Regulation of amino acid transport in chick embryo heart cells. 3. Formal identification of the A mediation as an adaptive transport system

Threonine deprivation rapidly activates the system A amino acid transporter in primary cultures of rat neurons from the essential amino acid sensor in the anterior piriform cortex

Omnivores show recognition of essential (indispensable) amino acid deficiency by changing their feeding behavior within 20 min, yet the cellular mechanisms of amino acid sensation in eukaryotes are poorly understood. The anterior piriform cortex (APC) of the brain in rats or its analog in birds likely houses the in vivo amino acid chemosensor. Because amino acid transporters adapt rapidly to essential amino acid deficiency in several cell models, we hypothesized that activation of electrogenic amino acid transport in APC neurons might contribute to the function of the amino acid sensor. We evaluated transport systems in primary cultures of neurons from the APC, hippocampus and cerebellum, or glia, incubated in complete or threonine-devoid (deficient) medium. After 10 min in deficient medium, uptake of threonine or a system A-selective substrate, methyl amino-isobutyric acid, was increased 60% in APC neurons only (P < 0.05). These results demonstrated upregulation of system A, an electrogenic amino acid-sodium symporter. This depletion-induced activation required sodium, intact intracellular trafficking, and phosphorylation of signal transduction-related kinases. Efflux studies showed that other transporter types were functional in the APC; they appeared to be altered dynamically in threonine-deficient cells in response to rapid increases in system A activity. The present data provided support for the chemical sensitivity of the APC and its role as the brain area housing the indispensable amino acid chemosensor. They also showed a region-specific, phosphorylation-dependent activation of the system A transporter in the brain in response to threonine deficiency.

Uptake of alpha-aminoisobutyric acid and cycloleucine on skeletal muscles in burned rats

The uptake of alpha-aminoisobutyric acid (AIB) and aminocyclopentane-carboxylic acid (cycloleucine) was studied in soleus muscles isolated from small rats (body weight 50-60 g) during the first 6 h after a major thermal injury, the so-called 'ebb phase' or 'hypometabolic phase'. Soleus muscles were dissected intact from rats at 0.5, 1, 3 and 6 h after extensive deep burn injury (30 per cent TBSA) and then incubated for 2 h in Krebs-Henseleit bicarbonate buffer (pH 7.4), 5.5 mM glucose, bovine serum albumin and radiolabelled AIB or cycloleucine. The results were expressed as the distribution ratio of AIB or cycloleucine between intracellular and extracellular fluid. The AIB uptake in vitro was found to be significantly increased (30 per cent) in the initial half hour postburn only, and then slowly reduced during the subsequent hours to near the value found in non-burn animals. Muscle cycloleucine uptake in vitro showed no significant change in these studies. In our second study, extensor digitorum longus leg muscle were incubated in Krebs-Henseleit bicarbonate buffer with different pH values (7.2-7.5). No significant difference was found in muscle AIB uptake. In summary, since muscle amino acid uptake remained relatively stable during this period, it is suggested that the alteration of amino acid transport across muscle cells may not be a contributing factor to the alteration of amino acid flux during the early phase of stress.

Prolonged incubation of skeletal muscle increases system A amino acid transport

During the course of experiments involving prolonged incubation of skeletal muscle, we observed large increases in system A amino acid transport activity. System A activity was monitored with the nonmetabolizable amino acid analogue alpha-(methylamino)isobutyrate (MeAIB). When rat epitrochlearis muscles are incubated in Krebs-Henseleit buffer supplemented with 0.1% bovine serum albumin and 8 mM glucose, basal MeAIB transport doubles after 5 h and is elevated approximately sevenfold after 9 h compared with rates measured in muscles incubated for 1 h. Insulin-stimulated transport also doubles after 5 h and increases by fourfold after 9 h. The increases in basal and insulin-stimulated system A transport over time can be prevented by incubating muscles in the presence of cycloheximide. Addition of minimum essential medium essential amino acids (EAA) to the incubation medium blocks the increase in basal and insulin-stimulated MeAIB transport measured after 9 h by 85-90 and 60%, respectively. A single amino acid, glutamine, can account for half of the inhibitory effect of EAA on the time-dependent increase in basal system A transport. Amino acid metabolism is not necessary for inhibition of the rise in basal MeAIB transport. At concentrations normally present in minimum essential medium, nonessential amino acids are less effective (51% inhibition) in preventing the rise in basal transport occurring over 9 h. At three times normal concentrations, however, the ability of nonessential amino acids to prevent the time-dependent increases in basal and insulin-stimulated MeAIB transport is comparable to that of EAA. These changes in MeAIB transport with prolonged incubation are not due to muscle deterioration.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of a polyamine transport system in murine embryonic palate mesenchymal cells

