Synthetic peptides including acidic clusters as substrates and inhibitors of rat liver casein kinase TS (type-2)

The hexapeptides AcSer-Glu-Glu-Glu-Val-Glu and Ser-Glu-Glu-Glu-Glu-Glu, reminiscent of the sites phosphorylated by type-2 casein kinase TS in troponin T and glycogen synthase, respectively, have been synthesized and tested as phosphorylatable substrates for casein kinase TS as well as for other protein kinases. Both peptides are readily phosphorylated by casein kinase TS but not, to any detectable extent, by either cAMP-dependent protein kinase or phosphorylase kinase. Phosphorylation by type-1 casein kinase S was almost negligible. On the other hand the hexapeptide Ser-Glu-Glu-Glu-Ala-Ala is phosphorylated much more slowly and the hexapeptide Ser-Glu-Glu-Ala-Ala-Ala is almost unaffected by casein kinase TS. While the Vmax values of casein kinase TS with the acidic hexapeptides are comparable to those obtained with the corresponding protein substrates, the apparent Km values for the peptides are about two orders of magnitude higher than those for the protein substrates. The heptapeptide Arg-Ser-Glu-Glu-Glu-Val-Glu is a very poor substrate of casein kinase TS in comparison with the corresponding hexapeptide lacking the N-terminal Arg; it is, however, a competitive inhibitor toward the protein substrates, exhibiting a Ki similar to those of Ser-Glu-Glu-Glu-Glu-Glu and (Glu)5 which, in turn, are one order of magnitude higher than that of (Glu)10. It is concluded that the minimum structural requirement of type-2 casein kinases consists of a phosphorylatable residue followed by an acidic cluster, whose length is critical for the binding to the enzyme. Additional residues on the N-terminal side are not required, but their nature can influence the transphosphorylation reaction considerably.     

A type-1 casein kinase from yeast phosphorylates both serine and threonine residues of casein. Identification of the phosphorylation sites

A protein kinase (casein kinase 1A) active on casein and phosvitin but not on histones has been purified to near homogeneity from yeast cytosol and meets most criteria for being considered a type-1 casein kinase: it is a monomeric enzyme exhibiting an Mr of about 27 kDa by sucrose gradient centrifugation: it is not affected by inhibitors of type-2 casein kinases, such as heparin and polyglutamate, and shows negligible affinity for GTP. It also readily phosphorylates the residue Ser-22 of beta-casein located within the sequence -Ser(P)-Ser(P)-Ser(P)-Glu-Glu-Ser22-Ile-Thr-Arg- which is typically affected by casein kinases of the first class. On the other hand, casein kinase 1A displays the unusual property of phosphorylating threonine residue(s) in both whole casein and alpha s1-casein. The threonine residue phosphorylated in alpha s1-casein and accounting for most of the 32P incorporated into this protein by casein kinase 1A has been identified as Thr-49, which occurs in the sequence -Ser(P)-Glu-Ser(P)-Thr(P*)49-Glu-Asp-Gln-, whose two Ser(P) residues are already phosphorylated in the native protein. It is concluded that some type-1 casein kinases can also phosphorylate threonine residues provided they fulfil definite structural requirements, probably an acidic cluster near their N-terminal side.     

Role of acidic residues as substrate determinants for casein kinase I

Sites phosphorylated by casein kinase I have been characterized by the presence of acidic amino acids NH2-terminal to the modified residue. Recently, phosphoserine was shown to be a particularly effective determinant for casein kinase I action when present in the motif -S(P)-X-X-S- (Flotow, H., Graves, P. R., Wang, A., Fiol, C. J., Roeske, R. W., and Roach, P. J. (1990) J. Biol. Chem. 265, 14264-14269). Nonetheless, nonphosphorylated substrates for casein kinase I are well documented. In this study, we examined the efficacy of Asp and Glu residues as determinants of casein kinase I action using synthetic peptide substrates. Peptides with runs of Asp residues in the motif Dn-X-X-S- were substrates for casein kinase I. Peptides with n = 3 or 4 were the most effective substrates, much better than n = 2. The peptide with n = 1, a single Asp residue, was a very poor substrate. A block of 4 Glu residues was a little less effective as a substrate determinant than 4 Asp residues in an otherwise identical peptide. The most effective substrate, with the motif -D-D-D-D-X-X-S-, was specific for casein kinase I and was not detectably phosphorylated by cyclic AMP-dependent protein kinase, casein kinase II, glycogen synthase kinase 3, or phosphorylase kinase and thus will be useful for the specific assay of casein kinase I. This peptide was nonetheless significantly worse as a substrate than peptides in which casein kinase I action was determined by phosphoserine in the -3 position. Still, the fact that Asp or Glu residues can specify a casein kinase I substrate suggests that acidic character has a role in substrate selection by this protein kinase.     

