Compartmental analysis of sulphate transport in Lemna minor L., taking plant growth and sulphate metabolization into consideration

Rat hepatoma cells accumulate considerably less 2-aminoisobutyrate after cultivating in the absence of serum the change in rate of aminoisobutyrate uptake takes place within 1 h of serum starvation. Starvation of amino acids by contrast raises aminoisobutyrate uptake in the presence or absence of serum, but the cells are much less responsive to amino acid supply than to availability of serum. Phosphate (10 mM) reduced aminoisobutyrate uptake by cells grown in serum to that exhibited by serum-starved cells. Aminoisobutyrate uptake by cells grown in serum was reduced by glycine, proline, alanine, serine, glutamine, methylaminoisobutyrate and 2-aminonorbornane-2-carboxylate, the effects of methylaminoisobutyrate and 2-aminonorbornane-2-carboxylate being additive. However, similar inhibition phenomena were not seen for cells deprived of serum where aminoisobutyrate uptake tended to a relatively constant level insensitive to inhibitory influences, yet substantially greater than that arising by simple diffusion. The comparative insensitivity of our hepatoma line when starved of serum to competition and repression phenomena is in contrast to findings of others. Our results also suggest a lack of clear delineation of specificities for the A and L transport systems as usually defined.     

Regulation of amino acid transport in L6 muscle cells: I. Stimulation of transport system a by amino acid deprivation

The regulation of amino acid transport in L6 muscle cells by amino acid deprivation was investigated. Proline uptake was Na⁺-dependent, saturable and concentrative, and was predominantly through system A. Proline uptake was inhibited by alanine, α-amino isobutyric acid (AIB), and by α-methylamino isobutyric acid, but not by lysine or valine. At 25°C, Km of proline uptake was 0.5 mM. Amino acid-deprivation resulted in a progressive increase in the rate of proline uptake, reaching up to 6-fold stimulation after 6 hours. The basal and stimulated transport were equally Na⁺-dependent, and both were inhibited by competition with the same amino acids. Kinetic analysis showed that Km decreased by a factor of 2.4 and Vmax increased 1.9-fold in deprived cells. Amino acid-deprivation did not stimulate amino acid uptake through systems other than system A. This suggests that the higher Km in proline-supplemented cells is not due to release of intracellular amino acids into unstirred layers surrounding the cells. The presence of amino acids which are substrates of system A (including AIB) during proline-deprivation, prevented stimulation of proline uptake, whereas those transported by systems Ly⁺ or L exclusively were ineffective. The stimulation of the transport-rate in deprived cells could be reversed by subsequent exposure to proline or other substrates of system A. L6 cells, deprived of proline for 6 hours, retained the stimulation of transport after detachment from the monolayers with trypsin. Uptake rates were comparable in suspended and attached cells in monolayer culture. Thus, amino acid-depreivation of L6 cells results in an adaptive increase in proline uptake, which is not due to unstirred layers but appears to be mediated by other mechanisms of selective transport regulation.     

The kinetic dissection of transport from metabolic trapping during substrate uptake by intact cells. Uridine uptake by quiescent and serum-activated Nil 8 hamster cells and their murine sarcoma virus-transformed counterparts.

1. We present a theoretical analysis of the tandem processes of transport and metabolic trapping which together constitute uptake of a substrate by intact cells. 2. Transport is assumed to occur by means of a simple carrier here analysed in its general form. Trapping is assumed to occur by a simple enzymic reaction. 3. We show how to obtain the separate parameters of the steps by analysing uptake data over a range of uptake times and substrate concentrations. 4. We present uptake data for uridine and cytosine-beta-D-arabinoside entering Nil 8 hamster fibroblasts, normal and murine sarcoma virus transformed, in the quiescent condition and after stimulation by added serum. We analyse the data in terms of the theory for tandem processes. 5. Transport is characterised by a system having a high Km and a high V for entry. The data for cytosine-beta-D-arabinoside suggest that the cytosine-beta-D-arabinoside system is not far from a symmetric one. The data for uridine transport do not differ when quiescent and serum-activated cells are compared. Transformed cells transport uridine at half the maximum velocity of normal cells, with or without added serum. 6. Trapping of cytosine-beta-D-arabinoside is insignificant. Trapping of uridine occurs by a system with both V and Km at least an order of magnitude smaller than are these parameters for transport. Trapping of uridine by non-transformed cells activated by serum, has twice the V of such cells in the quiescent state. 7. In the virus-transformed cells, the control of uridine trapping by added serum is lost, along with control of growth by this stimulant.     

