Regulation of amino acid transport in L6 myoblasts. II. Different chemical properties of transport after amino acid deprivation

Subcellular localization and adaptive up-regulation of the System A (SAT2) amino acid transporter in skeletal-muscle cells and adipocytes

The recently cloned amino acid transporter SAT2 is ubiquitously expressed and confers Na(+)-dependent transport of short-chain neutral amino acids, characteristics of the functionally defined System A transporter. Here we report the presence of SAT2 mRNA and protein in both skeletal muscle and adipocytes, and the characterization of polyclonal antibodies directed against this transporter. SAT2 protein was present in both plasma-membrane and internal-membrane fractions derived from rat skeletal muscle and adipose tissue, L6 myotubes and 3T3-L1 adipocytes, having a localization similar to that of the glucose transporter GLUT4. Moreover, consistent with the adaptive up-regulation of System A activity following chronic amino acid deprivation, a time-dependent increase in SAT2 protein abundance was observed in amino-acid-deprived L6 myotubes and 3T3-L1 adipocytes. These studies provide the first evidence regarding the subcellular distribution and adaptive up-regulation of SAT2 protein and the characterization of molecular probes for this physiologically important transporter, the function of which is altered in several disease states.

Regulation of System A amino acid transport in L6 rat skeletal muscle cells by insulin, chemical and hyperthermic stress

In this study we have investigated the effects of insulin, chemical and hyperthermic stresses upon the activity of the System A amino acid transporter in L6 rat muscle cells. Uptake of alpha-methyl-aminoisobutyric acid (Me-AIB), a non-metabolisable System A substrate, was increased by between 50% and 80% when muscle cells were exposed to a maximally effective concentration of insulin (100 nM), sodium arsenite (ARS, 0.5 mM) or a 42 degrees C heat shock (HS). The observed activation in System A in response to all three stimuli was maximal within 20 min and in the case of insulin and ARS primarily involved an increase in the Vmax of System A transport. In contrast, HS induced significant increases in both Vmax and Km of System A transport suggesting that hyperthermic stress may activate System A by a mechanism distinct from that mediating the effects of insulin and ARS. The hormonal stimulation of System A was blocked by the phosphoinositide 3-kinase (PI3k) inhibitor, wortmannin, but not by rapamycin or PD 98059 which respectively inhibit the mTOR and classical MAP kinase pathways. Exposure of L6 cells to ARS, but not HS, caused a 4.7-fold stimulation in MAPKAP-K2 activity that was blocked by SB 203580, a specific inhibitor of the stress activated protein kinase SAPK2/p38. However, neither SB 203580, rapamycin nor wortmannin were able to suppress the ARS- or HS-induced stimulation in System A transport. In summary, our results demonstrate that activity of the System A transporter can be rapidly upregulated in response to hormonal and stress stimuli through changes in the transport kinetics of the System A carrier. Our data show that whilst the hormonal response is PI3k dependent, the signalling mechanisms which instigate changes in System A activity in response to chemical or hyperthermic stress do not appear to involve PI3k or components of the mTOR, p42/p44 MAP kinase or SAPK2/p38 signalling pathways.

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.

Alanine uptake by liver of mid-lactating rats

L-Alanine transport in liver plasma membrane vesicle preparations from fed virgin and 15-day-lactating rats was studied. Lactation was found to induce a decrease of the maximal rate (Vmax) of a high-capacity-low-affinity component of the Na(+)-dependent L-alanine uptake. However, a high-affinity-low-capacity agency was significantly induced in lactating-rat livers. L-Alanine uptake was differentially inhibited by other amino acids in those preparations from lactating rats, and showed different sensitivity to Li+ as a cosubstrate instead of Na+ and to inhibition by sulfhydryl modifying reagents (N-ethylmaleimide [NEM] and p-chloromercuribenzosulfonate [PCMBS]). All of these observations taken together suggest that system A is upregulated in lactating-rat livers, thus resulting in a different contribution of both agencies A and ASC to the total Na(+)-dependent alanine transport into liver plasma membrane vesicles. This was demonstrated using the analogue alpha-methyl-aminoisobutyric acid (MeAIB), a specific system A substrate. L-Alanine uptake rates, as calculated from plasma membrane enzyme marker recoveries, were also enhanced in the physiologic range of alanine concentrations in blood. Our results prove that the physiologic adaptation to lactation involves modulation of system A activity in the liver.

