The rabbit jejunal 'imino carrier' and the ileal 'imino acid carrier' describe the same epithelial function.

For rabbit jejunal brush border vesicles an 'imino carrier' has been defined as a sodium-dependent, alanine-resistant transporter of cyclic imino acids, while for intact rabbit jejunal and ileal epithelia an 'imino acid carrier' has been defined as a sodium-dependent transporter of both aliphatic and cyclic imino acids. This study on intact rabbit intestine examines whether these two terms describe the same epithelial function. The KPro1/2 and the KProi against JMeAIBmc are identical and so are KMeAIB1/2 and KMeAIBi against JPromc. Likewise, KLeui is the same against the transport of both proline and MeAIB. It is, therefore, concluded that the terms 'imino carrier' and 'imino acid carrier' describe the same epithelial function: A sodium-dependent, relatively high afinity, saturable transporter of both aliphatic and cyclic imino acids. Estimates of the apparent affinity and inhibitory constants for MeAIB, proline and leucine confirm that the jejuno-ileal variation of amino acid transport along the rabbit small intestine is a variation of maximal transport capacity.     

Chloride-dependence of amino acid transport in rabbit ileum

Chloride-dependence of influx across the brush-border membrane of distal rabbit ileum was examined for beta-alanine, 2-methylaminoisobutyric acid (MeAIB), leucine, lysine, proline and D-glucose. Influx of leucine at 2 mM and of D-glucose at 0.5 mM was chloride-independent indicating that substitution of isethionate for chloride has no unspecific effect on sodium gradient driven transport processes. In contrast influx of beta-alanine and MeAIB was totally dependent on the presence of chloride ions. In the absence of chloride, proline transport was reduced to 20% of its control level. This remaining transport can be accounted for by the function of the carrier of alpha-amino-monocarboxylic acids. Transport of leucine at 0.1 mM was reduced by absence of chloride. This is in accordance with the observation of leucine transport by the beta-alanine carrier. The kinetics of chloride and sodium activation of transport of MeAIB were examined at 1 mM MeAIB. Chloride activation was characterized by a Hill coefficient of 1 and a K1/2 of 23.5 mM, and sodium activation by a Hill coefficient of 2 and a K1/2 of 51 mM. Thus cotransport of chloride with an imino acid would be compatible with the known rheogenic nature of this transport. This study adds the imino acid carrier and the beta-alanine carrier to the group of chloride-dependent, epithelial amino acid transport systems.     

Multiple transport pathways for neutral amino acids in rabbit jejunal brush border vesicles

Amino acids enter rabbit jejunal brush border membrane vesicles via three major transport systems: (1) simple passive diffusion; (2) Na-independent carriers; and (3) Na-dependent carriers. The passive permeability sequence of amino acids is very similar to that observed in other studies involving natural and artificial membranes. Based on uptake kinetics and cross-inhibition profiles, at least two Na-independent and three Na-dependent carrier-mediated pathways exist. One Na-independent pathway, similar to the classical L system, favors neutral amino acids, while the other pathway favors dibasic amino acids such as lysine. One Na-dependent pathway primarily serves neutral L-amino acids including 2-amino-2-norbornanecarboxylic acid hemihydrate (BCH), but not beta-alanine or alpha-methylaminoisobutyric acid (MeAIB). Another Na-dependent route favors phenylalanine and methionine, while the third pathway is selective for imino acids and MeAIB. Li is unable to substitute for Na in these systems. Cross-inhibition profiles indicated that none of the Na-dependent systems conform to classical A or ACS paradigms. Other notable features of jejunal brush border vesicles include (1) no beta-alanine carrier, and (2) no major proline/glycine interactions.     

How many Na+-dependent carriers for L-alanine and L-proline in the eel intestine? Studies with brush-border membrane vesicles

Using brush-border membrane (BBM) vesicles prepared from the intestine of the European eel, the specificity of L-alanine and L-proline Na+-dependent transport was investigated by measuring the uptake of isotopically labelled substrates. In the presence of Na+ ions, cross-inhibition between alanine and proline transports was observed; in addition alpha-(methylamino)isobutyric acid (MeAIB) inhibited proline but had no effect on alanine uptake. These results can be explained by the presence, in eel intestinal BBM vesicles, of at least two distinct agencies for Na+-dependent proline and alanine translocation. The first system is specific for alanine and short-chain neutral amino acids; the second system, specific for imino acids and the N-methylated analogues, is regulated by alanine concentration.     

