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.     

Neutral amino acid transport in human synovial cells: substrate specificity of adaptative regulation and transinhibition

Neutral amino acid transport was characterized in human synovial cells. The amino acids tested are transported by all three major neutral amino acid transport systems, that is, A, L, and ASC. The model amino acid 2-aminoisobutyric acid (AIB) was found to be a strong specific substrate for system A in synovial cells. When cells were starved of amino acids, the activity of AIB transport increased, reaching a maximum within 1 h. The stimulation of transport activity was not blocked by cycloheximide and would thus appear to be related to a release from transinhibition. Similarly, the decrease in the activity of AIB transport observed after the addition of alpha-methyl-aminoisobutyric acid (meAIB) appeared to be related to transinhibition. However, using a different approach, that is, amino acid starvation followed by incubation with 10 mM meAIB and transfer to an amino acid-free medium with or without cycloheximide supplementation, a clear increase in AIB uptake, due both to derepression and a release from transinhibition, was observed. Unlike human fibroblasts, the depression of system A in these synovial cells was not serum-dependent. The process of derepression was observed only after preloading with meAIB. Neither AIB nor alanine produced this phenomenon. Moreover, alanine preloading led to a large increase in AIB transport activity due to a release from transinhibition. These observations indicate that the process of derepression and release from transinhibition are specific to the substrates present in the culture medium prior to amino acid starvation.     

Regulation of Membrane Transport Sites for Amino Acids in Myogenic Cells

Abstract. Myoblasts from 12-day chick embryos in cell culture transport the nonmetabolizable amino acid α-aminoisobutyric acid (AIB) two to three-fold more rapidly than multinucleated myotubes which form from them. This decrease in transport is due to a relative decrease in the number of transport sites per unit area of cell surface suggesting a compositional change in the plasma membrane during myogenesis. In studies reported here, AIB transport was monitored throughout myogenesis and correlated with other aspects of differentiation. During myogenesis the number of amino acid transport sites remains constant per myotube nucleus. As myogenesis proceeds, there is a marked increase in cellular protein and cell surface without a commensurate increase in amino acid transport sites. The net consequence of the surface area change is fewer amino acid transport sites per unit area of myotube membrane surface. The decrease in membrane transport sites for AIB per unit area of membrane is not a result of length of time in culture per se, medium depletion, or cell density, but is a result of differentiation, since blocking myoblast fusion by deprivation of calcium delays the decrease in AIB transport sites per unit cell surface area while reversal of the calcium deprivation block is accompanied by a rapid decrease in the number of AIB transport sites per unit cell surface area. Thus, the decrease in AIB transport sites is an aspect of differentiation which accompanies the marked elaboration of surface membrane during myogenesis.     

Regulation of membrane transport sites for amino acids in myogenic cells. A differentiation dependent phenomenon

Myoblasts from 12-day chick embryos in cell culture transport the nonmetabolizable amino acid alpha-aminoisobutyric acid (AIB) two to three-fold more rapidly than multinucleated myotubes which form from them. This decrease in transport is due to a relative decrease in the number of transport sites per unit area of cell surface suggesting a compositional change in the plasma membrane during myogenesis. In studies reported here, AIB transport was monitored throughout myogenesis and correlated with other aspects of differentiation. During myogenesis the number of amino acid transport sites remains constant per myotube nucleus. As myogenesis proceeds, there is a marked increase in cellular protein and cell surface without a commensurate increase in amino acid transport sites. The net consequence of the surface area change is fewer amino acid transport sites per unit area of myotube membrane surface. The decrease in membrane transport sites for AIB per unit area of membrane is not a result of length of time in culture per se, medium depletion, or cell density, but is a result of differentiation, since blocking myoblast fusion by deprivation of calcium delays the decrease in AIB transport sites per unit cell surface area while reversal of the calcium deprivation block is accompanied by a rapid decrease in the number of AIB transport sites per unit cell surface area. Thus, the decrease in AIB transport sites is an aspect of differentiation which accompanies the marked elaboration of surface membrane during myogenesis.     

