Changes in the distribution of adenylate cyclase activity in PC 12 cells under the influence of nerve growth factor

Changes in distribution of adenylate cyclase in PC 12 cells under the influence of nerve growth factor (NGF) have been studied using cytochemical methods. The adenylate cyclase activity was predominantly associated with the plasma membrane. In cell cultures without NGF the activity was revealed on the contacting surfaces of cell aggregates; single grains of reaction product were revealed on exposed cell surface only in cultures with a high cell density. One day after administration of NGF, the adenylate cyclase activity on exposed cell surface increased, and three days later the whole cell surface was covered with lead sediment. The enzyme activity was also revealed in growth cones, filopodia and microcytospheres. The role of adenydlate cyclase system in neuron-like differentiation of PC 12 cells is discussed.     

Ultracytochemical study of adenylate cyclase localization in the adenohypophysis of rats

Using an electron cytochemical method and adenylylimidodiphosphate (AMP--PNP) as substrate, the localization of adenylate cyclase activity was determined in the rat's adenohypophysis. This activity was discovered in the perinuclear space, in the canaliculi of the endoplasmic reticulum and Golgi complex, in mitochondria, on the external surface of the plasma membrane. In sinusoidal capillaries, the reaction product was localized on the plasma membrane, in perinuclear space, endoplasmic reticulum and mitochondria. The addition of isoproterenol and sodium fluoride to the incubation medium led to a rise in adenylate cyclase activity.     

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.     

Histochemical localization of adenylate cyclase and phosphodiesterase activities in the folliate papillae of the rabbit I. Light microscopic observations

Adenylate cyclase and cyclic AMP phosphodiesterase activitieson the foliate papillae of rabbit were studied by means of histochemistry.In unfixed papillae the reaction product for adenylate cyclaseactivity was localized in the apex of taste buds, lamina proprioand connective tissue core of the papillae, but in fixed papillaeit was limited to the apex of taste buds. The reaction productfor cyclic AMP phosphodiesterase activity was limited to theapex of taste buds in unfixed and fixed papillae. Neither anacceleratory nor an inhibitory effect of sweet and bitter substanceson the adenylate cyclase and cyclic AMP phosphodiesterase activitieswas demonstrated, but NaCl prevented the formation of reactionproduct for the adenylate cyclase activity at the apex of tastebuds.     

The phorbol ester TPA prevents the expression of both glucagon desensitisation and the glucagon-mediated block of insulin stimulation of the peripheral plasma membrane cyclic AMP phosphodiesterase in rat hepatocytes

The phorbol ester TPA (12-O-tetradecanoyl phorbol-13-acetate) causes a dose-dependent inhibition of the glucagon-stimulated adenylate cyclase activity expressed in plasma membranes isolated from TPA-treated hepatocytes. However, no observable inhibitory effect of TPA on adenylate cyclase activity was observed in cells which had been exposed to glucagon for 5 min, prior to isolation, to desensitise adenylate cyclase. The degree of inhibition of adenylate cyclase elicited by both glucagon desensitisation and TPA treatment of hepatocytes was identical. Pre-treatment of hepatocytes with TPA was also found to prevent glucagon from blocking insulin's activation of the peripheral plasma membrane cyclic AMP phosphodiesterase in intact hepatocytes. TPA treatment also inhibited the ability of cholera toxin to activate the peripheral cyclic AMP phosphodiesterase in intact hepatocytes. It is suggested that in these particular instances TPA and glucagon elicit mutually exclusive processes rather than TPA mimicking glucagon desensitisation per se.     

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.     

Influence on adipocyte plasma membrane bound protein kinase by feedback regulator.

