A hepatic soluble cyclic nucleotide-independent protein kinase. Stimulation by basic polypeptides

Effects of polyamines, polyamine synthesis inhibitors, and polyamine analogs on casein kinase II using Myc oncoprotein as substrate

Polyamines, casein kinase II (CKII), and the myc oncogene are directly involved in the regulation of molecular events in cell proliferation, differentiation, and apoptosis. Each is increased in rapidly growing cancer cells. In our current study, we showed that the Km values for purified CKII were similar for casein and Myc oncoprotein under a variety of assay conditions, and that specific natural and synthetic polyamines stimulated CKII phosphorylation of Myc oncoprotein 2- to 20-fold via increases in Vmax. When polyamine synthesis inhibitors and analogs were studied with this purified enzyme system, two polyamine analogs (N1,N12-bis-(ethyl)-spermine [BESpm] and 1,19-bis-(ethylamino)-5,10,15, triazononadecane [BE4X4]), which did not affect basal enzyme activity, did prevent (or inhibit) polyamine-stimulated CKII activity by approximately 70 and 85 percent, respectively. Because the Myc oncoprotein transactivates several genes for key proteins involved in the regulation of cellular proliferation, including the omithine decarboxylase gene (rate-limiting enzyme of polyamine synthesis), we suggest that there may be linkages between polyamines, CKII, and Myc in the control of cellular proliferation. We also suggest that the anticancer drugs BESpm and BE4X4 may inhibit cancer cell proliferation partially through interference with the above-suggested CKII linkages.

Protein kinase activities in ripening mango, Mangifera indica L., fruit tissue. I: Purification and characterization of a calcium-stimulated casein kinase-I

A Ca(2+)-stimulated protein kinase (PK-I), active with dephosphorylated casein as exogenous substrate, was purified from ripening mango fruit. The purification procedure involved 30-70% ammonium sulphate fractionation and sequential anion exchange-, affinity-, hydrophobic interaction- and gel filtration chromatography. PK-I was purified ca. 40-fold with an overall yield of < 1%. The final specific activity in the presence of 0.1 mM Ca2+ was 55 nmol min-1 mg-1. Analysis of the most highly purified preparations revealed a monomeric enzyme with an M(r) of 30.9 kDa and pI of 5.1. PK-I efficiently phosphorylated casein and phosvitin, but did not phosphorylate histone II-S, histone III-S, protamine sulphate or bovine serum albumin. PK-I activity was stimulated by micromolar concentrations of Ca2+ and was dependent on millimolar Mg2+ concentrations, which could not be substituted with Mn2+. PK-I activity was stimulated by, but was not dependent on Ca2+. Calmodulin and calmodulin inhibitors did not affect PK-I activity, but heparin and cAMP acted as inhibitors. The pH and temperature optima of the enzyme under standard reaction conditions were 6.5 and 35 degrees C, respectively. The kinetic reaction mechanism of PK-I was studied by using casein as substrate. Initial velocity and product inhibition studies with ADP as product inhibitor best fit an ordered bi-bi kinetic mechanism with the Mg(2+)-ATP complex binding first to the enzyme followed by binding of the protein substrate. The K(m)ATP and K(m)casein of PK-I were 9 microM and 0.26 mg ml-1, respectively. The KiADP of PK-I was 9 microM.

A novel serine/threonine-specific protein phosphotransferase activity of Nm23/nucleoside-diphosphate kinase

