Two types of cyclic GMP binding site associated with the cyclic AMP-dependent protein kinase from lymphocytes

Low- and high-affinity binding sites for cyclic GMP were found to be associated with the cyclic AMP-dependent protein kinase (ATP: protein phosphotransferase, EC 2.7.1.37) from human tonsillar lymphocytes, but neither of them was identical with the cyclic AMP binding site.The enzyme activated by cyclic GMP phosphorylated the same site of calf thymus H2b histone as the cyclic AMP activated enzyme; however, more complex kinetics of activation were found with cyclic GMP.Two classes of cyclic GMP binding site were demonstrated by kinetic analysis of cyclic [³H]GMP binding in the enzyme preparations eluted by 0.1 M potassium phosphate (pH 7.0) from DEAE cellulose. The high-affinity cyclic GMP binding site (K_d about 44 · 10^?8 M belonged to some complex form of the protein kinase, as evidenced by the mutual inhibition of cyclic AMP binding and high affinity cyclic GMP binding. However, the high-affinity cyclic GMP binding site disappeared on Sephadex G-100 gel chromatography of the enzyme preparation, whereas the cyclic AMP binding activity was recovered quantitively as separate fractions. The low-affinity cyclic GMP binding site (K_d 2–5 · 10^?6 M) was demonstrated by the inhibitory effect of 10^?5 M cyclic GMP on cyclic AMP binding in each cyclic AMP binding fraction obtained by gel chromatography. However, cyclic AMP did not inhibit the binding of cyclic GMP to the low-affinity binding site.     

Two types of cyclic GMP binding site associated with the cyclic AMP-dependent protein kinase from lymphocytes.

Low- and high-affinity binding sites for cyclic GMP were found to be associated with the cyclic AMP-dependent protein kinase (ATP: protein phosphotransferase, EC 2.7.1.37) from human tonsillar lymphocytes, but neither of them was identical with the cyclic AMP binding site. The enzyme activated by cyclic GMP phosphorylated the same site of calf thymus H2b histone as the cyclic AMP activated enzyme; however, more complex kinetics of activation were found with cyclic GMP. Two classes of cyclic GMP binding site were demonstrated by kinetic analysis of cyclic [3H]GMP binding in the enzyme preparations eluted by 0.1 M potassium phosphate (pH 7.0) from DEAE cellulose. The high-affinity cyclic GMP binding site (Kd about 4 . 10(-8) M) belonged to some complex form of the protein kinase, as evidenced by the mutual inhibition of cyclic AMP binding and high affinity cyclic GMP binding. However, the high-affinity cyclic GMP binding site disappeared on Sephadex G-100 gel chromatography of the enzyme preparation, whereas the cyclic AMP binding activity was recovered quantitively as separate fractions. The low-affinity cyclic GMP binding site (Kd 2--5 . 10(-6) M) was demonstrated by the inhibitory effect of 10(-5) M cyclic GMP on cyclic AMP binding in each cyclic AMP binding fraction obtained by gel chromatography. However, cyclic AMP did not inhibit the binding of cyclic GMP to the low-affinity binding site.     

An unusual cyclic AMP-dependent protein kinase from nematodes

The search for an unusual cyclic nucleotide-dependent protein kinase in nematodes represented an attempt to gain some insight into the proposed homology of the cAMP and cGMP-dependent protein kinases. Two species of protein kinase were found in high speed supernatants of the mycophagous nematode $\text{Aphelenchus}$$\text{avenae}$. One of the two, bound to DEAE cellulose and was eluted from it in a manner characteristic of the type I cAMP kinase. The enzyme had high affinity for cAMP and dissociated upon binding to the cyclic nucleotide, as judged by the fact that catalytic activity did not bind to a cAMP affinity column. The second enzyme did not bind to DEAE. Unexpectedly, it too had high affinity for cAMP and much lower affinity for cGMP (unlike the $\text{cAMP}\text{cGMP}$ kinase from insects). The holoenzyme bound tightly to the cAMP affinity column and required a high concentration of the cyclic nucleotide for elution. This latter enzyme is the only example of a cAMP-dependent protein kinase that does not dissociate upon activation.     

