Activation of cyclic AMP-dependent protein kinase isoenzymes: studies using specific antisera

A novel method for rapidly determining the amount and degree of association-dissociation of the Type I and Type II cAMP-dependent protein kinases has been developed and validated. Antibodies directed against the regulatory subunits of Type I and Type II cAMP-dependent protein kinases were used. The antibodies formed complexes with holoenzymes and regulatory subunits which were precipitated by goat anti-rabbit IgG (immunoglobulin G). These complexes bound [3H]cAMP with an apparent Kb of 20 nM for protein kinase I and 80 nM for protein kinase II. Immunoprecipitated protein kinases I and II were catalytically active when incubated with cAMP, [gamma-32P]ATP, and histone H2B. When mixtures of the two kinase isoenzymes or cytosol were incubated with various amounts of [3H]cAMP and the isoenzymes were separated by precipitation with antisera specific for each isoenzyme, the amount of [3H]cAMP associated with immunoprecipitates was proportional to the concentration of [3H]cAMP. In contrast, the catalytic activity that was immunoprecipitated varied inversely with the concentration of [3H]cAMP, showing that the activation of protein kinase could be assessed by the disappearance of catalytic activity from the immunoprecipitates. In the absence of MgATP protein kinase I was activated by a 10-fold lower concentration of cAMP than protein kinase II. However, when MgATP was added to the incubation, there was no significant difference in the binding of [3H]cAMP or dissociation of catalytic subunits of the two isoenzymes. The anti-R antibodies were also used to rapidly quantitate the concentration of regulatory subunits and the relative ratio of protein kinases I and II in tissue cytosols.     

Enhanced activation of cAMP-dependent protein kinase by rapid synthesis and degradation of cAMP

Activation of cAMP-dependent protein kinase II by static and dynamic steady-state cAMP levels was studied by reconstituting an in vitro model system composed of hormone-sensitive adenylate cyclase, cyclic nucleotide phosphodiesterase, and cAMP-dependent protein kinase II. The rates of cAMP synthesis were regulated by incubating isolated membranes from AtT20 cells with various concentrations of forskolin. In the presence of 3-methylisobutylxanthine, the rate of protein kinase activation was proportional to the rate at which cAMP was synthesized, and there was a direct relationship between the degree of activation and the level of cAMP produced. The activation profiles of protein kinase generated in the presence of exogenous cAMP or cAMP produced by activation of adenylate cyclase in the absence of cAMP degradation were indistinguishable. Dynamic steady-state levels of cAMP were achieved by incubating the membranes with forskolin in the presence of purified cyclic nucleotide phosphodiesterase. Under these conditions, the apparent activation constant of protein kinase II for cAMP was reduced by 65-75%. This increased sensitivity to activation by cAMP was seen when phosphotransferase activity was measured directly in reaction mixtures containing membranes, protein kinase, and histone H2B or when regulatory and catalytic subunits were first separated by immunoprecipitation of holoenzyme and regulatory subunits with specific anti-serum. Our results are consistent with the hypothesis that rapid cAMP turnover may function as a mechanism for amplifying hormonal signals which use the cAMP-dependent protein kinase system.     

Comparison of cAMP-dependent protein kinase in normal and Rous sarcoma virus transformed chick embryo fibroblasts

cAMP-dependent protein kinase was compared in normal and Rous Sarcoma Virus transformed chicken embryo fibroblasts. Total cAMP binding activity and cAMP-dependent histone kinase activity were unaltered by RSV transformation. The apparent Km for activation of histone kinase activity by cAMP was 35 nM in both normal and transformed cells. Using 8-N3-cAMP photoaffinity labeling, normal and transformed cells were also found to contain equal quantities of a single 42,000 Mr regulatory sub-unit isoenzyme of A-kinase. This isoenzyme corresponded to the lower molecular weight isoenzyme of the two enzymes found in normal chicken skeletal muscle. Both avian isoenzymes were about 4,000 Mr smaller than the corresponding bovine type I and type II regulatory subunits. Rous Sarcoma Virus transformation does not directly alter the amount or activity of cAMP-dependent protein kinase.     

Microheterogeneity of adenosine cyclic monophosphate-dependent protein kinases from mouse brain and heart.

