Mutation of recombinant catalytic subunit alpha of the protein kinase CK2 that affects catalytic efficiency and specificity

In order to understand better the structural and functional relations between protein kinase CK2 catalytic subunit, the triphosphate moiety of ATP, the catalytic metal and the peptidic substrate, we built a structural model of Yarrowia lipolytica protein kinase CK2 catalytic subunit using the recently solved three-dimensional structure of the maize enzyme and the structure of cAMP-dependent protein kinase peptidic inhibitor (1CDK) as templates. The overall structure of the catalytic subunit is close to the structure solved by Niefind et al. It comprises two lobes, which move relative to each other. The peptide used as substrate is tightly bound to the enzyme, at specific locations. Molecular dynamic calculations in combination with the study of the structural model led us to identify amino acid residues close to the triphosphate moiety of ATP and a residue sufficiently far from the peptide that could be mutated so as to modify the specificity of the enzyme. Site-directed mutagenesis was used to replace by charged residues both glycine-48, a residue located within the glycine-rich loop, involved in binding of ATP phosphate moiety, and glycine-177, a residue close to the active site. Kinetic properties of purified wild-type and mutated subunits were studied with respect to ATP, MgCl(2) and protein kinase CK2 specific peptide substrates. The catalytic efficiency of the G48D mutant increased by factors of 4 for ATP and 17.5 for the RRRADDSDDDDD peptide. The mutant G48K had a low activity with ATP and no detectable activity with peptide substrates and was also inhibited by magnesium. An increased velocity of ADP release by G48D and the building of an electrostatic barrier between ATP and the peptidic substrate in G48K could explain these results. The kinetic properties of the mutant G177K with ATP were not affected, but the catalytic efficiency for the RRRADDSDDDDD substrate increased sixfold. Lysine 177 could interact with the lysine-rich cluster involved in the specificity of protein kinase CK2 towards acidic substrate, thereby increasing its activity.     

Mechanism of activation of cAMP-dependent protein kinase: in Mucor rouxii the apparent specific activity of the cAMP-activated holoenzyme is different than that of its free catalytic subunit

Kinetic constants for peptide phosphorylation by the catalytic subunit of the dimorphic fungus Mucor rouxii protein kinase A were determined using 13 peptides derived from the peptide containing the basic consensus sequence RRASVA, plus kemptide, S6 peptide, and protamine. As a whole, although with a greater Km, the order of preference of the peptides by the M. rouxii catalytic subunit was similar to the one displayed by mammalian protein kinase A. Particularly significant is the replacement of serine by threonine in the basic peptide RRATVA, which impaired its role as a substrate of M. rouxii catalytic subunit. Mucor rouxii protein kinase A is a good model in which to study the mechanism of activation since cAMP alone is not enough to promote activation and dissociation. Four peptides were selected for the study of holoenzyme activation under conditions in which the enzymatic activity was not proportional to the holoenzyme concentration: RRASVA, RRRRASVA, KRRRLSSRA (S6 peptide), and LRRASLG (kemptide); protamine was used as reference. Differential activation degree was observed depending on the peptide used and on cAMP concentration. Ratios of activity between different substrates displayed by the holoenzyme under the above conditions did not reflect the one expected for the free catalytic subunit. The degree of inhibition of the holoenzyme activity by an active peptide derived from the thermostable protein kinase inhibitor was dependent on the substrate used and on the holoenzyme concentration, while it was found to be independent of these two parameters for free catalytic subunit. Polycation modulation of holoenzyme activation by cAMP was also dependent on the polycation itself and on the peptide used as substrate. The observed kinetic differences between holoenzyme and free catalytic subunit were decreased or almost abolished when working at low enzyme or at high cAMP concentrations. Two hypotheses compatible with the results are discussed: substrate participation in the dissociation process and/or holoenzyme activation without dissociation.     