Hexose transport in L6 rat myoblasts. II. The effects of sulfhydryl reagents

The importance of sulfhydryl groups for hexose transport in undifferentiated L6 rat myoblasts was investigated. N-ethylmaleimide (NEM) and p-chloromercuribenzenesulfonic acid (pCMBS) inhibited 2-deoxy-D-glucose (2-DOG) transport in a time and concentration-dependent manner. The inhibition produced by both reagents was virtually complete within 5 min, although neither reagent inhibited transport more than 70-80% regardless of the concentrations or incubation times used. Furthermore, the inhibition of 2-DOG transport by pCMBS or NEM could not be prevented by simultaneous preincubation of cells with 20 mM D-glucose or 20 mM 2-DOG. This suggests that sulfhydryl groups required for transport are separate from the hexose binding and transport site. By comparing the effects of the membrane impermeant pCMBS to those of the membrane permeant NEM, cell surface sulfhydryl groups were shown to be essential for hexose binding and transport. In contrast to the inhibition of 2-DOG transport, pCMBS and NEM had much less of an effect on 3-O-methyl-D-glucose (3-OMG) transport. For example, 1 mM NEM inhibited 2-DOG transport by 66%, whereas 3-OMG transport was inhibited by only 7%. This supports the suggestion that these hexose analogues may be transported by different carriers. Kinetic analysis of transport shows that treatment of cells with 1 mM NEM or 1 pCMBS results in inactivation of the high affinity 2-DOG transport system, whereas the low affinity transport system is unaffected. 3-OMG is preferentially transported by the low affinity system.

Induction of sugar uptake response to insulin by serum depletion in fusing L6 myoblasts

The L6 muscle cell line is proposed as an excellent cell culture system for studying glucose transport and its regulation by serum and insulin throughout myogenesis. The rate of hexose uptake decreased after cell fusion. Fetal calf serum (5 h) stimulated hexose uptake, and serum deprivation depressed it. Both effects were prevented by cycloheximide. Insulin stimulated the uptake of either 2-deoxy-D-glucose or 3-O-methyl-D-glucose provided that the basal rate was previously depressed by serum deprivation. The response to the hormone was significant only after the onset of cell fusion. Stimulation of transport was observed within the first 10 min after insulin administration and was insensitive to cycloheximide. Half-maximal stimulation of uptake was obtained with 5 X 10(-8) M insulin in 1% albumin solutions. Basal and insulin-stimulated uptake showed equal sensitivity to cytochalasin B. However, they differed in their sensitivity to extracellular Ca2+: basal transport was depressed, whereas insulin-stimulated transport was further enhanced in Ca2+-free media. Advantages of the cell culture system are discussed.

Na+ -dependent proline transport in isolated membrane vesicles from the L6 muscle cell line. Stimulation of uptake by intravesicular proline

Membrane vesicles of L6 myoblasts were prepared in order to study the amino acid transport system A. The role of the membrane in the adaptive response of transport to amino acid-supplementation was assessed. The membranes, prepared by N2 cavitation, displayed Na+ (but not K+)-dependent L-proline uptake. An overshoot of L-[3H]proline uptake was observed after exposure of the vesicles to an inward Na+ gradient. Isolated membrane vesicles loaded with 50 microM proline displayed countertransport (stimulation of proline uptake). It is concluded that the adaptive decrease of proline uptake observed in amino acid-supplemented cells cannot be accounted for by trans-inhibition of transport.