Cyclic nucleotide-independent phosphorylation of vitellin by casein kinase II purified from Rhodnius prolixus oocytes

In this study we show that Vitellin (VT) phosphorylation in chorionated oocytes of Rhodnius prolixus is completely inhibited by heparin (10 microg/ml), a classical casein kinase II (CK II) inhibitor. VT phosphorylation is not affected by modulators of cyclic nucleotide-dependent protein kinases such as c-AMP (10 microM), H-8 (1 microM) and H-89 (0.1 microM). We have obtained a 3000-fold VT-free enriched preparation of CK II. Autophosphorylation of this enzyme preparation in the presence of (32)P-ATP demonstrated that it lacks any endogenous substrates. Rhodnius CK II is strongly inhibited by heparin (Ki = 9 nM) and uses ATP (Km = 36 microM) or GTP (Km = 86 microM) as phosphate donors. Incubation of VT with purified Rhodnius CK II and (32)P-ATP led to the incorporation of 2 mols of phosphate/mol VT. However, the total number of phosphorylation sites available can be altered by previous incubation of VT with alkaline phosphatase. These data show that an insect yolk protein contain phosphorylation sites for a cyclic nucleotide-independent protein kinase such as CK II.     

Protein phosphorylation in Rhodnius prolixus oocytes: identification of a type II casein kinase

A protein kinase activity in chorionated oocytes of Rhodnius prolixus phosphorylates in vitro vitellin (VT), the major yolk protein. Phosphatase inhibitors including NaF, sodium vanadate, beta-glycerophosphate and okadaic acid did not alter the protein phosphorylation profile to a visible extent. Among the exogenous protein substrates tested, casein was readily phosphorylated, but histones were not. Several different protein kinase activators, including cAMP, Ca2+ plus calmodulin, Ca2+ plus diolein and phosphatidylserine, were added to the reaction media but spermidine was the only effective one, inducing a 2-fold increase in the phosphorylation of VT. A strong inhibition was obtained with nanomolar levels of heparin. The enzyme could also accept GTP as the phosphate donor instead of ATP. These properties identify the major protein kinase activity as a type II casein kinase (CK II). The pH dependence and the effects of mono- and divalent cations on VT phosphorylation were also studied. Gel filtration revealed only one peak of protein kinase activity, with a molecular mass of 170 K, similar to values previously reported in the literature for CK IIs from other organisms.     

Identification of myosin II kinase from sea urchin eggs as protein kinase CK2

Here we purified and identified a myosin II kinase from sea urchin eggs. The activity of this myosin II kinase in the egg extract was not significantly affected by Ca(2+)/calmodulin (CaM). Using sequential column chromatographies, we purified the myosin II kinase from the egg extract as a complex composed of 36- (p36) and 28-kDa (p28) proteins. Partial amino acid sequences of these two components were highly coincident with those of the alpha and beta subunits of protein kinase CK2 (formerly casein kinase II) in sea urchin eggs, respectively. To confirm that the purified myosin II kinase was CK2, we obtained a cDNA which encodes p36 from a cDNA library of sea urchin eggs. The amino acid sequence derived from the obtained cDNA showed over 70% homology to CK2 from various eukaryotes. Furthermore, recombinant p36, as well as the purified myosin II kinase, phosphorylated MRLC. One dimensional phosphopeptide mapping revealed that the phosphorylation site(s) of MRLC by both recombinant p36 and the purified myosin II kinase was identical. These clearly showed that the Ca(2+)/CaM-independent myosin II kinase activity in sea urchin eggs was identical to CK2.     

Casein kinase II activity and polyamine-stimulated protein phosphorylation of cytosolic and plasma membrane proteins in bovine sperm

A highly purified preparation of sperm cytosolic protein kinase was obtained by repeated chromatography with phosphocellulose. The preferred substrate of the enzyme was casein and the activity was not stimulated by added Ca2+, calmodulin, or cAMP. With casein as substrate, both ATP and GTP served as phosphate donors and the activity was inhibited by low micromolar heparin and stimulated by low millimolar spermine and spermidine. These properties are characteristic of casein kinase II from other cells. Endogenous protein substrates of the enzyme in sperm cytosolic fractions and in plasma membranes were demonstrated by incubating the preparations with [gamma-32P]GTP, under conditions unfavorable to other protein kinases, and analyzing the products by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. Spermine greatly enhanced the phosphorylation of three (55, 92, and 106 kDa) proteins in both cytosolic and plasma membrane preparations. Our results indicate that polyamines play a role in modulating the phosphorylation state of proteins in sperm and may further regulate sperm function through this mechanism.     

