Partial characterization of protein kinase-catalyzed phosphorylation of low molecular weight proteins in purified preparations of pigeon heart sarcolemma and sarcoplasmic reticulum

Pigeon heart microsomes contain three minor size protein kinase substrates of minimal molecular weights of 22 000, 15 000, and 11 500, as estimated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. When the microsomes were partially loaded with calcium oxalate and subjected to rate zonal and isopynic centrifugations in sucrose density gradient columns, the 22 000 and the 15 000 dalton proteins settled in the heaviest fraction, which was composed mainly of vesicles of sarcoplasmic reticular membranes; the 11 500 dalton protein was concentrated in the lightest fractions, which consisted chiefly of vesicles of sarcolemmal origin. During incubation of the membrane fractions with Mg[γ-³²P]ATP significant amounts of ³²P were incorporated into all these proteins. Incorporation of ³²P into the 15 000 dalton protein was moderately and ³²P incorporation into the 22 000 dalton protein was markedly enhanced in the presence of exogenous soluble cyclic AMP-dependent protein kinase and cyclic AMP. The phosphorylation of the three proteins was virtually unaffected by CA²⁺ concentrations up to 0.1 mM and by ethyleneglycol-bis(β-aminoethylether)-N,N′-tetraacetic acid in the absence of added Ca²⁺.Phosphorylation of the 22 000 and the 11 500 dalton proteins occurred mainly at serine residues. In the 15 000 dalton protein threonine residues were the main site of endogenous phosphorylation. Nearly equal amounts of [³²P]-phosphate were incorporated into threonine and serine residues of this protein when phosphorylation was supported by exogenous cyclic AMP-dependent protein kinase and cyclic AMP.The 15 000 dalton protein could be removed from its membrane attachment by extraction with an acidic chloroform/methanol mixture. This step opens the way for the purification of this membrane-bound protein kinase substrate.     

A simultaneous protein-binding assay for adenosine 3':5'-monophosphate in biological materials.

Adenosine 3′:5′-monophosphate (cyclic AMP) and guanosine 3′:5′-monophosphate (cyclic GMP) have been determined simultaneously by combining individual protein binding assays using different isotopically labeled cyclic nucleotides. Preparations of cyclic AMP-binding protein from beef adrenal cortex and cyclic GMP-binding protein from the fat body of silkworm pupae ($\text{Bombyx mori}$) have been used for the assay. The method allows the analysis of cyclic AMP and cyclic GMP levels in crude extracts without any purification. The assay has been applied to hormone-stimulated Mouse liver and phorbol ester-treated Rat embryo cells.     

The activation by Ca2+ of platelet phospholipase A2: Effects of dibutyryl cyclic adenosine monophosphate and 8-(N,N-diethylamino)-octyl-3,4,5-trimethoxybenzoate

Thrombin-induced release of arachidonic acid from human platelet phosphatidylcholine is found to be more than 90% impaired by incubation of platelets with 1 mM dibutyryl cyclic adenosine monophosphate (Bt₂ cyclic AMP) or with 0.6 mM 8-(N,N-diethylamino)-octyl-3,4,5-trimethoxybenzoate (TMB-8), an intracellular calcium antagonist. Incorporation of arachidonic acid into platelet phospholipids is not enhanced by Bt₂ cyclic AMP. The addition of external Ca²⁺ to thrombin-treated platelets incubated with Bt₂ cyclic AMP or TMB-8 does not counteract the observed inhibition. However, when divalent cation ionophore A23187 is employed as an activating agent, much less inhibition is produced by Bt₂ cyclic AMP or TMB-8. The inhibition which does result can be overcome by added Ca²⁺. Inhibition of arachidonic acid liberation by Bt₂ cyclic AMP, but not by TMB-8, can be overcome by high concentrations of A23187. When Mg²⁺ is substituted for Ca²⁺, ionophore-induced release of arachidonic acid from phosphatidylcholine of inhibitor-free controls is depressed and inhibition by Bt₂ cyclic AMP is slightly enhanced. The phospholipase A₂ activity of platelet lysates is increased by the presence of added Ca²⁺, however, the addition of either A23187 or Bt₂ cyclic AMP is without effect on this activity. We suggest that Bt₂ cyclic AMP may promote a compartmentalization of Ca²⁺, thereby inhibiting phospholipase A activity. The compartmentalization may be overcome by ionophore. By contrast, TMB-8 may immobilize platelet Ca²⁺ stores in situ or restrict access of Ca²⁺ to phospholipase A in a manner not susceptible to reversal by high concentrations of ionophore.     