A Na+-DEPENDENT SYSTEM A AND ASC-INDEPENDENT AMINO ACID TRANSPORT SYSTEM STIMULATED BY GLUCAGON IN RAT HEPATOCYTES

The effects of glucagon on amino acid transport in rat hepatocytes are not fully understood. We examined the effect of this hormone on alanine, serine and cysteine preferring system (system ASC)-mediated amino acid transport in rat hepatocyte monolayers using 2-aminoisobutyric acid (AIB) and L -cysteine. Glucagon induced a time and protein synthesis-dependent stimulation of Na⁺-dependent alanine preferring system (system A)-independent AIB transport. The glucagon-induced increase in transport activity was not modified by substrate starvation and not related to changes in the intracellular pool of amino acids. Glucagon did not modify system ASC activity measured by L -cysteine. Therefore the transport activity of AIB independent of system A stimulated by glucagon cannot be attributed to system ASC. This suggests a Na⁺-dependent transport system in rat hepatocytes not identified until now.     

Neutral amino acid absorption by the rat epididymis

The technique of stopped-flow/split-drop microperfusion was used to study the absorption of the neutral amino acid alpha-aminoisobutyric acid (AIB) from different epididymal regions of the rat. Absorption of AIB from the lumen of the caput, corpus, and cauda was saturable and time-dependent. The apparent Km values for each of the regions studied were similar (approximately 6 mM), whereas the Vmax values were progressively higher from caput, corpus, and cauda, respectively. Absorption of AIB from the lumina of the caput, corpus, and cauda epididymidis was linear over 60 min. The absorption of AIB from the lumen of the caput was sodium-dependent and inhibitable by 2-methyl-alpha-aminoisobutyric acid (MeAIB), a specific inhibitor of neutral amino acid transport. Similarly, absorption of AIB from the lumen of the corpus epididymidis was sodium-dependent; however, uptake was not significantly reduced in the presence of MeAIB. Absorption of AIB from the lumen of the cauda epididymidis was neither sodium-dependent nor inhibitable by MeAIB. It is suggested that neutral amino acid absorption involves different transport carriers in different epididymal regions. These findings also support our previous observations that there exists a selective permeability barrier from lumen to blood along the epididymal duct.     

Characteristics of a neutral amino acid transport system (system A) in osteoblastic rat osteosarcoma cells

Transport of alpha-aminoisobutyric acid (AIB) in the clonal, osteoblastic-like cell line, ROS 17/2, was characterized. AIB transport was time-, temperature- and Na+-dependent. Both ouabain and monensin inhibited AIB transport in these cells. AIB uptake followed Michaelis-Menten kinetics with an apparent Km = 0.57 mM and a Vmax = 4.07 nmol/30 min/plate. These characteristics are consistent with the presence of system A neutral amino acid transport in ROS 17/2 cells. Exposure of ROS 17/2 cells to either parathyroid hormone or dibutyryl cyclic AMP (db-cAMP), but not to dibutyryl cyclic GMP (db-cGMP), markedly stimulated AIB transport. This suggests that extracellular stimuli which enhance osteogenic responses in this cell type, coordinately upregulate system A transport.     

Hormonal regulation of amino acid transport and cAMP production in monolayer cultures of rat hepatocytes

The effects of insulin, glucagon or Dexamethasone (DEX) and of glucagon with insulin or DEX were examined on the uptake of 2-amino [1-¹⁴C]isobutyric acid (AIB) and N-Methyl-2-amino [1-¹⁴C]isobutyric acid (NMe AIB) in monolayer cultures of rat hepatocytes. Insulin and glucagon stimulated the uptake of both the amino acids and DEX inhibited it, showing that all three of these hormones regulate the A system (the sodium-dependent system that permits the transport of NMe AIB) for amino acid transport in these cultures. Experiments investigating the transport of aminocyclopentane-1-carboxylic acid, 1- [carboxyl-¹⁴C] in the presence of excess AIB or in the absence of sodium showed that insulin had no effect on the activity of the L system (the sodium-independent system that prefers leucine). Experiments on the uptake of AIB in the presence of excess NMe AIB showed insulin had no effect on the transport activity of the ASC system (the sodium-dependent system that does not transport NEe AIB). Insulin concentrations ranging from 0.1 nM to 100 nM did not antagonize the stimulatory effect of optimum or suboptimum concentrations of glucagon on the uptake of either AIB or NMe AIB. Similarly, glucagon did not antagonize the stimulatory effect of optimum or suboptimum concentrations of insulin on the uptake of both the amino acids. The combined effect of insulin and glucagon was additive on the rate as well as the cumulative uptake of both AIB and NMe AIB. DEX alone inhibited the transport of both AIB and NMe AIB by about 25%, while glucagon caused a 2–3-fold increase; however, the addition of glucagon to cultures containing DEX caused a 7–8-fold increase in the uptake of both AIB and NMe AIB when compared to cultures containing DEX alone. The effect of insulin on the levels of cAMP was also investigated. Insulin had no effect on the cAMP levels in cultures treated or untreated with optimum or suboptimum concentrations of glucagon.     