Detection of type-2 casein kinase and its endogenous substrates in the components of the microsomal fraction of rat liver

Rat liver type-2 casein kinase-TS (Ck-TS) is unevenly distributed among the different components of the rat liver post-mitochondrial particulate fraction: while it accounts for the whole casein kinase activity of protein-glycogen particles, it is absent in the microsomal membranes (exhibiting exclusively casein kinase activity of type-1) and coexists with type-1 casein kinase in ribosomes. At least seven proteins whose phosphorylation is promoted by Ck-TS have been detected in these fractions. The only important target of Ck-TS in protein-glycogen particles is a rather heterogeneous protein of Mr around 85000 which has been identified as glycogen synthase. Two polypeptides of Mr about 16000, possibly identifiable with acidic proteins P1 and P2, and an unidentified protein of Mr about 35000 are the main ribosomal substrates of Ck-TS. Three protein bands of Mr 52000, 79000 and 91000 are also very efficiently phosphorylated whenever the microsomal membranes, devoid of intrinsic casein kinase-2, are incubated with cytosolic Ck-TS. These membrane-bound radiolabeled proteins require deoxycholate for their solubilization: they are very acidic, according to their high affinity for DEAE-cellulose, and give rise to partially superimposable [32P]peptide maps, suggesting extensive homologies among them. They also exhibit a low affinity Ca2+ binding activity comparable to that of calsequestrin.     

Substrate specificity determinants for casein kinase II as deduced from studies with synthetic peptides

The specificity of casein kinase II has been further defined by analyzing the kinetics of phosphorylation reactions using a number of different synthetic peptides as substrates. The best peptide substrates are those in which multiple acidic amino acids are present on both sides of the phosphorylatable serine or threonine. Acidic residues on the NH2-terminal side of the serine (threonine) greatly enhance the kinetic constants but are not absolutely required. Acidic residues on the COOH-terminal side of the serine (threonine) are absolutely required. One position for which the occupation of an acidic residue is especially critical is the position located 3 residues to the COOH terminus of the phosphate acceptor site, although the presence of an acidic amino acid in the positions that are 4 or 5 residues removed may also provide an appropriate structure that will serve as a substrate for the kinase. Aspartate serves as a better amino acid determinant than glutamate. A relatively short sequence of amino acids surrounding the phosphate acceptor site appears to serve as the basis for the specificity of casein kinase II. The peptides in this study were also assayed with casein kinase I and the casein kinase from the mammary gland so that the specificities of these kinases could be compared to that of casein kinase II.     

Purification and characterization of two casein kinases from ejaculated bovine spermatozoa.

Two protein kinases active on casein and phosvitin were partially purified from the soluble fraction of ejaculated bovine spermatozoa. They were operationally termed casein kinase A and B based on the order of their elution from a phosphocellulose column. CK-A showed an approximate molecular mass of 38 kDa, and it phosphorylated serine residues of casein and phosvitin utilizing ATP as a phosphate donor (Km 19 microM). Enzyme activity was maximal in the presence of 10 mM MgCl2, whereas it decreased in the presence of spermine, polylysine, quercetin, and NaCl (20-250 mM). CK-B seemed to have a monomeric structure of about 41 kDa; it underwent autophosphorylation and cross-reacted with polyclonal antibodies raised against recombinant alpha, but not beta, subunit of human type 2 casein kinase. It phosphorylated both serine and threonine residues of casein and phosvitin, utilizing ATP (Km 12 microM) but not GTP as a phosphate donor. Threonine was more affected in the phosphorylated phosvitin than in the partially dephosphorylated substrate. CK-B was active toward the synthetic peptide Ser-(Glu)5 and calmodulin (in the latter case, in the presence of polylysine), and it was activated by spermine, polylysine, MgCl2 (30 mM), and NaCl (20-400 mM). The activity of the enzymes was not affected by cAMP, or the heat-stable inhibitor of the cAMP-dependent protein kinase, or calcium.     

