Modulation of cofactor requirement for the activation of protein kinase C by heparin. Possible effect at the regulatory domain

Heparin was found to stimulate the phosphorylation of histone H1 but not protamine sulfate catalyzed by Ca2+/phospholipid-dependent protein kinase (protein kinase C or PKC). The effect of heparin on histone H1 phosphorylation appeared to be due to an increase in phosphatidylserine affinity for PKC activation in the presence of heparin. This effect of heparin was abolished when trypsinized, cofactor-independent, PKC was employed to phosphorylate histone H1. These studies suggest that heparin acts at the regulatory domain of PKC, and emphasize the importance of the negative charge in influencing the accessibility of the substrate to PKC action.     

Effects of suramin, an anti-human immunodeficiency virus reverse transcriptase agent, on protein kinase C. Differential activation and inhibition of protein kinase C isozymes.

Suramin inhibited protein kinase C (PKC) type I-III activity in a concentration-dependent manner. Similar inhibitory effects were observed with M-kinase, the constitutively active catalytic fragment of PKC, and autophosphorylation of PKC types I-III. Kinetic experiments indicated that suramin competitively inhibits activity with respect to ATP (Ki = 17, 27, and 31 microM, respectively) and that it can also inhibit by interaction with the substrate histone III-S. With protamine as the Pi acceptor, suramin inhibition was dependent on lipid, being approximately 4-fold less sensitive to inhibition in the absence of phosphatidylserine and diacylglycerol than in their presence. Suramin at low concentrations (10-40 microM), in the presence of Ca2+ and absence of lipid, was able to stimulate kinase activity (approximately 200-400%) in a type-dependent manner and at higher concentrations inhibited activity with histone III-S as substrate. These results indicate that suramin, a hexa-anionic hydrophobic compound, can act as a negatively charged phospholipid analog in activating PKC in the presence of Ca2+ and absence of lipid and can inhibit Ca2+/phosphatidylserine/diacylglycerol-stimulated kinase activity at higher concentrations by competing with ATP or by interaction with the exogenous substrate. Suramin inhibited cAMP-dependent protein kinase much less potently (IC50 = 656 microM) than PKC. The ability of suramin to inhibit PKC-mediated processes in intact cells was tested using the phorbol ester-stimulated respiratory burst of neutrophils as a model system. The respiratory burst of human neutrophils, when preincubated with suramin and then stimulated with phorbol ester, was inhibited in a concentration-dependent manner, suggesting that suramin may also be able to inhibit PKC-mediated processes in intact cells.     

Stimulation of the ATPase activity of rat brain protein kinase C by phospho acceptor substrates of the enzyme

We recently reported that autophosphorylated rat brain protein kinase C (PKC) catalyzes a Ca2(+)- and phosphatidylserine- (PS-) dependent ATPase reaction. The Ca2(+)- and PS-dependent ATPase and histone kinase reactions of PKC each had a Km app(ATP) of 6 microM. Remarkably, the catalytic fragment of PKC lacked detectable ATPase activity. In this paper, we show that subsaturating concentrations of protein substrates accelerate the ATPase reaction catalyzed by PKC and that protein and peptide substrates of PKC induce ATPase catalysis by the catalytic fragment. At subsaturating concentrations, histone III-S and protamine sulfate each accelerated the ATPase activity of PKC in the presence of Ca2+ and PS by as much as 1.5-fold. At saturating concentrations, the protein substrates were inhibitory. Poly(L-lysine) failed to accelerate the ATPase activity, indicating that the acceleration observed with histone III-S and protamine sulfate was not simply a result of their gross physical properties. Furthermore, histone III-S induced the ATPase activity of the catalytic fragment of PKC, at both subsaturating and saturating histone concentrations. The induction of ATPase activity was also elicited by the peptide substrate Arg-Arg-Lys-Ala-Ser-Gly-Pro-Pro-Val, when the peptide was present at concentrations near its Km app. The induction of the ATPase activity by the nonapeptide provides strong evidence that the binding of phospho acceptor substrates to the active site of PKC can stimulate ATP hydrolysis. Taken together, our results indicate that PKC-catalyzed protein phosphorylation is inefficient, since it is accompanied by Pi production.(ABSTRACT TRUNCATED AT 250 WORDS)     

Differential stimulation of protein kinase C activity by phorbol ester or calcium/phosphatidylserine in vitro and in intact synaptosomes.