Reversible inhibition of cyclic AMP-dependent protein kinase by insulin

Summary Extracts of fasted rat diaphragms, previously treated with or without insulin were assayed for glycogen synthase, protein kinase and cyclic [³H]-AMP binding. Treatment with insulin produced an elevation in the % of glycogen synthase I and a concurrent decrease in cyclic AMP-dependent protein kinase activity and cyclic [³H]-AMP binding. Analysis of extracts by disc gel electrophoresis demonstrated the inhibition of cyclic [3H]-AMP binding to involve the Type I protein kinase holoenzyme. Inhibition of protein kinase activity was most apparent in the presence of 0.2 µM cyclic AMP, with enzymatic activity of the insulin-treated extracts typically 60–65% of control. Higher assay concentrations diminished the difference between control and insulin-treated extracts and concentrations greater than 20 µm abolished it.The inhibition of cyclic AMP-dependent protein kinase activity after insulin was a transient and labile phenomenon. The effect was independent of ATP concentration in the assay, but was sensitive to the pH of tissue extraction, requiring a pH of 7.0 to 8.4 to be observed.Insulin-mediated inhibition of protein kinase activity was reversed upon preincubation of extracts at 0–2°. Relatively concentrated homogenates (<4 µl buffer/mg tissue) yielded extracts which exhibited little or no inhibition of protein kinase activity compared to extracts prepared from more dilute (6–10 µl/mg) homogenates. A model for the inhibition of the cyclic-AMP dependent protein kinase by an insulin-generated inhibitor which becomes directly associated with the Type 1 holoenzyme is proposed.Abbreviations cyclic AMP (cAMP) Adenosine 3,5-monophosphate - Tricine N-Tris (Hydroxy-methyl) methyl glycine - G-6-P glucose-6-phosphate - MES 2-[N-morpholino]ethane sulfonic acid A preliminary report was communicated to the 61st meeting of the F.A.S.E.B., April, 1977.     

Interconvertible cGMP-free and cGMP-bound forms of cGMP-dependent protein kinase in mammalian tissues

Several vascular and nonvascular mammalian tissue extracts exhibited variable amounts of two peaks (peaks I and II) of cGMP-dependent protein kinase by NaCl elution of DEAE columns. When [3H]cGMP was added to the extracts before chromatography, a peak of protein-bound [3H]cGMP coeluted with peak II. [3H]cGMP was added to purified bovine lung cyclic nucleotide-free enzyme followed by chromatography on high performance liquid chromatography-DEAE. Two kinase peaks, the first of which represented mainly cGMP-free enzyme and the second of which represented cGMP-bound enzyme, eluted at the same positions as peaks I and II, respectively, of the crude extracts. The relative amount of peak II increased as a function of increasing the [3H]cGMP added before chromatography, and peak II could be converted partially to peak I by rechromatography. The holoenzyme is known to contain two slowly exchanging cGMP binding sites (sites 1) and two rapidly exchanging sites (sites 2). Some protein-bound [3H] cGMP found entirely in site 1 coeluted with peak I, although most of the enzyme in that peak was cGMP-free. When low [3H]cGMP was used for the initial incubation, relatively more of the protein-bound [3H] cGMP appeared in peak I and could represent binding of [3H]cGMP to only one of the two sites 1 of the kinase. The [3H]cGMP bound to the peak II enzyme completely filled both sites 1. Cyclic GMP binding to these sites caused the apparent conformational change which shifted the DEAE elution position of the enzyme. The peak II kinase was partially active and had a higher sensitivity to further cGMP activation of kinase than did the cGMP-free enzyme, suggesting that activation of kinase by binding of cGMP to site 2 was facilitated by prior binding at site 1. In fractions of the trailing edge of peak II, the kinase activity was virtually cGMP-independent, and both sites 1 and 2 were almost saturated with [3H]cGMP. These results suggested a further conformational change and direct increase in activity by binding of cGMP at site 2.     

