Identification of the integrin alpha 3 beta 1 as a component of a partially purified A-system amino acid transporter from Ehrlich cell plasma membranes

Amino acid transceptors: gate keepers of nutrient exchange and regulators of nutrient signaling

Amino acid transporters at the surface of cells are in an ideal location to relay nutritional information, as well as nutrients themselves, to the cell interior. These transporters are able to modulate signaling downstream of intracellular amino acid receptors by regulating intracellular amino acid concentrations through processes of coupled transport. The concept of dual-function amino acid transporter/receptor (or "transceptor") proteins is well established in primitive eukaryotes such as yeast, where detection of extracellular amino acid deficiency leads to upregulation of proteins involved in biosynthesis and transport of the deficient amino acid(s). The evolution of the "extracellular milieu" and nutrient-regulated endocrine controls in higher eukaryotes, alongside their frequent inability to synthesize all proteinaceous amino acids (and, hence, the requirement for indispensable amino acids in their diet), appears to have lessened the priority of extracellular amino acid sensing as a stimulus for metabolic signals. Nevertheless, recent studies of amino acid transporters in flies and mammalian cell lines have revealed perhaps unanticipated "echoes" of these transceptor functions, which are revealed by cellular stresses (notably starvation) or gene modification/silencing. APC-transporter superfamily members, including slimfast, path, and SNAT2 all appear capable of sensing and signaling amino acid availability to the target of rapamycin (TOR) pathway, possibly through PI 3-kinase-dependent mechanisms. We hypothesize (by extrapolation from knowledge of the yeast Ssy1 transceptor) that, at least for SNAT2, the transceptor discriminates between extracellular and intracellular amino acid stimuli when evoking a signal.

Amino acid transporters: éminences grises of nutrient signalling mechanisms?

Nutrient signalling by the mTOR (mammalian target of rapamycin) pathway involves upstream sensing of free AA (amino acid) concentrations. Several AA-regulated kinases have recently been identified as putative intracellular AA sensors. Their activity will reflect the balance between AA flows through underlying mechanisms which together determine the size of the intracellular free AA pool. For indispensable AAs, these mechanisms are primarily (i) AA transport across the cell membrane, and (ii) protein synthesis/breakdown. The System L AA transporter is the primary conduit for cellular entry of indispensable neutral AAs (including leucine and phenylalanine) and potentially a key modulator of AA-sensitive mTOR signalling. Coupling of substrate flows through System L and other AA transporters (e.g. System A) may extend the scope for sensing nutrient abundance. Factors influencing AA transporter activity (e.g. hormones) may affect intracellular AA concentrations and hence indirectly mTOR pathway activity. Several AA transporters are themselves regulated by AA availability through 'adaptive regulation', which may help to adjust the gain of AA sensing. The substrate-binding sites of AA transporters are potentially direct sensors of AA availability at both faces of the cell surface, and there is growing evidence that AA transporters of the SNAT (sodium-coupled neutral AA transporter) and PAT (proton-assisted AA transporter) families may operate, at least under some circumstances, as transporter-like sensors (or 'transceptors') upstream of mTOR.

Inhibition of SNAT2 by metabolic acidosis enhances proteolysis in skeletal muscle

Insulin resistance is a major cause of muscle wasting in patients with ESRD. Uremic metabolic acidosis impairs insulin signaling, which normally suppresses proteolysis. The low pH may inhibit the SNAT2 l-Glutamine (L-Gln) transporter, which controls protein synthesis via amino acid-dependent insulin signaling through mammalian target of rapamycin (mTOR). Whether SNAT2 also regulates signaling to pathways that control proteolysis is unknown. In this study, inhibition of SNAT2 with the selective competitive substrate methylaminoisobutyrate or metabolic acidosis (pH 7.1) depleted intracellular L-Gln and stimulated proteolysis in cultured L6 myotubes. At pH 7.1, inhibition of the proteasome led to greater depletion of L-Gln, indicating that amino acids liberated by proteolysis sustain L-Gln levels when SNAT2 is inhibited by acidosis. Acidosis shifted the dose-response curve for suppression of proteolysis by insulin to the right, confirming that acid increases proteolysis by inducing insulin resistance. Blocking mTOR or phosphatidylinositol-3-kinase (PI3K) increased proteolysis, indicating that both signaling pathways are involved in its regulation. When both mTOR and PI3K were inhibited, methylaminoisobutyrate or acidosis did not stimulate proteolysis further. Moreover, partial silencing of SNAT2 expression in myotubes and myoblasts with small interfering RNA stimulated proteolysis and impaired insulin signaling through PI3K. In conclusion, SNAT2 not only regulates mTOR but also regulates proteolysis through PI3K and provides a link among acidosis, insulin resistance, and protein wasting in skeletal muscle cells.

