Effects of egg factors on cyclic nucleotide metabolism in sea urchin sperm.

Cyclic AMP in Strongylocentrotus purpuratus sperm was elevated approximately 2-fold by theophylline or 1-methyl-3-isobutylxanthine. Factors released from sea urchin eggs (FRE) elevated sperm cyclic AMP by about 7-fold within 1 min, and the combination of FRE with theophylline increased sperm cyclic AMP up to 100-fold within 1 min. Cyclic GMP in sea urchin sperm was slightly elevated by theophylline, but was lowered by FRE. Cyclic GMP in sperm treated with FRE plus theophylline was not higher than in sperm treated with theophylline alone. The ability of FRE-containing sea water to increase sperm cyclic AMP in the presence of theophylline was altered only slightly if at all by boiling, but it was decreased by about 50% by dialysis and destroyed by ashing. Filtration of FRE on Sephadex G-50 columns yielded two peaks of cyclic AMP-elevating activity. One peak (peak I) was eluted at the column void volume, and the other (peak II) was retained by the column. The cyclic GMP-lowering activity was located in fractions approximately corresponding to peak I of cyclic AMP-elevating activity. Dialysis of FRE-containing sea water before its application to the G-50 column virtually eliminated peak II of the cyclic AMP-elevating activity. When the cyclic AMP-elevating activity in peak I was filtered on Bio Gel A-5m columns, it also migrated at or near the column void volume. Fractions corresponding to peak I contained material that inhibited both guanylate and adenylate cyclase activities in broken cell preparations of sperm and guanylate cyclase from rat lung. The inhibitory material was stable to boiling, non-dialyzable, and destroyed by ashing. Under a variety of conditions, FRE-containing sea water or cyclic AMP-elevating peaks I or II did not stimulate sperm adenylate cyclase activity in broken cell preparations.     

The periodic change in adenosine 3',5'-monophosphate concentration in sea-urchin eggs

The level of adenosine 3',5'-monophosphate (cyclic AMP) in the eggs of the sea urchin, Anthocidaris crassispina, was found to change periodically after fertilization. The minimum and maximum levels of cyclic AMP were 1.0 X 10(-7)M and 1.5 X 10(-6)M, respectively. The activity of adenylate cyclase in a 105 000 X g precipitate reached a plateau at 20 min after fertilization and stayed constant for at least 2 h. It was also found that 1.0 mM CaCl2 increased the activity of adenylate cyclase in the same precipitate from unfertilized eggs. In contrast, phosphodiesterase activity changed periodically and correlated with cyclic AMP levels in the eggs. Up to a concentration of 1.5 X 10(-6)M cyclic AMP, phosphodiesterase activity was low, but it became activated when the level of cyclic AMP rose beyond this level. These results indicate that the change in the intracellular level of cyclic AMP is regulated mainly by the change in phosphodiesterase activity.     

The periodic change in adenosine 3′,5′-monophosphate concentration in sea-urchin eggs

The level of adenosine 3′,5′-monophosphate (cyclic AMP) in the eggs of the sea urchin, Anthocidaris crassispina, was found to change periodically after fertilization. The minimum and maximum levels of cyclic AMP were 1.0·10^?7 M and 1.5·10^?6 M, respectively. The activity of adenylate cyclase in a 105 000 × g precipitate reached a plateau at 20 min after fertilization and stayed constant for at least 2 h. It was also found that 1.0 mM CaCl₂ increased the activity of adenylate cyclase in the same precipitate from unfertilized eggs. In contrast, phosphodiesterase activity changed periodically and correlated with cyclic AMP levels in the eggs. Up to a concentration of 1.5·10^?6 M cyclic AMP, phosphodiesterase activity was low, but it became activated when the level of cyclic AMP rose beyond this level. These results indicate that the change in the intracellular level of cyclic AMP is regulated mainly by the change in phosphodiesterase activity.     

Enzymes of cyclic nucleotide metabolism in invertebrate and vertebrate sperm.

