Vitamin E inhibits protein kinase C activity

Vitamin E (dl-alpha-tocopherol) has been found to inhibit in vitro brain protein kinase c with a half inhibitory concentration of 450 microM. The known plasma concentrations of vitamin E are one order of magnitude lower than the protein kinase c half-inhibitory concentration but it is also known that, at the membrane level where the active protein kinase c is located, the lipophilic vitamin E is more concentrated (Burton, G.W., Joyce, A. and Ingold, K.U. and Locke, S. (1983) Arch. Biochem. Biophys. 221, 281-290). It appears that vitamin E, in addition to its antioxidant function, may play a role in regulating the activity of protein kinase c.     

An NF-kappaB-specific inhibitor, IkappaBalpha, binds to and inhibits cyclin-dependent kinase 4

IkappaBalpha, a protein composed of six ankyrin repeats, is a specific inhibitor of nuclear factor kappaB (NF-kappaB) and functions in signal transductions in many different cell types. Using both in vivo yeast two-hybrid assays and in vitro activity and binding assays, we showed that IkappaBalpha binds to cyclin-dependent kinase 4 (CDK4) specifically and inhibits its kinase activity. The potencies of binding and inhibition of IkappaBalpha are comparable to those of INK4 proteins, the specific CDK4 inhibitors that also contain ankyrin repeats. Furthermore, we showed that INK4 proteins and IkappaBalpha compete with each other for binding to CDK4. These results led us to propose a hypothesis that there is cross talk between the NF-kappaB/IkappaBalpha pathway and the p16/CDK4/Rb pathway in cells, and that IkappaBalpha could substitute for the CDK4-inhibiting function of p16, a tumor suppressor frequently inactivated in human tumors. To further understand the structural basis of IkappaBalpha-CDK binding, we used different mutants of CDK4 to show that there are notable differences between IkappaBalpha and INK4 proteins in CDK4 binding since the binding is affected differently by different CDK4 mutations. We also demonstrated that the interaction of IkappaBalpha with CDK4 is different from that with its NF-kappaB. While most of the contacts contributing to NF-kappaB binding are located within the last two C-terminal ankyrin repeats and the loop region bridging them, the first four ankyrin repeats at the N-terminus are responsible for CDK4 binding and inhibition.     

Aminosalicylic acid inhibits IkappaB kinase alpha phosphorylation of IkappaBalpha in mouse intestinal epithelial cells

Tumor necrosis factor alpha (TNFalpha)-stimulated nuclear factor (NF) kappaB activation plays a key role in the pathogenesis of inflammatory bowel disease (IBD). Phosphorylation of NFkappaB inhibitory protein (IkappaB) leading to its degradation and NFkappaB activation, is regulated by the multimeric IkappaB kinase complex, including IKKalpha and IKKbeta. We recently reported that 5-aminosalicylic acid (5-ASA) inhibits TNFalpha-regulated IkappaB degradation and NFkappaB activation. To determine the mechanism of 5-ASA inhibition of IkappaB degradation, we studied young adult mouse colon (YAMC) cells by immunodetection and in vitro kinase assays. We show 5-ASA inhibits TNFalpha-stimulated phosphorylation of IkappaBalpha in intact YAMC cells. Phosphorylation of a glutathione S-transferase-IkappaBalpha fusion protein by cellular extracts or immunoprecipitated IKKalpha isolated from cells treated with TNFalpha is inhibited by 5-ASA. Recombinant IKKalpha and IKKbeta autophosphorylation and their phosphorylation of glutathione S-transferase-IkappaBalpha are inhibited by 5-ASA. However, IKKalpha serine phosphorylation by its upstream kinase in either intact cells or cellular extracts is not blocked by 5-ASA. Surprisingly, immunodepletion of cellular extracts suggests IKKalpha is predominantly responsible for IkappaBalpha phosphorylation in intestinal epithelial cells. In summary, 5-ASA inhibits TNFalpha-stimulated IKKalpha kinase activity toward IkappaBalpha in intestinal epithelial cells. These findings suggest a novel role for 5-ASA in the management of IBD by disrupting TNFalpha activation of NFkappaB.     

Propranolol, a phosphatidate phosphohydrolase inhibitor, also inhibits protein kinase C.

