Isolation of plasma membranes from bovine corpus luteum possessing adenylate cyclase, 125I-hCG binding and NaK-ATPase activities

Plasma membranes from bovine corpora lutea have been purified by sucrose density gradient centrifugation. The purified membranes, in addition to binding ¹²⁵I-hCG, also possess hCG-stimulated adenylate cyclase and NaK-ATPase. The relative purification of ¹²⁵I-hCG binding, adenylate cyclase and NaK-ATPase on the basis of the specific activities in the whole homogenate were 7.8, 6.4 and 2.6, respectively. The presence of both the hormone sensitive adenylate cyclase and ¹²⁵I-hCG binding activities suggest that these plasma membranes might possess the ‘receptor’ for gonadotropin.     

Regulation of adenylate cyclase by adenosine and other agonists in rat myocardial sarcolemma

The presence of adenosine receptors coupled to adenylate cyclase in rat heart sarcolemma is demonstrated in these studies. Heart sarcolemma was isolated by the hypotonic shock-Lithium bromide treatment method. This preparation contained negligible amounts (2-4%) of contamination by other subcellular organelles such as mitochondria, sarcoplasmic reticulum, and myofibrils as verified by electron microscopic examination. In addition this preparation was also devoid of endothelial cells, since angiotensin-converting enzyme activity was not detected in this preparation. N-Ethylcarboxamide adenosine (NECA), L-N6-phenylisopropyladenosine (PIA), and adenosine N'-oxide (Ado N'-oxide) were all able to stimulate adenylate cyclase in heart sarcolemma, but not in crude homogenate, with an apparent Ka of 3-7 microM. The activation of adenylate cyclase by NECA was dependent on the concentrations of metal ions such as Mg2+ or Mn2+. The maximal stimulation was observed at lower concentrations of the metal ions (0.2-0.5 mM). At 5 mM Mg2+ or Mn2+, the stimulation by NECA was completely abolished. The stimulatory effect of NECA on adenylate cyclase was also dependent on guanine nucleotides and was blocked by 3-isobutyl-1-methylxanthine. In addition, 2'-deoxyadenosine showed an inhibitory effect on adenylate cyclase. The myocardial adenylate cyclase was also stimulated by beta-adrenergic agonists, dopamine and glucagon, and inhibited by cholinergic agonists such as carbachol and oxotremorine. The stimulation of adenylate cyclase by NECA was found to be additive with maximal stimulation obtained by epinephrine. These data suggest that rat heart sarcolemma contains adenosine (Ra), beta-adrenergic, dopaminergic, glucagon, and cholinergic receptors, and the stimulation of adenylate cyclase by epinephrine and adenosine occurs by distinctly different mechanism or adenosine and epinephrine stimulate different cyclase populations.     

Mechanism of adenylate cyclase activation by the rat lung cytoplasmic factors

Epinephrine, histamine and prostaglandin E₁ stimulated adenylate cyclase activity in lung membranes and their stimulation of the enzyme activity was completely blocked by propranolol, metiamide and indomethacin, respectively. A partially-purified activator from the adult rat lung also enhanced adenylate cyclase activity in membranes. However, stimulation of adenylate cyclase by the rat lung activator was not abolished by the above receptor antagonists. Further, epinephrine, NaF and Gpp(NH)p stimulated adenylate cyclase activity rather readily, whereas stimulation of the enzyme activity by the lung activator was evident after an initial lag phase of 10 min. Also, the lung activator produced additive activation of adenylate cyclase with epinephrine, NaF and Gpp(NH)p. These results indicate that the lung activator potentiates adenylate cyclase activity in membranes by a mechanism independent from those known for epinephrine, NaF and Gpp(NH)p. Incubation of lung membranes for 30 min at 40°C resulted in a loss of adenylate cyclase activation by NaF and Gpp(NH)p. Addition of the released proteins to the heat-treated membranes did not restore the enzyme response to these agonists. However, heat treatment of lung membranes in the presence of 2-mercaptoethanol or dithiothreitol prevented the loss of adenylate cyclase response to NaF and Gpp (NH)p. N-ethylmaleimide abolished adenylate cyclase activation by epinephrine, NaF, Gpp(NH)p and the lung activator. These results indicate that the sulfhydryl groups are important for adenylate cyclase function in rat lung membranes.Abbreviations Gpp(NH)p 5-Guanylimidodiphosphate     