Sperm from several invertebrates contained guanylate cyclase activity several-hundred-fold greater than that in the most active mammalian tissues; the enzyme was totally particulate. Activity in the presence of Mn²⁺ was up to several hundred-fold greater than with Mg²⁺ and was increased 3–10-fold by Triton X-100. Sperm from several vertebrates did not contain detectable guanylate cyclase. Sperm of both invertebrates and vertebrates contained roughly equal amounts of Mn²⁺-dependent adenylate cyclase activity; in invertebrate sperm, this enzyme was generally several hundred-fold less active than guanylate cyclase. Adenylate cyclase was particulate, was unaffected by fluoride, and was generally greater than 10-fold more active with Mn²⁺ than with Mg²⁺. Invertebrate sperm contained phosphodiesterase activities against 1.0 μm cyclic GMP or cyclic AMP in amounts greater than mammalian tissues. Fish sperm, which did not contain guanylate cyclase, had high phosphodiesterase activity with cyclic AMP as substrate but hydrolyzed cyclic GMP at a barely detectable rate. In sea urchin sperm, phosphodiesterase activity against cyclic GMP was largely particulate and was strongly inhibited by 1.0% Triton X-100. In contrast, activity against cyclic AMP was largely soluble and was weakly inhibited by Triton. The cyclic GMP and cyclic AMP contents of sea urchin sperm were in the range of 0.1–1 nmol/g. Sea urchin sperm homogenates possessed protein kinase activity when histone was used as substrate; activities were more sensitive to stimulation by cyclic AMP than by cyclic GMP.⁵     

Enzymatic formation of inosine 3',5'-monophosphate and of 2'-deoxyguanosine 3',5'-monophosphate. Inosinate and deoxyguanylate cyclase activity.

Enzymes in particulate fractions from sea urchin sperm and in soluble fractions from rat lung were shown to catalyze the formation of inosine 3',5'-monophosphate (cyclic IMP) and of 2'-deoxyguanosine 3',5'-monophosphate (cyclic dGMP) from ITP and dGTP, respectively. With sea urchin sperm particulate fractions, Mn2+ was an essential metal cofactor for inosinate, deoxyguanylate, guanylate and adenylate cyclase activities. Heat-inactivation studies differentiated inosinate and deoxyguanylate cyclase activities from adenylate cyclase, but indicated an association of these activities with guanylate cyclase. Preincubation of sea urchin sperm particulate fractions with trypsin altered in a very similar manner guanylate, inosinate, and deoxyguanylate cyclase activities, and various metals and metal-nucleotide combinations protected the three cyclase activities to comparable degrees against trypsin. The relative guanylate, deoxyguanylate and inosinate cyclase activities at 0.1 mM nucleoside triphosphate were 1.0, 0.5 and 0.08, respectively. With these three cyclase activities, plots of reciprocal velocities against reciprocal Mn2+-nucleoside triphosphate concentrations were concave upward, suggesting positive homotropic effects. With rat lung soluble preparations, relative guanylate, deoxyguanylate, inosinate and adenylate cyclase activities at 0.09 mM nucleoside triphosphate were 1.0, 1.7, 0.1 and 0, respectively. MnGTP was a competitive inhibitor of deoxyguanylate cyclase activity (Ki equals 12.2 muM) and MndGTP was a competitive inhibitor of guanylate cyclase activity (Ki equals 16.2 muM). Inhibition studies using ITP were not conducted. When soluble fractions from rat lung were applied to Bio-Gel A 1.5 m columns, elution profiles of guanylate, deoxyguanylate and inosinate cyclase activities were similar. These results suggest that deoxyguanylate, guanylate and inosinate cyclase activities reside within the same protein molecule.     

