Effects of guanine nucleotides on cholera toxin catalyzed ADP-ribosylation in rat adipocyte plasma membranes

ADP-ribosylation of rat adipocyte plasma membrane proteins was investigated following incubation of membranes with [alpha-32P]NAD and cholera toxin in the presence and absence of various guanine nucleotides. In membranes incubated without guanine nucleotides, cholera toxin induced incorporation of 32P into three discrete proteins of 48, 45, and 41 kDa. In membranes containing 100 microM GTP or GDP, toxin-catalyzed incorporation of 32P into the 41-kDa protein was inhibited. GMP and Gpp(NH)p (100 microM) allowed moderate incorporation of 32P into the 41-kDa protein. Toxin-catalyzed labeling of all proteins was rapid, reaching maximal levels between 5 and 10 min. Toxin-catalyzed ADP-ribosylation of the 48- and 45-kDa proteins was stimulated by GTP, reaching maximal levels at 10(-5) M GTP. Inhibition of toxin-dependent labeling of the 41-kDa protein required GTP concentrations above 10(-7) M with complete inhibition occurring between 10(-5) and 10(-4) M GTP. Cholera toxin catalyzed ADP-ribosylation was increased up to 2-fold in membranes supplemented with adipocyte cytosol. These results indicate that cholera toxin catalyzes ADP-ribosylation of three distinct adipocyte plasma membrane proteins, each of which is regulated by the amount and type of added guanine nucleotides.     

Activation of rat liver adenylate cyclase by cholera toxin requires toxin internalization and processing in endosomes

Involvement of acidic cell compartments in processing and action of cholera toxin (CT) in rat liver has been examined using subcellular fractionation. Liver cell fractions prepared various times after CT injection display, after a lag phase, a progressive increase in adenylate cyclase activity, detectable earlier in Golgi-endosomal fractions (20 min) than in plasma membrane fractions (30 min), with a maximum (3-fold basal activity) achieved by 60-90 min. Endosomes containing in vivo internalized CT display a time-dependent increase in their ability to bind anti-A-subunit antibodies and to stimulate exogenous adenylate cyclase, which kinetically parallels the generation of A1 peptide, suggesting a translocation of A-subunit (or A1 peptide) across the endosomal membrane. In vivo chloroquine treatment inhibits endocytosis of CT taken up into the liver, lengthens the lag phase for adenylate cyclase activation by CT, and reduces by 3- to 10-fold the apparent affinity of the toxin for the enzyme. Incubation of endosomes containing internalized toxin at 37 degrees C under isotonic conditions results in a pH-dependent increase in generation of A1 peptide, membrane translocation of A-subunit (or A1 peptide), and degradation of toxin, with a maximum at pH 5. Addition of ATP, by decreasing the internal endosomal pH, stimulates both generation of the A1 peptide and degradation of toxin at pH 6-8. It is concluded that activation of adenylate cyclase by CT in intact liver requires association and subsequent processing of toxin in an acidic cell compartment, presumably endosomal.     

Activation by cholera toxin of adenylate cyclase solubilized from rat liver.

Cholera toxin, or peptide A1 from the toxin, activates adenylate cyclase solubilized from rat liver with Lubrol PX, provided that cell sap, NAD+, ATP and thiol-group-containing compounds are present. The activation is abolished by antisera to whole toxin, but not to subunit B.     

High-resolution FRET microscopy of cholera toxin B-subunit and GPI-anchored proteins in cell plasma membranes

"Lipid rafts" enriched in glycosphingolipids (GSL), GPI-anchored proteins, and cholesterol have been proposed as functional microdomains in cell membranes. However, evidence supporting their existence has been indirect and controversial. In the past year, two studies used fluorescence resonance energy transfer (FRET) microscopy to probe for the presence of lipid rafts; rafts here would be defined as membrane domains containing clustered GPI-anchored proteins at the cell surface. The results of these studies, each based on a single protein, gave conflicting views of rafts. To address the source of this discrepancy, we have now used FRET to study three different GPI-anchored proteins and a GSL endogenous to several different cell types. FRET was detected between molecules of the GSL GM1 labeled with cholera toxin B-subunit and between antibody-labeled GPI-anchored proteins, showing these raft markers are in submicrometer proximity in the plasma membrane. However, in most cases FRET correlated with the surface density of the lipid raft marker, a result inconsistent with significant clustering in microdomains. We conclude that in the plasma membrane, lipid rafts either exist only as transiently stabilized structures or, if stable, comprise at most a minor fraction of the cell surface.     

