Evaluation of methods for the isolation of plasma membranes displaying guanosine 5'-triphosphate-dependence for the regulation of adenylate cyclase activity: potential application to the study of other guanosine 5'-triphosphate-dependent transduction systems

The GTP-dependence for stimulatory and inhibitory regulation of plasma membrane adenylate cyclase activity was measured in plasma membrane fractions isolated from a variety of cell types (platelets, lymphocytes, PC12 cells, GH3 cells, NBP2 cells, and hepatocytes). This report shows that the isolation of plasma membranes for the study of GTP-dependent adenylate cyclase activity was, for some cells, enhanced by the exposure of the cells to glycerol prior to cell lysis. The isolation of plasma membranes from other cells, which did not appear to be sensitive to glycerol pretreatment, was enhanced by the removal of heavy particulate matter prior to fractionation of the cell lysate. The regulation of enzyme activity by various agents was found to be dependent upon the presence of (exogenous) GTP to varying degrees, indicating variable contamination of membrane preparations with GTP. It is concluded that (i) exposure of platelets and lymphocytes to glycerol prior to cell lysis decreases subsequent contamination of the plasma membrane preparation with GTP, and (ii) although glycerol pretreatment of other cells does not ensure the subsequent isolation of plasma membrane adenylate cyclase activity displaying high requirements for (exogenous) GTP, it is a reasonable first approach to be used during the development of procedures for the isolation of plasma membranes.     

Stimulation of rat platelet adenylate cyclase by an endogenous calcium-dependent protease-like activity

The stimulation of adenylate cyclase by various exogenous proteases has been described in several tissues. In this study, we describe a 2 to 7-fold increase of adenylate cyclase activity in a particulate preparation from rat platelets following prior exposure of the homogenate to calcium. Calmodulin alone was unable to increase the adenylate cyclase activity and trifluoperazine only partially inhibited the calcium-dependent activation. On the other hand, calcium had a slight stimulatory effect on the particulate preparation but this activation was greatly enhanced by the addition of supernatant. Only the combined addition of calcium, supernatant and calmodulin to washed particulate preparations reconstituted the activation seen in homogenates. The activation was significantly inhibited by leupeptin and thiol reagents. It is concluded that platelets contain a calcium-dependent protease-like activity that is able to increase adenylate cyclase activity in membrane fractions. This phenomenon may be involved in the regulation of adenylate cyclase activity in platelets.     

Cytochemical localization of adenylate cyclase in the dense tubule system of human blood platelets stimulated by forskolin, prostacyclin and prostaglandin D2

Platelets were briefly fixed in paraformaldehyde/glutaraldehyde and then incubated with 5'-adenylyl imidodiphosphate under conditions suitable for the cytochemical detection of adenylate cyclase activity. The adenylate cyclase activity of these platelets retains the ability to respond to prostaglandins E1, D2, I2 (prostacyclin), forskolin and fluoride. Sites of stimulated adenylate cyclase activity were localized cytochemically by the reaction of lead with the reaction product imidodiphosphate to form deposits of lead imidodiphosphate that are visible in the electron microscope. Reaction product deposition was seen only in the dense tubule system of human platelets when the incubation medium contained forskolin, prostacyclin, or prostaglandin D2 at concentrations known to stimulate the enzyme in intact platelets. Epinephrine, an antagonist of adenylate cyclase inhibited the cytochemical reaction stimulated by prostacyclin. The fact that the cytochemical reaction was induced by agonists that stimulate the enzyme through two different types of prostaglandin receptors and by forskolin, which acts distal to the receptors, confirms that the method specifically detects adenylate cyclase. The presence of adenylate cyclase in the dense tubules may be significant for the regulation of intracellular Ca2+ and arachidonic acid metabolism by this membrane system.     