Neutral amino acid transport in isolated rat pancreatic islets

The neutral amino acid transport systems of freshly isolated rat pancreatic islets have been studied by first examining the transport of L-alanine and the nonmetabolizable analogue 2-(methylamino)isobutyric acid (MeAIB). By comparing the uptake of MeAIB and L-alanine for their pH dependency profile, choline and Li+ substitution for Na+, tolerance to N-methylation, and competition with other amino acids, the existence in pancreatic islets of both A and ASC amino acid transport systems was established. The systems responsible for the inward transport of five natural amino acids was studied using competition analysis and Na+ dependency of uptake. These studies defined three neutral amino acid transport systems: A and ASC (Na+-dependent) and L (Na+-independent). L-Proline entered rat islet cells mainly by system A; L-leucine by the Na+-independent system L. The uptake of L-alanine, L-serine, and L-glutamine was shared by systems ASC and L, the participation of system A being negligible for these three amino acids. An especially broad substrate specificity for systems L and ASC is therefore suggested for the rat pancreatic islet cells. The regulation of amino acid transport was also investigated in two conditions differing as to glucose concentration and/or availability, i.e. islets from fasted rats and islets maintained in tissue culture at high or low glucose concentrations. Neither alanine nor MeAIB transport was altered by fasting of the islet-donor rats. On the other hand, pancreatic islets maintained for 2 days in tissue culture at high (16.7 mM) glucose transported MeAIB at twice the rate of islets maintained at low (2.8 mM) glucose. Amino acid starvation of pancreatic islets during 11 h of tissue culture resulted in a 2-fold increase in MeAIB transport.     

Some Characteristics of Threonine Transport Across the Blood-Brain Barrier of the Rat

Threonine entry into brain is altered by diet-induced changes in concentrations of plasma amino acids, especially the small neutrals. To study this finding further, we compared effects of various amino acids (large and small neutrals, analogues, and transport models) on transport of threonine and phenylalanine across the blood-brain barrier. Threonine transport was saturable and was usually depressed more by natural large than small neutrals. Norvaline and 2-amino-n-butyrate (AABA) were stronger competitors than norleucine. 2-Aminobicyclo[2.2.1]heptane-2-carboxylate (BCH), a model in other preparations for the large neutral (L) system, and cysteine, a proposed model for the ASC system only in certain preparations, reduced threonine transport; 2-(methylamino)isobutyrate (MeAIB; a model for the A system for small neutrals) did not. Phenylalanine transport was most depressed by cold phenylalanine and other large neutrals; threonine and other small neutrals had little effect. Norleucine, but not AABA, was a strong competitor; BCH was more competitive than cysteine or MeAIB. Absence of sodium did not affect phenylalanine transport, but decreased threonine uptake by 25% (p less than 0.001). Our results with natural, analogue, and model amino acids, and especially with sodium, suggest that threonine, but not phenylalanine, may enter the brain partly by the sodium-dependent ASC system.     

A novel imino-acid carrier in the enterocyte basolateral membrane

Basolateral membrane vesicles prepared from rat small intestinal epithelial cells were used to study the sodium-independent transport of L-proline. The uptake of L-proline was unaffected by the presence of sodium and showed saturation kinetics (Kt = 0.5 mM and Vmax = 23.3 pmol/mg protein per s). Competition experiments indicated that other amino acids had an affinity for the carrier system with L-leucine greater than L-alanine greater than sarcosine greater than glycine greater than L-lysine greater than OH-proline greater than taurine greater than beta-alanine greater than D-alanine greater than D-proline greater than L-serine greater than phenylalanine greater than valine greater than D-serine greater than phenylalanine greater than valine greater than D-serine greater than MeAIB greater than methionine greater than threonine. This pathway does not resemble those previously described either in the brush-border membrane of intestinal epithelial cells or the plasma membrane of other cell types. The lack of effect of methionine and threonine indicate that proline is not using the L-type system, while the very low affinity for MeAIB and the Na+ independence suggest that this is a novel system for imino acids. The relatively high capacity of this system and its low Kt, which is almost identical to the proline system in the brush-border membrane, strongly suggest that this is an important pathway in the final step for proline absorption by the small intestine.     