Purification and succinylation of cyclic GMP from large volume samples and radioimmunoassay of succinyl cyclic GMP.

Improved procedures for isolation of cyclic GMP and cyclic AMP and radioimmunoassay of cyclic GMP with succinylation are described. Procedures involved include modified chromatography on alumina and succinylation of cyclic GMP followed by purification of succinyl cyclic GMP on a Dowex AG 1×8 column. These procedures are convenient and applicable to any volume up to 50 ml of tissue extracts and especially for isotonic incubation mixtures. This assay system is sensitive to 6 femtomoles of cyclic GMP/tube. On radioimmunoassay, free and antibody bound [¹²⁵I]-labeled cyclic GMP are separated by Millipore filtration. Cyclic GMP levels in several tissue samples were determined in order to show the applicability of the procedures.     

Regulation by a β-adrenergic receptor of a Ca2+-independent adenosine 3′,5′-(cyclic)monophosphate phosphodiesterase in C6 glioma cells

The hormonal control of cyclic nucleotide phosphodiesterase (EC 3.1.4.17) activity has been studied by using as a model the isoproterenol stimulation of cyclic AMP phosphodiesterase activity in C6 glioma cells. A 2-fold increase in cyclic AMP phosphodiesterase specific activity was observed in homogenates of isoproterenol-treated cells relative to control. This increase reached a maximum 3 h after addition of isoproterenol, was selective for cyclic AMP hydrolysis, was reproduced by incubation with 8-Br cyclic AMP but not with 8-Br cyclic GMP and was limited to the soluble enzyme activity. The presence of 0.1 mM EGTA did not alter the magnitude of the increase in phosphodiesterase activity. Moreover, the calmodulin content in the cell extracts was not changed after isoproterernol. DEASE-Sephacel chromatography of the 100 000×g supernatant resolved two peaks of phosphodiesterase activity. The first peak hydrolyzed both cyclic nucleotides and was activated by Ca²⁺ and purified calmodulin. The second peak was specific for cyclic AMP but it was Ca²⁺- and calmodulin-insensitive. Isoproterenol selectively increased the specific activity of the second peak. Kinetic analysis of the cyclic AMP hydrolysis by the induced enzyme reveled a non-linear Hofstee plot with apparent K_m values of 2–5 μM. Cyclic GMP was not hydrolyzed by this enzyme in the absence or presence of calmodulin and failed to affect the kinetics of the hydrolysis of cyclic AMP. Gel filtration chromatography of the induced DEASE-Sephacel peak resolved a single peak of enzyme activity with an apparent molecular weight of 54 000.     

Identification of guanosine 3′:5′-monophosphate in the fruit of Zizyphus jujuba

Evidence is presented here confirming the identification of guanosine 3′: 5′-monophosphate (c GMP) in the tissue of higher plants. The c GMP activity detected in fruits of Zizyphus jujuba was separated from the c AMP activity also present. The separated sample was extensively purified by Bio-Rad AG 1 × 4 and aluminium oxide CC, and by TLC. The purified sample showed the same physicochemical properties as authentic c GMP by TLC using different solvents and by UV spectroscopy, and was decomposable by cyclic nucleotide-specific phosphodiesterase. The identification was further supported by HPLC. The amount of c GMP present increases 90-fold during fruit ripening.     