1. DEAE-cellulose chromatography of mouse brain cytosol indicated the presence of only the type II isoenzyme of cyclic AMP-dependent protein kinase. Mouse heart cytosol contained approximately equal amounts of the type I and type II isoenzymes. 2. Both brain and heart type II isoenzymes reassociated after a transient exposure to cyclic AMP, but the heart type I isoenzyme remained dissociated. 3. Elution of brain cytosol continuously exposed to cyclic AMP resolved multiple peaks of protein kinase and cyclic AMP-binding activities. A single peak of kinase and multiple peaks of cyclic AMP-binding activities were found under the same conditions with heart cytosol. Various control experiments suggested that the heterogeneity within the brain type II isoenzymic class had not been caused by proteolysis. 4. Kinetic experiments with unfractionated brain cytosol showed that the binding of cyclic AMP, the dissociation of cyclic AMP from protein and the rate of heat denaturation of the cyclic AMP-binding activity gave results consistent with the presence of multiple binding species. 5. It concluded that the type II isoenzymic peak obtained by DEAE-cellulose chromatography of mouse brain cytosol represents a class of enzymes containing multiple regulatory and catalytic subunits. The two heart cytosol isoenzymes contain a common catalytic subunit. The degree of protein kinase 'microheterogeneity", defined as the presence of multiple regulatory and/or catalytic subunits within a single isoenzymic class, appears to be tissue-specific.     

Localization of cellular regulatory proteins using postembedding immunogold labeling

Cyclic AMP-dependent protein kinase (cAPK) mediates the effects of catecholamines and hormones that cause elevation of intracellular cyclic AMP levels. The holoenzyme is a tetramer consisting of catalytic (C) and cyclic AMP-binding regulatory (R) subunits. The type I and type II cAPK isoenzymes are defined by R subunits (RI and RII) of differing molecular weight, primary structure, and cyclic AMP-binding properties. Postembedding immunogold labeling procedures and specific polyclonal and monoclonal antibodies to RI, RII, and C were used to study the subcellular distribution of cAPK subunits in several tissues. In the rat parotid gland, both RI and RII were present in the cytoplasm, nuclei, and secretory granules of the acinar cells, whereas secretory granules of intercalated and striated duct cells were poorly labeled. These results confirmed that the acinar secretory granules are the source of R subunits previously identified in saliva by specific photoaffinity labeling techniques. Zymogen granules of pancreatic acinar cells and secretory granules of seminal vesicle cells were labeled with antibody to RII. Pancreatic and seminal fluids were shown to contain cyclic AMP-binding proteins. The granules of several endocrine cells (pituitary, pancreatic islet, intestinal) also labeled with RII antibody. Double labeling of ovarian granulosa cells showed that both RI and C were present in the nuclei and cytoplasm. The localization of cAPK subunits revealed by postembedding immunogold labeling is consistent with the postulated regulatory functions of these proteins in gene expression, cell proliferation, exocytosis, and various metabolic events The widespread occurrence of cAPK subunits in secretory granules and their release to the extracellular environment suggests that they play an important role in secretory cell function.     

Separation of the complexes formed between the regulatory and catalytic subunits of cyclic adenosine monophosphate-dependent protein kinase and topoisomerase I activity in preovulatory follicle-enriched immature rat ovaries

Our previous studies have shown that the regulatory subunits of the type II form of cAMP-dependent protein kinase (RII) present in soluble extract of immature rat ovaries elute from diethylaminoethyl-cellulose as three separate peaks of activity, based on their association with the catalytic subunit (C) of this enzyme, as R2IIC2, an apparent R2IIC, and R2II. Based upon the existence of ovarian RII in three different subunit arrangements, the large amount of C subunit-free R2II in this tissue, and a previous report which indicated that RII exhibited intrinsic topoisomerase I activity, we determined whether DNA topoisomerase I activity was associated with any of these molecular complexes of the ovarian RII subunits. Cyclic AMP-binding activities in soluble extracts of preovulatory follicle-enriched immature rat ovaries were separated by diethylaminoethyl-cellulose chromatography and sucrose density gradient centrifugation. Topoisomerase I activity cosedimented with the apparent R2IIC and R2II obtained from sucrose gradients but was not detected in fractions containing R2IIC2. Upon cAMP affinity purification of the RII derived from fractions containing R2IIC2, R2IIC, and R2II, respectively, no topoisomerase I activity could be detected in any fraction. Phosphorylation of the affinity purified RIIs by the C subunit of beef heart cAMP-dependent protein kinase did not alter this result. These data indicate that none of the RII subunits in soluble extracts of preovulatory follicle-enriched ovaries exhibit intrinsic topoisomerase I activity.     