Decrease in adenylate cyclase activity in spleen T- and B-lymphocytes and thymus T-lymphocytes in CBA mice treated with levamisole

The influence of various concentrations of levamisole on the activity of the membrane adenylate cyclase complex of lymphocytes is analyzed. It is ascertained that levamisole decreases the activity of adenylate cyclase at a concentration of 10(-9)-10(-7) M in thymic lymphocytes, and that the activity of the enzyme in spleen T- and B-lymphocytes remains constant. The influence of levamisole on the activity of adenylate cyclase thymocytes is studied under conditions of its stimulation by NaF, GTF and adrenaline. It is ascertained that levamisole at a concentration of 10(-9)-10(-7) M decreases the activity of the enzyme stimulated by NaF, GTF and adrenaline.     

Particulate guanylate cyclase and adenylate cyclase activities after activation with various agents in rabbit platelets. An ultracytochemical study

Summary The cytochemical localization of particulate guanylate cyclase and adenylate cyclase activities in rabbit platelets were studied after stimulation with various agents, at the electron microscope level. In the presence of platelet aggregating agents such as thrombin and ADP, the particulate reaction product of guanylate cyclase activity was detectable on plasma membrane and on membranes of the open canalicular system. In contrast, samples incubated with platelet-activating factor showed no activation of the cyclase activity. Atrial natriuretic factor stimulated the particulate guanylate cyclase. The ultracytochemical localization of this activated cyclase was the same as that of thrombin-or ADP-stimulated guanylate cyclase. Adenylate cyclase activity was studied in platelets incubated with prostaglandin E₁ plus or minus insulin. The enzyme reaction product was found at the same sites where guanylate cyclase was detected. Therefore guanylate and adenylate cyclase activities do not seem to be preferentially localised in platelet membranes.     

Desensitization of prostaglandin-activated platelet adenylate cyclase.

Prostaglandin D2 (PGD2) is one of several prostaglandins that can inhibit platelet aggregation and activate adenylate cyclase. Platelets were exposed to varying concentrations of PGD2 washed, and the adenylate cyclase response to prostaglandins, epinephrine, and sodium fluoride determined. Incubating platelets with 5 x 10(-5) M PGD2 for 2 hr resulted in a 45% decrease in PGD2 activation of adenylate cyclase and a 25% decrease in stimulation by PGE1. Fluoride activation (7-fold) epinephrine inhibition (30%) and basal enzyme activity were unchanged by exposure of the platelets to PGD2. Desensitization was concentration dependent, with loss of enzyme activity first noted when platelets were incubated with 10(-7) M PGD2. Enzyme sensitivity could be partially restored when desensitized platelets were washed free of PGD2 and incubated in buffer for 2 hr; complete resensitization required incubation for 24 hr in plasma. Regulation of prostaglandin sensitive platelet adenylate cyclase could be of importance in mediating the response of platelets to aggregating agents.     

Ethanol and guanine nucleotide binding proteins: a selective interaction

Guanine nucleotide binding proteins (G proteins) play key roles in signal transduction, including the coupling of hormone and neurotransmitter receptors to adenylate cyclase, ion channels, and polyphosphoinositide metabolism. One member of this family of proteins, Gs, appears to represent a specific site of action of ethanol in the central nervous system. Ethanol is often perceived as a nonspecific drug, and its anesthetic effects may in fact arise from relatively nonspecific interactions with cell membrane lipids. However, recent investigations point to a selective effect of low concentrations of ethanol to promote the activation of Gs, and thus to enhance adenylate cyclase activity. Ethanol seems to have little or no effect on the function of other identified G proteins. After chronic ingestion of ethanol by animals, or chronic exposure of cells in culture to ethanol, the sensitivity of adenylate cyclase to stimulation by guanine nucleotides and agonists that act via Gs is decreased. The mechanism of this change may involve qualitative and/or quantitative alterations in Gs, and seems to vary in different cell types. Studies of human platelets and lymphocytes also reveal differences in adenylate cyclase activity between alcoholics and control subjects. The differences are consistent with involvement of Gs, and do not appear to reverse upon cessation of alcohol exposure. The results suggest that the platelet and/or lymphocyte adenylate cyclase system may provide a biochemical marker of genetic predisposition to alcoholism.     

