A genetic approach to the study of neutral amino acid transport in mammalian cells in culture

Critical transporters of methionine and methionine hydroxyl analogue supplements across the intestine: What we know so far and what can be learned to advance animal nutrition

DL-methionine (DL-Met) and its analogue DL-2-hydroxy-4-(methylthio) butanoic acid (DL-methionine hydroxyl analogue or DL-MHA) have been used as nutritional supplements in the diets of farmed raised animals. Knowledge of the intestinal transport mechanisms involved in these products is important for developing dietary strategies. This review provides updated information of the expression, function, and transport kinetics in the intestine of known Met-linked transporters along with putative MHA-linked transporters. As a neutral amino acid (AA), the transport of DL-Met is facilitated by multiple apical sodium-dependent/-independent high-/low-affinity transporters such as ASCT2, B⁰AT1 and rBAT/b^0,+AT. The basolateral transport largely relies on the rate-limiting uniporter LAT4, while the presence of the basolateral antiporter y⁺LAT1 is probably necessary for exchanging intracellular cationic AAs and Met in the blood. In contrast, the intestinal transport kinetics of DL-MHA have been scarcely studied. DL-MHA transport is generally accepted to be mediated simply by the proton-dependent monocarboxylate transporter MCT1. However, in-depth mechanistic studies have indicated that DL-MHA transport is also achieved through apical sodium monocarboxylate transporters (SMCTs). In any case, reliance on either a proton or sodium gradient would thus require energy input for both Met and MHA transport. This expanding knowledge of the specific transporters involved now allows us to assess the effect of dietary ingredients on the expression and function of these transporters. Potentially, the resulting information could be furthered with selective breeding to reduce overall feed costs.

Amino acid transporters: roles in amino acid sensing and signalling in animal cells

Amino acid availability regulates cellular physiology by modulating gene expression and signal transduction pathways. However, although the signalling intermediates between nutrient availability and altered gene expression have become increasingly well documented, how eukaryotic cells sense the presence of either a nutritionally rich or deprived medium is still uncertain. From recent studies it appears that the intracellular amino acid pool size is particularly important in regulating translational effectors, thus, regulated transport of amino acids across the plasma membrane represents a means by which the cellular response to amino acids could be controlled. Furthermore, evidence from studies with transportable amino acid analogues has demonstrated that flux through amino acid transporters may act as an initiator of nutritional signalling. This evidence, coupled with the substrate selectivity and sensitivity to nutrient availability classically associated with amino acid transporters, plus the recent discovery of transporter-associated signalling proteins, demonstrates a potential role for nutrient transporters as initiators of cellular nutrient signalling. Here, we review the evidence supporting the idea that distinct amino acid "receptors" function to detect and transmit certain nutrient stimuli in higher eukaryotes. In particular, we focus on the role that amino acid transporters may play in the sensing of amino acid levels, both directly as initiators of nutrient signalling and indirectly as regulators of external amino acid access to intracellular receptor/signalling mechanisms.

Amino acid transport system A resembles system N in sequence but differs in mechanism

Classical amino acid transport System A accounts for most of the Na(+)-dependent neutral amino acid uptake by mammalian cells. System A has also provided a paradigm for short- and long-term regulation by physiological stimuli. We now report the isolation of a cDNA encoding System A that shows close similarity to the recently identified System N transporter (SN1). The System A transporter (SA1) and SN1 share many functional characteristics, including a marked sensitivity to low pH, but, unlike SN1, SA1 does not mediate proton exchange. Transport mediated by SA1 is also electrogenic. Amino acid transport Systems A and N thus appear closely related in function as well as structure, but exhibit important differences in ionic coupling.