Two human nm23 genes have been identified, designated nm23-H1 and nm23-H2, which encode the 88% identical nucleoside-diphosphate kinase (NDPK) A and NDPK B polypeptides, respectively. The nm23-H1 gene product has been shown to play a functional role in the suppression of tumor metastasis. The Nm23 proteins/NDPK are highly conserved throughout evolution and are implicated in controlling cellular differentiation and development in various species, while the underlying mechanisms remain undefined. Neither the NDPK activity nor the DNA-binding activity, identified recently for NDPK B, can satisfactory explain the regulatory functions of Nm23. The present study provides evidence that purified Nm23 proteins are capable of transferring a phosphate group to other proteins when non-denaturing amounts of urea are present. This novel Nm23/NDPK activity was found to be specific for serine and threonine residues, and the transphosphorylation of substrate proteins occurred stoichiometrically. Because of the absence of a substrate turn-over, the novel function was termed protein phosphotransferase activity instead of protein kinase activity. It is demonstrated that urea stimulates the interaction of NDPK with other proteins. Identical phosphoprotein patterns were obtained using purified NDPK preparations from human, Drosophila, yeast and Dictyostelium in the presence of urea. Partially purified NDPK from human erythrocytes produced a similar phosphorylation pattern independent of urea addition and also acted stoichiometrically. In this preparation, a protein phosphotransferase activity of Nm23 species may possibly be generated and/or stabilized by the interaction with copurified proteins. Using different mutants of Dictyostelium NDPK it was shown that the protein phosphotransferase activity depends on the same active site as the NDPK activity. A phosphotransfer mechanism analogous to that of protein-histidine kinases is proposed, involving a high-energy phosphohistidine intermediate. Furthermore, the novel Nm23 function is compared with an apparently similar protein phosphotransferase activity which was observed previously with partially purified NDPK from different plant species.

Spermine and polylysine enhanced phosphorylation of calmodulin and tubulin in an insect endocrine gland

Spermine-stimulated and heparin-inhibited phosphorylation of both exogenous casein and endogenous protein substrates of the prothoracic gland were measured in prothoracic gland cytosolic fractions from fifth instar larvae and early pupae of the tobacco hornworm, Manduca sexta. The results reveal a striking increase in casein kinase II (CKII) activity, i.e. approximately 3-fold above basal level in the presence of 5 mM spermine, with the highest activity exhibited by gland fractions from day 0-2 larvae, newly pupated animals and day 1 pupae. These results were verified by the results from Western blot analysis using a CKII alpha-subunit specific antibody and a 10 a.a. synthetic peptide that is a specific substrate for CKII. Several endogenous proteins were found to be substrates for CKII when assayed in the presence of spermine or polylysine. A 19 kDa peptide was shown to be calmodulin (CaM) by using the purified Manduca brain CaM as an indicator, and was only phosphorylated in the presence of polylysine. A 52 kDa protein was identified as tubulin by immunoprecipitation with a tubulin-specific monoclonal antibody, and was shown to be phosphorylated in the presence of spermine and polylysine. The possible roles of phosphocalmodulin and phosphotubulin are discussed in the context of prothoracic gland function.

The effect of polylysine on casein-kinase-2 activity is influenced by both the structure of the protein/peptide substrates and the subunit composition of the enzyme

The mechanism by which polybasic peptides stimulate the activity of casein kinase 2 (CK2) has been studied by comparing the effect of polylysine on the phosphorylation of a variety of protein and peptide substrates by the native CK2 holoenzyme and by its recombinant catalytic alpha subunit, either alone or in combination with the recombinant non-catalytic beta subunit. Calmodulin is not phosphorylated by the CK2 holoenzyme, in either the native or the reconstituted form, unless polylysine is added. In the presence of polylysine, it becomes a good substrate for CK2 (Km 14.2 microM, Kcat 4.6 mol.min-1.mol CK2-1). The recombinant alpha subunit, however, spontaneously phosphorylates calmodulin, this phosphorylation being actually inhibited rather than stimulated by polylysine. The calmodulin tridecapeptide, RKMKDTDSEEEIR, reproducing the phosphorylation site for CK2, is spontaneously phosphorylated by either CK2 holoenzyme or the recombinant alpha subunit with 5.8-fold and 2.8-fold stimulation by polylysine, respectively. The recombinant beta subunit of CK2 is itself a good exogenous substrate for the enzyme, its phosphorylation, however, is inhibited rather than enhanced by polylysine. On the contrary, the phosphorylation of the nonapeptide, MSSSEEVSW, reproducing the beta-subunit phosphoacceptor site, is dramatically stimulated by polylysine. Using a variety of small peptide substrates, it was shown that phosphorylation rate is diversely stimulated by polylysine. The observed stimulation, moreover, is variably accounted for by changes in Vmax and/or Km, depending on the structure of the peptide substrate. Maximum stimulation with all protein/peptide substrates tested requires the presence of the beta subunit, since the recombinant alpha subunit is much less responsive than CK2 holoenzyme, either native or reconstituted. While the phosphorylation of the peptide RRRDDDSDDD by CK2 is stimulated 2.8-fold, with 15 nM polylysine being required for half-maximal stimulation, a stimulation of only 1.9-fold, with 80 nM polylysine required for half-maximal stimulation, is attained with recombinant alpha subunit. The concentration of polylysine required for half-maximal stimulation is comparable to CK2 concentration and increases by increasing CK2 concentration, suggesting that polylysine primarily interacts with the enzyme, rather than with the peptide substrate.