Isozymes of cAMP-dependent protein kinase present in the rat corpus luteum.

Regulatory (R) subunits and their association with catalytic subunits to form cAMP-dependent protein kinase holoenzymes were investigated in corpora lutea of pregnant rats. Following separation by DEAE-cellulose chromatography, R subunits were identified by labeling with 8-N3[32P]cAMP and autophosphorylation on one and two-dimensional gel electrophoresis and by reactivity with antisera. DEAE-cellulose elution of R subunits with catalytic subunits as holoenzymes or without catalytic subunits was determined by sedimentation characteristics on sucrose density gradient centrifugation and by cAMP-stimulated kinase activation characteristics on Eadie-Scatchard analysis. We identified the presence of a type I holoenzyme containing RI alpha (Mr 47,000) subunits, a prominent type II holoenzyme containing RII beta (Mr 52,000) subunits, and a second more acidic type II holoenzyme peak containing both RII beta and RII alpha (Mr 54,000) subunits. However, the majority of total R subunit activity was associated with a catalytic subunit-free peak of RI alpha protein which on elution from DEAE-cellulose was associated with cAMP. This report establishes the more basic elution position from DEAE-cellulose of the prominent rat luteal RII beta holoenzyme in very close proximity to free RI alpha and presents one of the few reports of a normal tissue containing a large percentage of catalytic subunit-free RI alpha.     

Differential activation of type I and type II 3',5'-cyclic adenosine monophosphate-dependent protein kinases by growth hormone-releasing factor

Rat GH-releasing factor (rGRF) stimulated GH release and intracellular cAMP accumulation in cultured rat anterior pituitary cells with EC50 values of approximately 10 and 150 pm, respectively. Consistent with an effect on cellular cAMP levels, rGRF stimulated the adenylate cyclase activity of rat anterior pituitary membranes with an EC50 value of approximately 60 pm. Using antisera directed against the regulatory subunits of type I and II cAMP-dependent protein kinases, these enzymes were immunoprecipitated from the cytosolic fraction of cultured cells in order to monitor the degree of their activation by rGRF. Both isoenzymes were rapidly activated in cells incubated with rGRF but with different kinetics; full activation of protein kinase I was evident within 3-5 min and activation of protein kinase II occurred between 5 and 15 min. The magnitude of activation was differentially regulated by rGRF in a concentration-dependent manner. Somatostatin only partially attenuated rGRF-stimulated GH release, cAMP accumulation, and adenylate cyclase activation. Somatostatin was effective in partially antagonizing activation of protein kinase II at all concentrations of rGRF and of protein kinase I only at intermediate concentrations of rGRF. The significance of this rGRF-induced differential activation of the two isoenzymes of cAMP-dependent protein kinase is discussed in terms of the multiple effects of rGRF on somatotropic cells of the rat anterior pituitary.     

In situ reassociation of the regulatory and catalytic subunits of 3',5'-cyclic adenosine monophosphate-dependent protein kinase isoenzymes in AtT20 cells

Dissociation and reassociation of regulatory (R) and catalytic (C) subunits of cAMP-dependent protein kinases I and II were studied in intact AtT20 cells. Cells were stimulated with 50 microM forskolin to raise intracellular cAMP levels and induce complete dissociation of R and C subunits. After the removal of forskolin from the incubation medium cAMP levels rapidly declined to basal levels. Reassociation of R and C subunits was monitored by immunoprecipitation of cAMP-dependent protein kinase activity using anti-R immunoglobulins. The time course for reassociation of R and C subunits paralleled the loss of cellular cAMP. Total cAMP-dependent protein kinase activity and the ratio of protein kinase I to protein kinase II seen 30 min after the removal of forskolin was the same as in control cells. Similar results were seen using crude AtT20 cell extracts treated with exogenous cAMP and Mg2+. Our data showed that after removal of a stimulus from AtT20 cells inactivation of both cAMP-dependent protein kinase isoenzymes occurred by the rapid reassociation of R and C subunits to form holoenzyme. Our studies also showed that half of the type I regulatory subunit (RI) present in control cells contained bound cAMP. This represented approximately 30% of the cellular cAMP in nonstimulated cells. The cAMP bound to RI was resistant to hydrolysis by cyclic nucleotide phosphodiesterase but was dissociated from RI in the presence of excess purified bovine heart C. The RI subunits devoid of C may function to sequester cAMP and, thereby, prevent the activation of cAMP-dependent protein kinase activity in nonstimulated AtT20 cells.     