Differential activation of system A and betaine/GABA transport in MDCK cell membranes by hypertonic stress

Accumulation of osmolytes by renal cells is due in part to increased uptake via specific transporters. These include amino acid transport system A and the betaine/GABA transporter (BGT1). Transport changes have been characterized using intact cells which makes the intracellular mechanisms difficult to determine. In this study the hypertonic upregulation of system A and BGT1 was studied directly at the membrane level in Madin-Darby canine kidney (MDCK) cells. Both system A and BGT1 transport systems were detected in an isolated membrane fraction containing plasma membranes. System A transport was increased in membranes prepared from cells after 6 h hypertonic stress (449 mosmol/kg) but BGT1 activity was minimal and not different from isotonic controls. The increase in system A was blocked by inhibitors of RNA and protein synthesis. BGT1 transport was induced in membranes prepared after 24 h hypertonicity. At this time system A activity in the membrane fraction remained increased, unlike the downregulation observed in intact MDCK cells. We conclude that differential upregulation of system A and BGT1 by hypertonic stress is due to intrinsic changes in these transporters at the membrane level. In contrast, the downregulation of system A in intact cells when hypertonicity is prolonged for 24 h is likely due to the action of an intracellular repressor that is not present in the isolated membranes.

Cytoskeletal-dependent activation of system A for neutral amino acid transport in osmotically stressed mammalian cells: a role for system A in the intracellular accumulation of osmolytes

System A activity for neutral amino acid transport is increased after hypertonic shock in NBL-1 (an epithelial cell line) and CHO-K1 cells (a nonepithelial cell line) by a mechanism which is consistent with the synthesis of a regulatory protein that activates preexisting system A carrier proteins (Ruiz-Montasell et al., 1994, Proc. Natl. Acad. Sci. USA, 91,9569-9573). In this study, we have further investigated this biological response by determining the role of cytoskeletal structures in system A regulation by hypertonic stress. Using inhibitors of the microfilament and microtubule networks, we show that the increase in system A activity after hypertonic treatment requires the integrity of both cytoskeletal structures in NBL-1 cells, although the increase in system A activity triggered by amino acid starvation is completely insensitive to any of these drugs. In contrast, the enhancement of system A activity in osmotically stressed CHO-K1 cells is not sensitive to inhibitors of the microtubule network. In both cell types, the results suggest that the inhibitors block the increase of system A activity. System A transport decreases when CHO-K1 cells return to isotonic conditions by a mechanism that is insensitive to inhibitors of protein and mRNA synthesis. The increase in system A transport activity is also followed by the accumulation of neutral amino acids (fourfold for alanine), which is totally blocked by the same agents (cycloheximide and actinomycin D) that prevent the increase in system A activity after hypertonic treatment, thus indicating that system A is crucial for maintaining a high concentration of organic osmolytes inside the cell.

Identification and partial characterization of a novel membrane glycoprotein induced by amino acid deprivation in renal epithelial cells

We have identified a protein of 110 kDa in the renal epithelial cell line NBL-1. which is induced on incubation of the cells in an amino-acid-free medium. The protein was purified on conA-Sepharose and subjected to N-terminal sequencing. The sequence obtained. VDRINFKT, does not correspond to any protein in the databases. Antipeptide antibodies made to this sequence recognised a single protein of 110 kDa in whole cell membranes and in a conconavalin A protein extract. Using the antibody on Western blots, the protein was induced 2.5-3 fold in 10-15 h and the induction was inhibited by cycloheximide and tunicamycin. The protein was found also in rat liver plasma membranes. A procedure for the partial purification of this protein from rat liver is described, and some internal sequence is reported. The possible relationship of the induction of this novel protein to the induction of amino acid transport in these cells by amino acid deprivation is discussed.

Dual action of colchicine on hypertonic activation of system A amino acid transport in vascular smooth muscle cells

Amino acid transport system A is present in many cells and tissues and is regulated by hormones and other factors, including hypertonic stress. System A in vascular smooth muscle cells is also activated when microtubules are disrupted by drugs such as colchicine. The present study examined the action of colchicine on hypertonic activation of system A in smooth muscle cells. In serum-free medium, activation of system A by modest (340 mOsm) hypertonicity was not affected by colchicine addition. However, at high osmotic stress (460 mOsm) the addition of colchicine partially blocked the activation of system A. Addition of colchicine alone, at normal osmolarity, produced activation of system A. In the presence of serum, colchicine action was markedly different. Colchicine consistently inhibited hypertonic activation of system A at any degree of hypertonic stress but had no effect on system A at normal osmolarity. The action of colchicine as both an activator and inhibitor of system A implies microtubule involvement at more than one step in the intracellular regulation of system A.