Molecular Mechanism of Resistance of Equine (Equus caballus) Platelets to α2-Adrenergic Regulation

Adrenaline is a weak aggregating agonist for human platelets acting through G-protein-coupled α₂-adrenoceptors to inhibit adenylate cyclase and thus reduce cyclic AMP levels. Studies of equine platelets have shown that adrenaline is unable to promote their aggregation. We now confirm that adrenaline is without effect on equine platelet aggregation and demonstrate that it is also without effect on equine platelet membrane adenylate cyclase activity. We have previously shown that equine platelet membranes contain conventionally regulated adenylate cyclase activity, with both stimulatory ligands (forskolin and PGE₁) and inhibitory ligands (collagen and PAF) each showing substantial and dose-dependent effects. We now show, in Western blots, that equine platelet membranes contain G proteins, including G_i2 (which mediates inhibition of adenylate cyclase by adrenaline in human platelets), G_i3, G_s, and G_q. Hence, all the necessary components and responses are in place in equine platelets to provide for a conventional role for cyclic AMP and adenylate cyclase in modulating platelet aggregation. The basis for the failure of adrenaline, unlike other ligands, to deliver such a signal, appears to be a marked lack of α₂-adrenoceptors. This is supported by the low receptor density we found in idazoxan binding studies.     

Vasopressin inhibits the adenylate cyclase activity of human platelet particulate fraction through V1-receptors

Arg⁸-vasopressin inhibited the adenylate cyclase activity of human platelet particulate fraction up to a maximum of 27% (IC₅₀ = 1.2 nM). This inhibition required the presence of 10 μM GTP and was optimal with 100 mM NaCl. Orn⁸-vasopressin had similar effects. 1-Deamino-Val⁴, D-Arg⁸-vasopressin did not by itself affect adenylate cyclase activity but competitively inhibited the action of Arg⁸-vasopressin (pA₂ = 7.74). Arg⁸-vasopressin did not inhibit adenylate cyclase in intact platelets but instead caused platelet aggregation, an effect that was also competitively inhibited by 1-deamino-Val⁴, D-Arg⁸-vasopressin (pA₂ = 7.82). Thus, platelets possess vasopressin receptors of the V₁ type that, under appropriate conditions, can mediate either inhibition of platelet adenylate cyclase or platelet aggregation.     

Modulation of adenylate cyclase of human platelets by phorbol ester. Impairment of the hormone-sensitive inhibitory pathway

The influence of the phorbol ester, 12-O-tetradecanoylphorbol-13-acetate (TPA), a direct activator of the Ca2+-activated, phospholipid-dependent protein kinase (protein kinase C), was studied on regulation of human platelet adenylate cyclase. Intact platelets were pretreated with the phorbol ester and, thereafter, membranes were prepared and the regulation of the hormone-sensitive adenylate cyclase in these membranes was studied. The following data were obtained: The TPA treatment applied had apparently no effect on the activity of the catalytic moiety of the platelet adenylate cyclase nor on the stimulatory NS protein nor on stimulatory hormone receptors (prostaglandin E1) and the mutual interactions of these components of the stimulatory hormone-sensitive pathway. However, the TPA treatment of intact platelets largely impaired the GTP-dependent, hormone-sensitive inhibitory pathway to the adenylate cyclase, involving the inhibitory Ni protein. The pretreatment led to a large reduction or loss of adenylate cyclase inhibition by GTP itself and by the inhibitory agonists, epinephrine and thrombin, inhibiting the untreated enzyme via separate receptors by an Ni-mediated process. In contrast, platelet adenylate cyclase inhibition not involving the Ni protein was not affected by the TPA treatment. The observed effects of TPA were very rapid in onset and were not shared by a derivative of TPA which did not activate protein kinase C. The data obtained suggest than protein kinase C activated by the phorbol ester interferes with the platelet adenylate cyclase system, leading to a specific alteration of the Ni-protein-mediated signal transduction to the adenylate cyclase.     