Activation of protein kinase C (PKC) by phorbol 12-myristate 13-acetate (PMA) was compared with calcium/phosphatidylserine (Ca/PS). The substrate specificity of PKC was more limited with PS/PMA. Substrates could be divided into three overlapping groups according to their relative level of phosphorylation: C1, relatively preferred substrates with Ca/PS, included dephosphin, histone, and peptide GS1-10. C2, relatively preferred with PS/PMA, included myelin basic protein and MARCKS. C3, substrates independent of activators. PS/PMA altered the Vmax of PKC for substrate, and decreased the Km for Mg2+. Differential substrate phosphorylation by PS/PMA also occurred for PKC isozymes resolved by hydroxylapatite chromatography and was most dramatic for PKC-alpha, which could no longer phosphorylate histone or GS1-12. Differential activities of PKC were also observed in synaptosol and in intact synaptosomes where PMA stimulated phosphorylation of MARCKS, but not dephosphin. It was further shown that dephosphin was indeed a substrate of PKC in the intact synaptosomes by use of a repolarization-dependent dephosphin phosphorylation assay. The differential PKC activities could also be distinguished by inhibitors. H-7 was equipotent, palmitoylcarnitine did not inhibit in vitro C2 phosphorylation, but inhibited dephosphin in intact synaptosomes, and sphingosine did not inhibit C1 substrates and was without effect on dephosphin in intact synaptosomes. Therefore PS/PMA alters or limits the substrate specificity of PKC, leading to a differential substrate phosphorylation in vitro and in intact synaptosomes and differential inhibitor sensitivity. The pattern of protein phosphorylation observed after PKC activation in intact cells will therefore be dependent upon the activator.     

Requirement of protein association with membranes for phosphorylation by protein kinase C.

To clarify the requirement of the association of substrate proteins with phospholipid membranes for phosphorylation by protein kinase C (PKC), we studied the relationship between membrane association of PKC-substrate proteins and their phosphorylation by PKC. In the presence of phosphatidylserine, 12-O-tetradecanoylphorbol-13-acetate induced PKC autophosphorylation in either the presence or the absence of Ca2+, and this phosphorylation was not inhibited by increasing salt concentration (up to 200 mM NaCl). Thus, Ca2+ and ionic strength did not markedly affect the enzymatic activity of PKC. Annexin I required Ca2+ for both its association with phospholipid membranes and phosphorylation by PKC, whereas histone and monomyristilated lysozyme (C14:0-lysozyme) did not. This result indicates that the membrane association of substrates closely correlates with their phosphorylation by PKC. Similar correlation was also observed in the effects of ionic strength on the membrane association of the substrates and their phosphorylation by PKC; increased ionic strength (200 mM NaCl) remarkably inhibited both the membrane association and the phosphorylation of histone and annexin I by PKC but C14:0-lysozyme was not markedly affected. These results suggest that the membrane association of PKC-substrate proteins is a prerequisite for their phosphorylation by PKC. This concept further conforms to the mechanisms of PKC inhibitors; some types of PKC inhibitors are mediated all or in part through inhibition of the substrate-membrane interaction.     

Characterization of endogenous substrates for novel-type protein kinase C as well as conventional-type protein kinase C in primary cultured mouse epidermal cells

In primary cultured mouse epidermal cells, phorbol 12-myristate 13-acetate (PMA), which activates protein kinase C (PKC), induced changes in the phosphorylation levels of 10 proteins, termed KP-1 to 10, in two-dimensional PAGE. Seven of these proteins were phosphorylated and three were dephosphorylated. Similar changes were induced by other PKC activators, but not by inactive phorbol ester. Among these substrate proteins, phosphorylation of three proteins, i.e. KP-1 (pI 4.7/23,000 M_r), KP-2 (pI 4.7/20,700 M_r) and KP-10 (pI 4.7/25,000 M_r was markedly enhanced by PMA and inhibited by a potent PKC inhibitor staurosporine. In vitro phosphorylation studies and phosphoamino acid analysis, using these proteins as substrate and PKC preparations obtained from epidermal cell lysate, revealed that KP-1 and -2 were directly phosphorylated by Ca²⁺-, phospholipid-dependent protein kinase (conventional-type PKC; cPKC), but not by Ca²⁺-independent, phospholipid-dependent protein kinase (novel-type PKC; nPKC). On the other hand, KP-10 was mainly phosphorylated by nPKC in intact epidermal cells. These results indicate that cPKC and nPKC in epidermal cells have different substrate specificity for endogenous proteins and may induce different signal transduction.     