A single column method for the assay of adenylate cyclase

An improved, one-step method for the separation of cyclic AMP from other nucleotides on disposable columns of neutral aluminum oxide is described. The method consists of several modifications of an established assay for adenylate cyclase. These modifications were designed to increase the sensitivity of the method, to decrease the time required for column preparation, and to eliminate the variable elution patterns for cyclic AMP that are obtained when using aluminum oxide from different commercial sources. Uniform elution patterns and high recoveries (approximately 80%) of cyclic AMP were obtained when 0.1 M ammonium acetate was used to elute cyclic AMP instead of Tris-HCl buffer. Prior to column chromatography, the adenylate cyclase reactions were terminated with the addition of hydrochloric acid and the mixtures were heated to degrade acid-labile nucleotides that would otherwise elute with cyclic AMP from aluminum oxide columns. Disposable polypropylene columns, fabricated with a reservoir and fast-flow filters, were used for column chromatography. Low blank values, generally less than 15 dpm/assay tube, were obtained when the acidified reaction mixtures were applied directly to aluminum oxide columns without prior neutralization. The proposed method should be useful for the routine assay of adenylate cyclase activity.     

Nerve Growth Factor Affects Cyclic AMP Metabolism, but Not by Directly Stimulating Adenylate Cyclase Activity

Published experiments both support and contradict the hypothesis that nerve growth factor (NGF) can regulate adenylate cyclase activity. Using a sensitive assay that measures the conversion of [2-3H]adenine to [3H]cyclic AMP, we have shown that NGF alone cannot measurably stimulate cyclic AMP production, whereas the adenosine analog phenylisopropyladenosine (PIA) stimulates adenylate cyclase 20-fold over basal activity. NGF potentiates the capacity of both PIA and cholera toxin to stimulate cyclic AMP accumulation at all concentrations tested. This potentiation occurs at the earliest measurable times and does not require RNA synthesis. Therefore, we conclude that cyclase activation alone does not account for the effect of NGF on cyclic AMP accumulation and we discuss possible mechanisms.     

Resensitization of hepatocyte glucagon-stimulated adenylate cyclase can be inhibited when cyclic AMP phosphodiesterase inhibitors are used to elevate intracellular cyclic AMP concentrations to supraphysiological values.

Treatment of intact hepatocytes with glucagon led to the rapid desensitization of adenylate cyclase, which reached a maximum around 5 min after application of glucagon, after which resensitization ensued. Complete resensitization occurred some 20 min after the addition of glucagon. In hepatocytes which had been preincubated with the cyclic AMP phosphodiesterase inhibitor 3-isobutyl-1-methylxanthine (IBMX), glucagon elicited a stable desensitized state where resensitization failed to occur even 20 min after exposure of hepatocytes to glucagon. Treatment with IBMX alone did not elicit desensitization. The action of IBMX in stabilizing the glucagon-mediated desensitized state was mimicked by the non-methylxanthine cyclic AMP phosphodiesterase inhibitor Ro-20-1724 [4-(3-butoxy-4-methoxylbenzyl)-2-imidazolidinone]. IBMX inhibited the resensitization process in a dose-dependent fashion with an EC50 (concn. giving 50% of maximal effect) of 26 +/- 5 microM, which was similar to the EC50 value of 22 +/- 6 microM observed for the ability of IBMX to augment the glucagon-stimulated rise in intracellular cyclic AMP concentrations. Pre-treatment of hepatocytes with IBMX did not alter the ability of either angiotensin or the glucagon analogue TH-glucagon, ligands which did not increase intracellular cyclic AMP concentrations, to cause the rapid desensitization and subsequent resensitization of adenylate cyclase. It is suggested that, although desensitization of glucagon-stimulated adenylate cyclase is elicited by a cyclic AMP-independent process, the resensitization of adenylate cyclase can be inhibited by a process which is dependent on elevated cyclic AMP concentrations. This action can be detected by attenuating the degradation of cyclic AMP by using inhibitors of cyclic AMP phosphodiesterase.     

Adenosine potentiates lutropin-stimulated cyclic AMP production and inhibits lutropin-induced desensitization of adenylate cyclase in rat Leydig tumour cells.