Polyamines (putrescine, spermidine, and spermine) are normal cellular constituents able to modulate cellular proliferation and differentiation in a number of developing systems. Ornithine decarboxylase (ODC), the rate-limiting enzyme in the polyamine biosynthetic pathway, has been shown to be causally related to an increase in glycosaminoglycan synthesis in murine embryonic palatal mesenchyme cells (MEPM). In order to understand other mechanisms that exist to regulate polyamine levels in cells derived from the developing craniofacial area, the present study investigated the capacity of MEPM cells to accumulate exogenous putrescine and tests the hypothesis that polyamine transport can serve as an adaptational response of MEPM cells to a change in their ability to synthesize polyamines. Transport was initiated in confluent cultures of MEPM cells by the addition of 0.1 microCi/ml of 14C-putrescine. The rate of transport, monitored for 20-120 minutes, was found to be a time-dependent saturable process. The rate of initial transport, determined by incubating MEPM cells for 15 minutes in the presence of different concentrations (1.0-20.0 microM) of 14C-putrescine, was also found to be saturable, suggesting a carrier-mediated event. Lineweaver-Burk analysis of these data revealed an apparent Km of 5.78 microM and a Vmax of 2.63 nmol/mg protein/15 minutes. Transport measured either at 4 degrees C or in the presence of 2-4 DNP was dramatically inhibited. Thus, putrescine transport is an active process, dependent upon metabolic energy. Conditions in which 1) NaCl was iso-osmotically replaced with choline chloride or 2) the Na+-electrochemical gradient was dissipated with Na+, K+-specific ionophores resulted in a decreased rate of transport indicating that putrescine transport in these cells is Na+ dependent. Noncompetitive inhibition assays utilizing sulfhydryl reagents that blocked sulfhydryl groups inhibited putrescine transport, suggesting that sulfhydryl groups are important for putrescine uptake. Competitive inhibition assays demonstrated that while spermidine and spermine inhibited putrescine uptake, ornithine did not inhibit transport. Spermidine, spermine, and putrescine thus appear to share a common transport system that is separate from that for ornithine. Putrescine transport is subject to adaptive regulation in both exponentially growing and confluent cultures of MEPM cells.(ABSTRACT TRUNCATED AT 400 WORDS)

Characterization of L-threonine and L-glutamine transport in murine P388 leukemia cells in vitro. Presence of an N-like amino acid transport system

The transport of L-threonine and L-glutamine into murine P388 leukemia cells has been characterized. Threonine appears to be a specific substrate for a Na+-dependent amino acid transport system similar to system ASC of the HTC hepatoma cell. Threonine transport is uninhibited by 2-aminobicyclo[2,2,1]heptane-2-carboxylic acid and alpha-(methylamino)isobutyric acid, shows a pattern of transport similar to that seen in HTC hepatoma cells over the pH range of 5.5-7.5, and is inhibited by L-serine and L-cysteine. Approximately two-thirds of glutamine transport into P388 cells also appears to enter P388 cells via this ASC-analogous system. However, based upon (a) inhibition studies with threonine (where the K1 of threonine inhibition of glutamine transport was 7-fold the Km of threonine transport), (b) inhibition analysis of glutamine transport with various amino acids and amino acid analogues, and (c) different patterns of transport between threonine and glutamine over the pH range of 5.5-7.5, approximately one-third of glutamine transport can be attributed to a second Na+-dependent amino acid transport system. This system appears to be similar to the system N of rat hepatocytes. Glutamine and threonine do not appear to enter P388 cells via systems A or L to any significant degree. P388 cells do not appear to exhibit 'adaptive regulation' of amino acid transport. Differences in 'adaptive regulation' could therefore not be utilized for comparing threonine and glutamine transport.

