Investigation of Possible Participation of Nucleoside Transport Systems in the Postischemic Release of Purines and Pyrimidines from Cold Stored Liver

The aim of the study was to elucidate the role of nucleoside transport systems in the postischemic release of nucleosides and nucleobases accumulated by the rat liver during cold storage. Livers were preserved for 24 h in Euro-Collins (EC) or in a lactobionate-based solution (LBS) without exogenous adenosine. The rates of release of uric acid, xanthine, hypoxanthine, inosine, adenosine, uridine, and cytidine were monitored during early reperfusion. The greater part of the purines and pyrimidines (up to 80%) was lost in the first 2 min of reperfusion. After storage in EC, uric acid and xanthine formed more than 90% of the total purines released; nucleosides did not exceed 5% of the total. After storage in LBS, hypoxanthine formed more than 80% of purine efflux and the release of inosine and uridine was increased 5-10 times. These changes were shown to be due to the presence of allopurinol in LBS. Dipyridamole (an inhibitor of equilibrative nucleoside transporters) decreased the efflux of uric acid after storage in EC but residual release remained high. Dipyridamole exerted the most pronounced effect on the release of nucleosides (inosine and uridine) from livers stored in LBS. The use of sodium-free media for liver preservation and reperfusion did not alter the rates of purine and pyrimidine release. We conclude that equilibrative nucleoside transporters mediate the postischemic release of nucleosides and also, but to a less degree, of uric acid. Simple diffusion is an important factor in the release of nucleobases. Active Na(+)/nucleoside cotransport does not play an important role in early reperfusion.     

Sodium-dependent nucleoside transport in mouse leukemia L1210 cells

Nucleoside permeation in L1210/AM cells is mediated by (a) equilibrative (facilitated diffusion) transporters of two types and by (b) a concentrative Na(+)-dependent transport system of low sensitivity to nitrobenzylthioinosine and dipyridamole, classical inhibitors of equilibrative nucleoside transport. In medium containing 10 microM dipyridamole and 20 microM adenosine, the equilibrative nucleoside transport systems of L1210/AM cells were substantially inhibited and the unimpaired activity of the Na(+)-dependent nucleoside transport system resulted in the cellular accumulation of free adenosine to 86 microM in 5 min, a concentration three times greater than the steady-state levels of adenosine achieved without dipyridamole. Uphill adenosine transport was not observed when extracellular Na+ was replaced by Li+, K+, Cs+, or N-methyl-D-glucammonium ions, or after treatment of the cells with nystatin, a Na+ ionophore. These findings show that concentrative nucleoside transport activity in L1210/AM cells required an inward transmembrane Na+ gradient. Treatment of cells in sodium medium with 2 mM furosemide in the absence or presence of 2 mM ouabain inhibited Na(+)-dependent adenosine transport by 50 and 75%, respectively. However, because treatment of cells with either agent in Na(+)-free medium decreased adenosine transport by only 25%, part of this inhibition may be secondary to the effects of furosemide and ouabain on the ionic content of the cells. Substitution of extracellular Cl- by SO4(-2) or SCN- had no effect on the concentrative influx of adenosine.     

A nucleoside transporter is functionally linked to ectonucleotidases in rat liver canalicular membrane.

Prevention of nucleoside loss in bile is physiologically desirable because hepatocytes are the main source of nucleosides for animal cells which lack de novo nucleoside biosynthesis. We have demonstrated a Na+ gradient-energized, concentrative nucleoside transport system in canalicular membrane vesicles (CMV) from rat liver by studying [3H]adenosine uptake using a rapid filtration technique. The Na(+)-dependent nucleoside transporter accepts purine, analogues of purine nucleosides and uridine; exhibits high affinity for adenosine (apparent Km, 14 microM); is not inhibited by nitrobenzylthioinosine or dipyridamole, and is present in CMV but not in rat liver sinusoidal membrane vesicles. Adenosine transport in right side-out CMV was substantially greater than with inside-out CMV. CMV also contain abundant ecto-ATPase and ecto-AMPase (5'-nucleotidase). These ectoenzymes were shown to degrade nucleotides into nucleosides which were conserved by the Na(+)-dependent nucleoside transport system.     