Propranolol, a beta-adrenergic receptor antagonist, also inhibits phosphatidate phosphohydrolase, the enzyme that converts phosphatidic acid into diacylglycerol. This latter effect has prompted recent use of propranolol in studies examining the importance of diacylglycerol and phosphatidic acid in cellular signalling events. Here, we show that propranolol is also an inhibitor of protein kinase C. At concentrations greater than or equal to 20 microM, propranolol reduced [3H]phorbol dibutyrate binding (IC50 = 200 microM) and phorbol myristate acetate-stimulated superoxide anion release (IC50 = 130 microM) in human neutrophils. Scatchard analysis showed that propranolol lowers the number of phorbol diester binding sites without significantly affecting their affinity. In vitro kinetic analysis, performed in a mixed micellar assay with protein kinase C purified from human neutrophils, suggested a competitive inhibition of propranolol with the cofactor phosphatidylserine. Complex kinetic patterns were observed with respect to diacylglycerol and ATP, approximating competitive and noncompetitive inhibition, respectively. Taken together, these results suggest that the drug interacts at the level of the regulatory domain of the enzyme. Fifty % inhibition occurred at approximately 150 microM propranolol. Similar levels of inhibition were obtained using exogenous (histone) and endogenous (p47-phox, a NADPH oxidase component) substrates. Protein kinase C-alpha and protein kinase C-beta, two protein kinase C isozymes present in human neutrophils, were inhibited by propranolol in a comparable manner. In the range of concentrations tested (30-1000 microM), neither cAMP-dependent protein kinase nor neutrophil protein tyrosine kinases were affected. The racemic form of propranolol and the (+) and the (-) stereoisomers were equally active, and other beta-adrenergic receptor antagonists (pindolol) and agonists (isoproterenol) were inactive. This suggests that the inhibitory action of propranolol on protein kinase C is related to the amphipathic nature of the drug rather than to its beta-adrenergic receptor blocking ability. Analogs of propranolol were synthesized and found to be more potent protein kinase C inhibitors, with IC50 values in the 10-20 microM range. We conclude that the ability of propranolol to inhibit both protein kinase C and PA phosphohydrolase complicates interpretation of results when this drug is used in signal transduction studies. In addition, propranolol may be a useful prototype for the synthesis of new protein kinase C inhibitors.     

Chelerythrine is a potent and specific inhibitor of protein kinase C

The benzophenanthridine alkaloid chelerythrine is a potent, selective antagonist of the Ca++/phospholopid-dependent protein kinase (Protein kinase C: PKC) from the rat brain. Half-maximal inhibition of the kinase occurs at 0.66 microM. Chelerythrine interacted with the catalytic domain of PKC, was a competitive inhibitor with respect to the phosphate acceptor (histone IIIS) (Ki = 0.7 microM) and a non-competitive inhibitor with respect to ATP. This effect was further evidenced by the fact that chelerythrine inhibited native PKC and its catalytic fragment identically and did not affect [3H]- phorbol 12,13 dibutyrate binding to PKC. Chelerythrine selectively inhibited PKC compared to tyrosine protein kinase, cAMP-dependent protein kinase and calcium/calmodulin-dependent protein kinase. The potent antitumoral activity of celerythrine measured in vitro might be due at least in part to inhibition of PKC and thus suggests that PKC may be a model for rational design of antitumor drugs.     

PTP1B inhibitor Ertiprotafib is also a potent inhibitor of IkappaB kinase beta (IKK-beta)

Ertiprotafib was developed as an inhibitor of PTP1B for the treatment of type 2 diabetes. It normalized the plasma glucose and insulin levels in diabetic animal models, and progressed to a phase II clinical trial. Multiple in vivo targets of Ertiprotafib, in addition to PTP1B inhibition, have been suggested. In this study, Ertiprotafib was also shown to be a potent inhibitor of IkappaB kinase beta (IKK-beta), with an IC(50) of 400nM.     