Physiological and Pathological Roles of α3β1 Integrin

Alpha3beta1 integrin has been considered to be a mysterious adhesion molecule due to the pleiotropy in its ligand-binding specificity. However, recent studies have identified laminin isoforms as high-affinity ligands for this integrin, and demonstrated that alpha3beta1 integrin plays a number of essential roles in development and differentiation, mainly by mediating the establishment and maintenance of epithelial tissues. Furthermore, alpha3beta1 integrin is also implicated in many other biological phenomena, including cell growth and apoptosis, angiogenesis and neural functions. This integrin receptor forms complexes with various other membrane proteins, such as the transmembrane-4 superfamily proteins (tetraspanins), cytoskeletal proteins and signaling molecules. Recently, lines of evidence have been reported showing that complex formation regulates integrin functions in cell adhesion and migration, signal transduction across cell membranes, and cytoskeletal organization. In addition to these roles in physiological processes, alpha3beta1 integrin performs crucial functions in various pathological processes, especially in wound healing, tumor invasion and metastasis, and infection by pathogenic microorganisms.

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.

Beta1 integrins show specific association with CD98 protein in low density membranes

BACKGROUND

The CD98 (4F2, FRP-1) is a widely expressed cell surface protein heterodimer composed of a glycosylated heavy chain and a non-glycosylated light chain. Originally described as a T cell activation antigen, it was later shown to function in amino acid transport, cell fusion and homotypic cell aggregation. Several lines of evidence suggest its functional interaction with integrins but the biochemical basis for this interaction has been unclear.

RESULTS

We demonstrate that CD98 constitutively and specifically associates with beta1 integrins (alpha2beta1,alpha3beta1, alpha5beta1 and alpha6beta1), but minimally with alpha4beta1. Integrin-CD98 association was established by reciprocal immunoprecipitation experiments, and confirmed by CD98-induced clustering of alpha3beta1 but not alpha4beta1 on the surface of rhabdomyosarcoma cells. Integrin-CD98 association is independent of the alpha subunit cytoplasmic tail, is maintained in alpha3beta1 ligand-interaction deficient mutants, and is not inhibited by EDTA. Within the CD98 heavy chain, a C109S mutation (but not a C330S mutation) caused a loss of beta1 integrin association. The same C109S mutation also caused a loss of CD98 light chain association. Importantly, CD98 associated selectively with beta1 integrins present in low density "light membrane" fractions on a sucrose gradient. CD98 was not present in dense fractions that contained the majority of beta1 integrins. Notably, the C109S mutant of CD98, that did not associate with beta1 integrins, showed also a reduced localization into light membrane fractions.

CONCLUSIONS

We demonstrate that CD98 association with beta1 integrins is specific, occurs in the context of low density membranes, and may require the CD98 light chain.

Mutated-gamma-actin restores growth to a yeast amino acid transport defective mutant