Na+-dependent and -independent transport of uridine and its phosphorylation in mouse spleen cells

Rapid kinetic techniques were used to study the transport and salvage of uridine and other nucleosides in mouse spleen cells. Spleen cells express two nucleoside transport systems: (1) the non-concentrative, symmetrical, Na+-independent transporter with broad substrate specificity, which has been found in all mammalian cells and is sensitive to inhibition by dipyridamole and nitrobenzylthioinosine; and (2) a Na+-dependent nucleoside transport, which is specific for uridine and purine nucleosides and resistant to inhibition by dipyridamole and nitrobenzylthioinosine. The kinetic properties of the two transporters were determined by measuring uridine influx in ATP-depleted cells and dipyridamole-treated cells, respectively. The Michaelis-Menten constants for Na+-independent and -dependent transport were about 40 and 200 microM, respectively, but the first-order rate constants were about the same for both transport systems. Nitrobenzylthioinosine-sensitivity of the facilitated nucleoside transporter correlated with the presence of about 10,000 high-affinity (Kd = 0.6 nM) nitrobenzylthioinosine-binding sites per cell. The turnover number of the nitrobenzylthioinosine-sensitive nucleoside transporter was comparable to that of mouse P388 leukemia cells. The activation energy of this transporter was 20 kcal/mol. Entry of uridine via either of the transport routes was rapidly followed by its phosphorylation and conversion to UTP. The Michaelis-Menten constant for the in situ phosphorylation of uridine was about 50 microM and the first-order rate constants for phosphorylation and transport were about the same. The spleen cells also efficiently salvaged adenosine, adenine, and hypoxanthine, but not thymidine.     

Sodium-Dependent Uptake of Nucleosides by Dissociated Brain Cells from the Rat

Sodium-dependent 3H-labeled nucleoside transport was studied using a mixed population of dissociated brain cells from adult rats. The accumulation of [3H]adenosine during brief (15-s) incubation periods was significantly greater in the presence of 110 mM Na+ than in its absence. This occurred at substrate concentrations that ranged from 0.25 to 100 microM. Similar findings were observed for the rapid accumulation of [3H]uridine. Kinetically, the rapid accumulation of [3H]adenosine in both the absence and the presence of Na+ was best described by a two-component system. In the presence of Na+, the KT and Vmax values for the high-affinity affinity component were 0.9 microM and 8.9 pmol/mg of protein/15 s, and those for the low-affinity component were 313 microM and 3,428 pmol/mg of protein/15 s, respectively. In the absence of Na+, the KT value for the high-affinity component was significantly higher (1.8 microM). [3H]Uridine accumulation was best described kinetically by a one-component system that in the presence of Na+ had KT and Vmax values of 1.0 mM and 2.6 nmol/mg of protein/15 s, respectively. As was found for [3H]adenosine, in the absence of Na+, the KT value was significantly higher (1.8 mM). The sodium-dependent transport of [3H]adenosine was inhibitable by ouabain and 2,4-dinitrophenol. Of the three nucleoside transport inhibitors tested, only nitrobenzylthioninosine demonstrated high affinity and selectivity in blocking the sodium component. Thus, high-affinity sodium-dependent nucleoside transport systems, in addition to facilitated diffusion systems, exist on brain cells from adult rats.     