Eukaryotic gene expression: metabolite control by amino acids

Our understanding of the metabolite control in mammalian cells lags far behind that in prokaryotes. This is particularly true for amino-acid-dependent gene expression. Few proteins have been identified for which synthesis is selectively regulated by amino-acid availability, and the mechanisms for control of transcription and translation in response to changes in amino-acid availability have not yet been elucidated. The intimate relationship between amino-acid supply and the fundamental cellular process of protein synthesis makes amino-acid-dependent control of gene expression particularly important. Future studies should provide important insight into amino-acid and other nutrient signaling pathways, and their impact on cellular growth and metabolism.

Leucine activates system A amino acid transport in L6 rat skeletal muscle cells

In this study, we present evidence showing that leucine is involved in the upregulation of system A amino acid transport activity in the L6 rat skeletal muscle cell line. At leucine concentrations of > or = 0.05 mM, the uptake of N-methylamino-alpha-isobutyric acid (MeAIB), a paradigm system A substrate, was stimulated by up to 50%. Kinetic analysis revealed that this stimulation was a result of an increase in the maximal transport rate of MeAIB uptake, from 327 +/- 26 to 450 +/- 8 pmol.min-1.mg protein-1 after incubation of cells with leucine. No significant change in the concentration at which MeAIB transport was half maximal was observed. System A activation was biphasic, reaching an initial plateau after 3 h, with a second phase of activation being observed after 5 h. The initial activation of system A transport occurred by a mechanism distinct from that activated by insulin-like growth factor-I (IGF-I) (3 nM), since the effects of leucine and IGF-I were additive. This activation was not due to transstimulation, since 2-amino-2-norbornane-carboxylic acid, a specific system L substrate, did not stimulate system A. Leucine's keto acid, ketoisocaproic acid, prevented the activation of system A transport, whereas aminooxyacetate, a transaminase inhibitor, augmented the increase in system A activity by leucine. Both cycloheximide and actinomycin D inhibited the leucine-induced increase in MeAIB uptake. The present results indicate that leucine, or some cellular component regulated by it, is capable of stimulating system A transport through control of DNA transcription, possibly of a gene encoding either a repressor or enhancer molecule of system A or perhaps of the gene encoding system A itself.

Microtubule disruption stimulates system A transport in cultured vascular smooth muscle cells

This study has focused on the possible influence of microtubules for the regulation of Na(+)-dependent system A neutral amino acid transport in A10 cells, a cultured cell line derived from rat aortic vascular smooth muscle. When microtubules were disrupted by incubating cells for 5 h in serum-free medium containing colchicine, nocodazole, or vinblastine, there was a twofold increase in system A transport (Vmax change). The dose for the disruption of microtubules by colchicine was similar to the dose required for the stimulation of system A. The time course showed that system A stimulation did not occur until widespread disruption of microtubules was established. The stimulation was specific for system A; there were no changes in glucose transport and Na(+)-dependent transport of phosphate and glutamate. Serum refeeding of quiescent cells from 2 days of serum starvation led to stimulation of system A, glucose, and phosphate transport. However, only system A was activated when colchicine was added to the serum-free medium. Addition of colchicine during serum refeeding had no additive effect for the stimulation of system A. The stimulation by both colchicine and serum was blocked by cycloheximide and actinomycin D. These findings suggest that microtubule disruption may activate system A gene expression.

Coordinate induction of Na(+)-dependent transport systems and Na+,K(+)-ATPase in the liver of obese Zucker rats

Solute uptake into liver plasma membrane vesicles from either lean or obese Zucker rats was monitored. D-Glucose and L-leucine uptakes at physiological concentrations of the substrate were not different in lean and obese Zucker rats. In agreement with a previous report (Ruiz et al. (1991) Biochem. J. 280, 367-372) L-alanine uptake was significantly enhanced in those preparations from obese animals. Na(+)-coupled uridine transport was markedly enhanced also in obese rats. The effect was due to an increase in Vmax (5.5 +/- 0.6 vs. 2.1 +/- 0.2 pmol/mg protein per 3 s, P < 0.01) without any significant change in Km (11.0 +/- 2.8 vs. 9.0 +/- 2.7 microM for obese and lean rats, respectively). Na+,K(+)-ATPase activity was also higher in liver plasma membrane vesicles from rat liver and it correlated with a higher amount of alpha 1-subunit protein in both, plasma membrane vesicles and homogenates from obese rat livers. In summary, in the hypertrophic liver of obese Zucker rats a coordinate induction of several Na(+)-dependent transport systems occurs and, in order to sustain the metabolic pressure associated with this adaptation, a significant induction of the Na+,K(+)-ATPase expression is also found. These data also provide new evidence for regulation of the recently characterized Na(+)-dependent nucleoside transporter.