Neutrophil beta2-integrin upregulation is blocked by a p38 MAP kinase inhibitor

Tumor necrosis factor-alpha is known to upregulate the expression of surface adhesion molecules on polymorphonuclear leukocytes (PMNs). The purpose of this investigation was to study possible intracellular signaling pathways responsible for the upregulation of beta2 integrins on normal human PMNs induced by TNF. We report that treatment with TNF (10 ng/ml) for 30 min resulted in a significant increase in CD18 and MAC-1 surface expression (P < 0.001). In addition, pretreatment with 15 microM SB203580, a p38 MAP kinase inhibitor, for 10 min significantly inhibited TNF upregulation of CD18 and MAC-1 (P < 0.0001). Pretreatment with either 15 microM PD 98059, a p42/44 MAP kinase inhibitor, or 5 microM GO 6850, a protein kinase C inhibitor, had no significant inhibitory effect. These data suggest that the TNF-induced upregulation of beta2 integrins is mediated specifically through the p38 MAP kinase pathway and not through the p42/44 MAP kinase or protein kinase C pathways.     

Amino acid sequence of a 12-kDa inhibitor of protein kinase C

The complete primary structure of a bovine-brain-derived inhibitor of protein kinase C has been established. Fragments of the purified protein were obtained by cleavage with cyanogen bromide, Staphylococcus aureus V8 protease, trypsin and chymotrypsin. Subsequent analysis of the resulting fragments by fast-atom-bombardment mass spectrometry and Edman degradation revealed a calculated molecular mass of 11,779 Da with the following 107-amino-acid sequence: [sequence: see text] This inhibitor does not share significant primary structural identity with any other known protein.     

Sangivamycin, a nucleoside analogue, is a potent inhibitor of protein kinase C

Protein kinase C functions prominently in cell regulation via its pleiotropic role in signal transduction processes. Certain oncogene products resemble elements involved in transmembrane signaling, elevate cellular sn-1,2-diacylglycerol second messenger levels, and activate protein kinase C. Sangivamycin was unique among the nucleoside compounds tested in its ability to potently inhibit protein kinase C activity. Inhibition was competitive with respect to ATP for both protein kinase C and the catalytic fragment of protein kinase C prepared by trypsin digestion. Sangivamycin was a noncompetitive inhibitor with respect to histone and lipid cofactors (phosphatidylserine and diacylglycerol). Sangivamycin inhibited native protein kinase C and the catalytic fragment identically, with apparent Ki values of 11 and 15 microM, respectively. Sangivamycin was an effective an inhibitor of protein kinase C as H-7, an isoquinolinsulfonamide. Sangivamycin did not inhibit [3H]phorbol-12,13-dibutyrate binding to protein kinase C. Sangivamycin did not exert its action through the lipid binding/regulatory domain; inhibition was not affected by the presence of lipid or detergent. Unlike H-7, sangivamycin selectively inhibited protein kinase C compared to cAMP-dependent protein kinase. The discovery that protein kinase C is inhibited by sangivamycin and other antitumor agents suggests that protein kinase C may be a target for rational design of antitumor compounds.     

Amino acid sequence and characterization of a protein inhibitor of protein kinase C

The complete primary structure has been determined for an inhibitor protein of protein kinase C. The bovine brain-derived inhibitor has a pI of 6 and its N-terminal alanine residue is blocked by acetylation. Fragments obtained by chemical and enzymatic cleavage of the purified inhibitor were analyzed by Edman degradation, fast atom bombardment mass spectrometry, and tandem mass spectrometry. The results establish that the protein has a calculated average molecular mass of 13,690 daltons and contains 125 amino acid residues with the following sequence: (sequence: see text) The inhibitor does not show significant homology with any other known protein. Circular dichroism of the freshly prepared apoprotein indicated a secondary structural content of 23% alpha-helix, 31% beta-sheet, and 11% beta-turn. Immobilization on nitrocellulose followed by exposure to a 65Zn2(+)-containing overlay solution showed that, like protein kinase C itself, the inhibitor is a zinc-binding protein, although the sequence does not reveal a "zinc finger" structure. Competition with 10-fold molar excess Ca2+ or Mg2+ did not reduce the zinc-binding specificity of this inhibitor.     

The protein kinase C inhibitor, calphostin C, inhibits succinate-dependent mitochondrial reduction of MTT by a mechanism that does not involve protein kinase C.

