Effect of administered ethanol on protein kinase C in human platelets

Alcohol in Psoriasis-From Bench to Bedside

Alcohol affects the symptoms, compliance and comorbidities as well as the safety and efficacy of treatments in psoriatic patients. In this review, we aim to summarize and link clinical observations with a molecular background, such as signaling pathways at the cellular level and genetic variations, and to provide an overview of how this knowledge could influence our treatment selection and patient management.

Prenatal alcohol exposure and maternal glutamine supplementation alter the mTOR signaling pathway in ovine fetal cerebellum and skeletal muscle

Prenatal alcohol exposure causes fetal neurodevelopmental damage and growth restriction. Among regions of the brain, the cerebellum is the most vulnerable to developmental alcohol exposure. Despite vast research in the field, there is still a need to identify specific mechanisms by which alcohol causes this damage in order to design effective therapeutic interventions. The mammalian target of rapamycin (mTOR) is known to be associated with axonal regeneration, dendritic arborization, synaptic plasticity, cellular growth, autophagy, and many other cellular processes. Glutamine and glutamine-related amino acids play a key role in fetal development and are known to alter the mTOR pathway; recent research has shown that disturbances in their bioavailability and signaling pathways may mediate adverse effects of prenatal alcohol exposure. This study investigated the role of the mTOR signaling pathway in the fetal cerebellum and skeletal muscle after third trimester-equivalent prenatal alcohol exposure and maternal l-glutamine (GLN) supplementation using a sheep model. Fetal cerebella and skeletal muscles were sampled for Western blot analysis of mTOR and its downstream targets S6 kinase and eukaryotic initiation factor 4E-bindin protein (4E-BP1). The expression of cerebellar phosphorylated mTOR relative to the total mTOR was elevated in the alcohol+GLN group compared to the saline and GLN groups. Alcohol exposure increased the ratio of phosphorylated S6K to total S6K in fetal cerebellum, and no significant effect of GLN supplementation was observed. On contrary, maternal GLN supplementation reduced the activation of mTOR and S6K in fetal skeletal muscle, possibly to make GLN and other amino acids available for use by other organs. These findings suggest prenatal alcohol exposure and maternal GLN supplementation during the third trimester-equivalent alter the mTOR signaling cascade, which plays a possible key role in alcohol-induced developmental damage.

Effects of alcohol on hemostasis

Several epidemiologic studies have shown that moderate intake of alcohol is associated with a lower risk of cardiovascular disease (CVD), but the mechanism is not fully elucidated. One of the proposed mechanisms of the protective effect of moderate alcohol intake is its beneficial effect on hemostasis. The aim of this review is to summarize the effect of ethanol intake on platelet aggregation and activation, coagulation factors including von Willebrand factor (vWF), and the fibrinolytic system. With regard to the effect of alcohol on platelet function, evidence in the literature suggests both platelet activation and platelet inhibition by ethanol. A unifying hypothesis is that platelets are partially activated by ethanol, with partial degranulation allowing for continued circulation of platelets with impaired function. Evidence also exists showing that ethanol intake decreases fibrinogen, factor VII, and vWF levels. In addition, alcohol intake has been found to increase fibrinolysis by increasing tissue plasminogen activator activity. The effect of ethanol on platelets, coagulation factors, and the fibrinolytic system is likely to contribute to protection against CVD.

The EPR study of LDL perturbed by alcohols with different molecular architecture

In this work, the interaction of different isomers of lower aliphatic alcohols with LDL representing a complex macromolecular assembly is investigated in vitro. Emphasis is given to the comparison of the impact of molecular architecture of methanol, ethanol, propanol (n-, iso-) and butanol (n-, iso-, sec-, tert-) in perturbing the lipid-protein assembly. The geometrical characteristics as well as the lipophilicity of the respective alcohol are considered. The EPR method combined with the spin labeling of both the apoB and the lipid monolayer allowed parallel detection of changes provoked in both phases. In addition to the change in protein environment, the spectral decomposition of the experimental data revealed a decrease in lipid ordering with the increasing concentration of the alcohols. This phenomenon for aliphatic alcohols is linearly correlated with the equal volume occupation (EVO) of alcohol in LDL. The results support the molecular mechanism of alcohol action through its interference with the lipid-protein interactions in LDL, which could be applicable to the molecular mechanism of alcohol interaction with integral membrane proteins.