Allosteric Effect of Adenosine Triphosphate on Peptide Recognition by 3′5′-Cyclic Adenosine Monophosphate Dependent Protein Kinase Catalytic Subunits

The allosteric influence of adenosine triphosphate (ATP) on the binding effectiveness of a series of peptide inhibitors with the catalytic subunit of 3′5′-cyclic adenosine monophosphate dependent protein kinase was investigated, and the dependence of this effect on peptide structure was analyzed. The allosteric effect was calculated as ratio of peptide binding effectiveness with the enzyme-ATP complex and with the free enzyme, quantified by the competitive inhibition of the enzyme in the presence of ATP excess, and by the enzyme-peptide complex denaturation assay, respectively It was found that the principle “better binding—stronger allostery” holds for interactions of the studied peptides with the enzyme, indicating that allostery and peptide binding with the free enzyme are governed by the same specificity pattern. This means that the allosteric regulation does not include new ligand–protein interactions, but changes the intensity (strength) of the interatomic forces that govern the complex formation in the case of each individual ligand. We propose that the allosteric regulation can be explained by the alteration of the intrinsic dynamics of the protein by ligand binding, and that this phenomenon, in turn, modulates the ligand off-rate from its binding site as well as the binding affinity. The positive allostery could therefore be induced by a reduction in the enzyme’s overall intrinsic dynamics.     

Studies of the mechanism of action and regulation of cAMP-dependent protein kinase

Magnetic resonance and kinetic studies of the catalytic subunit of a Type II cAMP-dependent protein kinase from bovine heart have established the active complex to be an enzyme-ATP-metal bridge. The metal ion is β,γ coordinated with Δ chirality at the β-phosphorous atom. The binding of a second metal ion at the active site which bridges the enzyme to the three phosphoryl groups of ATP, partially inhibits the reaction. Binding of the metal-ATP substrate to the enzyme occurs in a diffusion-controlled reaction followed by a 40 ° change in the glycosidic torsional angle. This conformational change results from strong interaction of the nucleotide base with the enzyme. NMR studies of four ATP-utilizing enzymes show a correlation between such conformational changes and high nucleotide base specificity. Heptapeptide substrates and substrate analogs bind to the active site of the catalytic subunit at a rate significantly lower than collision frequency indicating conformational selection by the enzyme or a subsequent slow conformational change. NMR studies of the conformation of the enzyme-bound peptide substrates have ruled out α-helical and β-pleated sheet structures. The results of kinetic studies of peptide substrates in which the amino acid sequence was systematically varied were used to rule out the obligatory requirement for all possible β-turn conformations within the heptapeptide although an enzymatic preference for a β_2–5 or β_3–6 turn could not be excluded. Hence if protein kinase has an absolute requirement for a specific secondary structure, then this structure must be a coil. In the enzyme-substrate complex the distance along the reaction coordinate between the γ-P of ATP and the serine oxygen of the peptide substrate (5.3 ± 0.7 Å) allows room for a metaphosphate intermediate. This finding together with kinetic observations as well as the location of the inhibitory metal suggest a dissociative mechanism for protein kinase, although a mechanism with some associative character remains possible. Regulation of protein kinase is accomplished by competition between the regulatory subunit and peptide or protein substrates at the active site of the catalytic subunit. Thus, the regulatory subunit is found by NMR to block the binding of the peptide substrate to the active site of protein kinase but allows the binding of the nucleotide substrate and divalent cations. The dissociation constant of the regulatory subunit from the active site (10^?10m) is increased ~10-fold by phosphorylation and ~10⁴-fold by the binding of cAMP, to a value (10^?5m) which exceeds the intracellular concentration of the R₂C₂ holoenzyme complex (10^?6m). The resulting dissociation of the holoenzyme releases the catalytic subunit, permitting the active site binding of peptide or protein substrates.     

Studies on the mechanism of action of histone kinase dependent on adenosine 3':5'-monophosphate. Evidence for involvement of histidine and lysine residues in the phosphotransferase reaction.

The reaction of the phosphate residue transfer catalysed by histone kinase dependent on adenosine 3':5'-monophosphate (cyclic AMP) was studied. The phosphotransferase reaction was shown to obey the mechanism of ping-pong bi-bi type. After incubation of the catalytic subunit of histone kinase with [gamma-32P]ATP the incorporation of one mole of [32P]phosphage per mole of protein was observed. The tryptic [32P]phosphohistidine-containing peptide was isolated and its N-terminus and amino acid composition were determined. The 2',3'-dialdehyde derivative of ATP (oATP) was used as the affinity label for the catalytic subunit of cyclic-AMP-dependent histone kinase. The inhibitor formed an alidmine bond with epsilon-amino group of the lysine residue of the active site and was irreversibly bound to the enzyme after reduction by sodium borohydride with concurrent irreversible inactivation of the enzyme. After inactivation, about one mole of 14C-labelled inhibitor was incorporated per mole of the enzyme. ATP effectively protected the catalytic subunit of histone kinase against inactivation by oATP. Tryptic digestion of the enzyme-inhibitor complex led to the isolation of the 14C-labelled peptide of the active site of histone kinase. Basing on these results, the role of histidine and lysine residues in the active site of the catalytic subunit of histone kinase was suggested.     