Evidence for a regulatory protein involved in the increased activity of system A for neutral amino acid transport in osmotically stressed mammalian cells

System A for neutral amino acid transport is increased by hypertonic shock in NBL-1 cells previously induced to express system A activity by amino acid starvation. The hypertonicity-mediated effect can be blocked by cycloheximide but is insensitive to tunicamycin. The activity induced may be inactivated irreversibly by the addition of system A substrates, by a rapid mechanism insensitive to cycloheximide. In CHO-K1 cells, hypertonicity increases system A activity, as has been shown in NBL-1 cells. This effect is additive to the activity produced by derepression of system A by amino acid starvation and is insensitive to tunicamycin. Furthermore, the alanine-resistant mutant CHO-K1 alar4, which bears a mutation affecting the regulatory gene R1, involved in the derepression of system A activity after amino acid starvation, is still able to respond to the hypertonic shock by increasing system A activity to a level similar to that described in hypertonicity-induced derepressed CHO-K1 (wild type) cells. These results suggest (i) that the hypertonicity-mediated increase of system A activity occurs through a mechanism other than that involved in system A derepression and (ii) that a regulatory protein coded by an osmotically sensitive gene is responsible for further activation of preexisting A carriers.

Up-regulation of liver system A for neutral amino acid transport in euglycemic hyperinsulinemic rats

To determine the role of insulin on the in vivo modulation of liver system A activity, we used the euglycemic hyperinsulinemic clamp coupled to the measurement of solute uptakes into plasma membrane vesicles partially purified from livers of hyperinsulinemic rats and their saline-infused controls. The clamp was performed in chronically catheterized rats, either in the fasted state, 24 h after surgery (Group I), or after 3 days of recovery (Group II). System A activity, measured as the MeAIB-inhibitable L-alanine uptake, was selectively induced by hyperinsulinemia, although the effect was much greater in Group II than in Group I rats (137% vs. 24% over the basal values, respectively). This might be explained by the higher basal levels found in those liver plasma membrane vesicles from Group I fasted animals. Hyperinsulinemia also decreased blood amino acids but to a similar extent in both experimental groups. This suggests that amino acid depletion by itself may not cause up-regulation of system A. Other transport activities involved in neutral amino acid transport (Systems ASC, N and L) were not modified by the clamp. The induction of system A cannot be explained by changes in the dissipation rate of the Na+ transmembrane gradient, because the differences between insulin- and saline-infused rats remained even when the electrochemical Na+ gradient was disrupted in the presence of monensin. Thus, hyperinsulinemia might induce an increase in the number of transporters inserted into the plasma membrane.

Regulatory and molecular aspects of mammalian amino acid transport

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Up-regulation of system A activity in the regenerating rat liver

System A activity for neutral amino acid transport, measured as the MeAIB-sensitive Na(+)-dependent L-alanine uptake, is induced 6 h after partial hepatectomy in plasma membrane vesicles from rat livers. Other Na(+)-dependent transporters, like system ASC (MeAIB-insensitive Na(+)-dependent L-alanine transport) and the nucleoside carrier show similar inductions. Up-regulation of system A is not explained by changes in the dissipation rate of the Na+ transmembrane gradient, as deduced from uptake measurements performed in the presence of monensin. To determine whether induced system A shared any similarity with the activity found in hepatoma cell lines, we analyzed the N-ethylmaleimide (NEM) sensitivity of system A in both regenerating and control rat liver plasma membrane vesicles. NEM treatment was equally effective in inhibiting system A in both experimental groups. Thus, during the prereplicative phase of liver growth, a transport activity similar to basal system A is up-regulated in liver parenchymal cells, by a stable mechanism that does not involve changes in the Na+ transmembrane gradient.