Transport of sugars in chick-embryo fibroblasts. Evidence for a low-affinity system and a high-affinity system for glucose transport.

The rate of D-glucose uptake by cells that had been deprived of sugar for 18-24h was consistently observed to be 15-20 times higher than that in control cells maintained for the same length of time in medium containing glucose. This increased rate of glucose transport by sugar-starved cells was due to a 3-5-fold increase in the Vmax. value of a low-affinity system (Km 1 mM) combined with an increase in the Vmax of a separate high-affinity system (Km 0.05-0.2 mM). The high-affinity system, which was most characteristic of starved cells, was particularly sensitive to low concentrations of the thiol reagent N-ethylmaleimide; 50% inhibition of uptake occurred at approx. 0.01 mM-N-ethylmaleimide. In contrast with the high-affinity system, the low-affinity system of either the fed cells or the starved cells was unaffected by N-ethylmaleimide. In addition to the increases in the rate of D-glucose transport, cells deprived of sugar had increased rates of transport of 3-O-methyl-D-glucose and 2-deoxy-D-glucose. No measurable high-affinity transport system could be demonstrated for the transport of 3-O-methylgucose, and N-ethylmaleimide did not alter the initial rate. Thus the transport of 3-O-methyglucose by both fed and starved cells was exclusively by the N-ethylmaleimide-insensitive low-affinity system. The low-affinity system also appeared to be the primary means for the transport of 2-deoxyglucose by fed and starved cells. However, some of the transport of 2-deoxyglucose by starved cells was inhibited by N-ethylmaleimide, suggesting that 2-deoxyglucose may also be transported by a high-affinity system. The results of experiments that measured transport kinetics strongly suggest that glucose can be transported by a least two separate systems, and 3-O-methylglucose and 2-deoxyglucose by one. Support for these interpretations comes from the analysis of the effects of N-ethylmaleimide and cycloheximide as well as from the results of competition experiments. The uptake of glucose is quite different from that of 2-deoxyglucose and 3-O-methylglucose. The net result of sugar starvation serves to emphasize these differences. The apparent de-repression of the transport systems studied presents an interesting basis for further studies of the regulation of transport in a variety of cells.     

Serum-stimulated changes in calcium transport and distribution in mouse 3T3 cells and their modification by dibutyryl cyclic AMP.

Serum stimulation of quiescent 3T3 cells returns the cells to a proliferative state. Changes in Ca content, transport and distribution during the transition through G1 and S phase have been investigated following serum stimulation of these cells. 45 Ca exchange data indicate at least two kinetically defined cellular compartments for Ca; a rapidly exchanging component presumably representing surface Ca which is removable by EGTA and a slowly exchanging component presumably representing cytoplasmically located Ca. Previous studies (Tupper and Zorgniotti, '77) indicate that the approach to quiescence in the 3T3 cells is characterized by a large increase in the surface Ca component. The present data demonstrate that this component is rapidly lost following serum stimulation. Furthermore, the serum induces an 8-fold increase in Ca influx into the cytoplasmic compartment and a reduction in the unidirectional efflux rate coefficient for Ca. The increased Ca uptake peaks at approximately six hours (mid G1) and is accompanied by a parallel increase in cellular Ca. Prior to entrance of the cells into S phase (10-12 hours), Ca uptake declines. This is followed by a slower decline in cytoplasmic Ca levels. Simultaneous addition to fresh serum plus 0.5 mM dibutryl cAMP inhibits the entrance of the cells into S phase. Under these conditions the loss of surface Ca is not blocked. However, the presence of 0.5 mM dibutyryl cAMP inhibits the increase in Ca uptake and, in turn, diminishes the increase in cellular Ca following serum stimulation. In contrast, a low level of dibutyryl cAMP (0.1 mM) enhances progression through G1 phase but also reduces both Ca uptake and Ca content of the cells. The data suggest that the serum induced changes in Ca content and transport are linked to intracellular cyclic nucleotide levels and progression through G1 phase and that extracellular cAMP elevating agents may enhance of inhibit these interactions in a concentration dependent manner.     

Derepression and carrier turnover: evidence for two distinct mechanisms of hexose transport regulation in animal cells.

