The interaction of bovine milk galactosyltransferase with lipid and alpha-lactalbumin.

The activation of galactosyltransferase (UDPgalactose: N-acetyl-D-glucosaminyl-glycopeptide 4-beta-D-galactosyltransferase, EC 2.4.1.38) by alpha-lactalbumin has been studied at low concentrations of alpha-lactalbumin where the relationship is sigmoidal. The sigmoidal shape of the activation curve was eliminated by neutral lipids such as phosphatidylcholine and phosphatidylethanolamine, detergents such as Triton X-100 or by an aggregated form of alpha-lactalbumin generated by crosslinking alpha-lactalbumin with dithiobissuccinimidylpropionate. It is proposed that these different reagents present a hydrophobic surface to the enzyme which is necessary for lactose synthase activity. In competition experiments, large amounts of alpha-lactalbumin were able to displace lipid from the enzyme as suggested by the loss of the lipid-activating effect in the presence of an excess of alpha-lactalbumin. Optimal lactose synthase activity was obtained when the ratio of lipid/alpha-lactalbumin/enzyme was 60:6:1. The mechanism by which the lipid effect was obtained probably involved a phase transition in the enzyme which was detected as a sharp break in the Arrhenius curve. The presence of phosphatidylcholine abolished the break demonstrating that full activity of the enzyme required both alpha-lactalbumin and lipid.

Glucose transport and glucose transporters in muscle and their metabolic regulation.

Skeletal muscle is the primary tissue responsible for insulin-dependent glucose uptake in vivo; therefore, glucose uptake by this tissue plays an important role in determining glycemia. Glucose uptake in muscle occurs by a system of facilitated diffusion involving at least two distinct glucose transporters, GLUT-1 and GLUT-4. Both bind the fungal metabolite and inhibitor of glucose transport cytochalasin B. In human skeletal muscle, both types of transporters are detected immunologically, and corresponding mRNA transcripts of both transporter forms are detected. In human skeletal muscle cells in culture, in which contamination by other tissues is ruled out, a 50,000-Mr polypeptide is photolabeled with cytochalasin B. In rat skeletal muscle, acute treatment with insulin in vivo increases glucose-transport activity and the number of specific cytochalasin B-binding sites at the plasma membrane. In mildly diabetic (streptozocin-induced) rats, the number of cytochalasin B-binding sites is decreased in total membranes, and preferentially in the plasma membrane. In response to acute insulin treatment, however, there is still recruitment of glucose transporters to the plasma membrane from an intracellular membrane store. Hence, migration of transporters does occur in this form of diabetes. In L6 muscle cells in culture, acute treatment (1 h) with insulin causes recruitment of glucose transporters to the plasma membrane, and prolonged exposure to insulin or to glucose-deprived medium causes increased expression of GLUT-1 mRNA and GLUT-1 protein. Prolonged exposure (24 h) to high glucose in the medium causes a decrease in the number of glucose transporters in the plasma membrane. Hence, in those cells the expression of the GLUT-1 glucose transporter is modulated by insulin.

Isolation of zymogen granules from rat pancreas and characterization of their membrane proteins.

A zymogen granule fraction has been isolated from rat pancreas, and its purity has been assessed by biochemical and morphological criteria. Specific activities of two marker enzymes, amylase and chymotrypsin, are increased by 4.6 and 5.4-fold, respectively, as compared to the homogenate. The purified fraction is devoid of detectable RNA, DNA and 5'-nucleotidase, glucose-6-phosphatase, and cytochrome c oxidase activities. Electron micrographs confirm the absence of mitochondria, lysosomes, and rough endoplasmic reticulum fragments. Zymogen granule membranes were isolated from this fraction on a sucrose gradient following lysis in alkaline buffer. Secretory contaminants were efficiently removed from the membranes as indicated by experiments in which labeled secretory proteins were added during the isolation procedure and secondly by measuring residual levels of amylase and chymotrypsin. Three enzyme activities were found in the membranes: thiamine pyrophosphatase, ATP-diphosphohydrolase, and low levels of acid phosphatase. Membrane proteins were solubilized by urea-Triton X-100 and separated in double-dimension (isoelectric focusing and sodium dodecyl sulfate-polyacrylamide gel electrophoresis). Isoelectric point and molecular weight of each protein band were determined.