Standardization of the assay for the catalytic subunit of cyclic AMP-dependent protein kinase using a synthetic peptide substrate

Optimal assay conditions for analyses of the catalytic subunit activity of the cyclic AMP-dependent protein kinase using a well-defined, commercially available synthetic peptide as the phosphate acceptor are defined. Activity of purified catalytic subunit toward the synthetic peptide Leu-Arg-Arg-Ala-Ser-Leu-Gly (PK-1; Kemptide) was 1.5- to 45-fold greater than activity toward other commonly used substrates such as histone fractions, casein, and protamine. The effects of buffer, pH, Mg2+, and protein kinase concentration on activity toward PK-1 were investigated. The optimal assay conditions determined were as follows: 20 mM Hepes or phosphate buffer, pH 7.5, 100 microM PK-1, 100 microM [gamma-32P]ATP, 3 mM MgCl2, 12 mM KCl, and 20-200 ng of catalytic subunit assayed at 30 degrees C. Since PK-1 is the only commercially available, well-defined substrate for this enzyme, adaption of the proposed standard assay conditions for the analyses of purified catalytic subunit activity will permit direct comparison of kinetic parameters and purity of enzyme preparations from multiple preparations.     

Molecular cloning and expression of the catalytic subunit of protein kinase A from Trypanosoma cruzi

The activation of protein kinase A (cyclic adenosine monophosphate-dependent protein kinase) by cyclic adenosine monophosphate is believed to play an important role in regulating the growth and differentiation of Trypanosoma cruzi. A PCR using degenerate oligonucleotide primers against conserved motifs in the VIb and VIII subdomains of the ACG family of serine/threonine protein kinases was utilised to amplify regions corresponding to the parasite homologue of the protein kinase A catalytic subunit. This putative protein kinase A fragment was used to isolate the entire gene from T. cruzi genomic libraries. The deduced 329 amino acid sequence of this gene contained all of the signature motifs of known protein kinase A catalytic subunit proteins. The recombinant protein expressed in Escherichia coli was shown to phosphorylate Kemptide, a synthetic peptide substrate of protein kinase A, in a protein kinase inhibitor (PKI)-inhibitory manner. Immunoprecipitation with polyclonal antisera raised against recombinant protein of this gene was able to pull-down PKI-inhibitory phosphotransferase activity from epimastigote lysates. Immunoblot and Northern blot analyses, in combination with enzyme activity assays, revealed that this gene was a stage-regulated enzyme in T. cruzi with higher levels and activity being present in epimastigotes compared with amastigotes or trypomastigotes. Overall these studies indicate that the cloned gene encodes an authentic protein kinase A catalytic subunit from T. cruzi and are the first demonstration of PKI-inhibitory phosphotransferase activity in an expressed protozoan protein kinase A catalytic subunit.     

Method for determining protein kinase substrate specificities by the phosphorylation of peptide libraries on beads, phosphate-specific staining, automated sorting, and sequencing

A method is described for the elucidation of the peptide substrate phosphorylation specificity of a protein kinase. Peptide libraries with two to six degenerate positions and a length of seven or nine amino acids were generated directly on Sepharose beads by solid-phase peptide synthesis according to the split-and-mix procedure. The immobilized peptides were incubated with the catalytic subunit of the cyclic AMP-dependent protein kinase (PKA) as a model enzyme resulting in the phosphorylation of the beads that contain the recognition motif of the kinase. The beads were then stained with a new phosphate-monoester-specific fluorescent dye consisting of a complex of iron(III) with fluorescein-coupled iminodiacetic acid. A flow cytometer was used to analyze the phosphorylation efficiency and the beads with the highest phosphorylation degree were isolated by the use of a fluorescence-activated cell sorter. Pool sequencing of those beads revealed the preferred kinase motif. The results are in good agreement with data from the literature. The method lends itself to the rapid elucidation of the specificity of uncharacterized protein kinases.     

