Isolation of plasma membranes and Golgi apparatus from a single chicken liver homogenate

Chicken liver plasma membranes, minimally contaminated with Golgi apparatus-derived vesicles, were prepared from a low-speed (400 g) pellet by means of flotation in isotonic Percoll solution, followed by a hypotonic wash and flotation in a discontinuous sucrose gradient. Based on the analysis of suitable marker enzymes, alkaline phosphatase and alkaline phosphodiesterase, two plasma membrane fractions were isolated with enrichments, depending on the equilibrium density and marker of 28-97 and with a total yield of 4-5%. Golgi apparatus fractions were prepared by flotation of microsomes, obtained from the same homogenate as the low-speed pellet, in a discontinuous sucrose gradient. The trans-Golgi marker galactosyltransferase was 27-fold enriched in a fraction of intermediate density (d=1.077-1.116 g/ml). Approximately 12% of galactosyltransferase was recovered in the membranes equilibrating d=1.031-1.148 g/ml. Contamination with plasma membrane fragments was low in the light (d=1.031-1.077 g/ml) and intermediate density Golgi vesicles. The isolation of purified plasma membranes and Golgi vesicles from one liver homogenate will enable future studies on receptor cycling between these cell organelles.     

Localization of adenylate cyclase in Dictyostelium discoideum. I. Preparation and biochemical characterizations of cell fractions and isolated plasma membrane vesicles.

A difference in the organization of adenylate cyclase and 3′5′-cyclic phosphodiesterase in isolated plasma membranes was observed. Observation of this difference was made possible by the development of a new technique for the lysis of Dictyostelium discoideum using the polyene antibiotic amphotericin B. A particulate fraction prepared from the cell lysate contains adenylate cyclase, 3′5′-cyclic phosphodiesterase and 5′-nucleotidase. The yield of adenylate cyclase is 40% higher than in paniculate fractions prepared from cells lysed by sonication or with Triton X-100. Purification of the particulate fraction on discontinuous sucrose gradient completely separates membranes from mitochondria and other cellular material as shown by electron microscopic analysis of different fractions. Biochemical characterization of the purified membrane fraction shows it contains adenylate cyclase, 3′5′-cyclic phosphodiesterase and 5′-nucleotidase activities while electron microscopic analysis shows a vesicular morphology. Additional studies on the purified membranes used Triton X-100, trypsin and phospholipase C to probe the relationship between membrane structural elements and enzymatic activities. The results of these studies show distinct differences in the organization of each enzyme molecule within the membrane.     

Studies on isolated subcellular components of cat pancreas. I. Isolation and enzymatic characterization.

Pancreas of the cat was fractionated into its subcellular components by centrifugation through an exponential ficoll-sucrose density gradient in a zonal rotor. This enables a preparation of four fractions enriched in plasma membranes, endoplasmic reticulum, mitochondria and zymogen granules, respectively. The first fraction, enriched by 9- to 15-fold in the plasma membrane marker enzymes, hormone-stimulated adenylate cyclase, (Na+K+)-ATPase, and 5'-nucleotidase, is contaminated by membranes derived from endoplasmic reticulum but is virtually free from mitochondrial and zymogen-granule contamination. The second fraction from the zonal gradient shows only moderate enrichment of the above marker enzymes but contains a considerable quantity of plasma membrane marker enzymes and represents mostly rough endoplasmic reticulum. The third fraction contains the bulk of mitochondria and the fourth mainly zymogen granules as assessed by electron microscopy and marker enzymes for both mitochondria and zymogen granules, namely succinic dehydrogenase, trypsin and amylase. Further purification of the plasma membrane fractions by differential and sucrose step-gradient centrifugation yields plasma membranes enriched 40-fold in basal and hormone-stimulated adenylate cyclase and (Na+K+)-ATPase.     

