The Effects of Reactive Oxygen Species on Internodal Myelin Structure, and Role of Plasmalogen Phospholipids as Endogenous Antioxidants

Luoma, Adrienne M.

January 2009

Thesis advisor: Daniel A. Kirschner / Reactive oxygen species (ROS) are implicated in a range of degenerative conditions, including aging, neurodegenerative diseases, and neurological disorders such as multiple sclerosis. Myelin is a lipid-rich multilamellar assembly that facilitates rapid nerve conduction in higher animals, and may be intrinsically vulnerable to oxidative damage given the high energetic demands and low antioxidant capacity of myelinating cells. To determine whether ROS can cause structural damage to internodal myelin, whole mouse sciatic and optic nerves were incubated ex vivo with a previously-characterized copper (Cu)/hydrogen peroxide (HP)/o-phenanthroline (OP)-based hydroxyl radical-generating system followed by quantitative determination of myelin packing by x-ray diffraction. Exposure to Cu/OP/HP-mediated ROS caused irreversible myelin decompaction in both sciatic and optic nerves. The addition of the hydroxyl radical scavenger, sodium formate, to the ROS-producing incubation solution significantly prevented sciatic nerve myelin decompaction, implicating hydroxyl radical species in causing the damage. Furthermore, Cu/OP/HP-mediated decompaction could be prevented by the addition of EDTA, which can compete with OP for Cu binding and sequester the metal within the bulk solution. These findings suggest that Cu/OP/HP-dependent myelin decompaction is caused by OP-mediated membrane-targeted hydroxyl radical production. Myelin membranes are particularly enriched in plasmalogen phospholipids, which have been linked to antioxidant activity; this enrichment may constitute an endogenous ROS-defense mechanism that protects ROS-vulnerable myelin tissue from damage. Intriguingly, it was found that sciatic nerve myelin from plasmalogen deficient (Pex7 KO) mice was significantly more susceptible to ROS-mediated decompaction than that from WT mice, supporting the role of plasmalogens as endogenous antioxidants. / Thesis (MS) — Boston College, 2009. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Biology.

Myelin

plasmalogens

Reactive oxygen species

X-ray diffraction

S-nitrosothiols and reactive oxygen species in plant disease resistance and development

Brzezek, Kerstin

January 2014

Nitric oxide (NO) as well as reactive oxygen species (ROS) play an important role in defence signalling in plants. After successful recognition of an invading pathogen, an increase in ROS occurs, the ’oxidative burst’; and a ’nitrosative burst’ is also observed. This leads to the induction of defence responses, including the ’hypersensitive response’ (HR), a form of programmed cell death. A balanced production of hydrogen peroxide and NO is crucial for HR induction. In a process called S-nitrosylation, NO can react with cysteine thiols to form S-nitrosothiols, or react with glutathione to form S-nitrosoglutathione (GSNO). The enzyme GNSO reductase (GSNOR) indirectly regulates SNO levels by turning over GNSO. The Arabidopsis thaliana T-DNA insertion mutant atgsnor1-3 shows a complete loss of GNSOR activity and has drastically increased SNO levels, resulting in stunted growth, loss of apical dominance, increased HR, loss of salicylic acid (SA) accumulation and increased susceptibility to avirulent, virulent and non-host pathogens. Two recessive and allelic EMS suppressor mutants in the atgsnor1-3 background were isolated, which showed mostly wild type growth. The mutations were identified by map-based cloning as two different point mutations in At1g20620 or CAT3, one of three catalase genes in Arabidopsis. Catalases break down hydrogen peroxide, with CAT2 being the major catalase in Arabidopsis. All three catalases are structurally very similar, but show temporal and spatial differences in their expression patterns. The suppressor mutants recovered apical dominance, and partially recovered disease resistance to avirulent pathogens, but were still susceptible to virulent pathogens and showed decreased SA levels. The suppressor mutants showed wild type HR in response to different avirulent bacteria. Interestingly, loss-of-function of the other catalase genes as well as loss-of-function of other redox-related genes did not restore apical dominance of atgnsor1-3 plants. This effect seems to be highly specific to CAT3, possibly because of its expression pattern or its expression levels. Further research is needed to fully understand the mechanisms at work here, but these results certainly seem to show a direct connection between redox signalling and S-nitrosylation.