Regulation of the A system of amino acid transport in Chinese hamster ovary cells, CHO-K1: the difference in specificity between the apo-repressor inactivator (apo-ri) and the transporter and the characterization of the proposed apo-ri

When amino acids that are generally transported through the A system are added to derepressed cultures of CHO-K1 cells or to cultures that are undergoing starvation-derepression, as in the co-repressor (co-r), co-inactivator (co-i), (co-ri) assay, the A system undergoes trans-inhibition, inactivation, and repression. The effect of inactivation and repression is not related to the ability of amino acids to bind to the A system transporter but supports a model in which these amino acids act as co-r's/co-i's, and by binding to a aporepressor/inactivator (apo-ri), the product of gene R1, convert it into a repressor/inactivator (ri). For example, beta-alanine acts as a strong co-r but does not inhibit proline transport through the A system. Hydroxyproline and histidine, although poor inhibitors of proline transport, are very effective as co-ri's. Diaminobutyrate, phenylalanine, alpha-keto-glutarate, pyro-glutamate, isoleucine, and valine, compounds that inhibit A system transport, listed in decreasing order of effectiveness, are all equally poor as co-ri's. Also the Km for the transport of 2-(methylamino)isobutyric acid (MeAIB) through the A system is two times the concentration of MeAIB required to produce one-half inactivation. Amino acid effectors and mutation can modify the conversion of the apo-ri to repressor (r) and inactivator (i). The apo-ri is converted by alanine, serine, proline, and MeAIB to ri, by beta-alanine and tryptophane to r, and by hydroxyproline to r and reduced i. The full constitutive and partial constitutive mutants alar4 and alar2, respectively, are in the same complementation group. Alar4 has no active apo-ri while the rate of derepression of alar2 is twice and the inactivation rate is equal to that of the parent culture.     

Evidence for the transport of neutral as well as cationic amino acids by ATA3, a novel and liver-specific subtype of amino acid transport system A

We report here on the cloning and functional characterization of the third subtype of amino acid transport system A, designated ATA3 (amino acid transporter A3), from a human liver cell line. This transporter consists of 547 amino acids and is structurally related to the members of the glutamine transporter family. The human ATA3 (hATA3) exhibits 88% identity in amino acid sequence with rat ATA3. The gene coding for hATA3 contains 16 exons and is located on human chromosome 12q13. It is expressed almost exclusively in the liver. hATA3 mediates the transport of neutral amino acids including α-(methylamino)isobutyric acid (MeAIB), the model substrate for system A, in a Na⁺-coupled manner and the transport of cationic amino acids in a Na⁺-independent manner. The affinity of hATA3 for cationic amino acids is higher than for neutral amino acids. The transport function of hATA3 is thus similar to that of system y⁺L. The ability of hATA3 to transport cationic amino acids with high affinity is unique among the members of the glutamine transporter family. hATA1 and hATA2, the other two known members of the system A subfamily, show little affinity toward cationic amino acids. hATA3 also differs from hATA1 and hATA2 in exhibiting low affinity for MeAIB. Since liver does not express any of the previously known high-affinity cationic amino acid transporters, ATA3 is likely to provide the major route for the uptake of arginine in this tissue.     

Amino acid transport in kidney epithelial cell line (MDCK): characteristics of Na+/amino acid symport in membrane vesicles and basolateral localization in cell monolayers