Isolation and characterization of a liver plasma membrane fraction enriched in glucagon-sensitive adenylate cyclase

Partially purified liver plasma membranes were fractionated further on sucrose layers. Three membrane populations, numbered Peaks 1, 2 and 3, were isolated at densities of 1.23, 1.16, and 1.03, respectively. Peaks 1 and 2 were enriched to a similar degree in 5′-nucleotidase activity, a plasma membrane marker, relative to membranes in Peak 3. Electron micrographs indicated that Peak 1 possessed desmosomes and bile canaliculi, while Peak 2 contained large vesicles as well as smaller vesicular structures attached to membranes. The latter have been attributed to hepatocyte sinusoidal surfaces. All three membrane fractions contained adenylate cyclase activity with the highest specific activity found in Peak 2. The enzyme in all three peaks was F sensitive with higher sensitivity in Peaks 1 and 2. Glucagon sensitivity of adenylate cyclase in Peak 2 membranes was four times that of Peak 1. Only Peak 2 membranes were sensitive to epinephrine. The Peak 2 membranes were three times more sensitive to glucagon than the partially purified membranes from which they were derived. These findings indicate that, while both bile canalicular and sinusoidal faces of hepatocytes possess adenylate cyclase, the sinusoidal fraction is more sensitive to glucagon. Solubilized adenylate cyclase of the Peak 2 membranes, obtained as the 165,000g supernate of membranes treated with Lubrol-PX, was sensitive to stimulation by guanyl nucleotide analogs. Guanyl nucleotide sensitivity thus resides in the catalytic site and is not dependent on membrane integrity. All three membrane fractions possessed similar activities of nucleotide phosphohydrolase activity.     

Refractoriness of ovarian adenylate cyclase to continued hormonal stimulation.

Culture of preovulatory rat follicles with luteinizing hormone, follicle-stimulating hormone or prostaglandin E2 for 24 h reduced the subsequent response of adenylate cyclase to the homologous by 80, 50 and 90%, respectively; yet follicles refractory to luteinizing hormone fully responded to follicle-stimulating hormone responded to luteinizing hormone and prostaglandin E2, and those refractory to prostaglandin E2 could be stimulated by either gonadotropin. Desensitization of the adenylate cyclase system by luteinizing hormone was achieved by hormone concentrations of 0.8--2.0 mug/ml in the medium; a lower dose of luteinizing hormone (0.4 mug/ml), though effective in stimulating adenylate cyclase, did not induce refractoriness. Prostaglandin E2 caused partial refractoriness at dose levels of 0.1--0.25 mug/ml; higher dose levels were more effective. These findings suggest that continued exposure to the preovulatory follicle to elevated levels of hormones may cause perturbations in either the interaction between the hormone and its specific receptor or in a subsequent step essential for activation of adenylate cyclase.     

Association of sequestered beta-adrenergic receptors with the plasma membrane: a novel mechanism for receptor down regulation

Chronic exposure of frog erythrocytes to beta-adrenergic agonists leads to desensitization of the responsiveness of adenylate cyclase to isoproterenol and is accompanied by "down-regulation", a decrease in the number of beta-adrenergic receptors on the cell surface. When frog erythrocyte plasma membranes are prepared by osmotic lysis of cells, the receptors lost from the cell surface during desensitization can be recovered in a "light membrane fraction", obtained by centrifuging the cell cytosol at 158,000 X g for 1 hr. These receptors are sequestered away from the plasma membrane fraction which contains the adenylate cyclase and the guanine nucleotide regulatory protein. If desensitized frog erythrocytes are disrupted by gentler freeze/thaw procedures, however, the sequestered beta-adrenergic receptors can be demonstrated to be physically associated with the plasma membrane. Typically, plasma membranes prepared in this fashion do not demonstrate a significant down regulation despite attenuation of isoproterenol-stimulated adenylate cyclase activity. Under these conditions, beta-adrenergic receptors from control and desensitized preparations co-migrate on sucrose density gradients in exactly the same place as the plasma membrane marker, adenylate cyclase. In contrast, when membranes from osmotically lysed desensitized cells are fractionated on sucrose gradients the down regulated receptors are sequestered in a light membrane fraction which barely enters the gradient and which is physically separated from adenylate cyclase activity. The data are consistent with a novel mechanism of receptor down-regulation which appears to involve the sequestration of the beta-adrenergic receptors away from the cell surface into a membrane compartment which remains physically associated with the plasma membrane.     