572

Einfluss des Multidrug Resistance Protein-1 auf die vaskuläre Funktion im Modell des Streptozotocin-induzierten Diabetes der Maus / Role of multidrug resistance protein-1 on endothelial dysfunction in streptozotocin-induced diabetes

Wick, Matthias Christian

January 2013

Vaskuläre Komplikationen wie Atherosklerose sind bei Diabetikern weit verbreitet. Eine erhöhte Produktion reaktiver Sauerstoffspezies trägt zu einer Dysfunktion des Endothels bei Diabetes und hohen Glukosespiegeln bei. Glutathion (GSH) ist das häufigste zelluläre Thiol und stellt ein bedeutendens Antioxidans des menschlichen Organismus dar. Das Multidrug Resistance Protein 1 (MRP 1) ist im Endothel der Haupttransporter von oxidiertem GSH. Blockiert man MRP 1, so wird unter oxidativem Stress der intrazelluläre GSH-Spiegel erhalten. In dieser Arbeit wird der Einfluss von MRP 1 auf die endotheliale Funktion und Produktion reaktiver Sauerstoffspezies bei Diabetes und erhöhten Glukosespiegeln anhand von MRP 1-/- -Mäusen und Wildtyp-FVB-Tieren untersucht. Acht Wochen nach Injektion von STZ wurde die endothelabhängige Vasorelaxation an den isolierten thorakalen Aorten bestimmt. Diabetische Wildtyp-Tiere wiesen eine signifikant verminderte endothelabhängige Vasorelaxation auf. In MRP 1-/- -Tieren hingegen kam es zu keiner Beeinträchtigung der Endothelfunktion. Die endothelunabhängige Vasorelaxation war nicht signifikant unterschiedlich. STZ-induzierter Diabetes führte zu einer signifikant erhöhten Produktion von Superoxidanionen sowie Wasserstoffperoxid in Wildtyp-Tieren. Diabetische MRP 1-/- -Mäuse hingegen zeigten keinen Anstieg der Produktion reaktiver Sauerstoffspezies. Erhöhte Glukosekonzentrationen führten in vitro in humanen aortalen Endothelzellen ebenso zur erhöhten Superoxidanion-Produktion. In Zellen, in denen MRP 1 mittels siRNA herunterreguliert war, zeigte sich keine Erhöhung von Superoxidanionen. In Wildtyp-Mäusen führte Diabetes zu einer Verminderung des vaskulären GSH-Spiegels, wohingegen bei MRP 1-/- -Tieren keine Veränderung auftrat. Diese Daten weisen auf die wichtige Rolle von MRP 1 bei der unter hohen Glukosekonzentrationen auftretenden endothelialen Dysfunktion hin. MRP 1 stellt somit einen neuen Ansatzpunkt in der Behandlung der durch Diabetes ausgelösten vaskulären Dysfunktion dar. / Vascular complications and atherosclerosis are common in patients with diabetes. An increased production of reactive oxygen species contributes to endothelial dysfunction in diabetes. A major cellular defense against reactive oxygen species is Glutathione. The multidrug resistance associated protein 1 is the main transporter of oxidized glutathione in endothelial cells. Blockade of MRP 1 prevents endothelial cell dysfunction induced by reactive oxygen species. Diabetes was induced in 12 week old male MRP 1-/- mice or corresponding FVB background wildtype mice by injection of streptozotocin. Eight weeks thereafter endothelium-dependent vasorelaxation was blunted in isolated thoracic aortae. In aortae from diabetic mice lacking MRP 1, endothelium-dependent vasorelaxation was only mildly impaired. STZ induced diabetes increased aortic superoxide and hydrogen peroxide production in wildtype animals, while in aortae from MRP 1-/- mice the reactive oxygen species production was nearly unchanged by diabetic conditions. Aortic levels of reduced glutathione were diminished in diabetic FVB. Glutathione levels did not change in diabetic MRP 1-/- mice. These data indicate that MRP 1 plays an important role for endothelial dysfunction and reactive oxygen species production in diabetes and under conditions of high glucose. MRP 1 therefore may represent a therapeutic target in treatment of diabetes induced vascular dysfunction.