Effects of adrenergic agonists and mitochondrial energy state on the Ca2+ transport systems of mitochondria

This study investigates the effects of adrenergic agonists and mitochondrial energy state on the activities of the Ca2+ transport systems of female rat liver mitochondria. Tissue perfusion with the alpha-adrenergic agonist phenylephrine and with adrenaline, but not with the beta-adrenergic agonist isoprenaline, induced significant activation of the uniporter and the respiratory chain. Uniporter activation was evident under two sets of experimental conditions that excluded influences of delta psi, i.e., at high delta psi, where uniporter activity was delta psi independent, and at low delta psi, where uniporter conductance was measured. Preincubation of mitochondria with extracts from phenylephrine-perfused tissue quantitatively reproduced uniporter activation when comparison was made with mitochondria treated similarly with extracts from tissue perfused without agonist. Similar, but more extensive, data were obtained with heart mitochondria pretreated with extracts from hearts perfused with the alpha-adrenergic agonist methoxamine. Phenylephrine did not affect Ca2+ efflux mediated by the Na+-Ca2+ carrier or the Na+-independent system. In contrast, the liver mitochondrial Na+-Ca2+ carrier was activated by tissue perfusion with isoprenaline; the Na+-independent system was unaffected. Na+-Ca2+ carrier activation was not associated with any change in a number of basic bioenergetic parameters. It is concluded that the Ca2+ transport systems of liver mitochondria may be controlled in an opposing manner by alpha-adrenergic agonists (promotion of Ca2+ influx) and beta-adrenergic agonists (promotion of Ca2+ efflux). At delta psi values greater than 110 mV, the Na+-independent system was activated by increase in delta psi; the uniporter and Na+-Ca2+ carrier activities were insensitive to delta psi changes in this range.(ABSTRACT TRUNCATED AT 250 WORDS)     

Energy metabolism following prolonged hepatic cold preservation: benefits of interrupted hypoxia on the adenine nucleotide pool in rat liver.

The ability of brief hypothermic reperfusion (HtR) to restore hepatic energy metabolism following periods of cold hypoxic preservation was studied in isolated rat livers after storage times of 5, 10, and 24 h. In addition, investigations were performed on the effects of HtR used to restore liver oxidative metabolism in the middle of a prolonged (24 h) hypoxic preservation period. A histidine-lactobionate-raffinose solution was used for the initial cold portal flush in all groups. Results showed that cold hypoxia for either 5 or 10 h yielded livers capable of similar recoveries of ATP, energy charge, and total adenine nucleotides, but that HtR after 24 h cold preservation resulted in reduced regeneration of ATP, a lower energy charge, and a fall in tissue adenine nucleotides. When livers were stored for 24 h but subjected to brief HtR after either 5 or 10 h before return to hypoxic storage, improved recoveries of the energy metabolites were seen over those recorded after 24 h hypoxia alone. The fact that these improvements were not due to an improved supply of adenine nucleotide precursors was demonstrated by studying groups which were given HtR with perfusate containing precursors of adenine nucleotides (adenosine, adenine, and inosine) after 24 h cold hypoxia. These data are consistent with the hypothesis that poor metabolic recovery after long-term hepatic cold preservation results more from decreased mitochondrial oxidative phosphorylation than from a lack of precursors for adenine nucleotide resynthesis. In addition, restoring oxidative metabolism at hypothermia for brief periods can to some extent protect final metabolic status after prolonged storage.     

Transport of physiological nucleosides and anti-viral and anti-neoplastic nucleoside drugs by recombinant Escherichia coli nucleoside-H(+) cotransporter (NupC) produced in Xenopus laevis oocytes

The recently identified human and rodent plasma membrane proteins CNT1, CNT2 and CNT3 belong to a gene family (CNT) that also includes the bacterial nucleoside transport protein NupC. Heterologous expression in Xenopus oocytes has established that CNT1-3 correspond functionally to the three major concentrative nucleoside transport processes found in human and other mammalian cells (systems cit, cif and cib, respectively) and mediate Na(+) - linked uptake of both physiological nucleosides and anti-viral and anti-neoplastic nucleoside drugs. Here, one describes a complementary Xenopus oocyte transport study of Escherichia coli NupC using the plasmid vector pGEM-HE in which the coding region of NupC was flanked by 5'- and 3'-untranslated sequences from a Xenopus beta-globin gene. Recombinant NupC resembled human (h) and rat (r) CNT1 in nucleoside selectivity, including an ability to transport adenosine and the chemotherapeutic drugs 3'-azido-3'-deoxythymidine (AZT), 2',3'- dideoxycytidine (ddC) and 2'-deoxy-2',2'-difluorocytidine (gemcitabine), but also interacted with inosine and 2',3'- dideoxyinosine (ddl). Apparent affinities were higher than for hCNT1, with apparent K(m) values of 1.5-6.3 microM for adenosine, uridine and gemcitabine, and 112 and 130 microM, respectively, for AZT and ddC. Unlike the relatively low translocation capacity of hCNT1 and rCNT1 for adenosine, NupC exhibited broadly similar apparent V(max) values for adenosine, uridine and nucleoside drugs. NupC did not require Na(+) for activity and was H(+) - dependent. The kinetics of uridine transport measured as a function of external pH were consistent with an ordered transport model in which H(+) binds to the transporter first followed by the nucleoside. These experiments establish the NupC-pGEM-HE/oocyte system as a useful tool for characterization of NupC-mediated transport of physiological nucleosides and clinically relevant nucleoside therapeutic drugs.     