Distribution of parathyroid hormone-stimulated adenylate cyclase in plasma membranes of cells of the kidney cortex.

Free flow electrophoresis was employed to separate renal cortical plasma membranes into luminal (brush border microvilli) and contraluminal (basal-lateral membrane) fractions. During the separation adenylate cyclase activity was found to parallel the activity of Na+-K+-activated ATPase, an enzyme which is present in contraluminal but not in luminal membranes. In the basal-lateral membrane fraction the specific activities of adenylate cyclase and Na+-K+-activated ATPase were 4.4 and 4.6 times greater, respectively, than in the brush border fraction. The adenylate cyclase of the basal-lateral membrane fraction was specifically stimulated by parathyroid hormone which maximally increased enzyme activity eightfold. The biologically active (1-34) peptide fragment of paratyhroid hormone produced a 350% increase in adenylate cyclase activity. In contrast, calcitonin, epinephrine and vasopressin maximally stimulated the enzyme by only 55, 35 and 30%, respectively. These results indicate that adenylate cyclase, specifically stimulated by parathyroid hormone, is distributed preferentially in the contraluminal region of the plasma membrane of renal cortical epithelial cells.     

Partial purification and characterization of oestrogen receptors in subfractions of hepatocyte plasma membranes

To assess the subcellular distribution of oestrogen-binding components in their native state, plasma membrane and other cell fractions were prepared from hepatocytes in the absence of [³H]oestradiol-17β. Cells from livers of ovariectomized rats were disrupted, with submaximal homogenization in buffered isotonic sucrose with CaCl₂ and proteinase inhibitor, and fractionated by using isotonic media. Fractions were characterized by determinations of enzyme activities, biochemical constituents and ligand binding. Specific binding of 2nm-[³H]oestradiol-17β to intact cells and their fractions was detemined after equilibration for 1.5h at 4°C. More than 92% of the radioactivity from representative preparations was verified as authentic oestradiol by thin-layer chromatography. Activities of plasma-membrane marker enzymes as well as binding sites for oestrogen and for wheat germ agglutinin were present principally in particulate fractions, rather than in 105000g-supernatant fractions. However, by using alternative homogenization procedures (i.e. hypotonic media), known to fragment and strip structural components, oestradiol-binding sites and activities of plasma-membrane marker enzymes were distributed predominantly into cytosol. By using the more conservative procedures, plasma membranes of low (ρ=1.13–1.16) and high (ρ=1.16–1.18) density were purified from crude nuclear fractions. A second low-density subfraction of plasma membrane was prepared from microsome-rich fractions. Activities of plasma-membrane marker enzymes were enriched to about 28 and four times that of the homogenate in plasma membranes of low and high density respectively. Binding sites for wheat germ agglutinin and oestradiol were concentrated in low-density plasma membranes to 46–63 times that of the homogenate. Specific binding of oestrogen in low-density plasma membranes purified from crude nuclei was saturable, with an apparent association constant of 3.5nm. At saturation, such oestradiol receptors corresponded to 526fmol/mg of membrane protein. A Hill plot showed a moderate degree of positive co-operativity in the interaction of hormone with plasma membranes. Specific binding of [³H]oestradiol-17β was reduced by a 200-fold molar excess of unlabelled oestradiol-17β, oestriol or diethylstilbestrol, but not by oestradiol-17α, cortisol, testosterone or progesterone. Binding was also blocked by prior exposure of membranes to trypsin or to 60°C, but remained essentially undiminished by extraction of membranes with either hypotonic or high-salt buffers. Extraction with 0.1% (v/v) Triton X-100 partially solubilized the oestrogen-binding component(s) of plasma membranes. Particle-free extracts were resolved on 5–20% (w/v) sucrose density gradients with either 0.01m- or 0.4m-KCl, and the fractions were analysed by adsorption to hydroxyapatite. In low-salt gradients macromolecule-bound oestrogen sedimented at predominantly 7.4S and binding was 1560 times that of the homogenate. Under high-salt conditions oestradiol-binding activity occurred at both 3.6S and 4.9S.     