Regulation of amino acid uptake by phorbol esters and hypertonic solutions in rat thymocytes

Growth factors, mitogens, and malignant transformation can alter the rate of amino acid uptake in mammalian cells. It has been suggested that the effects of these stimuli on proliferation are mediated by activation of Na+/H+ exchange. In lymphocytes, Na+/H+ exchange can also be activated by phorbol esters and by hypertonic media. To determine the relationship between the cation antiport and amino acid transport, we tested the effects of these agents on the uptake of alpha-aminoisobutyric acid (AIB), methyl-AIB, proline, and leucine in rat thymocytes. Both 12-O-tetradecanoylphorbol-13-acetate (TPA) and hypertonicity stimulated amino acid uptake through system A (AIB, proline, and methyl-AIB). In addition, TPA, but not hypertonicity, also elevated leucine uptake. The stimulation of the Na+ -dependent system A was not due to an increased inward electrochemical Na+ gradient. The effects of TPA and hypertonic treatment were not identical: Stimulation of AIB uptake by TPA was observed within minutes, whereas at least 1 hr was required for the effect of hypertonicity to become noticeable. Moreover, stimulation by hypertonicity but not that by TPA, was partially inhibited by cycloheximide, suggesting a role of protein synthesis. That stimulation of Na+/H+ exchange does not mediate the effects on amino acid transport is suggested by two findings: 1) the stimulation of AIB uptake was not prevented by concentrations of amiloride or of 5-(N,N-disubstituted) amiloride analogs that completely inhibit the Na+/H+ antiport and 2) conditions that mimic the effect of the antiport, namely, increasing [Na+]i or raising pHi failed to stimulate amino acid uptake. Thus, in lymphocytes, activation of Na+/H+ exchange and stimulation of amino acid transport are not casually related.     

Induction of amino acid transport by L-triiodothyronine in cultured growth hormone-producing rat pituitary tumor cells (GC cells)

The action of L-triiodothyronine (T3) on amino acid transport in the GC clonal strain of rat pituitary cells was investigated by measurement of the uptake of the nonmetabolizable amino acid, alpha-aminoisobutyric acid (AIB). The uptake of AIB by GC cells appeared to require energy and Na+ and displayed Michaelis-Menten kinetics. In comparison to cultures maintained in the absence of T3, T3 addition resulted in an increase in AIB uptake which seemed due to an increase in the initial rate of AIB transport. T3 addition resulted in increased AIB accumulation at later time points as well. T3 induction of AIB transport did not occur until 3.5 h after addition of T3, and this effect was blocked by cycloheximide. Maximal induction occurred 48 to 72 h later. One-half maximal induction occurred 24 to 48 h after addition of T3. No detectable changes either in AIB uptake or intracellular water space, measured by uptake of the nonmetabolizable sugar, 3-O-methyl-D-glucose, were noted for the first 120 min after addition of T3. Induction of AIB transport occurred at 0.05 nM T3 (total medium concentration) and one-half maximal induction occurred at 0.17 nM T3. The relative potencies of four iodothyronine analogues for AIB transport were in accord with their reported activities in nuclear T3 receptor binding assays. These data suggest that induction of AIB transport by T3 may be mediated by the nuclear T3 receptor and may reflect the pleiotrophic response of GC cells to thyroid hormone.     