Location of the phosphorylation site for casein kinase-2 within the amino acid sequence of ornithine decarboxylase

The sizes of the radiolabeled fragments obtained by CNBr and DMSO/HBr digestion of 32P-labeled ornithine decarboxylase phosphorylated by rat liver casein kinase TS (type-2) are consistent with the location of the phosphorylation site within the sequence(303-309) Ser-Asp-Asp-Glu-Asp-Glu-Ser. Parallel experiments with synthetic peptides rule out the suitability of Ser-309, as well as of other serines of ornithine decarboxylase having just two or three acidic residues close to their C terminal side. Ser-303 appears, therefore, to be the main if not the only target for casein kinase-2.     

Phosphorylation of nucleolin by a nucleolar type NII protein kinase

Nucleolin [C23 or 100 kilodaltons (kDa)] is the major nucleolar phosphorylated protein in exponentially growing Chinese hamster ovary cells. A nucleolar cyclic nucleotide independent protein kinase copurified with nucleolin in a complex which could be dissociated by hydroxyapatite chromatography. The kinase was stimulated by spermine and inhibited by heparin and presented most of the properties of nuclear casein kinase NII. Kinetic analyses showed the apparent Km value for nucleolin (7 X 10(-4) mg/mL) to be lower than those for other casein kinase II substrates such as nuclear protein HMG 14 (0.15 mg/mL), topoisomerase I (0.025 mg/mL), or topoisomerase II (0.04 mg/mL). Similarly, Vmax values were higher for nucleolin than for other substrates. Nucleolin thus appears to be a natural preferential substrate of nucleolar casein kinase NII. The kinase phosphorylated nucleolin in vitro at serine residues in a 29-kDa CNBr fragment located near the amino terminus of the molecule. The enzyme labeled typical casein kinase II sites. These sites were found predominantly in two highly acidic tryptic fragments designated A (residues 21-49) and C (residues 180-221) which contained serines having at least two acidic residues on their carboxyl-terminal sides. These results demonstrate the existence in the nucleolus of a type of NII protein kinase that uses a protein involved in ribosome assembly as preferential substrate.     

The use of soybean trypsin inhibitors as phosphorylatable substrates for a rat liver protein kinase.

Phosphorylation by a cAMP-independent rat liver protein kinase of protein substrates containing the structural feature required by mammary gland casein kinase (-Ser-X-Glu/Asp) has been demonstrated. In particular, the Bowman-Birk Soybean trypsin inhibitor, which is characterized, like other legume protease inhibitors, by clusters of acidic residues near the C-terminal side of seryl residue(s), proved to be a good model substrate for the protein kinase. Its phosphorylation, involving the Ser 65 residue, is apparently hindered by the binding of trypsin, while it is stimulated by unfolding induced by reduction and subsequent carboxy-methylation.     