Comparative aspects of the apparent Michaelis constant for neutral amino acid transport in several animal tissues

The apparent Michaelis constant, Km, for transport of a number of neutral amino acids has been compared between intestine, heart, brain and erythrocytes among a variety of animals using values available in the literature. Neutral amino acids with side chains containing 3, 4, 7 and 9 carbon atoms had approximately equal mean Km values when tested for intestinal transport among a variety of species; alanine appeared to have a mean Km value that was larger than those found for the first group, and glycine had a significantly greater mean Km than all of the other compounds tested. Km values for phenylalanine and tryptophan measured in rat heart were found to be close to the means measured for these substrates in intestine. The mean Km values measured in mammalian brain for each of the neutral amino acid substrates were found not be significantly different from each other. When the means of Km values for the neutral amino acids tested were compared between intestine and brain, only the glycine means were shown to differ significantly between the organs. Based on data for several mammalian species, brain appears to have a greater average apparent affinity for glycine than does intestine. In the human erythrocytes and in a few other mammalian species, Km values for all neutral amino acids tested with exception of glycine were found to be similar in magnitude to each other and to the Km averages of neutral amino acids found in intestine for the series containing 3-9 carbon atoms. The Km value for glycine in the human erythrocyte was noted to be substantially lower in value than the averages for glycine in brain or intestine. Avian red blood cells appear to have high apparent affinity for neutral amino acid transport when compared with red cells of several mammalian species.

Regulation of amino acid transport system L by amino acid availability in CHO-K1 cells. A special role for leucine

Starvation of CHO-K1 cells for leucine leads to a 3-4-fold increase in transport system L activity, without modification of transport through systems A and ASC. The concentration of leucine must be below 10 microM before the enhancement of transport can be clearly seen. To achieve low concentrations of leucine such as 10 microM, extensive dialysis of fetal calf serum was required. The enhancement of transport was completed after 12-24 h of starvation and was fully reversed within 1 h of re-feeding with leucine. Starvation for isoleucine, valine or phenylalanine also produced an increase in system L transport activity, but the effect was only one half of that seen following leucine starvation.

The effect of transport system A and N amino acids and of nerve and epidermal growth factors on the induction of ornithine decarboxylase activity

The induction of ornithine decarboxylase (EC 4.1.1.17) (ODC) by amino acids and by the peptide hormones nerve growth factor (NGF) and epidermal growth factor (EGF) in salts-glucose media has been studied. Only those neutral amino acids taken into the cell via one of the Na+ dependent transport systems stimulate ODC activity. Asparagine and the nonmetabolizable alpha-amino-isobutyric acid (AIB) were used as representatives of this class of inducing amino acids, and their intracellular concentrations were related to the levels of ODC induced. A threshold intracellular concentration of asparagine or AIB has to be attained before ODC can be induced. Further slight increases in intracellular concentrations of asparagine or AIB produce disproportionately large increases of ODC, resulting in a sigmoidal curve of ODC induction. These results, and the fact that the decrease in ODC levels caused by valine is associated with a concurrent decrease in the intracellular level of the inducing amino acid, suggest that the intracellular amino acid level is causally related to the induction of ornithine decarboxylase. Glutamic acid, EGF, and NGF do not induce ODC except in the presence of an inducing amino acid. They act synergistically with the inducing amino acid and produce higher ODC levels at the same intracellular concentration of the inducing amino acid.