Hexose uptake by hamster cells was increased five to ten fold by either substituting D-fructose for glucose or by completely omitting D-glucose from the culture medium for 24 to 48 hours. Conversely, when cycloheximide was present for 24 hours in media containing glucose, up to 20-fold decreases in hexose uptake were observed. However, these decreases in uptake activity were only observed over a narrow range of cycloheximide concentrations. After extended exposure to low concentrations of cycloheximide (0.05 to 10 mug/ml), the uptake by the fed cells decreased parallel with inhibition of protein synthesis whereas at high concentrations (greater than 50 mug/ml) uptake was increased. Cells deprived of glucose and maintained in the presence of cycloheximide did not show decreases in uptake activity. In separate experiments the high uptake rates of glucose-starved cells could be decreased by addition of glucose-free medium. The reversal was complete in 6 to 8 hours. The analog of glucose, 2-deoxy-D-glucose, did not promote the time-dependent decrease suggesting that the 6-phosphoester of glucose is not an inhibitor of transport. In addition, when cycloheximide is added at the same time as glucose, there is no decrease in uptake for at least 12 hours. We propose that turnover of components of hexose uptake systems could account for part of the control of hexose transport. Moreover, the results indicate that the turnover mechanism becomes inactive during glucose starvation and must be resynthetized following refeeding of the starved cells with glucose.     

Induction of sugar transport in chick embryo fibroblasts by hexose starvation. Evidence for transcriptional regulation of transport.

Incubation of chick embryo fibroblasts in glucose-free medium resulted in a dramatic increase in the rate of 2-deoxy-D-glucose transport. The greatest increase in rate occurred during the first 20 hours of incubation in glucose-free medium and was blocked by actinomycin D, dordycepin, or cycloheximide. The conditions of 2-deoxy-D-glucose concentration and time of incubation with the sugar were determined where transport rather than phosphorylation was rate-limiting in sugar uptake. These studies demonstrated that the transport of 2-deoxy-D-glucose was rate-limiting for only 1 or 2 min when the concentration of sugar in the medium was near the Km for transport, i.e. 2mM. No difference was found in the level of hexokinase activity in homogenates prepared from cells incubated glucose-free medium or standard medium when either 2-deoxy-D-[14C]glucose or D-glucose was used as substrate. A kinetic analysis of the initial rates of 2-deoxy-D-glucose transport by Lineweaver-Burk plots showed that the Vmax for sugar transport increased from 18 to 95 nmol per mg of protein per min when fibroblasts were incubated in glucose-free medium for 40 hours. The Km remained constant at 2 mM. Analysis of the initial rates of 3-omicron-methyl-D-glucose transport by Lineweaver-Burk plots further substantiated that the increase in sugar transport was due to an increase in the Vmax for transport with the Km remaining constant. The activation energy for the transport reaction calculated from an Arrhenius plot was 17.4 Cal per mol for cells cultured in the standard medium and 17.2 Cal per mol for cells cultured in the glucose-free medium. These results are consistent with the interpretation that the Vmax increase observed in hexose-starved cells is due to an increase in the number of transport sites.     

Effects of confluence on phosphate transport capacity in cultured renal cell lines

The LLC-PK1 cell line transports phosphate (Pi), glucose, and amino acids using carriers similar to those in proximal tubular cells. Others have reported that when monolayers reach confluence, hexose transport increases and activity of the A-amino acid transporter falls. The present study evaluates Pi uptake by two continuous cell lines derived from renal proximal tubule, and demonstrates that phosphate uptake falls sharply upon reaching confluence in LLC-PK1 cells but not in cultured opossum kidney (OK) cells. The fall in Pi uptake in LLC-PK1 cells at confluence represents a halving in Vmax for Na-dependent phosphate uptake (2.33 vs. 5.00 nmol/mg protein/5 min) without a change in Km (82 vs. 94 microM). Suppression of phosphate transport in confluent monolayers of LLC-PK1 cells is completely reversed by bringing the cells into suspension. As has been shown for the phorbol ester 12-O-tetradecanoyl-phorbol-13-acetate (TPA), exposure of monolayers to serum stimulates phosphate uptake, but unlike phorbol ester, serum does so without stimulating alanine uptake. OK cells differ from LLC-PK1 in that no change occurs in Pi uptake at confluence, although they resemble LLC-PK1 cells in that sugar uptake rises and alanine uptake falls at confluence. The different temporal patterns for Pi uptake in the two cell lines indicates that developmental change in the uptake of Pi is not linked to that of glucose or alanine.     