Characterization of synthetic peptide substrates for p34cdc2 protein kinase

Synthetic peptide substrates for the cell division cycle regulated protein kinase, p34cdc2, have been developed and characterized. These peptides are based on the sequences of two known substrates of the enzyme, Simian Virus 40 Large T antigen and the human cellular recessive oncogene product, p53. The peptide sequences are H-A-D-A-Q-H-A-T-P-P-K-K-K-R-K-V-E-D-P-K-D-F-OH (T antigen) and H-K-R-A-L-P-N-N-T-S-S-S-P-Q-P-K-K-K-P-L-D-G-E-Y-NH2 (p53), and they have been employed in a rapid assay of phosphorylation in vitro. Both peptides show linear kinetics and an apparent Km of 74 and 120 microM, respectively, for the purified human enzyme. The T antigen peptide is specifically phosphorylated by p34cdc2 and not by seven other protein serine/threonine kinases, chosen because they represent major classes of such enzymes. The peptides have been used in whole cell lysates to detect protein kinase activity, and the cell cycle variation of this activity is comparable to that measured with specific immune and affinity complexes of p34cdc2. In addition, the peptide phosphorylation detected in mitotic cells is depleted by affinity adsorption of p34cdc2 using either antibodies to p34cdc2 or by immobilized p13, a p34cdc2-binding protein. Purification of peptide kinase activity from mitotic HeLa cells yields an enzyme indistinguishable from p34cdc2. These peptides should be useful in the investigation of p34cdc2 protein kinase and their regulation throughout the cell division cycle.

A synthetic peptide substrate for selective assay of protein kinase C

Among various phosphate acceptor proteins and peptides so far tested, a synthetic peptide having the sequence surrounding Ser(8) of myelin basic protein, Gln-Lys-Arg-Pro-Ser(8)-Gln-Arg-Ser-Lys-Tyr-Leu, (MBP4-14), is the most specific and convenient substrate which can be used for selective assay of protein kinase C. This peptide is not phosphorylated by cyclic AMP-dependent protein kinase, casein kinases I and II, Ca2+/calmodulin-dependent protein kinase II, or phosphorylase kinase, and can be routinely used for the assay of protein kinase C with low background in the crude tissue extracts. The Km value is considerably low (7 microM) with a Vmax value of twice as much as that for H1 histone.

Diverse effects of poly-basic amino acids, heparin and ionic strength on the phosphorylation of various substrates by cytosolic protein-tyrosine kinase from porcine spleen

1. Effects of poly-basic amino acids, heparin and ionic strength on the activity of cytosolic protein-tyrosine kinase from porcine spleen (CPTK-40) have been studied. 2. Both polylysine and polyarginine stimulated the phosphorylation of [Val5]angiotensin II and E11 G1 (synthetic peptide of EDAEYAARRRG), but could neither stimulate nor inhibit the phosphorylation of random copolymers; poly(EY)4:1 and poly(EAY)6:3:1. 3. Heparin stimulated the phosphorylation of poly(EY)4:1 by 2.5-fold, however, it inhibited those of E11G1, poly(EAY)6:3:1, casein and H2B histone. 4. Elevation of ionic strength of either NaCl, KCl or (NH4)2SO4 stimulated the phosphorylation of poly(EY)4:1 by greater than 5-fold, but inhibited those of casein, tubulin, H2B histone, E11G1 and poly(EAY)6:3:1. 5. These effectors did not change the Km for substrates but increased the Vmax. 6. These results suggest that the effects of poly-basic amino acids, heparin and ionic strength on the activity of CPTK-40 are mainly on the substrates employed rather than on the enzyme itself.

