Cysteine uptake and taurine biosynthesis in freshly isolated and primary cultured rat hepatocytes

Analysis of the uptake and metabolism of [14C]cysteine in rat liver was undertaken using freshly isolated hepatocytes and hepatocytes maintained in primary culture. The uptake of [14C]cysteine by freshly isolated hepatocytes was by means of both saturable and non-saturable transport systems and the former system was thought to involve facilitated diffusion. The uptake of [14C]cysteine by hepatocytes maintained in primary culture for 24 h also consisted of non-saturated and saturated transport mechanisms. The magnitude of the saturable transport system in cultured hepatocytes was, however, much greater than that found in freshly isolated hepatocytes, and was considered to be operated by active transport. Both freshly isolated and primary cultured hepatocytes had cysteine sulphinic acid decarboxylase activity, but this enzyme activity in the latter cells was noticeably reduced in comparison with that found in freshly isolated hepatocytes. Hepatocytes maintained in primary culture produced not only radiolabelled taurine, but also radiolabelled cysteine sulphinic acid, hypotaurine and alanine when incubated with [14C]cysteine. The present results indicate that cultured hepatocytes actively transport cysteine as well as metabolizing cysteine to taurine via cysteine sulphinic acid and hypotaurine.     

Cholic acid uptake and isolated rat hepatocytes.

Cholic acid uptake was studied in isolated rat hepatocytes using a centrifugal filtration technique to allow rapid sampling. Hepatocytes were found to adsorb as well as to transport cholic acid. The adsorption was characterized by a capacity of 24 nmol X mg cell protein-1 and an association constant of 0.59 X 103 M-1. Cholic acid uptake was linear with respect to concentration at or below 10 degree C, suggesting a unsaturable uptake process which was considered to represent simple diffusion and is quantitated by a diffusion coefficient of 1.76 pmol cholic acid X min-1 X mg protein-1 X muM-1. Above 10 degrees C the uptake curve was biphasic. After subtracting the unsaturable component from uptake rates at higher temperatures, a curve showing saturable kinetics resulted. The apparent Km and V values at 37 degrees C were calculated to be 31muM and 0.8 nmol X min-1 X mg protein-1 respectively. This saturable uptake process was temperature-dependent with an activation energy of 13 kcal X mol-1 (5.44 X 104 J X mol-1) and was inhibited by oligomycin and KCN. Countertransport was demonstrated with cholic, taurocholic and chenodeoxycholic acids. The results suggest that cholic acid is transported by an energy-dependent carrier-mediated process in addition to simple diffusion by hepatocytes, and that the postulated carrier has affinity for other bile acids.     

Selective inhibition of long-chain fatty acid uptake in short-term cultured rat hepatocytes by an antibody to the rat liver plasma membrane fatty acid-binding protein

Uptake of long-chain fatty acids by short-term cultured hepatocytes was studied. Rat hepatocytes, which were cultured for 16 h on plastic dishes (3.6 X 10(6) cells/dish), were incubated with [3H]oleate in the presence of various concentrations of bovine serum albumin as a function of the concentration of unbound [3H]oleate in the medium. At 37 degrees C initial uptake velocity (V0) was saturable (Km = 9 X 10(-8) M; Vmax = 835 pmol/min per mg protein). V0 was temperature dependent with an optimum at 37 degrees C and markedly reduced at 4 degrees C and 70 degrees C. To evaluate the biologic significance of a previously isolated rat liver plasma membrane fatty acid-binding protein as putative carrier protein in the hepatocellular uptake of fatty acids, cultured hepatocytes were treated with a monospecific rabbit antibody (IgG-fraction) to this membrane protein or the IgG-fraction of the pre-immune serum as controls. Uptake kinetics of [3H]oleate in antibody pretreated short-term cultured hepatocytes revealed a depression of Vmax by 70%, while Km was only reduced by 16% compared to controls, indicating a predominant non-competitive type of inhibition. V0 of a variety of long-chain fatty acids (oleic acid, arachidonic acid, palmitic acid, stearic acid) was reduced by 56-69%, while V0 of [35S]sulfobromophthalein, [3H]cholic acid and [14C]taurocholic acid remained unaltered. These data support the concept that in the system of cultured hepatocytes, uptake of long-chain fatty acids is mediated by the rat liver plasma membrane fatty acid-binding protein.     