Effect of insulin on the rates of synthesis and degradation of GLUT1 and GLUT4 glucose transporters in 3T3-L1 adipocytes.

The effect of continuous insulin stimulation on the rates of turnover and on the total cellular contents of the glucose-transporter proteins GLUT1 and GLUT4 in 3T3-L1 adipocytes was investigated. Pulse-and-chase studies with [35S]methionine followed by immunoprecipitation of GLUT1 and GLUT4 with isoform-specific antibodies revealed the half-lives of these proteins to be 19 h and 50 h respectively. Inclusion of 100 nM insulin in the chase medium resulted in a decrease in the half-lives of both proteins to about 15.5 h. This effect of insulin was specific for the glucose-transporter proteins, as the average half-life of all proteins was found to be 55 h both with and without insulin stimulation. The effect of insulin on the rate of synthesis of the glucose transporters was determined by the rate of incorporation of [35S]methionine. After 24 h of insulin treatment, the rate of synthesis of GLUT1 and GLUT4 were elevated over control levels by 3.5-fold and 2-fold respectively. After 72 h of treatment under the same conditions, the rate of synthesis of GLUT1 remained elevated by 2.5-fold, whereas the GLUT4 synthesis rate was not different from control levels. Western-blot analysis of total cellular membranes revealed a 4.5-fold increase in total cellular GLUT1 content and a 50% decrease in total cellular GLUT4 after 72 h of insulin treatment. These observations suggest that the rates of synthesis and degradation of GLUT1 and GLUT4 in 3T3-L1 adipocytes are regulated independently and that these cells respond to prolonged insulin treatment by altering the metabolism of GLUT1 and GLUT4 proteins in a specific manner.

A kinetic comparison of partially purified rat liver Golgi and rat serum galactosyltransferases.

UDP-galactose: N-acetylglucosamine beta-1,4-galactosyltransferase was partially purified from rat liver Golgi membranes and rat serum. The kinetic parameters of the two enzymes isolated by affinity chromatography were compared with each other and with those for commercial bovine milk galactosyltransferase. When N-acetyl-glucosamine was the acceptor the Km values for UDP-galactose were 65,52 and 43 microM for the rat liver Golgi, rat serum and bovine milk enzymes respectively. The Km values for N-acetylglucosamine were 0.33, 1.49 and 0.5 mM for the three enzymes respectively. The Km values for UDP-galactose, with glucose as acceptor in the presence of 1 mg of alpha-lactalbumin, were 23, 9.0 and 60 microM for the three enzymes respectively, and the Km values for glucose were 2.3, 1.8 and 2.0 mM respectively. The effects of alpha-lactalbumin in both the lactosamine synthetase and lactose synthetase reactions were similar. The activation energies were 94.0 kJ/mol (22.5 kcal/mol) and 96.0 kJ/mol (22.9 kcal/mol) for the Golgi and serum enzymes respectively. Although some differences in Km values were observed between the rat liver Golgi and serum enzymes, the values obtained suggest a high degree of similarity between the kinetic properties of the three galactosyltransferases.

Vanadate induces the recruitment of GLUT-4 glucose transporter to the plasma membrane of rat adipocytes.

In rat adipocytes, the insulin stimulation of the rate of glucose uptake is due, at least partially, to the recruitment of glucose transporter proteins from an intracellular compartment to the plasma membrane. Vanadate is a known insulin mimetic agent and causes an increase in the rate of glucose transport in rat adipocytes similar to that seen with insulin. The objective of the present study was to determine whether vanadate exerts its effect through the recruitment of glucose transporters to the plasma membrane. We report that under conditions where vanadate stimulates the rate of 2-deoxyglucose uptake to the same extent as insulin, the concentration of GLUT-4 in the plasma membrane was increased similarly by both insulin and vanadate, and its concentration was decreased in the low density microsomal fraction. These results suggest that vanadate induces the recruitment of GLUT-4 to the plasma membrane. The effects of vanadate and insulin on the stimulation of 2-deoxyglucose uptake and recruitment of GLUT-4 were not additive. This is the first report of an effect of vanadate on the intracellular distribution of the glucose transporter.