Amino acid uptake by liver of genetically obese Zucker rats

Alanine and glutamine uptake by the liver of 50-52-day-old genetically obese Zucker rats and their lean littermates has been studied. The net uptake in vivo of L-alanine is 2-fold higher in the obese animals. No significant change in L-glutamine net balance was found. We also studied the Na(+)-dependent uptake of L-alanine and L-glutamine into plasma-membrane vesicles isolated from either obese- or lean-rat livers. Vmax. values of both L-alanine and L-glutamine transport were 2-fold higher in those preparations from obese rats. No change in Km was observed. As suggested by inhibition studies, this seemed to be mediated by an enhancement of the activities of systems A, ASC and N. We conclude that the liver of the obese Zucker rat is extremely efficient in taking up neutral amino acids from the afferent blood, which results in an enhanced net uptake of L-alanine in vivo. The changes in transport activities at the plasma-membrane level might contribute to increase amino acid disposal by liver, probably for lipogenic purposes, as recently reported by Terrettaz & Jeanrenaud [Biochem. J. (1990) 270, 803-807].

Evidence for coordinate regulation of the A system for amino acid transport and the mRNA for the alpha 1 subunit of the Na+,K(+)-ATPase gene in Chinese hamster ovary cells

Previous work suggested that the structural gene for the A system transporter and the mRNA for the alpha subunit of the Na+,K(+)-ATPase in Chinese hamster ovary cells CHO-K1 [wild type (WT)] are coordinately controlled by regulatory gene R1. This conclusion was based on analysis of a mutant for the A system, alar4. This mutant had a constitutive level of A system transport activity equal to the level found in derepressed WT cells and a 4 times increase in abundance of the alpha 1 subunit of Na+,K(+)-ATPase mRNA over that found in repressed WT. The level of Na+ per cell in alar4 was not significantly greater than that found in the WT. To further characterize the likely coregulation of both genes, we have studied the A system activity and Na+,K(+)-ATPase mRNA alpha 1-subunit levels in cells grown under various conditions that result in repression or derepression of the A system in the WT. System A activity increased up to 2-3 times the basal transport rate (repressed state) and Na+,K(+)-ATPase mRNA alpha 1-subunit levels showed a 3-fold increase after amino acid starvation (derepressed state). These changes occurred along with a decrease in intracellular Na+ levels. N-Methyl-alpha-aminoisobutyric acid and beta-alanine, previously shown to be corepressors for the A system, prevented to a similar extent A system derepression and Na+,K(+)-ATPase mRNA alpha 1-subunit accumulation. On the other hand, phenylalanine and lysine, amino acids that are not corepressors of the A system, failed to significantly prevent derepression of both genes. Hybrids between the WT and alar4 have the phenotype of the WT when grown under repressed conditions. These results give further support to the proposition that both the A system transporter and mRNA for the alpha 1 subunit of the Na+,K(+)-ATPase are coordinately controlled by regulatory gene R1 and elevated Na+ concentrations are not involved. No Na+,K(+)-ATPase activity was detected in derepressed cells. Activity was restored by the addition of monensin. However, this activity was no greater than that obtained in repressed cells. Indications are that the reduced Na+ content in derepressed cells inhibits Na+,K(+)-ATPase activity and that conditions that favored derepression do not allow for de novo synthesis of the Na+,K(+)-ATPase.

L-alanine transport in isolated cells of interscapular brown adipose tissue in rat

The pattern of L-alanine uptake in isolated cells of interscapular brown adipose tissue has been determined. The uptake can be divided into the diffusion component (Kd = 0.55 min-1) and a saturable Na(+)-dependent transport (KM = 0.87 mM and Vmax = 155 nmol/min/10(6) cells). The saturable component can be subdivided into MeAIB-sensitive (KM = 1.63 mM and Vmax = 162 nmol/min/10(6) cells) and MeAIB-insensitive (KM = 3.2 mM and Vmax = 39.5 nmol/min/10(6) cells). This kinetic pattern could indicate the presence of transport system (s) that resemble the commonly described transport systems for alanine uptake in several tissues.