Protein kinases phosphorylating acidic ribosomal proteins from yeast cells

Phosphorylation of ribosomal acidic proteins ofSaccharomyces cerevisiae is an important mechanism regulating a number of active ribosomes. The key role in the regulatory mechanism is played by specific phosphoprotein kinases and phosphoprotein phosphatases. Three different cAMP-independent protein kinases phosphorylating acidic ribosomal proteins have been identified and characterized. The protein kinase 60S (PK60S), RAP kinase, and casein kinase type 2 (CK2). All three protein kinases phosphorylate serine residues which are localized in the C-terminal end of phosphoproteins. Synthetic peptides were used to determinate the amino acid sequence of phosphoacceptor site for PK60S. Peptide AAEESDDD derived from phosphoproteins YP1β/β′ and YP2α turned out to be the best substrate for PK60S. A number of halogenated benzimidazoles and 2-azabenzimidazoles were tested as inhibitors of the three protein kinases. 4,5,6,7-Tetrabromo-2-azabenzimidazole inhibits phosphorylation only of these polypeptides phosphorylated by protein kinase 60S, namely YP1β/β′ and YP2α, but not the other, YP1α and YP2β phosphorylated by protein kinases RAP and CK2. RAP kinase has been found in an active form in the soluble fraction ofS. cerevisiae. The enzyme uses ATP as a phosphate donor and is less sensitive to heparin than casein kinase 2. RAP kinase monophosphorylates the four acidic proteins. The ribosome-bound proteins are a better substrate for the enzyme. Multifunctional CK2 kinase phosphorylate all four acidic proteins. The kinase phosphorylates preferentially serine or threonine residues surrounded by cluster of acidic residues. The enzyme activity is stimulatedin vitro by the presence of polylysine and inhibited by heparin. Presented at theSymposium on Regulation of Translation of Genetic Information by Protein Phosphorylation, 21 st Congress of the Czechoslovak Society for Microbiology, Hradec Králové (Czech Republic), September 6–10, 1998.     

Phosphate groups as substrate determinants for casein kinase I action

Phosphorylation of rabbit muscle glycogen synthase by cyclic AMP-dependent protein kinase has been shown to enhance subsequent phosphorylation by casein kinase I (Flotow, H., and Roach, P. J. (1989) J. Biol. Chem. 264, 9126-9128). In the present study, synthetic peptides based on the sequences of the four phosphorylated regions in muscle glycogen synthase were used to probe the role of substrate phosphorylation in casein kinase I action. With all four peptides, prior phosphorylation significantly stimulated phosphorylation by casein kinase I. A series of peptides was synthesized based on the NH2-terminal glycogen synthase sequence PLSRTLS7VSS10LPGL, in which phosphorylation at Ser7 is required for modification of Ser10 by casein kinase I. The spacing between the P-Ser and the acceptor Ser was varied to have 1, 2, or 3 intervening residues. The peptide with a 2-residue spacing (-S(P)-X-X-S-) was by far the best casein kinase I substrate. When the P-Ser residue at Ser7 was replaced with P-Thr, the resulting peptide was still a casein kinase I substrate. However, substitution of Asp or Glu residues at Ser7 led to peptides that were not phosphorylated by casein kinase I. Phosphorylation of one of the other peptides showed that Thr could also be the phosphate acceptor. From these results, we propose that there are substrates for casein kinase I for which prior phosphorylation is a critical determinant of protein kinase action. In these instances, an important recognition motif for casein kinase I appears to be -S(P)/T(P)-Xn-S/T- with n = 2 much more effective than n = 1 or n = 3. Thus, casein kinase I may be involved in hierarchal substrate phosphorylation schemes in which its activity is controlled by the phosphorylation state of its substrates.     

Identification and purification of a cytosolic phosphotyrosyl protein phosphatase from bovine spleen

A protein tyrosine kinase with an apparent Mr of 60,000 was highly purified from bovine spleen and used to phosphorylate poly(Glu, Tyr) (4:1) on tyrosine residues for the study of phosphotyrosyl protein phosphatases from this tissue. About 70% of the phosphotyrosyl protein phosphatase activity in extracts of bovine spleen was adsorbed on DEAE-Sepharose. Chromatography of the eluted phosphotyrosyl protein phosphatases on phosphocellulose indicated the presence of at least two species, one that did not bind to the phosphocellulose and a second species that did bind and was eluted at about 0.5 M NaCl. The phosphatase that did not bind to phosphocellulose was further purified by successive chromatography on poly(L-lysine)-Sepharose, L-tyrosine-agarose, poly(Glu,Tyr)-Sepharose, and Sephacryl S-200. The enzyme had an apparent Mr of 50,000 as estimated by gel filtration and 52,000 as estimated by NaDodSO4- polyacrylamide gel electrophoresis. The phosphatase exhibited a pH optimum of 6.5-7.0, was inhibited by Zn2+ and vanadate ions, and was stimulated by EDTA. Sodium fluoride and sodium pyrophosphate, inhibitors of phosphoseryl protein phosphatases, had no effect on the enzyme. Protein inhibitors of type 1 phosphoseryl/threonyl phosphatase were also ineffective.     