The light-activated protein kinase C inhibitor, calphostin C, is shown to inhibit the ability of IL-3-dependent 32D cells to reduce the tetrazolium salt, MTT. To determine whether this inhibition was mediated through mitochondria which have been implicated in MTT reduction, isolated mitochondria were treated with calphostin C in the presence of various substrates for mitochondrial electron transport and EDTA (to exclude PKC involvement). Calphostin C extensively inhibited succinate-dependent MTT reduction (IC50 = 110nM) but had little effect on either NADH- or NADPH-dependent MTT reduction. An alternative protein kinase C inhibitor, H7, did not affect succinate-dependent mitochondrial MTT reduction, and the protein kinase A inhibitor, KT5720, had little effect on either cellular or mitochondrial MTT reduction. These results show that in addition to its role as a PKC inhibitor, calphostin C is also a potent inhibitor of succinate-dependent mitochondrial electron transport.     

The adriamycin-iron(III) complex is a potent inhibitor of protein kinase C

Using Triton X-100/lipid mixed micellar methods, we observed that the adriamycin-iron(III) complex was a potent inhibitor of protein kinase C while uncomplexed adriamycin itself was a poor inhibitor in the absence of heavy metal contaminants. The 3:1 adriamycin-iron complex was more potent than 2:1, 1:1, and 1:0 complexes. Inhibition of protein kinase C was reversible, and 50% inhibition occurred at 13 microM (adriamycin)3Fe3+. Both the catalytic and the regulatory domain of protein kinase C were affected by adriamycin-iron(III). Adriamycin-iron(III) was a competitive inhibitor of the catalytic domain of protein kinase C with respect to MgATP but not with respect to magnesium (IC50 350 microM). The predominant interaction of adriamycin-iron(III) with native protein kinase C was as a competitive inhibitor with respect to diacylglycerol. Inhibition was not competitive with respect to phosphatidylserine, calcium, magnesium, MgATP, or histone. Interaction with the regulatory domain was demonstrated by the ability of adriamycin-iron(III) to inhibit phorbol dibutyrate binding. Other adriamycin transitional metal complexes showed little inhibition of protein kinase C activity. Acetylation of the amine on the daunosamine moeity of adriamycin did not preclude the formation of a ferric complex but resulted in total loss of inhibitory activity. These results suggest that the presence of free amines in a highly structured adriamycin-iron complex is necessary for inhibition. The implications of inhibition of protein kinase C by adriamycin-iron(III) are discussed.     

The major endogenous bovine brain protein kinase C inhibitor is a heat-labile protein.

A crude cytosolic fraction prepared from bovine brain contained protein kinase C, as shown by immunoblotting, but its activity was undetectable, suggesting the presence of interfering factors. Phosphatase, ATPase and protease activities did not account for the absence of detectable protein kinase C activity. The major contributing factor was found to be a heat-labile protein which was separated from the kinase by ion-exchange chromatography. The contribution to the total inhibitory activity of heat-stable proteins was relatively minor, suggesting that they may not function physiologically as protein kinase C inhibitors.     

beta3-endonexin as a novel inhibitor of cyclin A-associated kinase

Cyclin A is indispensable for S phase cell cycle progression and is suggested to be a crucial target of cell adhesion signals. In this study, we demonstrate that beta3-endonexin, a molecule known to associate with the integrin beta3 cytoplasmic domain, specifically binds cyclin A. Deletion of the amino-terminal 52-amino-acid residues including the cyclin-binding RxL motif abolishes the ability of beta3-endonexin to interact with cyclin A. In an in vitro kinase assay, beta3-endonexin inhibits pRB kinase activity associated with cyclin A-Cdk2 while leaving its histone H1 kinase activity unaffected. Coexpression of beta3-endonexin in yeast cells overcomes growth suppression caused by an activation of cyclin A-associated kinase. Our results indicate that beta3-endonexin is a novel cyclin A-binding molecule that regulates cyclin A-associated pRB kinase activity.     