NADP improves the efficiency of cholera toxin catalyzed ADP-ribosylation in liver and heart membranes

Guanine nucleotide binding proteins (G-proteins) can be identified by their ability to be ADP-ribosylated using [32P]NAD as the substrate and bacterial toxins as catalysts. This labelling, when performed in liver and sarcolemma membrane preparations, can be complicated by competing enzymes which degrade NAD, making it unavailable to participate in the desired reaction. The addition of NADP in reaction mixtures markedly slows the degradation of NAD, but does not compete with NAD in cholera toxin labelling of stimulatory G-protein. The efficiency of cholera toxin labelling is improved to the extent that saturation curves may be constructed, allowing the quantitation of ADP-ribosylation sites in membranes.     

Covalent labeling of neurotensin receptors in rat gastric fundus plasma membranes

Neurotensin receptors from plasma membranes of rat gastric fundus smooth muscle were specifically and covalently labeled either by using the photoreactive analogue ¹²⁵I-labeled azidobenzoyl (Trp¹¹)-neurotensin or by cross-linking (monoiodo-Tyr³)neurotensin to the membrane preparation by means of disuccinimidyl suberate. Analysis of plasma membranes by sodium dodecylsulfate-polyacrylamide gel electrophoresis and autoradiography revealed that the same protein band with an apparent molecular weight of 110,000 was specifically labeled by both methods. This band consisted of a single chain protein since its apparent size was found to be the same with or without reduction of membrane samples before electrophoresis. Only neurotensin and its biologically active analogues were able to protect plasma membranes against specific labeling of the protein band of molecular weight 110,000. Comparison of these results with those obtained from rat brain synaptic membranes shows that although rat central and peripheral neurotensin receptors exhibit similar specificities towards a series of neurotensin analogues, their subunit structures are different.     

Modulation of gamma-glutamyltranspeptidase activity in rat liver plasma membranes by thyroid hormone

1. In adult male and female rats, liver plasma membrane gamma-glutamyltranspeptidase activities were 16-fold higher in the propylthiouracil (PTU)-induced hypothyroid state than in the control euthyroid state; thyroxine (T4)-replacement resulted in an 80% restoration to control levels. 2. Liver plasma membrane gamma-glutamyltranspeptidase activities were 6.7-fold higher in PTU-induced congenitally hypothyroid rats than in control euthyroid rats; T4-replacement reduced enzyme activities to 37% of control levels. 3. In adult rats, in response to the development and recovery from tri-iodothyronine (T3) excess, liver plasma membrane gamma-glutamyltranspeptidase activities were inversely related to, and out of phase by 12 hr, to the earlier changes in T3. 4. Liver gamma-glutamyltranspeptidase is a thyroid hormone-dependent enzyme.     

Fluorescence anisotropy from diphenylhexatriene in rat liver plasma membranes

Rat livers were fractionated to obtain intracellular membrane preparations and a highly purified preparation of bile canaliculi. The fraction containing bile canaliculi was homogenized and subfractionated to give fractions representing fragments of contiguous membrane and of canalicular microvilli. The relative purity and extent of contamination of each preparation was determined. When the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene was incorporated into aliquots of each fraction at the same probe: lipid ratio and the steady-state anisotropy of its fluorescence measured, it was found that the plasma membrane preparations were much more ordered than the intracellular membrane preparations. Of the plasma membrane preparations, that containing the canalicular microvilli was the most ordered, even allowing for any contribution of contaminants. Thus the microvillus membrane of the bile canaliculus appears to be the most ordered domain of the plasma membrane of the hepatocyte. The high order in this domain may be a factor in reducing the susceptibility to bile salt damage during bile secretion, since it is this region which is exposed to high concentrations of bile salts in vivo.     