Transport of 2-oxoisocaproate in isolated hepatocytes and liver mitochondria

The transport of 2-oxoisocaproate into isolated hepatocytes and liver mitochondria of rat was studied using [U-14C]2-oxoisocaproate and the silicone oil filtration procedure. 2-Oxoisocaproate uptake by hepatocytes was composed of: rapid adsorption, unmediated diffusion and carrier-mediated transport. The carrier-mediated transport was strongly inhibited by 4,4'-diisothiocyano-2,2'-stilbenedisulphonic acid and p-chloromercuribenzoate, was less sensitive to alpha-cyano-4-hydroxycinnamate and insensitive to p-chloromercuriphenylsulphonate. Other 2-oxo acids: pyruvate, 2-oxoisovalerate and 2-oxo-3-methylvalerate, were also inhibitory. The kinetic parameters of the carrier-mediated transport were Km 30.6 mM and Vmax 23.4 nmol/min per mg wet wt, at 37 degrees C. It is concluded that at its low, physiological, concentration, 2-oxoisocaproate penetrates the hepatocyte membrane mainly by unmediated diffusion. The uptake of 2-oxoisocaproate by isolated liver mitochondria was partly inhibited by alpha-cyano-4-hydroxycinnamate, the inhibitor of mitochondrial monocarboxylate carrier. The remaining uptake was linearly dependent on 2-oxoisocaproate concentration and represented unmediated diffusion. The carrier-mediated transport exhibited the following kinetic parameters: Km 0.47 mM, Vmax 1.0 nmol/min per mg protein at 6 degrees C; and Km 0.075 mM and Vmax about 8 nmol/min per mg protein at 37 degrees C.     

Effects of temperature on the transport of nucleosides in guinea pig erythrocytes

The initial rate of [14C]uridine transport by guinea pig erythrocytes was investigated at different temperatures. At 37, 22, and 10 degrees C the concentration dependence of uridine zero-trans influx and equilibrium exchange influx was resolved into two components; (a) a saturable component which followed simple Michaelis-Menten kinetics and which was inhibited by nitrobenzylthioinosine, and (b) a linear component of low magnitude and insensitive to nitrobenzylthioinosine inhibition. The maximum velocity, Vmax, of zero-trans uridine influx for the saturable transport system was 70-fold higher at 37 than 10 degrees C (1.24, 0.20, and 0.018 mmol/L of cells per hour at 37, 22, and 10 degrees C, respectively). Similarly, the apparent affinity, Km, for zero-trans influx decreased as the temperature was lowered (0.27, 0.066, and 0.038 mM at 37, 22, and 10 degrees C, respectively). In contrast, uridine equilibrium exchange influx was less temperature dependent (Vmax, 2.80, 0.89, and 0.14 mmol/L of cells per hour; apparent Km 0.61, 0.36, and 0.24 mM at 37, 22, and 10 degrees C, respectively). These results demonstrate that the mobility of the empty carrier is impaired to a greater extent than the mobility of the loaded carrier temperature decreased. However, the kinetic constants for zero-trans uridine influx and efflux at 37 degrees C were similar, indicating that the nucleoside transporter exhibited directional symmetry at 37 degrees C. Arrhenius plots of the maximum velocity for equilibrium exchange and zero-trans uridine influx were discontinuous above 25 degrees C, but between 20 and 5 degrees C the plots were linear (Ea = 22 and 30 kcal/mol for equilibrium exchange and zero-trans influx, respectively.     

