Adenosine-3':5'-monophosphate-dependent and plasma-membrane-associated protein kinase from bovine corpus luteum. Solubilization and properties of solubilized enzyme.

The solubilization of plasma membrane fractions FI and FII associated protein kinases has been attempted using monovalent salts of high ionic strength and various detergent treatments. Extraction of FI and FII plasma membranes with high ionic strength salt solutions did not release more than 20% of the protein kinase activity. Similarly, monovalent salts released little adenosine 3':5'-monophosphate (cyclic AMP) binding activity, but after extraction binding capacity of cyclic [3H]AMP to plasma membranes was increased about 150-200%. Triton X-100 was a better solubilizing agent that Lubrol WX or deoxycholate. In addition to solubilization, 0.1% Triton X-100 also stimulated the protein kinase activity 150-200%. The properties of Triton X-100 solubilized FI and FII and purified cytosol KII were characterized with respect to protein substrate specificity, effect of cyclic AMP, cyclic nucleotide specificity, effects of divalent metal ion and gonadotropins. Upon sucrose density gradient centrifugation, FI solubilized protein kinase and cyclic AMP binding activities co-sedimented with a sedimentation coefficient of 6.3 S. The FII solubilized protein kinase sedimented as two components with sedimentation coefficients of 7.7 S and 5.5 S. The cyclic AMP binding activity also sedimented as two components with sedimentation coefficient 6.7 S and 5.5 S. Cyclic AMP caused dissociation of solubilized protein kinase from FI into a single catalytic (4.8 S) and two cyclic AMP binding subunits (8.1 S and 6.7 S). FII solubilized enzyme was dissociated into one catalytic (4.8 S) and one cyclic AMP binding subunit (6.3 S). Fractionation of FI and FII solubilized enzymes on DEAE-cellulose column chromatography resolved them each into two peaks Ia, Ib and IIa, IIb, respectively. Peaks Ib and IIb were more sensitive to cyclic AMP STIMULATION THAN Ia and IIa peaks. From these studies it is concluded that the plasma-membrane associated and cytosol protein kinases have similar catalytic properties but differ in some of their physical properties.     

Binding proteins for adenosine 3′:5′-cyclic monophosphate in bovine adrenal cortex

Five peaks of cyclic AMP-binding activity could be resolved by DEAE-cellulose chromatography of bovine adrenal-cortex cytosol. Two of the binding peaks co-chromatographed with the catalytic activities of cyclic AMP-dependent protein kinases (ATP-protein phosphotransferase, EC 2.7.1.37) of type I or type II respectively. A third binding protein was eluted between the two kinases, and appeared to be the free regulatory moiety of protein kinase I. Two of the binding proteins for cyclic AMP, sedimenting at 9S in sucrose gradients, could also bind adenosine. They bound cyclic AMP with an apparent equilibrium dissociation constant (K(d)) of about 0.1mum, and showed an increased binding capacity for cyclic AMP after preincubation in the presence of K(+), Mg(2+) and ATP. The two binding proteins differed in their apparent affinities for adenosine. The isolated regulatory moiety of protein kinase I had a very high affinity for cyclic AMP (K(d)<0.1nm). At low ionic strength or in the presence of MgATP, the high-affinity binding of cyclic AMP to the regulatory subunit of protein kinase I was decreased by the catalytic subunit. At high ionic strength and in the absence of MgATP the high-affinity binding to the regulatory subunit was not affected by the presence of catalytic subunit. Under all experimental conditions tested, dissociation of protein kinase I was accompanied by an increased affinity for cyclic AMP. To gain some insight into the mechanism by which cyclic AMP activates protein kinase, the interaction between basic proteins, salt and the cyclic nucleotide in activating the kinase was studied.     

Altered interaction between binding and catalytic subunits of a cyclic AMP-stimulated protein kinase from hepatoma cells.

