Characterization of protein kinases from adrenal medulla. A study of cytosol and nuclear enzymes.

Since phosphorylation of chromosomal proteins by cyclic AMP-dependent protein kinases (EC 2.7.1.37) enhances template activity of adrenal medulla chromatin (9), we have studied the properties and regulation of protein kinases isolated from chromaffin cell cytosol and nuclei. DEAE-cellulose chromatography revealed three peaks of kinase activity in the nucleus (nPKI, nPKII, nPKIII) and two in the cytosol (cPKI, cPKII). The three nuclear enzymes, as well as cPKII, did not require cyclic AMP to express their catalytic activity. nPKI and nPKIII preferred acidic substrates as PO3-4 acceptors, while nPKII and the cytosol enzymes preferred basic PO3-4 acceptors. Enzyme recombination experiments using protein kinase regulatory subunits from cytosol suggested that cPKII was the catalytic subunit of cPKI. In contrast, the nuclear enzymes were not catalytic subunits of the cyclic AMP-dependent protein kinase in the cytosol (cPKI). Only the cytosol protein kinases could be inhibited by endogenous heat-stable protein kinase inhibitors. The nuclear and cytosol cyclic AMP-independent protein kinases were distinguishable on the basis of their sedimentation constants as well as Mc2+ and Mn2+ requirements.     

Protein kinases and their substrates in brown adipose tissue from newborn rats.

The 10000 X g supernatant fraction of brown fat from newborn rats catalyzed the cyclic AMP-dependent phosphorylation of both histone and a preparation of proteins from the same subcellular fraction (endogenous proteins). The apparent affinity for ATP was lower for the phosphorylation of the endogenous proteins than for the phosphorylation of histone. In order to discover whether the phosphorylation of histone and the endogenous proteins were catalyzed by different enzymes, the 100000 X g supernatant was fractionated by ion-exchange and adsorption chromatography. Three different cyclic AMP-dependent protein kinases and one cyclic AMP-independent protein kinase were separated and partially purified. Each of these enzymes catalyzed the phosphorylation of both substrates, and the difference in apparent Km for ATP remained. Neither affinity chromatography on histone-Sepharose, nor electrophoresis on polyacrylamide gels resulted in the separation of the phosphorylation of histone from that of the endogenous proteins of any of the partially purified kinases. Moreover, experiments in which the phosphorylated substrates were separated by differential precipitation with trichloroacetic acid showed that the endogenous proteins competitively inhibited the phosphorylation of lysine-rich histone. It is concluded that each of the partially purified kinase preparations contains protein kinase, which catalyzes the phosphorylation of both substrates. The difference in apparent Km for ATP was found to be due to the presence in the endogenous protein preparation of a low molecular weight compound which competes with ATP. This was not ATP nor the modulator protein. The ratio of the phosphorylation of endogenous proteins to that of histone was much higher for the cyclic AMP-independent kinase preparation than for the other enzymes. Electrophoresis of the endogenous substrates in the presence of sodium dodecyl sulphate showed that the enzyme phosphorylated a greater number of proteins than did the cyclic AMP-dependent kinases. The phosphorylation of endogenous proteins relative to that of histone was significantly lower for one of the cyclic AMP-dependent kinases than for the other two. This difference was not reflected in a different pattern of phosphorylation of the individual proteins of the endogenous mixture.     

Characterization of protein kinases from adrenal medulla

Since phosphorylation of chromosomal proteins by cyclic AMP-dependent protein kinases (EC 2.7.1.37) enhances template activity of adrenal medulla chromatin (9), we have studied the properties and regulation of protein kinases isolated from chromaffin cell cytosol and nuclei. DEAE-cellulose chromatography revealed three peaks of kinase activity in the nucleus (nPKI, nPKII, nPKIII) and two in the cytosol (cPKI, cPKII). The three nuclear enzymes, as well as cPKII, did not require cyclic AMP to express their catalytic activity, nPKI and nPKIII preferred acidic substrates as PO ₄ ^3– acceptors, while nPKII and the cytosol enzymes preferred basic PO ₄ ^3– acceptors. Enzyme recombination experiments using protein kinase regulatory subunits from cytosol suggested that cPKII was the catalytic subunit of cPKI. In contrast, the nuclear enzymes were not catalytic subunits of the cyclic AMP-dependent protein kinase in the cytosol (cPKI). Only the cytosol protein kinases could be inhibited by endogenous heat-stable protein kinase inhibitors. The nuclear and cytosol cyclic AMP-independent protein kinases were distinguishable on the basis of their sedimentation constants as well as Mg²⁺ and Mn²⁺ requirements.     