Isolation of plasma membranes from rat lungs. Effect of age on the subcellular distribution of adenylate cyclase activity

A simple and rapid method of isolating plasma membranes from rat lungs is described. The method involves homogenization of tissue in isotonic sucrose-buffered medium followed by differential and sucrose density gradient centrifugation. Plasma membranes obtained by this procedure were essentially free from other subcellular contamination. Plasma membranes isolated from 2-day-old rat lungs showed 6 to 7-fold purification of adenylate cyclase and 5′-nucleotidase activities compared to the original homogenate In contrast, plasma membranes from 35-day-old rat lungs showed no purification of adenylate cyclase activity although 5′-nucleotidase activity showed similar enrichment. These results suggest that adenylate cyclase activity is not a reliable marker for plasma membranes from adult rat lungs.     

Isolation of plasma membranes from rat lungs: effect of age on the subcellular distribution of adenylate cyclase activity

A simple and rapid method of isolating plasma membranes from rat lungs is described. The method involves homogenization of tissue in isotonic sucrose-buffered medium followed by differential and sucrose density gradient centrifugation. Plasma membranes obtained by this procedure were essentially free from other subcellular contamination. Plasma membranes isolated from 2-day-old rat lungs showed 6 to 7-fold purification of adenylate cyclase and 5'-nucleotidase activities compared to the original homogenate. In contrast, plasma membranes from 35-day-old rat lungs showed no purification of adenylate cyclase activity although 5'-nucleotidase activity showed similar enrichment. These results suggest that adenylate cyclase activity is not a reliable marker for plasma membranes from adult rat lungs.     

Studies on isolated subcellular components of cat pancreas

Summary Pancreas of the cat was fractionated into its subcellular components by centrifugation through an exponential ficoll-sucrose density gradient in a zonal rotor. This enables a preparation of four fractions enriched in plasma membranes, endoplasmic reticulum, mitochondria and zymogen granules, respectively. The first fraction, enriched by 9- to 15-fold in the plasma membrane marker enzymes, hormone-stimulated adenylate cyclase, (Na⁺K⁺)-ATPase, and 5-nucleotidase, is contaminated by membranes derived from endoplasmic reticulum but is virtually free from mitochondrial and zymogen-granule contamination. The second fraction from the zonal gradient shows only moderate enrichment of the above marker enzymes but contains a considerable quantity of plasma membrane marker enzymes and represents mostly rough endoplasmic reticulum. The third fraction contains the bulk of mitochondria and the fourth mainly zymogen granules as assessed by electron microscopy and marker enzymes for both mitochondria and zymogen granules, namely succinic dehydrogenase, trypsin and amylase. Further purification of the plasma membrane fractions by differential and sucrose step-gradient centrifugation yields plasma membrane enriched 40-fold in basal and hormone-stimulated adenylate cyclase and (Na⁺K⁺)-ATPase.     

β-adrenergic receptors and enzymes in rat myocardial membranes: implications of fractionation procedures andβ-adrenoceptor antagonists

1. We performed an enzymatic characterization of two different fractionation procedures of ventricles from rat hearts. The enzymatic assays covered succinic dehydrogenase as a marker for inner mitochondrial membranes, monoamine oxidase as a marker for outer mitochondrial membranes, NADPH-cytochrome c reductase and RNA as endoplasmatic reticular markers, acid phosphatase as a lysosomal marker, and lactic dehydrogenase as a marker for the "soluble" compartment; DNA was estimated for nuclear contamination. 2. The plasma membrane markers 5'-nucleotidase, Ca2+-ATPase, Mg2+-ATPase, Na+-K+-ATPase, and adenylate cyclase were determined. 3. The roughly prepared membrane fractions showed increased yields of the membrane markers; the number of beta receptors, determined with (-)-[3H] dihydroalprenolol and DL-propranolol, amounted to 68 +/- 6 fmol/mg protein (KD = 3390 +/- 450 pmol, Hill coefficient = 1.5). 4. The membrane fraction prepared with a linear sucrose gradient showed an increased inner mitochondrial membrane marker; presumably the outer mitochondrial membrane was stripped off. The beta-receptor number was 39 +/- 3 fmol/mg protein (KD = 6250 +/- 300 pmol; Hill coefficient = 1.2).     