Binding activity obtained from an established line of hepatoma tissue culture (HTC) cells has a lower apparent affinity for cyclic AMP at physiological pH than has the analogous binding activity from rat liver. However, the apparent binding affinity of HTC preparations can be reversibly increased by adding NaCl or guanidine · HCl. In the presence of such activating substances, a macromolecular inhibitory activity has been chromatographically separated from the cyclic AMP-binding activity. Removal of this inhibitory component causes the apparent affinity of the cyclic AMP-binding activity from HTC cells to increase and resemble that observed with liver preparations. Before treatment with salt, the inhibitory activity seems to be physically associated with the binding activity. Adding the isolated inhibitory component back to a suitably activated binding preparation from HTC cells results in a decrease in the apparent affinity for cyclic AMP. The isolated inhibitory component is devoid of cyclic AMP-binding and cyclic AMP phosphodiesterase activities and has an apparent minimal molecular weight of about 30,000 by gel filtration. It possesses protein kinase activity and seems to be identical to the catalytic subunit of a cyclic AMP-stimulated protein kinase on the basis of chromatographic properties and sensitivities to heat and low pH. This catalytic subunit represents only a minor portion of total cellular protein kinase activity and is also present in liver extracts. However, the binding activity from liver is not inhibited significantly under conditions where the binding from HTC cells is affected by the catalytic subunit. The difference in this inhibitory response between liver and HTC preparations appears to reflect differences in the cyclic AMP-binding proteins themselves.     

Altered regulation of cyclic AMP-dependent protein kinase in a mouse lymphoma cell line.

The ability of cyclic AMP to inhibit growth, cause cytolysis and induce synthesis of cyclic AMP-phosphodiesterase in S49.1 mouse lymphoma cells is deficient in cells selected on the basis of their resistance to killing by 2 mM dibutyryl cyclic AMP. The properties of the cyclic AMP-dependent protein kinase (ATP:protein phosphotransferase, EC 2.7.1.37) in the cyclic AMP-sensitive (S) and cyclic AMP-resistant (R) lymphoma cells were comparatively studied. The cyclic AMP-dependent protein kinase activity or R cells cytosol exhibits an apparent Ka for activation by cyclic AMP 100-fold greater than that of the enzyme from the parental S cells. The free regulatory and catalytic subunits from both S and R kinase are thermolabile, when associated in the holoenzyme the two subunits are more stable to heat inactivation in R kinase than in S kinase. The increased heat stability of R kinase is observed however only for the enzyme in which the catalytic and cyclic AMP-binding activities are expressed at high cyclic AMP concentrations (10(-5)--10(-4) M), the activities expressed at low cyclic AMP concentrations (10(-9)--10(-6) M) being thermolabile. The regulatory subunit of S kinase can be stabilized against heat inactivation by cyclic AMP binding both at 2-10(-7) and 10(-5) M cyclic AMP concentrations. In contrast, the regulatory subunit-cyclic AMP complex from R kinase is stable to heat inactivation only when formed in the presence of high cyclic AMP concentrations (10(-5)M). The findings indicate that the transition from a cyclic AMP-sensitive to a cyclic AMP-resistant lymphoma cell phenotype is related to a structural alteration in the regulatory subunit of the cyclic AMP-dependent protein kinase which has affected the protein's affinity for cyclic AMP and its interaction with the catalytic subunit.     

Characterization of calf-ovary adenosine;3':5'-monophosphate-dependent protein kinases and adenosine-3':5'-monophosphate-binding proteins.

Protein phosphokinase activity from the calf ovary cytosol (105000 X g supernatant fraction) has been resolved by chromatography and polyacrylamide gel electrophoresis into two major protein kinases, PK-H1 and PK-H2, both dependent on adenosine 3':5'-monophosphate (cyclic AMP). The enzymes have similar molecular weights (230000) and substrate specificities but differ in their cyclic-AMP-dependency and stimulation by cyclic AMP. The differences have been explained by the presence in PK-H1 of a unique cyclic-AMP-binding protein which has little catalytic activity associated with it. The cyclic-AMP-binding protein has a high affinity for cyclic AMP and in addition is able to inhibit the activity of the isolated catalytic subunit. The ovarian cyclic-AMP-dependent protein kinases have properties similar to those found in other tissues. They can be dissociated into catalytic and regulatory subunits and are inhibited by a heat-stable protein inhibitor isolated from rabbit skeletal muscle. Preincubation of the cytosol with high levels of cyclic AMP resulted in additional cyclic-AMP-dependent protein kinases and cyclic-AMP-binding proteins which include protein kinases and binding proteins of greater than 400 000 molecular weight.     