Cytoplasmic and nuclear protein kinases during the cell cycle.

Nuclear and cytoplasmic protein kinases were measured during the traverse of synchronous CHO cultures through G1 into S phase. Cells were synchronized by selective detachment of cells blocked in metaphase using colcemid. Nuclei were isolated and the protein kinases extracted from the nuclear preparation with 0.6 M NaCl. This procedure solubilized greater than 90% of the total protein kinase activity present in the nuclear preparation. DEAE chromatography of this extract showed 5 apparently different ionic forms of nuclear protein kinases. The nuclear protein kinases preferred casein and phosvitin to histone as substrates and were cyclic AMP-independent. Nuclear protein kinase activities increased greater than two-fold, when expressed as units of activity per cell nucleus, during G1 phase traverse, concomitant with a 70% increase in nuclear non-histone proteins (those soluble in 0.6 M NaCl). This resulted in only a 40% increase in the specific activities (units/microgram protein in 0.6 M NaCl extractable nuclear fraction) of these enzymes as cells progressed through G1 into S phase. This was in contrast to cytoplasmic cyclic AMP-dependent protein kinase activities which also increased two-fold during progression through G1 phase while total cellular protein increased less than 20%. Activation of, as well as synthesis of, cyclic AMP-dependent cytoplasmic protein kinases during G1 phase suggests a regulatory mechanism for precise temporal phosphorylation, whereas the constant specific activity in nuclear kinases during cell cycle is more compatible with the maintenance of bulk phosphorylation processes in the nucleus.     

Resonance Raman spectra of heme a derivatives. Evidence for the reaction of peripheral formyl group with HCN and NaHSO3.

A separate and distinct population of polyribosomes exists in the detergent-washed nuclei of adenovirus-infected HeLa cells. These polyribosomes, released by exposure to polynucleotides such as high molecular weight nuclear RNA or poly(U), do not appear to be cytoplasmic contaminants. Nuclear polyribosomes have a considerably lower buoyant density compared to cytoplasmic ones. Nuclear polyribosomes, in a cell-free system of protein synthesis, are six- to eight-fold less active compared to cytoplasmic ones and are insensitive to aurin tricarboxylic acid. They do not complement cytoplasmic polyribosomes in protein synthesis in the cell-free system. Finally, the number of proteins synthesized by nuclear polyribosomes is higher compared with that synthesized by the cytoplasmic ones. Only the virus-specific proteins, including P-VII, are synthesized by cytoplasmic polyribosomes. Nuclear polyribosomes, on the other hand, synthesize virusspecific proteins, including P-VII and VII, and a number of additional proteins not synthesized by the cytoplasmic ones.     

Nuclear protein kinase activities during the cell cycle of HeLa S3 cells

To ascertain the activity and substrate specificity of nuclear protein kinases during various stages of the cell cycle of HeLa S3 cells, a nuclear phospho-protein-enriched sample was extracted from synchronised cells and assayed in vitro in the presence of homologous substrates. The nuclear protein kinases increased in activity during S and G2 phase to a level that was twice that of kinases from early S phase cells. The activity was reduced during mitosis but increased again in G1 phase. When the phosphoproteins were separated into five fractions by cellulose-phosphate chromatography each fraction, though not homogenous, exhibited differences in activity. Variations in the activity of the protein kinase fractions were observed during the cell cycle, similar to those observed for the unfractionated kinases. Sodium dodecyl sulfate polyacrylamide gel electrophoretic analysis of the proteins phosphorylated by each of the five kinase fractions demonstrated a substrate specificity. The fractions also exhibited some cell cycle stage-specific preference for substrates; kinases from G1 cells phosphorylated mainly high molecular weight polypeptides, whereas lower molecular weight species were phosphorylated by kinases from the S, G2 and mitotic stages of the cell cycle. Inhibition of DNA and histone synthesis by cytosine arabinoside had no effect on the activity or substrate specificity of S phase kinases. Some kinase fractions phosphorylated histones as well as non-histone chromosomal proteins and this phosphorylation was also cell cycle stage dependent. The presence of histones in the in vitro assay influenced the ability of some fractions to phosphorylate particular non-histone polypeptides; non-histone proteins also appeared to affect the in vitro phosphorylation of histones.     