Inhibition of protein kinase C by annexin V.

Annexin V is a protein of unknown biological function that undergoes Ca(2+)-dependent binding to phospholipids located on the cytosolic face of the plasma membrane. Preliminary results presented herein suggest that a biological function of annexin V is the inhibition of protein kinase C (PKC). In vitro assays showed that annexin V was a specific high-affinity inhibitor of PKC-mediated phosphorylation of annexin I and myosin light chain kinase substrates, with half-maximal inhibition occurring at approximately 0.4 microM. Annexin V did not inhibit epidermal growth factor receptor/kinase phosphorylation of annexin I or cAMP-dependent protein kinase phosphorylation of the Kemptide peptide substrate. Since annexin V purified from both human placenta and recombinant bacteria inhibited protein kinase C activity, it is not likely that the inhibitor activity was associated with a minor contaminant of the preparations. The following results indicated that the mechanism of inhibition did not involve annexin V sequestration of phospholipid that was required for protein kinase C activation: similar inhibition curves were observed as phospholipid concentration was varied from 0 to 800 micrograms/mL; the extent of inhibition was not significantly affected by the order of addition of phospholipid, substrate, or PKC, and the core domain of annexin I was not a high-affinity inhibitor of PKC even though it had similar Ca2+ and phospholipid binding properties as annexin V. These data indirectly indicate that inhibition occurred by direct interaction between annexin V and PKC. Since the concentration of annexin V in many cell types exceeds the amounts required to achieve PKC inhibition in vitro, it is possible that annexin V inhibits PKC in a biologically significant manner in intact cells.     

Phosphoinositide-dependent protein kinase-1 (PDK1)-independent activation of the protein kinase C substrate, protein kinase D

Phosphoinoisitide dependent kinase l (PDK1) is proposed to phosphorylate a key threonine residue within the catalytic domain of the protein kinase C (PKC) superfamily that controls the stability and catalytic competence of these kinases. Hence, in PDK1-null embryonic stem cells intracellular levels of PKCalpha, PKCbeta1, PKCgamma, and PKCepsilon are strikingly reduced. Although PDK1-null cells have reduced endogenous PKC levels they are not completely devoid of PKCs and the integrity of downstream PKC effector pathways in the absence of PDK1 has not been determined. In the present report, the PDK1 requirement for controlling the phosphorylation and activity of a well characterised substrate for PKCs, the serine kinase protein kinase D, has been examined. The data show that in embryonic stem cells and thymocytes loss of PDK1 does not prevent PKC-mediated phosphorylation and activation of protein kinase D. These results reveal that loss of PDK1 does not functionally inactivate all PKC-mediated signal transduction.     

Substrate-dependent inhibition of protein kinase C by specific inhibitors

Protein kinase C (PKC) and its proteolysis-derived protein kinase independent of Ca2+ and phospholipids (PKM), were purified from rat brain. By using histone H1 and protamine as substrates, we assayed the effect of several inhibitors of PKC and PKM. The inhibition turned out to be dependent on both the nature of the kinase and the type of substrate assayed. These results may help to interpret the different responses elicited by PKC inhibitors in vivo.     

Halothane enhances the phosphorylation of H1 histone and rat brain cytoplasmic proteins by protein kinase C

The effect of halothane, a typical volatile anesthetic, on the calcium- and phospholipid-dependent protein kinase (PKC), which is one of the key enzymes of membrane signal transduction, was examined. PKC was partially purified from the cerebral tissue of male Wistar rats. Halothane increased PKC-mediated phosphorylation of calf thymus H1 histone in the presence or absence of phorbol ester or diolein, and also increased phosphorylation of the rat brain cytosolic proteins (47 kDa and 80 kDa). A similar but slight increase in H1 histone phosphorylation was observed with isoflurane and enflurane, less lipid soluble volatile anesthetics. These findings suggest that halothane may increase PKC-mediated phosphorylation by the modification of phospholipid membrane and affect membrane signal transduction of the nerve cell under the anesthetic state.     