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.

Random tyrosine and glutamic acid-containing polymers are very powerful inhibitors of casein kinase-2

The random heteropolymers Glu/Tyr(4:1) and Glu/Tyr(1:1) that are widely used as substrates for tyrosine protein kinases, are very powerful competitive inhibitors of casein kinase-2, but not of casein kinase-1, with respect to the protein substrate, their Ki values being one to two orders of magnitude lower than those of polyglutamates of similar size. The inhibitory power is reduced if tyrosine is partially replaced by alanine, as in the polymer Glu/Ala/Tyr(6:3:1) and it disappears upon inclusion of lysine, the polymer Glu/Ala/Lys/Tyr(2:6:5:1) actually behaving as a stimulator. These data indicate that non-phosphorylatable hydroxylic residues in addition to acidic ones are required in order to optimize the binding of pseudo-substrates to the catalytic site of casein kinase-2.

Regulation of cytosolic protein-tyrosine kinase from porcine spleen by polyamines and negative-charged polysaccharides

In vitro regulation of cytosolic protein-tyrosine kinase from porcine spleen (CPTK-40) by various positive or negative charged compounds was studied. Spermine and spermidine stimulated the activity of CPTK-40 about two-fold using (Val5)angiotensin II as a substrate. This stimulation was not specific for the peptide but was also observed in the case of tubulin phosphorylation indicating a direct effect of these compounds on the enzyme itself. On the contrary, negative-charged polysaccharides were shown to be strong inhibitors of CPTK-40. The possibility of the physiological regulation of CPTK-40 by these compounds is briefly discussed.

The polycation-stimulated protein phosphatases: regulation and specificity

Four classes of protein phosphatases are presumed to play an important role in dephosphorylating the major proteins involved in the control of general metabolism. Based on the enzyme-directed regulation of activity they have been classified as ATP,Mg-dependent-, polycation-stimulated-, Mg2+-dependent protein phosphatases and calcineurin. We have recently purified from rabbit skeletal muscle four distinct PCS protein phosphatases, classified according to the apparent molecular weight of the native enzymes in gel filtration at an early stage of the purification as: PCSH (390 kDa), PCSM (250 kDa) and PCSL (200 kDa) phosphatases. The PCSH phosphatase could be resolved into a 3(65:55 35 kDa)-subunit PCSH1 phosphatase and a 2(65:35 kDa)-subunit PCSH2 enzyme probably derived from the PCSH1 phosphatase, both characterized as specific deinhibitor phosphatases. PCSM phosphatase, a 3(72:65 35 kDa)-subunit enzyme, shows a high degree of stimulation with a low concentration optimum of polycations and is sensitive to a Ca2+-dependent protease, which brings about a five- to ten-fold increase in inhibitor-1 phosphatase activity. PCSL phosphatase is characterized by a 2(65:35 kDa)-subunit structure, a low intrinsic deinhibitor phosphatase activity and a low degree of stimulation of phosphorylase phosphatase activity requiring high concentrations of polycations. At low concentrations of polycations the stimulation of phosphorylase phosphatase activity of the PCS enzymes is enzyme-directed, since it occurs at concentrations far below the substrate concentration. The degree of stimulation is also typical for each type of enzyme (PCSM greater than PCSH1 greater than PCSH2 greater than PCSL greater than PCSC) and dependent on the polycation used; at the optimum concentration the most effective polycations (polylysine, protamine, histone H1) stimulate the phosphorylase phosphatase activity to about the same extent. Polycation concentrations above the optimum are less effective on phosphorylase phosphatase activity and can even become inhibitory to the basal activity. Whether this effect is enzyme- or substrate-directed (or both) is not known. The stimulation by polycations could be completely lost following preincubation of the PCS phosphatase with polycations. This deactivation is time-, temperature- and concentration-dependent. However the polycations did not affect the basal phosphorylase phosphatase activity. In addition to phosphorylase a and inhibitor-1, casein, myosin light chains and phosphorylase b kinase (alpha-subunit) are choice substrates for these enzymes.(ABSTRACT TRUNCATED AT 400 WORDS)