Influence of colloid, preservation medium and trimetazidine on renal medulla injury

In organ transplantation, preservation injury is an important factor which could influence short-term and long-term graft outcome. The renal medulla is particularly sensitive to oxidant stress and ischemia-reperfusion injury (IRI). Using an autotransplant pig kidney model, we investigated renal function and medullary damage determined between day 1 and week 2 after 24- or 48-h cold storage in different preservation solutions: University of Wisconsin solution (UW), Hopital Edouard Herriot solution (a high Na+ version of UW), ECPEG (high Na+ preservation solution with PEG) and ICPEG (a high K+ version of ECPEG) with or without trimetazidine (TMZ). TMZ improved renal preservation and increased renal function when added in each preservation solution (particularly HEH and ECPEG). Medullary damage led to the early appearance of trimethylamine-N-oxide (TMAO) followed by 1H-NMR in urine and plasma. TMZ and ECPEG is the most efficient association to reduce medullary damage. This study clarifies the role of colloid and polarity solution and the role of mitochondrial protection by TMZ.     

Bile analysis as a tool for assessing integrity of biliary epithelial cells after cold ischemia--reperfusion of rat livers

Previous morphological studies failed to show appreciable injury of biliary epithelial cells (BEC) after cold ischemia of rat liver, although recent evidence indicated that BEC integrity and function were impaired in this model. We tested the hypothesis that analysis of bile for enzymes, such as lactate dehydrogenase (LDH), alanine transaminase (ALT), and aspartate transaminase (AST), can be used for assessing cold ischemic injury of BEC. Furthermore, we examined whether biliary gamma-glutamyltransferase (GGT) reflects warm ischemic injury of BEC and whether normothermic reperfusion aggravates the negative effect of cold ischemia on BEC integrity and function. Rat livers were reperfused after different periods of cold or warm ischemia using a blood-free perfusion model. Compared with controls, perfusate LDH, ALT, and AST levels and parameters of hepatocyte function, including hepatocyte tight junction permeability, were not significantly altered by 18-h cold ischemia. On the other hand, 9-h cold ischemia markedly increased biliary LDH, ALT, and AST levels. However, only LDH release into the bile was strongly dependent on the time of cold storage. Biliary GGT, LDH, and glucose levels decreased during the reperfusion period following 18-h cold ischemia. The results suggest that biliary LDH can be used for assessing injury of BEC in cold-preserved livers and that normothermic reperfusion does not aggravate preservation-induced injury of BEC after cold ischemic storage.     

Effect of parathyroid hormone on Na+-dependent phosphate transport and cAMP-dependent 32P phosphorylation in brush border vesicles from isolated perfused canine kidneys

