Inhibition of protein kinase C from polymorphonuclear neutrophils by long chain acyl coenzyme A and counteraction by Mg-ATP

Signalling functions of coenzyme A and its derivatives in mammalian cells

In all living organisms, CoA (coenzyme A) is synthesized in a highly conserved process that requires pantothenic acid (vitamin B5), cysteine and ATP. CoA is uniquely designed to function as an acyl group carrier and a carbonyl-activating group in diverse biochemical reactions. The role of CoA and its thioester derivatives, including acetyl-CoA, malonyl-CoA and HMG-CoA (3-hydroxy-3-methylglutaryl-CoA), in the regulation of cellular metabolism has been extensively studied and documented. The main purpose of the present review is to summarize current knowledge on extracellular and intracellular signalling functions of CoA/CoA thioesters and to speculate on future developments in this area of research.

Mechanism of Free Fatty Acid Effects on Hepatocyte Insulin Receptor Binding and Processing

We determined whether the palmitate effects on hepatocyte insulin receptor binding and post-receptor trafficking were mediated by accelerated mitochondrial beta-oxidation or accumulation of intracellular fatty acyl-CoA derivatives and possibly protein acylation. Preincubation of hepatocytes with moderate concentrations of palmitate (0.5 mM) resulted in a 23% decline in cell-surface binding and proportional decreases in receptor-mediated insulin internalization and degradation. Brief pretreatment of hepatocytes with the carnitine palmityltransferase-I inhibitor, methyl palmoxirate (MP), prevented 70% of the palmitate effects. At higher palmitate concentrations (2.0 mM), cell-surface binding was reduced by 34%, whereas internalization of the receptor complex was reduced by 78%. These effects were only partially prevented by MP pretreatment. Receptor-mediated insulin degradation increased by 34% and was uninfluenced by MP pretreatment. Octanoate, which is rapidly shunted into mitochondrial oxidation, produced a dose-dependent reduction in insulin binding, with proportional decreases in internalization and degradation. Similarly preincubation with 2.0 mM oleate, which, unlike palmitate, is not known to produce protein acylation, resulted in proportional decreases in insulin receptor binding and receptor-mediated internalization and degradation. High concentrations of octanoate or oleate (2.0 mM) did not reproduce the additive post-receptor effects of palmitate. We conclude that the receptor and post-receptor effects of moderate palmitate concentrations are closely linked to accelerated fatty acid oxidation. The post-receptor effects observed at higher concentrations involve other mechanisms, possibly relating to intracellular levels of palmityl-CoA derivatives.

Effect of fatty acids and their acyl-CoA esters on protein kinase C activity in fibroblasts: possible implications in fatty acid oxidation defects

We studied the effect of fatty acids and their acyl-CoA esters on protein kinase C (PK-C) activity in human skin fibroblasts. Butyrate, octanoate, palmitate and oleate did not alter PK-C activity in either cytosolic or particulate fraction. In the presence of calcium, phosphatidylserine and diacylglycerol, both palmitoyl-CoA (Pal-CoA) and oleoyl-CoA (Ole-CoA) enhanced particulate PK-C activity by approx. 70% and octanoyl-CoA (Oct-CoA) by approx. 35%. Partially purified cytosolic PK-C activity was enhanced by 60-70% by 13.5 microM of either Pal-CoA or Ole-CoA. Basal histone phosphorylation (i.e., PK-C-independent phosphorylation) was decreased in the particulate fraction in the presence of these esters in a concentration-dependent manner. Both Pal-CoA and Ole-CoA fully substituted diacylglycerol in activating the kinase in both the cytosolic and particulate fractions, whereas Oct-CoA had a moderate effect. The pattern of endogenous cytosolic and particulate protein phosphorylation was altered in the presence of either Pal-CoA or Ole-CoA. We conclude that long-chain fatty acyl-CoA esters may activate PK-C in non-stimulated fibroblasts, i.e., in the absence of physiological diacylglycerol formation. Activation of PK-C in stimulated fibroblasts, i.e., in the presence of an elevated diacylglycerol concentration, is less pronounced. These results support the hypothesis that activation of PK-C and alteration of endogenous protein phosphorylation may play a role in the pathogenesis of diseases in which there is intracellular accumulation of fatty acyl-CoA esters, such as in inborn fatty-acid oxidation defects.

Exogenous arachidonic acid inactivates protein kinase C in mouse pancreatic islets