Characterization of cyclic GMP-binding sites of cyclic GMP-dependent protein kinase by rapid filtration assay.

The kinetics of cyclic [3H]GMP binding to the purified cyclic GMP-dependent protein kinase (cG kinase) were studied by using the rapid filtration assay method with polyethyleneimine-treated glass filters (method A), and the data were compared with those of the (NH4)2SO4 precipitation procedure (method B), which has been used for many previous studies on cyclic GMP binding to cG kinase. Each method gave a similar stoichiometry of approx. 2 mol of cyclic GMP/mol of cG kinase subunit; however, other binding kinetics obtained with these two methods were different. The dissociation of bound cyclic [3H]GMP from the kinase showed a single slow component when method A was used, whereas rapid and slow dissociation components were observed with method B. The Scatchard plot of cyclic [3H]GMP binding with method A was linear with a Kd value of 11 +/- 2 nM, suggesting that the two intrachain binding sites have similar high affinity for cyclic GMP. Results obtained on cyclic nucleotide analogue specificity of the two intrachain cyclic GMP-binding sites were also different between these two methods. These findings suggest that cG kinase has two high-affinity cyclic GMP-binding sites per subunit in the native state, and that when (NH4)2SO4 is added, ostensibly to stop the binding reaction, one low-affinity site is created from one high-affinity site.     

Adenosine 3′:5′-cyclic phosphate-dependent and -independent protein kinases of renal brush border membranes: Solubilization,separation, and characterization of multiple forms

Multiple protein kinase activities were found in the luminal segment of the renal proximal tubule cell plasma membrane (brush border membrane). Membranes were extracted with Lubrol, with no loss in activity, and the extract was chromatographed on diethylaminoethyl cellulose with a salt gradient. With protamine as substrate, activity eluted in two peaks, designated I and IIb, and was cyclic AMP independent. With histone VII-S, one peak, designated IIa, appeared, which eluted slightly ahead of IIb and was cyclic AMP dependent. The three activities eluted in their original patterns following rechromatography. Histone kinase activity in the combined IIa+b fraction was stimulated threefold by cyclic nucleotides (K_a = 0.013 and 0.94 μM for cyclic AMP and cyclic GMP, respectively) by increasing V. Cyclic AMP binding activity eluted with histone kinase activity. Rechromatography of IIa+b on diethylaminoethyl cellulose containing 1 μm cyclic AMP resulted in passage through the column of most of the histone kinase activity (IIa) prior to the salt gradient, but retention of kinase IIb, which again eluted in its original position. Characterization of the separated enzymes revealed that kinase I was highly specific for protamine and totally insensitive to cyclic AMP and a specific protein inhibitor of cyclic AMP-dependent kinases. Kinase IIa was relatively specific for histones and was completely inhibited by the protein inhibitor. Kinase IIb was nonspecific, catalyzing phosphorylation of protamine, casein, histones, and phosvitin in decreasing order of activity, and was insensitive to cyclic AMP and the protein inhibitor. Exposure of intact brush border membranes to elevated temperatures revealed that phosphorylation of intrinsic membrane proteins and protamine was thermolabile, whereas cyclic AMP-dependent histone kinase activity was relatively thermostable. These findings implicate cyclic AMP-independent protamine kinases in the cyclic AMP-independent autophosphorylation of the brush border membrane.     

Activity of imidazole on the hydrolysis of cyclic AMP and cyclic GMP by bovine heart and rat liver cyclic nucleotide phosphodiesterases.