Endothelial dysfunction

Glutathion

Reactive Oxygen Species

Diabetes

ddc:610

Systèmes hydrophiles antioxydants pour applications cardiovasculaires : synthèse, caractérisation, études in vitro et in vivo / Hydrophilic Antioxydant Systems for Cardiovascular Applications : Synthesis, Characterization, In Vitro and In Vivo Studies

Zuluaga tamayo, Marisol

21 September 2017

Une présence en excès d'espèces réactives oxygénées induit un déséquilibre redox cellulaire pouvant conduire à des pathologies liées au stress oxydatif, notamment les pathologies cardiovasculaires. Connue et étudiée pour ses propriétés antioxydantes, l’astaxanthine, molécule de la famille des caroténoïdes, présente un intérêt thérapeutique potentiel. Cependant, sa structure chimique lui confère un caractère hydrophobe ainsi qu’une sensibilité à l’air, à la lumière et à la chaleur. Dans cette thèse, tout d’abord, un système de complexation de l’astaxanthine avec l’hydroxypropyl-b-cyclodextrine a été élaboré (CD-A). Nous démontrons que cette complexation améliore la stabilité de l’astaxanthine en solution aqueuse tout en préservant ses activités antioxydantes, mesurées par des méthodes chimiques et biologiques. L’action du CD-A semble être médiée par les voies de signalisation PTEN/AKT, Nrf2/OH1/NQO1 dans des cellules endothéliales soumises au stress oxydatif. Puis, afin de libérer l’astaxanthine in situ sur le site du stress, nous avons élaboré deux systèmes de type matriciel en PVA/dextrane ou en pullulane/dextrane chargés en CD-A. Nous avons évalué, comme preuve de concept, la faisabilité de ces dispositifs pour le traitement local de la pathologie d’ischémie/reperfusion. Les patchs de PVA/dextrane/CD-A ont montré une bonne compatibilité in vitro, ainsi qu’une grande stabilité et tenue mécanique sans modification des propriétés antioxydantes. Leur biocompatibilité in vivo et suturabilité au muscle cardiaque ont aussi été étudiées. Le deuxième système à base de pullulane/dextrane/CD-A a été évalué in vitro et in vivo dans un modèle d’ischémie/reperfusion du membre inférieur à différentes périodes d'implantation. Les résultats ont montré l’activation d’un mécanisme de défense normal lié à la présence d’un matériel étranger et une diminution de la translocation du Nrf2 pouvant indiquer un effet protecteur dans les tissus traités par le CD-A. Ce manuscrit présente des arguments en faveur du potentiel thérapeutique de systèmes de libération d’astaxanthine agissant au niveau du stress oxydatif lié aux pathologies cardiovasculaires. / An over concentration of reactive oxygen species induces a redox imbalance within the cell inducing oxidative tissue damage and leading to oxidative stress related diseases, particularly cardiovascular pathologies. Astaxanthin, a well-known and studied antioxidant molecule, member of the xanthophyll carotenoid family, presents an important therapeutic potential. However, the chemical structure confers to astaxanthin a hydrophobic character and renders it susceptible to air, light and temperate degradation. During this thesis, a carrier system based on astaxanthin inclusion within hydroxypropyl-β-cyclodextrin(CD-A) was developed. We demonstrate that after astaxanthin inclusion, not only its stability was enhanced by also the antioxidant scavenging capabilities were preserved, confirmed by chemical and biological tests. The action of CD-A seems to be mediated by PTEN/AKT, Nrf2/OH1/NQO1 signaling pathways of endothelial cells submitted to oxidative stress. Then, two systems based on PVA/dextran and Pullulan/Dextran loaded within CD-A were evaluated for astaxanthin in situ delivery in the stressed environment. The feasibility of using these systems in the local treatment of ischemia/reperfusion injury was evaluated as a proof of concept. PVA/Dextran patches showed good in vitro compatibility, high mechanical and stability properties, while preserving CD-A antioxidant capabilities, also the path suturability to the cardiac muscle and the in vivo biocompatibility were studied. The second system based on pullulan/dextran scaffolds were evaluated in vitro and in vivo in an ischemic/reperfusion model at different implantation periods. Results showed an inner body defense mechanism to foreign materials. Additionally, the Nrf2 translocation could indicate a protective effect of CD-A in treated tissues. This manuscript provides a support evidence of the therapeutic potential of CD astaxanthin delivery system, to act against oxidative stress linked to cardiovascular conditions.