Transport of prostaglandins through normal and diabetic rat hepatocytes

Transport of alprostadil (prostaglandin E1) and dinoprost (prostaglandin F2 alpha) was studied in enzymatically dispersed normal and streptozocin-treated rat hepatocytes prepared by collagenase perfusion. Cell suspensions incubated at 37 degrees were sampled at time intervals for a period of 5 min and the supernatant analyzed for prostaglandins after centrifugation. The data analysis employed a theory and a model for solute transfer at the cell membrane-water interphase. Biophysical parameters such as the effective partition and the apparent permeability constants were used to define the transport mechanism. The apparent permeability coefficient of alprostadil and dinoprost transfer through normal hepatocytes was calculated to be 5 X 10(-3) and 3 X 10(-3) cm/sec with a mean partition coefficient of 1345 and 764 for both solutes, respectively. The permeability coefficient of alprostadil and dinoprost transfer through diabetic hepatocytes were 3 X 10(-3) and 2 X 10(-3) cm/sec with partition coefficient of 572 and 206, respectively. The results showed differences in prostaglandin transport between normal and diabetic hepatocytes, resulting from morphological and lipid alteration in the cytoplasmic membrane.

Amino acid transport in human lymphocytes: distinctions in the enhanced uptake with PHA treatment or amino acid deprivation

Human blood lymphocytes increase their concentrative uptake of amino acids when treated with plant lectins such as phytohemagglutinin or when exposed to an amino acid deficient environment (adaptation). Previous studies of the PHA effect have been conducted principally with alpha-aminoisobutyric acid (AIB). We have studied the transport characteristics of naturally occurring amino acids by PHA-treated lymphocytes. These studies have been conducted in the absence and presence of added carrier amino acid to determine whether an increase in transport after PHA treatment is mediated by the same mechanism that occurs during adaptation to a low amino acid environment. PHA stimulated the uptake of AIB, alanine, and proline 1.5- to 2-fold after 4 hours' exposure. AIB and proline, but not alanine transport, also increased when lymphocytes were in an amino acid-deficit medium. When lymphocytes were in an amino acid-deficient medium with PHA, the increase in uptake induced by PHA was superimposed on the increase that occurred in response to an amino acid-deficient medium. Also, PHA stimulated a delayed increase (16--20 hours) in the transport of leucine, whose uptake does not adapt to an amino acid-deficient medium. These data suggest that PHA and amino acid deprivation stimulated rate increases in amino acid transport by separate mechanisms.

Cell density and amino acid transport in 3T3, SV3T3, and SV3T3 revertant cells

The transport of selected neutral and cationic amino acids has been studied in Balb/c 3T3, SV3T3, and SV3T3 revertant cell lines. After properly timed preincubations to control the size of internal amino acid pools, the activity of systems A, ASC, L, and Ly+ has been discriminated by measurements of amino acid uptake (initial entry rate) in the presence and absence of sodium and of transport-specific model substrates. L-Proline, 2-aminoisobutyric acid, and glycine were primarily taken up by system A; L-alanine and L-serine by system ASC; L-phenylalanine by system L; and L-lysine by system Ly+ in SV3T3 cells. L-Proline and L-serine were also preferential substrates of systems A and ASC, respectively, in 3T3 and SV3T3 revertant cells. Transport activity of the Na+-dependent systems A and ASC decreased markedly with the increase of cell density, whereas the activity of the Na+-independent systems L and Ly+ remained substantially unchanged. The density-dependent change in activity of system A occurred through a mechanism affecting transport maximum (Vmax) rather than substrate concentration for half-maximal velocity (Km). Transport activity of systems A and ASC was several-fold higher in transformed SV3T3 cells than in 3T3 parental cells at all the culture densities that could be compared. In SV3T3 revertant cells, transport activity by these systems remained substantially similar to that observed in transformed SV3T3 cells. The results presented here add cell density as a regulatory factor of the activity of systems A and ASC, and show that this control mechanism of amino acid transport is maintained in SV40 virus-transformed 3T3 cells that have lost density-dependent inhibition of growth, as well as in SV3T3 revertant cells that have resumed it.