The effects of imidazole on the hydrolysis of cyclic AMP and cyclic GMP by crude and partially purified phosphodiesterases obtained from bovine heart and rat liver were studied in order to determine if imidazole has an activity on cyclic nucleotide hydrolysis under conditions which might explain its ability to antagonize the effects of several hormones. Imidazole-Cl (40 mm, pH 7.4) had no effect on the hydrolysis of cyclic AMP or cyclic GMP at substrate levels below 10 μm by the crude enzymes but increasing stimulation was observed with increasing substrate concentrations reaching a twofold stimulation at 1 mm cyclic nucleotide. Three phosphodiesterases with varying substrate specificities were partially purified from bovine heart by ammonium sulfate precipitation and diethyl aminoethyl cellulose chromatography. With these enzymes imidazole had less stimulatory activity and some inhibitory effect on the hydrolysis of 10^?4m cyclic AMP and cyclic GMP but was without significant effect on the hydrolysis of 10^?6m cyclic AMP or cyclic GMP. The stimulatory activity of imidazole on the hydrolysis of high levels of cyclic nucleotide was dependent on the presence of phosphodiesterase activator. The stimulatory effect of the activator and imidazole plus activator on the hydrolysis of 10^?4m cyclic GMP by the rather cyclic GMP-specific enzyme could be eliminated by the addition of ethylene glycol-bis-(β-aminoethyl ether)N,N′-tetraacetate (EGTA) and restored by Ca²⁺. Imidazole was without effect on the binding of cyclic AMP to a cyclic AMP-dependent protein kinase from bovine heart. The lack of effect of imidazole on the hydrolysis of physiological levels of cyclic AMP or cyclic GMP suggests that the activity of imidazole to antagonize the effects of various hormones is probably not due to a direct action of imidazole on the hydrolysis of cyclic AMP or cyclic GMP.     

Solubilization and photoaffinity labeling of renal membrane cyclic AMP receptors.

Renal cortical plasma membranes were solubilized with sodium deoxycholate. The membrane-bound cyclic AMP receptors retained biologic activity in the detergent-dispersed state exhibiting the properties of high affinity for cyclic AMP, saturability and specificity. Half-maximal binding of cycle [3H]-AMP to these receptors was found to occur at 0.06 muM and 1.5 pmol of cyclic [3H]AMP was bound per mg membrane protein at saturation (0.5 muM cyclic [3H]AMP). Sodium deoxycholate-solubilized membrane proteins were chromatographed on Biogel A-5m. Cyclic [3H]AMP receptors eluted in the internal volume at positions equivalent to molecular sizes of 50 000 and 20 000 daltons and in the void volume at molecular size greater than 450 000. After photoaffinity labeling the renal membrane receptors with cyclic [3H]AMP, we found peaks of tritium radioactivity which eluted at similar molecular size positions on this Bogel A-5m column. Further treatment of photoaffinity labeled membranes with sodium dodecyl sulfate, mercaptoethanol and urea, followed by polyacrylamide gel electrophoresis, showed bands of tritium-labeled receptor protein with relative mobilities corresponding to molecular sizes of 26 000 and 21 000 daltons. This study shows that porcine renal cortical membranes contain at least two molecular species of cyclic AMP receptors which may be associated with regulation of the membrane-bound cyclic AMP-dependent protein kinase.     

Inactivation of cyclic GMP-dependent protein kinase by N alpha-tosyl-L-lysine chloromethylketone

Cyclic GMP-dependent protein kinase from bovine lung and cyclic AMP-dependent protein kinase from bovine heart are inactivated by N^α-tosyl-L-lysine chloromethylketone (TLCK) in the presence of cyclic GMP and cyclic AMP, respectively. The inactivation of both protein kinases is pseudo-first order, suggesting the rate limiting step is beyond the binding of TLCK. Cyclic GMP-dependent protein kinase is inactivated less than $\text{1}\text{4}$ as rapidly as cyclic AMP-dependent protein kinase, although it shows a higher apparent affinity for TLCK. Cyclic AMP stimulated the rate of inactivation of cyclic AMP-dependent protein kinase 10-fold but cyclic GMP stimulated the rate of inactivation of cyclic GMP-dependent protein kinase only 1.5-fold. The rate of inactivation of cyclic GMP-dependent protein kinase by TLCK is sufficiently rapid (half-time of about 30 min at 37°C with 2 mM TLCK) to account for the effects of TLCK on cell growth observed by others.     