The effects of triethyltin bromide on red cell and brain cyclic AMP-dependent protein kinases

Triethyltin bromide activates the cyclic AMP-dependent protein kinases of human red cell membranes and of bovine brain. Additions of 25-500 microM triethyltin to red cell ghosts resulted in enhanced phosphorylation of ghost proteins. When added to partially purified cyclic AMP-dependent protein kinases from red cell ghosts or bovine brain, stimulation of the phosphorylation of calf thymus histone was observed. The enhancement of kinase activity was due to release of catalytic subunits from the intact protein kinase. Brief exposure of the partially purified enzymes to triethyltin, followed by DE52 chromatography, resulted in elution profiles for regulatory and catalytic subunits that were similar to the profile resulting after cyclic AMP activation. Triethyltin interacts with both regulatory and catalytic subunits. When it was added to the partially purified cyclic AMP-dependent protein kinases from human red cell ghosts or bovine brain, noncompetitive inhibition of cyclic AMP binding to the regulatory subunit of the enzyme was observed. It interacted with the catalytic subunit to produce slow inhibition of catalytic activity. The inhibition was non-competitive with respect to both histone and ATP. When intact red cells were subjected to brief exposure with triethyltin, enhanced phosphorylation of certain membrane proteins occurred, suggesting that the activation of the cyclic AMP protein kinases by triethyltin may be physiologically significant.     

Dissociation and reassociation of the phosphorylated and nonphosphorylated forms of adenosine 3':5' -monophosphate-dependent protein kinase from bovine cardiac muscle.

Adenosine 3':5' -monophosphate (cyclic AMP) -dependent protein kinase from bovine heart muscle catalyzes the phosphorylation of its regulatory, cyclic AMP-binding subunit. Phosphorylation enhances net dissociation of the enzyme by cyclic AMP. Chromatography on omega-aminohexyl-agarose was used to study the effects of phosphorylation on cyclic AMP binding and subunit dissociation and reassociation. This method permitted rapid separation of the catalytic subunit from the cyclic AMP -binding protein and holoenzyme. Phospho- and dephosphoprotein kinases were found to dissociate to the same extent at any given concentration of cyclic AMP and completely at saturation. At equilibrium, the amount of cyclic AMP bound was the same for both forms of enzyme and was directly proportional to the degree of dissociation of the holoenzyme. In the absence of cyclic AMP, phospho- and dephospho-cyclic AMP-binding proteins reassociated completely with the catalytic subunit. However, the rate of reassociation of the dephospho-cyclic AMP-binding protein was at least 5 times greater than the phospho-cyclic AMP-binding protein. Retardation of reassociation was directly proportional to the extent of phosphorylation. We conclude that the degree to which the cyclic AMP-binding protein is phosphorylated markedly affects its intrinsic ability to combine with the catalytic subunit to regenerate the inactive cyclic nucleotide-dependent kinase and that the state of phosphorylation of this subunit may be important in detemining the proportion of dissociated (active) and reassociated (inactive) protein kinase at any given time.     

An adenosine 3':5'-monophosphate-adenosine binding protein from mouse liver.

A cyclic AMP-adenosine binding protein from mouse liver has been purified to apparent homogeneity as judged by polyacrylamide gel electrophoresis in the absence and presence of sodium dodecyl sulfate and by analytical ultracentrifugation. The binding protein had a Stokes radium of 48 A based on gel chromatography. Both the purified binding protein and the binding activity in fresh cytosol sedimented as 9 S on sucrose gradient centrifugation. The homogeneous protein had a sedimentation coefficient (S20, w) of 8.8 x 10-13 s, as calculated from sedimentation velocity experiments. By use of the Stokes radius and S20, w', the molecular weight was calculated to be 180,000. The protein was composed of polypeptides having the same molecular weight of 45,000 as judged by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and thus appeared to consist of four subunits of equal size. The isoelectric point, pI = 5.7. The binding capacity for cyclic AMP increased by preincubating the receptor protein in the presence of Mg2+ ATP. This process, tentatively termed activation, was studied in some detail and was shown not be be be accompanied by dissociation, aggregation, or phosphorylation of the binding protein. Cyclic AMP was bound to the protein with an apparent dissociation constant (Kd) of 1.5 x 10-7 M. The binding of cyclic AMP was competitively inhibited by adenosine, AMP, ADP, and ATP whose inhibition constants were 8 x 10-7 M, 1.2X 10-6 M, 1.5 X 10-6 M, and higher than 5 x 10-6 M respectively. A hyperbolic Scatchard plot was obtained for the binding of adenosine to the activated binding protein, indicating more than one site for adenosine. The binding of adenosine to the site with the highest affinity (Kd=2 x 10-7 M) for this nucleoside was not suppressed by excess cyclic AMP and was thus different from the aforementioned cyclic AMP binding site. Cyclic GMP, GMP, guanosine, cyclic IMP, IMP, and inosine did not inhibit the binding of either cyclic AMP or adenosine. The binding protein had no cyclic AMP phosphodiesterase, adenosine deaminase, phosphofructokinase, or protein kinase activities, nor does it inhibit the catalytic subunit of the cyclic AMP-dependent protein kinase.     