Calmodulin and acidic compounds alter basic protein phosphorylation by the protein kinase from human platelets

A cyclic nucleotide-independent protein kinase of human platelets, which phosphorylated histones, myelin basic protein and protamine and did not catalyze the phosphorylation of acidic proteins such as casein, phosvitin and myosin light chain, has been purified approx. 1,500-fold from the crude extract by steps of DEAE-cellulose, Sephadex G-200, hydroxylapatite and phosphoryl cellulose column chromatography. The substrate phosphorylation by this kinase was markedly enhanced by calmodulin even in the absence of Ca²⁺, when mixed histone was used as a substrate. The interaction of the kinase with mixed histone resulted in an irreversible inactivation of the enzyme. Calmodulin prevented this inactivation, and this compound produced an apparent increase in histone phosphorylation by the kinase. It should be noted that acidic polypeptides such as troponin-C, phospholipids and nucleic acids have a similar ability. The addition of Ca²⁺ reduced the effect of calmodulin more than the effects of other acidic compounds.     

Independent modulation of hepatic protein kinase activities.

The effects of hormonal status on protein kinase activity was examined in homogenates of rat liver. Protein kinase activity was evaluated from incorporation of 32P from [gamma-32P]ATP into protamine or histone as receptor substrates. Protamine phosphorylation in the presence or absence of cyclic AMP exceeded histone phosphorylation by at least a factor or two. Hypophysectomy markedly increased protamine phosphorylation in the presence or absence of saturating amounts of cyclic AMP. In contrast, hypophysectomy only slightly increased cyclic AMP independent phosphorylation of histone. These results could not be amounted for by differences in ATPase or protein phosphase activities. Cortisone (2 mg/day x 3) decreased total protein kinase activity in livers of hypophysectomized rats when protamine was substrate, but had no effect on the total activity toward histone. Growth hormone (100 mug/day x 3) significantly increased histone, but not protamine phosphorylation in livers of hypophysectomized rats. Administration of 5 mug of triiodothyonine/day to hypophysectomized rats also markedly increased the phosphorylation of histone, but not protamine when saturating amounts of cyclic AMP were present. These results support the hypothesis that liver may contain more than one type of protein kinase activity and that the different protein kinase activities can be separately affected by hormones. Such control distal to cyclic AMP might allow selective modulation of cyclic AMP-dependent processes in cells which carry out more than one such process.     

Unsaturated fatty acid-activated protein kinase (PKx) from goat testis cytosol.

The cytosolic fraction of goat cauda epididymis possesses a protein kinase (PKx) activity which is stimulated by a number of unsaturated fatty acids of which arachidonic acid is the best activator in absence of cAMP or Ca(2+). Phosphatidylcholine, phosphatidylethanolamine, phosphatidylserine and diacylglycerol have no effect either alone or in combination. The membrane fraction does not show any appreciable kinase activity even after detergent treatment. PKx migrates as a single band of apparent molecular mass of 116 kDa on 10% SDS-PAGE after sequential chromatographic separation on DEAE-cellulose, phenyl-Sepharose, high-Q anion exchange and protamine-agarose affinity column. PKx phosphorylates histone H1, histone IIIs and protamine sulfate, but not casein. However, the best phosphorylation was obtained with a substrate based on PKC pseudosubstrate sequence (RFARKGSLRQKNV). The kinase phosphorylates two endogenous cytosolic proteins of 60 and 68 kDa. Ser residues are primarily phosphorylated although a low level of phosphorylation is observed on Thr residues also. Ca(2+) and Mn(2+) inhibit PKx activity in the micromolar range. Staurosporine is found to inhibit the PKx activity to a significant level at sub-nanomolar concentration. Lyso-phosphatidylcholine and certain detergents at very low concentrations (<0.05%) stimulate enzyme activity to some extent. The immuno-crossreactivity study with antibody against different PKC isotypes suggests that the protein kinase under study is not related to any known PKC family. Even the antibody against PKN (a related protein kinase reported in rat testis found to be activated by arachidonic acid) does not cross-react with this protein kinase. Hence we believe that the protein kinase (PKx) reported here is different even from the PKN of rat testis. The phosphorylation of endogenous proteins by the protein kinase may be involved in cell regulation including fertility regulation and signal transduction.     