The action of adenosine on lutropin (LH)-stimulated cyclic AMP production and LH-induced desensitization of adenylate cyclase in rat Leydig tumour cells was investigated. Adenosine and N6-(phenylisopropyl)adenosine caused a dose-dependent potentiation of LH-stimulated cyclic AMP production at concentrations (0.01-10 microM) which alone did not produce an increase in cyclic AMP production. However, 2-deoxyadenosine had no effect either alone or in combination with LH on cyclic AMP production. The potentiation produced by adenosine was unaffected by concentrations of the specific nucleoside-transport inhibitor dipyridamole, which inhibited [3H]adenosine uptake by up to 90%. The phosphodiesterase inhibitor 3-isobutyl-l-methylxanthine, but not RO-10-1724, inhibited the adenosine-induced potentiation. In the presence of adenosine, the kinetics of LH-stimulated cyclic AMP production were linear with time up to 2h, compared with those with LH alone, which showed a characteristic decrease in rate of cyclic AMP production after the first 15-20 min. Consistent with the altered kinetics, adenosine also inhibited the LH-induced desensitization of adenylate cyclase. These results suggest that adenosine has effects on rat tumour Leydig cells through receptors on the external surface of the plasma membrane. This receptor has characteristics similar to those of the R-type receptors, which have been shown either to stimulate or to inhibit adenylate cyclase. However, the effects of adenosine in the present studies does not involve a direct inhibition or activation of adenylate cyclase, but may involve an as yet undefined receptor-mediated modulation of adenylate cyclase.     

Effects of glucose, glucose metabolites and calcium ions on adenylate cyclase activity in homogenates of mouse pancreatic islets.

The effects of glucose, a series of glucose metabolites, nicotinamide nucleotides, Ca2+ and p-chloromercuribenzenesulphonate on adenylate cyclase activity in homogenates of mouse pancreatic islets were studied. The basal activity of the adenylate cyclase was approx. 6 pmol of cyclic AMP formed/30 min per microng of DNA at 30 degrees C. The enzyme activity was stimulated by some 150% by fluoride. Starvation of the animals for 48h had no effect on either the basal or the fluoride-stimulated activity. The adenylate cyclase activity was increased by 40-50% when 17 mM-glucose, 10 micronM-phosphoenolpyruvate or 10 micronM-pyruvate was added to the assay medium. The effect of glucose was unchanged in the presence of 17 mM-mannoheptulose, and mannoheptulose alone had no effect. The other glycolytic intermediates, and the coenzymes NAD+, NADH and NADPH, at concentrations up to 1 mM were without any detectable effect on the rate of formation of cyclic AMP. The insulin secretagogue p-chloromercuribenzenesulphonate inhibited the adenylate cyclase markedly even at a concentration of 10 micronM. Calculated concentrations of free Ca2+ of 10 micronM and 0.1 mM inhibited adenylate cyclase by 29 and 71% respectively. It is concluded that both glucose itself and phosphoenolpyruvate and/or pyruvate are true activating ligands for islet and adenylate cyclase and that inhibition of the cyclase by Ca2+ may be of physiological significance.     

Stimulation by glucose of cyclic AMP accumulation in mouse pancreatic islets is mediated by protein kinase C.

The mechanism of glucose-stimulated cyclic AMP accumulation in mouse pancreatic islets was studied. In the presence of 3-isobutyl-1-methylxanthine, both glucose and the phorbol ester 12-O-tetradecanoylphorbol 13-acetate (TPA), an activator of protein kinase C, enhanced cyclic AMP formation 2.5-fold during 60 min of incubation. Both TPA-stimulated and glucose-stimulated cyclic AMP accumulations were abolished by the omission of extracellular Ca2+. The Ca2+ ionophore A23187 did not affect cyclic AMP accumulation itself, but affected the time course of TPA-induced cyclic AMP accumulation, the effect of A23187 + TPA mimicking the time course for glucose-induced cyclic AMP accumulation. A 24 h exposure to TPA, which depletes islets of protein kinase C, abolished the effects of both TPA and glucose on cyclic AMP production. Both TPA-induced and glucose-induced cyclic AMP productions were inhibited by anti-glucagon antibody, and after pretreatment with this antibody glucose stimulation was dependent on addition of glucagon. Pretreatment of islets with TPA for 10 min potentiated glucagon stimulation and impaired somatostatin inhibition of adenylate cyclase activity in a particulate fraction of islets. Carbamoylcholine, which is supposed to activate protein kinase C in islets, likewise stimulated cyclic AMP accumulation in islets. These observations suggest that glucose stimulates islet adenylate cyclase by activation of protein kinase C, and thereby potentiates the effect of endogenous glucagon on adenylate cyclase.     