Vasoactive intestinal polypeptide and glucagon: stimulation of adenylate cyclase activity via distinct receptors in liver and fat cell membranes

Vasoactive intestinal polypeptide (VIP), a peptide hormone that is chemically and biologically related to glucagon and secretin, stimulates the activity of adenylate cyclase in liver and fat cell membranes. Effects of combinations of VIP with glucagon and secretin at concentrations that maximally activate adenylate cyclase suggest that in adipose tissue, the three hormones act on the same enzyme, whereas in liver, VIP and secretin activate a common enzyme that is distinct from that responding to glucagon. Studies with radioiodinated derivatives of VIP and glucagon indicate that these hormones interact with separate receptors. Secretin, which gives a maximal stimulation of adenylate cyclase activity virtually identical to that elicited by VIP, inhibits the binding of the latter to its receptor. However, the apparent affinity of secretin for adenylate cyclase and for the VIP receptor is about two order of magnitude lower than that of VIP. It is suggested that VIP and secretin may activate adenylate cyclase via a common receptor.     

Transient complexes. A structural model for the activation of adenylate cyclase by hormone receptors (guanine nucleotides/irradiation inactivation)

1. The irradiation-inactivation procedure was used to study changes in the state of association of the protein components of adenylate cyclase in intact rat liver plasma membranes by measurement of alterations in the target size determined from the catalytic activity of the enzyme. 2. A decrease in target size at 30 degrees C in response to p[NH]ppG (guanosine 5'-[betagamma-imido]triphosphate) or GTP was demonstrated, which we take to reflect the dissociation of a regulatory subunit. The effect of GTP is potentiated by glucagon. This effect is not observed at 0 degrees C. 3. An increase in target size was observed in response to glucagon in the absence of guanine nucleotides, which we take to reflect the association of glucagon receptor with adenylate cyclase. 4. We propose a model for the activation of adenylate cyclase by glucagon in which the binding of the hormone to its receptor causes an initial association of the receptor with the catalytic unit of the enzyme and a regulatory subunit to form a ternary complex. The subsequent activation of the adenylate cyclase results from the dissociation of the ternary complex to leave a free catalytic unit in the activated state. This dissociation requires the binding of a guanine nucleotide to the regulatory subunit. 5. The effects of variation of temperature on the activation of adenylate cyclase by glucagon and guanine nucleotides were examined and are discussed in relation to the irradiation-activation data. 6. The effectiveness of hormones, guanine nucleotides and combinations of hormone and guanine nucleotides as activators of adenylate cyclase in both rat liver and rat fat-cell plasma membranes was studied and the results are discussed in relation to the model proposed, which is also considered in relation to the observations published by other workers.     

Hormone responsiveness of plasma membrane-bound enzymes in normal and regenerating rat liver.

The hormonal responsiveness of plasma membrane-bound enzymes (Na-+-K-+)-ATPase and adenylate cyclase has been investigated in normal and regenerating rat liver. (Na-+-K-+)-ATPase basal activity is not affected by surgery and only slightly affected by partial hepatectomy; its response to epinephrine and cyclic AMP is decreased only 15 h after hepatectomy. Adenylate cyclase activity of plasma membranes from untreated animals is stimulated by parathyroid hormone and thyroxine; partial hepatectomy increased basal activity as well as the stimulation exerted by the aforementioned hormones, when glucagon and epinephrine sensitivity is essentially unaltered.     

Quantitation of epinephrine- and glucagon-sensitive adenylate cyclases of rat liver implications of alterations of enzymatic activities during preparation of particulate fractions and membranes

Stimulated and basal adenylate cyclase activities from livers of young and old rats were lower in particulates than in homogenates. Particulates were compared to homogenates by reconstituting the suspensions to the volume of the homogenates from which they were derived; enzyme activities in paired homogenates and particulates therefore reflected the same amounts of membrane-bound enzyme. The magnitude of the losses of hormone-sensitive activities in particulates was dependent on the age and sex of the animals and the concentrations of hormone. Particulates from 3-month-old animals showed glucagon-( (1 · 10^?5 M) and epinephrine-sensitive (1 · 10^?4 M) activities which were 67 and 78% of homogenate activities, respectively; particulates from 24-month-old animals had activities relative to homogenates of 55% for glucagon and as low as 32% for epinephrine. The glucagon dose vs. response curve in particulates and membranes showed maximal activity at 1 · 10^?7 M glucagon while in homogenates activity increased linearly with increasing glucagon concentrations up to 1 · 10^?5 M. Losses of basal and anion-stimulated activities were similar at both ages. Fluoride and azide stimulations relative to basal activities were greater in particulates than in homogenates, while relative epinephrine activity was lower in particulates, suggesting qualitative alteration of adenylate cyclase during preparation of particulates. These studies show that adenylate cyclase activity in rat liver is presently best quantitated in homogenates and suggest caution in comparisons of enzyme activities based on particulates or membranes prepared from animals of differing physiologic states.     