A protein kinase associated with apoptosis and tumor suppression: structure, activity, and discovery of peptide substrates

Death-associated protein kinase (DAPK) has been implicated in apoptosis and tumor suppression, depending on cellular conditions, and associated with mechanisms of disease. However, DAPK has not been characterized as an enzyme due to the lack of protein or peptide substrates. Therefore, we determined the structure of DAPK catalytic domain, used a homology model of docked peptide substrate, and synthesized positional scanning substrate libraries in order to discover peptide substrates with K(m) values in the desired 10 microm range and to obtain knowledge about the preferences of DAPK for phosphorylation site sequences. Mutagenesis of DAPK catalytic domain at amino acids conserved among protein kinases or unique to DAPK provided a link between structure and activity. An enzyme assay for DAPK was developed and used to measure activity in adult brain and monitor protein purification based on the physical and chemical properties of the open reading frame of the DAPK cDNA. The results allow insight into substrate preferences and regulation of DAPK, provide a foundation for proteomic investigations and inhibitor discovery, and demonstrate the utility of the experimental approach, which can be extended potentially to kinase open reading frames identified by genome sequencing projects or functional genetics screens and lacking a known substrate.     

Synthesis, characterization and inhibitory activities of (4-N3[3,5-3H]Phe10)PKI(6-22)amide and its precursors: photoaffinity labeling peptides for the active site of cyclic AMP-dependent protein kinase

PKI(6-22)amide is a 17 residue peptide corresponding to the active portion of the heat-stable inhibitor of cAMP-dependent protein kinase. The peptide is a potent (Ki = 1.6 nM), competitive inhibitor of the enzyme. The photoreactive peptide analog (4-azidophenylalanine10)PKI(6-22)amide was synthesized in both its non-radiolabeled and tritiated forms by chemical modification of precursor peptides that were prepared by stepwise solid-phase synthesis. (4-Amino[3,5-3H]phenylalanine10)PKI(6-22)amide, the precursor for the radiolabeled arylazide peptide, was obtained by catalytic reduction of the corresponding peptide containing the 3,5-diiodo-4-aminophenylalanine residue at position 10. The purified PKI peptides were analyzed by HPLC, amino acid analysis, and u.v. spectra. In the dark, (4-azidophenylalanine10)PKI(6-22)amide inhibited the catalytic subunit of cAMP-dependent protein kinase with a Ki value of 2.8 nM. The photoreactivity of the arylazide peptide was demonstrated by time-dependent u.v. spectral changes on exposure to light. Photolysis of the catalytic subunit (4-azido[3,5-3H]phenylalanine10)PKI(6-22)amide complex resulted in specific covalent labeling of the enzyme. The data indicate that this peptide is a useful photoaffinity labeling reagent for the active site of the protein kinase.     

Physiological Phosphorylation of Protein Kinase A at Thr-197 Is by a Protein Kinase A Kinase

Phosphorylation of the catalytic subunit of cyclic AMP-dependent protein kinase, or protein kinase A, on Thr-197 is required for optimal enzyme activity, and enzyme isolated from either animal sources or bacterial expression strains is found phosphorylated at this site. Autophosphorylation of Thr-197 occurs in Escherichia coli and in vitro but is an inefficient intermolecular reaction catalyzed primarily by active, previously phosphorylated molecules. In contrast, the Thr-197 phosphorylation of newly synthesized protein kinase A in intact S49 mouse lymphoma cells is both efficient and insensitive to activators or inhibitors of intracellular protein kinase A. Using [³⁵S]methionine-labeled, nonphosphorylated, recombinant catalytic subunit as the substrate in a gel mobility shift assay, we have identified an activity in extracts of protein kinase A-deficient S49 cells that phosphorylates catalytic subunit on Thr-197. The protein kinase A kinase activity partially purified by anion-exchange and hydroxylapatite chromatography is an efficient catalyst of protein kinase A phosphorylation in terms of both a low K_m for ATP and a rapid time course. Phosphorylation of wild-type catalytic subunit by the kinase kinase activates the subunit for binding to a pseudosubstrate peptide inhibitor of protein kinase A. By both the gel shift assay and a [γ-³²P]ATP incorporation assay, the enzyme is active on wild-type catalytic subunit and on an inactive mutant with Met substituted for Lys-72 but inactive on a mutant with Ala substituted for Thr-197. Combined with the results from mutant subunits, phosphoamino acid analysis suggests that the enzyme is specific for phosphorylation of Thr-197.     