Membrane potential and amino acid transport in a mutant Chinese hamster ovary cell line

The bioenergetics of amino acid transport system A was studied in two Chinese hamster ovary (CHO) cell lines, the parent line CHO-PEOT/1 and CHY-1, a mutant of the former exhibiting a low activity of the same transport system. The steady-state transmembrane distribution ratio of the cationic amino acid L-arginine (RARG) was employed as an indicator of membrane potential (delta psi). Evidence for the reliability of RARG to measure delta psi can be summarized as follows: (1) L-arginine transmembrane distribution increased under conditions of cell hyperpolarization and decreased under conditions of cell depolarization; (2) L-arginine distribution conformed closely to that expected for a probe of delta psi in conditions in which delta psi depends largely on the transmembrane potassium gradient; and (3) the value of delta psi obtained through a valinomycin null point experiment (-72.7 mV) was very similar to the value calculated from L-arginine distribution using the Nernst equation (-73.4 mV). The transmembrane gradient of sodium electrochemical potential (delta mu Na), the driving force for the operation of system A, was slightly higher in the mutant cell line CHY-1. In the same line, the intracellular level of the specific system A substrate MeAIB at steady state was also higher. Studies of the rheogenicity of system A in the two lines indicated that the depolarization associated with the entry of substrates of system A was proportional to the amount of amino acid taken up by the cells. Kinetic analysis showed that the low activity of system A in the mutant cell line was referrable to a decrease in transport Vmax. It is concluded that neither a decrease in energy available for the operation of system A nor a decreased efficiency of coupling of the system to delta psi is responsible for the defect observed in the mutant line.

Substrate-dependent adaptive regulation and trans-inhibition of System A-mediated amino acid transport. Studies using rat hepatoma plasma membrane vesicles

Substrate-dependent regulation of amino acid transport by System A occurs by both direct action at the carrier (trans-inhibition) and transcriptional control (adaptive regulation). While experiments with intact cells have led to working models that describe these regulatory phenomena, the use of subcellular approaches will serve to refine the present hypotheses. Adaptive induction of System A transport following amino acid starvation of cells was shown to be dependent on de novo RNA and protein synthesis, and the stimulated activity was shown to be retained in isolated plasma membrane vesicles. This stimulated transport activity was tightly associated with the plasma membrane, but could be solubilized by 4 M urea and 2.5% cholate, and recovered following reconstitution of the protein into artificial proteoliposomes. These data support the working hypothesis that adaptive induction of transport is the result of de novo synthesis and insertion into the plasma membrane of System A carrier protein. In contrast, the activity of System ASC in the vesicles from the amino acid starved cells was actually reduced by 2-5-fold when compared to amino acid-fed cells. A more rapid form of regulation of System A activity is trans-inhibition. The use of isolated plasma membrane vesicles demonstrated that trans-inhibition in whole cells did not survive membrane isolation. However, substrate loading of isolated membrane vesicles containing high levels of System A activity, produced trans-inhibition in a very specific manner in that System A substrates resulted in decreased transport activity, while those amino acids which are poor substrates for the System A carrier did not. Thus, trans-inhibition is not the result of a recycling process involving an intracellular pool of carriers, but rather can be accounted for by differences in the kinetics for amino acid binding and/or translocation on the two sides of the membrane.

Electrophysiological investigation of the amino acid carrier selectivity in epithelial cells from Xenopus embryo

The electrical responses induced by external applications of neutral amino acids were used to determine whether different carriers are expressed in the membrane of embryonic epithelial cells of Xenopus laevis. Competition experiments were performed under voltage-clamp conditions at constant membrane potential. Gly, L-Ala, L-Pro, L-Ser, L-Asn and L-Gln generate electrical responses with similar apparent kinetic constants and compete for the same carrier.They are [Na]o and voltage-dependent, insensitive to variations in [Cl]o and [HCO3]o, inhibited by pHo changes, by amiloride and, for a large fraction of the current, by MeAIB. The increase in [K]o at constant and negative membrane potential reduces the response, whereas lowering [K]o augments it. L-Leu, L-Phe and L-Pro appear to compete for another carrier. They generate electrogenic responses insensitive to amiloride and MeAIB, as well as to alterations of membrane potential, [Na]o and [K]o. Lowering [Cl]o decreases their size, whereas increasing [HCO3]o at neutral pHo increases it. It is concluded that at least two and possibly three transport systems (A, ASC and L) are expressed in the membrane of the embryonic cells studied. An unexpected electrogenic character of the L system is revealed by the present study and seems to be indirectly linked to the transport function. L-Pro seems to be transported by system A or ASC in the presence of Na and by system L in the absence of Na. MeAIB induces an inward current.