Inhibition of prostaglandin E1-induced activation of adenylate cyclase in human blood platelet membrane

Activation of human blood platelet adenylate cyclase is initiated through the binding of prostaglandin E1 to the membrane receptors. Incubation of platelet membrane with [3H]prostaglandin E1 at pH 7.5 in the presence of 5 mM MgCl2 showed that the binding of the autacoid was rapid, reversible and highly specific. The binding was linearly proportional to the activation of adenylate cyclase. Although the membrane-bound radioligand could not be removed either by GTP or its stable analogue 5'-guanylylimido diphosphate, 150 nM cyclic AMP displaced about 40% of the bound agonist from the membrane. Scatchard analyses of the binding of the prostanoid to the membrane in the presence or absence of cyclic AMP showed that the nucleotide specifically inhibited the high-affinity binding sites without affecting the low-affinity binding sites. Incubation of the membrane with 150 mM cyclic AMP and varying amounts of prostaglandin E1 (25 nM to 1.0 microM) showed that the percent removal of the membrane-bound autacoid was similar to the percent inhibition of adenylate cyclase at each concentration of the agonist. At a concentration of 25 nM prostaglandin E1, both the binding of the agonist and the activity of adenylate cyclase were maximally inhibited by 40%. With the increase of the agonist concentration in the assay mixture, the inhibitory effects of the nucleotide gradually decreased and at a concentration of 1.0 microM prostaglandin E1 the effect of the nucleotide became negligible. These results show that cyclic AMP inhibits the activation of adenylate cyclase by low concentrations of prostaglandin E1 through the inhibition of the binding of the agonist to high-affinity binding sites.     

Neuroblastoma cell adenylate cyclase: direct activation by adenosine and prostaglandins.

—Adenylate cyclase activity of permeabilized neuroblastoma cells was measured by the conversion of [α³²P]ATP into labelled cyclic AMP. Adenosine (10^?6 - 10^?4m ) induced a dose-dependent increase in cyclic AMP formation. This effect could not be accounted for either by an adenosine-induced inhibition of the phosphodiesterase activity present in the enzyme preparation, or by a direct conversion of adenosine into cyclic AMP. This indicates that the observed increase in cyclic AMP accumulation reflected an activation of adenylate cyclase. Adenosine is partially metabolized during the course of incubation with the enzyme preparation. However, none of the identified non-phosphorylated adenosine metabolites were able to induce an adenylate cyclase activation. This suggests that adenosine itself is the stimulatory agent. The apparent K_m of the adenylate cyclase for adenosine was 5 ± 10^?6-10^?5m . Maximal activation represented 3-4 times the basal value (10-100 pmol cyclic AMP formed/10 min/mg protein). The adenosine effect was stereospecific, since structural analogues of adenosine were inactive. Adenosine increased the maximal velocity of the adenylate cyclase reaction. The stimulatory effect of adenosine was inhibited by theophylline. Prostaglandin PGE₁ had a stimulatory effect much more pronounced than that of adenosine (6-10-fold the basal value at 10^?6m ). Dopamine and norepinephrine induced a slight adenylate cyclase activation which was not potentiated by adenosine. It is concluded that adenosine is able to activate directly neuroblastoma cell adenylate cyclase. It seems very likely that such a direct activation is also present in intact nervous tissue and account, at least partly, for the observed cyclic AMP accumulation in response to adenosine.     

Inhibition of cholera toxin-stimulated intestinal epithelial cell adenylate cyclase by adenosine analogs.

