15-Deoxy-Δ(12,14)-prostaglandin J2 prevents oxidative injury by upregulating the expression of aldose reductase in vascular smooth muscle cells.

The omega-6 fatty acid derivative 15-Deoxy-Δ(12,14)-prostaglandin J2 (15d-PGJ2) is believed to play a role in cellular protection against oxidative stress in diverse cell systems. However, the cellular mechanisms by which protection is afforded by 15d-PGJ2 are not fully elucidated in vascular smooth muscle cells (VSMCs). In this study, we report the finding that 15d-PGJ2 elicited a time and concentration- dependent increase in aldose reductase (AR) expression. This induction was independent of the activation of peroxisome proliferator- activated receptor γ. Inhibition of phosphatidylinositol 3-kinase (PI3K) significantly suppressed the increase in expression and promoter activity of AR induced by 15d-PGJ2. Luciferase reporter assays demonstrated that 15d-PGJ2 targets the multiple stress response regions comprising the antioxidant response element in the promoter of the AR gene. 15d-PGJ2-mediated induction of AR promoter activity was potentiated in the presence of nuclear factor-erythroid 2-related factor 2 (Nrf2), but not in cells expressing dominant negative Nrf2. Cells treated with 15d-PGJ2 were resistant to oxidant-induced apoptotic cell death by inhibiting production of reactive oxygen species. These effects were significantly attenuated in the presence of an AR inhibitor or small interfering RNA against AR, indicating that AR plays a protective role against oxidative injury. Taken together, these findings demonstrate that activation of PI3K by 15d-PGJ2 increases the expression of AR through Nrf2, and increased AR activity may function as an important cellular response against oxidative injury.

Integrin-linked kinase mediates the hydrogen peroxide-dependent transforming growth factor-ß1 up-regulation.

Transforming growth factor type-ß1 (TGF-ß1) has been recognized as a central mediator in many pathological events related to extracellular matrix (ECM) proteins accumulation, where their locally increased expression has been implicated in the fibrosis process of numerous organs, including glomerular fibrosis in the kidney. We and others have reported the TGF-ß1 synthesis regulation by reactive oxygen species (ROS), and moreover we also described the implication of integrin-linked kinase (ILK) in the AP-1-dependent TGF-ß1 up-regulation. Thus, we propose here that hydrogen peroxide (H2O2)-dependent TGF-ß1 regulation may be mediated by ILK activation. First we confirmed the increase in TGF-ß1 expression in human mesangial cells (HMC) after treatment with H2O2 or with an alternative H2O2-generating system such as the glucose-oxidase enzyme (GOX). By using immunoblotting, immunofluorescence, and ELISA techniques, we demonstrate that extracellular H2O2 up-regulates TGF-ß1 transcription, as well as increases TGF-ß1 promoter activity. Furthermore, catalase-decreased intracellular H2O2 abolished TGF-ß1 up-regulation. The use of pharmacological inhibitors as well as knockdown of ILK with small interfering RNA (siRNA) demonstrated the implication of a PI3K/ILK/AKT/ERK MAPK signaling pathway axis in the H2O2-induced TGF-ß1 overexpression. Finally, we explored the physiological relevance of these findings by treating HMC with angiotensin II, a known stimuli of H2O2 synthesis. Our results confirm the relevance of previous findings after a more physiological stimulus. In summary, our results provide evidence that ILK activity changes may act as a mechanism in response to different stimuli such as H2O2 in the induced TGF-ß1 up-regulation in pathological or even physiological conditions.

Mitochondrial DNA integrity may be a determinant of endothelial barrier properties in oxidant-challenged rat lungs.