Cyclic nucleotides and platelet aggregation. Effect of aggregating agents on the activity of cyclic nucleotide-metabolizing enzymes.

The activities of adenylate and guanylate cyclase and cyclic nucleotide 3':5'-phosphodiesterase were determined during the aggregation of human blood platelets with thrombin, ADP, arachidonic acid and epinephrine. The activity of guanylate cyclase is altered to a much larger degree than adenylate cyclase, while cyclic nucleotide phosphodiesterease activity remains unchanged. During the early phases of thrombin-and ADP-induced platelet aggregation a marked activation of the guanylate cyclase occurs whereas aggregation induced by arachidonic acid or epinephrine results in a rapid diminution of this activity. In all four cases, the adenylate cyclase activity is only slightly decreased when examined under identical conditions. Platelet aggregation induced by a wide variety of aggregating agents including collagen and platelet isoantibodies results in the "release" of only small amounts (1-3%) of guanylate cyclase and cyclic nucleotide phosphodiesterase and no adenylate cyclase. The guanylate cyclase and cyclic nucleotide phosphodiesterase activities are associated almost entirely with the soluble cytoplasmic fraction of the platelet, while the adenylate cyclase if found exclusively in a membrane bound form. ADP and epinephrine moderately inhibit guanylate and adenylate cyclase in subcellular preparations, while arachidonic and other unsaturated fatty acids moderately stimulate (2-4-fold) the former. It is concluded that (1) the activity of platelet guanylate cyclase during aggregation depends on the nature and mode of action of the inducing agent, (2) the activity of the membrnae adenylate cyclase during aggregation is independent of the aggregating agent and is associated with a reduction of activity and (3) cyclic nucleotide phosphodiesterase remains unchanged during the process of platelet aggregation and release. Furthermore, these observations suggest a role for unsaturated fatty acids in the control of intracellular cyclic GMP levels.     

Unmasking of membrane enzyme activities and the problem of subcellular localization of adenylate cyclase in pig lymph node lymphocytes

A large-scale purification of plasma membranes from pig lymph node lymphocytes is described. Centrifugation on a discontinuous sucrose density gradient was performed in a zonal rotor. Adenylate cyclase activity of untreated fractions displayed a profile different from that of plasma membrane enzymatic markers and was maximal at higher density. However, when latent adenylate cyclase was unmasked by Lubrol PX treatment, its maximum was shifted to lower density and was no longer significantly different from that of plasma membrane markers. These results are discussed in terms of cell surface topography.     

Calcitonin-sensitive adenylate cyclase in rat renal tubular membranes.

1. Renal tubular membranes from rat kidneys were prepared, and adenylate cyclase activity was measured under basal conditions, after stimulation by NaF or salmon calcitonin. Apparent Km value of the enzyme for hormone-linked receptor was close to 1 x 10(-8) M. 2. The system was sensitive to temperature and pH. pH was found to act both on affinity for salmon calcitonin-linked receptor and maximum stimulation, suggesting an effect of pH on hormone-receptor binding and on a subsequent step. 3. KCl was without effect areas whereas CoCl and CaCl2 above 100 muM and MnCl2 above 1 muM inhibited F- -and salmon calcitonin-sensitive adenylate cyclase activities. The Ca2+ inhibition of the response reflected a fall in maximum stimulation and not a loss of affinity of salmon calcitonin-linked receptor for the enzyme. 4. The measurement of salmon calcitonin-sensitive adenylate cyclase activity as a function of ATP concentration showed that the hormone increases the maximum velocity of the adenylate cyclase. GTP, ITP and XTP at 200 muM did not modify basal, salmon calcitonin- and parathyroid hormone-sensitive adenylate cyclase activities. 5. Basal, salmon calcitonin- and F- -sensitive adenylate cyclase activities decreased at Mg2+ concentrations below 10 mM. High concentrations of Mg2+ (100 mM) led to an inhibition of the F- -stimulated enzyme. 6. Salmon calcitonin-linked receptor had a greater affinity for adenylate cyclase than human or porcine calcitonin-linked receptors. There was no additive effect of these three calcitonin peptides whereas parathyroid hormone added to salmon calcitonin increased adenylate cyclase activity, thus showing that both hormones bound to different membrane receptors. Human calcitonin fragments had no effect on adenylate cyclase activity. 7. Salmon calcitonin-stimulated adenylate cyclase activity decreased with the preincubation time. This was due to progressive degradation of the hormone and not to the rate of binding to membrane receptors.     