Adenosine 3',5'-monophosphate-dependent protein kinases of myocardial non-histone nuclear proteins.

Myocardial acidic non-histone nuclear proteins (NHPs) contain endogenous protein kinase activity. Phosphocellulose chromatography of purified NHPs identifies nine separate peaks of protein kinases which can phosphorylate both endogenous and exogenous substrates to a variable degree; endogenous NHPs are the best substrates. Cyclic AMP-stimulated protein kinase induced phosphorylation of endogenous and exogenous substrates; the extent of this stimulation varied according to the protein kinase fraction and substrate used. Cyclic AMP also enhanced NHP-induced stimulation of RNA polymerase activity. This enhancement was dependent on protein kinase-induced phosphorylation of NHPs since it was prevented by alkaline phosphatase pretreatment. It is concluded that nuclear protein kinases regulate myocardial RNA synthesis by enhancing phosphorylation of NHPs and that this regulation is under cyclic AMP control.     

Nuclear protein phosphorylation in isolated nuclei from HeLa cells. Evidence that 32P incorporation from [gamma-32P]GTP is catalyzed by nuclear kinase II

A nuclear system for studying nuclear protein phosphorylation is characterized, using as phosphate donor either low levels of [gamma-32P]GTP, low levels of [gamma-32P]ATP, or low levels of labeled ATP plus excess unlabeled GTP. Since nuclear casein kinase II is the only described nuclear protein kinase to use GTP with high affinity, low levels of GTP should specifically assay this enzyme. ATP should measure all kinases, and ATP plus unlabeled GTP should measure all kinases except nuclear casein kinase II (ATP-specific kinases). The results are consistent with these predictions. In contrast with the ATP-specific activity, endogenous phosphorylation with GTP was enhanced by 100 mM NaCl, inhibited by heparin and quercetin, stimulated by polyamines, and did not use exogenous histone as substrate. The GTP- and ATP-specific kinases phosphorylated different subsets of about 20 endogenous polypeptides each. Addition of purified casein kinase II enhanced the GTP-supported phosphorylation of the identical proteins that were phosphorylated by endogenous kinase. These results support the hypothesis that activity measured with GTP is catalyzed by nuclear casein kinase II, though other minor kinases which can use GTP are not ruled out. Preliminary observations with this system suggest that the major nuclear kinases exist in an inhibited state in nuclei, and that the effects of polyamines on nuclear casein kinase II activity are substrate specific. This nuclear system is used to determine if the C-proteins of hnRNP particles, previously shown to be substrates for nuclear casein kinase II in isolated particles, is phosphorylated by GTP in intact nuclei. The results demonstrate that the C-proteins are effectively phosphorylated by GTP, but in addition they are phosphorylated by ATP-specific kinase activity.     

Nuclear protein phosphorylation in isolated nuclei from HeLa cells. Evidence that 32P incorporation from [γ-32P]GTP is catalyzed by nuclear kinase II

