Marcial Llanillo

p22phox-dependent NADPH oxidase activity is required for megakaryocytic differentiation.

Transient reactive oxygen species (ROS) production is currently proving to be an important mechanism in the regulation of intracellular signalling, but reports showing the involvement of ROS in important biological processes, such as cell differentiation, are scarce. In this study, we show for the first time that ROS production is required for megakaryocytic differentiation in K562 and HEL cell lines and also in human CD34+ cells. ROS production is transiently activated during megakaryocytic differentiation, and such production is abolished by the addition of different antioxidants (such as N-acetyl cysteine, trolox, quercetin) or the nicotinamide adenine dinucleotide phosphate (NADPH) oxidase inhibitor diphenylene iodonium. The inhibition of ROS formation hinders differentiation. RNA interference experiments have shown that a p22phox-dependent NADPH oxidase activity is responsible for ROS production. In addition, the activation of ERK, AKT and JAK2 is required for differentiation, but the activation of phosphatidylinositol 3-kinase and c-Jun N-terminal kinase seems to be less important. When ROS production is prevented, the activation of these signalling pathways is partly inhibited. Taken together, these results show that NADPH oxidase ROS production is essential for complete activation of the main signalling pathways involved in megakaryocytopoiesis to occur. We suggest that this might also be important for in vivo megakaryocytopoiesis.

Reactive oxygen species: Are they important for haematopoiesis?

The production of reactive oxygen species (ROS) has traditionally been related to deleterious effects for cells. However, it is now widely accepted that ROS can play an important role in regulating cellular signalling and gene expression. NADPH oxidase ROS production seems to be especially important in this regard. Some lines of evidence suggest that ROS may be important modulators of cell differentiation, including haematopoietic differentiation, in both physiologic and pathologic conditions. Here we shall review how ROS can regulate cell signalling and gene expression. We shall also focus on the importance of ROS for haematopoietic stem cell (HSC) biology and for haematopoietic differentiation. We shall review the involvement of ROS and NADPH oxidases in cancer, and in particular what is known about the relationship between ROS and haematological malignancies. Finally, we shall discuss the use of ROS as cancer therapeutic targets.

Comparison of changes in erythrocyte and platelet phospholipid and fatty acid composition and protein oxidation in chronic obstructive pulmonary disease and asthma

Objective: To analyse and compare the phospholipid and fatty acid composition of total lipids and the occurrence of lipid peroxidation and protein oxidation directly in erythrocytes or platelets from chronic obstructive pulmonary disease (COPD) and asthma patients. Patients: Fifteen consecutive outpatients with COPD (all smokers) and asthma (non-smokers) recruited during a moderate-to-severe (COPD) or moderate (asthma) exacerbation. Fifteen subjects with smoking habits similar to those of COPD patients were studied as a control group. Methods: Phospholipid and total fatty acid compositions were analysed by two-dimensional thin layer chromatography or gas chromatography–mass spectrometry, respectively. The lipid fluorescence of lipid extracts was measured by spectrofluorimetry. Protein carbonyl contents and profiles were measured by immunoblot detection. Results: No differences were found either in erythrocyte or platelet cholesterol or phospholipid levels. Only a decrease in the content of phosphatidylserine + phosphatidylinositol (P < 0.003) was detected in platelets from the asthma patients. In erythrocytes, the fatty acid profile changed in both lung pathologies, especially as regards polyunsaturated fatty acids (decreases in arachidonic and 22:4 fatty acid contents). Other observed changes were: COPD, an increase in palmitic fatty acid; asthma, an increase in oleic and decreases in eicosapentaenoic and 22:6 + 24:1 fatty acids. In platelets, the fatty acid profiles revealed many differences between both lung pathologies: COPD, a decrease in 18:1 and increases in 20:5 and 22:5 + 24:0; asthma, a decrease in 20:4 and increase in 22:6 + 24:1. In COPD vs. asthma patients, fatty acid changes were mainly detected in platelets, especially in 18-carbon species, with decreases in stearic and 18:1 fatty acids in the COPD patients. Protein oxidation levels were increased in both lung pathologies in both erythrocytes and platelets. Conclusions: COPD and asthma are associated with common or specific changes in the lipid composition of erythrocytes and/or platelets. The data point to lipid peroxidation and protein oxidation phenomena in both types of blood cell, although platelets would be more susceptible to stress.

Lipid composition of subcellular particles from sheep platelets. Location of phosphatidylethanolamine and phosphatidylserine in plasma membranes and platelet liposomes.