Further studies on the properties of the rabbit reticulocyte adenosine 3',5'-cyclic monophosphate-dependent protein kinase I

The properties of cyclic AMP-dependent protein kinase I isolated from rabbit reticulocytes were further investigated. The enzyme catalyzes the phosphorylation of histone in the presence of ATP and Mg²⁺ and this reaction is stimulated by cyclic AMP. The pH optimum of the reaction was between 8.5 and 9.0, when assayed in the presence of cyclic AMP. No distinct pH optimum was observed in the absence of the cyclic nucleotide. The K_m values for ATP appeared to be very similar whether it was determined in the presence (K_m = 1.7 × 10⁻⁴m) or absence (K_m = 2.5 × 10⁻⁴m) of cyclic AMP. The rate of heat inactivation of the catalytic activity and the cyclic AMP binding activity of kinase I were found to be dependent on the presence of Mg²⁺, ATP, and/or cyclic AMP. In the presence of cyclic AMP, the rate of inactivation of the catalytic activity of kinase I at 53 ° was accelerated. On the other hand, the cyclic AMP binding activity appeared to be protected from heat inactivation by the cyclic nucleotide. When both ATP and Mg²⁺ were present in the heating mixture, no loss of catalytic and binding activities of kinase I were observed even up to 8 min of heating at 53 °. The cyclic AMP binding activity of kinase I was almost completely inhibited by mercuric acetate at a concentration of 1 mm, while the loss in catalytic activity was only 50%. These results substantiate our previous observation that kinase I contains two nonidentical subunits, a catalytic subunit and a cyclic AMP binding subunit.     

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.     

Chromatographic behavior of cyclic AMP dependent protein kinase and its subunits from Dictyostelium discoideum

An adenosine cyclic 3',5'-monophosphate (cAMP) dependent protein kinase has recently been shown to exist in Dictyostelium discoideum and to be developmentally regulated. In this report we have followed the chromatographic behavior of both the holoenzyme and its subunits. A cAMP-dependent holoenzyme could be obtained from the 100000 g soluble fraction after passage through DE-52 cellulose (pH 7.5) and Sephacryl S300. Under conditions of low pH the holoenzyme could be further purified by flat-bed electrofocusing (pI = 6.8). Application of the holoenzyme to electrofocusing at high pH resulted in dissociation of the holoenzyme into a cAMP binding component (pI = 6.1) and a cAMP-independent catalytic activity (pI = 7.4). Dissociation of the holoenzyme into subunits also occurred during histone affinity chromatography and gel filtration chromatography (S300) in the presence of a dissociating buffer. Although the subunit structure was clearly evident during chromatography, the holoenzyme could not be dissociated by simple addition of cAMP to the extract. The catalytic subunit could be purified further by CM-Sephadex, DE-52 cellulose (pH 8.5), histone affinity, and hydrophobic chromatography. The regulatory subunit was further purified by DE-52 cellulose (pH 8.5) and cAMP affinity chromatography. Proof that the cAMP binding activity and the cAMP-independent catalytic activity were in fact the regulatory and catalytic subunits was shown by reconstitution of the cAMP-dependent holoenzyme from the purified subunits. By using these separation procedures, one can obtain from extracts of Dictyostelium the subunits that are free of each other as well as free of any endogenous protein substrates.     

Cyclic AMP-dependent protein kinase activity in Trypanosoma cruzi.