A mutated yeast cell 22574d lacking all three proline transporters, PUT4, UGA4, and GAP1, and incapable of growth on proline recovers its lost ability to grow on proline as sole nitrogen source when transformed with a mutagenized mouse gamma-actin cDNA (M-gamma-A). Native mouse gamma-actin cDNA is ineffective. The 3'-region of gamma-actin cDNA was mutagenized to resemble E51 cDNA previously isolated from Ehrlich tumor cells. The E51 cDNA has an extended reading frame in the 3'-region compared to that in native gamma-actin. The extension of the open reading frame in E51 cDNA, was found to be due to an additional pair of bases (TG) at position 1104 of E51 cDNA. After site-directed mutagenesis of the 3'-region of native gamma-actin cDNA to resemble that of E51 cDNA, the construct, M-gamma-A cDNA, was expressed in the 22574d yeast. While the transformation with M-gamma-A increased the uptake of both proline and gamma-amino butyric acid, the transport of five other solutes was not changed by this transformation. Northern blotting of the nontransformed and the M-gamma-A-transformed 22574d cells with gene-specific probes for the three proline transporters showed the expression of an mRNA for UGA4 in both transformed and nontransformed cells but no evidence for the expression of GAP1 or PUT4. The mRNA for UGA4 was expressed at a lower level in strain 22574d than in the parent yeast sigma1278b. Furthermore, the message in the mutated cells is smaller in size by about 15%. These results are consistent with the synthesis of a mutated transporter which requires the coexpression of M-gamma-A, but not native gamma-actin, to restore physiological function, i.e., proline or gamma-amino acid transport.

Integrin and cytoskeletal involvement in signalling cell volume changes to glutamine transport in rat skeletal muscle

1. Muscle glutamine transport is modulated in response to changes in cell volume by a mechanism dependent on active phosphatidylinositol 3-kinase. We investigated the possibility that this mechanism requires interactions between the extracellular matrix (ECM), integrins and the cytoskeleton as components of a mechanochemical transduction system. 2. Using skeletal muscle cells, we studied effects of (a) inactivating integrin-substratum interactions by using integrin-binding peptide GRGDTP with inactive peptide GRGESP as control, and (b) disrupting the cytoskeleton using colchicine or cytochalasin D, on glutamine transport after brief exposure to hypo-osmotic, isosmotic or hyperosmotic medium (170, 300 and 430 mosmol kg-1, respectively). 3. Neither GRGDTP nor GRGESP significantly affected basal glutamine uptake (0.05 mM; 338 +/- 58 pmol min-1 (mg protein)-1) but GRGDTP specifically prevented the increase (71%) and decrease (39%) in glutamine uptake in response to hypo- and hyperosmotic exposure, respectively. 4. Colchicine and cytochalasin D prevented the increase and decrease in glutamine uptake in response to changes in external osmolality. They also increased basal glutamine uptake by 59 +/- 19 and 85 +/- 16%, respectively, in a wortmannin-sensitive manner. 5. These results indicate involvement of ECM-integrin-mediated cell adhesion and the cytoskeleton in mechanochemical transduction of cell volume changes to chemical signals modulating glutamine transport in skeletal muscle. Phosphatidylinositol 3-kinase may function to maintain the mechanotransducer in an active state.

Molecular biology of mammalian plasma membrane amino acid transporters

Molecular biology entered the field of mammalian amino acid transporters in 1990-1991 with the cloning of the first GABA and cationic amino acid transporters. Since then, cDNA have been isolated for more than 20 mammalian amino acid transporters. All of them belong to four protein families. Here we describe the tissue expression, transport characteristics, structure-function relationship, and the putative physiological roles of these transporters. Wherever possible, the ascription of these transporters to known amino acid transport systems is suggested. Significant contributions have been made to the molecular biology of amino acid transport in mammals in the last 3 years, such as the construction of knockouts for the CAT-1 cationic amino acid transporter and the EAAT2 and EAAT3 glutamate transporters, as well as a growing number of studies aimed to elucidate the structure-function relationship of the amino acid transporter. In addition, the first gene (rBAT) responsible for an inherited disease of amino acid transport (cystinuria) has been identified. Identifying the molecular structure of amino acid transport systems of high physiological relevance (e.g., system A, L, N, and x(c)- and of the genes responsible for other aminoacidurias as well as revealing the key molecular mechanisms of the amino acid transporters are the main challenges of the future in this field.