The effect of arachidonic acid on protein kinase C activity and insulin secretion in mouse islets was investigated. Arachidonic acid stimulated protein kinase C activity in islet cytosol and membrane fractions by substituting for phosphatidylserine. Stimulation by arachidonic acid was dependent on either Ca2+ or the phorbol ester 12-O-tetradecanoylphorbol 13-acetate, was potentiated by the combined addition of Ca(2+) + 12-O-tetradecanoylphorbol 13-acetate, and did not further increase protein kinase C activity in the presence of saturating concentrations of phosphatidylserine. Arachidonic acid stimulation of protein kinase C was prevented by binding of arachidonic acid to albumin. In the absence of extracellular Ca2+, exogenous arachidonic acid stimulated insulin secretion. Arachidonic acid-induced insulin secretion was not potentiated by 12-O-tetradecanoylphorbol 13-acetate and was not prevented by the protein kinase C inhibitor staurosporine, suggesting that arachidonic acid-induced insulin secretion may occur independently of protein kinase C activation. Arachidonic acid-induced insulin secretion in Ca(2+)-free medium was on the other hand potentiated by addition of extracellular Ca2+. Stimulation of insulin secretion by exogenous arachidonic acid was associated with inactivation of protein kinase C. Inactivation of protein kinase C was also observed in islet homogenate after pre-incubation with arachidonic acid. Arachidonic acid-induced protein kinase C inactivation in islet homogenate was prevented by albumin or MgATP. Inactivation by arachidonic acid in intact islets was, however, not produced during enzyme isolation and was not prevented by inclusion of albumin or MgATP during preparation of protein kinase C extracts.(ABSTRACT TRUNCATED AT 250 WORDS)

A fast and versatile method for extraction and quantitation of long-chain acyl-CoA esters from tissue: content of individual long-chain acyl-CoA esters in various tissues from fed rat

A method for the extraction of acyl-CoA esters from tissue, and their subsequent analysis by HPLC is described. The lipids are removed by a two-phase extraction in a chloroform/methanol/water system. The long-chain acyl-CoA esters are extracted using methanol and a high salt concentration (2 M ammonium acetate). Reextraction of the dry residue after evaporation of extraction solvent results in low overall recoveries (20%). By adding 1 mg/ml acyl-CoA-binding protein to the extraction solvent the overall recovery was increased to 55%. The method is easy and fast to perform and is thereby suitable for analysis of a large number of samples. The advantages of the method over previously published methods are discussed.

Phorbol ester-induced actin assembly in neutrophils: role of protein kinase C

The shape changes and membrane ruffling that accompany neutrophil activation are dependent on the assembly and reorganization of the actin cytoskeleton, the molecular basis of which remains to be clarified. A role of protein kinase C (PKC) has been postulated because neutrophil activation, with the attendant shape and membrane ruffling changes, can be initiated by phorbol esters, known activators of PKC. It has become apparent, however, that multiple isoforms of PKC with differing substrate specificities exist. To reassess the role of PKC in cytoskeletal reorganization, we compared the effects of diacylglycerol analogs and of PKC antagonists on kinase activity and on actin assembly in human neutrophils. Ruffling of the plasma membrane was assessed by scanning EM, and spatial redistribution of filamentous (F)-actin was assessed by scanning confocal microscopy. Staining with NBD-phallacidin and incorporation of actin into the Triton X-100-insoluble ("cytoskeletal") fraction were used to quantify the formation of (F)- actin. [32P]ATP was used to detect protein phosphorylation in electroporated cells. Exposure of neutrophils to 4 beta-PMA (an activator of PKC) induced protein phosphorylation, membrane ruffling, and assembly and reorganization of the actin cytoskeleton, whereas the 4a-isomer, which is inactive towards PKC, failed to produce any of these changes. Moreover, 1,2-dioctanoylglycerol, mezerein, and 3-(N- acetylamino)-5-(N-decyl-N-methylamino)-benzyl alcohol, which are nonphorbol activators of PKC, also promoted actin assembly. Although these effects were consistent with a role of PKC, the following observations suggested that stimulation of conventional isoforms of the kinase were not directly responsible for actin assembly: (a) Okadaic acid, an inhibitor of phosphatases 1 and 2A, potentiated PMA-induced protein phosphorylation, but not actin assembly; and (b) PMA-induced actin assembly and membrane ruffling were not prevented by the conventional PKC inhibitors 1-(5-isoquinolinesulfonyl)-2- methylpiperazine, staurosporine, calphostin C, or sphingosine at concentrations that precluded PMA-induced protein phosphorylation and superoxide production. On the other hand, PMA-induced actin assembly was inhibited by long-chain fatty acid coenzyme A esters, known inhibitors of nuclear PKC (nPKC). We conclude that PMA-induced actin assembly is unlikely to be mediated by the conventional isoforms of PKC, but may be mediated by novel isoforms of the kinase such as nPKC.

The superoxide-generating oxidase of phagocytic cells. Physiological, molecular and pathological aspects

Professional phagocytes (neutrophils, eosinophils, monocytes and macrophages) possess an enzymatic complex, the NADPH oxidase, which is able to catalyze the one-electron reduction of molecular oxygen to superoxide, O2-. The NADPH oxidase is dormant in non-activated phagocytes. It is suddenly activated upon exposure of phagocytes to the appropriate stimuli and thereby contributes to the microbicidal activity of these cells. Oxidase activation in phagocytes involves the assembly, in the plasma membrane, of membrane-bound and cytosolic components of the oxidase complex, which were diassembled in the resting state. One of the membrane-bound components in resting phagocytes has been identified as a low-potential b-type cytochrome, a heterodimer composed of two subunits of 22-kDa and 91-kDa. The link between NADPH and cytochrome b is probably a flavoprotein whose subcellular localization in resting phagocytes remains to be determined. Genetic defects in the cytochrome b subunits and in the cytosolic factors have been shown to be the molecular basis of chronic granulomatous disease, a group of inherited disorders in the host defense, characterized by severe, recurrent bacterial and fungal infections in which phagocytic cells fail to generate O2- upon stimulation. The present review is focused on recent data concerning the signaling pathway which leads to oxidase activation, including specific receptors, the production of second messengers, the organization of the oxidase complex and the molecular defects responsible for granulomatous disease.