Hepatocellular transport of cyclosomatostatins: evidence for a carrier system related to the multispecific bile acid transporter.

The uptake of the cyclopeptide c(Phe-Thr-Lys-Trp-Phe-D-Pro) (008), an analog of somatostatin with retro sequence, was studied in isolated hepatocytes. 008 is taken up by hepatocytes in a concentration-, time-, energy- and temperature- dependent manner. Since 008 is hydrophobic, it binds rapidly to liver cells. This is evident by the positive intercept at the gamma-axis in the uptake curves. At higher concentrations, a minor part of the transport occurs by diffusion at a rate of 8.307.10(-6) cm/s. This part of diffusion is measured at 4 degrees C and can be subtracted from the uptake at 37 degrees C resulting in the carrier mediated part of uptake which is saturable. Kinetic parameters for the saturable part of uptake are Km 1.5 microM and Vmax 40.0 pmol/mg per min. The transport is decreased in the absence of oxygen and in the presence of metabolic inhibitors. Uptake is accelerated at temperatures above 20 degrees C. The activation energy was determined to be 30.77 kJ/mol. The membrane potential and not a sodium gradient is the main driving force for 008 transport. Cholate (a typical substrate of the multispecific bile acid transporter) and taurocholate are mutual competitive inhibitors of 008 uptake. Phalloidin, antamanide and iodipamide, typical foreign substrates of the transporter, interfere with the uptake of 008. AS 30D ascites hepatoma cells, known to be unable to transport bile acids, phalloidin and iodipamide, are also unfit to transport 008. Interestingly, sulfobromophthalein (BSP) but not rifampicin, both foreign substrates of the bilirubin carrier, inhibits the transport of 008 in a competitive manner.     

Excretion of glutathione conjugates by primary cultured rat hepatocytes

Conjugation of xenobiotics with glutathione occurs commonly within the liver, and these glutathione conjugates are then preferentially excreted into bile. We have characterized this excretory process using primary cultured hepatocytes (24 h). 1-Chloro-2,4-dinitrobenzene rapidly entered the cells and formed a glutathione conjugate, S-(dinitrophenyl)glutathione, irrespective of the temperature of incubation. In contrast, the efflux of the glutathione conjugate was essentially absent in the cold but recovered rapidly upon rewarming of the cells. Therefore, initial rates of efflux of the conjugate at 37 degrees C were measured from cells preloaded biosynthetically at 10 degrees C. Efflux was a saturable process with respect to intracellular S-(dinitrophenyl)glutathione with an apparent Km of 0.58 +/- 0.12 mM and Vmax of 0.15 +/- 0.05 nmol/min/mg of protein. The excretion of S-(dinitrophenyl)glutathione had an energy of activation of 15.3 kcal/mol. The glutathione conjugate of p-nitrobenzylchloride when formed within the hepatocytes acted as a competitive inhibitor of S-(dinitrophenyl)glutathione efflux. Cultured hepatocytes, therefore, appeared to have a specific transport process for the excretion of glutathione conjugates. The addition of S-(dinitrophenyl)glutathione, but not GSH, GSSG, or methionine, to the medium caused a decrease in the rate of efflux of radiolabeled S-(dinitrophenyl)glutathione. The hepatocytes were able, however, to excrete the glutathione conjugate against an excess of extracellular S-(dinitrophenyl)glutathione. This observation suggested that extracellular S-(dinitrophenyl)glutathione, although capable of binding to the carrier, entered the hepatocytes quite slowly relative to rates of efflux. This carrier may function in a manner that would minimize the reuptake by hepatocytes of conjugates that have been excreted into the bile.     

Inward fluxes of adenosine in erythrocytes and cultured cells measured by a quenched-flow method.