Altered G-protein expression and adenylate cyclase activity in platelets of non-insulin-dependent diabetic (NIDDM) male subjects

Adenylate cyclase activity and levels of guanine nucleotide regulatory proteins (G-proteins) were compared in platelets from normal and non-insulin-dependent diabetic (NIDDM) male subjects. Whilst no differences were noted in basal and NaF-stimulated adenylate cyclase activities the degree of stimulation achieved by both forskolin and prostaglandin, E1 was lower by some 34 and 52% respectively, in platelet membranes from diabetic subjects compared with those from normal control subjects. Altered alpha 1-adrenoceptor-mediated inhibition of prostaglandin E1-stimulated adenylate cyclase activity was evident; it being some 34% lower in platelet membranes from diabetic subjects compared to controls. Analysis of G-protein alpha-subunits, using specific anti-peptide antisera, showed that platelets from all subjects exhibited the Gi-2 and Gi-3, but not the Gi-1 forms of the inhibitory G-protein 'Gi' and all expressed the 42 kDa species of alpha-subunit of the stimulatory G-protein Gs. Whilst platelets of diabetic subjects had levels of Gs which were comparable to those found in control subjects their levels of Gi-2 and Gi-3 were some 49 and 75%, respectively, of those found in platelets from control subjects. It is suggested that changes in adenylate cyclase functioning and G-protein expression may contribute to altered platelet functioning in non-insulin-dependent diabetic subjects.     

Uncoupling of alpha-adrenoceptor-mediated inhibition of human platelet adenylate cyclase by N-ethylmaleimide

Human platelet adenylate cyclase is stimulated by prostaglandin E1 (PGE1) and is inhibited by epinephrine via alpha-adrenoceptors. Both agonists, epinephrine more than PGE1, increase the activity of a low Km GTPase in platelet membranes. Pretreatment of intact platelets or platelet membranes with the sulfhydryl reagent, N-ethylmaleimide (NEM), abolished the inhibition of the adenylate cyclase and the concomitant stimulation of the GTPase by epinephrine. In contrast, stimulation of the adenylate cyclase by PGE1 was not affected or even increased by NEM pretreatment; only at high NEM concentrations were both basal and PGE1-stimulated activities decreased. Similarly, the PGE1-induced activation of the low Km GTPase was not or was only partially reduced by NEM. Adenylate cyclase activation by stable GTP analogs, NaF, and cholera toxin was also not decreased by NEM pretreatment. Exposure of intact platelets to NEM did not reduce alpha-adrenoceptor number and affinities for agonists and antagonists, as determined by [3H]yohimbine binding in platelet particles. The data indicate that NEM uncouples alpha-adrenoceptor-mediated inhibition of platelet adenylate cyclase, leaving the receptor recognition site and the adenylate cyclase itself relatively intact. Although the effect of NEM may be based on a reaction with the alpha-adrenoceptor site interacting with a coupling component, the selective loss of the adenylate cyclase inhibition together with an even increased stimulation of the enzyme by PGE1 suggests that there are two at least partially distinct regulatory sites involved in opposing hormonal regulations of adenylate cyclase activity, with that involved in hormonal inhibition being highly susceptible to inactivation by NEM.     