Deciphering the Arginine-binding preferences at the substrate-binding groove of Ser/Thr kinases by computational surface mapping

Protein kinases are key signaling enzymes that catalyze the transfer of γ-phosphate from an ATP molecule to a phospho-accepting residue in the substrate. Unraveling the molecular features that govern the preference of kinases for particular residues flanking the phosphoacceptor is important for understanding kinase specificities toward their substrates and for designing substrate-like peptidic inhibitors. We applied ANCHORSmap, a new fragment-based computational approach for mapping amino acid side chains on protein surfaces, to predict and characterize the preference of kinases toward Arginine binding. We focus on positions P-2 and P-5, commonly occupied by Arginine (Arg) in substrates of basophilic Ser/Thr kinases. The method accurately identified all the P-2/P-5 Arg binding sites previously determined by X-ray crystallography and produced Arg preferences that corresponded to those experimentally found by peptide arrays. The predicted Arg-binding positions and their associated pockets were analyzed in terms of shape, physicochemical properties, amino acid composition, and in-silico mutagenesis, providing structural rationalization for previously unexplained trends in kinase preferences toward Arg moieties. This methodology sheds light on several kinases that were described in the literature as having non-trivial preferences for Arg, and provides some surprising departures from the prevailing views regarding residues that determine kinase specificity toward Arg. In particular, we found that the preference for a P-5 Arg is not necessarily governed by the 170/230 acidic pair, as was previously assumed, but by several different pairs of acidic residues, selected from positions 133, 169, and 230 (PKA numbering). The acidic residue at position 230 serves as a pivotal element in recognizing Arg from both the P-2 and P-5 positions.     

Phosphorylation of DARPP-32, a dopamine- and cAMP-regulated phosphoprotein, by casein kinase II

DARPP-32 (dopamine- and cAMP-regulated phosphorprotein, Mr = 32,000 as determined by sodium dodecyl sulfate-polyacrylamide gel electrophoresis) is an inhibitor of protein phosphatase-1 and is enriched in dopaminoceptive neurons possessing the D1 dopamine receptor. Purified bovine DARPP-32 was phosphorylated in vitro by casein kinase II to a stoichiometry greater than 2 mol of phosphate/mol of protein whereas two structurally and functionally related proteins, protein phosphatase inhibitor-1 and G-substrate, were poor substrates for this enzyme. Sequencing of chymotryptic and thermolytic phosphopeptides from bovine DARPP-32 phosphorylated by casein kinase II suggested that the main phosphorylated residues were Ser45 and Ser102. In the case of rat DARPP-32, the identification of these phosphorylation sites was confirmed by manual Edman degradation. The phosphorylated residues are located NH2-terminal to acidic amino acid residues, a characteristic of casein kinase II phosphorylation sites. Casein kinase II phosphorylated DARPP-32 with an apparent Km value of 3.4 microM and a kcat value of 0.32 s-1. The kcat value for phosphorylation of Ser102 was 5-6 times greater than that for Ser45. Studies employing synthetic peptides encompassing each phosphorylation site confirmed this difference between the kcat values for phosphorylation of the two sites. In slices of rat caudate-putamen prelabeled with [32P]phosphate, DARPP-32 was phosphorylated on seryl residues under basal conditions. Comparison of thermolytic phosphopeptide maps and determination of the phosphorylated residue by manual Edman degradation identified the main phosphorylation site in intact cells as Ser102. In vitro, DARPP-32 phosphorylated by casein kinase II was dephosphorylated by protein phosphatases-1 and -2A. Phosphorylation by casein kinase II did not affect the potency of DARPP-32 as an inhibitor of protein phosphatase-1, which depended only on phosphorylation of Thr34 by cAMP-dependent protein kinase. However, phosphorylation of DARPP-32 by casein kinase II facilitated phosphorylation of Thr34 by cAMP-dependent protein kinase with a 2.2-fold increase in the Vmax and a 1.4-fold increase in the apparent Km. Phosphorylation of DARPP-32 by casein kinase II in intact cells may therefore modulate its phosphorylation in response to increased levels of cAMP.     