In cultured pulmonary artery endothelial cells and other cell types, overexpression of mt-targeted DNA repair enzymes protects against oxidant-induced mitochondrial DNA (mtDNA) damage and cell death. Whether mtDNA integrity governs functional properties of the endothelium in the intact pulmonary circulation is unknown. Accordingly, the present study used isolated, buffer-perfused rat lungs to determine whether fusion proteins targeting 8-oxoguanine DNA glycosylase 1 (Ogg1) or endonuclease III (Endo III) to mitochondria attenuated mtDNA damage and vascular barrier dysfunction evoked by glucose oxidase (GOX)-generated hydrogen peroxide. We found that both Endo III and Ogg1 fusion proteins accumulated in lung cell mitochondria within 30 min of addition to the perfusion medium. Both constructs prevented GOX-induced increases in the vascular filtration coefficient. Although GOX-induced nuclear DNA damage could not be detected, quantitative Southern blot analysis revealed substantial GOX-induced oxidative mtDNA damage that was prevented by pretreatment with both fusion proteins. The Ogg1 construct also reversed preexisting GOX-induced vascular barrier dysfunction and oxidative mtDNA damage. Collectively, these findings support the ideas that mtDNA is a sentinel molecule governing lung vascular barrier responses to oxidant stress in the intact lung and that the mtDNA repair pathway could be a target for pharmacological intervention in oxidant lung injury.

Therapy mediated by mitophagy abrogates tumor progression.

Autophagy is mainly a cellular recycling process that promotes survival, but it can also cause cell death if cell injury persists. The role of mitophagy in tumorigenesis remains uncertain. Other cell death types, such as apoptosis or necrosis, are often altered during tumor development and therefore are not ideal targets to generate efficient antitumor therapies. We have used the system linamarase/linamarin/glucose oxidase (lis/lin/GO) to eliminate tumor cells. This therapeutic strategy is based on the combination of cyanide and oxidative stress to abrogate tumor growth. After severe mitochondrial insult by lis/lin/GO, the electron transport chain is blocked and hydrogen peroxide production increased. This triggers a degradative phase of these damaged organelles inducing mitophagy that finally leads to cell death. This death process depends on the vacuole generation, BNIp3 and the formation of autolysosomes. Importantly, evasion of apoptosis is known to result in resistance to anti-cancer therapies but this inhibition also augments sensitivity to autophagy, which could be used to promote tumor regression. We explored the potential of this powerful mitophagy-inducing system in vitro and in vivo to eradicate human malignant tumors.

Enzyme-mediated redox initiation for hydrogel generation and cellular encapsulation.

A rapid, water-soluble enzyme-mediated radical chain initiation system involving glucose oxidase and Fe(2+) generated hydrogels within minutes at 25 degrees C and in ambient oxygen. The initiation components were evaluated for their effect on polymerization rates of hydroxyethyl acrylate-poly(ethylene glycol)(575) diacrylate comonomer solutions using near-infrared spectroscopy. Increasing glucose concentration increased polymerization rates until reaching a rate plateau above 1 x 10(-3) M of glucose. A square root dependence of the initial polymerization rate on Fe(2+) concentration was observed between 1.0 x 10(-4) M and 5.0 x 10(-4) M of Fe(2+), whereupon excess Fe(2+) reduced final acrylate conversions. The glucose oxidase-mediated initiation system was employed for encapsulation of fibroblasts (NIH3T3s) into a poly(ethylene glycol) tetra-acrylate (M(n) approximately 20000) hydrogel scaffold demonstrating 96% (+/-3%) viability at 24 h postencapsulation. This first use of enzyme-mediated redox radical chain initiation for cellular encapsulation demonstrates polymerization of hydrogels in situ with kinetic control, minimal oxygen inhibition issues, and utilization of low initiator concentrations.

Large scale motions in a biosensor protein glucose oxidase: a combined approach by QENS, normal mode analysis, and molecular dynamics studies.

The characteristics of the glucose oxidase were studied using a combination of experimental and theoretical techniques. Quasi elastic neutron scattering experiments were used to obtain the vibrational frequencies of the protein. These were compared to theoretical results obtained by normal mode analysis. Results indicate a good match between the experimental and theoretical values. Molecular dynamic simulation with covariant analysis was used to study the structure and dynamics of glucose oxidase. Various parameters like the radius of gyration, root mean square fluctuations, solvent accessibility were studied for evaluating the structural stability of the protein. The frequency of vibration calculated from the three methods is used to derive the large scale motions. Theses studies were used to predict the suitable lysine residues for linkage with carbon nanotubes.

Ablation of caterpillar labial salivary glands: technique for determining the role of saliva in insect-plant interactions.