Astaxanthine

Espèces réactives oxygénées

Astaxanthin

Reactive oxygen species

Evaluation of desiccation-induced oxidative injury in human red blood cells

Kanias, Tamir

11 1900

The current practice of red blood cell banking for transfusion medicine relies primarily on a six-week liquid storage. A growing demand for red blood cell (RBC) products has prompted the search for alternative preservation methods including dry storage. Being desiccation sensitive, attempts to recover RBCs from the dry state have failed. This dissertation offers a new mechanistic understanding of desiccation-induced cellular injury that is correlated with the oxidative state of the hemoglobin. The general hypothesis states that RBC desiccation is accompanied with non-physiological oxidation of hemoglobin and, consequently, the release of toxic products capable of compromising cellular recovery through oxidative injury. Data acquired for this dissertation demonstrates that water loss induces a drastic increase in the rate of hemoglobin oxidation, formation of intracellular reactive oxygen species (ROS), and hemolysis. Pharmacological treatments of the hemoglobins oxygen binding site reveal that hemoglobin-induced cellular injury is more prominent in RBC samples that are partially dehydrated (about 3.5 to 5.5 g H2O/g dry weight) than in samples that are relatively dry ( 2 g H2O/g dry weight). Furthermore, partially dehydrated RBC samples contain higher levels of oxidized lipids than more fully dried samples. This dissertation also examined the role that glucose and glutathione play in enhancing desiccation tolerance of RBCs. Glucose treatment (5 mmol/L) significantly reduced ROS formation and hemolysis levels in partially dehydrated RBC samples (5.8 0.3 g H2O/g dry weight), but not in samples that are relatively dry (2.8 0.5 g H2O/g dry weight). Treating RBCs with DL-buthionine-(S,R)-sulfoximine, a glutathione depleting agent, was correlated with reduced levels of desiccation-induced hemolysis. This study suggests that desiccation-induced oxidative injury in RBCs is water dependent corresponding to earlier stages of water loss, in which cells can retain metabolic activity. Pharmacological treatments at this stage can significantly affect cell recovery as demonstrated with modifying the hemoglobins oxygen binding site, glutathione depletion, and glucose supplementation. On the other hand, increased cytoplasmatic viscosity compromises biochemical reactions at lower residual moisture contents, and cellular injury is likely the result of physical and mechanical stress. These differences should be taken into consideration in the design of innovative approaches to RBC preservation.