Stoichiometry of cAMP binding and limited proteolysis of protein kinase regulatory subunits R I and R II.

Protein kinase regulatory subunits type I (rabbit skeletal muscle) and type II (bovine heart) were isolated by a rapid two step procedure which involved affinity chromatography on an 8-thio cAMP matrix. The R proteins were analyzed for cAMP binding capacity using three different methods for the separation of bound from free cAMP, and various methods for protein determination. Regulatory subunits type I as well as type II were both found to contain $\text{two}$ high affinity cAMP binding sites per R monomer corresponding to a formula for the native R proteins of R₂·cAMP₄. - Kinetic analyses of limited proteolysis by various proteases revealed striking differences between R I and R II with respect to loss of cAMP binding capacity, ability to inhibit the catalytic subunit C, and susceptibility to further degradation. Some of the products had lost about one half of the cAMP binding capacity supporting the presence of two binding sites in R while other degradation products showed no change in high affinity binding sites. By contrast, the ability to inhibit the catalytic subunit C was lost in all products of limited proteolysis except one.     

Reduced levels of cardiac cAMP-dependent protein kinase in spontaneously hypertensive rat

Cardiac cAMP-dependent protein kinases were compared between the spontaneously hypertensive rat and the age-matched normotensive Wistar-Kyoto rat by DEAE-cellulose chromatography, photoaffinity labeling with 8-N3[32P]cAMP, and Western blots using the antiregulatory and 125I-anticatalytic subunit antibodies. DEAE-cellulose chromatography revealed that the ratio of type I to type II cAMP-dependent protein kinase was 3:1 in the cytoplasmic soluble proteins from the heart of normotensive rat. In contrast, the ratio of type I to type II was 1:1 in the heart of hypertensive rat. Type I protein kinase was reduced by 3-fold in hypertensive rat compared to normotensive rat. The levels of type II protein kinase were similar in both normotensive and hypertensive rats. The ratio of regulatory subunits of type I (RI) to type II (RII) cAMP-dependent protein kinase was 2.5 in the soluble proteins from the heart of normotensive rat compared to a ratio of 0.62 for hypertensive rat. RI was reduced by 4-fold in hypertensive rat compared to normotensive rat. The decrease in RI from hypertensive rat was also demonstrated by photoaffinity labeling with 8-N3[32P] cAMP. Western blot analysis of the catalytic subunit revealed a 2-fold decrease in catalytic subunit (C) in the soluble proteins from the hypertensive rat compared to normotensive rat. These results show that the reduced level of activity of cardiac type I protein kinase in hypertensive rat was the result of a decrease in both the RI and C subunits, thus reducing the number of type I cAMP-dependent protein kinase holoenzyme molecules. Comparison of type I protein kinase from "prehypertensive" and "hypertensive" stages of hypertensive rat indicated that the type I protein kinase was reduced by 3-fold before an increase in the blood pressure was detectable. Cardiac type I protein kinase is predominantly associated with the cytoplasmic proteins in both the normotensive and hypertensive rats. The levels of RI, RII, and C associated with the membrane-solubilized proteins were not affected in the hypertensive rat. The levels of RII were similar in the brain tissue of normotensive and hypertensive rats, suggesting that the decrease in type I protein kinase is specific in hypertensive rat. In conclusion, a decrease in cardiac type I cAMP-dependent protein kinase may affect the degree of phosphorylation of cardiac regulatory proteins, thus impairing normal cardiac physiology in hypertensive rat.     

Activation of type I cyclic AMP-dependent protein kinases with defective cyclic AMP-binding sites