Protein kinase, phosphodiesterase and adenylate cyclase of plasma membrane of adipocytes and the effect of the feedback regulator (FR) on these three enzymes was measured and compared. The basal level ratio of adenylate cyclase to phosphodiesterase to protein kinase was 1:1.9:3.0. Epinephrine and/or FR alters this ratio. FR stimulated protein kinase activity up to 3 fold in the presence of a wide range of enzyme concentrations, 5-50 mug membrane protein/tube. The concentration of FR effective for stimulation of membrane protein kinase was much greater than that needed for inhibition of adenylate cyclase and phosphodiesterases. The inhibition by FR on adenylate cyclase was the most potent effect among the 3 enzymes. 1 U (or 2 U/ml) of FR inhibited 50% of the adenylate cyclase activity in a defined system. The maximum effective concentration of FR for stimulation of membrane protein kinase was greater than 10 U/ml. Histone type 11A was the best substrate for protein phosphorylation so far observed. The FR stimulatory effect was observed at all substrate concentrations used ranging from 1-5 mg/ml. A NaF concentration curve shows that 15 mM NaF gave maximum phosphorylation. The stimulatory effect of FR was observed both in the presence and absence of NaF. Protein kinase of adipocyte plasma membrane was mainly cAMP-independent. The effect of FR (20 U/ml) in stimulation of protein phosphorylation was much greater than that of cAMP (1 X 10(-6) M). The cAMP and FR effects seemed to be additive. Preincubation of plasma membrane with FR in the absence of ATP resulted in no decrease but slight increase in protein kinase activity. A shift in protein kinase, phosphodiesterase and adenylate cyclase ratios by FR suggests the regulatory role of FR in cAMP metabolism in adipocytes.     

cAMP-stimulated adenylate cyclase activation in Dictyostelium discoideum is inhibited by agents acting at the cell surface

The ability of Dictyostelium discoideum amoebae to synthesize and secrete cAMP in response to exogenous cAMP is called cAMP signaling. Concanavalin A is a potent, rapid, noncompetitive inhibitor of this response, with the rate of inhibition consistent with its rate of binding. The concanavalin A does not deplete cellular ATP, alter cAMP binding to its surface receptors, or affect basal adenylate cyclase activity, but blocks the cAMP-stimulated activation of adenylate cyclase. Therefore, concanavalin A appears to inhibit a step between the receptor and the adenylate cyclase which is necessary for the transduction of the cAMP signal. Wheat germ agglutinin, a polyclonal antibody against an 80-kDa glycoprotein, four monoclonal antibodies against the amoebal surface, and a chemical cross-linking agent which reacts with cell surface primary amines also inhibit signaling. To determine the importance of cross-linking in the inhibition, succinylated concanavalin A and the unlinked, reactive portion of the chemical cross-linker were tested and found to be relatively ineffective inhibitors. Thus it appears that ligands capable of cross-linking molecules on the external surface of D. discoideum amoebae inhibit cAMP signaling. It is proposed that these cross-linking agents prevent membrane or cytoskeletal rearrangement and that this rearrangement must occur before the adenylate cyclase is activated.     

Production and turnover of cAMP signals by prestalk and prespore cells in Dictyostelium discoideum cell aggregates

Dictyostelium discoideum prestalk cells and prespore cells from migrating slugs and culminating cell aggregates were isolated by Percoll density centrifugation. Several activities relevant to the generation, detection, and turnover of extracellular cyclic AMP (cAMP) signals were determined. It was found that: the two cell types have the same basal adenylate cyclase activity; prespore cells and prestalk cells are able to relay the extracellular cAMP signal equally well; intact prestalk cells show a threefold higher cAMP phosphodiesterase activity on the cell surface than prespore cells, whereas their cytosolic activity is the same; intact prestalk cells bind three to four times more cAMP than prespore cells; no large differences in cAMP metabolism and detection were observed between cells derived from migrating slugs and culminating aggregates. The results are discussed in relation to the possible morphogenetic role of extracellular cAMP in Dictyostelium cell aggregates. On the basis of the properties of the isolated cells we assume that a gradient of extracellular cAMP exists in Dictyostelium aggregates. This gradient appears to be involved in the formation and stabilization of the prestalk-prespore cell pattern.     