Calmodulin regulation of adenylate cyclase activity in human platelet membranes

The mechanism of calmodulin dependent regulation of adenylate cyclase has been studied in human platelet membranes. Calmodulin activated adenylate cyclase exhibited a biphasic response to both Mg2+ and Ca2+. A stimulatory effect of Mg2 on adenylate cyclase was observed at all Mg2+ concentrations employed, although the degree of activation by calmodulin was progressively decreased with increasing concentrations of Mg2+. These results demonstrate that the Vmax of calmodulin dependent platelet adenylate cyclase can be manipulated by varying the relative concentrations of Mg2+ and Ca2+. The activity of calmodulin stimulated adenylate cyclase was always increased 2-fold above respective levels of activity induced by GTP, Gpp(NH)p and/or PGE. The stimulatory influence of calmodulin was not additive but synergistic to the effects of PGE1, GTP and Gpp(NH)p. GDP beta S inhibited GTP-and Gpp(NH)p stimulation of adenylate cyclase but was without effect on calmodulin stimulation. Since the inhibitory effects of GDP beta S have been ascribed to apparent reduction of active N-protein-catalytic unit (C) complex formation, these results suggest that the magnitude of calmodulin dependent adenylate cyclase activity is proportional to the number of N-protein-C complexes, and that calmodulin interacts with preformed N-protein-C complex to increase its catalytic turnover. Our data do not support existence of two isoenzymes of adenylate cyclase (calmodulin sensitive and calmodulin insensitive) in human platelets.     

Modulation of adenylate cyclase activity by sulfated glycosaminoglycans. II. Effects of mucopolysaccharides and dextran sulfate on the activity of adenylate cyclase derived from various tissues.

Heparin was found to be the most potent inhibitor of rat ovarian luteinizing hormone-sensitive adenylate cyclase (I50 = 2 microgram/ml) when compared to other naturally occurring glycosamin oglycans. This inhibition was also apparent when this enzyme was stimulated by follicle-stimulating hormone or prostaglandin E2. Heparin was also found to inhibit glucagon-sensitive rat hepatic adenylate cyclase, and the prostaglandin E1-sensitive enzyme from rat ileum and human platelets. In contrast, heparin stimulated the dopamine sensitive adenylate cyclase from rat caudate nucleus. The sulfated polysugar dextran sulfate exerts similar effects on adenylate cyclase activity of the rat ovary and was shown to inhibit hormone binding to rat ovarian plasma membrane in a manner similar to that exerted by heparin. In contrast to heparin, dextran sulfate inhibited dopamine-sensitive adenylate cyclase from rat caudate nucleus.     

Adenylate cyclase activity in lymphocyte subcellular fractions. Characterization of a nuclear adenylate cyclase.

Nuclei from purified human peripheral lymphocytes were prepared by incubations with Triton X-100 to disrupt the cells, followed by sucrose-density gradient centrifugation. The nuclei were pure as judged by phase-contrast microscopy and had low contents of non-nuclear marker enzymes. In addition, nuclei prepared from lymphocytes surface-labelled with 125I had only 2-7% of the radioactivity bound to intact lymphocytes. At 3.3 mM-Ca2+ and 100 micronM-ATP a fluoride-sensitive adenylate cyclase was demonstrated in nuclei prepared in 0.2% Triton X-100 or 0.33% Triton X-100. There was linear accumulation of cyclic AMP for 10 min in both preparations. The apparent Km for ATP was 90 micronM. Adenylate cyclase activity was augmented by 1.0 mM-Mn2+ and inhibited at higher concentrations. Ca2+ showed two peaks of stimulation, at 1.0-2.5 mM- and above 10 mM-Ca2+. Mg2+ was inhibitory at all concentrations. EDTA OR EGTA only slightly decreased adenylate cyclase activity, suggesting that another metal ion may be necessary for activity. Adenylate cyclase activity was stimulated by 10mM-isoproterenol and 10 micronM-adrenaline in the presence of a phosphodiesterase inhibitor. Phytohaemagglutinin and prostaglandin E1 alone or in combination with isoproterenol had no effect on nuclear adenylate cyclase activity in either nuclei preparation. These results indicate that human lymphocyte nuclei contain one or several adenylate cyclases which differ from adenylate cyclases found in other subcellular fractions of these cells with regard to their bivalentcation requirements and responsiveness to pharmacological agents.     