Energetic mechanism of system A amino acid transport in normal and transformed mouse fibroblasts

Ouabain treatment (0.4 mM) of normal and transformed C3H-10T1/2 cells caused a progressive increase in 2-aminoisobutyrate (AIB) transport reaching a maximum after 16 to 18 h exposure. There was a virtually complete blockage of this stimulated rate when 3 microM cycloheximide (CHX) was added together with ouabain at T = 0. In the transformed cell, addition of CHX after 14 h had no effect; in the normal cell, it inhibited (ca. 50%) the final AIB transport rate achieved after 24 h. The t1/2 for reaching maximal activity (insensitive to CHX exposure) was thus shifted from 8 h in the transformed cell to 15 h in the normal cell. Since the rate of achieving maximal activity in the absence of CHX was about the same in the two cells, the shift in t1/2 in the presence of CHX suggests that the rate of degradation is more rapid in the normal cell. Following ouabain treatment, the apparent Km for Na+ was decreased in both cells. The Km returned to the basal level 1 h after ouabain removal in the normal cell, but remained low in the transformed cell during this time period. The stimulation of AIB transport following ouabain removal was largely abolished by a proton ionophore (1799), a lipophilic cation (tetraphenyl-phosphonium), or ouabain. These results suggest that, under the conditions of ouabain stress, there is a switch in the bioenergetic mechanism. The Na+/K+ pump and System A transporter appear to be linked and the membrane potential generated by the Na+/K+ pump activity becomes a major driving force for AIB uptake.     

Metabolism of Round Spermatids: A Possible Regulation of Hexose Transport

Round spermatids (steps 1–8) were isolated from rat testes and glucose transport into the cells was examined. The exposure of spermatids to glucose resulted in an extremely low level of ATP. In contrast, the level of ATP remained constant in the presence of pyruvate. Transport of a glucose analogue, 2-deoxy-D-[³H]glucose ([³H]dGlc) into spermatids was correlated with intracellular levels of ATP and was much greater in cells with higher rather than lower levels of ATP. [³H]dGlc transport into spermatids with low levels of ATP was partially reversed when the cells were incubated with pyruvate. Inhibition of [³H]dGlc transport was exerted on Vmax and not on Km. Moreover, glucose acted as a competitive inhibitor of [³H]dGlc uptake (Km increased; Vmax unaltered). These results suggest that glucose transport into spermatids is active in vitro and probably regulated by the intracellular level of ATP.     

Transport of urea at low concentrations in Chlamydomonas reinhardi.

Urea transport into the unicellular green alga Chlamydomonas reinhardi was investigated to further our understanding of controls operating on urea catabolism in this organism. Transport into cells grown with acetate and deprived of ammonia is a saturable process, mediated by at least two systems operating maximally at different external urea concentrations. The lower concentration system, with an apparent Km for urea of 5.1 micron, was the object of detailed study. Transport of urea from a saturating concentration (57 micron) into ammonia- and acetate-grown cells freshly suspended in ammonia-limited medium was not detected. Upon further culturing in the absence of ammonia, derepression occurred with transport ability, first appearing at about 1 h , reaching a maximum at about 2 h, and maintaining this maximum at least 5 h. In contrast to this, CO2-grown cells became derepressed more slowly, and maximum transport ability was not maintained. Addition of ammonia or methylamine (5 mM) during nitrogen deprivation prevented further increases in transport ability and caused loss of previously acquired transport ability. Cycloheximide (10 microng/ml) had a similar effect. Energy uncouplers or dark, anaerobic conditions depressed transport. By these criteria, transport from low urea concentrations is mediated by a process that requires protein synthesis and activation by cellular energy, and the process has a rapid rate of turnover and of deactivation by ammonia.     

Induced alteration in uptake properties of Tetrahymena and its association with the development of mating competency.

The rate of uridine uptake in Tetrahymena declines by an order of magnitude by two hours after shiftdown to a non-nutrient buffer. This alteration in uptake properties cannot be accounted for by an increase in the intracellular pool of uridine, an increase in apparent Km for uptake or a decline in the rate in which uridine is processed intracellularly. It is argued that the decrease in uridine uptake is due to a reduction in numbers of functional transport molecules exposed at the cell surface and is a reflection of a developmentally related cell surface transformation. In addition, the putative decline in functional transport molecules cannot be entirely explained by metabolic turnover of these molecules in the absence of replacement, nor does it require the synthesis of new protein. We discuss the possibility that a shift in equilibrium between accessible and inaccessible transporters is operating. Finally, a close correlation between conditions which elicit the transport alteration and those which allow the development of mating competency suggests that the two phenomena may be coordinately regulated.     