Immunocharacterization of beta- and zeta-subspecies of protein kinase C in bovine neutrophils

The isoforms present in a crude preparation of bovine neutrophil protein kinase (PKC) were identified by immunodetection with antibodies directed against specific sequences of bovine and rat brain PKC isozymes. The major isoform of bovine neutrophil PKC was identified as beta-PKC and the minor one as zeta-PKC.

Differential inhibition of protein kinase C subtypes

Catalytic properties of protein kinase C isoforms purified from rat brain and bovine adrenocortical tissues were examined. The results showed that known inhibitors of PKC activity such as gossypol and H-7 were active on all the three isolated enzyme isoforms with similar IC50 values. However, whereas the type III brain isozyme activity was not affected by a preincubation with phosphatidylserine (PS), the same treatment resulted in a virtually complete loss of the type I and II isoform activities within 4 min at 30 degrees. This kinase inactivation caused by PS preincubation was prevented in the presence of ATP-Mg2+ or its competitive inhibitor H-7. These findings indicate that the type III isoform can clearly be distinguished from the other members of the PKC family by this specific property. This approach was used to confirm the characterization of the single form of PKC detected in bovine adrenocortical tissue as a type III isotype. This specific behavior toward phosphatidylserine suggests that the molecular organization of the phospholipid sensitive, regulatory domain of the PKC isoform III with regard to its catalytic site and thus its mechanism of activation may differ from that of other PKC isotypes.

Characterization of fatty acid elongation system in porcine neutrophil microsomes

Microsomes purified from porcine neutrophils containing the fatty acid chain-elongation system for long- and very-long-chain fatty acyl-CoAs, and several enzymatic characters for the elongation of palmitoyl-CoA (16:0-CoA) and arachidoyl-CoA (20:0-CoA) were examined. The heat-inactivation profile for the elongation of 16:0-CoA was different from that of 20:0-CoA, suggesting the presence of different enzyme systems for palmitoyl-CoA and arachidoyl-CoA. Contrary to the elongation system of brain microsomes, the successive synthesis of lignoceric acid (24:0) from 20:0-CoA at 60 microM was not prominent under normal conditions in the neutrophil microsomes. The synthesis of behenic acid (22:0) was slightly inhibited by 0.5 mM N-ethylmaleimide (NEM) present in the assay mixture, whereas the pre-treatment of microsomes with 0.5 mM NEM largely inhibited the synthesis of 22:0 from 20:0-CoA. The synthesis of 24:0, however, was enhanced by 0.5 mM NEM in the elongation of 20:0-CoA and the rate of 24:0 synthesis became dominant over the synthesis of 22:0. These results suggested that the elongation enzyme for very-long-chain fatty acyl-CoA, especially for 20:0-CoA elongation to 22:0 in the neutrophil microsomes contained NEM-sensitive sulfhydryl groups in the active center and the mechanism for the synthesis of 24:0 through successive elongation from 20:0-CoA was different from that of 22:0, as the former was enhanced by NEM whereas the latter was strongly inhibited.

Platelet aggregation is inhibited by long chain acyl-CoA

Oleoyl coenzyme A and other acyl-CoA derivatives inhibited ADP or thrombin-induced aggregation of platelets. Arachidonic acid-induced aggregation was also inhibited, but not the slower aggregation caused by 1-oleoyl-2-acetylglycerol or tetradecanoyl-phorbol-13-acetate. Coenzyme A and free fatty acids had little or no effect, and transfer of labeled oleate from oleoyl Co-A to other lipid classes was not detected. Because acyl Co-A compounds have recently been shown to modulate protein kinase C activity, acyl Co-A may provide a useful tool for investigating activation sequences in platelets and other membranes.

Diacylglycerol activation of protein kinase C is modulated by long-chain acyl-CoA

The activity of rat brain protein kinase C, measured in the presence of diacylglycerol, phosphatidylserine and Ca+2, was found to be greatly increased by micromolar amounts of long chain acyl-CoAs, using two different assay systems (lipids added as sonicated dispersion or as mixed micelles with Triton X-100). The potentiation phenomenon required the presence of both diacylglycerol and phosphatidylserine; it was observed at low and saturating concentrations of these effectors, and it was inhibited at high, non physiological Ca+2 concentrations. Under similar conditions, fatty acids alone or coenzyme A were ineffective. The data strongly suggest that acyl-CoAs at the intracellular concentration levels, are important in the modulation of protein kinase C, after activation of the enzyme by the phospholipase C/phosphatidylinositol pathway.