Progesterone-induced activation of RNA-binding casein kinase type II during maturation of frog oocytes

During progesterone-induced maturation of the Rana temporaria oocytes phosphorylation of RNA(heparin)-binding proteins changes drastically due to the alterations in the activity of RNA-binding casein kinase II. Its activity increases 7 hr later administration of progesterone and correlates with the level of translation in oocytes. Cycloheximide almost completely inhibits the protein biosynthesis but has no effect on the activity of RNA-binding casein kinase and the set of phosphorylated polypeptides. The possibility is discussed that this enzyme participates in the translation control mechanisms.     

Activation of casein kinase II by sphingosine

Sphingosine activates casein kinase II in the presence of endogenous substrates as well as a synthetic peptide substrate. The activation response occurred between 12 and 25 micrograms/ml sphingosine and exhibited positive cooperativity with a Hill coefficient of 3.0. Sphingosine not only increased the Vmax of casein kinase II but decreased the Km(app) for the peptide substrate from 0.5 to 0.08 mM. In contrast, the Km(app) for MgCl2 was increased from 0.12 to 0.7 mM. Consequently, sphingosine altered significantly several parameters which determine casein kinase II activity. The effect of sphingosine was relatively specific, inasmuch as related lipids were less potent activators or largely ineffective in stimulating casein kinase II. On the other hand, the effect of sphingosine itself could be potentiated or inhibited by other lipids. Ceramide and sphingosylphosphorylcholine augmented the sphingosine effect. Phospholipids alone did not alter the activity of casein kinase II significantly, but abolished enzyme activation by sphingosine with different potencies (phosphatidylserine greater than phosphatidylethanolamine greater than phosphatidylinositol greater than phosphatidylcholine). Moreover, the sphingosine effect could be abrogated by KCI and NaCl, which alone are known to induce enzyme activation and dissociation of aggregated casein kinase II protein; LiCl and NH4Cl also inhibited the sphingosine effect. Polyamines, known activators of casein kinase II, partially mimicked the effect of sphingosine on endogenous polypeptide phosphorylation but failed to do so with the peptide substrate. These observations demonstrate that sphingosine is a potent activator of casein kinase II. The potential pharmacological and physiological modulation of casein kinase II by sphingoid bases is discussed.     

Association of casein kinase II with microtubules

A magnesium-dependent heparin-inhibited protein kinase activity associated with brain microtubule preparations has been identified as casein kinase II using a monospecific polyclonal antibody. This enzyme appears enriched in cold-stable microtubule fractions. By immunofluorescence microscopy using an antiserum against casein kinase II, the in situ immunolabeling of some microtubule assays has been observed. Thus, mitotic spindles are stained by the anti-casein kinase II antibody in fibroblast cells. In neuroblastoma cells induced to differentiate, the labeling of microtubule arrays inside developing axon-like processes is also seen. These results support the view that casein kinase II can modulate cytoskeletal assembly and dynamics through phosphorylation of microtubule proteins.     

Effects of cationic polypeptides on the activity, substrate interaction, and autophosphorylation of casein kinase II: a study with calmodulin.

The effects of basic polypeptides on the ability of casein kinase II to phosphorylate an exogenous substrate (calmodulin) are correlated with steady-state autophosphorylation of the alpha- and beta-subunits of casein kinase II. Polylysine and polyarginine increase autophosphorylation of the alpha-subunit with a concomitant decrease in beta-subunit phosphorylation, while enhancing casein kinase II-stimulated phosphorylation of calmodulin over 100-fold. The highly basic carboxyl terminal segment of the endogenous p21c-Ki-ras has similar effects on the phosphorylation of calmodulin and the alpha- and beta-subunits of casein kinase II. Altering the concentration of cationic polypeptides produces a biphasic effect on the phosphorylation of both calmodulin and the alpha-subunit, which correlate positively with each other but do not correlate with beta-subunit phosphorylation. When the KCl concentration is changed, casein kinase II activity correlates positively only with alpha-subunit phosphorylation. In contrast, the biphasic response of calmodulin phosphorylation by casein kinase II at different Ca2+ concentrations correlates positively with both alpha- and beta-subunit phosphorylation. Therefore, in the presence of basic protein activators, the rate of phosphorylation of a substrate, calmodulin, correlates with steady-state phosphorylation of the alpha-subunit, but not with the beta-subunit under all conditions tested. Endogenous cationic factors may modulate the in vivo activity of casein kinase II and alter the interaction of the enzyme with specific intracellular substrates.     