Interactions between thyroid hormone and tryptophan transport in rat liver are modulated by thyroid status

We have identified both N-ethylmaleimide (NEM)-resistant (system T) and NEM-sensitive (system L1) L-[3H]tryptophan transporters in sinusoidal membrane vesicles (SMVs) from euthyroid, hypothyroid (propylthiouracil-treated), and hyperthyroid [L-3,5,3'-triiodothyronine (L-T3)-injected] rats. L-[125I]T3 associates with SMVs largely by surface binding. Kinetic characteristics of tryptophan uptake and T3 binding (transporter or receptor abundance and substrate affinity) are not significantly affected by thyroid status. T3 and thyroxine (T4) inhibit NEM-resistant tryptophan uptake in SMVs to an extent dependent on the thyroid status of the donor rat, increasing in the order hypothyroid < euthyroid < hyperthyroid; the inhibitor constant for this inhibition (0.3 microM T3) is equal to the dissociation constant for T3 binding. Both T3 binding and T3 inhibition of tryptophan transport in SMVs are markedly reduced by treatments (Triton X-100 or trypsin) that do not significantly affect vesicle integrity or transport of tryptophan and glucose. T3 and/or T4 transport at the liver-plasma interface may be facilitated by direct interactions between hormone receptors and system T transporter proteins. Modulation of such interactions may be important for control of hepatic T4 and/or T3 turnover and aromatic amino acid metabolism during altered thyroid status.

Is gamma-actin a regulator of amino acid transport?

A mutated yeast cell line incapable of growth in minimal medium with proline as the sole nitrogen source was restored to normal growth by transfection with a cDNA from mouse Ehrlich cells. The cloned cDNA (E51) was found to be 90% homologous to gamma-actin. Immediately after transfection with E51 cDNA, both alpha-aminoisobutyric acid (AIB) and proline uptake in the mutated yeast were increased, particularly at pH 5. The expression of the same E51 cDNA also enhanced amino acid uptake in Xenopus laevis oocytes after injection into the Xenopus nuclei. A mutated mammalian lymphocyte cell line (GF-17), deficient in system A transport, also showed increased Na(+)-dependent transport after transfection with E51 cDNA. Whereas the mock transfected GF-17 cells failed to grow in the selection medium, the transfectants with E51 cDNA grew better than the untransfected cells. The data are consistent with the conclusion that expression of E51 cDNA can modify inactive, endogenous amino acid transporters, permitting substantial amino acid uptake in cells deficient in amino acid transporter(s) and permitting rapid cell growth. The data suggest that the gamma-actin-like protein coded for by E51 cDNA may play a significant regulatory role in amino acid transport.

VLA-beta 1 integrin subunit-specific monoclonal antibodies MB1.1 and MB1.2: binding to epitopes not dependent on thymocyte development or regulated by phorbol ester and divalent cations

We report here the isolation of two new monoclonal antibodies (MB1.1 and MB1.2) against mouse VLA-beta 1 integrin subunit. Characterization by flow cytometry demonstrated binding of MB1.1 and MB1.2 to freshly isolated thymocytes, primary bone marrow mast cell lines, as well as cell lines of distinct lineage each expressing different combination of VLA integrins. The specificity of MB1.1 and MB1.2 was determined by (1) their binding to antigen with M(r) about 120 kDa, and (2) the ability of antiserum against the carboxyl terminal of VLA-beta 1 subunit to deplete antigens for MB1.1 and MB1.2 in sequential immunoprecipitation experiments. The epitopes for MB1.1 and MB1.2 were in close proximity to each other since preincubation of cells with one MAb inhibited the binding of the other. However, MB1.1 and MB1.2 differed in their affinity for the beta 1 subunit. In addition, neither MAbs had any effect on cell adhesion to matrix proteins indicating that the epitopes involved are distant from VLA integrin ligand-binding sites. MB1.1 and MB1.2 appear to differ from the two MAbs so far reported against mouse VLA-beta 1 subunit, KMI6 and 9EG7. Thus, the epitopes for MB1.1 and MB1.2 were readily detectable on unfractionated thymocytes whereas KMI6 has been reported to bind only a fraction of CD4-8- and CD4-8+ thymocytes. Phorbol ester and Mn2+, which have been shown to regulate the binding of 9EG7, had no effect on MB1.1 and MB1.2 binding to VLA-beta 1 integrin subunit.