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.     

Proteolytic activation of rat liver adenylate cyclase by a contaminant of crude collagenase from Clostridium histolyticum.

Treatment of rat liver plasma membranes with various commercial preparations of crude collagenase from Clostridium histolyticum at concentrations as low as 1 mug/ml, resulted in activation of the adenylate cyclase system. Maximal activation occurred at 50 to 100 mug/ml of collagenase, and promoted a 2- to 3-fold increase in the basal activity as well as in the activities stimulated by catecholamines, glucagon, fluoride, or GTP. This was due to an increase in the maximal velocity of the cyclizing reaction without any increase in the affinity of the enzyme for its substrate. Treatment of plasma membranes with crude collagenase did not induce gross structural modifications as judged by electron microscopic examination. 5'-Nucleotidase activity was slightly inhibited and ATPase activity remained unaffected. The stimulatory substance was nondialyzable, thermolabile, and inhibited by both EDTA and -SH reagents, thus appearing to be a protein. The following observations suggest the effects observed were due to other protease(s) present in crude collagenase: (a) only crude collagenase was active on liver adenylate cyclase: treatment with purified collagenase from C. histolyticum or from Achromobacter iophagus gave no stimulation; (b) the stimulatory activity was irreversible since washing of the membranes after treatment was without effect; (c) crude collagenase contained no lecithinase or sphingomyelinase activity under our conditions of adenylate cyclase assay; (d) after chromatography on Sephadex G-100, the activator appeared as a peak in the 30,000-dalton region and was clearly separated from the collagenase and clostripain peaks, but coincident with elastolytic and caseinolytic activities; (e) the effect of crude collagenase could be prevented by addition of elastin in vitro and was mimicked by purified elastase from hog pancreas. It remains to be seen whether the effects observed result from an increase in the catalytic constant of adenylate cyclase, or an unmasking of new catalytic sites.     

Subcellular localization of adenylate cyclase of buffalo spermatozoa

The intracellular localization of adenylate cyclase and 3',5'-cyclic nucleotide phosphodiesterase in buffalo sperm was examined. Adenylate cyclase activity is distributed in heads (8.4%), midpieces (16.6%), tails (49.5%) and 5.7% in the soluble supernatant; the total recovery being 81%. A 4-fold increase in specific activity was observed in the tail fraction relative to sonicated suspension. Further fractionation of the tail fraction into plasma membrane and microtubules by dialysis against low ionic strength buffer was followed by marker enzymes (Mg2+ -ATPase, 5'-nucleotidase and alkaline phosphatase) as well as by examination of fractions under electron microscope. The recovered adenylate cyclase (79%) was found in microtubules (45%) and plasma membrane (34%). Cyclic nucleotide phosphodiesterase in tails was distributed in tail plasma membrane (13.7%), microtubules (31.5%) and cytosol (34%) with a total recovery of 80%. Similar results were obtained when the distribution of adenylate cyclase and cyclic nucleotide phosphodiesterase was studied by treatment with Triton X-100; 40% activity of adenylate cyclase present in tails (about 20% relative to sperm sonicate) appeared in the soluble form by this method. The results are discussed in relation to control of cyclic AMP levels in buffalo sperm by adenylate cyclase and cyclic nucleotide phosphodiesterase.     

Activation of adenylate cyclase in renal medulla by bovine growth hormone. An artifact attributable to vasopressin.