Insulin action inhibits insulin-like growth factor-II (IGF-II) receptor phosphorylation in H-35 hepatoma cells. IGF-II receptors isolated from insulin-treated cells exhibit enhanced in vitro phosphorylation by casein kinase II

Insulin caused a rapid, dose-dependent increase in the binding of 125I-insulin-like growth factor-II (IGF-II) to the surface of cultured H-35 hepatoma cells. The [32P]phosphate content of the IGF-II receptors, immunoprecipitated from extracts of H-35 cell monolayers previously incubated with [32P]phosphate for 24 h, was decreased after brief exposure of the cells to insulin. Analysis of tryptic digests of labeled IGF-II receptors by bidimensional peptide mapping revealed that the decrease in the content of [32P]phosphate occurred to varying degrees on three tryptic phosphopeptides. Thin layer electrophoresis of an acid hydrolysate of isolated IGF-II receptors revealed the presence of [32P] phosphoserine and [32P]phosphothreonine. Insulin treatment of cells caused a decrease in the labeled phosphoserine and phosphothreonine content of IGF-II receptors. The ability of a number of highly purified protein kinases (cAMP-dependent protein kinase, protein kinase C, phosphorylase kinase, and casein kinase II) to catalyze the phosphorylation of purified IGF-II receptors was examined. Casein kinase II was the only kinase capable of catalyzing the phosphorylation of the IGF-II receptor on serine and threonine residues under the conditions of our assay. Bidimensional peptide mapping revealed that the kinase catalyzed phosphorylation of the IGF-II receptor on a tryptic phosphopeptide which comigrated with the main tryptic phosphopeptide found in receptors obtained from cells labeled in vivo with [32P]phosphate. IGF-II receptors isolated by immunoadsorption from insulin-treated H-35 cells were phosphorylated in vitro by casein kinase II to a greater extent than the receptors isolated from control cells. Similarly, IGF-II receptors from plasma membranes obtained from insulin-treated adipocytes were phosphorylated by casein kinase II to a greater extent than the receptors from control adipocyte plasma membranes. Thus, the insulin-regulated phosphorylation sites on the IGF-II receptor appear to serve as substrates in vivo for casein kinase II or an enzyme with similar substrate specificity.     

Transient increase of a protein kinase activity identified to CK2 during sea urchin development

Using GST-EF-1 delta as an exogenous substrate, and EF-1 delta kinase activity was shown to increase transiently during early development of sea urchin embryos. The basal activity of EF-1 delta kinase in unfertilized eggs was 150 fmoles/min/mg protein. The activity began to increase 10 h after fertilization and reached its maximum level (8.4 x basal) at 24 h. The activity then declined to twice the basal value at 72 h post-fertilization. The EF-1 delta kinase activity was identified to a CK2-type enzyme on the basis of its substrate specificity for EF-1 delta, crude casein and beta casein, its inhibition by heparin, DRB, 2,3-bisphosphoglycerate, and its stimulation by spermine, spermidine, and polylysin. Furthermore, the activity was inhibited by the synthetic peptide RRREEETEEE specific for CK2. DRB (200 microM) and 2,3-bisphosphoglycerate (2.5 mM) blocked or delayed the transition from blastula to gastrula of the embryos, suggesting a role for the kinase in early development.     

Identification of casein kinase 1, casein kinase 2, and cAMP-dependent protein kinase-like activities in Trypanosoma evansi

Trypanosoma evansi contains protein kinases capable of phosphorylating endogenous substrates with apparent molecular masses in the range between 20 and 205 kDa. The major phosphopolypeptide band, pp55, was predominantly localized in the particulate fraction. Anti-alpha and anti-beta tubulin monoclonal antibodies recognized pp55 by Western blot analyses, suggesting that this band corresponds to phosphorylated tubulin. Inhibition experiments in the presence of emodin, heparin, and 2,3-bisphosphoglycerate indicated that the parasite tubulin kinase was a casein kinase 2 (CK2)-like activity. GTP, which can be utilized instead of ATP by CK2, stimulated rather than inactivated the phosphorylation of tubulin in the parasite homogenate and particulate fraction. However, GTP inhibited the cytosolic CK2 responsible for phosphorylating soluble tubulin and other soluble substrates. Casein and two selective peptide substrates, P1 (RRKDLHDDEEDEAMSITA) for casein kinase (CK1) and P2 (RRRADDSDDDDD) for CK2, were recognized as substrates in T. evansi. While the enzymes present in the soluble fraction predominantly phosphorylated P1, P2 was preferentially labeled in the particulate fractions. These results demonstrated the existence of CK1-like and CK2-like activities primarily located in the parasite cytosolic and membranous fractions, respectively. Histone II-A and kemptide (LRRASVA) also behaved as suitable substrates, implying the existence of other Ser/Thr kinases in T. evansi. Cyclic AMP only increased the phosphorylation of histone II-A and kemptide in the cytosol, demonstrating the existence of soluble cAMP-dependent protein kinase-like activities in T. evansi. However, no endogenous substrates for this enzyme were identified in this fraction. Further evidences were obtained by using PKI (6-22), a reported inhibitor of the catalytic subunit of mammalian cAMP-dependent protein kinases, which specifically hindered the cAMP-dependent phosphorylation of histone II-A and kemptide in the parasite soluble fraction. Since the sum of the values obtained in the parasite cytosolic and particulate fractions were always higher than the values observed in the total T. evansi lysate, the kinase activities examined here appeared to be inhibited in the original extract.     