Dilazep, a vasodilator previously recognized as an inhibitor of adenosine permeation, very rapidly blocked the uptake of adenosine by cultured L5178Y cells, and accordingly was used as a quencher in a simple quenched-flow system for measuring cellular uptake of nucleosides during very short intervals. Time courses of cellular uptake of adenosine, assayed during intervals between 0.05 and 0.5s with the quenched-flow system, were linear and defined initial rates of adenosine uptake. The latter are rates of inward transport of adenosine. Kinetic constants for that process in cultured S49 cells determined with the quenched-flow procedure were similar to those determined with an assay dependent on manual timing. In studies of adenosine uptake kinetics in human erythrocytes at 22 degrees C and 37 degrees C in which the quenched-flow procedure was used, time courses of adenosine uptake were linear at both temperatures and defined initial uptake rates; kinetic constants (means +/- S.E.M.) at 22 degrees C (n = 8) were Km 25 +/- 14 microM and Vmax. 15 +/- 5 pmol/s per microliter of cell water and at 37 degrees C (n = 3) were Km 98 +/- 17 microM and Vmax. 80 +/- 9 pmol/s per microliter of cell water.     

Characteristics of taurine transport system and its developmental pattern in mouse cerebral cortical neurons in primary culture

Developmental patterns and pharmacological and biochemical properties of taurine transport system were investigated using developing primary cultured neurons prepared from mouse cerebral cortex by trypsin treatment. [3H]Taurine was incorporated into neurons via a high-affinity transport system of which the Km value as well as the Vmax value increased during neuronal development in vitro. This transport system was also inhibited by sodium withdrawal from incubation medium and exposures for 15 h to several metabolic inhibitors such as 2,4-dinitrophenol and monoiodoacetate. In addition, [3H]taurine uptake in both neurons cultured for 3 and 14 days was competitively inhibited by beta-alanine, guanidinoethanesulfonate and hypotaurine. Cysteic acid and cysteine sulfinic acid, metabolic intermediates produced in the process of taurine biosynthesis in the brain from cysteine, induced significant reductions in [3H]taurine uptake in both types of cultured neurons, while cysteine, isethionic acid, cysteamine and cystamine exhibited no alterations in [3H]taurine transport. Moreover, non-competitive inhibition of [3H]taurine uptake by cysteic acid was observed in both neurons. These results clearly indicate that taurine uptake was mediated by the sodium- and energy-dependent transport system with high affinity in 14-day-old neurons as well as neurons cultured for 3 days and that both the Km and Vmax values of this transport system increase during neuronal development in vitro. The results described above suggest that the decrease in taurine content observed in developing brain is unlikely to be due to alteration in the capacity of the taurine transport system during neuronal development.     

Adenine and hypoxanthine transport in human erythrocytes: distinct substrate effects on carrier mobility.

Transport of adenine and hypoxanthine in human erythrocytes proceeds via two mechanisms: (1) a common carrier for both nucleobases and (2) unsaturable permeation 4-5-fold faster for adenine for hypoxanthine. The latter process was resistant to inactivation by diazotized sulfanilic acid. Carrier mediated transport of both substrates was investigated using zero-trans and equilibrium exchange protocols. Adenine displayed a much higher affinity for the carrier (Km approximately 5-8 microM) than hypoxanthine (Km approximately 90-120 microM) but maximum fluxes at 25 degrees C were generally 5-10-fold lower for adenine (Vmax approximately 0.6-1.4 pmol/microliters per s) than for hypoxanthine (Vmax approximately 9-11 pmol/microliters per s). The carrier behaved symmetrically with respect to influx and efflux for both substrates. Adenine, but not hypoxanthine reduced carrier mobility more than 10-fold. The mobility of the unloaded carrier, calculated from the kinetic data of either hypoxanthine or adenine transport, was the same thus providing further evidence that these substrates share a common transporter and that their membrane transport is adequately described by the alternating conformation model of carrier-mediated transport.     