dessication

hemoglobin oxidation

reactive oxygen species

red blood cells

NF-kB activation by Reactive Oxygen Species: mechanisms and ensuing findings

Gloire, Geoffrey

01 December 2006

Le facteur de transcription NF-κB joue un rôle majeur dans lorchestration de nombreux processus biologiques, tels que les réponses immunitaires innée et adaptative, la division cellulaire, lapoptose et le développement. Le NF-κB est activé en réponse à un grand nombre de stimuli, comme les cytokines pro-inflammatoires, les agents viraux et bactériens et la stimulation antigénique des cellules du système immunitaire. Il peut être aussi activé dans des conditions de stress oxydant, par exemple après une exposition à des concentrations physiologiques (de lordre du µM) de peroxyde dhydrogène (H2O2). Au début de ce travail, le mécanisme conduisant à lactivation du NF-κB par le stress oxydant était mal connu et sujet à maintes controverses, ce qui nous a poussé à investiguer cette voie plus avant. Dans une première partie, nous nous sommes attachés à étudier le mécanisme dactivation du NF-κB dans des lymphocytes T soumis à un stress oxydant. Les cellules du système immunitaire sont en effet très sensibles à lenvironnement redox, et sont fréquemment en contact avec des espèces réactives de loxygène libérées par les cellules phagocytaires (monocytes/macrophages et neutrophiles) lors dune réponse inflammatoire. Comme le NF-κB est une protéine cruciale pour le développement et lhoméostasie des lymphocytes T, létude de sa modulation lors dun stress oxydant savère particulièrement importante. Nous avons pu mettre en évidence une activation importante du facteur de transcription lors dun traitement oxydant, ainsi quune dégradation presque compète de linhibiteur IκBα. Létude approfondie du mécanisme menant à cette dégradation a mis au jour un mécanisme dactivation tout à fait inédit, impliquant lactivation du complexe IKK via lintervention de lInositol Phosphatase SHIP-1. Dans cette première partie, nous avons également mis en évidence le rôle crucial de la protéine SHIP-1 dans la protection des lymphocytes T contre lapoptose induite par le stress oxydant, ce qui en fait une protéine clé dans la lhoméostasie des lymphocytes T. Dans un second temps, nous nous sommes intéressés au mécanisme influençant la fixation du NF-κB à lADN. Nous avons pu démontrer le rôle important de la protéine IKKα comme déterminant la fixation du NF-κB aux promoteurs de certains gènes, mettant ainsi au jour un mode daction inconnu pour cette protéine. Ce rôle est dautant plus intéressant quil est spécifique, ce qui pourrait déboucher sur des applications thérapeutiques intéressantes.

SHIP-1

IKK

Inflammation

Reactive Oxygen Species

NF-kB

Reactive Oxygen Species (ROS) Up-regulates MMP-9 Expression Via MAPK-AP-1 Signaling Pathway in Rat Astrocytes

Malcomson, Elizabeth

14 March 2011

Ischemic stroke is characterized by a disruption of blood supply to a part of the brain tissue, which leads to a focal ischemic infarct. The expression and activity of MMP-9 is increased in ischemic stroke and is considered to be one of the main factors responsible for damages to the cerebral vasculature, resulting in compromised blood-brain barrier (BBB) integrity. However, the regulatory mechanisms of MMP-9 expression and activity are not well established in ischemic stroke. Since hypoxia/ischemia and reperfusion generates reactive oxygen species (ROS), I hypothesize that ROS is one of factors involved in up-regulation of MMP-9 expression in brain cells and ROS-mediated effect may occur via MAPK signaling pathway. My study has provided the evidence that ROS is responsible for an increase in MMP-9 expression in astrocytes mediated via MAPK-AP1 signaling pathway. Preliminary studies with an in vitro model of the BBB suggest that inhibition of MMP-9 is a critical component of reducing ROS-induced BBB permeability.

MMP-9

blood-brain barrier

ischemic stroke

reactive oxygen species

Role of Reactive Oxygen Species in Normal Postnatal Lung Growth

Jamal, Mobin

20 November 2012

Rationale/ Hypothesis: Reactive oxygen species, including lipid hydroperoxides, play a critical role as second messengers in many physiological processes in the body. Heightened reactive oxygen species production at the time of birth imposes an oxidative stress upon the lung, which may trigger postnatal alveologenesis and physiological lung cell apoptosis in the neonatal rat. Methods: Neonatal rats were subcutaneously injected daily with vehicle (corn oil) or diphenyl-phenyl diamine for the first 6 days of life to study alveologenesis and physiological lung cell apoptosis. Add-back experiments were conducted with a prototypic lipid hydroperoxide, t-butyl hydroperoxide. Main Results: Treatment with diphenyl-phenyl diamine resulted in parenchymal thickening, reduced numbers of secondary crests and enlarged air spaces, all consistent with the inhibition of alveologenesis and reduced physiological lung cell apoptosis. Conclusion: Following an oxidative stress at birth, lipid hydroperoxide formation triggers postnatal alveologenesis and physiological lung cell apoptosis in the neonatal rat.