Dysmorphogenic effects of a specific protein kinase C inhibitor during neurulation

Protein kinase C (PKC) plays a key role in signal transduction and is an important mediator of events throughout development. However, no information exists regarding the effect of a specific PKC inhibitor on mammalian embryogenesis during neurulation. This investigation was undertaken to examine the effects of a specific inhibitor of PKC, as well as inhibitors of other important kinases, on cultured mouse embryos. CD-1 mouse embryos (3 to 6 somite stage) were exposed to bisindolylmaleimide I (a specific PKC inhibitor) as well as specific inhibitors of PKA, PKG, and MAP kinase kinase for 24 h. The PKC inhibitor was a potent embryotoxicant and elicited malformations at concentrations as low as 0.01 microM. Inhibitors of other kinases also produced malformations but at much higher concentrations than those required to produce similar defects with the PKC inhibitor. These data suggest that PKC plays an important role in mammalian neurulation. Further research is required to clarify the mechanism by which PKC inhibition at this developmental stage produces malformations and the potential effects of environmental toxicants with PKC inhibitory properties on this signal transduction pathway.

Dietary supplementation of grape polyphenols and chronic ethanol administration on LDL oxidation and platelet function in rats

Polyphenolic compounds have been implicated as the active ingredients for the cardiac protective effect in red wine. We tested the effects of dietary supplementation of polyphenols from grape (GP) and chronic ethanol administration on low-density-lipoprotein (LDL) oxidation and platelet function in rats. Four groups of young male Sprague-Dawley rats were fed the following diets for 2 months: (I) a high fat Lieber-DeCarli liquid diet with an isocaloric amount of maltose, (II) with 5% ethanol (w/v), (III) with 5 mg/dL of GP, and (IV) ethanol plus GP. Platelet aggregation was induced by thrombin and phorbol myristate acetate (PMA) and LDL oxidation was induced by Cu2+. Chronic ethanol administration resulted in a significant increase in LDL oxidation and this effect was partially protected by supplementation with GP. Although platelet number was not affected by either ethanol or GP administration, platelet aggregation induced by thrombin was reduced in ethanol, GP and ethanol plus GP groups as compared to controls. On the other hand, platelet aggregation induced by PMA was not altered in any groups, suggesting that protein kinase C was not a causal factor for the reduction of aggregatory response induced by thrombin. These results show similar effects of ethanol and GP on platelet aggregation but different effects on LDL oxidation. It can be concluded that dietary supplementation with GP may exert partial protection on oxidative insults such as those elicited by chronic ethanol ingestion.

Role of PKC and tyrosine kinase in ethanol-mediated inhibition of LPS-inducible nitric oxide synthase

Ethanol increases human and animal susceptibility to opportunistic lung infections in part by suppression of endotoxin (LPS) and bacteria-mediated upregulation of inducible nitric oxide synthase (iNOS) in alveolar macrophages (AM). LPS and cytokine-induced NOS mRNA are dependent on NF-kappaB/Rel (NFkappaB) and Activator Protein-1 (AP-1), which are regulated in turn by protein kinase C and tyrosine kinase-dependent phosphorylation. ETOH does not directly inhibit NFkappaB or AP-1, in vivo, but rather inhibits LPS-induced activation of the MEKK/MAP kinase system and inhibition of inhibitory protein IkappaBalpha required for formation of AP-1 and NFkappaB, respectively. in AM. Both transcription factors are involved iNOS mRNA transcription. LPS-induced upregulation of MEKK/MAP tyrosine kinase upregulates NADPH oxidase activity and oxygen free radical formation required for activation of NFkappaB and AP-1 and phosphorylation of IkappaBalpha. LPS downregulates endogenous calcium-sensitive PKC isozymes (PKCdelta), which repress iNOS mRNA expression. ETOH inhibits LPS-induced upregulation of iNOS mRNA by preventing its ability to decrease PKCdelta and upregulate tyrosine kinase-mediated phosphorylation. This effect of ETOH is prevented by inhibitors of PKC and tyrosine kinase. The data support the hypothesis that ETOH inhibits LPS-induced upregulation of iNOS mRNA by interfering with the phosphorylation processes involved in activation of the nuclear transcription factors NFkappaB and AP-1.