Concentrative uptake of 32Pi induced by the dissipation of a Na+ gradient (overshoot) was demonstrated in brush border membrane vesicles obtained from isolated perfused canine kidneys. Na+-dependent 32Pi transport was decreased in brush border vesicles from isolated kidneys perfused with parathyroid hormone (PTH) for 2 h compared to uptake measured in vesicles from kidneys perfused without PTH. Cyclic AMP-dependent 32P phosphorylation of a 62,000 Mr protein band was demonstrable on autoradiograms of sodium dodecyl sulfate-polyacrylamide gels of membrane suspensions from kidneys perfused +/- PTH. Evidence that perfusion with PTH resulted in cAMP-dependent phosphorylation in isolated kidneys from parathyroidectomized dogs (decreased cAMP-dependent 32P phosphorylation of the 62,000-Mr band in brush border vesicles) was obtained after 2-h perfusion with PTH. Decreased 32P phosphorylation was not observed if membranes were allowed to dephosphorylate prior to 32P phosphorylation in vitro. We conclude that brush border vesicles from isolated perfused canine kidneys can be used to study the action of PTH on Na+-Pi cotransport in brush border membranes and on cAMP-dependent phosphorylation of the membrane. It is strongly suggested that PTH effects changes in Na+-dependent 32Pi transport in isolated brush border vesicles and changes in 32P phosphorylation of vesicles via a direct action on the renal cortical cell rather than as a consequence of extrarenal actions of the hormone.     

CSF-1 stimulates nucleoside transport in S1 macrophages

We have examined nucleoside transport (NT) in a cell line derived from primary day 7 murine bone marrow macrophages (S1 macrophages) in response to the macrophage growth factor, colony-stimulating factor 1 (CSF-1). Adenosine and uridine transport in quiescent S1 macrophages occurred primarily by two facilitated diffusional routes, one that was sensitive and one that was relatively resistant to the inhibitor nitrobenzylthioinosine (NBMPR). Addition of CSF-1 to quiescent cultures resulted in increased adenosine and uridine transport with biphasic kinetics with respect to the cell cycle. Basal NT activity was elevated (about twofold) within 15 min of CSF-1 addition, returned to near basal levels by 1 h, and then increased again (three- to fourfold) 8–12 h later, returning again to basal levels by 48 h post CSF-1 stimulation. We propose that the large increase in NT activity at 8–12 h corresponded with the time when cultures synchronously began to enter the S phase of the cell cycle. In addition to these changes in the absolute rates, the proportions of NBMPR-sensitive and NBMPR-insensitive transport also change after CSF-1 addition. Quiescent cultures exhibited primarily NBMPR-insensitve transport while logrithmically growing cultures exhibited primarily NBMPR-sensitive nucleoside transport activity. The increase in the NBMPR-sensitive component of the transport process paralleled a similar increase in the number of high-affinity NBMPR binding sites, suggesting that the mechanism for upregulating NBMPR-sensitive NT activity involves increases in the number of NBMPR-sensitive transporter sites. Interestingly, we were unable to detect Na+-dependent concentrative uptake of adenosine, uridine, or formycin-B either in the S1 macrophage cell line or in primary (day 7) murine macrophages. Thus these bone marrow derived macrophages did not display the characteristically large Na+-dependent transport systems observed by others in peritoneal macrophages, implying that these two populations of macrophages are, indeed, functionally distinct. © 1993 Wiley-Liss, Inc.     

Release of carnitine from the perfused rat liver

Perfused rat liver was shown to be the proper model for studies on hepatic cellular transport of carnitine. During recirculating perfusion the livers kept equilibrium with 45 nmol/ml total carnitine in perfusate, exhibited concentrative uptake and there was no sign of artificial leakage. The release side of the carnitine transport was characterized by utilizing outflow perfusions. The livers from fed rats exported daily 9.93 mumol per 100 g body weight total carnitine. This release rate is 4- or 10-fold higher than the estimated daily turnover in vivo or the measured urinary excretion. Therefore, the major part of the released carnitine has to re-enter the liver. The outward carnitine transport does not depend on energy or the Na+-K+ pump, since it did not respond to metabolic poisons and ouabain. However, the release rate was strongly inhibited by mersalyl and showed saturability in function of tissue carnitine levels. The Vmax of the saturable outward transport system was 2.47 nmol . min-1 . g-1 liver, the apparent Km was 0.27 mM tissue level (both as compared to total carnitine). These data showed the outward transport of carnitine from the liver to be protein mediated. The contribution of a diffusion (nonsaturable) component was estimated to be 20-25% in the range of tissue levels occurring in vivo. The rate of carnitine release from the liver decreased as an effect of 24 h starvation from the daily 9.92 mumol release to 6.55 mumol on 100 g body weight basis. This decrease is more pronounced when the release rates are expressed on the basis of tissue carnitine levels. The resulting value can be called rate constant (at the linear part of the saturation curve, Fig. 5) and it decreased to 5.00 min-1 from 8.41 min-1 as an effect of starvation. We have concluded that the altered parameters of carnitine transport across the liver cell is decisive in developing the higher hepatic carnitine concentration in the fasted state.     