Mechanism of vanadate-induced activation of tyrosine phosphorylation and of the respiratory burst in HL60 cells. Role of reduced oxygen metabolites.

Vanadate induces phosphotyrosine accumulation and activates O2 consumption in permeabilized differentiated HL60 cells. NADPH, the substrate of the respiratory burst oxidase, was found to be necessary not only for the increased O2 consumption, but also for tyrosine phosphorylation. The effect of NADPH was not due to reduction of vanadate to vanadyl. Instead, NADPH was required for the synthesis of superoxide, which triggered the formation of peroxovanadyl [V(4+)-OO] and vanadyl hydroperoxide [V(4+)-OOH]. One or both of these species, rather than vanadate itself, appears to be responsible for phosphotyrosine accumulation and activation of the respiratory burst. Accordingly, the stimulatory effects of vanadate and NADPH were abrogated by superoxide dismutase. Moreover, phosphorylation was activated in the absence of NADPH by treatment with V(4+)-OO and/or V(4+)-OOH, generated by treatment of orthovanadate with KO2 or H2O2 respectively. The main source of the superoxide involved in the formation of V(4+)-OO and V(4+)-OOH is the NADPH oxidase. This was shown by the inhibitory effects of diphenylene iodonium and by the failure of undifferentiated cells, which lack oxidase activity, to undergo tyrosine phosphorylation when treated with vanadate and NADPH. By contrast, exogenously generated V(4+)-OO induced marked phosphorylation in the undifferentiated cells, demonstrating the presence of the appropriate tyrosine kinases and phosphatases. A good correlation was found to exist between induction of tyrosine phosphorylation and activation of the respiratory burst, suggesting a causal relationship. Therefore an amplification cycle appears to exist in cells treated with vanadate, whereby trace amounts of superoxide initiate the formation of V(4+)-OO and/or V(4+)-OOH. These peroxides promote phosphotyrosine formation, most likely by inhibition of tyrosine phosphatases. Accumulation of critical tyrosine-phosphorylated proteins then initiates a respiratory burst, with abundant production of superoxide. The newly formed superoxide catalyses the formation of additional V(4+)-OO and/or V(4+)-OOH, thereby magnifying the response. Since vanadium derivatives are ubiquitous in animal tissues, V(4+)-OO and/or V(4+)-OOH could be formed in vivo by reduced O2 metabolites, becoming potential endogenous tyrosine phosphatase inhibitors. Because of their potency, peroxides of vanadate may be useful as probes for the study of protein phosphotyrosine turnover.

Chloroquine inhibits glucose-transporter recruitment induced by insulin in rat adipocytes independently of its action on endomembrane pH.

In adipocytes, stimulation of glucose transport by insulin is mediated largely by translocation of the GLUT4 isoform of glucose transporters from an intracellular store to the plasma membrane. Most endomembrane compartments are endowed with H(+)-pumping ATPases, and the resulting luminal acidification is thought to play a role in vesicular traffic. Chloroquine (Clq), a permeant weak base, was used to test whether endomembrane pH is an important factor in GLUT4 translocation. Under conditions chosen to optimize Clq uptake, the weak base precluded insulin-induced GLUT4 translocation and the associated stimulation of glucose transport. Clq also effectively dissipated the delta pH of acidic endomembrane compartments, assessed fluorimetrically. To define whether the intracellular GLUT4 storage compartment is acidic, immunoadsorption and immunoblotting experiments were performed to determine whether glucose transporters and vacuolar-type H+ pumps coexist in the same membranes. Unexpectedly, H+ pumps were not detectable in vesicles bearing GLUT4. Moreover, dissipation of endomembrane delta pH by monensin failed to inhibit insulin-stimulated GLUT4 translocation and hexose transport. Finally, the inhibitory effect of Clq persisted in the presence of monensin. We conclude that GLUT4 resides in an intracellular compartment devoid of H+ pumps. The insertion of this compartment into the plasmalemma is not regulated by transmembrane pH gradients. Clq impairs the stimulation of glucose transport by blocking translocation of GLUT4 by a pH-independent mechanism. Clq may provide a useful tool to elucidate the signalling or fusion steps involved in insulin-induced GLUT4 translocation.