Comparison of cyclic nucleotide specificity of guanosine 3′,5′-monophosphate-dependent protein kinase and adenosine 3′,5′-monophosphate-dependent protein kinase

Guanosine 3′,5′-monophosphate-dependent protein kinase (cyclic GMP-dependent protein kinase) and adenosine 3′,5′-monophosphate-dependent protein kinase (cyclic AMP-dependent protein kinase) exhibited a high degree of cyclic nucleotide specificity when hormone-sensitive triacylglycerol lipase, phosphorylase kinase, and cardiac troponin were used as substrates. The concentration of cyclic GMP required to activate half-maximally cyclic dependent protein kinase was 1000- to 100-folds less than that of cylic AMP with these substrates. The opposite was true with cyclic AMP-dependent protein kinase where 1000- to 100-fold less cyclic GMP was required for half-maximal enzyme activation. This contrasts with the lower degree of cyclic nucleotide specificity of cyclic GMP-dependent protein kinase of 25-fold when histone H2b was used as a substrate for phosphorylation. Cyclic IMP resembled cyclic AMP in effectiveness in stimulating cyclic GMP-dependent protein kinase but was intermediate between cyclic AMP and cyclic GMP in stimulating cyclic. AMP-dependent protein kinase. The effect of cyclic IMP on cyclic GMP-dependent protein kinase was confirmed in studies of autophosphorylation of cyclic GMP-dependent protein kinase where both cyclic AMP and cyclic IMP enhanced autophophorylation. The high degree of cyclic nucleotide specificity observed suggests that cyclic AMP and cyclic GMP activate only their specific kinase and that crossover to the opposite kinase is unlikely to occur at reported cellular concentrations of cyclic nucleotides.     

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.     

In vitro studies of skeletal muscle membranes characterization of a phosphorylated intermediate of sarcolemmal (Na+ + K+)ATPase

The sarcolemmal membranes isolated from rat skeletal muscle are capable of incorporating ³²P from [γ?³²P]ATP. The membrane protein phosphorylation requires Mg²⁺. Cyclic AMP, cyclic GMP and their dibutyrul derivatives showed no marked effect on sarcolemmal phosphorylation.The Mg²⁺-dependent ³²P labeling was significantly enhanced by Na⁺. The rate of Na⁺ -stimulated ³²P incorporation was quite rapid reaching steady state levels within 5 s at 0 °C. K⁺ reduced the Na⁺ -stimulated ³²P-incorporation but enhanced the ³²P_i release. This inhibitory effect of K⁺ on Na⁺ -stimulated ³²P incorporation was prevented by the cardiac glycoside, ouabain.The Na⁺ -dependent ³²P labeling showed substrate dependency and the Na⁺ site was saturable. The apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ for ATP was 2 · 10?5 M. The optimum pH for ³²P labeling was between 7 and 8.Na⁺ -dependent membrane phosphorylation showed a direct relationship with the (Na⁺ + K⁺ATPase activity. The high turnover rate of ³²P intermediate (12 000 min ?1) suggested its functional significance in the overall transport ATPase reaction sequence.The predominate portion (> 90%) of the phosphorylated membrane complex was sensitive to acidified hydroxylamine and to alkaline pH suggesting an acylphosphate nature of the phosphoprotein.Sodium dodecyl sulfate-polyacrylamide gel electrophoresis revealed that ³²P incorporation occurred predominately into a 108 000 dalton subunit which is a major protein component of sarcolemmal membranes. A very low level of ³²P incorporation was also observed into a 25 000 dalton subunit and Ca²⁺ slightly enhanced the phosphorylation of this component.The size ($\text{M}{}_{\mathrm{<mtext>r</mtext>}}\text{108 000}$) and some properties of the sarcolemmal phosphoprotein are closely similar to other (Na⁺ + K⁺ATPase preparations reported so far.     

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.     