The lipid composition of whole sheep platelets and their subcellular fractions was determined. The basic lipids show similar distributions in granules, microsomes, plasma membranes and whole platelets. Phospholipid (about 70% of total lipids) and cholesterol (25% of total lipids) are the principal lipid components. Free cholesterol represents about 98% of the total, whereas cholesteryl ester is a minor component. The phospholipid composition found in intact platelets and their subcellular particles is about: 35% phosphatidylethanolamine (PE), 30% phosphatidylcholine (PC), 20% sphingomyelin and 15% phosphatidylserine (PS). We also investigated aminophospholipid topology in intact platelet plasma membranes and platelet liposomes by using the nonpenetrating chemical probe trinitrobenzenesulfonic acid (TNBS), because they are the major components of total lipids. In intact platelets, PS is not accessible to TNBS during the initial 15 min of incubation, whereas 18% PE is labelled after 15 min. In contrast, in phospholipid extracted from platelets 80% PE and 67% PS react with TNBS within 5 min, while 27 and 25% PE and 15 and 19% PS from liposomes and isolated plasma membranes, respectively, were modified after 15 min of incubation. In view of this chemical modification, it is concluded that 22% of PE and less than 1% of PS are located on the external surface of intact platelet plasma membranes. The asymmetric orientation of aminophospholipids is similar between liposomes and isolated plasma membrane. PS (23 and 28%) and PE (34 and 31%) are scarcely represented outside the bilayer. The data found are consistent with the nonrandom phospholipid distribution of blood cell surface membranes.

Oxidative inactivation of human and sheep platelet membrane-associated phosphotyrosine phosphatase activity

Incubation of human or sheep platelet crude membranes with xanthine oxidase/hypoxanthine in the presence of Fe2+/ADP inactivated phosphotyrosine phosphatase (PTPase, protein-tyrosine-phosphate-phosphohydrolase, EC 3.1.3.48) activity in a time-dependent manner, this inhibition being significant within 5 min of treatment. The dynamics of protein thiols differed depending on the platelet species, but in any case decreases in protein thiols were only visible 20-45 min after the start of the treatment. The inhibition of PTPase activity in general showed good a correlation with the production of thiobarbituric acid-reactive substances (TBARS). The results with several antioxidants suggest that the inhibition of PTPase activity is related to the generation of alkoxyl and/or peroxyl radicals. Furthermore, the formation of fluorescent products and changes in amino groups were observed only after long incubation times with the oxidizing agents, these fluorescent products and the residual enzyme activity remaining in the membrane fraction. Treatment of platelet membranes with trans-2-nonenal and n-heptaldehyde, but not with acetaldehyde, also inhibited membrane-associated PTPase activity. However, the amount of protein thiols was reduced only by treatment with trans-2-nonenal. Fluorescence product formation was always higher with trans-2-nonenal, these products being mainly located in the protein fraction. The results with aldehydes suggest that secondary degraded products of lipid hydroperoxides affect PTPase activity. Kinetic studies of PTPase activity indicated that with all treatments enzyme inhibition is mainly due to a decrease in the Vmax value. The results of fluorescence anisotropy measurements of labeled platelet membranes did not support the notion of a contribution of the lipid organization to peroxidation-mediated PTPase inhibition. All the above results indicate that platelet membrane-associated PTPase inhibition due to treatment with xanthine oxidase/ hypoxanthine in the presence of Fe2+/ADP is a very complex, time-dependent process, and that it is probably related, at least after long periods of peroxidation, to changes in protein thiols and amino groups. We predict that the sensitivity of PTPase to lipid peroxidation must be physiologically relevant because of the increasing importance of tyrosine phosphorylation in signal transduction, in general, and in platelet activation and aggregation in particular.

Membrane cholesterol contents modify the protective effects of quercetin and rutin on integrity and cellular viability in oxidized erythrocytes

Flavonoids protect cells damaged by oxidative stress. This, together with other biological activities, is governed by structural features of flavonoids and the nature and physical state of the cell membrane. We have previously proved that membrane cholesterol contents modify the protective power of quercetin and rutin against oxidative stress in erythrocytes. Here we analyzed the lipid asymmetry, the integrity, and cell viability of native and cholesterol-modified erythrocytes exposed to tert-butyl hydroperoxide in presence of both antioxidants. Our results provides clear evidence that quercetin affords better protection than rutin against lipid peroxidation, ROS generation, erythrophagocytosis and cellular instability in oxidized erythrocytes with normal and modified cholesterol contents. Both antioxidants provided a high of protection for the transbilayer aminophospholipid asymmetry, only partly preserving cell morphology in oxidized control and cholesterol-depleted erythrocytes. Cholesterol depletion reduced the protection provided by both antioxidants against phosphatidylserine externalization, erythrophagocytosis and hemolysis, which is in accordance with the lower degree of preservation against lipid peroxidation observed in oxidized cholesterol-depleted erythrocytes. This lower degree of preservation is presumably attributable to the low antioxidant contents in these erythrocyte membranes, or even to a lower efficiency of the antioxidant in a modified lipid environment due to the removal of cholesterol.