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.     

Insulin action and binding in isolated hepatocytes from fasted, streptozotocin-diabetic, and older, spontaneously obese rats

Insulin binding and basal and insulin-stimulated uptake of α-aminoisobutyric acid were measured in isolated hepatocytes from young control rats as well as from older spontaneously obese, 72h-starved, and nonketotic streptozotocin-diabetic rats. Isolated hepatocytes from older spontaneously obese rats are similar to those from younger smaller rats in size, maximal insulin responsiveness, the dose–response relationship for insulin-stimulated aminoisobutyrate uptake, and the number and affinity of insulin receptors. Hepatocytes from 72h-fasted rats have similar numbers of insulin receptors per cell as cells from young control animals, but are significantly smaller, have an enhanced basal rate of aminoisobutyrate uptake, and are insulin resistant with regard to maximal insulin-stimulated uptake of aminoisobutyrate at 0.1mm-aminoisobutyrate. Because of the decreased maximal response to insulin, the concentration of insulin that elicits a half-maximal response of aminoisobutyrate uptake is decreased. Hepatocytes from diabetic animals, like those from starved rats, have significantly greater basal rates of aminoisobutyrate uptake; whereas the maximal absolute insulin response is the same as control cells, the percentage response is smaller. These cells bind significantly more insulin than do control cells. The increase in insulin binding is reflected in a shift to the left of the dose–response curve for insulin-stimulated uptake of aminoisobutyrate. These studies indicate that there is no insulin resistance with regard to uptake of aminoisobutyrate in hepatocytes from older obese rats. Furthermore, the insulin resistance observed in hepatocytes from starved rats occurs despite an increase in the number of receptors per unit surface area and cannot be explained by alterations in the interaction between insulin and its receptor. The enhanced insulin binding per unit surface area, however, is reflected in the shift to the left of the dose–response curve for insulin. This is also true for hepatocytes from diabetic animals, in which insulin binding per cell is increased.     

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.     

Effects of multiplication stimulating activity (MSA) on AIB transport into myoblast and myotube cultures

The effects of a somatomedian analog, Temin's multiplication stimulating activity (MSA), on amino acid transport into muscle cells have been characterized in a series of experiments on myoblasts and myotubes in culture. Addition of MSA to serum-starved L6 myoblasts increased the rate of aminoisobutyrate (AIB) uptake 50-150% within five hours. This early effect on transport was followed by increases in cell number, protein content and 3H-thymidine incorporation. Kinetic analyses indicated that MSA increased the maximal velocity of AIB uptake but had no effect on the KM for AIB. When myoblasts were allowed to fuse (and dividing cells eliminated by addition of 10(-4) M cytosine arabinoside) the AIB transport system(s) remained similarly responsive to MSA. In myoblasts and in myotubes, both the basal and MSA-stimulated rate of AIB uptake were sodium-dependent processes; little stimrulation occurred if sodium was absent from the labeling medium. Further suggesting the involvement of cations in response to hormone, MSA stimulated uptake of the potassium analog, 86Rb+, and increase net intracellular potassium in both myoblasts and myotubes. MSA was active at concentrations equivalent to in vivo levels of somatomedins; neither insulin nor growth hormone had any effect at or near physiological concentrations.     

Active amino acid transport in plasma membrane vesicles from Simian virus 40-transformed mouse fibroblasts. Characteristics of electrochemical Na+ gradient-stimulated uptake.

Selectively permeable membrane vesicles isolated from Simian virus 40-transformed mouse fibroblasts catalyzed Na+ gradient-coupled active transport of several neutral amino acids dissociated from intracellular metabolism. Na+-stimulated alanine transport activity accompanied plasma membrane material during centrifugation in discontinuous dextran 110 gradients. Carrier-mediated transport into the vesicle was demonstrated. When Na+ was equilibrated across the membrane, countertransport stimulation of L-[3H]alanine uptake occurred in the presence of accumulated unlabeled L-alanine, 2-aminoisobutyric acid, or L-methionine. Competitive interactions among neutral amino acids, pH profiles, and apparent Km values for Na+ gradient-stimulated transport into vesicles were similar to those previously described for amino acid uptake in Ehrlich ascites cells, which suggests that the transport activity assayed in vesicles is a component of the corresponding cellular uptake process. Both the initial rate and quasi-steady state of uptake were stimulated as a function of a Na+ gradient (external Na+ greater than internal Na+) applied artificially across the membrane and were independent of endogenous (Na+ + K+)-ATPase activity. Stimulation by Na+ was decreased when the Na+ gradient was dissipated by monensin, gramicidin D or Na+ preincubation. Na+ decreased the apparent Km for alanine, 2-aminoisobutyric acid, and glutamine transport. Na+ gradient-stimulated amino acid transport was electrogenic, stimulated by conditions expected to generate an interior-negative membrane potential, such as the presence of the permeant anions NO3- and SCN-. Na+-stimulated L-alanine transport was also stimulated by an electrogenic potassium diffusion potential (K+ internal greater than K+ external) catalyzed by valinomycin; this stimulation was blocked by nigericin. These observations provide support for a mechanism of active neutral amino acid transport via the "A system" of the plasma membrane in which both a Na+ gradient and membrane potential contribute to the total driving force.     