Phosphorylation and inactivation of liver glycogen synthase by liver protein kinases

A rapid method for purifying glycogen synthase a from rat liver was developed and the enzyme was tested as a substrate for nine different protein kinases, six of which were isolated from rat liver. The enzyme was phosphorylated on a 17-kDa CNBr fragment to approximately 1 phosphate/87-kDa subunit by phosphorylase b kinase from muscle or liver with a decrease in the activity ratio (-Glc-6-P/+Glc-6-P) from 0.95 to 0.6. Calmodulin-dependent glycogen synthase kinase from rabbit liver produced a similar phosphorylation pattern, but a smaller activity change. The catalytic subunit of beef heart cAMP-dependent protein kinase incorporated greater than 1 phosphate/subunit initially into a 17-kDa CNBr peptide and then into a 27-30-kDa CNBr peptide, with an activity ratio decrease to 0.5. Glycogen synthase kinases 3, 4, and 5 and casein kinase 1 were purified from rat liver. Glycogen synthase kinase 3 rapidly phosphorylated liver glycogen synthase to 1.5 phosphate/subunit with incorporation of phosphate into 3 CNBr peptides and a decrease in the activity ratio to 0.3. Glycogen synthase kinase 4 produced a pattern of phosphorylation and inactivation of liver synthase which was very similar to that caused by phosphorylase b kinase. Glycogen synthase kinase 5 incorporated 1 phosphate/subunit into a 24-kDa CNBr peptide, but did not alter the activity of the synthase. Casein kinase 1 phosphorylated and inactivated liver synthase with incorporation of phosphate into a 24-kDa CNBr peptide. This kinase and glycogen synthase kinase 4 were more active against muscle glycogen synthase. Calcium-phospholipid-dependent protein kinase from brain phosphorylated liver and muscle glycogen synthase on 17- and 27-kDa CNBr peptides, respectively. However, there was no change in the activity ratio of either enzyme. The following conclusions are drawn. 1) Liver glycogen synthase a is subject to multiple site phosphorylation. 2) Phosphorylation of some sites does not per se control activity of the enzyme under the assay conditions used. 3) Liver contains most, if not all, of the protein kinases active on glycogen synthase previously identified in skeletal muscle.     

小鼠cAMP依赖的蛋白激酶催化亚基α的重组表达研究

将小鼠ｃＡＭＰ依赖的蛋白激酶（ｃＡＰＫ）催化亚基α（ｍＣα）分别以成熟、麦芽糖结合蛋白（ＭＢＰ）融合以及Ｎ端连续六个组氨酸（Ｈｉｓ_６）融合的形式在大肠杆菌中得到了高效表达,且成熟及融合的重组ｍＣα均有明显的蛋白激酶活性,表明蛋白激酶催化核心结构具有相对的独立性。其中Ｈｉｓ_６－ｍＣα可利用金属离子（Ｎｉ￣（２＋））配体亲和层析（Ⅰ－ＭＡＣ）一步纯化,所得融合蛋白可通过Ｈｉｓ_６亲合手臂（Ｔａｇ）固相化于金属离子（Ｎｉ￣（２＋））配体亲和树脂上,为进一步利用ＰｈａｇｅＤｉｓｐｌａｙ多肽库筛选ｃＡＰＫ识别的底物序列和专一性抑制剂打下了基础。     

Activation of the particulate low Km phosphodiesterase of adipocytes by addition of cAMP-dependent protein kinase

The purified catalytic subunit (C) of cAMP-dependent protein kinase produced a 2-fold activation of the low Km phosphodiesterase in crude microsomes (P-2 pellet) of rat adipocytes. This activation was C subunit concentration-dependent, ATP-dependent, blocked by a specific peptide inhibitor, and lost if the C subunit was first heat denatured. The concentration of ATP necessary for half-maximal activation of the low Km phosphodiesterase was 4.50 +/- 1.1 microM, which was nearly the same as the known Km of C subunit for ATP (3.1 microM) using other substrates. The concentration of C subunit producing half-maximal activation of phosphodiesterase was 0.22 +/- 0.04 microM, slightly less than the measured concentration of total C subunit in adipocytes (0.45 microM). The activation of the low Km phosphodiesterase by C subunit was specific, since on an equimolar basis, myosin light chain kinase, cGMP-dependent protein kinase, or Ca2+/calmodulin-dependent protein kinase II did not activate the enzyme. The percent stimulation of phosphodiesterase by C subunit was about the same as that produced by incubation of adipocytes with a cAMP analog, and the enzyme first activated in vivo with the analog was not activated to the same extent (on a percentage basis) by in vitro treatment with C subunit. Treatment of the crude microsomes with trypsin resulted in transfer of phosphodiesterase catalytic activity from the particulate to the supernatant fraction, but the enzyme in the supernatant was minimally activated by C subunit, suggesting either loss or dislocation of the regulatory component. The C subunit-mediated activation of phosphodiesterase was preserved after either transfer of phosphodiesterase activity to the supernatant fraction by nonionic detergents or partial purification of the transferred enzyme. The present findings are consistent with the suggestion that protein kinase regulates the concentration of cAMP through phosphodiesterase activation and provide direct evidence that the mechanism of activation involves phosphorylation.     