Polyamine-enhanced casein kinase II in mouse pancreatic islets

The occurrence of polyamine-stimulated protein kinase (casein kinase II) in cytosol of mouse pancreatic islets was investigated. Islet protein phosphorylation was enhanced by spermidine, spermine, lysine-rich histone and polylysine; the major endogenous substrates in the cytosol were three proteins of Mr 50,000, 55,000 and 100,000. Cadaverine and putrescine were without effects. A Mr 100,000 protein is a major substrate for Ca2+-calmodulin-dependent protein kinase, and Mr 50,000 and 55,000 proteins are substrates for cyclic adenosine 3',5'-cyclic monophosphate (AMP) dependent protein kinase in mouse islets. However, neither cyclic-AMP-dependent protein kinase inhibitor nor trifluoperazine inhibited polyamine-enhanced protein phosphorylation. Both basal and polyamine-enhanced protein phosphorylation patterns were identical when either [gamma-32P] adenosine 5'-triphosphate (ATP) or [gamma-32P] guanosine 5'-triphosphate (GTP) was used as phosphate donors, indicative of the presence of a polyamine-stimulated casein kinase II in pancreatic islets. It is suggested that polyamines and polyamine-enhanced casein kinase II activity may have an important role in regulation of protein phosphorylation in pancreatic islets.

Structure and properties of casein kinase-2 from Saccharomyces cerevisiae. A comparison with the liver enzyme

A type-2 casein kinase (YCK-2), lacking the 25-kDa autophosphorylatable beta subunit characteristic of animal casein kinases-2, has been obtained in a nearly pure form from Saccharomyces cerevisiae and was compared with liver casein kinase-2 (LCK-2). A 22-kDa phosphorylatable protein, copurifying with YCK-2, can be removed by ultracentrifugation at low ionic strength and is shown by several criteria to be unrelated to the beta subunit of LCK-2. The native Mr of YCK-2, deprived of the 22-kDa phosphoprotein, is about 150 000. Limited proteolysis experiments show that YCK-2 included 37-kDa catalytic subunits, which can be converted into still active 35-kDa proteolytic derivatives. These data are consistent with a homotetrameric quaternary structure as opposed to the heterotetrameric subunit composition alpha 2 beta 2 of LCK-2 and other animal casein kinases-2. Although many properties of YCK-2 and LCK-2, including substrate specificity, inhibition by heparin, polyglutamic acid and quercetin and stimulation by polyamines, are similar; their stability under denaturing and dissociating conditions and their response to polybasic peptides are quite different. In particular YCK-2 is more readily denatured than LCK-2 by heating and exposure to urea, sodium dodecylsulphate and deoxycholate while its activity is inhibited by 100-150 mM NaCl, which conversely stimulates LCK-2 activity 2-3-fold. The Km value of the synthetic peptide substrate Ser-(Glu)5 for YCK-2 is not significantly changed by the addition of polylysine. On the contrary the Km value of the same peptide substrate for LCK-2 decreases approximately tenfold upon addition of polylysine, which also prevents the fast autophosphorylation of the kinase at its beta subunit. These data suggest that the beta subunit of animal CK-2 may play a role in determining both the stability of the enzyme and its regulation and that, consequently, the different properties of YCK-2 may be at least in part accounted for by its lack of beta subunits.