A cyclic AMP-dependent protein kinase activity from epimastigote forms of Trypanosoma cruzi was characterized. Cytosolic extracts were chromatographed on DEAE-cellulose columns, giving two peaks of kinase activity, which were eluted at 0.15 M- and 0.32 M-NaCl respectively. The second activity peak was stimulated by nanomolar concentrations of cyclic AMP. In addition, a cyclic AMP-binding protein co-eluted with the second kinase activity peak. Cyclic AMP-dependent protein kinase activity was further purified by gel filtration, affinity chromatography on histone-agarose and cyclic AMP-agarose, as well as by chromatography on CM-Sephadex. The enzyme ('holoenzyme') could be partially dissociated into two different components: 'catalytic' and 'regulatory'. The 'regulatory' component had specific binding for cyclic AMP, and it inhibited phosphotransferase activity of the homologous 'catalytic component' or of the 'catalytic subunit' from bovine heart. Cyclic AMP reversed these inhibitions. A 'holoenzyme preparation' was phosphorylated in the absence of exogenous phosphate acceptor and analysed by polyacrylamide-gel electrophoresis. A 56 kDa band was phosphorylated. The same preparation was analysed by Western blotting, by using polyclonal antibodies to the regulatory subunits of protein kinases type I or II. Both antibodies reacted with the 56 kDa band.     

Characterization of two adenosine 3':5'-phosphate-dependent protein kinase species from Chinese hamster ovary cells.

Chinese hamster ovary cells exhibit several characteristic morphological and physiological responses upon treatment with agents which increase the intracellular level of adenosine 3':5'-phosphate (cyclic AMP). To better understand the mechanism of these cyclic AMP-mediated responses, we separated two cyclic AMP-dependent protein kinases (ATP:protein phosphotransferase, EC 2.7.1.37) (protein kinase I and protein kinase II) from the cytosol of Chinese hamster ovary cells by DEAE-cellulose chromatography and studied their properties. Protein kinase I is eluted at a lower salt concentration than protein kinase II and is stimulable to 10 times its basal catalytic activity, while protein kinase II is stimulable only 2-fold. Both kinases are completely dissociated by cyclic AMP and inhibited by specific cyclic AMP-dependent protein kinase inhibitor. They have similar Km values for magnesium (approximately 1 mM), cyclic AMP (approximately 60 nM), and ATP (approximately 0.1 mM), and the dissociation constant (Kdis) for cyclic AMP (approximately 13 nM) is the same for both enzymes. However, they appear to have different substrate preferences and cyclic AMP-binding properties in that cyclic AMP bound to protein kinase II exchanges readily with free cyclic AMP, while that bound to protein kinase I is not exchangeable. The native enzymes have different sedimentation coefficients (6.4 S for protein kinase I and 4.8 S for protein kinase II), whereas those of the activated enzymes are the same (2.9--3.0 S). It appears that the two cyclic AMP-dependent protein kinases which differ from each other in their regulatory subunits may play different roles in the mediation of cyclic AMP action in Chinese hamster ovary cells.     

Presence of the sites for interacting with cyclic AMP and with catalytic subunit on small fragments of protein kinase regulatory subunit.

During the purification of cyclic AMP binding proteins from rat liver, some smaller active fragments were obtained, possibly as the result of proteolysis. The binding proteins detected had approximate molecular weights of 50,000, 36,000, and 10,000. Each of these components bound cyclic [3H]AMP with high affinity (apparent dissociation constants ranging from 2 to 10 nM) and had a similar ability to inhibit the purified catalytic subunit of rat liver protein kinase. Cyclic AMP prevented this inhibition in each instance. These results suggest that the binding site for cyclic AMP and the site for interacting with catalytic subunit occur relatively close to one another on the regulatory subunit and can remain functional when a substantial fraction of the subunit is lost.     

Adenosine 3'':5''-cyclic monophosphate-binding proteins in bovine and rat tissues.