Hormonal regulation of hepatic amino acid transport

The transport of 2-aminoisobutyric acid (AIB) into liver tissue was increased by both insulin and glucagon. We have now shown that these hormones do not stimulate the same transport system. Glucagon, possibly via cAMP, increased the hepatic uptake of AIB by a mechanism which resembled system A. This glucagon-sensitive system could be monitored by the use of the model amino acid MeAIB. In contrast, the insulin-stimulated system exhibited little or no affinity for MeAIB and will be referred to as system B. On the basis of other reports that the hepatic transport of AIB is almost entirely Na⁺ dependent and the present finding that the uptake of 2-aminobicyclo [2,2,1] heptane-2-carboxylic acid (BCH) was not stimulated by either hormone, we conclude that system B is Na⁺ dependent. Furthermore, insulin added to the perfusate of livers from glucagon-pretreated donors suppressed the increase in AIB or MeAIB uptake. Depending upon the specificities of systems A and B, both of which are unknown for liver tissue, the insulin/glucagon ratio may alter the composition of the intracellular pool of amino acids.     

Characteristics of alpha-aminoisobutyric acid transport in rat skeletal muscles.

alpha-Aminoisobutyric acid (AIB) transport into the intracellular compartment of extensor digitorum longus and soleus muscles was measured (in vitro) after allowance for the equilibration of the amino acid in the extracellular space. The latter was determined with three markers, [14C]inulin, 60Co-EDTA and [3H]mannitol. Net transport of AIB was subsequently divided into its two components, i.e. influx and efflux. Rates of influx were measured as the intracellular accumulation of [14C]AIB after a short incubation (5 min), and efflux was measured as the release of AIB with time (up to maximum of 50 min) from muscles that had previously been preloaded with AIB. This intracellular efflux was resolved into two phases, which probably represent two separate components of exit. The influence of extracellular Na+ on the transport of this neutral amino acid (representing the A system) was investigated. Na+ depletion resulted in lower accumulations of AIB, the effects becoming more pronounced with progressive depletions of external Na+. These changes arose from an inhibition of AIB influx, concomitant with an enhancement of its efflux. In contrast, all components of tyrosine transport (representing the L system) were unaffected by lowering external Na+ concentrations. The net accumulation of AIB was also suppressed by cortisol. This inhibitory effect was, however, Na+-dependent and resulted solely from the steroid's enhancement of AIB efflux, the hormone being without effect on AIB influx.     

Uptake of 14C-α-aminoisobutyric acid by Phaseolus vulgaris

Specific uptake (S.U.) of α-aminoisobutyric acid ([1-¹⁴C]AIB), a non-metabolizable neutral amino acid analog, by dwarf bush bean plants (Phaseolus vulgaris cv Top Crop) demonstrated wide differences in active transport between various plant organs. The kinetic and timed uptake data reported were expressed as S.U. because this corrects for the diffusion of AIB which is part of the total AIB uptake process. Roots accumulated AIB to concentrations up to 18 times and leaf disks to twice those of the incubation medium. Stem tissue showed very little uptake, if any, that could not be accounted for by simple diffusion or water free space. Although initial rate kinetic studies demonstrated the presence of a normal transport system, timed uptake studies revealed greatly decreased transport by etiolated plants, suggesting a relationship between active transport and the lack of photosynthate. The reproducibility of the AIB uptake pattern by mature roots strongly supports the concept that the transport of neutral amino acids is biphasic and suggested one or more carrier systems are inducible by either low intracellular concentrations or repressed by high intracellular concentrations of the amino acid.     

Glucagon regulation of amino acid transport in hepatocytes: Effect of cell enucleation

Glucagon and cAMP analogs stimulate amino acid transport in freshly isolated hepatocytes by inducing the synthesis of new transport proteins. The role of the cell nucleus in the glucagon regulation of amino acid transport has been studied in rat hepatocytes enucleated by centrifugation through a discontinuous Ficoll gradient in the presence of cytochalasin B. Enucleated hepatocytes take up alpha-aminoisobutyric acid (AIB) through a Na⁺-dependent transport component with kinetic properties similar to those found in intact hepatocytes. Cytoplasts prepared from glucagon-stimulated cells retain the increase AIB transport induced by the hormone in the intact cells. The direct addition of glucagon to cytoplasts has no effect on AIB transport, in spite of the fact that the cytoplasts exhibit a higher capacity to bind glucagon than their nucleated counterparts. These data indicate that the nucleus is required for the glucagon stimulation of amino acid transport in isolated hepatocytes.     