There has been an ardent interest in herbivore saliva due to its roles in inducing plant defenses and its impact on herbivore fitness. Two techniques are described that inhibit the secretion of labial saliva from the caterpillar, Helicoverpa zea, during feeding. The methods rely on cauterizing the caterpillar's spinneret, the principal secretory structure of the labial glands, or surgically removing the labial salivary gland. Both methods successfully inhibit secretion of saliva and the principal salivary enzyme glucose oxidase. Caterpillars with inhibited saliva production feed at similar rates as the untreated caterpillars, pupate, and emerge as adults. Glucose oxidase has been suggested to increase the caterpillar's survival through the suppression of inducible anti-herbivore defenses in plants. Tobacco (Nicotiana tabacum) leaves fed on by caterpillars with ablated salivary glands had significantly higher levels of nicotine, an inducible anti-herbivore defense compound of tobacco, than leaves fed upon by caterpillars with intact labial salivary glands. Tomato (Lycopersicon esculentum) leaves fed upon by caterpillars with suppressed salivary secretions showed greatly reduced evidence of hydrogen peroxide formation compared to leaves fed upon by intact caterpillars. These two methods are useful techniques for determining the role that saliva plays in manipulating plant anti-herbivore defenses.

The antioxidant, rather than prooxidant, activities of quercetin on normal cells: quercetin protects mouse thymocytes from glucose oxidase-mediated apoptosis.

The bioflavonoid quercetin is a dietary anticancer chemical that is capable of inducing apoptosis in tumor cells. Although the activity of quercetin is believed to be due to its antioxidative properties, it has recently been suggested that quercetin also has prooxidant activities, which might effect cytotoxicity directly. In this study, we used mouse thymocytes to investigate whether quercetin behaved as a protector against oxidative stress or as a cytotoxic agent. Quercetin treatment did not induce oxidative damage, but protected mouse thymocytes from glucose oxidase (GO)-mediated apoptosis in a dose-dependent manner. Furthermore, electrophoretic mobility shift assays revealed that quercetin (50 microM) treatment suppressed the GO-mediated DNA binding activity of redox state-sensitive transcription factors, such as NF-kappaB, AP-1, and p53. This result suggests that quercetin has antioxidative effects on thymocytes. More interestingly, quercetin treatment alone (50 microM) increased the DNA-binding activity of AP-1, which consisted of heterodimer of c-Jun and Fra-2. Finally, the antioxidant activity of quercetin was confirmed using a cell-free system of radical generation. Our findings suggest that quercetin protects mouse thymocytes from oxidative stress-mediated apoptosis and modulates the intracellular redox state through its antioxidant activity.

In vitro analysis of the role of glucose oxidase from Talaromyces flavus in biocontrol of the plant pathogen Verticillium dahliae.

Culture filtrates from Talaromyces flavus grown on glucose contained high levels of glucose oxidase activity, while culture filtrates from T. flavus grown on xylan contained negligible glucose oxidase activity. Culture filtrates from T-flavus grown on both media contained complex protein profiles. However, only culture filtrates from T. flavus grown on glucose inhibited germination of microsclerotia of Verticillium dahliae in in vitro inhibition assays. A polyclonal antiserum preparation, pABGO-1, raised against purified glucose oxidase from T. flavus was highly specific for glucose oxidase. Only one protein band in culture filtrates (from glucose medium), migrating at 71 kDa, was detected in Western blots (immunoblots) with this antiserum. This band comigrated with purified glucose oxidase. No bands were detected in culture filtrates from the xylan medium. Glucose oxidase was removed via immunoprecipitation from culture filtrates of T. flavus grown in glucose medium, resulting in filtrates which no longer inhibited in vitro microsclerotial germination. When glucose oxidase-depleted filtrates were amended with purified glucose oxidase from T. flavus, the ability to kill microsclerotia in vitro was restored to original levels. We conclude that glucose oxidase is the only protein in culture filtrates of T. flavus responsible for inhibition of germination of microsclerotia of V. dahliae.

The role of cationized catalase and cationized glucose oxidase in mucosal oxidative damage induced in the rat jejunum.