1. At least two classes of high-affinity cyclic AMP-binding proteins have been identified: those derived from cyclic AMP-dependent protein kinases (regulatory subunits) and those that bind a wide range of adenine analogues (adenine analogue-binding proteins). 2. In fresh-tissue extracts, regulatory subunits could be further subdivided into 'type I or 'type II' depending on whether they were derived from 'type I' or 'type II' protein kinase [see Corbin et al. (1975) J. Biol. Chem. 250, 218-225]. 3. The adenine analogue-binding protein was detected in crude tissue supernatant fractions of bovine and rat liver. It differed from the regulatory subunit of cyclic AMP-dependent protein kinase in many of its properties. Under the conditions of assay used, the protein accounted for about 45% of the binding of cyclic AMP to bovine liver supernatants. 4. The adenine analogue-binding protein from bovine liver was partially purified by DEAE-cellulose and Sepharose 6B chromatography. It had mol.wt. 185000 and was trypsin-sensitive. As shown by competition and direct binding experiments, it bound adenosine and AMP in addition to cyclic AMP. At intracellular concentrations of adenine nucleotides, binding of cyclic AMP was essentially completely inhibited in vitro. Adenosine binding was inhibited by only 30% under similar conditions. 5. Rat tissues were examined for the presence of the adenine analogue-binding protein, and, of those examined (adipose tissue, heart, brain, testis, kidney and liver), significant amounts were only found in the liver. The possible physiological role of the adenine analogue-binding protein is discussed. 6. Because the adenine analogue-binding protein or other cyclic AMP-binding proteins in tissues may be products of partial proteolysis of the regulatory subunit of cyclic AMP-dependent protein kinase, the effects of trypsin and aging on partially purified protein kinase and its regulatory subunit from bovine liver were investigated. In all studies, the effects of trypsin and aging were similar. 7. In fresh preparations, the cyclic AMP-dependent protein kinase had mol.wt. 150000. Trypsin treatment converted it into a form of mol.wt 79500. 8. The regulatory subunit of the protein kinase had mol.wt. 87000. It would reassociate with and inhibit the catalytic subunit of the enzyme. Trypsin treatment of the regulatory subunit produced a species of mol.wt. 35500 which bound cyclic AMP but did not reassociate with the catalytic subunit. Trypsin treatment of the protein kinase and dissociation of the product by cyclic AMP produced a regulatory subunit of mol.wt. 46500 which reassociated with the catalytic subunit. 9. These results may be explained by at least two trypsin-sensitive sites on the regulatory subunit. A model for the effects of trypsin is described.     

Guanosine cyclic monophosphate-dependent protein kinase from foetal calf heart. Purification, general properties and catalytic subunit.

Cyclic GMP-dependent protein kinase was purified from foetal calf hearts, and its general properties and subunit structure were studied. The enzyme was purified over 900-fold from the heart extract by pH 5.3-isoelectric precipitation, DEAE-cellulose chromatography, Sephadex G-200 filtration and hydroxyapatite treatment. The purified myocardial enzyme, free from cyclic AMP-dependent protein kinase contamination, exhibited an absolute requirement of stimulatory modulator (or crude modulator containing the stimulatory modulator component) for its cyclic GMP-stimulated activity. Inhibitory modulator (protein inhibitor) of cyclic AMP-dependent protein kinase could not stimulate nor inhibit the cyclic GMP target enzyme. The enzyme had Ka values of 0.013, 0.033 and 3.0 micronM for 8-bromo cyclic GMP, cyclic GMP and cyclic AMP respectively. The cyclic GMP-dependent enzyme required Mg2+ and Co2+ for its activity, with optimal concentrations of about 30 and 0.5 mM respectively. The pH optimum for the enzyme activity ranged from 6 to 9. Histones were generally effective substrate proteins. The enzyme exhibited a greater affinity for histones than did the cyclic AMP-dependent class of protein kinase. The holoenzyme (apparent mol.wt. 150 000) of the myocardial cyclic GMP-dependent protein kinase was dissociated into a cyclic GMP-independent catalytic subunit (apparent mol.wt. 60 000) by cyclic GMP and histone. The catalytic subunit required the stimulatory modulator for its activity, as in the case of the holoenzyme in the presence of cyclic GMP.     

Antiserum against the catalytic subunit of adenosine 3'':5''-cyclic monophosphate-dependent protein kinase. Reactivity towards various protein kinases.

An antiserum against the catalytic subunit C of cyclic AMP-dependent protein kinase, isolated from bovine heart type II protein kinase, was produced in rabbits. Reaction of the catalytic subunit with antiserum and separation of the immunoglobulin G fraction by Protein A-Sepharose quantitatively removed the enzyme from solutions. Comparative immunotitration of protein kinases showed that the amount of antiserum required to eliminate 50% of the enzymic activity was identical for pure catalytic subunit, and for holoenzymes type I and type II. The reactivity of the holoenzymes with the antiserum was identical in the absence or the presence of dissociating concentrations of cyclic AMP. Most of the holoenzyme (type II) remains intact when bound to the antibodies as shown by quantification of the regulatory subunit in the supernatant of the immunoprecipitate. Titration with the antibodies also revealed the presence of a cyclic AMP-independent histone kinase in bovine heart protein kinase I preparations obtained by DEAE-cellulose chromatography. Cyclic AMP-dependent protein kinase purified from the particulate fraction of bovine heart reacted with the antiserum to the same degree as the soluble enzyme, whereas two cyclic AMP-independent kinases separated from the particle fraction neither reacted with the antiserum nor influenced the reaction of the antibodies with the cyclic AMP-dependent protein kinase. Immunotitration of the protein kinase catalytic subunit C from rat liver revealed that the antibodies had rather similar reactivities towards the rat liver and the bovine heart enzyme. This points to a relatively high degree of homology of the catalytic subunit in mammalian tissues and species. Broad applicability of the antiserum to problems related to cyclic AMP-dependent protein kinases is thus indicated.     