Dissociation of protein kinase C redistribution from the phosphorylation of its substrates

Increases in cytoplasmic [Ca2+] caused by receptor activation are thought to stimulate the redistribution of loosely associated protein kinase C (PKC) to a tightly membrane-bound form that is activated by diacylglycerol. The precise role of Ca2(+)-dependent redistribution of PKC in the activation of this enzyme has not been critically assessed. We examined the relationship between PKC redistribution and substrate phosphorylation by comparing the kinetics and the Ca2+ dependence of the two events. Using immunoblotting with specific PKC antibodies, we find that 1321N1 cells express the alpha form of PKC, approximately 10-20% of which is membrane-associated in unstimulated cells. This fraction is increased to 60% in response to muscarinic receptor stimulation. Agonist-induced redistribution of PKC is rapid and transient, peaking at 30 s and returning to control levels by 2-5 min. Stimulation of muscarinic receptors also rapidly increases phosphorylation of both an endogenous 80-kDa protein and the peptide substrate, VRKRTLRRL. However, unlike the time course of PKC redistribution, PKC-mediated phosphorylation of these substrates is sustained for up to 30 min. To compare the Ca2+ dependence of PKC redistribution and substrate phosphorylation, we buffered muscarinic receptor-induced increases in cytoplasmic [Ca2+] with the divalent cation chelator 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid. Under these conditions, redistribution of PKC and phosphorylation of the exogenous peptide substrate are inhibited by about 80%. In contrast, muscarinic receptor-stimulated phosphorylation of the 80-kDa protein occurs even when increases in cytoplasmic [Ca2+] are prevented. Taken together, these data demonstrate that the redistribution of PKC does not correlate in extent or duration with phosphorylation of PKC substrates.     

Independent modulation of hepatic protein kinase activities

The effects of hormonal status on protein kinase activity was examined in homogenates of rat liver. Protein kinase activity was evaluated from incorporation of ³²P from [γ-³²P]ATP into protamine or histone as receptor substrates. Protamine phosphorylation in the presence or absence of cyclic AMP exceeded histone phosphorylation by at least a factor or two. Hypophysectomy markedly increased protamine phosphorylation in the presence or absence of saturating amounts of cyclic AMP. In contrast, hypophysectomy only slightly increased cyclic AMP independent phosphorylation of histone. These results could not be accounted for by differences in ATPase or protein phosphase activities. Cortisone (2 mg/day × 3) decreased total protein kinase activity in livers of hypophysectomized rats when protamine was substrate, but had no effect on the total activity toward histone. Growth hormone (100 μg/day × 3) significantly increased histone, but not protamine phosphorylation in livers of hypophysectomized rats. Administration of 5 μg of triiodothyronine/day to hypophysectomized rats also markedly increased the phosphorylation of histone, but not protamine when saturating amounts of cyclic AMP were present. These results support the hypothesis that liver may contain more than one type of protein kinase activity and that the different protein kinase activities can be separately affected by hormones. Such control distal to cyclic AMP might allow selective modulation of cyclic AMP-dependent processes in cells which carry out more than one such process.     

Immunological identification of protein kinase C-alpha and protein kinase C-delta in cultured rat mesangial cells: differential sensitivity of the two isoforms towards the protein kinase inhibitor H7.

Rat mesangial cells contain both calcium-dependent protein kinase C (PKC) activity, which phosphorylates histone H1 and endogenous proteins, and calcium-independent, phospholipid-dependent PKC activity, which phosphorylates only endogenous proteins. The calcium-dependent PKC was identified as PKC alpha by immunoblot analysis and hydroxyapatite chromatography (HPLC). The calcium-insensitive, phospholipid-dependent isoform was identified as PKC delta using similar techniques. The inhibition of these two PKC isoforms by the protein kinase inhibitor H7 [1-(iso-quinolinyl sulphonyl)-2-methyl piperazine] was examined using both histone H1 and endogenous proteins as substrates. Phosphorylations catalyzed by the calcium-dependent PKC isoform alpha were almost 90% inhibited when histone H1 was used, and only 55% when endogenous proteins were the substrate. In contrast, the phosphorylation of endogenous proteins catalysed by the calcium-insensitive, phospholipid-dependent PKC delta was not significantly affected by the inhibitor.     