Cation transport in Escherichia coli. VIII. Potassium transport mutants

Analysis of K transport mutants indicates the existence of four separate K uptake systems in Escherichia coli K-12. A high affinity system called Kdp has a Km of 2 muM, and Vmax at 37 degrees C of 150 mumol/g min. This system is repressed by growth in high concentrations of K. Two constitutive systems, TrkA and TrkD, have Km's of 1.5 and 0.5 mM and Vmax's of 550 and 40 at 37 and 30 degrees C, respectively. Mutants lacking all three of these saturable systems take up K slowly by a process, called TrkF, whose rate of transport is linearly dependent on K concentration up to 105 mM. On the whole, each of these systems appears to function as an independent path for K uptake since the kinetics of uptake when two are present is the sum of each operating alone. This is not true for strains having both the TrkD and Kdp systems, where presence of the latter results in K uptake which saturates at a K concentration well below 0.1 mM. This result indicates some interaction between these systems so that uptake now has the affinity characteristic of the Kdp system. All transport systems are able to extrude Na during K uptake. The measurements of cell Na suggest that growing cells of E. coli have very low concentrations of Na, considerably lower than indicated by earlier studies.     

Comparison of uptake kinetics in freshly isolated suspensions and short-term primary cultures of rat hepatocytes

The apparent kinetics of uptake of various model substrates were examined for hepatocytes in suspension and primary culture up to 72 h. The ability of hepatocytes to take up taurocholate and ouabain was decreased in culture. Vmax for uptake of both substrates diminished rapidly with increasing time in culture. An increase in Km was observed in cultures 6 h after plating, but there was no further change with prolongation of culture time. The decrease of uptake of taurocholate and ouabain during culture may be due to the reduction in the number of transport carriers plus a decrease of affinity of the carrier to substrates. The nonsaturable component of cadmium uptake was much reduced in cultured cells compared with the suspensions. The saturable process was lower in 6 h culture but increased to a level comparable with the fresh cells at longer culture time. No significant change was found in the Km between suspensions and cultures. Uptake of alpha-aminoisobutyric acid was greater in culture while that of 3-O-methyl-D-glucose was relatively stable but about one-half that found in cell suspension. Thus, uptake of two substrates, taurocholate and ouabain, is clearly compromised with increasing time in primary culture, while uptake of the other substrates does not reflect such a dramatic decrease. It is therefore apparent that the cell preparation of choice in uptake studies depends on the substrate and the nature of the experiments.     

Liver endothelium mediates the uptake of iron-transferrin complex by hepatocytes

We have previously shown that in the liver, transferrin (TF) receptors are limited to endothelial cells, and hepatocytes and Kupffer cells do not have TF receptors. To study the transport of iron into hepatocytes, we fractionated liver cell suspensions into endothelium and hepatocyte fractions. At 4 degrees C liver (but not umbilical cord) endothelium bound Fe-TF with a saturable kinetics. At 37 degrees C, the endothelial uptake was followed by its gradual release. Transendothelial transport of TF was visually demonstrated by perfusion of liver using colloidal gold-labeled TF. The released Fe-TF acquired the potential for binding to fresh target hepatocytes and binding was not inhibited by excess cold TF but was inhibitable by asialofetuin, suggesting galactosyl receptors and not TF receptors as a recognition mechanism. Isoelectrofocusing of the supernate after preincubation for 90 min at 37 degrees C with endothelial cells, demonstrated the presence of a newly generated band which co-migrated with asialotransferrin. We conclude that Fe-TF is initially removed by liver endothelium where it is modified probably by desialation to expose the galactosyl residues of the glycoproteins. The modified molecule is subsequently released and recognized by hepatocytes through a TF receptor-independent mechanism which may involve galactosyl receptors of hepatocytes. The findings indicate a key role for endothelium in the transport of Fe-TF into the liver and may suggest a physiological function for galactosyl receptors on hepatocyte surface.     