Casein kinase II from Rana temporaria oocytes. Intracellular localization and activity during progesterone-induced maturation

A homogeneous preparation of casein kinase II has been isolated from the ribosome-free extracts of Rana temporaria oocytes by means of chromatography on heparin-Sepharose, phosphocellulose and mono Q. The enzyme consists of three subunits with molecular mass of 43 kDa, 41 kDa and 29 kDa. The protein kinase was labelled with radioactive iodine and injected back into oocytes. As shown by histoautoradiography the enzyme forms a diffuse ring around the nucleus in the oocyte cytoplasm. A part of casein kinase II is found in informosomes. During oocytes maturation casein kinase II activity increases 7 h after progesterone administration and at the final stages of maturation (20-23 h). Cycloheximide blocks the second augmentation of kinase activity and does not influence the first one.     

Basic region of residues 228-231 of protein kinase CK1alpha is involved in its interaction with axin: binding to axin does not affect the kinase activity

Protein kinase CK1, also known as casein kinase 1, participates in the phosphorylation of beta-catenin, which regulates the functioning of the Wnt signaling cascade involved in embryogenesis and carcinogenesis. beta-catenin phosphorylation occurs in a multiprotein complex assembled on the scaffold protein axin. The interaction of CK1alpha from Danio rerio with mouse-axin has been studied using a pull-down assay that uses fragments of axin fused to glutathione S transferase, which is bound to glutathione sepharose beads. The results indicate that the three lysines present in the basic region of residues 228-231 of CK1alpha are necessary for the binding of CK1 to axin. Lysine 231 is particularly important in this interaction. In order to define the relevance of the axin-CK1alpha interaction, the effect of the presence of axin on the phosphorylating activity of CK1alpha was tested. It is also evident that the region of axin downstream of residues 503-562 is required for CK1alpha interaction. The binding of CK1alpha to axin fragment 292-681 does not facilitate the phosphorylation of beta-catenin despite the fact that this axin fragment can also bind beta-catenin. Binding of CK1alpha to axin is not required for the phosphorylation of axin itself and, likewise, axin does not affect the kinetic parameters of the CK1alpha towards casein or a specific peptide substrate.     

Effect of Ethanol on Nuclear Casein Kinase II Activity in Brain

Casein kinase II (CK II) plays an important role in serine/threonine dependent protein phosphorylation. In brain it is associated with long term potentiation besides its involvement in DNA, RNA and protein metabolism. Ethanol has been shown to induce cognitive impairment and affects DNA, RNA and protein metabolism at various steps. Since CK II is central in all these events, which are specifically affected by ethanol, the role of nuclear CK II is investigated in the present study. Total nuclear casein kinase activity was unaffected while heparin sensitive nuclear casein kinase II activity showed a 30% decrease in the brain from chronic alcohol fed rats. Cytosolic CK II activity was also unaffected. Immunological detection by western analysis using CK II antibodies showed no alteration in the quantity of enzyme. The decrease in nuclear casein kinase II might be responsible for ethanol induced cognitive impairment in the brain.     

Partial purification and characterization of a new phosphoprotein kinase from cells infected with pseudorabies virus