Differential effects of polyamines on rat thyroid protein kinase activities

Ornithine decarboxylase, the rate-limiting enzyme in polyamine biosynthesis, has been shown to be regulated in thyroid by thyrotropin both in vivo and in vitro. Little, however, is known of the role of polyamines in thyroid cell function. Since studies in other tissues suggest that polyamines may influence protein phosphorylation, we studied the effect of the polyamines on various protein kinase activities in rat thyroid. Putrescine, spermidine, and spermine inhibit cyclic-AMP-dependent histone H1 kinase activity when measured in the cytosol fraction of rat thyroid; this effect is largely reproduced by NaCl concentrations of equivalent ionic strength. Both spermidine and spermine effect a 1.6-2.4-fold increase in cytosolic cyclic-AMP-independent (messenger-independent) casein kinase activity; stimulation by both polyamines is maximal at 5mM. A similar profile of stimulation is observed for messenger-independent casein kinase activity in crude nuclear preparations. Sodium chloride fails to stimulate both cytosolic and nuclear messenger-independent casein kinase activities at ionic strength equivalent to the spermine concentrations used. Spermine, but not putrescine, spermidine, or sodium chloride, inhibits calcium/phospholipid-dependent protein kinase C activity in cytosol extracts partially purified by DEAE chromatography. These findings suggest that regulation of protein kinase(s) by polyamines may represent a proximal locus (i) of action of thyrotropin-regulated ornithine decarboxylase activity in thyroid.

Some properties of the nucleotide-binding site of troponin T kinase-casein kinase type II from skeletal muscle

Investigation of properties of skeletal muscle troponin T kinase (EC 2.7.1.37) has revealed that the enzyme belongs to the group of casein kinases of the second type. The enzyme consists of two subunits with apparent molecular weights of 44 000 and 26 000 and contains a protein with molecular weight of 39 000, which is probably the proteolytic fragment of the 44 000 subunit. The substrate specificity of troponin T kinase was tested, using 20 analogs of the nucleotide. The enzyme has a low substrate specificity toward the purine base and uses both ATP and GTP as substrates. Modification of the ribose ring does not influence the enzyme interaction with the nucleotide; however, the cleavage of ribose leads to a decrease of the enzyme-nucleotide interaction. Elimination of the gamma-terminal phosphate or its modification by bulky hydrophobic radicals do not affect this interaction. A comparison of the Ki values for different analogs suggests that the interaction of troponin T kinase with the nucleotide occurs via the binding of the purine base and the beta-phosphate group of the analog.

Alterations in hepatic protein kinase activity induced by triiodothyronine

Quantitative and qualitative alterations in protein kinase (PK) activity in preparations of rat liver from hypothyroid (H) and T3-treated hypothyroid animals (T) were analyzed in comparison to enzyme from normal (N) animals. Qualitative variations in type of protein kinase were assessed by chromatography of cytosol preparations on DE-52 cellulose columns. Cytosol kinases resolved into a small fraction I containing a catalytic subunit, fraction II containing a type 1 holoenzyme, fraction III containing a cyclic-AMP independent PK, and fraction IV containing a type 2 holoenzyme. A cytosolic kinase active with casein as substrate was also identified. In H the type 1 holoenzyme was reduced in comparison to N. There were no other qualitative changes. Nuclear PKs were extracted with solvents containing 0.3 M KCl. Qualitative changes were evaluated by chromatography on phosphocellulose columns, but available methodology did not give reproducible evidence of changes in individual PKs. H had significantly more cytosolic PK active with protamine substrate than did normal animals, and by administration of T3, the H level was reduced progressively over 48 h to the N level. The activation ratio of total PK in cytosol was higher in H, and was also reduced to the N level by T3 administration. This suggests a higher steady state level of cyclic-AMP may be present in H rat liver cytosol. Cytosolic protein kinase reactive with casein as substrate increased gradually over 48 h after T3 administration from the H to the higher N level. It was significantly elevated to 110% of the H value by 48 h after T3 administration. The behavior of nuclear PK was entirely different. Nuclear PK reactive with protamine as substrate was increased within 1-1/2 h after T3 administration, reaching a peak of 130% of the control value at 5 h and returning to the normal level by 48 h. In contrast, nuclear PK reactive with casein as substrate also increased by 1-1/2 h after T3 administration and remained elevated at 110-115% of the control value throughout 48 h after T3 administration. The early changes in nuclear PK activity were prevented by administration of cycloheximide or alpha-amanitin. The observed changes in cytosolic PK, including the increment induced by T3 in type 1 enzyme, reduction in