Regulation of amino acid transport in chicken embryo fibroblasts by purified multiplication-stimulating activity (MSA)

Enhanced amino acid transport is observed when quiescent cultures of chicken embryo fibroblasts are stimulated to proliferate by the addition of purified multiplication-stimulating activity (MSA). This increase in amino acid transport is an early event occurring prior to the onset of DNA synthesis in stimulated cells. Results indicate that the changes in transport activity, as measured by alpha-aminoisobutyric acid (AIB) uptake, are due to stimulation of only the Na+-dependent A transport system. There is little or no change in the activities of transport systems ASC, L, or Ly+ upon exposure to MSA. A kinetic analysis shows this increased activity is due to a change in Vmax while Km remains unaltered. Continuous exposure to the stimulus is required to maintain the increased level of transport activity and the presence of inhibitors of RNA and protein synthesis significantly inhibits the response. Results also indicate that a similar specific increase in the A transport system is initiated when RSV tsNY68 infected cells are shifted to the permissive temperature. It appears that the A system of mediation is emerging as a strategic regulatory site for cell function.

Amino acid transport in normal and Rous sarcoma virus-transformed chicken embryo fibroblasts

A study was made of the transport of a variety of amino acids by uninfected and Rous sarcoma virus-infected chicken embryo fibroblasts. Following a period of amino acid starvation, transformed, but not normal cells, showed increased levels of transport for alpha-aminoisobutyric acid, proline and alanine, three amino acids which are transported primarily by the A transport system. There was no starvation-induced increase in the transport of leucine, phenylalanine, lysine, or cycloleucine. In the absence of starvation, normal and transformed cells exhibited comparable rates of amino acid transport. Cycloheximide was able to block the increase in uptake. The enhanced uptake was characterized by an increase in Vmax for transport and little change in Km. The data demonstrate that an alteration in the regulation of the A amino acid transport system is an early event in malignant transformation by Rous sarcoma virus. However, since this alteration in made manifest only following a period of starvation, our findings suggest that increased amino acid uptake does not play a role in generating the other manifestations of the transformed state seen in cell culture.

Serum-dependent regulation of alpha-aminoisobutyric acid uptake in bovine granulosa cells

The removal of serum from the medium of ovarian granulosa cells in exponential or confluent stages of growth results in a rapid and pronounced decrease in the rate of transport of the non-metabolizable amino acid, alpha-aminoisobutyric acid. This decrease is rapidly and completely reversed by the addition of serum. The decrease and its reversal are insensitive to inhibitors of RNA and protein syntheisis and are unaffected by a number of other metabolic inhibitors. The serum requirement cannot be replaced by peptide hormones known to stimulate cell division and secretion by these cells. These data are consistent with a model of post-translational control of AIB transport by a high-molecular-weight component of serum.

Amino acid transport in diaphragms from newborn rats: evidence for insulin resistance

Diaphragms from rats under 24-h-old did not show the well-known increased transport of alpha-aminoisobutyrate found in older tissues in respone to insulin in vitro. A small effect was apparent by 3 days, and stimulation increased as donor rats aged (up to 4--5 wk). One-day diaphragms also had greater uptake than older tissues, due to both decreased Km and elevated Vmax. The change in insulin sensitivity did not result from alteration in the transport system used by alpha-aminoisobutyrate because uptake showed characteristics of the A system at both 1 day and older. Results suggest instead that the 1-day tissues had been made insulin-resistant by high insulin levels in donor animals. Plasma insulin levels of 1-day-old rats were 5 times those of 5-day animals. Elevating the plasma insulin levels of 5-day or 25- to 35-day rats led to a decreased effectiveness of insulin in vitro in stimulating alpha-aminoisobutyrate transport into their diaphragms. In the older animals, the stimulation was inversely proportional to the plasma insulin level 2 h after insulin injection.