The ability of various adenosine analogs to inhibit cholera toxin activation of the intestinal epithelial cell adenylate cyclase-cyclic AMP system was investigated. After incubation of cells with cholera toxin for 6 hr, large increases in cellular cyclic AMP content were observed. Addition of 2', 5'-dideoxyadenosine during the last 30 min of this 6-hr incubation resulted in 70% reduction in elevated cyclic AMP content. Other analogs were not effective inhibitors. 2', 5'-Dideoxyadenosine was also a potent inhibitor of cholera toxin-activated intestinal cell adenylate cyclase activity with half-maximal inhibition occuring at 16 muM. NaF-stimulated cyclase was less susceptible to inhibition. The data suggest that inhibition by 2', 5'-dideoxyadenosine is due at least in part to direct inhibition of the cholera toxin-activated intestinal adenylate cyclase activity.     

Subcellular localizations of guanylate cyclase and 3',5'-cyclic nucleotide phosphodiesterase in sea urchin sperm.

The subcellular localizations of guanylate cyclase and 3',5'-cyclic nucleotide phosphodiesterase in sea urchin sperm were examined. Both the specific and total activities of these two enzymes were much higher in sperm flagella (tails) than in the heads. In addition to the observation that guanylate cyclase in the flagella was particulate-bound and solubilized by Triton X-100, more than 80% of the cyclase activity in the flagella was found in the plasma membrane fraction, whereas the activity of cyclic nucleotide phosphodiesterase was observed in both the axonemal and plasma membrane fractions. The observations indicated that the cyclase in the flagella appeared to be associated with the plasma membrane. Cyclic nucleotide phosphodiesterase in the plasma membrane fraction as well as the axonemal fraction hydrolyzed both cyclic GMP and cyclic AMP; however, the rates of hydrolysis for cyclic GMP were obviously higher than those for cyclic AMP. The enzymic properties of guanylate cyclase and cyclic nucleotide phosphodiesterase in sperm flagella were also briefly described.     

A dopamine sensitive adenylate cyclase in the salivary glands of Amblyomma americanum (L.)

1. Enzyme activity, basal or dopamine-stimulated (10 microM), was linear with time to 25 min and with protein concentration to 0.8 mg protein/ml of final assay volume. Activity was maximal between pH 7.0 and 7.5. 2. Mg2+ maximally stimulated basal or dopamine-sensitive adenylate cyclase activity at about 4 mM. 3. Adenylate cyclase had a Km of 0.042 mM for ATP and maximum velocities for basal and dopamine-stimulated activity of 107 and 179 pmol cyclic AMP formed/mg protein per min, respectively. 4. Half-maximal stimulation of the enzyme occurred at about 4.2 x 10(-7) M dopamine with the threshold being less than 10(-9) M. Dopamine increased the Vmax but had no effect on the Km of ATP. 5. Eighty-five to 90% of the adenylate cyclase activity was found in the particulate fraction. 6. Calcium ion produced a marked inhibition of adenylate cyclase activity above 0.04 mM and half-maximal inhibition occurred near 0.1-0.2 mM.     

Effect of Ricinus communis toxin on cyclic adenosine 3':5'-monophosphate metabolism in Yoshida ascites sarcoma cells.

Prostaglandin E1 (2.5 mug/ml) enhanced the level of cyclic adenosine 3':5'-monophosphate (cyclic AMP) three to four times in Yoshida ascites sarcoma (YS) cells cultured in vitro. When Ricinus communis toxin (RC-toxin) was added 30 min after the addition of prostaglandin E1, the enhanced level of cyclic AMP in the YS cells decreased rapidly. Of RC-toxin, 0.2 mug/ml was enough to produce the maximum effect. By addition of 5 mM lactose with RC-toxin, approximately 60% of the RC-toxin effect on the levels of cyclic AMP was abolished. This indicates that the specific binding of RC-toxin on the surface membrane is largely responsible for the observed decrease of the cyclic AMP level. The toxin treatment did not induce either leakage of cyclic AMP from the cell or change in the activity of cyclic AMP phosphodiesterase. However, the treatment of YS cells with RC-toxin caused a decrease of adenylate cyclase activity when the activity was measured at a substrate concentration of 0.15 mM ATP. In contrast, there was little difference with the control when the activity was assayed at a higher ATP concentration, 0.24 mM. It was found that the K-m of adenylate cyclase for ATP was changed by RC-toxin from 0.1 to 0.25 mM, and that the Mg2+ activation of the enzyme observable in untreated cells disappeared. These results suggested that the decrease in the level of cyclic AMP in YS cells induced by RC-toxin can be explained in terms of the change in K-m of the adenylate cyclase activity.     