The effect of bovine growth hormone on adenylate cyclase activity was studied in bovine and rat renal medulla. Highly purified growth hormone (lot B1003A) increased adenylate cyclase activity in plasma membranes from bovine renal medulla from 132+/-6 pmol cyclic AMP formed/mg protein per 10 min to 364+/-10 pmol cyclic AMP formed/mg protein per 10 min. Similar results were seen with homogenates of rat renal medulla. The minimum effective concentration of bovine growth hormone required to activate adenylate cyclase was 0.5 mug/ml and maximum activation was detected at 500 mug/ml. The amount of vasopressin determined by radioimmunoassay to contaminate the growth hormone caused an increase in adenylate cyclase activity comparable to that of the corresponding concentration of growth hormone that was tested. Dialysis of growth hormone and vasopressin resulted in parallel reductions in the effect of each hormone on adenylate cyclase activity. Similarly, both growth hormone and vasopressin produced increases in short circuit current in isolated toad bladders but these effects were not detectable after dialysis of the hormones. In contrast, the effect of growth hormone on the uptake of 35SO2-4 by cartilage from hypophysectomized rats was not decreased after dialysis. These results indicate that available preparations of growth hormone are contaminated by small but physiologically significant amounts of vasopressin and that the activation of adenylate cyclase activity in renal medulla in response to growth hormone can be explained by this contamination rather than by an effect of growth hormone per se.     

The purification and characterization of plasma membranes and the subcellular distribution of adenylate cyclase in mouse parotid gland.

1. Plasma membranes have been purified 17-fold from mouse parotid gland homogenates prepared in hypertonic sucrose media using differential centrifugation. The method is fast and simple. The membranes were characterised by electron microscopy, enzyme composition and chemical composition. Further purification was achieved by isopycnic centrifugation in discontinuous sucrose gradients. 2. The purified membranes contain an adenylate cyclase activity which is stimulated by isoproterenol and fluoride. Only 50% of the total adenylate cyclase activity sedimented in the plasma membrane fraction. The rest of the activity resided in the crude nuclear and mitochondrial pellets. However, this adenylate cyclase activity was not associated with these organelles but with membrane fragments in the pellets. Purified nuclei did not contain adenylate cyclase activity. 3. Adenylate cyclase activity was also localised by electron microscopic cytochemistry. Besides being found at the plasma membrane, large amounts of adenylate cyclase were found in a small proportion of the vesicles within the acinar cells, which appeared to be secondary lysosomes. 4. Adenylate cyclase activities, under standard assay conditions, are proportional to the time of incubation and the concentration of enzyme. The enzyme requires both Mg-2+ and CA-2+ for activity. Isoproterenol increased activity 2-fold and this increase is abolished by beta-adrenergic blocking agents.     

Subfractionation of rat liver plasma membrane. Uneven distribution of plasma membrane-bound enzymes on the liver cell surface.

Plasma membranes were isolated from rat liver mainly under isotonic conditions. As marker enzymes for the plasma membrane, 5'-nucleotidase and (Na+ + K+)-ATPase were used. The yield of plasma membrane was 0.6-0.9 mg protein per g wet weight of liver. The recovery of 5'-nucleotidase and (Na+ +K+)-ATPase activity was 18 and 48% of the total activity of the whole-liver homogenate, respectively. Judged from the activity of glucose-6-phosphatase and succinate dehydrogenase in the plasma membrane, and from the electron microscopic observation of it, the contamination by microsomes and mitochondria was very low. A further homogenization of the plasma membrane yielded two fractions, the light and heavy fractions, in a discontinuous sucrose gradient centrifugation. The light fraction showed higher specific activities of 5'-nucleotidase, alkaline phosphatase, (Na+ +K+)-ATPase and Mg2+-ATPase, whereas the heavy one showed a higher specific activity of adenylate cyclase. Ligation of the bile duct for 48 h decreased the specific activities of (Na2+ +K+)-ATPase and Mg2+-ATPase in the light fraction, whereas it had no significant influence on the activities of these enzymes in the heavy fraction. The specific activity of alkaline phosphate was elevated in both fractions by the obstruction of the bile flow. Electron microscopy on sections of the plasma membrane subfractions showed that the light fraction consisted of vesicles of various sizes and that the heavy fractions contained membrane sheets and paired membrane strips connected by junctional complexes, as well as vesicles. The origin of these two fractions is discussed and it is suggested that the light fraction was derived from the bile front of the liver cell surface and the heavy one contained the blood front and the lateral surface of it.     