Interaction of polyamines and magnesium with casein kinase II

In reticulocytes, polyamines appear to be physiologically relevant activators of casein kinase II [Hathaway, G. M. and Traugh, J. A. (1984). J. Biol. Chem. 259, 7011-7015]. The mechanism by which polyamines and Mg2+ interact to activate casein kinase II has been investigated. These studies were conducted by holding ionic strength constant at 0.10 M. At low Mg2+ (2.5 mM), activation by spermine resulted in a 33% decrease in the apparent Km for casein. Under these conditions, a 2.3-fold increase in the maximum velocity of the reaction was observed, and half-maximal stimulation was obtained with 275 microM spermine. At a kinetically optimal Mg2+ concentration of 12.5 mM, the effects of spermine on Km and Vmax were reduced, and the concentration of spermine required to give 50% of maximal stimulation was increased to 750 microM. Kinetic data obtained at the two Mg2+ concentrations indicated that Mg2+ and spermine competed for the same form of the enzyme. Double-reciprocal plots of velocity versus Mg2+ concentration showed downward curvature at Mg2+ concentrations higher than 1 mM, and these results were interpreted as evidence for two binding sites on the enzyme with an apparent Km of 0.5 and 2.5 mM. Experiments carried out with ATP-Mg2+ in the absence of excess MgCl2 gave results consistent with an absolute requirement of the enzyme for the metal ion which could not be replaced by spermine. These results are consistent with the formation of an enzyme-activator complex. A model is proposed where spermine activates casein kinase II at one site on the enzyme at which MgCl2 can also bind, while a second, high-affinity site exists exclusively for the metal ion.

Polyamine-mediated protein phosphorylations: a possible target for intracellular polyamine action

Polyamines are well-known ubiquitous components of living cells. Although these polycations have been implicated in the regulation of major cellular functions such as DNA, RNA and protein synthesis occurring during cellular proliferation and/or differentiation processes, their mechanism of action at the molecular level has remained obscure. On the other hand, protein phosphorylation has emerged as a regulatory process of prime importance in cellular regulation. Data have recently been presented suggesting that polyamines may express at least part of their biological action through an effect upon selective protein phosphorylation systems. Two types of polyamine-sensitive protein kinases have been characterized in the last few years. The best known in molecular terms is the widespread casein kinase G (also termed casein kinase II), which represents a multifunctional protein kinase, at present classified as a messenger-independent activity. The other is a polyamine-dependent nuclear ornithine decarboxylase kinase characterized in Physarum polycephalum and several mammalian tissues. Both protein kinases are activated by polyamines in vitro at concentrations compatible with a physiological role, by a mechanism which most likely also involves an effect through the protein substrate conformation. Preliminary evidence suggests that both kinases may be implicated in the regulation of DNA-dependent RNA polymerase activities, although several other potential substrates have been suggested for casein kinase G. Another suggestion is that these kinases may also participate in the post-translational regulation of ornithine decarboxylase, the rate-limiting step in the polyamine biosynthetic pathway. A novel class of protein kinase activities may thus be defined as polyamine-mediated phosphorylation systems for which polyamines may function as intracellular messenger. Although their biological significance remains to be fully established, especially with regard to the definition of their specific intracellular target(s) and subsequent biological functions, these systems will be interesting to consider in future studies aimed at understanding the role of polyamines in cell regulation.

Regulation of polyamine-responsive protein kinase by certain highly specific polyamines and charged carbohydrates

Polyamine-responsive protein kinase, a cyclic nucleotide-independent protein kinase from the cytosol of Morris hepatoma 3924A, was stimulated 8-9 fold by several different polymers of polylysine, polyornithine and random copolymers of lysine-alanine; spermidine, spermine, and mixtures of spermine and spermidine stimulated 2, 3, and 5 fold, respectively. The protein kinase was not stimulated by poly-carboxybenzyl-lysine, random copolymer of lysine-tyrosine, polyhistidine, polymethionine, polyglutamic acid, polyaspartic acid, dipeptide (Lys-Lys), lysine, ornithine, and putresine. The polyamine stimulation of the protein kinase was prevented by certain specific charged carbohydrates: heparin, chondroitin sulfates A, B, and C, dextran sulfate and hyaluronic acid. It was not prevented by noncharged carbohydrates: dextran, glycogen, starch, sucrose, etc; or by sulfate salts: ammonium sulfate, potassium sulfate, sodium thiosulfate, etc. The inhibition was reversed by increased polylysine. Heparin was non-competitive inhibitor of Mg2+-ATP. It would appear that this enzyme is regulated by certain highly specific molecules with certain sizes and charges; plus charge is stimulatory, negative charge prevents the stimulation.