Mechanism of activation of adenylate cyclase by Vibrio cholerae enterotoxin. Relations to the mode of activation by hormones.

The influence of Vibrio cholerae enterotoxin (choleragen) on the response of adenylate cyclase to hormones and GTP, and on the binding of 125I-labeled glucagon to membranes, has been examined primarily in rat adipocytes, but also in guinea pig ileal mucosa and rat liver. Incubation of fat cells with choleragen converts adenylate cyclase to a GTP-responsive state; (-)-isoproterenol has a similar effect when added directly to membranes. Choleragen also increases by two- to fivefold the apparent affinity of (-)-isoproterenol, ACTH, glucagon, and vasoactive intestinal polypeptide for the activation of adenylate cyclase. This effect on vasoactive intestinal polypeptide action is also seen with the enzyme of guinea pig ileal mucosa; the toxin-induced sensitivity to VIP may be relevant in the pathogenesis of cholera diarrhea. The apparent affinity of binding of 125I-labeled glucagon is increased about 1.5- to twofold in choleragen-treated liver and fat cell membranes. The effects of choleragen on the response of adenylate cyclase to hormones are independent of protein synthesis, and they are not simply a consequence to protracted stimulation of the enzyme in vivo or during preparation of the membranes. Activation of cyclase in rat erythrocytes by choleragen is not impaired by agents which disrupt microtubules or microfilaments, and it is still observed in cultured fibroblasts after completely suppressing protein synthesis with diphtheria toxin. Choleragen does not interact directly with hormone receptor sites. Simple occupation of the choleragen binding sites with the analog, choleragenoid, does not lead to any of the biological effects of the toxin.     

Potentiation by GTP of hormone-responsive adenylate cyclase in renal cortex plasma membrane preparations

GTP potentiated the stimulation by parathyroid hormone and prostaglandin E₁ of adenylate cyclase in a renal cortex preparation enriched in proximal tubule basal-lateral plasma membranes. Adenylate cyclase in these membranes did not respond to epinephrine nor glucagon, in the absence or presence of GTP. Activation of basal activity by GMP-PNP was strongly inhibited by GTP. GTP also increased the sensitivity of renal adenylate cyclase to parathyroid hormone and prostaglandin E₁. The synergistic effect of GTP was not inhibited by chelating nor thiol-reducing reagents.     

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.     

Cholera toxin and adenylate cyclase: properties of the activated enzyme in liver plasma membranes.

Adenylate cyclase (EC 4.6.1.1) activity in mouse liver plasma membranes is increased fivefold when animals are pretreated with cholera toxin. The increase in activity is detectable within 20 min of an intravenous injection of the toxin. The response of the control and cholera-toxin-activated adenylate cyclase to hormones, GTP, and NaF is complex. GTP causes the same fold stimulation of control and toxin-activated cyclase, but glucagon and NaF remain the most potent activators of liver adenylate cyclase irrespective of whether the enzyme is activated by cholera toxin. Determination of kinetic parameters of adenylate cyclase indicates that cholera toxin, hormones, and NaF do not change the affinity of the enzyme for ATP-Mg nor do they alter the Ka for free Mg2+. High concentrations of Mg2+ inhibit adenylate cyclase that is stimulated by either cholera toxin, glucagon, or NaF. These same Mg2+ concentrations have no effect on the basal activity of the enzyme or its activity in the presence of GTP.     

The temperature dependence of adenylate cyclase activity solubilised using various Lubrol detergents

Arrhenius plots of the fluoride-stimulated adenylate cyclase activity of rat liver plasma membranes are linear. Solubilisation using various lubrol detergents yield adenylate cyclase preparations whose Arrhenius plots reflect the physical properties of the detergent used. This suggests that the detergent is tightly bound to the enzyme and can modulate its activity.     