Prostaglandin E1 binding protein on the surface of primary cultured hepatocytes

Prostaglandin E1 (PGE1) was bound to primary cultured rat hepatocytes in a receptor-dependent manner in serum-free medium at 4 degrees C. When added at a concentration of 2 X 10(-9) M, maximal specific binding occurred within 60-90 min. Trypsin treatment of the cells reduced the binding capacity to about 50% of that of untreated cells. Scatchard-analysis of the binding data showed that the cells had an apparent dissociation constant of 1.2 X 10(-8) M and a binding capacity of 580 fmol (approximately 3.5 X 10(11) PGE1 receptors)/mg of protein. In experiments at 37 degrees C, maximal specific binding occurred within 5 min and was 6-7 times that at 4 degrees C, but the amount of bound PGE1 decreased rapidly after 5 min due to metabolism of PGE1 in the hepatocytes. Thin-layer chromatographic analysis showed that the material bound to the cell surface consisted of intact PGE1 and its metabolites at 37 degrees C, but PGE1 only at 4 degrees C.     

High-Affinity Uptake of Spermine by Slices of Rat Cerebral Cortex

Abstract: The accumulation of the polyamine spermine into 0.1-mm prisms of rat cerebral cortex has been investigated at both 37°C and at 4°C. Kinetic analysis of the temperature-sensitive portion of uptake indicates two high-aftinity saturable components together with an unsaturable component at high concentrations. The 'very high'– affinity saturable system ( K _m= 3.8 nM) was temperature- and sodium-dependent, and significantly reduced by metabolic inhibitors, findings that are consistent with an active transport system for spermine into brain tissue. The 'high'– affinity saturable component ( K _m= 0.44 μM) was sodium-dependent and inhibited by ouabain, but only partially susceptible to inhibition by 2,4-dinitrophenol and sodium cyanide. The significance of these results with respect to the function of spermine in the central nervous system is discussed.     

The hepatic binding and uptake kinetics of epidermal growth factor: studies with isolated rat hepatocytes

Hepatocytes are known to bind and internalize a variety of small molecular weight proteins by a process known as receptor-mediated endocytosis (RME). The purpose of this investigation was to characterize the binding and uptake kinetics of a small protein known to be taken up by the liver by RME, epidermal growth factor (EGF), using suspensions of freshly isolated rat hepatocytes. Rat hepatocytes accumulated 125I-EGF (90 pM) in a temperature-dependent fashion. Isolated hepatocytes incubated at 37 degrees C with 125I-EGF began to release a TCA-soluble radiolabeled material into the incubation medium with a lag period of 20 min. EGF uptake by isolated hepatocytes was linear for only 60 seconds and displayed saturation kinetics (apparent Km of 4 nM and a Vmax of 105 fM/min/10(6) cells). Hepatocytes incubated at 4 degrees C bound, but did not internalize, EGF. Under these conditions, EGF binding was saturable at concentrations above 8 nM. A Scatchard analysis revealed that the average number of receptors per hepatocyte was 7.7 X 10(4) with a dissociation constant of 2.6 nM. These data demonstrate that freshly isolated hepatocytes are capable of binding, internalizing and metabolizing EGF and thus are a good model to study RME of small molecular weight proteins.     

Transcellular transport of lipoprotein through arterial endothelial cells in monolayer culture

To study the mechanism of lipoprotein transport through arterial endothelial cells, porcine endothelial cells were cultured on gelated type I collagen supported by a dacron sheet, and the transport of low density lipoprotein (LDL) labeled with rhodamine B isothiocyanate (RB-LDL) through the cells was measured. Light and scanning electron microscopy showed that the cells on the gel were confluent. There was little RB-LDL transport through the endothelial monolayer at 0 degrees C. RB-LDL transport through the monolayer at 37 degrees C was dose-dependent saturable at 0.4 mg protein/ml. The transport was energy-dependent, since its rate was affected by temperature and was inhibited by a combination of 2-deoxyglucose (50 mM) and NaN3 (10 mM). RB-LDL was shown not to be degraded during transport.     