A nuclear system for studying nuclear protein phosphorylation is characterized, using as phosphate donor either low levels of [γ-³²P]GTP, low levels of [γ-³²P]ATP, or low levels of labeled ATP plus excess unlabeled GTP. Since nuclear casein kinase II is the only described nuclear protein kinase to use GTP with high affinity, low levels of GTP should specifically assay this enzyme. ATP should measure all kinases, and ATP plus unlabeled GTP should measure all kinases except nuclear casein kinase II (ATP-specific kinases). The results are consistent with these predictions. In contrast with the ATP-specific activity, endogenous phosphorylation with GTP was enhanced by 100 mM NaCl, inhibited by heparin and quercetin, stimulated by polyamines, and did not use exogenous histone as substrate. The GTP- and ATP-specific kinases phosphorylated different subsets of about 20 endogenous polypeptides each. Addition of purified casein kinase II enhanced the GTP-supported phosphorylation of the identical proteins that were phosphorylated by endogenous kinase. These results support the hypothesis that activity measured with GTP is catalyzed by nuclear casein kinase II, though other minor kinases which can use GTP are not ruled out. Preliminary observations with this system suggest that the major nuclear kinases exist in an inhibited state in nuclei, and that the effects of polyamines on nuclear casein kinase II activity are substrate specific. This nuclear system is used to determine if the C-proteins of hnRNP particles, previously shown to be substrates for nuclear casein kinase II in isolated particles, is phosphorylated by GTP in intact nuclei. The results demonstrate that the C-proteins are effectively phosphorylated by GTP, but in addition they are phosphorylated by ATP-specific kinase activity.     

Phosphorylation Characteristics of Brain Clathrin-Coated Vesicle Endogenous Proteins

Clathrin-coated vesicles purified from bovine brain express protein kinase activity on two principal endogenous vesicle-associated substrates: a 50,000-Mr polypeptide (pp50) and clathrin-associated protein2 (CAP2; the faster-migrating clathrin light chain). Various exogenous substrates, e.g., casein, phosvitin, histone II, and histone III, also are phosphorylated. The pp50 protein kinase activity of clathrin-coated vesicles is not modulated by Ca2+, calmodulin, phosphatidylserine, or cyclic AMP. On the other hand, phosphorylation of the other endogenous substrates requires certain activators, including histone, polylysine, polyarginine, or polyethylenimine. Phosphate incorporation into pp50 was sensitive to divalent cations that inhibit sulfhydryl-dependent enzymes in the following order of potency: Zn2+ greater than Hg2+ greater than Cd2+, Cu2+, and Pb2+. Phosphate incorporation into CAP2 with polylysine present was insensitive to divalent cations. The alkylating agents dithiodinitrobenzene, phenacyl bromide, and N-ethylmaleimide inhibited phosphate incorporation into pp50 up to 90% without affecting incorporation into the other substrates. Vanadium pentoxide inhibited phosphorylation of CAP2 but had a minimal effect on pp50. CAP2 kinase activity was separated from the coated vesicle membrane and from dis-assembled clathrin triskelions, coeluting with the assembly polypeptide complex on a Sepharose 4B column. It retained phosphorylation properties similar to those of intact vesicles. These data imply that clathrin-coated vesicle kinases are elements of the coat proteins and may be involved in the assembly/disassembly of clathrin triskelions or interactions of coated vesicles with other cellular components.     

Protein kinase activity and substrates at the surface of intact HeLa cells

Evidence is presented for the location at the surface of HeLa cells of a protein kinase capable of phosphorylating surface as well as extracellular (foreign) proteins. The reaction products have been found to be proteins containing phosphoryl groups as monoesters of seryl and threonyl residues (but not of tyrosine). The enzyme is of the cyclic AMP-independent type, since neither cyclic AMP nor the heat- and acid-stable inhibitor protein (specific for cyclic AMP-dependent protein kinases) influenced its activity. Further, co-substrate ATP could in part be substituted by GTP, and the spectrum of proteins phosphorylated by the ecto-enzyme differed from that phosphorylated by cyclic AMP-dependent protein kinases. Evidence for the ecto-enzymic nature of this protein kinase includes (a) utilization of co-substrate and location of products at the surface of cells carefully controlled as being in an intact state and (b) phosphorylation of exogenous protein (phosvitin; specific serum proteins) by intact cells. Conclusive proof was gained by qualitative and quantitative comparative studies of phosphorylation in cultures with varying degrees of damaged cells either as a whole or after separation into groups of intact and damaged cells by electronic cell sorting. The results of experiments with cell sonicates excluded the possibility that either enzyme or substrates released from damaged cells were simply adsorbing to the cell surface.     