Hormone regulated enzyme activities of plasma membrane of decidual endometrium of the rat

Plasma membranes were purified from deciduoma of pseudopregnant rats and rat liver. Preparations contained 80% plasma membrane-derived material as based on electron microscope morphometry and analysis of enzyme markers. Several plasma membrane enzymes were tested for direct response to hormones. NADH-ferricyanide reductase of plasma membranes from both tissues was stimulated by glucagon and inhibited by insulin but was unresponsive to steroids. For steroids, responsiveness was limited to a reduction in NaF-stimulated adenylate cyclase activity by the steroid R5020. Thus, interaction of steroid hormones with plasma membranes, unlike that of glucagon and insulin, is not reflected in an altered activity of plasma membrane-bound dehydrogenases but may be exerted directly on adenylate cyclase.     

Mechanisms of heart adenylate cyclase activation by epinephrine and fluoride ions

The effects of epinephrine and NaF on the membrane preparations of adenylate cyclase from rabbit heart were studied. After preincubation with epinephrine or NaF at 37 degrees C and subsequent washing of the membranes at 4 degrees C from the effectors, adenylate cyclase passes into the activated state and loses its sensitivity to epinephrine and NaF. The effect may be "reversed" by preincubation of the membranes at 37 degrees C. The addition of ATP to the preincubation media does not affect the regulatory and catalytic properties of the enzyme. It is assumed that adenylate cyclase regulation by hormones and fluoride ions may occur without hypothetical processes of phosphorylation and dephosphorylation of the enzyme. The effect of preincubation is probably due to the temperature-dependent association and dissociation of the enzyme-receptor complex in the membrane. Epinephrine and NaF partially protect the cyclase against trypsin-induced inactivation, which is indicative of structural or conformational changes of the adenylate cyclase complex during its interaction with activators.     

Inhibition of basal and hormone-stimulated adenylate cyclase in adipocyte ghosts by the prostaglandin endoperoxide prostaglandin H2.

The prostaglandin endoperoxide PGH2 (15-hydroxy-9alpha, 11alpha-peroxidoprosta-5,13-dienoic acid), at a concentration of 2.8 x 10(-5) M inhibited basal adenylate cyclase activity 11% and epinephrine-stimulated activity 30 to 35%. PGH2 inhibited epinephrine-stimulated enzyme activity in the presence of 10 mM theophylline, 2.5 mM adenosine 3':5'-monophosphate (cAMP), or in the absence of inhibitors or substrates of the cAMP phosphodiesterase. When the cAMP phosphodiesterase was assayed directly using 62 nM and 1.1 muM cAMP, PGH2 did not affect the 100,000 x g particulate cAMP phosphodiesterase from fat cells. The inhibition of adenylate cyclase by PGH2 was readily reversible. A 6-min preincubation of ghost membranes with PGH2, followed by washing, did not alter subsequent epinephrine-stimulated adenylate cyclase activity. During epinephrine stimulation, the PGH2 inhibition was apparent on initial rates of cAMP synthesis, and the addition of PGH2 to the enzyme system at any point during an assay markedly reduced the rate of cAMP synthesis. Between 2.8 x 10(-7) M and 2.8 x 10(-5) M, PGH2 inhibited epinephrine-stimulated enzyme activity in a concentration-dependent manner. The stimulation of adenylate cyclase by thyroid-stimulating hormone, glucagon, and adrenocorticotropic hormone as well as by epinephrine was antagonized by PGH2, suggesting that PGH2 may be an endogenous feedback regulator of hormone-stimulated lipolysis in adipose tissue.     

Mechanism of molybdate activation of adenylate cyclase

Molybdate activation of rat liver plasma membrane adenylate cyclase has been examined and compared with the effect of glucagon, Gpp(NG)p and fluoride. Glucagon does not stimulate the detergent solubilized enzyme, though molybdate, fluoride, and Gpp(NH)p are effective in this regard. The stimulatory effects of either fluoride or molybdate are additive with those of GTP and do not require guanyl nucleotide to evoke their activation. Neither fluoride nor molybdate can substitute for GTP when glucagon is the activator of rat liver adenylate cyclase. The stimulatory effects of either ion on adenylate cyclase are additive with that produced by glucagon. Activation of adenylate cyclase by either molybdate or fluoride occurs by a mechanism distinct from that of glucagon or guanyl nucleotide. The data presented here suggest that fluoride and molybdate may act via a similar mechanism of action. Neither ion displays a lag in activation of adenylate cyclase. The pH profiles of fluoride and molybdate-stimulated adenylate cyclase activity are similar, and distinct from guanyl nucleotide-stimulated activity. Cholera toxin treatment of adenylate cyclase blocks fluoride and molybdate stimulation of the enzyme to the same extent, while enhancing the activation obtained with GTP and hormones.     