The successful prevention of hydrogen peroxide-induced damage to the rat jejunal mucosa by cationized catalase is described in this study. Biological damage was induced in a closed circulating intestinal loop of the rat by hydrogen peroxide and by hydroxyl radicals induced in situ via the metal-mediated Haber-Wiess reaction. The mucosal activity of lactate dehydrogenase and the amount of potassium ions were used to quantitatively characterize the tissue damage. Catalase was cationized by reacting it with N,N'-dimethyl-1,3-propanediamine to give a soluble product or with polyhistidine to give an insoluble product. The activity of the modified enzymes was assessed, and their ability to protect the rat jejunal mucosa against oxidative stress was studied. It was found that in all cases the cationized enzymes were superior to the native catalase in their shield capability. A significant protection against Fe(II)/H2O2 and ascorbic acid/copper ion-mediated damage was obtained when the cationized enzymes were used. In the presence of glucose, native glucose oxidase failed to cause damage in the rat jejunal mucosa; however, the cationized enzyme caused profound tissue injury. These findings indicate the potential therapeutic merit of cationized enzymes for the treatment of pathological processes in the intestine, whenever oxidative stress is involved.

Riboflavin 5'-pyrophosphate: a contaminant of commercial FAD, a coenzyme for FAD-dependent oxidases, and an inhibitor of FAD synthetase.

Commercially available preparations of flavin adenine dinucleotide (FAD) have been found to be 94% pure, the remaining 6% being composed of four or five minor contaminants which can be separated from FAD by reverse-phase high-performance liquid chromatography. FAD purified in this manner has been shown to be 100% pure. One of the contaminants has been identified as riboflavin 5'-pyrophosphate (RPP) by spectroscopic and chemical methods of analysis. This compound has been shown to exhibit biological activity as a weak cofactor for two FAD-requiring enzymes. With the apoprotein of porcine D-amino-acid oxidase, values determined for RPP were 8.4 microM for Km and 0.10 for Vmax compared to 0.47 microM and 0.28 (36 U/mg), respectively, for FAD. With fungal glucose apooxidase, values determined for RPP were 474 nM for Km and 0.02 for Vmax and 45 nM and 0.09 (105 U/mg), respectively, for FAD. RPP can also inhibit FAD biosynthesis. For bovine liver FAD synthetase, a Ki value for RPP against FMN was determined to be 9 microM where Km for FMN was 5.5 microM. These studies illustrate the value of riboflavin 5'-pyrophosphate as a flavin analog for use in the study of structure/function relationships within certain flavin-dependent enzymes.

Rotating disc electrode characterization of immobilized glucose oxidase.

The kinetic properties of glucose oxidase (EC 1.1.3.4) which has been covalently immobilized to a rotating glassy carbon electrode surface have been investigated. Analysis of the rotation rate dependence of the hydrogen peroxide-derived current suggests that oxygen mass transport to the enzyme-electrode surface is rate controlling at low rotation rates. Only as the diffusion layer approaches zero thickness (i.e., infinitely fast rotation rate) does mass transport become unimportant. A diffusion-free glucose Km for air-saturated buffer is found to be 66 mM using this methodology. The importance of mass transport restrictions in two-substrate enzymes such as glucose oxidase is discussed in the context of biosensor design.

Production of interleukin 1-like factor from human peripheral blood monocytes and polymorphonuclear leukocytes by superoxide anion: the role of interleukin 1 and reactive oxygen species in inflamed sites.

In the present study, we investigated the possibility that oxidative stress to human peripheral blood monocytes and polymorphonuclear leukocytes (PMNs) can induce interleukin 1 (IL-1)-like activity. Oxidative stress that we used was superoxide anion (O2-) and hydrogen peroxide (H2O2). O2-, but not H2O2, could induce an IL-1-like factor(s) from monocytes and PMNs. IL-1-like activity from monocytes and PMNs induced by O2- was due to de novo synthesis because no IL-1-like activity was found in culture supernatants and in the lysate of unstimulated cells. We next examined the effects of radical scavengers on production of an IL-1-like factor(s). Generation of IL-1-like activity from monocytes was amplified by preincubation with catalase (H2O2 scavenger), although it was suppressed by preincubation with either superoxide dismutase (O2- scavenger) or vitamin E (antioxidant analogs). These results suggest that production of an IL-1-like factor(s) from monocytes and PMNs was due to O2- stimulation. Our data that production of an IL-1-like factor(s) from inflammatory cells by stimulation with O2- imply a model of the up-regulation mechanism of inflammation mediated by enhanced IL-1-like factor production stimulated with reactive oxygen species.