Observations on the binding of adenosine 3′:5′-monophosphate to cell membrane fragments from ox cerebral cortex

Microsomal or synaptosome membrane fragments from ox brain bind cyclic AMP with a pH optimum of 7.0. Scatchard analysis shows the presence of at least two binding sites. Cyclic GMP and cyclic IMP only inhibit binding at concentrations 5000 times that of cyclic AMP and even higher concentration ratios of ATP and AMP have no effect. Membrane fragments saturated with cyclic [³H] AMP lost less than 7 % of bound nucleotide on incubation at 0°C for 45 min but lost 25 % in the same period in the presence of 10 μM non-radioactive cyclic AMP.     

A cyclic nucleotide-independent protein kinase in Leishmania donovani.

Leishmania donovani promastigotes labelled for 2 h with 32Pi incorporated radioactivity into at least 21 different proteins, as determined by SDS/polyacrylamide-gel electrophoresis. Pulse-chase studies with 32Pi demonstrated that the labelled proteins were in a dynamic state: some radiolabelled proteins rapidly disappeared and others appeared after the chase. The possibility of an ectokinase on the parasite was examined; incubation of intact parasites for 10 min at 25 degrees C in an osmotically buffered medium containing [gamma-32P]ATP, but not [alpha-32P]ATP, resulted in the labelling of 10 different protozoal proteins, presumably localized to the surface of the organism's plasma membrane. Intact promastigotes also catalysed the transfer of 32P from [gamma-32P]ATP to histones. The histone-dependent kinase was solubilized by repeated freezing and thawing, and sonication, and purified 118-fold by chromatographing the high-speed (200,000 g, 1 h) supernatant fraction on QAE-Sephadex, Sephadex G-150 and hydroxyapatite columns. The kinase eluted as a single activity peak from all three columns. The partially purified histone-dependent kinase had the following properties: pH optimum, 7.0; optimum temperature, 37 degrees C; Km for mixed calf thymus histone, 0.15 mM; Km for ATP, 0.8 mM; preferred fractionated histone acceptors, H2b greater than H4 greater than H2a greater than H3 (H1 does not serve as an acceptor); optimum activity required 10-20 mM-Mg2+; inhibited 50-80% by 0.01 mM- and 1 mM-Ca2+; activity was not stimulated by calmodulin, cyclic AMP (1 mM) or cyclic GMP (1 mM) nor inhibited by a cyclic AMP-dependent protein kinase inhibitor (50 micrograms/assay); apparent Mr 75,000, as determined by Sephadex G-150 gel filtration chromatography; phosphorylated exclusively serine residues. Protein kinase activity was low in the early exponential phase of the growth curve and increased 6-fold upon entry into the stationary phase.     

Effect of hexoses and mannoheptulose on cyclic AMP accumulation and insulin secretion in rat pancreatic islets

The effects of various sugars on the simultaneous release of insulin and accumulation of cyclic AMP were studied in collagenase isolated rat pancreatic islets. d-Glucose stimulated the formation of cyclic AMP at 3 and 60 min of incubation, whether measured by a label incorporation technique, or by the protein kinase binding assay of Gilman. Only d-glucose and d-mannose were able to stimulate insulin release and cyclic [³H]AMP accumulation in the absence of other substrate. d-fructose had a stimulatory effect in the presence of 3.3 mM d-glucose only at a high concentration (38.8 mM), and enhanced the effects of 8.3 mM glucose when added at the concentration of 8.3 mM. d-Galactose was effective only together with 8.3 mM d-glucose. The order of potency of these hexoses, both regarding insulin secretion and cyclic [³H]AMP accumulation, was glucose-mannose-fructose-galactose.l-Glucose and 3-O-methylglucose had no effects at 60 min when incubated together with 8.3 mM d-glucose, whereas at 3 min, 3-O-methylglucose induced a small stimulation of the cyclic [³H]AMP response.d-mannoheptulose and d-glucosamine inhibited the insulin and cyclic [³H]-AMP responses to 27.7 mM glucose. Mannoheptulose suppressed completely the glucose effect on cyclic nucleotide accumulation within 90 s.Although under all incubation conditions, the threshold stimulatory or inhibitory concentration of a given agent was identical for insulin release and cyclic [³H]AMP accumulation, these two variables showed quantitative differences in incubations of 60 min, the magnitude of the changes in insulin secretion being larger than that for the cyclic nucleotide. It is suggested that modulation of islet cyclic AMP level is an important step in the transmission of the effect of various sugars on insulin release; however, glucose and possibly other sugars may also enhance insulin release by additional mechanisms not involving the adenylate cyclase-cyclic AMP system of the β-cell.     