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.     

Solubilization of calcitonin-responsive renal cortical adenylate cyclase.

Purification of pork renal cortex membranes yielded a particulate adenylate cyclase retaining good sensitivity to stimulation by parathyroid hormone and glucagon and a modest but significant response to porcine calcitonin. Treatment of this partially purified membrane fraction with 0.5% Lubrol PX and 5 mM NaF released adenylate cyclase activity into a fraction which was not sedimented by centrifugation for 20 min at 37,000 X g or for 2 hours at 100,000 X g and passed through a Millipore filter (0.22 mum pore). This solubilized adenylate cyclase was stimulated by porcine calcitonin and NaF but not by parathyroid hormone or glucagon. On gel filtration (Sephadex G-200) in the presence of 1mM dithiothreitol and 5mM NaF, the major portion of the adenylate cyclase activity eluted with the void volume of the column and showed 2.0-fold stimulation with 10 muM calcitonin. Binding of 125I-labeled porcine calcitonin was demonstrated in the 37,000 X g and the 100,000 X g supernatants. From 74 to 86% of the observed binding could be blocked by the addition of unlabeled porcine calcitonin to the reaction mixture. Addition of salmon calcitonin, parathyroid hormone, or glucagon blocked only 12 to 18% of the binding. The dose-response curves for inhibition of binding of iodinated calcitonin by unlabeled calcitonin and the activation of adenylate cyclase by the hormone each showed 50% maximal effect at a concentration between 4.5 and 8 muM porcine calcitonin and maximal effect at a concentration between 33 and 66 muM porcine calcitonin.     

The epinephrine-sensitive adenylate cyclase of rat liver plasma membranes. Role of guanyl nucleotides.

The epinephrine sensitivity in vitro of the adenylate cyclase system in liver plasma membranes from adrenalectomized rats was increased by the addition of 1 to 100 muM GTP or GDP in the incubation medium. Basal and glucagon-stimulated cyclase activities were also enhanced by GTP and GDP. These effects occurred even in the absence of an ATP-regenerating system. They were mimicked by 5'-guanyl diphosphonate and a series of guanyl derivatives, indicating that the structural requirement for the GTP action is not very stringent. Guanyl nucleotides did not increase the affinity of the adenylate cyclase system for the activating hormones, nor did they protect the enzyme activity against denaturation. Their synergic effect was due to an enhancement of the affinity of the enzyme for the substrate MgATP and also to an increase of the maximal velocity of the reaction. It is proposed that the guanyl nucleotides act directly and primarily upon the catalytic component of the cyclase system, independently of their effects on the binding of the activating hormones to liver plasma membrane. Since the activating effects of epinephrine and glucagon are similar in the presence of GTP, but not in its absence, it is suggested that the lower efficiency of epinephrine under normal conditions is not due to intrinsic membrane characteristics, but rather, to superimposed extraneous modulations.     

Characterization of membrane-bound adenosinetriphosphatase activity of sarcolemma-enriched fraction from vascular smooth muscle

Membrane-bound adenosinetriphosphatase (ATPase) activities of the sarcolemma-enriched fraction from bovine aorta were characterized. The membranes, isolated by a sucrose density gradient method, were enriched about 31-fold in sodium- and potassium-stimulated, magnesium-dependent ATPase (Na,K-ATPase) activity, and about 8-fold in 5'-nucleotidase activity compared to the homogenate, suggesting that the isolated membranes were substantially enriched with the sarcolemma. The membranes exhibited about 31, 33 and 42 mumol Pi/mg protein/h of Na,K-ATPase, magnesium-dependent ATPase and calcium-dependent ATPase activities, respectively, in the presence of 4 mmol/l ATP. The sarcolemma-enriched membranes required considerably high concentrations of well-known inhibitors for Na,K-ATPase such as vanadate (more than 1 mumol/l), lanthanum (more than 1 mmol/l) and calcium (10 mmol/l), to induce a significant inhibition in the Na,K-ATPase activity. Treatments of the membrane with physical disruptions and sodium dodecyl sulfate or deoxycholate reduced the total Na,K-ATPase activity, and did not expose fully the ouabain sensitivity of the Na,K-ATPase. These results indicate that there are marked differences in the properties of the ATPase between vascular smooth muscle sarcolemma and cardiac sarcolemma.