Ethanol-induced effects on expression level, activity, and distribution of protein kinase C isoforms in rat liver Golgi apparatus

Acute ethanol administration induces significant modifications both in secretive and formative membranes of rat liver Golgi apparatus. The decrease in glycolipoprotein secretion and their retention into the hepatocyte contribute to the pathogenesis of alcohol-induced fatty liver. Molecular and cellular mechanisms behind the ethanol-induced injury of the liver secretory pathway are not yet completely defined. In this study on intact livers from ethanol-treated rats, the involvement of the Golgi compartment in the impairment of hepatic glycolipoprotein secretion has been correlated with changes in the expression level, subcellular distribution and enzymatic activity of protein kinase C (PKC) isoforms. Acute ethanol exposure determined a translocation of classic PKCs and delta isoform from the cytosol to cis and trans Golgi membranes, the site of glycolipoprotein retention in the hepatic cell. A marked stimulation of cytosolic epsilon PKC activity was observed throughout the period of treatment. The presence of activated PKC isozymes at the Golgi compartment of alcohol-treated rat livers may play a role in hepatic secretion and protein accumulation. Direct and indirect effects of ethanol consumption on PKC isozymes and Golgi function are discussed.

Regulation of glutamate uptake in astrocytes continuously exposed to ethanol

CNS glutamatergic transmission is altered by chronic ethanol intake and may underlie the behavioral hyperactivity associated with ethanol withdrawal. Because astrocytes regulate extracellular glutamate levels, the aim of this investigation was to characterize the effects of in vitro ethanol exposure on Na+-dependent glutamate uptake parameters in astrocytes. Ethanol exposure elicited a time and concentration-dependent increase in the maximal uptake capacity, Vmax, for [3H] glutamate, which was reversed upon withdrawal of ethanol from the media. None of the ethanol exposures had any effect on the Km for this process. In addition, the ethanol-induced increase in Vmax for glutamate was reversed by the protein kinase C inhibitors, calphostin C and bisindolylmaleimide, and was not associated with an increase in the expression of either of the major glutamate transporter proteins, GLT-1 or GLAST.

Ethanol metabolism in the brain

Acetaldehyde is suspected of being involved in the central mechanism of central nervous system depression and addiction to ethanol, but in contrast to ethanol, it can not penetrate easily from blood into the brain because of metabolic barriers. Therefore, the possibility of ethanol metabolism and acetaldehyde formation inside the brain has been one of the crucial questions in biomedical research of alcoholism. This article reviews the recent progress in this area and summarizes the evidence on the first stage of ethanol oxidation in the brain and the specific enzyme systems involved. The brain alcohol dehydrogenase and microsomal ethanol oxidizing systems, including cytochrome P450 II E1 and catalase are considered. Their physicochemical properties, the isoform composition, substrate specificity, the regional and subcellular distribution in CNS structures, their contribution to brain ethanol metabolism, induction under ethanol administration and the role in the neurochemical mechanisms of psychopharmacological and neurotoxic effects of ethanol are discussed. In addition, the nonoxidative pathway of ethanol metabolism with the formation of fatty acid ethyl esters and phosphatidylethanol in the brain is described.