Cytochemical localization of adenylate cyclase activity in the theca folliculi of the mouse graafian follicle

Summary The adenylate cyclase activity in the theca folliculi of the mouse Graafian follicle was investigated using the electron microscopic cytochemistry. Deposits of reaction product are recognized on the plasma membrane of the fibroblast, theca cell and transitional cell from the fibroblast-like cell to the theca cell (partially or incompletely differentiated theca cell) after incubation with adenylyl-imidodiphosphate (AMP-PNP) as an effective substrate for adenylate cyclase. This fact indicates that these cells have the receptor on the plasma membrane, and the adenylate cyclase-cyclic AMP system is important for the steroid secretion or the collagen fiber production. It is difficult to clarify by this method the relationship between the adenylate cyclase activity and the functional differentiation of the theca cell.Supported by a grant from the Japanese Educational ministry     

cAMP-independent oscillations of adenylate cyclase in Dictyostelium discoideum

In starved Dictyostelium discoideum amoebae, extracellular cAMP appears to regulate adenylate cyclase activity such that synthesis of cAMP is rhythmic. Here we report that periodic modulation of adenylate cyclase also occurs via a cAMP-independent mechanism. This was demonstrated using cells which have high levels of adenylate cyclase activity, as measured in cell extracts, but which do not express this enzymic potential when intact. Such cells still rhythmically modify their adenylate cyclase activity and both the periodicity and the amplitude of the oscillations are similar to those seen in cells actively synthesizing cAMP. The phenomenon is observed using both wild-type cells and certain aggregation-minus mutants. The results implicate a mechanism which is cAMP independent in the regulation of adenylate cyclase as well as in the synchrony of the cell population.     

Localization of adenylate cyclase and 5′-nucleotidase activities in human thyroid follicular cells

Summary The localization of adenylate cyclase and 5-nucleotidase activities in the follicular cells of adenomatous goiter and normal thyroid was studied by light and electron microscopy. Simultanous biochemical measurement for both activities was carried out to confirm the histochemical findings. Adenylyl-imidodiphosphate (AMP-PNP) was used as an effective substrate for adenylate cyclase. The specificity of the adenylate cyclase reaction was also examined by adding oxalacetic acid or PCMB as an adenylate cyclase inhibitor, and by adding sodium fluoride or TSH as an adenylate cyclase stimulator to the reaction mixture. In the case of tissue from adenomatous goiter, a large amount of the reaction product of the adenylate cyclase activity was found uniformly in the apical and lateral plasma membrane and not in the basal plasma membrane. In the cases of normal thyroid, a small amount of the reaction product of adenylate cyclase activity was demonstrated, and only in the lateral plasma membrane of the follicular cells. On the other hand, the histochemical localization of 5-nucleotidase activity was the same in adenomatous goiter and normal thyroid. The reaction product of 5-nucleotidase activity was found predominantly in the apical plasma membrane of the follicular cells. The biochemical findings indicated that the activity of adenylate cyclase per gram tissue was approximately 2 times higher in the case of adenomatous goiter than that in the case of normal thyroid, while the 5-nucleotidase activity in adenomatous goiter was in slightly higher level than in normal thyroid. Thus the histochemically demonstrable amount of adenylate cyclase and 5-nucleotidase reflected the activity levels measured biochemically. The lack of demonstrable adenylate cyclase activity in the basal plasma membrane suggests the possibility that this structure may not play any important role in TSH reception.     

Protein activator of cyclic 3':5'-nucleotide phosphodiesterase of bovine or rat brain also activates its adenylate cyclase.

Bovine or rat brain adenylate cyclase (EC 4.6.1.1) solubilized by Lubrol PX contained an activator which was separated from the enzyme by an anionic exchange resin column. Dissociation of the activator from adenylate cyclase rendered the enzyme less active, and reconstituting with an exogenous activator restored full enzyme activity. A pure protein activator of cyclic 3′:5′-nucleotide phosphodiesterase (EC 3.1.4.17) isolated from bovine brain also stimulated this adenylate cyclase. Stimulation of adenylate cyclase by the activator required Ca⁺⁺, the effect being immediate and reversible. Although the activator was specific, it lacked tissue specificity; an activator isolated from bovine brain cross-activated effectively adenylate cyclase from rat, and vice versa. These findings indicate that brain adenylate cyclase required an activator for activity and that this activator is functionally identical to the protein activator of phosphodiesterase (J.B.C. 249: 4943–4954, 1974).     

Histidine regulation of cyclic AMP metabolism in cultured renal epithelial LLC-PK1 cells.