Amino acid transport by a muscle cell line

An established rat muscle cell culture, L-6, was employed for the evaluation of muscle amino acid transport. The initial influx of 16 radiolabeled amino acids into these cells was determined, and an overall uptake profile was constructed. L-6 cells accumulate amino acids progressively with time by saturable, temperature-dependent processes. As found in other preparations, several amino acids have sodium-dependent uptake systems. There is a wide range in the rate of transport of the different amino acids. The overall profile of uptake is fairly reproducible and may be characteristic of muscle tissue; it does not resemble that previously found in other cell types. The profile of amino acid uptake into these cells compares favorably with the pattern of amino acid transfer from the bloodstream to muscle found in intact rats. It is concluded that muscle cell transport is basically similar to that of other cell types. L-6 muscle cells have an amino acid uptake profile which resembles that of intact muscle; they should thus prove useful in the further delineation of muscle amino acid transport mechanisms.

Characteristics of proline transport into R3230AC mammary tumor cells

Cells separated by enzyme treatment of the R3230AC mammary carcinoma were used to characterize the entry of proline. These cells showed minimal changes in cell viability and intracellular volume and were found to be suitable for transport studies, since the vi of proline was maintained for at least 4 h when cells were stored at 37 or 4 degrees C, or when transport was measured in the presence or absence of Na+. Proline was acitvely transported by these tumor cells, reaching a distribution ratio ([proline] intracellular/[proline] extracellular) of 20 after 2 h. Proline entry consisted of two processes, one saturable (carrier mediated) and the other, non-saturable. The carrier-mediated entry, Km - 0.83 mM and V = 151.10(-5) mumol/min per 5.10(6) cells, was Na+-dependent, sensitive to pH and metabolic inhibitors, and completely inhibited by alpha-(methylamino)-isobutyric acid (Ki = 0.34 mM). Proline entry in the absence of Na+ was 20% that in the presence of Na+ and was found to be due to a non-saturable process, since (a) vi of proline uptake in the absence of Na+ increases linearly with increasing proline concentration and (b) was not suppressed by either 20 mM alpha-(methyl-amino)-isobutyric acid, 50 mM glycine +20 mM phenylalanine, or 50 mM serine +20 mM phenylalanine when proline uptake was measured in the presence or absence of Na+. Therefore, under the conditions studied, we conclude that proline transport appears to be restricted to the A (alanine-preferring) system. Furthermore, these cells should provide a suitable model to study the effect of hormonal manipulations on the amino acid transport process.

Characterization of a carrier-mediated transport system for taurine in the fetal mouse heart in vitro

Cardiac taurine levels are elevated in hypertension and congestive heart failure. A possible mechanism for this increase in taurine is an alteration of its uptake. We sought to identify and characterize a carrier-mediated transport system for taurine in the mammalian myocardium utilizing the fetal mouse heart in organ culture. Hearts from fetuses of 16-19 days gestational age used in these studies had an endogenous taurine content of 14.1+/-0.5 nmol/mg tissue. The uptake of [(3)H]taurine was linear for up to 8 h. Taurine was accumulated against a concentration gradient as demonstrated by a net increase in taurine concentration when hearts were incubated in 0.5 mM taurine. [(3)H]Taurine uptake was saturable, K(m) = 0.44 mM, temperature dependent, and required sodium. The close structural analogues, hypotaurine and beta-alanine, reduced [(3)H]taurine uptake by 87% when present in 100-fold excess. The alpha-amino acids alanine, alpha-aminoisobutyric acid, glycine, leucine, and threonine did not inhibit uptake. Other taurine analogues tested were guanidinotaurine, guanidinopropionic acid, gamma-aminobutyric acid, 2-aminoethane phosphonic acid, aminomethane sulfonic acid, 3-aminopropane sulfonic acid, N-acetyltaurine, and isethionic acid. We conclude that a carrier-mediated transport system for taurine exists in the fetal mouse heart based on the demonstration of (a) temperature dependence, (b) saturability, and (c) structural selectivity of the uptake process. Transport was demonstrated to be mediated by a beta-amino acid uptake system. In addition, taurine uptake was observed to be sodium dependent, energy dependent, and capable of accumulating taurine against a concentration gradient.