Evidence for amino Acid-h co-transport in oat coleoptiles

Microelectrode and tracer techniques were used to test for possible amino acid-H⁺ co-transport in coleoptiles of Avena sativa L. cv. “Garry.” The amino acid analogue α-aminoisobutyric acid (AIB) caused transient depolarization of the membrane potential. The absolute magnitude of the maximum depolarization was affected by the same factors that affected AIB transport. Both increased with higher concentrations of AIB, increased with higher acidities in the medium, and were enhanced by indoleacetic acid (which hyperpolarized the membrane potential). AIB transport was reduced as K⁺ concentrations in the medium were increased and by the metabolic inhibitor NaN₃, both of which reduce membrane potentials. Our data fit an amino acid-H⁺ co-transport model in which transport is controlled by both the membrane potential and proton concentration components of the chemical potential difference of protons across the coleoptile cell membrane.     

Adaptive enhancement of amino acid uptake and exodus by thymic lymphocytes: influence of pH.

Entry of certain free amino acids (alpha aminoisobutyric acid (AIB), alanine and proline), but not of leucine into rat thymic lymphocytes increased progressively when the cells were incubated in amino acid deficient medium. Actinomycin D, cycloheximide, or a high concentration of AIB abolished the time-related increase in AIB accumulation, whereas exposure to a high concentration of leucine had no effect. This phenomenon could not be attributed to a progressive alteration in the nature of the incubation medium nor to reduced transinhibition of AIB uptake. The exodus of AIB also increased with time, but to a smaller degree than AIB entry. Initial rates of AIB entry and exodus increased with increases in the pH of the incubation medium over the range 6.5-8.0. The effects of pH on entry and exodus were time-related, increasing progressively oveb nullified the magnified time related increments in AIB transport caused by prolonged incubation at pH 8.0. The influence of a given pH on transport of AIB decreased rapidly when the cells were transferred to medium of another pH, but this tendency diminished the longer the cells were exposed to the initial pH. pH influenced the entry of alanine and proline in the same fashion as that of AIB, but did not affect leucine entry. These results indicate that thymic lymphocytes exhibit adaptive enhancement in the accumulation of free amino acids that are transported largley by the A or alanine-preferring system, and that the adaptive process involves both entry and exodus. Moreover, alterations in pH modify entry and exodus of these same amino acids, profoundly affect the magnitude of time-released increases, and may induce fundamental changes in the mechanism(s) serving amino acid transport.     

Neutral Amino Acid Transport in Astrocytes: Characterization of Na+-Dependent and Na+-Independent Components of α-Aminoisobutyric Acid Uptake

Neutral amino acid transport is largely unexplored in astrocytes, although a role for these cells in blood-brain barrier function is suggested by their close apposition to cerebrovascular endothelium. This study examined the uptake into mouse astrocyte cultures of alpha-aminoisobutyric acid (AIB), a synthetic model substrate for Na+-dependent system A transport. Na+-dependent uptake of AIB was characteristic of system A in its pH sensitivity, kinetic properties, regulatory control, and pattern of analog inhibition. The rate of system A transport declined markedly with increasing age of the astrocyte cultures. There was an unexpectedly active Na+-independent component of AIB uptake that declined less markedly than system A transport as culture age increased. Although the saturability of the Na+-independent component and its pattern of analog inhibition were consistent with system L transport, the following properties deviated: (1) virtually complete inhibition of Na+-independent AIB uptake by characteristic L system substrates, suggesting unusually high affinity of the transporter; (2) apparent absence of trans-stimulation of AIB influx; (3) unusually concentrative uptake at steady state (the estimated distribution ratio for 0.2 mM AIB was 55); and (4) susceptibility to inhibition by N-ethylmaleimide. Direct study of the uptake of system L substrates in astrocytes is needed to confirm the present indications of high affinity and concentrative Na+-independent transport.     

Hormonal regulation of amino acid transport and gluconeogenesis in primary cultures of adult rat liver parenchymal cells.