Mechanisms of the ability of insulin to activate the glucose-transport system in rat adipocytes.

Isolated rat adipocytes were used to assess the mechanisms of the ability of insulin to accelerate glucose transport. Glucose transport was determined by measuring the initial rates of 2-deoxyglucose uptake, and at 24 degrees C insulin increased the Vmax. of transport from 7.3 +/- 1 to 23.1 +/- 2 nmol/min per 10(6) cells, but the Km value remained unchanged (2.5, cf. 2.4 mM). When the Vmax. of basal and insulin-stimulated transport was measured as a function of temperature (15-37 degrees C), parallel Arrhenius plots were obtained yielding equal activation energies of approx. 59kJ/mol. Since both processes have equal activation energies the data indicate that insulin increases Vmax. by increasing the number of available carriers rather than enhancing intrinsic activity of already functioning carriers. Since the ability of insulin to activate glucose transport did not decrease with temperature (whereas plasma-membrane fluidity declines), it is suggested that lateral diffusion of insulin receptors within the plasma-membrane bilayer is not a rat-determining step in insulin action.     

Adipose differentiation related protein (ADRP) expressed in transfected COS-7 cells selectively stimulates long chain fatty acid uptake.

Adipose differentiation related protein (ADRP) is a 50-kDa novel protein cloned from a mouse 1246 adipocyte cDNA library, rapidly induced during adipocyte differentiation. We have examined ADRP function, and we show here that ADRP facilitates fatty acid uptake in COS cells transfected with ADRP cDNA. We demonstrate that uptake of long chain fatty acids was significantly stimulated in a time-dependent fashion in ADRP-expressing COS-7 cells compared with empty vector-transfected control cells. Oleic acid uptake velocity increased significantly in a dose-dependent manner in ADRP-expressing COS-7 cells compared with control cells. The transport Km was 0.051 microM, and Vmax was 57.97 pmol/10(5) cells/min in ADRP-expressing cells, and Km was 0.093 microM and Vmax was 20.13 pmol/10(5) cells/min in control cells. The oleate uptake measured at 4 degrees C was only 10% that at 37 degrees C. ADRP also stimulated uptake of palmitate and arachidonate but had no effect on uptake of medium chain fatty acid such as octanoic acid and glucose. These data suggest that ADRP specifically enhances uptake of long chain fatty acids by increasing the initial rate of uptake and provide novel information about ADRP function as a saturable transport component for long chain fatty acids.     

Enantiomeric selectivity of carbovir transport.

Carbovir (9-[4 alpha-(hydroxymethyl)cyclopent-2-ene-1 alpha-yl]guanine) (CBV) is a carbocyclic analogue of 2',3'-dideoxyguanosine that exhibits potent and selective in vitro activity against human immunodeficiency virus. Antiviral activity is associated with only the (-)-enantiomer. The transport characteristics of both (-)-CBV and (+)-CBV were investigated in human erythrocytes at 37 degrees C using a papaverine-stop assay. The influx of both enantiomers appeared saturable and was inhibited greater than 90% by a combination of adenine (a low Km permeant of the nucleobase carrier) and dilazep (a potent inhibitor of nucleoside transport). The influx of (-)-CBV and (+)-CBV proceeded primarily via the nucleobase carrier with Vmax (picomoles/second/5 microliters of cells)/Km (millimolar) values of 17/0.12 and 140/1.9, respectively. To a lesser extent, the influx of (-)-CBV and (+)-CBV also occurred via the nucleoside transporter. Although both compounds exhibited a similar low affinity for this latter carrier (Km approximately 2 mM), the Vmax for (-)-CBV influx was approximately 4-fold higher than the Vmax for (+)-CBV influx. We conclude that both CBV enantiomers enter human erythrocytes by two transporters that are enantiomerically selective.