Butein, a tetrahydroxychalcone, inhibits nuclear factor (NF)-kappaB and NF-kappaB-regulated gene expression through direct inhibition of IkappaBalpha kinase beta on cysteine 179 residue

Although butein (3,4,2',4'-tetrahydroxychalcone) is known to exhibit anti-inflammatory, anti-cancer, and anti-fibrogenic activities, very little is known about its mechanism of action. Because numerous effects modulated by butein can be linked to interference with the NF-kappaB pathway, we investigated in detail the effect of this chalcone on NF-kappaB activity. As examined by DNA binding, we found that butein suppressed tumor necrosis factor (TNF)-induced NF-kappaB activation in a dose- and time-dependent manner; suppressed the NF-kappaB activation induced by various inflammatory agents and carcinogens; and inhibited the NF-kappaB reporter activity induced by TNFR1, TRADD, TRAF2, NIK, TAK1/TAB1, and IKK-beta. We also found that butein blocked the phosphorylation and degradation of IkappaBalpha by inhibiting IkappaBalpha kinase (IKK) activation. We found the inactivation of IKK by butein was direct and involved cysteine residue 179. This correlated with the suppression of phosphorylation and the nuclear translocation of p65. In this study, butein also inhibited the expression of the NF-kappaB-regulated gene products involved in anti-apoptosis (IAP2, Bcl-2, and Bcl-xL), proliferation (cyclin D1 and c-Myc), and invasion (COX-2 and MMP-9). Suppression of these gene products correlated with enhancement of the apoptosis induced by TNF and chemotherapeutic agents; and inhibition of cytokine-induced cellular invasion. Overall, our results indicated that antitumor and anti-inflammatory activities previously assigned to butein may be mediated in part through the direct inhibition of IKK, leading to the suppression of the NF-kappaB activation pathway.     

The bisindolylmaleimide GF 109203X is a potent and selective inhibitor of protein kinase C

Staurosporine is the most potent inhibitor of protein kinase C (PKC) described in the literature with a half-maximal inhibitory concentration (IC50) of 10 nM. Nevertheless, this natural product is poorly selective when assayed against other protein kinases. In order to obtain specific PKC inhibitors, a series of bisindolylmaleimides has been synthesized. Structure-activity relationship studies allowed the determination of the substructure responsible for conferring high potency and lack of selectivity in the staurosporine molecule. Several aminoalkyl bisindolylmaleimides were found to be potent and selective PKC inhibitors (IC50 values from 5 to 70 nM). Among these compounds GF 109203X has been chosen for further studies aiming at the characterization of this chemical family. GF 109203X was a competitive inhibitor with respect to ATP (Ki = 14 +/- 3 NM) and displayed high selectivity for PKC as compared to five different protein kinases. We further determined the potency and specificity of GF 109203X in two cellular models: human platelets and Swiss 3T3 fibroblasts. GF 109203X efficiently prevented PKC-mediated phosphorylations of an Mr = 47,000 protein in platelets and of an Mr = 80,000 protein in Swiss 3T3 cells. In contrast, in the same models, the PKC inhibitor failed to prevent PKC-independent phosphorylations. GF 109203X inhibited collagen- and alpha-thrombin-induced platelet aggregation as well as collagen-triggered ATP secretion. However, ADP-dependent reversible aggregation was not modified. In Swiss 3T3 fibroblasts, GF 109203X reversed the inhibition of epidermal growth factor binding induced by phorbol 12,13-dibutyrate and prevented [3H] thymidine incorporation into DNA, only when this was elicited by growth promoting agents which activate PKC. Our results illustrate the potential of GF 109203X as a tool for studying the involvement of PKC in signal transduction pathways.     

Cremophor EL, a widely used parenteral vehicle, is a potent inhibitor of protein kinase C

Cremophor EL, a castor oil derivative, has been considered a non-toxic solubilizer for lipophilic drugs and vitamins. Protein kinase C, a phospholipid/Ca++-dependent protein kinase, is known to phosphorylate, in response to extracellular stimuli, a variety of proteins for cellular functions. The present study shows that Cremophor EL selectively inhibits the activity of protein kinase C in vitro. The potency of this selective inhibition is greater than that of other protein kinase C-specific inhibitor thus far reported. Cremophor EL acts primarily on the enzyme activator diacylglycerol (or the phorbol ester) and prevents the latter from both interacting with the phospholipid and binding to protein kinase C. This is the first report of a significant biological activity induced by this widely used substituted castor oil solubilizer.