Topography of protein kinases and phosphoproteins in the plasma membrane of 3T3 cells

The plasma membrane of 3T3 cells contains at least two different endogenous cyclic AMP-dependent protein kinase systems. One catalyzes the phosphorylation of endogenous protein substrates, i.e., PP24 and PP14, whereas the other catalyzes the phosphorylation of exogenous substrates. In this paper the topography of these cyclic AMP-dependent phosphorylation systems is described. The results show that the kinases which phosphorylate only exogenous substrates are primarily localized to the outer plasma membrane surface whereas the endogenous cyclic AMP-dependent protein kinase and its two endogenous substrates are localized to the cytoplasmic plasma membrane surface. The data also establish that neither the cytoplasmically orientated kinase nor its substrates has a transmembrane orientation even though factors acting on the outer plasma membrane can affect these proteins. This suggests that functional modulation of the cytoplasmically localized cyclic AMP-dependent phosphorylation system can be mediated by a transmembrane regulatory mechanism. The importance of determining the topography of such plasma membrane phosphorylation systems is emphasized by recent studies which show that neoplastic transformation can be mediated at least in part by protein kinases and/or phosphoproteins which are localized on the cytoplasmic surface of the plasma membrane.     

Manifold effects of sodium butyrate on nuclear function. Selective and reversible inhibition of phosphorylation of histones H1 and H2A and impaired methylation of lysine and arginine residues in nuclear protein fractions

In addition to its known effect in suppressing the deacetylation of the nucleosomal core histones, sodium butyrate in the concentration range 0.5 to 15 mM causes a selective inhibition of [32P]phosphate incorporation into histones H1 and H2A of cultured HeLa S3 cells. No commensurate general inhibition of phosphorylation is seen in the non-histone nuclear proteins of butyrate-treated cells, but phosphorylation patterns are altered and 32P-uptake may be stimulated, as well as inhibited, depending upon the protein fraction analyzed. The degree of inhibition of histone phosphorylation in intact cells increases progressively as the butyrate concentration is raised from 0.5 to 15 mM. The effect is time-dependent and fully reversible. Butyrate has no effect on the kinetics of phosphate release from previously phosphorylated histones of cultured cells, nor does it significantly alter the rate of dephosphorylation of 32P-labeled histone H1 by endogenous phosphatases in vitro. Despite the suppression of [32P]phosphate incorporation into histones H1 and H2A of butyrate-treated cells, Na-butyrate does not inhibit the in vitro activities of either type I or type II cyclic AMP-dependent protein kinases, or the cAMP-independent H1 kinase associated with cell cycle progression. This suggests that the butyrate effect on histone phosphorylation in vivo is indirect and may involve an alteration in substrate accessibility or a modulation of systems affecting kinase activities. The poly(ADP)-ribosylation of HeLa histones is not inhibited by 5 mM Na-butyrate. Cells exposed to butyrate show an impaired methylation of lysine and arginine residues in their histones and nuclear hnRNP particles, respectively.     

The effects of thyroparathyroidectomy and 1,25 dihydroxyvitamin D3 on changes in the activities of some cytoplasmic and nuclear protein kinases during liver regeneration

Partial hepatectomy (HPX), which proliferatively activates the remaining liver cells, triggered two transient prereplicative surges in the total activities of cytoplasmic types I and II cyclic AMP-dependent protein kinase holoenzymes, and of nuclear catalytic subunits from cyclic AMP-dependent protein kinases. It also induced a transient prereplicative increase in the activities of a nuclear Ca2+-calmodulin-stimulable, protamine-phosphorylating protein kinase, and a nuclear poly(L-lysine)-phosphorylating, 105 kDa protein kinase. Thyroparathyroidectomy (TPTX) delayed and reduced the first surge and completely eliminated the second surge of both of the cytoplasmic cyclic AMP-dependent protein kinases, reduced the rises in the activity of nuclear catalytic subunits, and completely eliminated the surge of the Ca2+-calmodulin-stimulable protein kinase, but did not affect the surge of the nuclear 105 kDa protein kinase. The impairment of the responses of the two cyclic AMP-dependent protein kinases to HPX in TPTX rats was not accompanied by a rise in the level of heat-stable inhibitor of cyclic AMP-dependent protein kinase activity. One intraperitoneal injection of 1,25-dihydroxyvitamin D1 into TPTX rats immediately after HPX completely restored the post-HPX surges in the activity of type I cyclic AMP-dependent protein kinase, but the hormone, even in high doses, had little or not effect on the type II isoenzyme or the nuclear Ca2+-calmodulin-stimulable, protamine-phosphorylating enzyme.     