Na+-stimulated amino acid transport was investigated in MDCK kidney epithelial cell monolayers and in isolated membrane vesicles. When transport polarity was assessed in confluent polarized epithelial cell monolayers cultured on Nucleopore filters and mounted between two lucite chambers, Na+-stimulated transport of 2-(methylamino)isobutyric acid (MeAIB), a substrate specific for the A system, was predominantly localized on the basolateral membrane. Na+-stimulated amino acid transport activity was maximal in subconfluent cultures, and was substantially reduced after confluence. A membrane vesicle preparation was isolated from confluent MDCK cell cultures which was enriched in Na+-stimulated MeAIB transport activity and Na+,K+,ATPase activity, a basolateral marker, but was not enriched in apical marker enzyme activities or significantly contaminated by mitochondria. Na+-coupled amino acid transport activity assayed in vesicles exhibited a marked dependence on external pH, with an optimum at pH 7.4. The pattern of competitive interactions among neutral amino acids was characteristic of A system transport. Na+-coupled MeAIB and AIB transport in vesicles was electrogenic, stimulated by creation of an interior-negative membrane potential. The Na+ dependence of amino acid transport in vesicles suggested a Na+ symport mechanism with a 1:1 stoichiometry between Na+ and amino acid.     

Variation in amino acid transport along the rabbit small intestine. Mutual jejunal carriers of leucine and lysine.

The jejuno-ileal variation of amino and imino acid transport across the brush-border membrane of intact rabbit small intestine was studied. For the amino acids tested--beta-alanine, leucine, lysine, MeAIB, proline--and for D-glucose, the rates of transport at constant concentrations increase from very low values in the proximal jejunum to maximum values in the most distal 30 cm of the ileum. The apparent affinity constant for jejunal taurine transport is identical to that of the distal ileum, while the jejunal transport capacity is less than half. In the jejunum, as in the distal ileum, leucine and lysine share both sodium-dependent and sodium-independent carriers. Approx. 50% of the quantitative difference in transport capacity is accounted for by the absence of the beta-alanine carrier in the jejunum. These data indicate that the gradients of transport along the small intestine reflect gradients of transport capacities rather than affinities. In comparison with hamster, man and rat, the rabbit seems unique with respect to the location of transport maximum and the steepness of the gradient along the intestine.     

Recessive constitutive mutant Chinese hamster ovary cells (CHO-K1) with an altered A system for amino acid transport and the mechanism of gene regulation of the A system.

Chinese hamster ovary cells (CHO-K1) starved for 24 h for amino acids show a severalfold increase in velocity of proline transport through the A system (Vmax is five times that of unstarved cells). This increase is inhibited by cycloheximide, actinomycin D, N-methyl-alpha-amino isobutyric acid (MeAIB, a non-metabolizable specific A system amino acid analog), and by other amino acids that are generally transported by the A system. However, transport by the A system is not a prerequisite for this repression, and all compounds that have affinity for the A system do not necessarily act as "co-repressors." The addition of proline, MeAIB, or other amino acids, as described above, to derepressed cells results in a rapid decrease in A system activity. As shown with proline and MeAIB, this decrease in activity is in part due to a rapid trans-inhibition and a slow, irreversible inactivation of the A system. Neither process is inhibited by cycloheximide or actinomycin D. Alanine antagonizes the growth of CHO-K1 pro cells by preventing proline transport, and alanine-resistant mutants (alar) have been isolated (Moffett et al., Somatic Cell Genet. 9:189-213, 1983). alar2 and alar4 are partial and full constitutive mutants for the A system and have two and six times the Vmax for proline uptake by the A system, respectively. The A system in alar4 is also immune to the co-repressor-induced inactivation. Both alar2 and alar4 phenotypes are recessive. Alar3 shows an increase in Vmax and Km for proline transport through the A system, and this phenotype is codominant. All three mutants have a pleiotropic effect, producing increases in activity of the ASC and P systems of amino acid transport. This increase is not due to an increase in the Na+ gradient. The ASC and P phenotypes behave similarly to the A system in hybrids. A model has been proposed incorporating these results.     

Electrogenic Na(+)-dependent L-alanine transport in the lizard duodenum. Involvement of systems A and ASC