Neurotensin receptors on the rat liver plasma membranes

Neurotensin (NT) is now classified as a brain-gut peptide in the central nervous system and gastrointestinal tract. In the present study, we characterized the NT receptors on the rat liver plasma membranes. The specific binding of [3H]NT was time dependent, reversible, and saturable. Scatchard analysis of the specific binding data yielded two classes of binding sites, a high affinity site and a low affinity site. The average maximum number of binding sites (Bmax) amounted to 13.3 +/- 1.1 fmol/mg protein at high affinity site and 122.3 +/- 21.5 fmol/mg protein at low affinity site, respectively. The dissociation constant (Kd) had values of 0.39 +/- 0.01 nM at high affinity site and 8.1 +/- 1.1 nM at low affinity site, respectively. The amount of specifically bound [3H]NT was significantly reduced in the presence of mono and divalent cations, EDTA, EGTA and a peptidase inhibitor bacitracin, NT1-13 competed with [3H]NT for its binding site with an IC50 of 0.19 nM at high affinity site (0.2 nM concentration of [3H]NT) and 0.7 nM at low affinity site (4.0 nM concentration of [3H]NT). Xenopsin, a NT analogue separated from the skin of Xenopus laevis, was equipotent (IC50 0.75 nM) with NT1-13 at 4.0 nM concentration of [3H]NT. C-terminal sequence of NT contains the structure necessary for interaction with NT binding sites whereas N-terminal sequence had no binding activity. Since NT has a hyperglysemic and a hypercholesterolemic effects in rats, these NT receptors on the rat liver plasma membranes may be involved in the hyperglycemia and/or hypercholesteroremia induced by NT.     

Characterization by photoaffinity labeling of a steroid binding protein in rat liver plasma membrane

Summary The mechanism of steroid uptake by the cell remains controversial. [³H]R5020 was utilized to characterize by photoaffinity labeling the steroid binding site in plasma membrane. This binding was saturable, reversible and had one type of binding site (K _d = 33 ± 4 nm, B _max = 32 ± 2 pmol/mg). [³H]R5020 could be prevented from binding by a variety of steroids (cortisol, progesterone, deoxycorticosterone, and levonorgestrel); estradiol did not have affinity for this binding site. The kinetics of R5020 photoactivation was time dependent and saturable. SDS-PAGE showed a specific band which corresponded to a 53-kDa peptide. The sucrose density gradient analysis has revealed the existence of a protein with a sedimentation coefficient of 3.6 ± 0.2 S. This polypeptide shows different characteristics than cytosolic steroid receptor or serum steroid binding proteins. This binding protein could correspond to the steroid binding site previously found in the plasma membrane.This work was supported by grants PB85-0461 from the Comisión Asesora de Investigatión Científica y Técnica and PGV-8612 from the Departamento de Educatión, Universidades e Investigation del Gobierno Vasco. We thank Roussel-Uclaf (France) for the nonradioactive RU-steroids kindly provided.     

Glycosyltransferases with endogenous acceptor activity in plasma membranes isolated from rat liver

Plasma membrane fractions from rat liver exhibited glycosyltransferase activity with endogenous membrane-associated acceptors and either UDP-galactose, UDPglucose, UDP-N-acetylglucosamine, or GDPmannose donors. Of these, incorporation into non-lipid acceptors was most active with UDP-galactose and only with UDPgalactose and UDPmannose was there incorporation into endogenous lipid acceptors. CMP-N-acetylneuraminic acid was inactive as a donor with the isolated plasma membranes. In order to demonstrate transferase activity, low concentrations of substrate sugar nucleotides and short incubation times were used as well as sulfhydryl protectants and a phosphatase inhibitor (NaF) in the reaction mixtures. The findings support the concept of surface localization of at least a galactosyl transferase in cells of rat liver.