L-Histidine and imidazole (the histidine side chain) significantly increase cAMP accumulation in intact LLC-PK1 cells. This effect is completely inhibited by isobutylmethylxanthine (IBMX). Histidine and imidazole stimulate cAMP phosphodiesterase activity in soluble and membrane fractions of LLC-PK1 cells suggesting that the IBMX-sensitive effect of these agents to stimulate cAMP formation is not due to inhibition of cAMP phosphodiesterase. Histidine and imidazole but not alanine (the histidine core structure) increase basal, GTP-, forskolin-, and AVP-stimulated adenylate cyclase activity in LLC-PK1 membranes. Two other amino acids with charged side chains (aspartic and glutamic acids) increase AVP-stimulated but neither basal- nor forskolin-stimulated adenylate cyclase activity. This suggests that multiple amino acids with charged side chains can regulate selected aspects of adenylate cyclase activity. To better define the mechanism of histidine regulation of adenylate cyclase, membranes were detergent-solubilized which prevents histidine and imidazole potentiation of forskolin-stimulated adenylate cyclase activity and suggests that an intact plasma membrane environment is required for potentiation. Neither pertussis toxin nor indomethacin pretreatment alter imidazole potentiation of adenylate cyclase. IBMX pretreatment of LLC-PK1 membranes also prevents imidazole to potentiate adenylate cyclase activity. Since IBMX inhibits adenylate cyclase coupled adenosine receptors, LLC-PK1 cells were incubated in vitro with 5'-N-ethylcarboxyamideadenosine (NECA) which produced a homologous pattern of desensitization of NECA to stimulate adenylate cyclase activity. Despite homologous desensitization, histidine and imidazole potentiation of adenylate cyclase was unaltered. These data suggest that histidine, acting via an imidazole ring, potentiates adenylate cyclase activity and thereby increases cAMP formation in cultured LLC-PK1 epithelial cells. This potentiation requires an intact plasma membrane environment, occurs independent of a pertussis toxin-sensitive substrate and of products of cyclooxygenase, and is inhibited by IBMX. This IBMX-sensitive pathway does not involve either inhibition of cAMP phosphodiesterase activity or a stimulatory adenosine receptor coupled to adenylate cyclase.     

The cytochemical localization of adenylate cyclase activity in mucous and serous cells of the salivary gland

The present study was undertaken to localize adenylate cyclase activity in salivary glands by cytochemical means. For the study, serous parotid glands and mixed sublingual glands of the rat were used. Pieces of the fixed glands were incubated with adenosine triphosphate (ATP) or adenylyl-imidodi-phosphate (AMP-PNP) as substrate: inorganic pyrophosphate or PNP liberated upon the action of adenylate cyclase on the substrates is precipitated by lead ions at their sites of production. In both glands, the reaction product was detected along the myoepithelial cell membranes in contact with secretory cells, indicating that a high level of adenylate cyclase activity occurs in association with these cell membranes. The association with a high level of the enzyme activity might be related to the contractile nature of myoepithelial cells which are supposed to aid secretory cells in discharging secretion products. A high level of adenylate cyclase activity was also detected associated with serous secretory cells (acinar cells of the parotid gland and demilune cells of the sublingual gland), but not with mucous secretory cells. In serous cells, deposits of reaction product were localized along the extracellular space of the apical cell membrane bordering the lumen. This is the portion of the cell membrane which fuses with the granule membranes during secretion. Since the granule membranes are not associated with a detectable level of adenylate cyclase activity, it appears that the enzyme activity becomes activated or associated with the granule membranes as they become part of the cell membrane by fusion. The association with a high level of adenylate cyclase activity appears to be related to the ability of the membrane to fuse with other membranes. It is likely, since the luminal membrane of mucous cells which does not fuse with mucous granule membranes during secretion is not associated with a detectable enzyme activity.     

Ultracytochemical localizations of adenylate cyclase, guanylate cyclase and cyclic 3',5'-nucleotide phosphodiesterase activity on the trophoblast in the human placenta. Direct histochemical evidence

Ultracytochemical localizations of cyclic nucleotide-metabolizing enzymes, namely adenylate cyclase (AC), guanylate cyclase (GC) and cyclic 3',5'-nucleotide phosphodiesterase (PDE), have been demonstrated in the human term placenta. AC activity was found positive on the basal plasma membrane of the syncytiotrophoblast and on the pinocytotic vesicle of the fetal capillary endothelial cell. GC activity was observed to be strong on the plasma membrane of the microvilli of the syncytiotrophoblast. The cAMP PDE activity was shown positive both on the basal plasma membrane and on the microvillous membrane, while cGMP PDE activity was exclusively confined to the microvilli of the syncytiotrophoblast. These observations suggest that the syncytiotrophoblast plays an important role in the cyclic nucleotide metabolism in the human term placenta and that there might be significant functional differences between its basal plasma membrane and its microvillous membrane.     