Cyclic AMP-stimulated protein kinases at brain synaptic junctions.

We have examined endogenous cyclic AMP-stimulated phosphorylation of subcellular fractions of rat brain enriched in synaptic plasma membranes (SPM), purified synaptic junctions (SJ), and postsynaptic densities (PSD). The analyses of these fractions are essential to provide direct evidence for cyclic AMP-dependent endogenous phosphorylation at discrete synaptic junctional loci. Protein kinase activity was measured in subcellular fractions using both endogenous and exogenous (histones) proteins as substrates. The SJ fraction possessed the highest kinase activity toward endogenous protein substrates, 5-fold greater than SPM and approximately 120-fold greater than PSD fractions. Although the kinase activity as measured with histones as substrates was only slightly higher in SJ than SPM fractions, there was a marked preference of kinase activity toward endogenous compared to exogenous substrates in SJ fractions but in SPM fractions. Although overall phosphorylation in SJ fractions was increased only 36% by 5 micron cyclic AMP, there were discrete proteins of Mr = 85,000, 82,000, 78,000, and 55,000 which incorporated 2- to 3-fold more radioactive phosphate in the presence of cyclic AMP. Most, if not all, of the cyclic AMP-independent kinase activity is probably catalyzed by catalytic subunit derived from cyclic AMP-dependent kinase, since the phosphorylation of both exogenous and endogenous proteins was greatly decreased in the presence of a heat-stable inhibitor protein prepared from the soluble fraction of rat brain. The specific retention of SJ protein kinase(s) activity during purification and their resistance to detergent solubilization was achieved by chemical treatments which produce interprotein cross-linking via disulfide bridges. Two SJ polypeptides of Mr = 55,000 and 49,000 were photoaffinity-labeled with [32P]8-N3-cyclic AMP and probably represent the regulatory subunits of the type I and II cyclic AMP-dependent protein kinases. The protein of Mr = 55,000 was phosphorylated in a cyclic AMP-stimulated manner suggesting autophosphorylation as previously observed in other systems.     

Cell adhesion-dependent differences in endogenous protein phosphorylation on the surface of various cell lines

Endogenous phosphorylation of intact cells was studied with four mouse, hamster and human cell lines using [gamma-32P]ATP and [gamma-32P]GTP as exogenous substrates. With all four cell lines distinct differences in the phosphoprotein patterns could be demonstrated for cells grown in suspension culture compared to cells grown in monolayers. Two major, apparently ubiquitous phosphoproteins with molecular weights of 135 000 (128 000 in HeLa cells) and 105 000, representing up to 60% of total phosphorylation, were phosphorylated only in cells grown in suspension. These phosphoproteins and the kinase(s) were located on the surface of the suspension cells. Evidence showed that phosphorylation was apparently not a true endogenous reaction, that rather it occurred by cell-cell collision, showing exponentially increasing 32P incorporation with increasing cell population density. Phosphorylation of pp135 and pp105 was established with ATP as well as with GTP and was not dependent on cyclic nucleotides cyclic AMP, cyclic GMP and cyclic CMP. The substrate-attached cells of all four cell lines have protein kinases on the cell surface. The lack of pp135 and pp105 phosphorylation may be due to the fact that these phosphoproteins are not expressed at all on the surface of substrate-attached cells or that these phosphoproteins are already fully phosphorylated.     