Reciprocal periodicity in cyclic AMP binding and phosphorylation of differentiating Dictyostelium discoideum cells.

The binding of [³H]cyclic AMP to cell surface receptors of differentiated D. discoideum cells at 25° is an oscillatory process with a periodicity of 2 min. This alternating change in the cells' binding capacity for cyclic AMP may be the basis for the refractory period to cyclic AMP stimulation, an essential feature of the chemotactic system. The incorporation of [³²P] by whole cells from [γ³²P]ATP is also oscillatory with a periodicity identical to that of [³H]cyclic AMP binding. However, the two processes are inversely related in time such that periods of maximal cyclic AMP binding correspond to periods of minimal cellular phosphorylation. These results suggest a receptor kinase/phosphatase mediated desensitization of the cyclic AMP receptor.     

Multiple forms of glycogen synthase kinase: isolation of forms which are independent of cyclic AMP.

Rabbit renal cortex was found to contain three types of glycogen synthase kinase (GSK). Cylic AMP-dependent protein kinase (GSK-C) accounted for only a small fraction of the total GSK activity. The predominant type of GSK (GSK-P) could be adsorbed to phosphocellulose, but not to DEAE cellulose. The other major type (GSK-D) could be adsorbed to DEAE cellulose and exhibited several peaks when eluted with a linear NaC1 gradient. GSK-P and GSK-D were not affected by cyclic AMP or by the heat-stable protein inhibitor of cyclic AMP-dependent protein kinase. This suggests that cyclic AMP-independent mechanisms may play a major role in regulation of GSK. Neither GSK-P nor GSK-D were associated with the major peak of histone, kinase, casein kinase, protamine kinase or phosvitin kinase. Therefore it cannot be assumed that these protein kinase activities can be used to monitor GSK activity.     

Cyclic AMP-binding proteins in human blood platelets detected by photoaffinity labelling

Cyclic AMP inhibits platelet aggregation induced by physiological agents. 8 Azido [³²P]cyclic AMP (N₃ cyclic AMP) has been utilized as a photoaffinity probe to define the cyclic AMP-binding proteins present in unperturbed human platelets and their subcellular fractions. Specificity of cyclic AMP binding was determined by contrasting binding in the presence and absence of excess unlabelled cyclic AMP, cyclic GMP and 5′-AMP. Binding was unaffected by 5′-AMP and obliterated by cyclic AMP. Four major species of binding proteins, 49 000, 42 000, 39 000, 37 000, were obtained in all platelet fractions (crude homeogenate, cytosol, membranes and granules). Two-dimensional gel electrophoresis of platelet cytosol resolved the major molecular weight species into 15 specific cyclic AMP binding proteins of four molecular weight classes differing by charge density. These studies suggest that platelets contain an array of specific cyclic AMP-binding proteins which may function in hemostatic regulation.     

The use of affinity chromatography in purification of cyclic nucleotide receptor proteins.