lung development

alveolar formation

reactive oxygen species

physiological apoptosis

0433

Role of Reactive Oxygen Species in Normal Postnatal Lung Growth

Jamal, Mobin

20 November 2012

Rationale/ Hypothesis: Reactive oxygen species, including lipid hydroperoxides, play a critical role as second messengers in many physiological processes in the body. Heightened reactive oxygen species production at the time of birth imposes an oxidative stress upon the lung, which may trigger postnatal alveologenesis and physiological lung cell apoptosis in the neonatal rat. Methods: Neonatal rats were subcutaneously injected daily with vehicle (corn oil) or diphenyl-phenyl diamine for the first 6 days of life to study alveologenesis and physiological lung cell apoptosis. Add-back experiments were conducted with a prototypic lipid hydroperoxide, t-butyl hydroperoxide. Main Results: Treatment with diphenyl-phenyl diamine resulted in parenchymal thickening, reduced numbers of secondary crests and enlarged air spaces, all consistent with the inhibition of alveologenesis and reduced physiological lung cell apoptosis. Conclusion: Following an oxidative stress at birth, lipid hydroperoxide formation triggers postnatal alveologenesis and physiological lung cell apoptosis in the neonatal rat.

lung development

alveolar formation

reactive oxygen species

physiological apoptosis

0433

Analysis of Arabidopsis <i>AIR12</i> and <i>Brassica carinata CIL1</i> in root development and response to abiotic stress

Gibson, Shawn William

09 September 2010

The development of plants challenged by environmental stress alters plant architecture through several pathways, including those involving plant hormone responses and reactive oxygen species (ROS) production. Auxin, a phytohormone associated with every aspect of development, and abscisic acid (ABA), a phytohormone involved in abiotic stress responses, both interact with ROS. These ROS are used as secondary messengers to activate transcription of abiotic stress genes, and also in developmental responses such as cell elongation. To understand the mechanisms involved in the abiotic stress response and how the response intersects with auxin, ABA, and ROS, I examined COPPER INDUCED IN LEAVES 1 (<i>CIL1</i>) from <i>Brassica carinata</i> and its Arabidopsis orthologue, AUXIN INDUCED IN ROOTS 12 (AIR12). Expression of both genes increases in response to auxin and recent work has placed both <i>CIL1</i> and AIR12 within a family of plant-specific cytochrome b561 proteins thought to be involved with transmission of ROS signals. This suggests a link between auxin and ROS production resulting from abiotic stress. Antisense <i>CIL1 B. carinata</i> plants produced fewer lateral roots and were resistant to salinity stress during vegetative growth. Mutant air12 plants showed a 50% reduction in lateral root number, lateral root length, and H2O2 root distribution. Growth in the presence of H2O2 was able to restore lateral root length to control levels. In silica analysis of the <i>CIL1</i> and AIR12 amino acid sequences detected an attachment site for glucosylphosphatidylinositol, predicting that the protein is targeted to the extracellular leaflet of the plasma membrane where it could be cleaved and released into the apoplast. Subcellular localization using p35S::GFP-CIL1 and p35S::GFP-AIR12 translational fusions confirmed that CIL1 and AIR12 localize to the plasma membrane and are released into the apoplast. Organ localization of AIR12 using the pAIR12::GFP-AIR12 construct in stably transformed Arabidopsis showed fusion protein accumulation in the apex of the primary root and in the vascular tissue. Fusion protein also localized to cells flanking emerging lateral roots. Investigation of pAIR12::GUS Arabidopsis showed GUS accumulation in the apex of elongating lateral roots. I demonstrate that AIR12 is an extracellular protein and that air12 seedlings are susceptible to salt stress, but not osmostic stress and display increased and decreased sensitivity to ABA during germination and primary root elongation, respectively, suggesting that AIR12 acts downstream of abiotic stress recognition.

Auxin

abscic acid

lateral root development

reactive oxygen species