Resveratrol preferentially inhibits protein kinase C-catalyzed phosphorylation of a cofactor-independent, arginine-rich protein substrate by a novel mechanism.

Resveratrol, a polyphenolic natural product abundantly present in grape skins, is a candidate cancer chemopreventive agent that antagonizes each stage of carcinogenesis and inhibits protein kinase C (PKC), a key mediator of tumor promotion. While resveratrol has been shown to antagonize both isolated and cellular forms of PKC, the weak inhibitory potency observed against isolated PKC cannot account for the reported efficacy of the polyphenol against PKC in cells. In this report, we analyze the mechanism of PKC inhibition by resveratrol. Our results indicate that resveratrol has a broad range of inhibitory potencies against purified PKC that depend on the nature of the substrate and the cofactor dependence of the phosphotransferase reaction. Resveratrol weakly inhibited the Ca2+/phosphatidylserine-stimulated activity of a purified rat brain PKC isozyme mixture (IC(50) = 90 microM) by competition with ATP (K(i) = 55 microM). Consistent with the kinetic evidence for a catalytic domain-directed mechanism, resveratrol inhibited the lipid-dependent activity of PKC isozymes with divergent regulatory domains similarly, and it was even more effective in inhibiting a cofactor-independent catalytic domain fragment (CDF) of PKC generated by limited proteolysis. This suggested that regulatory features of PKC might impede resveratrol inhibition of the enzyme. To explore this, we examined the effects of resveratrol on PKC-catalyzed phosphorylation of the cofactor-independent substrate protamine sulfate, which is a polybasic protein that activates PKC by a novel mechanism. Resveratrol potently inhibited protamine sulfate phosphorylation (IC(50) = 10 microM) by a mechanism that entailed antagonism of the activation of PKC by protamine sulfate and did not involve competition with either substrate. On the basis of the presence of PKC isozymes at subcellular sites rich in polybasic proteins, it has been proposed that certain endogenous polybasic PKC substrates may activate PKC in cells by the same mechanism as protamine sulfate. Our results suggest that antagonism by resveratrol of the phosphorylation of cellular PKC substrates that resemble protamine sulfate in their interactions with PKC may contribute to the efficacy of resveratrol against PKC in cells.     

Effect of poly-basic amino acids on the phosphorylation of various substrate proteins by cytosolic protein-tyrosine kinase from porcine spleen

Cytosolic protein-tyrosine kinase from porcine spleen (CPTK-40) is strongly activated by poly-L-lysine using bovine serum albumin, ovalbumin, phosphorylase b, calmodulin and H1 histone as substrate proteins. However, this polyamine inhibited the enzyme activities when myelin basic protein, tubulin and H2B histone were used as substrate proteins. These stimulatory and inhibitory effects on CPTK-40 are not specific for polylysine, but polyarginine and polyornithine have similar effects on this phosphorylation reaction. Effect of poly-basic amino acids on CPTK-40 seems to be mainly on the substrate proteins, rather than on the enzyme itself.     

Chronic ethanol exposure increases levels of protein kinase C delta and epsilon and protein kinase C-mediated phosphorylation in cultured neural cells.

Exposure to ethanol for several days increases the number and function of dihydropyridine-sensitive Ca2+ channels in excitable tissues. In the neural cell line PC12, this process is blocked by inhibitors of protein kinase C (PKC), suggesting that PKC mediates ethanol-induced increases in Ca2+ channels. We report that treatment with 25-200 mM ethanol for 2-8 days increased PKC activity in PC12 cells and NG108-15 neuroblastoma-glioma cells. Detailed studies in PC12 cells showed that ethanol also increased phorbol ester binding and immunoreactivity to PKC delta and PKC epsilon. These changes were associated with increased PKC-mediated phosphorylation. Ethanol did not activate the enzyme directly, nor did ethanol increase levels of diacylglycerol. Ethanol-induced increases in PKC levels may promote up-regulation of Ca2+ channels, and may also regulate the expression and function of other proteins involved in cellular adaptation to ethanol.