Biospecific affinity chromatography has been used to purify specific cyclic AMP and cyclic GMP receptor proteins. Several variables are important for successful purification of the cyclic AMP receptor protein, the most critical being the length of the aliphatic spacer side arm. 8-(2-Aminoethyl)-amino-cyclic AMP coupled to the aliphatic spacer side arm. 8-(2-Aminoethyl)-amino-cyclic AMP coupled to agarose specifically retains the cyclic AMP receptor protein by interaction with the immobilized nucleotide. Binding of the cyclic AMP receptor subunit of cyclic AMP-dependent protein kinase to the immobilized nucleotide results in dissociation of the catalytic protein phosphokinase subunit which is not retained. The retained cyclic AMP receptor protein is subsequently eluted by cyclic AMP. Homogeneous cyclic AMP receptor protein prepared from rabbit skeletal muscle by affinity chromatography has been characterized. The molecular weight of the native protein as determined by analytical ultracentrifugation and polyacrylamide gel electrophoresis at varying acrylamide concentrations is 76 800 and 82 000, respectively. The protein is asymmetric with frictional and axial ratios of 1.64 and 12. SDS and urea polyacrylamide gel electrophoresis indicate that the native cyclic AMP receptor is composed of two identical subunits of 42 700 molecular weight. The native protein dimer binds 2 moles of cyclic AMP per mole of protein and is active in suppressing activity of isolated catalytic subunits of cyclic AMP-dependent protein kinase. Cyclic GMP receptor protein from bovine lung has been purified using the same affinity chromatography media. Since cyclic nucleotide binding to cyclic GMP-dependent protein kinase does not result in dissociation of regulatory receptor and catalytic phosphotransferase subunits, the cyclic GMP-dependent protein kinase holoenzyme is retained on the column and can be subsequently specifically eluted with cyclic GMP.     

A comparison of the uptake, metabolism, and action of cyclic adenine nucleotides in cultured hepatoma cells.

Intracellular radioactivity following incubation of HTC or RLC cells in [³H]cAMP exceeds that following incubation in either [³H]mono- or dibutyryl cAMP by 30-fold, yet little [³H]cAMP is found within the cells. Even at early times (30 min) the label derived from [³H]cAMP is predominantly found in ADP or ATP, suggesting it mostly enters the cell as the nucleoside. Significant intracellular concentrations of monobutyryl cAMP (2–10 μm) result from incubation of both cell lines in either N⁶ mono- or dibutyryl cAMP. A very small percentage of this label is in cAMP, and within 2 h of incubation > 65% of the label is again found in ADP or ATP.Liver cytosol contains three major cAMP-dependent protein kinases, designated A, B, and C, as resolved by DEAE-Sephadex chromatography. cAMP is the most effective in vitro activator (10- to 16-fold stimulation) of kinases A and B, the preponderant forms, in the order cAMP > N⁶ monobutyryl cAMP ? dibutyryl cAMP. Kinase C, a minor fraction, was stimulated two to threefold with the order cAMP ≥ N⁶ monobutyryl cAMP > dibutyryl cAMP. HTC and RLC cell cytosol protein kinase has Chromatographic and cyclic nucleotide activation properties similar to those of liver fraction C.The activation state of the protein kinases of HTC and RLC cells incubated in the various cyclic nucleotides was also studied. The ability of such nucleotides to occupy regulatory protein binding sites in intact cells (as determined by the inhibition of subsequent in vitro binding of [³H]cAMP) was of the order N⁶ monobutyryl cAMP > dibutyryl cAMP > cAMP > untreated cells. Correspondingly, the ratio of basal protein kinase activity in cyclic nucleotide treated:control cells was higher in cells incubated in monobutyryl cAMP > dibutyryl cAMP > cAMP. This in vivo activation suggests that little additional stimulation would be obtained by adding cAMP to extracts prepared from such cells. This activation can be expressed as the ratio ? cAMP: + cAMP (a ratio of 1 being maximal activation). The highest such ratio was seen in cells which had been incubated in monobutyryl cAMP > dibutyryl cAMP > cAMP > untreated cells. The studies indicate that all three cyclic nucleotides are capable of activating protein kinase in intact RLC and HTC cells; however the monobutyryl derivative is the most effective, and the degree of stimulation is greater in RLC than in HTC cells.RLC cell tyrosine aminotransferase activity is increased two to threefold by butyrylated cAMP derivatives (but not by cAMP) whereas the HTC cell enzyme is not induced. The rate of replication of both lines is unaltered by the butyrylated compounds.Since HTC and RLC cells accumulate and metabolize cAMP and its derivatives equally, and since they both contain a protein kinase with similar in vivo and in vitro activation properties, it is suggested that the effects of butyrylated cAMP derivatives on cell replication and tyrosine aminotransferase induction are mediated separately, either by distinct protein kinases, or at a point distal to protein kinase, or by a mechanism independent of protein kinase.     