Inhibition of cyclic AMP-dependent protein kinase activity by the cardiotonic drugs amrinone and milrinone

Amrinone and milrinone are new cardiotonic drugs that have potent inotropic and vasodilatory properties. The mechanism of action of these agents is controversial, but the positive inotropic component is thought to be due to the inhibition of phosphodiesterase. Because amrinone and milrinone have been shown to be involved primarily in cyclic AMP-mediated processes, we examined the effect of these agents on cyclic AMP-dependent protein kinase. The results indicate that amrinone and milrinone inhibit cyclic AMP-dependent protein kinase activity by competing with ATP but not cyclic AMP binding sites. Dissociation constants (Ki) of amrinone and milrinone for ATP binding sites on protein kinase were calculated to be 100-300 microM and 842 microM, respectively. The phosphodiesterase inhibitor isobutylmethylxanthine (1 mM) had no effect on protein kinase activity. Amrinone and milrinone inhibited the catalytic subunit of protein kinase to the same degree as the holo-enzyme by competitively inhibiting the binding of ATP. Amrinone and milrinone had no effect on phospholipid-sensitive, calcium-dependent protein kinase indicating that there may be differences in the ATP binding sites on these two protein kinases. Inhibition of cyclic AMP-dependent protein kinase by amrinone and milrinone occurs at concentrations higher than those used clinically. However, because amrinone and milrinone are lipophilic drugs, they may be useful tools for the investigation of protein kinase mediated reactions.     

Further studies on cyclic adenosine 3':5'-monophosphate protein kinase from dimorphic fungus Mucor rouxii

In this paper, cyclic adenosine-3′:5′-monophosphate-dependent protein kinase from yeast-like cells of Mucor rouxii is characterized. A scheme of partial purification is described together with K_m for ATP (15 μm), histone (0.2 mg/ml), half-maximal activation constant for cyclic AMP (30 nm), and dissociation constant for the binding of cyclic AMP (40 nm). This enzyme is similar to type II protein kinases in two main aspects: the elution position in DEAE-cellulose chromatography and the readiness of its reassociation. But it has a singular characteristic: it does not dissociate completely with cyclic AMP alone (even at concentrations as high as 0.3 mm) unless histone or NaCl is present. NaCl displays several roles: helps dissociation, prevents inactivation of the catalytic subunit, inhibits enzyme activity, and does not prevent reassociation as occurs with type II protein kinases. Once the holoenzyme is dissociated, cyclic AMP is essential to maintain the enzyme in the dissociated state.     

Isolation and characterization of a dimeric cAMP-dependent protein kinase from the fungus Saccobolus platensis

A cAMP-dependent protein kinase from mycelia of Saccobolus platensis was characterized. The holoenzyme seems to be a dimer (i.e., regulatory subunit--catalytic subunit) of 78,000 Da, slightly activated by cAMP but susceptible to dissociation into its subunits by cAMP, or by kemptide and protamine, the best substrates for Saccobolus protein kinase. The regulatory subunit was purified to homogeneity by affinity chromatography. It is highly specific for cAMP and has two types of binding sites but failed to inhibit the phosphotransferase activity of the homologous or the heterologous (bovine heart) catalytic components. The activity of the catalytic subunit was completely abolished by the regulatory component of the bovine heart protein kinase as well as by a synthetic peptide corresponding to the active site of the mammalian protein kinase inhibitor. The data suggest that interaction between the subunits of the S. platensis protein kinase is different than that found in cAMP-dependent protein kinases from other sources. Similarities and differences between the Saccobolus protein kinase and enzymes from low eucaryotes and mammalian tissues are discussed.