Electron-microscopic cytochemical localization of adenylate cyclase activity in the myoepithelial cells of the lactating mouse mammary gland

Adenylate cyclase activity was localized in the lactating mouse mammary gland using an ultrastructural histochemical technique. Reaction product was deposited on the plasma membrane of the myoepithelial cells adjacent to the secretory epithelium. No reaction product was encountered on the secretory epithelium. These findings suggest that the presence of cAMP, previously biochemically documented in lactating mammary gland, is mainly connected with myoepithelial cellular activity. The asymmetrical distribution of adenylate cyclase activity suggests that cAMP is involved in the intercellular communication between the secretory and myoepithelial cells and that the secretory epithelium takes part in the regulation of the contraction of myoepithelial cells.     

Cytochemical localization of adenylate cyclase activity in the rat anterior pituitary

Summary The cytochemical localization of adenylate cyclase was studied in relation to the secretory function of the anterior pituitary glands of male rats. The reaction product of adenylate cyclase was localized on the outside of plasma membranes, but was not detected intracellularly. High activity of adenylate cyclase was detected on somatotrophs and microvilli of follicular cells, whereas no activity was found on thyrotrophs or corticotrophs. Although most of the gonadotrophs showed little or no adenylate-cyclase activity, some was detected in a small number of gonadotrophs in the central portion of the gland. In somatotrophs, activity was not detected on the plasma membranes facing perivascular spaces where exocytotic extrusion of secretory granules was frequently observed, although the remaining areas of plasma membranes of the same somatotrophs were associated with high levels of adenylate-cyclase activity. These findings indicate that the association of a high level of adenylate-cyclase activity is not directly related to the ability of the plasma membranes to fuse with secretory granule membranes.     

Translocation of phospholipid/Ca2+-dependent protein kinase in B-lymphocytes activated by phorbol ester or cross-linking of membrane immunoglobulin.

Treatment of hepatocytes with islet activating protein (pertussis toxin) from Bordetella pertussis blocked the ability of insulin to inhibit adenylate cyclase activity both in broken plasma membranes and in intact hepatocytes. Such treatment of intact hepatocytes with pertussis toxin did not prevent insulin from activating the peripheral plasma membrane cyclic AMP phosphodiesterase although it did inhibit the ability of insulin to activate the 'dense-vesicle' cyclic AMP phosphodiesterase. The ability of glucagon pretreatment of hepatocytes to block insulin's activation of the plasma membrane cyclic AMP phosphodiesterase was abolished in pertussis toxin-treated hepatocytes. It is suggested that the ability of insulin to manipulate cyclic AMP concentrations by inhibiting adenylate cyclase and activating the plasma membrane and 'dense-vesicle' cyclic AMP phosphodiesterases involves interactions with the guanine nucleotide regulatory protein system occurring in liver plasma membranes.     

A stage-specific inhibitor of adenylate cyclase in Dictostelium discoideum

A sudden increase in adenylate cyclase activity occurs during the chemotaxis and aggregation of Dictyostelium discoideum. Preincubation of extracts from the pre-aggregation stage, in which adenylate cyclase activity was low, with post-aggregation stages, in which the increase in activity occurred, resulted in the demonstration of a heat-stable inhibitor of adenylate cyclase (ACI) that was present only during the early stages of development. Cellular fractionation studies showed that ACI was present in both the 100 000 g pellet and supernatant fractions. The inhibitor was not inactivated by proteases or protease inhibitors. A heat-treated preparation of the inhibitor was dialysable. The effect of ACI was dependent upon a pre-incubation treatment, with notable inhibition occurring only after a 20 min pre-incubation period. The apparent inhibition was not artifactual, due to the degradation of the substrate, ATP, or to the loss of the reaction product, cAMP. Additionally, the inhibitor was specific for adenylate cyclase, as it had no effect on the activity of several other enzymes, including cAMP phosphodiesterase.