Insulin regulation of amino acid transport in mesenchymal cells from avian and mammalian tissues

Insulin regulation of amino acid transport across the cell membrane was studied in a variety of mesenchymal cell directly isolated from avian and mammalian tissues or collected from confluent cultures. Transport activity of the principal systems of mediation in the presence and absence of insulin was evaluated by measuring the uptake of representative amino acids under conditions approaching initial entry rates. Insulin enhanced the transport rate of substrate amino acids from the A system(alpha-aminoisobutyric acid, L-proline, glycine, L-alanine and L-serine) in fibroblasts and osteoblasts from chick-embryo tissues, in mesenchymal cells (fibroblasts and smooth muscle cells) from immature rat uterus, in thymic lymphocytes from young rats and in chick-embryo fibroblasts from confluent secondary cultures. In these tissues, the uptake of amino acid substrates of transport systems L and Ly+ (L-leucine, L-phenylalanine, L-lysine) was not affected by the presence of the hormone. No insulin control of amino acid transport was detected in chick-embryo chondroblasts and rat peritoneal macrophages. These observations identify the occurrence of hormonal regulatory patterns of amino acid transport for different mesenchymal cells types and indicate that these properties emerge early during cell differentiation.

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.

Density regulation of amino acid transport in cultured, androgen-responsive tumour cells

In androgen-responsive cells, activity of a sodium-dependent transport system for neutral amino acids is shown to be density-dependent, whereas activity of a sodium-independent system is not. Transport of the non-metabolizable amino acid, alpha-aminoisobutyric acid (alpha-aib) was largely sodium-dependent, whereas transport of cycloleucine (cyleu) was by both sodium-dependent and sodium-independent systems. The Km for cyleu transport changed with density because only the sodium-dependent portion of this transport was density-dependent. By contrast, the Vmax for alpha-aib transport changed with density, indicating that either the amount of functional membrane carrier or the activity of the sodium pump was affected.

Influence of serum and insulin on the accumulation of aminoisobutyrate by rat hepatoma cells

1. Cultured rat hepatoma cells accumulate 2-aminoisobutyrate to high concentrations by a transport mechanism probably of the A type mediation. 2. Transport is enhanced by the presence of serum. When cells are deprived of serum the rate of transport declines over a period of hours; conversely addition of serum leads over a period of hours to increase in transport activity. In the presence of serum the apparent Km for aminoisobutyrate uptake is about 8 mM. In cells deprived of serum the Km is much higher. 3. Addition of insulin produces both an immediate increase in the rate of aminoisobutyrate uptake and a time-dependent rise. 4. The presence of alanine diminished aminoisobutyrate uptake in a concentration-dependent fashion. Competition is seen both in the presence and absence of serum but not when cells are incubated at 4 degrees C. 5. Preincubation with alanine for 1 h also diminishes aminoisobutyrate uptake when the alanine is removed. Cells take a period of several hours to recover from the depression of transport induced by alanine. 6. Transport of aminoisobutyrate rapidly declines in the presence of cycloheximide. Actinomycin had no effect for at least 8 h.

Evidence for genetic control of glycine uptake in cultured cells, regulated by the amino acid concentration of the growth medium

1. Cultured cells were grown in various concentrations of amino acids for periods up to 3 days and the characteristics of the glycine transport system measured under fixed experimental conditions. During this time, the effect of enucleation, using cytochalasin B, and the effects of protein synthesis inhibitors (cycloheximide and actinomycin D) were investigated. 2. Glycine influx is regulated by the prior growth concentration of similarly transported amino acids. 3. The modification in transport involves primarily a change in Vmax (but also a change in Km in HeLa cells) and is effected within 2-10 hr after media change. Increased transport activity is calculated to be sufficient to compensate for the reduction in extracellular amino acid concentration, so that nearly normal influx values from media are maintained. Regulation over the range of concentrations studied is shown to be very accurate. 4. The nucleus is essential for the regulatory mechanism to function. It seems probable that mRNA synthesis is required for acquisition of increased transport activity and mRNA translation required for maintenance of normal activity. 5. The controlling factor in the regulatory mechanism appears unlikely to be intracellular pool size. Other possible signals are discussed.