Amino acid transport was studied in primary cultures of parenchymal cells isolated from adult rat liver by a collagenase perfusion technique and maintained as a monolayer in a serum-free culture medium. These cells carried out gluconeogenesis from three carbon precursors (alanine, pyruvate, and lactate) in response to glucagon addition. Amino acid transport was assayed by measuring the uptake of the nonmetabolizable amino acid, alpha-aminoisobutyric acid (AIB). Addition of insulin or glucagon to culture rat liver parenchymal cells resulted in an increased influx of AIB transport. The glucocorticoid, dexamethasone, when added alone to cultures did not affect AIB transport. However, prior or simultaneous addition of dexamethasone to glucagon-treated cells caused a strong potentiation of the glucagon induction of AIB transport. Kinetic analysis of the effects of insulin and glucagon demonstrated that insulin increased the Vmax for transport without changing the Km while glucagon primarily decreased the Km for AIB transport. The effect of dexamethasone was to increase the Vmax of the low Km system.     

Insulin and glucagon stimulation of amino acid transport in isolated rat hepatocytes. Synthesis of a high affinity component of transport.

Insulin and glucagon stimulate amino acid transport in freshly prepared suspensions of isolated rat hepatocytes. The kinetic properties of alpha-amino[1-14C]isobutyric acid (AIB) transport were investigated in isolated hepatocytes following stimulation by either hormone in vitro. In nonhormonally treated cells (i.e. basal state), saturable transport occurred mainly through a low affinity (Km approximately equal to 40 mM) component. In insulin or glucagon-treated hepatocytes, saturable transport occurred through both a low affinity component (similar to that observed in the basal state) and a high affinity (Km approximately equal to 1 mM) component. At low AIB concentrations (less than 0.5 mM), insulin and glucagon at maximally stimulating doses increased AIB uptake about 2-fold and 5-fold, respectively. The high affinity component induced by either hormone exhibited the properties of the A (alanine preferring) mediation of amino acid transport. This component required 2 to 3 h for maximal expression, and its emergence was completely prevented by cycloheximide. Half-maximal stimulation was elicited by insulin at about 3 nM and by glucagon at about 1 nM. Dibutyryl cyclic AMP mimicked the glucagon effect and was not additive to it at maximal stimulation. Maximal effects of insulin and glucagon, or insulin and dibutyryl cyclic AMP, were additive. We conclude that insulin and glucagon can modulate amino acid entry in hepatocytes through the synthesis of a high affinity transport component.     

Glucagon resistance of hepatoma cells. Evidence for receptor and post-receptor defects.

Of all available liver cells in culture, only primary cultured hepatocytes are known to respond to glucagon in vitro. In the present study we investigated whether glucagon could stimulate amino acid transport and tyrosine aminotransferase (TAT;EC 2.6.1.5) activity (two well-characterized glucagon effects in the liver) in Fao cells, a highly differentiated rat hepatoma cell line. We found that glucagon had no effect on transport of alpha-aminoisobutyric acid (AIB; a non-metabolizable alanine analogue) nor on TAT activity, even though both activities could be fully induced by insulin [2-fold and 3-fold effects for AIB transport and TAT activity, respectively, after 6h; EC50 (median effective concentration) = 0.3 nM], or by dexamethasone (5-8-fold effects after 20 h; EC50 = 2 nM). Analysis of [125I]iodoglucagon binding revealed that Fao cells bind less than 1% as much glucagon as do hepatocytes, whereas insulin binding in Fao cells was 50% higher than in hepatocytes. The addition of dibutyryl cyclic AMP, which fully mimics the glucagon stimulation of both AIB transport and TAT activity in hepatocytes, induced TAT activity in Fao cells (a 2-fold effect at 0.1 mM-dibutyryl cyclic AMP) but had no effect on AIB transport. Cholera toxin stimulated TAT activity to the same extent as did dibutyryl cyclic AMP. These results indicate that the lack of glucagon responsiveness in cultured hepatoma cells results from both a receptor defect and, for amino acid transport, an additional post-receptor defect. Moreover, the results show that amino acid transport and TAT activity, which appeared to be co-induced by insulin or by dexamethasone in these cells, respond differently to cyclic AMP. This suggests that different mechanisms are involved in the induction of these activities by glucagon in liver.