Two S49 mouse lymphoma cell variants hemizygous for expression of mutant regulatory (R) subunits of type I cyclic AMP-dependent protein kinase were used to investigate functional consequences of lesions in the putative cAMP-binding sites of R subunit. Kinase activation properties of wild-type and mutant enzymes were compared using cAMP and six site-selective analogs of cAMP. Kinases from both mutant sublines were relatively resistant to cyclic nucleotide-dependent activation, but they were fully activable by at least some effectors. Relative resistances of the mutant kinases varied from about 5-fold for analogs selective for their nonmutated sites to as much as 700-fold for analogs selective for their mutated sites; resistance to cAMP was intermediate. Apparent affinities of wild-type and mutant R subunits for [3H]cAMP were not appreciably different, but competition experiments with site-selective analogs of cAMP suggested that binding of cAMP to mutant R subunits was primarily to their nonmutated sites. Analyses of cooperativity in cyclic nucleotide-dependent activation of mutant kinases, synergism between site I- and site II-selective analogs in activating the mutant enzymes, and dissociation of bound cAMP from mutant R subunits provided additional evidence that the mutations in these strains selectively inactivated single classes of cAMP-binding sites: phenomena attributable in wild-type enzyme to intrachain interactions between sites I and II were always absent or severely diminished in experiments with the mutant enzymes. These results confirm that R subunit sequences implicated in cAMP binding by homology with other cyclic nucleotide-binding proteins actually correspond to functional cAMP-binding sites. Furthermore, occupation of either cAMP-binding site I or II is apparently sufficient for activation of cAMP-dependent protein kinase. The presence of four functional cAMP-binding sites in wild-type kinase enhances the cooperativity and sensitivity of cAMP-mediated activation.     

Molecular basis for regulatory subunit diversity in cAMP-dependent protein kinase: crystal structure of the type II beta regulatory subunit

BACKGROUND: Cyclic AMP binding domains possess common structural features yet are diversely coupled to different signaling modules. Each cAMP binding domain receives and transmits a cAMP signal; however, the signaling networks differ even within the same family of regulatory proteins as evidenced by the long-standing biochemical and physiological differences between type I and type II regulatory subunits of cAMP-dependent protein kinase. RESULTS: We report the first type II regulatory subunit crystal structure, which we determined to 2.45 A resolution and refined to an R factor of 0.176 with a free R factor of 0.198. This new structure of the type II beta regulatory subunit of cAMP-dependent protein kinase demonstrates that the relative orientations of the two tandem cAMP binding domains are very different in the type II beta as compared to the type I alpha regulatory subunit. Each structural unit for binding cAMP contains the highly conserved phosphate binding cassette that can be considered the "signature" motif of cAMP binding domains. This motif is coupled to nonconserved regions that link the cAMP signal to diverse structural and functional modules. CONCLUSIONS: Both the diversity and similarity of cAMP binding sites are demonstrated by this new type II regulatory subunit structure. The structure represents an intramolecular paradigm for the cooperative triad that links two cAMP binding sites through a domain interface to the catalytic subunit of cAMP-dependent protein kinase. The domain interface surface is created by the binding of only one cAMP molecule and is enabled by amino acid sequence variability within the peptide chain that tethers the two domains together.     

Adenosine-3':5'-monophosphate-binding proteins from bovine kidney. Isolation by affinity chromatography and limited proteolysis of the regulatory subunit of protein kinase II.

Affinity chromatography on cyclic AMP columns allowed a two-step isolation of the cyclic-AMP-binding proteins from bovine kidney cytosol. An AMP-binding protein (apparent molecular weight approximately 60 000) and large amounts of a low affinity binding protein ('P35'; apparent subunit size approximately 35 000) were obtained in practically pure form besides the high affinity binding proteins of the R type. Among the R proteins the dimer R2 of the regulatory subunit of protein kinase II (apparent subunit size approximately 54 000) represented the bulk material. Small amounts of monomer, of higher aggregates, and of a protein 'P49' (subunit size approximately 49 000) presumably identical with the regulatory subunit of protein kinase I were also detected. The R protein fraction of kidney also contained a high affinity binding protein of smaller size (designated as R'; molecular weight approximately 37 000) which appeared to be derived from protein R2 of protein kinase II by limited proteolysis. At all stages of purification, R protein and its aggregates could be quantitatively transformed into R' protein (or a closely related polypeptide) by several proteases including the relatively unspecific proteinase K. The degradation product exhibited unchanged cyclic-AMP-binding capacities but had largely lost the ability to inhibit the catalytic subunit C of protein kinase, to be phosphorylated by C, and to form a dimer. Preliminary experiments indicate that protein R' may be a natural component of kidney tissue.     

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.     

Analysis of the dominance of mutations in cAMP-binding sites of murine type I cAMP-dependent protein kinase in activation of kinase from heterozygous mutant lymphoma cells.