A cyclic GMP-dependent histone kinase bound to liver nucleoli

A method of steady-state electrophoresis in polyacrylamide gels was used to analyze the presence of cyclic nucleotide binding components in cell extracts. Multiple cyclic AMP and cyclic GMP binding components were detected in soluble cytoplasmic and nuclear extracts derived from avian liver, but only a single cyclic GMP binding protein was found in the 0.3 M NaCl extract of liver nucleoli. In the presence of cyclic GMP, this protein phosphorylated efficiently a calf thymus histone mixture and an endogenous nucleolar protein which migrated identically with histone H4 in sodium dodecyl sulfate polyacrylamide gel electrophoresis. The isoelectric point of the cyclic GMP-binding protein was 4.8. Addition of cyclic GMP did not influence the activity of the endogenous nucleolar RNA polymerase.     

Casein kinase II is a major protein phosphorylating activity in the nuclei of Xenopus laevis oocytes

The nuclei of Xenopus laevis oocytes contain kinases capable of phosphorylating endogenous and exogenous proteins using either ATP or GTP as phosphoryl donors. These enzymes are much more active with casein and phosvitin as substrates than with histones or protamines. The protein phosphorylating activity of oocyte nuclear extracts is not regulated by cyclic nucleotides, phorbol esters, calmodulin and calcium, or phospholipids. However, the casein phosphorylating activity can be greatly enhanced by the polyamines spermine or spermidine and drastically inhibited by heparin. Fractionation of the nuclear casein kinase activities by DEAE-Sephadex chromatography and glycerol gradient centrifugation indicate that the nuclei contain enzymes with the properties of casein kinases I and II as characterized in other species. Oocyte casein kinase I (Mr 37,000) is specific for ATP as phosphoryl donor, is only slightly inhibited by 10 micrograms/ml heparin, and is not significantly stimulated by polyamines. Casein kinase II (Mr 135,000) can use both ATP and GTP as substrates, and is very sensitive to heparin inhibition and polyamine stimulation. The fact that low concentrations of heparin (10 micrograms/ml) can inhibit a large percentage of the endogenous phosphorylation of nuclear extracts or of whole nuclei indicates that casein kinase II is probably the major protein phosphorylating activity of these oocyte organelles.     

Adenosine 3'':5''-cyclic monophosphate-dependent and plasma-membrane-associated protein kinase(s) from bovine corpus luteum.

Plasma-membrane fractions FI and FII isolated from bovine corpus luteum by discontinuous sucrose-density-gradient centrifugation, at sucrose-density interfaces of 1.14/1.16 and 1.16/1.18 respectively, contained membrane-associated protein kinases that phosphorylated both the structural proteins of membranes as well as exogenously added protein substrates. Both fractions were characterized with respect to endogenous and exogenous protein substrate specificity, pH-dependence, effect of bivalent metal ions and sensitivity toward cyclic nucleotides. These membrane-associated kinases showed an optimum pH of 6.0 and had an absolute requirement for bivalent metal ions such as Mg2+, Mn2+, or Co2+ that cannot be replaced by Ca2+. Both the activities were stimulated two- to four-fold by cyclic AMP in vitro with an apparent Km of 83 and 50 nM for fractions FI and FII respectively. Other cyclic 3':5'-nucleotides were effective only at higher concentrations, but even the most effective, cyclic IMP, showed a stimulation nearly an order of magnitude lower than that of cyclic AMP. In contrast, stimulation by cyclic dTMP and cyclic dAMP was very weak. Cyclic AMP showed no significant effect on the apparent Km value of both enzymes for histone and MgCl2 but it somewhat decreased the Km value for ATP. Nucleoside triphosphates like GTP, CTP and UTP inhibited the transfer of [32P]Pi from [gamma-32P]ATP into mixed histone catalysed by membrane-associated kinases either in the presence or in the absence of cyclic AMP. In addition to protein kinases, these membrane fractions also possessed cyclic AMP-binding activities. The apparent association constant (Kalpha) for cyclic AMP binding was 1.0 X 10(10) and 2.6 X 10(10) M for FI and FII membrane fractions respectively.