On the role of calcium as second messenger in liver for the hormonally induced activation of glycogen phosphorylase

We have studied the mode of action of three hormones (angiotensin, vasopressin and phenylephrine, an α-adrenergic agent) which promote liver glycogenolysis in a cyclic AMP-independent way, in comparison with that of glucagon, which is known to act essentially via cyclic AMP. The following observations were made using isolated rat hepatocytes: (a) In the normal Krebs-Henseleit bicarbonate medium, the hormones activated glycogen phosphorylase (EC 2.4.1.1) to about the same degree. In contrast to glucagon, the cyclic AMP-independent hormones did not activate either protein kinase (EC 2.7.1.37) or phosphorylase $\text{b}$ kinase (EC 2.7.1.38). (b) The absence of Ca²⁺ from the incubation medium prevented the activation of glycogen phosphorylase by the cyclic AMP-independent agents and slowed down that induced by glucagon. (c) The ionophore A 23187 produced the same degree of activation of glycogen phosphorylase, provided that Ca²⁺ was present in the incubation medium (d) Glucagon, cyclic AMP and three cyclic AMP-independent hormones caused an enhanced uptake of ⁴⁵Ca; it was verified that concentrations of angiotensin and of vasopressin known to occur in haemorrhagic conditions were able to produce phosphorylase activation and stimulate ⁴⁵Ca uptake. (e) Appropriate antagonists (i.e. phentolamine against phenylephrine and an angiotensin analogue against angiotensin) prevented both the enhanced ⁴⁵Ca uptake and the phosphorylase activation.We interpret our data in favour of a role of calcium (1) as the second messenger in liver for the three cyclic AMP-independent glycogenolytic hormones and (2) as an additional messenger for glucagon which, via cyclic AMP, will make calcium available to the cytoplasm either from extracellular or from intracellular pools. The target enzyme for Ca²⁺ is most probably phosphorylase $\text{b}$ kinase.     

Effects of chymotrypsin and a calcium-dependent protein activator on guanosine 3′,5′-monophosphate phosphodiesterase from rat liver

Cyclic GMP phosphodiesterases from 100 00 × g rat liver supernatant were partially resolved by chromatography on DEAE-cellulose. Multiple forms of cyclic GMP phosphodiesterase(s) that were activated to different degrees by calcium plus a low molecular weight protein from rat liver and bovine brain supernantants, or by limited exposure to chymotrypsin, were identified. The cyclic GMP phosphodiesterase in some column fractions was activated over 10-fold by calcium plus activator or chymotrypsin. Activation by chymotrypsin was dependent both on the time of incubation with protease and its concentration. Prolonged exposure to chymotrypsin resulted in a decrease in s_20,w by sucrose density gradient centrifugation. The chymotrypsin-treated enzyme was no longer activated by exposure to calcium plus activator. The calcium- and protein activator-stimulated enzyme was inactivated by ethyleneglycol-bis-(β-aminoethylether)-N,N′-tetraacetic acid (EGTA). Exposure of this activated enzyme to chymotrypsin did not result in further activation, but the chymotrypsin-treated enzyme was no longer inhibited by EGTA. The apparently irreversible effects of chymotrypsin and the reversible effects of calcium plus activator on cyclic GMP hydrolysis by the phosphodiesterase over a wide range of cyclic GMP concentrations appeared to be identical.     

Adenosine 3′:5′-cyclic monophosphate,adenylate cyclase and a cyclic AMP binding-protein in Phaseolus vulgaris

The validity of using the binding-protein method for determining cyclic AMP in purified and partially purified extracts of Phaseolus tissues has been examined and confirmed. Measurement of cyclic AMP concentration by binding-protein gave similar results to those obtained by direct spectrophotometry of purified extracts. A cyclic AMP binding-protein and adenylate cyclase were demonstrated in Phaseolus extracts. Isolated intact chloroplasts were shown to possess adenylate cyclase activity but persistent cyclic AMP phosphodiesterase activity obviated quantitative assessment.     

Inhibition of thyroid secretion by sodium fluoride in vitro

NaF mimicked the activation by thyrotropin of iodide binding to proteins and of glucose C-I oxidation but not the accumulation of intracellular colloid droplets or the stimulation of secretion in dog thyroid slices in vitro. On the contrary, NaF inhibited the two latter thyrotropin effects. The inhibitory action of F⁻ was partially relieved by the addition of glucose to the medium; it was mimicked by sodium oxamate. These data suggest that NaF depresses the endocytosis of colloid and thyroid secretion by inhibiting aerobic glycolysis in the follicular cell. NaF inhibited the activation of colloid droplet accumulation and secretion by N⁶,O^2′-dibutyryl-adenosine 3′,5′-monophosphate (dibutyryl cyclic AMP) and the accumulation of cyclic AMP in thyrotropin-stimulated slices. This suggests an inhibition at the level of both cyclic AMP accumulation and cyclic AMP action. The inhibition by NaF and sodium oxamate of colloid droplet formation and thyroid secretion but not of glucose C-I oxidation in stimulated slices further confirms our conclusion that the latter effect is not merely a consequence of the activation by thyrotropin of colloid endocytosis.     