L-Alanine transport across the isolated duodenal mucosa of the lizard Gallotia galloti has been studied in Ussing chambers under short-circuit conditions. Net L-alanine fluxes, transepithelial potential difference (PD), and short-circuit current (Isc) showed concentration-dependent relationships. Na(+)-dependent L-alanine transport was substantially inhibited by the analog alpha-methyl aminoisobutyric acid (MeAIB). Likewise, MeAIB fluxes were completely inhibited by L-alanine, indicating the presence of system A for neutral amino acid transport. System A transport activity was electrogenic and exhibited hyperbolic relationships for net MeAIB fluxes, PD, and Isc, which displayed similar apparent K(m) values. Na(+)-dependent L-alanine transport, but not MeAIB transport, was partially inhibited by L-serine and L-cysteine, indicating the participation of system ASC. This transport activity represents the major pathway for L-alanine absorption and seemed to operate in an electroneutral mode with a negligible contribution to the L-alanine-induced electrogenicity. It is concluded from the present study that the active Na(+)-dependent L-alanine transport across the isolated duodenal mucosa of Gallotia galloti results from the independent activity of systems A and ASC for neutral amino acid transport.     

Insulin-stimulated alpha-(methyl)aminoisobutyric acid uptake in skeletal muscle. Evidence for a short-term activation of uptake independent of Na+ electrochemical gradient and protein synthesis.

1. The present study was designed to explore the mechanisms by which insulin stimulates system A of amino acid transport in extensor digitorum longus (EDL) muscles, by using a system A analogue, alpha-(methyl)aminoisobutyric acid (MeAIB). 2. Insulin stimulation of MeAIB uptake was noted after only 30 min of incubation and was maximal at 60 min. Kinetics of the insulin effect on MeAIB uptake were characterized by an increased Vmax. without modification of Km for MeAIB. 3. Incubation of EDL muscles with cycloheximide for 90 min did not modify MeAIB uptake in either the presence or the absence of insulin, indicating the independence of insulin action from protein synthesis de novo. Incubations for 180 min with cycloheximide caused a decrease in basal MeAIB uptake; however, the percentage stimulation of amino acid transport by insulin was unaltered. Basal MeAIB uptake was increased by incubation for 180 min, but under these conditions no change in the percentage effect of insulin was found. 4. Ouabain, gramicidin D, or both, markedly decreased basal MeAIB uptake by EDL muscle, but the percentage effect of insulin was unaltered. 5. We conclude that insulin action on amino acid transport through system A in muscle is rapid, is characterized by an increased Vmax., and is independent of protein synthesis de novo and the Na+ electrochemical gradient. Our data are compatible with insulin acting directly on the system A transporter.     

Hormonal regulation of hepatic amino acid transport

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

Multiple transport pathways for neutral amino acids in rabbit jejunal brush border vesicles

Summary Amino acids enter rabbit jejunal brush border membrane vesicles via three major transport systems: (1) simple passive diffusion; (2) Na-independent carriers; and (3) Na-dependent carriers. The passive permeability sequence of amino acids is very similar to that observed in other studies involving natural and artificial membranes. Based on uptake kinetics and cross-inhibition profiles, at least two Na-independent and three Na-dependent carrier-mediated pathways exist. One Na-independent pathway, similar to the classical L system, favors neutral amino acids, while the other pathway favors dibasic amino acids such as lysine. One Na-dependent pathway primarily serves neutrall-amino acids including 2-amino-2-norbornanecarboxylic acid hemihydrate (BCH), but not -alanine or -methylaminoisobutyric acid (MeAIB). Another Na-dependent route favors phenylalanine and methionine, while the third pathway is selective for imino acids and MeAIB. Li is unable to substitute for Na in these systems. Cross-inhibition profiles indicated that none of the Na-dependent systems conform to classical A or ACS paradigms. Other notable features of jejunal brush border vesicles include (1) no -alanine carrier, and (2) no major proline/glycine interactions.     

Proton gradient-dependent transport of glycine in rabbit renal brush-border membrane vesicles

This study describes evidence for the existence of a H+/glycine symport system in rabbit renal brush-border membrane vesicles. An inward proton gradient stimulates glycine transport across the brush-border membrane, and this H+-driven glycine uptake is attenuated by the protonophore carbonyl cyanide p-trifluoromethoxyphenylhydrazone. It is a positive rheogenic process, i.e. the H+-dependent glycine uptake is further enhanced by an intravesicular negative potential. Glycine uptake is stimulated to a lesser degree by an inward Na+ gradient. H+-dependent glycine uptake is inhibited by sarcosine (69%), an analog amino acid, imino acids (proline 81%, hydroxy proline 67%), and beta-alanine (31%), but not by neutral (L-leucine) or basic (L-lysine) amino acids. The results demonstrate that H+ glycine co-transport system in rabbit renal brush-border membrane vesicles is a carrier-mediated electrogenic process and that transport is shared by imino acids and partially by beta-alanine.     