Multiple effects of guanine nucleotides on human platelet adenylated cyclase.

We report that the adenylate cyclase system in human platelets is subject to multiple regulation by guanine nucleotides. Previously it has been reported that GTP is either required for or has little effect on the response of the enzyme to prostaglandin E1. We have found that when platelet lysates were prepared in the presence of 5 mM EDTA, GTP lowered the basal and prostaglandin E1-stimulated adenylate cyclase activity, but at a higher concentration of Mn2+, it caused an increase in enzyme activity exceeding that occurring in the presence of prostaglandin E1. In the presence of Mn2+, dGTP mimics the effect of GTP and is 50% as effective as GTP. Our data suggest that the inhibitory effect of GTP on prostaglandin E1-stimulated adenylate cyclase is mainly due to its direct effect on the enzyme itself, whereas the stimulatory effect of GTP on prostaglandin E1-stimulated adenylate cyclase is due to enhancement of the coupling between the prostaglandin E1 receptor and adenylate cyclase. These studies also indicate that the method of preparation of platelet lysates can profoundly alter the nature of guanine nucleotide regulation of adenylate cyclase.     

Cytochemical localization of adenylate cyclase and of calcium ion, magnesium ion-activated ATPases in the dense tubular system of human blood platelets.

Cytochemical techniques have been employed to study the localization of adenylate cyclase and (Ca2+ + Mg2+)-stimulated ATPase activities in platelets after fixation. Biochemical analysis of adenylate cyclase demonstrated a 70% reduction in activity in homogenates from fixed cells, but the residual activity could be stimulated 10--20 times by prostaglandin E1 (1 micrometer) under the same incubation conditions as employed in the cytochemical studies (e.g. media containing 2 mM lead nitrate and 10 mM NaF). Adenylate cyclase activity employing 5'-adenylyl-imiodiphosphate (AMP-P(NH)P) as substrate was found to be associated with the dense tubular system (smooth endoplasmic reticulum) in intact fixed platelets, and was apparent only when the cells were incubated with prostaglandin E1. Less activity was found along the membranes of the surface connected open canalicular system and occasionally at the outer cell surface. Enzymatic activity was blocked by the adenylate cyclase inhibitor 9-(tetrahydro-2-furyl) adenine and was not due to AMP-P(NH)P phosphohydrolase activity. The low adenylate cyclase activity in the surface membranes may be due to enzyme inactivation as a result of fixation, since a surface membrane fraction obtained by the glycerol lysis technique from unfixed cells had an adenylate cyclase specific activity equivalent to that in the microsomal membrane fraction. (Ca2+ + Mg2+)-stimulated ATPase activity was found associated with the membranes of the surface connected open canalicular system in unfixed cells. After brief fixation (5--15 min) with glutaradehyde, strong (Ca2+ + Mg2+)ATPase activity became apparent in the dense tubular system. Longer periods of fixation inactivated enzymatic activity. Addition of Ca2+ (1.0 mM) to incubation medium with low Mg2+ (0.2 mM), or increasing Mg2+ to 4.0 mM, in both cases strongly stimulated enzyme activity. The ATPase activity in the platelet membranes was not inhibited by ouabain. It is suggested that the Ca2+-stimulated ATPase and adenylate cyclase activities in the dense tubules may possibly be involved in regulation of intracellular Ca2+ transport.