Modulation of liver cell membrane NHE-1, Na+-K+ ATPase, and GLUT-2 protein content after cold preservation and rewarming

Liver cell pH and volume regulation are perturbed by prolonged cold storage in University of Wisconsin solution and subsequent rewarming, but the molecular basis of this effect remains unknown. We prepared membranes from hepatocytes subjected to variable periods of cold preservation with or without subsequent rewarming and probed them by Western blotting with specific antibodies against the Na+ -H+ exchanger isoform NHE-1 and the Na+ -K+ ATPase alpha subunit. Results were compared with the content of GLUT-2, an abundant basolateral protein. NHE-1 decreased significantly as cold preservation times exceeded 10 h. Subsequent rewarming by short-term culture at 37 degrees C did not further reduce this parameter. On the other hand, expression of Na+ -K+ ATPase remained stable during cold storage times lasting up to 48 h, whereas rewarming resulted in a dramatic reduction in cells cold preserved beyond 10 h. In contrast, the membrane content of GLUT-2 was unaffected by cold preservation with or without subsequent rewarming. The results indicate that cold storage and rewarming respectively and selectively modulate the expression of specific hepatocellular membrane transport proteins.     

Na+/adenosine co-transport in Vibrio parahaemolyticus

Adenosine transport in Vibrio parahaemolyticus was studied. Na+ greatly stimulated adenosine uptake. Addition of adenosine to a cell suspension under anaerobic conditions elicited Na+ uptake, and the Na+ uptake was inhibited by monensin, an Na+ ionophore. Imposition of an electrochemical potential of Na+ or a membrane potential in energy-depleted cells elicited adenosine uptake. Therefore, adenosine transport in this organism was concluded to proceed by an Na+/adenosine co-transport mechanism. The Na+/adenosine co-transport system was induced when cells were grown in the presence of adenosine, and repressed by glucose. Although Na+ uptake elicited by adenosine was reduced by glucose, it was enhanced by methyl alpha-glucoside, which reduced the intracellular ATP level. Thus, the effects of glucose and the glucoside on the Na+/adenosine co-transport system did not seem to be due to inducer exclusion, but to be related to the intracellular ATP level.     

Na+- and K+-dependent uridine transport in rat renal brush-border membrane vesicles

The transport of uridine into rat renal brush-border membrane vesicles was investigated using an inhibitor-stop filtration method. Uridine was not metabolized under these conditions. The rapid efflux of intravesicular uridine was prevented by adding 1 mM phloridzin to the ice-cold stop solution. In the presence of inwardly directed gradients of either Na+ or K+, zero-trans uridine uptake exhibited a transient overshoot phenomenon indicating active transport. The overshoot was much more pronounced with Na+ than K+ and it was not observed when either Na+ or K+ was at equilibrium across the membrane. The K+-induced overshoot was not due to the presence of a membrane potential alone, as an inwardly directed gradient of choline chloride failed to produce it. The amplitude of the overshoot was increased by raising either the Na+ or K+ concentration outside the membrane or by using more lipophilic anions (reactive order was NO3- greater than SCN- greater than Cl- greater than SO4(2-). Zero-trans efflux studies showed that the uridine transport is bidirectional. Li+ could substitute poorly for Na+ but not at all for K+. Stoichiometries of 1:1 and greater than 1:1 were observed for Na+: uridine and K+: uridine coupling, respectively. A preliminary analysis of the interactions between Na+ and K+ for uridine uptake showed complex interactions which can best be explained by the involvement of two different systems for nucleoside transport in the rat renal brush-border membrane, one requiring Na+ and the other K+ as transport coupler.     