Substrate-specificity determinants for a membrane-bound casein kinase of lactating mammary gland. A study with synthetic peptides

A tissue-specific casein kinase, purified from the Golgi-enriched-membrane fraction of guinea-pig lactating mammary gland (GEF-CK), readily phosphorylates the synthetic peptide Ser-Glu5, a good substrate of casein kinase-2, and several derivatives varying for the number and position of acidic residues on the C-terminal side of serine, except those lacking an acidic side chain at position +2. The least acidic peptide, still significantly affected by GEF-CK, is Ser-Ala-Glu-Ala3 which is not a substrate for CK-2. Conversely, the peptides Ser-Ala2-Glu-Ala2, Ser-Ala2-Glu3, Ser-Ala2-Glu5 and Ser-Glu-Ala-Glu3, all of which are more or less readily phosphorylated by CK-2, are not appreciably affected by GEF-CK. On the other hand the presence of additional glutamyl residues, besides the one in the second position, improves the affinity of the peptide substrate for GEF-CK, as indicated by the Km values of Ser-Glu5, Ser-Glu2-Ala3 and Ser-Ala-Glu-Ala3 which are 80, 950 and 3950 microM respectively. It is concluded that although both CK-2 and GEF-CK require, for optimal activity, rather extended acidic clusters on the C-terminal side of the target serine, the most critical residue in the case of GEF-CK is not the one at position +3, which is required for CK-2 catalyzed phosphorylation [Marin, O. et al. (1986) Eur. J. Biochem. 160, 239-244], but the one lying at position +2. Additional differences, concerning the site specificities of these enzymes, have been outlined using the threonyl derivative of Ser-Glu5 and the peptide Arg-Ser-Glu3-Val-Glu. The former is still phosphorylated by CK-2 but not to any appreciable extent by GEF-CK, which apparently is strictly specific for seryl residues. On the contrary, the presence of an N-terminal basic residue, which greatly reduces phosphorylation by CK-2, is tolerated rather well by GEF-CK. On the other hand a C-terminal basic residue, interrupting the acidic cluster, compromises phosphorylation by GEF-CK, as indicated by the extremely high Km value of Ser-Glu3-Lys-Glu vs Ser-Glu3-Val-Glu (13,000 and 170 microM, respectively).     

Phosphorylation of rat heart ornithine decarboxylase by type-2 casein kinase

Highly purified preparations of rat heart ornithine decarboxylase are readily phosphorylated by rat liver type-2 casein kinase-TS at the same 54 KDa protein band which is also radiolabeled by 3H-DFMO. The reaction, which is stimulated by polylysine leads to the incorporation of up to 0.8 mol P/mol ornithine decarboxylase at seryl residue(s) included in a single 8.6 KDa CNBr fragment. Partially purified preparations of ornithine decarboxylase contain a type-2 casein kinase which promotes the phosphorylation of ornithine decarboxylase at the same CNBr fragment affected by rat liver casein kinase-TS.     

Phosphorylation of the modulator protein of the ATP, Mg-dependent protein phosphatase by casein kinase TS. Reversal by PCS phosphatases and control by distinct phosphorylation site(s)

The phosphorylation by casein kinase TS (II) of the modulator protein of the ATP, Mg-dependent phosphatase increases after preincubation with the PCSH1 phosphatase or with the catalytic subunit of the ATP, Mg-dependent phosphatase. Dephosphorylation by the two phosphatases combined leads to the incorporation of 2 mol phosphate per mol modulator (at Ser residues). Occupancy of the ATP, Mg-dependent phosphatase phosphorylation site(s) is a negative determinant in the phosphorylation of the modulator by kinase TS. Among the PCS phosphatases PCSH1 shows the highest activity toward the 32P-Ser residues labeled by kinase TS in untreated or previously dephosphorylated modulator, while the ATP, Mg-dependent phosphatase is totally ineffective. Protamine stimulates all phosphatase activities, so that the catalytic subunit of the ATP, Mg-dependent phosphatase becomes almost as effective as the PCSC phosphatase in dephosphorylating the kinase TS sites.     