Adenylate cyclase from sea urchin eggs is positively and negatively regulated by D-1 and D-2 dopamine receptors

The adenylate cyclase present in membranes prepared from sea urchin eggs is sensitive to dopamine stimulation. The receptor sites coupled to sea urchin adenylate cyclase were characterized by means of specific agonists and antagonists. The D-1 dopamine agonist SKF-38393 was able to stimulate enzyme activity, while the two D-1 dopamine antagonists, SCH-23390 and SKF-83566, suppressed the stimulatory effect of dopamine. In addition, the D-2 dopamine agonists, PPHT and metergoline, brought about a dose-dependent inhibition of dopamine-stimulated adenylate cyclase activity. These data show that: (i) in sea urchin eggs adenylate cyclase is regulated by dopamine receptors; (ii) these receptors share characteristics with D-1 and D-2 dopamine receptors present in the mammalian brain.     

Subcellualr localizations of guanylate cyclase and 3′,5′-cyclic nucleotide phophodiesterase in sea urchin sperm

The subcellular localizations of guanylate cyclase and 3′,5′-cyclic nucleotide phophodiesterase in sea urchin sperm were examined. Both the specific and total activities of these two enzymes were much higher in sperm flagella (tails) than in the heads. In addition to the observation that guanylate cyclase in the flagella was particulate-bound and solubilized by Triton X-100, more than 980% of the cyclase activity in the flagella was found in the plasma membrane fraction, whereas the activity of cyclic nucleotide phosphodiesterase was observed in both the axonemal and plasma membrane fractions. The observations indicated that the cyclase in the flagella appeared to be associated with the plasma membrane. Cyclic nucleotide phosphodiesterase in the plasma membrane fraction as well as the axonemal fraction hydrolyzed both cyclic GMP and cyclic AMP; however, the rates of hydrolysis for cyclic GMP were obviously higher than those for cyclic AMP. The enzymic properties of guanylate cyclase and cyclic nucelotide phosphodiesterase in sperm flagella were also briefly described.     

Formation of adenosine 3',5'-monophosphate from adenosine in mouse thymocytes.

The effect of adenosine on the mouse thymocyte adenylate cyclase-adenosine 3':5'-monophosphate (cyclic AMP) system was examined. Adenosine, like prostaglandin E1, can cause 5-fold or greater increases in thymocyte cyclic AMP content in the presence but not in the absence of certain cyclic phosphodiesterase inhibitors. Two non-methylxanthine inhibitors potentiated the prostaglandin E1 and adenosine responses, while methylxanthines selectively inhibited the adenosine response. Adenosine increased cyclic AMP content significantly within 1 min and was maximal by 10 to 20 min with approx. 2 and 10 muM adenosine being minimal and half-maximal effective doses, respectively. Combinations of prostaglandin E1, isoproterenol and adenosine were near additive and not synergistic. Of the adenosine analogues tested, only 2-chloro- and 2-fluoroadenosine significantly increased cyclic AMP. Thymocytes prelabeled with [14C]adenine exhibited dramatic increases in cyclic [14C]AMP 10 min after addition of adenosine or prostaglandin E1 which corresponded to simultaneously determined increases in total cyclic AMP. Using [14C]adenosine, the percent of total cyclic AMP increase due to adenosine was only 16%. Adenosine was also shown to elicit a 40% increase in particulate thymocyte adenylate cyclase activity. Therefore, the increased content of cyclic AMP seen in mouse thymocytes after incubation with adenosine was due primarily to stimulation of adenylate cyclase and only partially to conversion of adenosine to cyclic AMP. The increased cellular content of cyclic AMP may be, in part, responsible for various immunosuppressive effects of adenosine.