (pH 5.5 to 7.5). The effect of ionophores on the uptake of L-alanine and L-serine has been studied in membrane vesicles of S. cremoris fused with proteoliposomes containing beef heart mitochondrial cytochrome c oxidase as a proton motive force (delta p)-generating system (Driessen et al., Proc. Natl. Acad. Sci. USA 82:7555-7559, 1985). An increase in the initial rates of L-serine and L-alanine uptake is observed with decreasing pH, which is not consistent with the pH dependency of delta p. Nigericin, an ionophore that induced a nearly complete interconversion of delta pH into delta psi, stimulated both the rate and the final level of L-alanine and L-serine uptake. Valinomycin, an ionophore that induced a collapse of delta psi with a noncompensating increase in delta pH, inhibited L-alanine and L-serine uptake above pH 6.0 more efficiently than it decreased delta p. Experiments which discriminate between the effects of the internal pH and the driving force (delta pH) on solute transport indicate that at high internal pH the transport systems for L-alanine and L-serine are inactivated. A unique relation exists between the internal pH and the initial rate of uptake of L-serine and L-alanine with an apparent pK of 7.0. The rate of L-alanine and L-serine uptake decreases with increasing internal pH. The apparent complex relation between the delta p and transport of L-alanine and L-serine can be explained by a regulatory effect of the internal pH on the activity of the L-serine and L-alanine carriers.     

Characterization of L-carnitine transport into rat skeletal muscle plasma membrane vesicles.

Transport of L-carnitine into skeletal muscle was investigated using rat sarcolemmal membrane vesicles. In the presence of an inwardly directed sodium chloride gradient, L-carnitine transport showed a clear overshoot. The uptake of L-carnitine was increased, when vesicles were preloaded with potassium. When sodium was replaced by lithium or cesium, and chloride by nitrate or thiocyanate, transport activities were not different from in the presence of sodium chloride. However, L-carnitine transport was clearly lower in the presence of sulfate or gluconate, suggesting potential-dependent transport. An osmolarity plot revealed a positive slope and a significant intercept, indicating transport of L-carnitine into the vesicle lumen and binding to the vesicle membrane. Displacement experiments revealed that approximately 30% of the L-carnitine associated with the vesicles was bound to the outer and 30% to the inner surface of the vesicle membrane, whereas 40% was unbound inside the vesicle. Saturable transport could be described by Michaelis-Menten kinetics with an apparent Km of 13.1 microM and a Vmax of 2.1 pmol.(mg protein-1).s-1. L-Carnitine transport could be trans-stimulated by preloading the vesicles with L-carnitine but not with the carnitine precursor butyrobetaine, and was cis-inhibited by L-palmitoylcarnitine, L-isovalerylcarnitine, and glycinebetaine. On comparing carnitine transport into rat kidney brush-border membrane vesicles and OCTN2, a sodium-dependent high-affinity human carnitine transporter, cloned recently from human kidney also expressed in muscle, the Km values are similar but driving forces, pattern of inhibition and stereospecificity are different. This suggests the existence of more than one carnitine carrier in skeletal muscle.     

Control by amino acids of the activity of system A-mediated amino acid transport in isolated rat hepatocytes.

The effect of amino acids, in concentrations corresponding to those found in the portal vein of rats given a high-protein diet, was investigated on the activity of system A amino acid transport in hepatocytes from fed rats. Amino acids counteracted the induction of system A by insulin or glucagon. This effect was observed at all concentrations of hormones tested, up to 1 microM. Amino acids did not affect the basal cyclic AMP concentration in hepatocytes, or the large rise in cyclic AMP elicited by glucagon. The reversal of system-A induction was observed at relatively low concentration of amino acids, corresponding to plasma values reported in rats given a basal diet. Amino acids were separately tested: substrates of system A were particularly efficient, but so were glutamine and histidine. Non-metabolizable substrates of system A, such as 2-aminoisobutyrate, were also inhibitory, suggesting that a part of the effect of amino acids is independent of their cellular metabolism. Provision of additional energy substrates such as lactate and oleate did not affect induction of system A or the inhibitory effects of amino acids. Thus amino acids do not act by serving as an energy source and by maintaining the integrity of hepatocytes. Inhibition of mRNA synthesis by actinomycin practically abolished the effect of amino acids on the induction of system A by glucagon. The results suggest that amino acids may promote the synthesis of protein(s) affecting the activity of system A either directly at the carrier unit or at an intermediate stage of its emergence.     

Relationship between amino acid transport and electron transport by membrane vesicles of Micrococcus denitrificans

Membrane vesicles were prepared from Micrococcus denitrificans by osmotic shock of lysozyme spheroplasts. These vesicles concentrated 4 amino acids via two systems; one for glycine-alanine and the other for asparagine-glutamine. Amino acid transport was coupled to the membrane-bound electron transport system and involved interactions of the primary dehydrogenases, cytochromes, cytochrome oxidase and oxygen. After transport the amino acids were recovered unchanged from the vesicles. The substrates of the membrane-bound electron transport system d-lactate, l-lactate, formate, succinate, NADH, glucose-6-phosphate and α-glycerolphosphate all stimulated transport at least 2-fold. Both oxygen and nitrate could serve as terminal electron acceptors with vesicles prepared from cells grown anaerobically with nitrate. Anaerobic transport in the presence of nitrate was not inhibited by cyanide but was inhibited by nitrite. A system stimulated by substrates of the electron transport system but independent of added terminal electron acceptors was found also in the vesicles prepared from anaerobically grown cells. Addition of one combination of two substrates for electron transport produced an amino acid uptake 12 to 15% greater than the sum of the rates for each substrate added singly. Additions of other combinations gave rates of transport less than the sum of the rates of each added alone. Both the dehydrogenase activities and the coupling of electron transport to amino acid uptake were modified by changing the growth conditions and differences between the effectiveness of each substrate for each of the two transport systems could be detected. The efficiency of the vesicles per protoheme, the prosthetic group of the membrane-bound cytochrome b, with d-lactate as substrate was 27% for glutamine and 6% for glycine of the rates of transport of these two amino acids in intact cells when driven by endogenous respiration. Assuming one amino acid transported per electron, the transport of glycine utilized 1% of the respiratory capacity with glucose-6-phosphate as substrate. The coupling to the electron transport with the other substrates was less efficient. It appeared that a small portion of the total capacity of the electron transport system was coupled to amino acid transport and the coupling to respiration, as well as the primary dehydrogenase activities and terminal cytochrome oxidase, were modified in response to the conditions of growth.