alar4, a constitutive mutant of the A system for amino acid transport, has increased abundance of the Na+,K+-ATPase and mRNA for alpha 1 subunit of this enzyme

A constitutive mutant, alar4, for the A system of amino acid transport, has increased activity and amount of the A system. This is accompanied by increased sensitivity to ouabain, as measured by efficiency of plating, and increased activity and abundance of the Na+,K+-ATPase that is present in the parental cell line, CHO-K1 (wild type). The latter was shown by increases in (i) ouabain-inhibitable 86Rb uptake in intact cells, (ii) ouabain-inhibitable ATPase activity in mixed membrane vesicles, and (iii) number of ouabain-binding sites and by similar Kd values for ouabain binding and K1/2 for ouabain inhibition of Na+,K+-ATPase as compared to the wild type. The increase in abundance of the Na+ pump is associated with a 4-fold increase in abundance of the mRNA for the alpha 1 subunit of the Na+,K+-ATPase. We could not detect mRNA for alpha 2 or alpha 3 or for the beta subunits. The increase in abundance of the A system and Na+,K+-ATPase is associated with a negligible increase in intracellular Na+ concentration. We propose that the increase in the abundance of the A system and the Na+,K+-ATPase is the result of a mutation in regulatory gene R1 that controls the A system and the Na+,K+-ATPase and is not due to a primary effect of a possible initial increase in Na+ concentration.

Effects of 5-azacytidine, sodium butyrate, and phorbol esters on amino acid transport system A in a kidney epithelial cell line, MDCK: evidence for multiple mechanisms of regulation

Neutral amino acid transport by system A was investigated in the epithelial cell lines MDCK and MDCK-T1. The latter line is a chemically induced, oncogenically transformed line derived from MDCK. Inducers of differentiation, sodium butyrate and 5-azacytidine, and a tumor promoter, TPA, were used as probes to delineate pathways of regulation involved in system A response to a variety of physiological conditions and agents. Azacytidine, an inhibitor of DNA methylation, and butyrate, an enhancer of histone acetylation, inhibited expression of system A, had little effect on system ASC, and slightly stimulated system L. Inhibition of system A expression by butyrate and azacytidine occurred under different conditions. Increases in system A activity due to amino acid starvation or transformation were inhibited by butyrate but not by azacytidine. Repressed system A activity, normally observed in the presence of high levels of amino acids, was more sensitive to azacytidine than to butyrate. The tumor promoter, TPA, stimulated system A activity in MDCK cells under normal growth conditions but did not stimulate activity in amino acid-starved MDCK cells or in MDCK-T1 cells. Stimulation of system A activity by TPA was prevented by prior exposure to butyrate but not to azacytidine. These results suggest 1) that system A expression observed in growing amino-acid-repressed MDCK cells is modulated by an azacytidine-sensitive mechanism and 2) that the elevated expression of system A activity induced by amino acid starvation, by chemical transformation to MDCK-T1, and by TPA is modulated by a butyrate-sensitive mechanism.

Kinetics of the Na+/alanine cotransporter in pancreatic acinar cells

Electric currents associated with Na+-coupled alanine transport in pancreatic acinar cells were investigated by the technique of tight-seal whole-cell recordings. In a previous study the observed concentration dependence of alanine-dependent currents was found to be consistent with a 'simultaneous' transport mechanism with 1:1 stoichiometry. In the present work the sidedness of the cotransporter was investigated by comparing inward (I") and outward currents (I') measured under mirror-symmetrical conditions. I' and I" were found to be nearly equal (within a factor of approx. 2) in a wide range of Na+ and alanine concentrations. The transport model was further tested by 'infinite-cis' experiments with fixed, saturating concentrations of Na+ and L-alanine on one side of the membrane and variable concentrations on the other. By measuring transmembrane currents as a function of Na+ and alanine concentrations, numerical values of the equilibrium dissociation constants of both substrates could be estimated.