Epidermal growth factor: modulator of murine embryonic palate mesenchymal cell proliferation, polyamine biosynthesis, and polyamine transport

Polyamines (putrescine, spermidine, and spermine) are normal cellular constituents able to modulate cellular proliferation and differentiation in a number of tissues and cell types. This investigation explores the response of murine embryonic palate mesenchymal (MEPM) cells to epidermal growth factor (EGF) in terms of biosynthesis of putrescine and its transport across the plasma membrane and tests the hypothesis that polyamine transport can serve as an alternative mechanism (other than biosynthesis) for elevating intracellular polyamines during stimulation of MEPM cellular proliferation. MEPM cells treated with EGF were stimulated to proliferate and showed a dose- and time-dependent stimulation of ornithine decarboxylase (ODC) which was maximal at 4-6 hours. EGF also stimulated the initial rate of putrescine transport in a dose- and time-dependent manner. This stimulation was found to be maximal 3 hours after treatment and specific for the putrescine transport system. The kinetic parameters of putrescine transport shifted from 2.52 microM (Km) and 23.6 nmol/mg protein/15 minutes (Vmax) in nonstimulated cells to 4.48 microM (Km) and 39.8 nmol/mg protein/15 minutes (Vmax) in EGF-treated cells. This kinetic shift did not require de novo protein or RNA synthesis, as cycloheximide (10 micrograms/ml) and actinomycin D (50 micrograms/ml) had little effect on the ability of EGF to stimulate the initial rate of putrescine uptake. The rate of transport, however, was found to be inversely related to cell density. The addition of exogenous putrescine concomitantly with EGF blocked the induction of ODC, while in the presence of difluoromethylornithine (DFMO) (irreversible inhibitor of ODC) the initial rate of putrescine transport remained elevated throughout the time course studied. This stimulation of putrescine uptake caused by polyamine deprivation was reversed by exogenous putrescine and Ca++ while alpha-aminoisobutyric acid (AIB) further stimulated the rate of uptake. EGF's ability to stimulate cellular DNA synthesis was inhibited by DFMO. If DFMO-treated cells were stimulated with EGF in the presence of exogenous putrescine, this stimulatory effect was preserved. These studies indicate that the rate of polyamine transportation is highly responsive to a signal which initiates biosynthesis of polyamines. Further, this transportation system provides a compensatory mechanism allowing the cell to increase intracellular levels of polyamines when environmental conditions inhibit biosynthesis or when polyamines are abundant.     

Alterations in amino acid transport in Na,K-ATPase amplified HeLa cells

Amino acid transport was studied in C1 cells which contain amplified levels of sodium- and potassium-activated adenosine triphosphatase (Na,K-ATPase), in C4 cells which are ouabain-sensitive revertants, and in parental HeLa S3. Sodium-dependent uptake of aminoisobutyric acid and alanine was increased 2-fold in the amplified C1 cells. After a 6 h amino acid starvation period, the rate of sodium-dependent uptake of methylaminoisobutyric acid was 70-90% greater for C1 than for C4 and HeLa. This uptake was inhibitable by ouabain and the apparent Km values for high affinity uptake were similar in all three lines. Overall, neutral amino acid uptake through Systems A, ASC, and L was 2-fold higher in the Na,K-ATPase amplified C1 cells relative to C4 or HeLa. The induction of System A uptake of methylaminoisobutyric acid after starvation was more rapid in both the amplified C1 cells and the revertant C4 when compared to HeLa, which suggests that the selection for amplification of the Na,K-ATPase produced membrane alterations affecting the adaptive regulation of System A.