Fluorescence analysis of denaturation and reassembly of dansylated creatine kinase

Upon exposure of rabbit muscle creatine kinase (ATP: creatine N-phosphotransferase, EC 2.7.3.2) that has been dansylated at the two reactive lysines to 8 M urea, the maximum emission of the extrinsic fluorophore shifts 4 nm towards the blue, this being accompanied by a small decrease in intensity. The fluorescence emission and excitation spectra of the reassembled and native proteins are the same. Denaturation is accompanied by a rapid decrease in fluorescence which is complete in 10 s. This suggests that denaturation is accompanied by an early disorganization at the catalytic center, where the reactive lysines are located. Reassembly is associated with a rapid increase in dansyl fluorescence followed by a slower decrease that is complete in 6 min. Since reactivation is not complete until 20 min, minor additional structural changes are needed for the reacquisition of catalytic activity. The intrinsic protein fluorescence (eight tryptophans per dimer) of dansylated creatine kinase is approximately 60% less than that of the unlabelled enzyme, which may be attributed to resonance energy transfer, indicating that the reactive lysine is located near one or more of the tryptophans. A more limited quenching of intrinsic fluorescence is observed when dansylated creatine kinase is exposed to 8 M urea. Reassembly, monitored by a decrease in intrinsic fluorescence, reveals that the dansylated protein achieves its final fluorescence after 18 min of renaturation compared with 30 min for unlabelled enzyme. The powerful quenching by the dansyl group may limit the ability to monitor changes in the tryptophan environment. Kinetics of fluorescence polarization changes during denaturation are consistent with a mechanism involving rapid dissociation, followed by a subunit disorganization and possible aggregation. Reassembly would appear to involve first a refolding of the disorganized monomers and subsequent association. These results correspond to our previous observations that subunit renaturation precedes dimerization.     

Phosphorylation of mammalian myosin light chain kinases by the catalytic subunit of cyclic AMP-dependent protein kinase and by cyclic GMP-dependent protein kinase

The phosphorylation of the calmodulin-dependent enzyme myosin light chain kinase, purified from bovine tracheal smooth muscle and human blood platelets, by the catalytic subunit of cAMP-dependent protein kinase and by cGMP-dependent protein kinase was investigated. When myosin light chain kinase which has calmodulin bound is phosphorylated by the catalytic subunit of cAMP-dependent protein kinase, 1 mol of phosphate is incorporated per mol of tracheal myosin light chain kinase or platelet myosin light chain kinase, with no effect on the catalytic activity. Phosphorylation when calmodulin is not bound results in the incorporation of 2 mol of phosphate and significantly decreases the activity. The decrease in myosin light chain kinase activity is due to a 5 to 7-fold increase in the amount of calmodulin required for half-maximal activation of both tracheal and platelet myosin light chain kinase. In contrast to the results with the catalytic subunit of cAMP-dependent protein kinase, cGMP-dependent protein kinase cannot phosphorylate tracheal myosin light chain kinase in the presence of bound calmodulin. When calmodulin is not bound to tracheal myosin light chain kinase, cGMP-dependent protein kinase phosphorylates only one site, and this phosphorylation has no effect on myosin light chain kinase activity. On the other hand, cGMP-dependent protein kinase incorporates phosphate into two sites in platelet myosin light chain kinase when calmodulin is not bound. The sites phosphorylated by the two cyclic nucleotide-dependent protein kinases were compared by two-dimensional peptide mapping following extensive tryptic digestion of the phosphorylated myosin light chain kinases. With respect to the tracheal myosin light chain kinase, the single site phosphorylated by cGMP-dependent protein kinase when calmodulin is not bound appears to be the same site phosphorylated in the tracheal enzyme by the catalytic subunit of cAMP-dependent protein kinase when calmodulin is bound. With respect to the platelet myosin light chain kinase, the additional site that was phosphorylated by cGMP-dependent protein kinase when calmodulin was not bound was different from that phosphorylated by the catalytic subunit of cAMP-dependent protein kinase.     