Adenylate cyclase from rabbit small intestine: activation by cholera toxin and interaction with calcium

The stimulation of adenylate cyclase in various fractions of plasma membranes from rabbit small intestinal epithelium has been studied. In crude plasma membranes cholera toxin activated 5-fold at 10 micrograms/ml; vasoactive intestinal peptide (VIP) activated at concentration from 10(-8) to 10(-7) M, the maximal stimulation being 6-fold. Fluoride activated 10-fold at 10 mM. VIP-stimulated enzyme was inhibited by Ca2+ concentrations in the micromolar range. In the presence of calmodulin a biphasic response was obtained. At low Ca2+ concentration (4 x 10(-9)-6 x 10(-8) M) the enzyme was activated. As the Ca2+ concentration was increased the enzyme was concomitantly inhibited. We have investigated the mechanism by which cholera toxin activates intestinal adenylate cyclase. We have found that cholera toxin catalyzed incorporation of 32P into proteins located in the brush-border membrane whose molecular weights are in the range of 40-45kDa. These membranes bind [3H]GTP with a Kd of 1.8 x 10(-7) M. In contrast, basal lateral membranes do not contain any protein which becomes labeled in a toxin-dependent manner when incubated with cholera toxin and [32P]NAD. The modification of brush-border membrane protein occurred in spite of the absence of adenylate cyclase in these membranes. Adenylate cyclase in basal lateral membranes was poorly activated by cholera toxin as compared to crude plasma membranes. On the other hand, the ability of VIP and fluoride to activate the enzyme was enhanced in basal lateral membranes with respect to crude membranes. The results are discussed in relation to the mechanism by which cholera toxin activates adenylate cyclase in intact intestinal cells.     

Characterization and subcellular localization of nucleotide cyclases in calf thymus lymphocytes

The role of cyclic nucleotides in the regulation of lymphocyte growth and differentiation remains controversial, as an adequate characterization of the key enzymes, adenylate cyclase and guanylate cyclase, in the plasma membrane of lymphocytes is still lacking. In this study, calf thymus lymphocytes were disrupted by nitrogen cavitation and various cellular fractions were isolated by differential centrifugation and subsequent sucrose density ultracentrifugation. As revealed by the chemical composition and the activities of some marker enzymes, the plasma membrane fraction proved to be highly purified. Nucleotide cyclases were present in the plasma membranes in high specific activities, basal activities of adenylate cyclase being 13.7 pmol/mg protein per min and 34.0 pmol/mg protein per min for the guanylate cyclase, respectively. Adenylate cyclase could be stimulated by various effectors added directly to the enzyme assay, including NaF, GTP, 5'-guanylyl imidodiphosphate, Mn2+ and molybdate. Addition of beta-adrenergic agonists only showed small stimulating effects on the enzyme activity in isolated plasma membranes. Basal activity of adenylate cyclase as well as activities stimulated by NaF or 5'-guanylyl imidodiphosphate exhibited regular Michaelis-Menten kinetics. Activation by both agents only marginally affected the Km values, but largely increased Vmax. The activity of the plasma membrane-bound guanylate cyclase was about 10-fold enhanced by the nonionic detergent Triton X-100 and high concentrations of lysophosphatidylcholine, but was slightly decreased upon addition of the alpha-cholinergic agonist carbachol. Basal guanylate cyclase indicated to be an allosteric enzyme, as analyzed by the Hill equation with an apparent Hill coefficient close to 2. In contrast, Triton X-100 solubilized enzyme showed regular substrate kinetics with increasing Vmax but unaffected Km values. Thus the lymphocyte plasma membrane contains both adenylate cyclase and guanylate cyclase at high specific activities, with properties characteristic for hormonally stimulated enzymes.