Susceptibility of Plasmodium falciparum to a peroxidase-mediated oxygen-dependent microbicidal system.

The viability of Plasmodium falciparum in culture was assessed by [3H]hypoxanthine incorporation during 24 h of incubation with lactoperoxidase, glucose-glucose oxidase, hydrogen peroxide, halides, or thiocyanate, alone or in combination. Synergistic inhibition was produced by the following combinations: lactoperoxidase plus hydrogen peroxide, lactoperoxidase plus glucose-glucose oxidase, and lactoperoxidase plus hydrogen peroxide plus halides or thiocyanate. These inhibitory effects were reversed by catalase and glutathione. The presence of plasmodial crisis forms inside the erythrocytes suggests that the oxygen-dependent microbicidal system of phagocytes has a killing effect.

Augmentation of neutrophil-mediated erythrocyte lysis by cells derived in vitro from human monocytes.

Neutrophilic polymorphonuclear leukocytes (PMNs) were incubated with opsonized zymosan and lysed human erythrocytes (RBCs) as measured by a 51Cr release method. Conversely, myeloperoxidase (MPO)-negative hydrogen peroxide (H2O2)-generating cells, derived in vitro from human monocytes (monocyte-derived cells (MDCs), were ineffective per se but capable of augmenting the lysis by PMNs. The lysis by PMNs and PMNs plus MDCs was inhibited by catalase, azide, taurine, and alanine, consistent with the requirement for hypochlorous acid (HOCl). As detected under conditions similar to those used for lytic assays, MDCs failed to produce HOCl but augmented the HOCl recovery from the PMN-RBC system. Moreover, when the extent of the lysis was plotted as a function of the HOCl recovery, a positive linear relationship was found. Although the actual size of the H2O2 extracellular pool could not be measured because of the inexistence of a reliable assay to probe our cytolytic model without perturbing the equilibrium of the system, the results presented suggest that MDCs enhance the PMN-mediated lysis by improving the HOCl production, presumably by supplying extra amounts of H2O2 to be handled by PMN MPO. In fact, the events mediated by MDCs could be reproduced by using an appropriate H2O2-generating enzymatic system (glucose-glucose oxidase). The present study provides direct evidence for the possibility of cooperation between MPO-positive and MPO-negative phagocytes in exerting functions (HOCl production and, in turn, cytolysis) possibly relevant to the outcome of inflammatory processes.

An experimental model for hydrogen peroxide-induced tissue damage. Effects of a single inflammatory mediator on (peri)articular tissues.

Hydrogen peroxide is receiving increasing attention as a mediator of tissue damage during inflammation. To evaluate its destructive potential in vivo, we devised a model in which hydrogen peroxide is, initially, the sole mediator of tissue damage. Glucose oxidase, which was made cationic to obtain good retention in tissue, was injected intraarticularly in mouse knee joints. This enzyme produces hydrogen peroxide, using endogenous glucose as a substrate. The local production of hydrogen peroxide induced drastic vascular damage, as measured by 99mTc uptake and leakage of 125I-albumin. The chondrocyte proteoglycan synthesis was severely inhibited, as measured by 35SO4 incorporation. Histologic examination showed impressive inflammatory and degenerative changes, including periarticular infiltration, chondrocyte death, subchondral erosions, and muscle necrosis. Intraarticular administration of catalase could inhibit these vascular effects and cartilage damage. Systemic administration of ebselen, a synthetic glutathione peroxidase-like compound, provided partial protection. Indomethacin and piroxicam were not effective in the acute phase. We think this model is useful both for testing drugs that are purported to act as scavengers of hydrogen peroxide and for studying chronic destructive processes.

Lack of lignin degradation by glucose oxidase-negative mutants of Phanerochaete chrysosporium.

Glucose oxidase-negative (gox-) mutants of Phanerochaete chrysosporium were isolated after exposing conidia to UV irradiation. The gox- mutants exhibited little or no ability to degrade lignin (2-[14C]-synthetic lignin to 14CO2); however, they retained other secondary metabolic features such as the ability to conidiate and produce veratryl alcohol, suggesting that they are not pleiotropic for secondary metabolism. Lignin degradation activity was restored in gox+ revertants. These results, in support of earlier evidence, indicate that glucose oxidase activity plays an important role in lignin degradation by P. chrysosporium.