Cytoplasmic fractions from normal baby hamster kidney fibroblasts and from fibroblasts infected with pseudorabies virus were fractionated by DEAE-cellulose chromatography and fractions assayed for protein kinase activity. In preparations from uninfected and infected cells protein kinase activities identified as casein kinase I and II, the two isoforms of the cyclic-AMP-dependent protein kinase, protein kinase C, and a presumed proteolytic fragment of protein kinase C were present in comparable amounts. However in infected cells a new protein kinase activity was detected, appearing about 4 h after infection and increasing during the following 6 h at least. This new protein kinase was purified 100-fold by high-performance gel-permeation and ion-exchange chromatography, and characterized. It has an apparent relative molecular mass of 68 000 on the basis of gel-permeation chromatography, and a sedimentation coefficient of 4.3 S. It catalysed the phosphorylation of serine residues of basic proteins in vitro, with protamine a better substrate than mixed histones; and used ATP (apparent Km = 60 microM), but not GTP, as phosphoryl donor. Molecules that can serve as effectors for other protein kinases (cyclic AMP, cyclic GMP, Ca2+ + calmodulin, Ca2+ + phospholipid, double-stranded RNA, and heparin) did not significantly alter the activity of this enzyme. A distinguishing characteristic of the protein kinase was a high KCl concentration optimum with the persistence of activity up to 800 mM KCl, at least.     

Antibodies to Xenopus egg S6 kinase II recognize S6 kinase from progesterone- and insulin-stimulated Xenopus oocytes and from proliferating chicken embryo fibroblasts.

Ribosomal protein S6 becomes highly phosphorylated during progesterone- or insulin-induced maturation of Xenopus laevis oocytes. We have previously purified an Mr 92,000 protein as one of the major S6 kinases from Xenopus unfertilized eggs. In this paper we confirm by renaturation of activity from a sodium dodecyl sulfate-polyacrylamide gel that this protein is an S6 kinase. This enzyme, termed S6 kinase II (S6 K II), was used for the preparation of polyclonal antiserum. Immunocomplexes formed with the antiserum and purified S6 K II were able to express kinase activity with the same substrate specificity as that of the purified enzyme, including autophosphorylation of S6 K II itself. The antiserum did not react with S6 kinase I, another major S6 kinase present in Xenopus eggs, which is chromatographically distinct from S6 K II. The administration of progesterone to oocytes resulted in a 20- to 25-fold increase in S6 kinase activity in extracts of these cells. Immunocomplex kinase assays done on extracts revealed that anti-S6 K II serum reacted with S6 kinase from progesterone-treated oocytes. This antiserum also reacted with the activated S6 kinase from insulin-stimulated oocytes. In addition, anti-S6 K II serum reacted with activated S6 kinase from chicken embryo fibroblasts stimulated with serum or transformed by Rous sarcoma virus. These results indicate that S6 K II or an antigenically related S6 kinase(s) is subject to regulation by mitogenic stimuli in various cell types.     

Modulation of casein kinase II activity by the polar head group of an insulin-sensitive glycosyl-phosphatidylinositol

A phospho-oligosaccharide, whose production is stimulated by insulin, modulated the activity of partially purified casein kinase II. Whereas at 2 microM the phospho-oligosaccharide stimulated casein kinase II 1.3-fold, higher concentrations of this molecule were inhibitory. 50% inhibition of the enzyme was obtained at 15 microM phospho-oligosaccharide. This biphasic effect of the phospho-oligosaccharide on casein kinase II activity was observed using as substrate both casein or the specific peptide for casein kinase II, Arg-Arg-Arg-Glu-Glu-Glu-Thr-Glu-Glu-Glu. The effect of the phospho-oligosaccharide on casein kinase II was still observed after gel filtration. Deamination of the phospho-oligosaccharide with nitrous acid abolished both the activation and the inhibition of casein kinase II. The glycophospholipid precursor of the phospho-oligosaccharide did not affect casein kinase II activity. Moreover, modulation of casein kinase II activity was not observed with other compounds structurally related to the phospho-oligosaccharide, when used in the micro-molar range. In conclusion, the present results indicate that the phospho-oligosaccharide that mimics and might mediate some of the actions of insulin modulates casein kinase II activity in vitro.     

M-phase-specific cdc2 protein kinase phosphorylates the beta subunit of casein kinase II and increases casein kinase II activity

The M-phase-specific cdc2 (cell division control) protein kinase (a component of the M-phase-promoting factor) was found to activate casein kinase II in vitro. The increase in casein kinase II activity ranged over 1.5-5-fold. Increase in activity was prevented if ATP was replaced during the activation reaction by a non-hydrolysable analogue. Alkaline phosphatase treatment of the activated enzyme decreased the activity to the basal level. The beta subunit of casein kinase II was phosphorylated by cdc2 protein kinase at site(s) different from the autophosphorylation sites of the enzyme. Phosphoamino acid analysis showed that the beta subunit was phosphorylated by cdc2 protein kinase at threonine residues while autophosphorylation involved serine residues. Casein kinase II may be part of the cascade which leads to increased phosphorylation of many proteins at M-phase and therefore be involved in the pleiotropic effects of M-phase-promoting factor.