Calmodulin stimulates polyamine-responsive protein kinase in the absence of Ca2+

A cyclic nucleotide-independent, polyamine-responsive protein kinase from the cytosol of Morris hepatoma 3924A, which phosphorylated heat-stable endogenous substrates and casein in the presence of polyamines (Criss, W.E., Yamamoto, M., Takai, Y., Nishizuka, Y. and Morris, H.P. (1978) Cancer Res. 38, 3540-3545) was observed to be stimulated by an endogenous protein activator. This protein activator was identified to be calmodulin. the polyamine-responsive protein kinase was also stimulated by purified calmodulin, but only in the presence of polyamines such as polylysine. This action of calmodulin did not require Ca2+ for activation of the enzyme; and activation occurred in the presence of EGTA. DNA and RNA inhibited the polyamine-responsive protein kinase, either in the presence or absence of Ca2+. Purified calmodulin, in the presence of cyclic AMP or cyclic GMP, did not activate the protein kinase. Therefore, polyamines such as polylysine are an absolute requirement for this expression of calmodulin action. The increased enzyme activity by calmodulin was accompanied with an increased Vmax and with no changes in the Km (ATP). High levels of cation, up to 100 mM Mg2+, did not effect the action of calmodulin. These results indicate that tumor cytosolic polyamine-responsive protein kinase is regulated by calmodulin, the latter being increased in the tumor tissue.

Tissue energy of mammalian modulator-dependent protein kinases

The levels of modulator-dependent protein kinases and protamine-dependent protein kinase(s) in various tissues of adult mice were compared. Cerebellum contained the highest levels of both modulator-dependent protein kinases and protamine-dependent protein kinase(s), whereas skeletal muscle contained no detectable enzymes. The lung and the ileum were also rich in modulator-dependent protein kinases, while other tissues were poor sources of these enzymes.

Polyamine-activated protein kinase reaction from nuclei and nucleoli of Physarum polycephalum which phosphorylates a unique Mr 70 000 nonhistone protein

Methods are described for the detection and purification of a protein kinase from nuclei and nucleoli of Physarum polycephalum which catalyzed transfer of phosphate from [gamma-32P]ATP to a unique nonhistone protein of Mr 70 000 in a reaction that was polyamine dependent. Enzymatic phosphorylation of the nonhistone protein by the purified protein kinase was stimulated greatly, at times more than 60-fold, by the polyamines spermidine and spermine. This unique polyamine-dependent reaction was localized on the rDNA minichromosome of the nucleolus. The polyamine-dependent protein kinase, which was first partially purified with the acidic nonhistone protein fraction from isolated nucleoli, was resolved from at least six other protein kinases by phosphocellulose chromatography into a catalytic component of Mr 26 000 and a complex comprised of the catalytic component associated with a phosphate acceptor protein of Mr 70 000. The complex also catalyzed polyamine-dependent phosphorylation of the endogenous Mr 70 000 component. The resolved catalytic component catalyzed polyamine-dependent phosphorylation of a dephosphorylated Mr 70 000 nonhistone protein that had been independently isolated from nucleoli and previously demonstrated to have properties concordant with a specific regulatory role in rRNA gene transcription [Keuhn, G. D., Affolter, H. U., Atmar, V. J., Seebeck, T., Gubler, U., & Braun, R. (1979) Proc. Natl. Acad. Sci. U.S.A. 76, 2541-2545]. These studies indicate one way that the polyamines may regulate rRNA gene transcription through the mediation of a highly specific nonhistone protein kinase.