Near- and far-ultraviolet circular dichroism of the catalytic subunit of adenosine cyclic 5'-monophosphate dependent protein kinase

The circular dichroism spectrum of the catalytic subunit of cAMP-dependent protein kinase was measured in the far-UV (190-240 nm) and near-UV (250-300 nm) region. Data from the far-UV spectra were processed with the CONTIN program for estimation of globular protein secondary structure [ Provencher , S. W. (1982) CONTIN (Version 2) User's Manual, European Molecular Biology Laboratory, Heidelberg, West Germany]. The composition of the protein determined by this method was 49 +/- 2% alpha-helix, 20 +/- 4% beta-sheet, and 31 +/- 3% remainder. This composition changes when the protein is allowed to bind Kemptide , a synthetic peptide substrate, with more than half of the disordered portion of the protein taking the form of beta-sheet. A certain portion of the alpha-helical structure also appears to move into a beta-sheet form. The near-UV CD spectrum of catalytic subunit shows changes in aromatic amino acid dichroism associated with substrate binding. These changes can be ascribed with a fair degree of certainty to alterations in the orientation of a tyrosine residue at the surface of the protein. These findings are discussed in terms of previous work on induced dichroism in this enzyme with regard to control mechanisms operating at the active site.     

Identification of amino acid residues involved in substrate recognition by the catalytic subunit of bovine cyclic AMP dependent protein kinase: peptide-based affinity labels

Two peptide-based affinity inactivators Ac-Leu-(BrAc)Orn-Arg-Ala-Ser-Leu-Gly (4) and Ac-Leu-Arg-(BrAc)Orn-Ala-Ser-Leu-Gly (5) were prepared as probes for the study of the nature of the active-site residues in the catalytic subunit of cyclic AMP dependent protein kinase. Under conditions of inhibitor in excess, both peptides inactivated the catalytic subunit by an apparent biphasic process. A fast phase, which inactivated the protein by approximately 40%, was followed by a slow phase that accounted for the loss of the remaining enzyme activity. Protection experiments with the kinase substrates showed that the slow phase of inactivation was active site directed, while the fast phase was not. Studies with radioactively labeled peptides 4 and 5 indicated incorporation of two peptide residues per molecule of the catalytic subunit upon complete inactivation. This observation is consistent with the occurrence of one alkylation event in each phase of the inactivation. The protein was proteolyzed subsequent to its modification with radioactive peptides. High-performance liquid chromatography afforded two radioactive peptide fragments in each case, which were sequenced by Edman degradation. Peptide 4 alkylated Thr-197 and Glu-346, while peptide 5 modified Cys-199 and also Glu-346. Data are presented to support the conclusion that Thr-197 and Cys-199 are located at or near the active site.     

Structural basis for peptide binding in protein kinase A. Role of glutamic acid 203 and tyrosine 204 in the peptide-positioning loop

For optimal activity the catalytic subunit of cAMP-dependent protein kinase requires a phosphate on Thr-197. This phosphate anchors the activation loop in the proper conformation and contributes to catalytic efficiency by enhancing the phosphoryl transfer rate and increasing the affinity for ATP (1). The crystal structure of the catalytic subunit bound to ATP, and the inhibitor peptide, IP20, highlights the contacts made by the Thr-197 phosphate as well as the role adjacent residues play in contacting the substrate peptide. Glu-203 and Tyr-204 interact with arginines in the consensus sequence of PKA substrates at the P-6 and P-2 positions, respectively. To assess the contribution that each residue makes to peptide recognition, the kinetic properties of three mutant proteins (E203A, Y204A, and Y204F) were monitored using multiple peptide substrates. The canonical peptide substrate, Kemptide, as well as a longer 9-residue peptide and corresponding peptides with alanine substitutions at the P-6 and P-2 positions were used. While the effect of Glu-203 is more localized to the P-6 site, Tyr-204 contributes to global peptide recognition. An aromatic hydrophobic residue is essential for optimal peptide recognition and is conserved throughout the protein kinase family.