SYNTHETIC AMINO ACIDS AND THE NATURE OF l-DOPA TRANSPORT AT THE BLOOD-BRAIN BARRIER

—The blood-brain barrier transport of amino acids has been measured using the carotid injection technique in the rat. The synthetic amino acids, 2-aminobicyclo(2,2,1)heptane-2-carboxylic acid (BCH) and α-(methylamino)isobutyric acid (MeAIB), were model substrates in the Ehrlich cell for the leucine (L) and alanine (A) neutral amino acid transport mechanisms, respectively. The uptake (±)b-[carboxyl-¹⁴C]BCH at the same rate for the five brain regions tested suggested a similarity between regions for the L transport mechanism. At injectant concentrations of 0·1 mm (similar to naturally occurring aromatic neutral amino acids), BCH was mainly taken up by a saturable mediated transport mechanism (K₁, 0·16 mm and V_max, 0·03/μmol/g per min). At higher concentrations, uptake by a nonsaturable or diffusional mechanism could be demonstrated. When BCH was added as a second amino acid to l -[3-¹⁴C]DOPA, the saturable component of l -DOPA transport was significantly inhibited. MeAIB had no measurable effect on the rate of l -DOPA transport. These results suggested that the mediated transport mechanism for l -DOPA at the cerebral capillaries is similar to the l -neutral amino acid transport system.     

Glycine transport by cultured human fibroblasts

The transport of glycine was studied in cultured human fibroblasts. The amino acid entered the cell by Na+-dependent and Na+-independent mechanisms. Na+-independent glycine (0.1 mM) transport was less than 10% of total uptake and occurred by a mechanism formally indistinguishable from diffusion. Two distinct routes contributed to Na+-dependent glycine transport. The first route was identified with system A because it was inhibited by MeAIB and underwent adaptive regulation. The second route was identified with system ASC as it was inhibited by L-alanine, but not by MeAIB. Kinetic analysis revealed that the two systems operated glycine transport with the same Km of 1.6 mM, a value unusually high for system ASC.     

Protein kinase C activators selectively inhibit insulin-stimulated system A transport activity in skeletal muscle at a post-receptor level.

We have investigated the role of phorbol esters on different biological effects induced by insulin in muscle, such as activation of system A transport activity, glucose utilization and insulin receptor function. System A transport activity was measured by monitoring the uptake of the system A-specific analogue alpha-(methyl)aminoisobutyric acid (MeAIB), by intact rat extensor digitorum longus muscle. The addition of 12-O-tetradecanoylphorbol 13-acetate (TPA, 0.5 microM) for 60 or 180 min did not modify basal MeAIB uptake by muscle, suggesting that insulin signalling required to stimulate MeAIB transport does not involve protein kinase C activation. However, TPA added 30 min before insulin (100 nM) markedly inhibited insulin-stimulated MeAIB uptake. The addition of polymyxin B (0.1 mM) or H-7 (1 mM), protein kinase C inhibitors, alone or in combination with TPA leads to impairment of insulin-stimulated MeAIB uptake. This paradoxical pattern is incompatible with a unique action of Polymyxin B or H-7 on protein kinase C activity. Therefore these agents are not suitable tools with which to investigate whether a certain insulin effect is mediated by protein kinase C. TPA did not cause a generalized inhibition of insulin action. Thus both TPA and insulin increased 3-O-methylglucose uptake by muscle, and their effects were not additive. Furthermore, TPA did not modify insulin-stimulated lactate production by muscle. In keeping with this selective modification of insulin action, treatment of muscles with TPA did not modify insulin receptor binding or kinase activities. In conclusion, phorbol esters do not mimic insulin action on system A transport activity; however, they markedly inhibit insulin-stimulated amino acid transport, with no modification of insulin receptor function in rat skeletal muscle. It is suggested that protein kinase C activation causes a selective post-receptor modification on the biochemical pathway by which insulin activates system A amino acid transport in muscle.