Structural lesions in cAMP-binding sites of regulatory (R) subunit of cAMP-dependent protein kinase caused identical increases in apparent constants for cyclic nucleotide-dependent kinase activation in preparations from cells that were hemizygous or heterozygous for mutant R1 subunit expression. No wild-type kinase activation was observed in extracts from heterozygous mutant cells. This "dominance" was investigated by characterizing expression of wild-type and mutant R1 subunits and properties of protein kinase from S49 mouse lymphoma cell mutants heterozygous for expression of wild-type R1 subunits and R1 subunits with a lesion (Glu200) that inactivates cAMP-binding site A. By both studies of cAMP dissociation and two-dimensional gel analysis, wild-type R subunits comprised about 35% of total R1 subunits in heterozygous mutants. Synthesis of wild-type and mutant R1 subunits was equivalent, but wild-type subunits were degraded preferentially. Hydroxylapatite chromatography revealed a novel R1 subunit-containing species from heterozygous mutant preparations whose elution behavior suggested a trimeric kinase consisting of an R1 subunit dimer and one catalytic (C) subunit. Wild-type R1 subunit was found only in dimer and "trimer" peaks; the tetrameric kinase peak contained only mutant R1 subunit. It is concluded that C subunit binds preferentially to mutant R1 subunit in heterozygous cells forming either tetrameric kinase with mutant R1 subunit homodimers or trimeric kinase with R1 subunit heterodimers. This preferential binding results both in suppression of wild-type kinase activation and differential stabilization of mutant R1 subunits.     

Catalytic independent functions of a protein kinase as revealed by a kinase-dead mutant: study of the Lys72His mutant of cAMP-dependent kinase

A highly conserved lysine in subdomain II is required for high catalytic activity among the protein kinases. This lysine interacts directly with ATP and mutation of this residue leads to a classical "kinase-dead" mutant. This study describes the biophysical and functional properties of a kinase-dead mutant of cAMP-dependent kinase where Lys72 was replaced with His. Although the mutant protein is less stable than the wild-type catalytic subunit, it is fully capable of binding ATP. The results highlight the effect of the mutation on stability and overall organization of the protein, especially the small lobe. Phosphorylation of the activation loop by a heterologous kinase, 3-phosphoinositide-dependent protein kinase-1 (PDK-1) also contributes dramatically to the global organization of the entire active site region. Deuterium-exchange mass spectrometry (DXMS) indicates a concerted stabilization of the entire active site following the addition of this single phosphate to the activation loop. Furthermore the mutant C-subunit is capable of binding both the type I and II regulatory subunits, but only after phosphorylation of the activation loop. This highlights the role of the large lobe as a scaffold for the regulatory subunits independent of catalytic competency and suggests that kinase dead members of the protein kinase superfamily may still have other important biological roles although they lack catalytic activity.     

Reconstitution of types I and II adenosine cyclic 3',5'-phosphate dependent protein kinase

Fluorescence intensity and anisotropy measurements using the fluorescent adenosine cyclic 3',5'-phosphate (cAMP) analogue 1,N6-ethenoadenosine cyclic 3',5'-phosphate (epsilon-cAMP) are sensitive to the dissociation of epsilon-cAMP which occurs when either the type I or the type II regulatory subunit (RI or RII) of cAMP-dependent protein kinase associates with the catalytic subunit. Studies using epsilon-cAMP show that MgATP has opposite effects on the reconstitution of both types of protein kinase: MgATP strongly stabilizes the type I holoenzyme while it slightly destabilizes the type II holoenzyme. The synthetic substrate Kemptide has a small inhibitory effect on the reconstitution of both holoenzymes when tested at 10 microM concentration. The protein kinase inhibitor has a larger effect which is especially pronounced in the reassociation of the type I enzyme. The diminished relative ability of the type I regulatory subunit to compete with the protein kinase inhibitor suggests that the combined effects of the two opposing equilibria (epsilon-cAMP and catalytic subunit binding) are different for the two types of regulatory subunits. Displacement experiments show that cAMP and epsilon-cAMP bind about equally well to the type I subunit. Slow conformational changes accompanying the binding of epsilon-cAMP by both regulatory subunits are greatly accelerated with the holoenzymes, suggesting that dissociation of the holoenzymes occurs via ternary complexes. The time courses of epsilon-cAMP binding also show the heterogeneity of binding characteristics of RII. The 37 000-dalton fragment of type II subunit retains the epsilon-cAMP binding properties of the native subunit. However, only a fraction of the fragment preparation (approximately 32% estimated from sedimentation measurements) binds the catalytic subunit well, suggesting heterogeneity of cleavage.