Regulation of Muscarinic Receptor-Mediated Cyclic GMP Synthesis by Cultured Mouse Neuroblastoma Cells

Mouse neuroblastoma clone N1E-115 has muscarinic acetylcholine receptors that mediate cyclic GMP synthesis. This receptor-mediated response is not significantly higher than background until the cells have been maintained in the stationary phase for at least 1 week. The basis of the influence of time in culture on the cyclic GMP response was investigated. The relative amount of cyclic GMP synthesized by intact cells was measured by radioactively labeling the GTP pool with [³H]guanine, incubating cells with agonists, and then chromatographically isolating [³H]cyclic GMP. Carbamylcholine-, ionophore X-537A-, and sodium azide-induced cyclic GMP formation increased with time in culture to a maximum of 13-, 9-, and 2.5-fold above basal, respectively. There was no change in the number or the apparent affinity of the muscarinic receptors as measured by [³H]quinuclidinyl benzylate ([³H]QNB) binding. In addition, there was no change in the apparent affinity of the receptors for agonist as measured by the ability of carbamylcholine to displace the specific binding of [³H]QNB. Guanylate cyclase activity per milligram protein and per cell in-creased six- and sevenfold, respectively, from day 0 to day 22. However, this increase in guanylate cyclase appeared to precede the marked increase in sensitivity of the cells to agonists. These data suggest that, in addition to guanylate cyclase and muscarinic receptors, there is another factor which is responsible for the development of this muscarinic receptor-mediated response.     

Characterization of soluble cyclic adenosine monophosphate-dependent protein kinase isozymes in murine embryonic palatal tissue

Certain hormonal primary messengers identified in the mammalian palate during its ontogeny transmit information to the interior of the cell via transmembrane signaling systems that control the production of the secondary messenger cyclic adenosine monophosphate. The singular role of intracellular cyclic AMP is to activate cAMP-dependent protein kinases (cAMP-dPK). cAMP-dPK were thus identified and characterized in the developing murine embryonic palate. Incubation of cytosolic fractions of embryonic palatal tissue with cAMP resulted in a dose-dependent increase in the cAMP-dPK activity ratio. A transient elevation of basal cAMP-dPK was seen during the period of palatal ontogeny that corresponded temporally with a previously demonstrated transient elevation of palatal basal cAMP levels. Fractions of embryonic palatal tissue cytosols derived by diethylaminoethyl (DEAE)-Sephacel chromatography were analyzed for phosphotransferase activity and for [3H]-cAMP binding to the regulatory (R) subunits of cAMP-dPK. Such analyses revealed two peaks of activity on day 13 of gestation. Based on the salt concentration at which the material in these peaks eluted from DEAE, its ability to cochromatograph with authentic cAMP-dPK isozymes, its molecular weight as determined by sodium dodecyl sulfate-polycrylamide gel electrophoresis, and the ability of the material to be photoaffinity labeled with [3H]-8-azidoadenosine 3',5' cyclic phosphate, types I and II cAMP-dPK were identified. Regulatory subunits of cAMP-dPK were characterized by the binding of [3H]-cAMP to cytosolic fractions of embryonic palatal tissue. Such binding was saturable (Bmax = 1,096 fmol/mg protein) and of high affinity (Kd = 7 nM). Only cAMP and cyclic guanosine monophosphate competed in a dose-related manner with [3H]-cAMP for binding to R subunits of cAMP-dPK. Adenosine, cTMP, and adenosine triphosphate, at doses up to 10(-4) M, did not compete for binding. Temporal analysis of binding data indicated that the number of binding sites transiently decreased during day 13 of gestation. Characterization of cAMP-dPK in tissue derived from the developing mammalian palate allows consideration of cAMP-dPK as a key regulatory enzyme capable of transducing hormonally elevated intracellular levels of cAMP into metabolic responses during orofacial ontogenesis.