Synthesis of adenosine 3′,5′-monophosphate by guanylate cyclase,a new pathway for its formation

The 105 000 × g supernatant fractions from homogenates of various rat tissues catalyzed the formation of both cyclic GMP and cyclic AMP from GTP and ATP, respectively. Generally cyclic AMP formation with crude or purified preparations of soluble guanylate cyclase was only observed when enzyme activity was increased with sodium azide, sodium nitroprusside, N-methyl-N′-nitro-N-nitrosoguanidine, sodium nitrite, nitric oxide gas, hydroxyl radical and sodium arachidonate. Sodium fluoride did not alter the formation of either cyclic nucleotide. After chromatography of supernatant preparations on Sephadex G-200 columns or polyacrylamide gel electrophoresis, the formation of cyclic AMP and clycic GMP was catalyzed by similar fractions. These studies indicate that the properties of guanylate cyclase are altered with activation. Since the synthesis of cyclic AMP and cyclic GMP reported in this study appears to be catalyzed by the same protein, one of the properties of activated guanylate cyclase is its ability to catalyze the formation of cyclic AMP from ATP. The properties of this newly described pathway for cyclic AMP formation are quite different from those previously described for adenylate cyclase preparations. The physiological significance of this pathway for cyclic AMP formation is not known. However, these studies suggest that the effects of some agents and processes to increase cyclic AMP accumulation in tissue could result from the activation of either adenylate cyclase or guanylate cyclase.     

Subcellular location of adenylate cyclase in rat cardiac muscle

Crude homogenates of rat cardiac muscle were fractionated in order to examine the subcellular location of adenylate cyclase in this tissue. The fractionation procedure employed differential centrifugation of homonized material, followed by collagenase treatment, centrifugation on a discontinuous sucrose density gradient and extraction with 1 M KCl. The particulate fraction obtained by this procedure contained a high specific activity and yield of adenylate cyclase, moderate levels of mitochondria and low levels of sarcoplasmic reticulum and contractile protein as judged by marker enzyme activities. Adenylate cyclase was purified 20-fold with a 33% yield from the crude homogenate, while mitochondrial, sarcoplasmic reticulum and contractile protein yields were 5, 0.4 and 0.7% respectively. The membrane fractions prepared in this manner were examined by sodium dodecyl sulfate · gel electrophoresis.Adenylate cyclase copurified with ouabain-sensitive (Na⁺ + K⁺)-ATPase, a plasma membrane marker enzyme, and not with Ca²⁺-accumulating activity, which is associated with the sarcoplasmic reticulum. The distribution of marker enzyme activities indicates that heart adenylate cyclase is not located in the sarcoplasmic reticulum but is localized predominantly, if not exclusively, in the plasma membrane.     

Differences in macromolecular binding between cyclic AMP and its dibutyryl derivative in vitro

Rat liver cytosol binds ³H-cAMP and ³H-DBcAMP $\text{in vitro}$. Fractionation of bound radioactivity by DEAE-Sephadex chromatography shows that ³H-cAMP is associated with a different cytosolic protein than is ³H-DBcAMP. The pI's of the cAMP-protein and the ³H-DBcAMP-protein complexes are 6.7 and 3.9, respectively. Competition studies between ³H-cAMP and its structural analogues have shown the following order of effectiveness in competing for binding sites in rat liver cytosol: cAMP > N⁶-MBcAMP > O²′-MBcAMP. No inhibition of ³H-cAMP binding was observed with 5′-AMP, adenosine, cGMP or DBcAMP. $\text{In vitro}$ binding experiments with rat serum has shown that only ³H-DBcAMP binds to any significant extent.