[3H]Ouabain binding and Na+, K+-ATPase in resealed human red cell ghosts

The interaction of the cardiac glycoside [3H]ouabain with the Na+, K+ pump of resealed human erythrocyte ghosts was investigated. Binding of [3H]ouabain to high intracellular Na+ ghosts was studied in high extracellular Na+ media, a condition determined to produce maximal ouabain binding rates. Simultaneous examination of both the number of ouabain molecules bound per ghost and the corresponding inhibition of the Na+, K+-ATPase revealed that one molecule of [3H]ouabain inhibited one Na+, K+-ATPase complex. Intracellular magnesium or magnesium plus inorganic phosphate produced the lowest ouabain binding rate. Support of ouabain binding by adenosine diphosphate (ADP) was negligible, provided synthesis of adenosine triphosphate (ATP) through the residual adenylate kinase activity was prevented by the adenylate kinase inhibitor Ap5A. Uridine 5'-triphosphate (UTP) alone did not support ouabain binding after inhibition of the endogenous nucleoside diphosphokinase by trypan blue and depletion of residual ATP by the incorporation of hexokinase and glucose. ATP acting solely at the high- affinity binding site of the Na+, K+ pump (Km approximately 1 microM) promoted maximal [3H]ouabain binding rates. Failure of 5'-adenylyl-beta- gamma-imidophosphate (AMP-PNP) to stimulate significantly the rate of ouabain binding suggests that phosphorylation of the pump was required to expose the ouabain receptor.     

Effects of perturbation of the Na+ electrochemical gradient on influx and efflux of alanine in isolated rat hepatocytes

Transmembrane alanine transport was studied in hepatocytes isolated from 48-h fasted rats. Aminooxyacetate was used to render alanine nonmetabolizable. Gramicidin D eliminated the transmembrane Na+ electrochemical gradient. At 135 mM Na+ and 0.1 mM alanine gramicidin D decreased the steady-state intracellular-to-extracellular alanine distribution ratio from 20.2 to 0.9. The underlying kinetic changes appeared to be a decrease in alanine influx to one-third of the control value and an increase in the rate constant of alanine efflux by a factor of 9. Analogous changes were observed when the Na+ gradient was decreased by ouabain. The inhibitory effect of gramicidin D on alanine influx was confined to the Na+-dependent, saturable component which showed a prominent increase in the apparent Km for alanine and a small decrease in the apparent Vmax. The effect of gramicidin D on alanine efflux was related to the increased cytosolic Na+ concentration: the rate constant of alanine efflux was increased by cytosolic Na+ with half-maximal stimulation at 30 mM; voltage-sensitive alanine efflux could not be demonstrated.     

Characteristics of the transport of alanine, serine and glutamine across the plasma membrane of isolated rat liver cells.

1. Alanine, glutamine and serine were actively accumulated in liver cells isolated from starved rats. 2. This accumulation was inhibited when either Na+ or HCO3- ions were omitted from the incubation medium. In general the degree of dependence on Na+ was quantitatively similar to that on HCO3-. 3. The apparent Km values for the transport of all three amino acids were in the range 3--5mM with Vmax. values in the range 15--25nmol/min per mg of cell protein at 37 degrees C. 4. Alanine and serine transport were mutually competitive; glutamine inhibited the transport of alanine and serine non-competitively. 5. The initial rate of transport of these amino acids was inhibited when the intracellular content of ATP was decreased. 6. Ouabain inhibited the rate of alanine transport without inhibiting the rate of alanine metabolism. 7. It is concluded that a minimum of three transport systems must be postulated to exist in the liver cell plasma membrane to account for the transport of alanine, serine and glutamine. The rate of transport of these amino acids in isolated hepatocytes is unlikely to limit the rate at which they are metabolized.