Distinct structural requirements of Ca2+/phospholipid-dependent protein kinase (protein kinase C) and cAMP-dependent protein kinase as evidenced by synthetic peptide substrates

Protein kinase C, purified to near homogeneity from the brain, has been tested toward a variety of synthetic peptide substrates including different phosphorylatable residues. While it proved totally inactive toward the tyrosyl peptide Asp-Ala-Glu-Tyr-Ala-Ala-Arg-Arg-Arg-Gly, as well as toward several more or less acidic seryl peptides, it phosphorylates with a Ca2+/phospholipid-dependent mechanism, at seryl and/or threonyl residues, many basic peptides, some of which are also good substrates for cAMP-dependent protein kinase (A-kinase). Among the peptides tested, however, the best substrate for protein kinase C, with kinetic constants comparable to those of histones, is the nonapeptide Gly-Ser-Arg6-Tyr, which is not a substrate for A-kinase. Moreover, although the peptide Pro-Arg5-Ser-Ser-Arg-Pro-Val-Arg is a good substrate for both kinases, its derivative with ornitines replacing arginines is phosphorylated only by protein kinase C. Some typical substrates of A-kinase on the other hand, like the peptides Phe-Arg2-Leu-Ser-Ile-Ser-Thr-Glu-Ser and Arg2-Ala-Ser-Val-Ala, are phosphorylated by protein kinase C rather slowly and with unfavourable kinetic constants. It is concluded that, while both protein kinase C and A-kinase need basic groups close to the phosphorylatable residues, their primary structure determinants are quite distinct.     

Discovery of cyclin-dependent kinase inhibitor, CR229, using structurebased drug screening

To generate new scaffold candidates as highly selective and potent cyclin-dependent kinase (CDK) inhibitors, structure-based drug screening was performed utilizing 3D pharmacophore conformations of known potent inhibitors. As a result, CR229 (6-bromo-2,3,4,9-tetrahydro-carbolin-1-one) was generated as the hit-compound. A computational docking study using the X-ray crystallographic structure of CDK2 in complex with CR229 was evaluated. This predicted binding mode study of CR229 with CDK2 demonstrated that CR229 interacted effectively with the Leu83 and Glu81 residues in the ATP-binding pocket of CDK2 for the possible hydrogen bond formation. Furthermore, biochemical studies on inhibitory effects of CR229 on various kinases in the human cervical cancer HeLa cells demonstrated that CR229 was a potent inhibitor of CDK2 (IC50: 3 microM), CDK1 (IC50: 4.9 microM), and CDK4 (IC50: 3 microM), yet had much less inhibitory effect (IC50: >20 microM) on other kinases, such as casein kinase 2-1 (CK2- alpha1), protein kinase A (PKA), and protein kinase C (PKC). Accordingly, these data demonstrate that CR229 is a potent CDK inhibitor with anticancer efficacy.     

Apparent activation of the MgATP-dependent protein phosphatase by pp60v-src. Identification of an activity like that of glycogen synthase kinase 3 in immunoaffinity purified pp60v-src preparations

Immunoaffinity purified pp60v-src was found to activate the MgATP-dependent protein phosphatase in the presence of MgATP. Although preliminary evidence suggested that phosphorylation of the inhibitor-2 subunit on tyrosine residues was responsible for the activation, preincubation of the pp60v-src preparation at 41 degrees C resulted in a rapid loss of its protein kinase activities towards both casein and inhibitor-2 while its ability to activate the protein phosphatase complex was relatively insensitive to this treatment. This result demonstrated that pp60v-src was not responsible for activation of the MgATP-dependent protein phosphatase. A protein kinase activity which phosphorylated glycogen synthase on serine residues was detected in the pp60v-src preparation. The protein kinase was active in the presence of inhibitors of phosphorylase kinase, glycogen synthase kinase 5/casein kinase II, and cAMP-dependent protein kinase. It is, therefore, likely that activation of the MgATP-dependent protein phosphatase resulted from the presence of a glycogen synthase kinase 3 like activity in the pp60v-src preparation. Our results illustrate the importance of applying multiple criteria to link the phosphorylation of a protein with an observed change in its activity.