Two membrane-bound proteins associated with alanine resistance and increased A-system amino acid transport in mutants of CHO-K1

Growth of CHO-K1, a proline auxotroph, is inhibited by amino acids that prevent proline transport. From a hydroxyurea-treated, alanine-resistant, constitutive mutant, alar4, we isolated, in a stepwise fashion, mutants, resistant to higher concentrations of alanine, that have increased velocity of amino acid transport through the A system. Two such mutants, alar4-H2.1 and alar4-H3.9, isolated as resistant to 50 mM and 125 mM alanine, respectively, showed increases in Vmax of proline transport through the A system that are directly proportional to their resistance to alanine. Alar4-H3.9, as compared to alar4 and CHO-K1, has six and 29 times the Vmax of proline transport through the A system and two and five times the velocity of transport through the combined ASC and P systems, respectively, and no change in system L. No double-minute or homologous staining regions were detectable in alar4-H3.9. A-system activity of alar4-H2.1 and alar4-H3.9, when grown under nonselective conditions, was stable for 20 generations and then declined. The phenotype of alar4-H3.9 is codominant with that of alar4 and partially recessive to that of CHO-K1. Membrane vesicles prepared from alar4-H3.9 show increases mainly in A-system transport. In sodium dodecylsulfate-polyacrylamide gel electrophoresis analysis of A-system active membrane vesicles and endoplasmic reticulum, two bands of molecular weight of approximately 62-66 kd and 29 kd are present in higher concentrations in alar4-H3.9 than in CHO-K1. These results are compatible with the hypothesis that the phenotype of alar4-H3.9 is the result of gene amplification of an A-system transporter structural gene and that the two bands may represent this transporter.

Control of A-system amino acid transport by a second regulatory gene R2 in Chinese hamster ovary cells CHO-K1 and the possible connection of this gene with insulin activity

Evidence based on a study of alanine-resistant (Alar), constitutive mutants of CHO-K1 cells and the conditions that favor stimulation of the A system of amino acid activity supports the model that the A system of amino acid transport in these cells is repressible and under negative control of regulatory gene R1. In this study, we show that mutant Alar6, when grown under conditions of repression, has an A system of amino acid transport activity similar to that of the derepressed parental cell line, CHO-K1 (wild type) and of the fully constitutive mutant in gene R1, Alar4. However, the A system of Alar6 is further derepressible. The Vmax for proline transport through this system in mutant Alar6 is four times that of the parental culture, with no significant change in Km. Analysis of hybrids produced by crossing mutant Alar6 with the parental culture and with Alar4 shows that mutant Alar6 is recessive to wild type and complements mutant Alar4. Although the amino acid transport A system of CHO-K1 is stimulated by insulin, mutant alar6 is not stimulated by insulin. These results support the hypothesis that mutant alar6 results from mutation in another regulatory gene, R2, that, in conjunction with gene R1, negatively controls the expression of a structural gene for the A-system transport. Evidence also indicates that R2 gene product is not responsive to amino acids and that insulin stimulation of the A system may result from insulin inactivation of this repressor.

Isolation and characterization of a glycine transport mutant in an established mammalian cell line, CHO(PEOT/1)

Glycine uptake in CHO(PEOT/1) cells is mediated by at least three systems, of which two have been identified and partially characterized in this study: (1) a low affinity "A" system that transports a number of small neutral amino acids including glycine and methylaminoisobutyric acid (MeAIB), and (2) a high-affinity system, specific for glycine and sarcosine. By a combination of tritium suicide and replica plating, we have isolated a mutant (CHY-3) with a 47% decrease in glycine transport at the standard test concentration of 2.5 microM. Uptake studies with radioactive glycine, MeAIB, and sarcosine revealed that the mutant lacks the glycine-sarcosine system, but has undergone a compensatory 30-50% increase in the A system. Thus, there appears to be a regulatory interaction between these two systems for glycine uptake by CHO cells.