NADPH Oxidases as Therapeutic Targets in Chronic Myelogenous Leukemia

Purpose: Cancer cells show higher levels of reactive oxygen species (ROS) than normal cells and increasing intracellular ROS levels are becoming a recognized strategy against tumor cells. Thus, diminishing ROS levels could be also detrimental to cancer cells. We surmise that avoiding ROS generation would be a better option than quenching ROS with antioxidants. Chronic myelogenous leukemia (CML) is triggered by the expression of BCR-ABL kinase, whose activity leads to increased ROS production, partly through NADPH oxidases. Here, we assessed NADPH oxidases as therapeutic targets in CML. Experimental Design: We have analyzed the effect of different NADPH oxidase inhibitors, either alone or in combination with BCR-ABL inhibitors, in CML cells and in two different animal models for CML. Results: NADPH oxidase inhibition dramatically impaired the proliferation and viability of BCR-ABL–expressing cells due to the attenuation of BCR-ABL signaling and a pronounced cell-cycle arrest. Moreover, the combination of NADPH oxidase inhibitors with BCR-ABL inhibitors was highly synergistic. Two different animal models underscore the effectiveness of NADPH oxidase inhibitors and their combination with BCR-ABL inhibitors for CML targeting in vivo. Conclusion: Our results offer further therapeutic opportunities for CML, by targeting NADPH oxidases. In the future, it would be worthwhile conducting further experiments to ascertain the feasibility of translating such therapies to clinical practice. Clin Cancer Res; 20(15); 4014–25. ©2014 AACR.

Comparative antioxidant capacities of quercetin and butylated hydroxyanisole in cholesterol-modified erythrocytes damaged by tert-butylhydroperoxide.

Phenolic compounds are potent antioxidants that scavenge reactive oxygen species (ROS), protecting the cells against oxidative damage. Their antioxidant capacities are governed by their structural features and the nature and physical state of the cell membrane. Our study compares the protective effects of butylated hydroxyanisole (BHA) and quercetin against the cellular injury induced by oxidative stress, and the influence of membrane cholesterol contents in their antioxidant capacities, analyzing the structural changes and cellular stability of native and cholesterol-modified erythrocytes exposed to tert-butylhydroperoxide in presence of each antioxidant. The data provide clear evidence that BHA affords better protection than quercetin against ROS generation, lipid peroxidation and lipid and GSH losses in oxidized erythrocytes. However, cellular integrity and stability are better protected by quercetin owing to the hemolytic effect of BHA. Both antioxidants suppress the alterations in membrane fluidity with similar efficiency, reducing methemoglobin formation in all oxidized erythrocytes. Membrane cholesterol depletion decreases the protection against the oxidative damage provided by both antioxidants. This lower preservation may be due to low antioxidant contents, a lower antioxidant capacity, or even to an increased oxidative damage in this membrane type as a consequence of environment modifications after cholesterol depletion.

Platelet linoleic acid is a potential biomarker of advanced non-small cell lung cancer

New parameters that could be used as tumor markers for lung cancer would be valuable. Our aim was to analyze the fatty acid profiles of total lipids from erythrocytes and platelets from patients with advanced non-small cell lung cancer (NSCLC), chronic obstructive pulmonary disease (COPD) and asthma to reveal the fatty acids that could be used as NSCLC biomarkers. In our study, 50, 15 and 15 patients with advanced NSCLC, COPD and asthma and 50 healthy subjects were enrolled. Fatty acid profiles were investigated using gas chromatography/mass spectrometry followed by ROC (receiver operating characteristics) curves analysis to gain information about biomarkers. Sialic acid (SA) and cytokeratins were measured by the thiobarbituric acid and immunoradiometric methods respectively. Useful fatty acid markers were as follows: erythrocytes, 22:0 and linoleic acid (LA, 18:2n6); platelets, 16:0, 18:0, and LA. At the cutoff value to obtain maximum accuracy, the best biomarker was platelet LA, with higher diagnostic yields than the commonly used markers SA or cytokeratins (100%, 76%, 75% and 86% sensitivity, specificity, positive predictive value and accuracy, respectively). These findings suggest that platelet LA might be used as a biomarker of NSCLC in relation to different aspects of the disease process that now needs to be explored.

Erythrocyte and Platelet Phospholipid Fatty Acids as Markers of Advanced Non-Small Cell Lung Cancer: Comparison with Serum Levels of Sialic Acid, TPS and Cyfra 21-1

The phospholipid fatty acid profiles of erythrocytes and platelets from fifty patients with advanced non-small cell lung cancer were investigated using gas chromatography/mass spectrometry, followed by “ROC” curves analysis to gain novel biomarker information. Sialic acid and cytokeratins were also examined. Potentially useful fatty acid markers: Erythrocytes: phosphatidylcholine, 18:2n6 and 20:4n6; phosphatidylethanolamine, 22:4n6 and 22:6n3 + 24:1n9. Platelets: phosphatidylcholine, 22.0; phosphatidylethanolamine, 22:5n3 + 24:0. At the cut-off value to obtain maximum accuracy, the best biomarkers were found in platelets: phosphatidylserine + phosphatidylinositol (PS + PI), 21:0; sphyngomyelin: 20:1n9 and 22:1n9. All these fatty acids showed similar/higher diagnostic yields than the commonly used markers sialic acid or cytokeratins.