Branch specificity of purified rat liver Golgi UDP-galactose: N-acetylglucosamine beta-1,4-galactosyltransferase. Preferential transfer of of galactose on the GlcNAc beta 1,2-Man alpha 1,3-branch of a complex biantennary Asn-linked oligosaccharide.

In the final stages of the terminal glycosylation of N-linked complex oligosaccharides, UDP-galactose: N-acetylglucosamine beta-1,4-galactosyltransferase (galactosyltransferase) transfers galactose (Gal) onto the N-acetylglucosamine (GlcNAc) residue of each branch of a biantennary oligosaccharide. Purified rat liver Golgi galactosyltransferase was used with GlcNAc beta 1,2-Man alpha 1,6-(GlcNAc beta 1,2-Man alpha 1,3-)-Man beta 1,4-GlcNAc beta 1,4-(Fuc alpha 1,6-)-GlcNAc-Asn in order to determine the sequence of addition of Gal residues to the biantennary oligosaccharide. The different galactosylated products were separated by concanavalin A affinity chromatography and high voltage paper electrophoresis in borate. It was found that Gal was transferred at a much faster rate to the GlcNAc beta 1,2-Man alpha 1,3-branch than to the GlcNAc beta 1,2-Man alpha 1,6-branch, i.e. k1 was at least 5 times larger than k2. Also, k3 was larger than k4, indicating that most of the digalactosylated product "GG" was formed by the sequential addition of Gal to the Man alpha 1,3-branch followed by addition to the Man alpha 1,6-branch. The preferential galactosylation of the GlcNAc beta 1,2-Man alpha 1,3-branch may explain the formation of the asymmetrical oligosaccharides found in bovine and human IgG.

Activation of permeabilized HL60 cells by vanadate. Evidence for divergent signalling pathways.

The possible role of tyrosine phosphorylation in the activation of granulocytic HL60 cells was examined using vanadate, a phosphotyrosine phosphatase inhibitor. Treatment of permeabilized cells with micromolar concentrations of vanadate resulted in a substantial accumulation of tyrosine-phosphorylated proteins, detected by immunoblotting. At comparable concentrations, vanadate was also found to elicit an NADPH-dependent burst of oxygen utilization. Actin assembly, studied using 7-nitrobenz-2-oxa-1,3-diazole (NBD)-phallacidin, was similarly stimulated by vanadate, though considerably higher concentrations were required to observe this effect. In contrast with these responses, the secretion of lysozyme was not stimulated by vanadate, nor did vanadate affect calcium-induced secretion. Therefore, accumulation of tyrosine-phosphorylated proteins is associated with stimulation of some, but not all, of the responses characteristic of granulocytic cell activation. This indicates that the effects of vanadate are selective and suggests divergence of the signalling pathways leading to the individual effectors.

Components responsible for transport between successive Golgi cisternae are highly conserved in evolution.

Transport of a glycoprotein between compartments of the Golgi has been reconstituted in an in vitro system (Balch, W. E., Dunphy, W. G., Braell, W. A., and Rothman, J. E. (1984) Cell 39, 405-416). Cytosolic components and ATP are absolutely required for transport. Here, we have tested the acceptor activity of Golgi fractions and of cytosolic fractions prepared from a variety of organisms. All mammalian Golgi fractions can act as "acceptor" in the in vitro assay. Similarly, the cytosol fractions obtained from plants as well as animals and a lower eukaryote substitute for the homologous CHO cytosol normally used. Moreover, a cytosol subfraction prepared from wheat germ complements a different cytosolic fraction obtained from bovine brain. Apparently, the essential components involved in the post-translational protein transport are remarkably conserved between plants, animals, and lower eukaryotes.