p97 Negatively Regulates NRF2 by Extracting Ubiquitylated NRF2 from the KEAP1-CUL3 E3 Complex

Tao, Shasha, Liu, Pengfei, Luo, Gang, Rojo de la Vega, Montserrat, Chen, Heping, Wu, Tongde, Tillotson, Joseph, Chapman, Eli, Zhang, Donna D.

15 April 2017

Activation of the stress-responsive transcription factor NRF2 is the major line of defense to combat oxidative or electrophilic insults. Under basal conditions, NRF2 is continuously ubiquitylated by the KEAP1-CUL3-RBX1 E3 ubiquitin ligase complex and is targeted to the proteasome for degradation ( the canonical mechanism). However, the path from the CUL3 complex to ultimate proteasomal degradation was previously unknown. p97 is a ubiquitin-targeted ATP-dependent segregase that extracts ubiquitylated client proteins from membranes, protein complexes, or chromatin and has an essential role in autophagy and the ubiquitin proteasome system ( UPS). In this study, we show that p97 negatively regulates NRF2 through the canonical pathway by extracting ubiquitylated NRF2 from the KEAP1-CUL3 E3 complex, with the aid of the heterodimeric cofactor UFD1/NPL4 and the UBA-UBX containing protein UBXN7, for efficient proteasomal degradation. Given the role of NRF2 in chemoresistance and the surging interest in p97 inhibitors to treat cancers, our results indicate that dual p97/NRF2 inhibitors may offer a more potent and long-term avenue of p97-targeted treatment.

KEAP1

NRF2

autophagy

cancer chemoresistance

oxidative stress

p97

proteasome

protein quality control

ubiquitylation

Towards understanding stable isotope signatures in stressed systems

Ek, Caroline

January 2016

Stable isotope analysis (SIA) is a valuable tool in ecotoxicology because δ13C and δ15N may provide insights into the trophic transfer of contaminants in a food web. The relationship between a species’ trophic position (TP, determined from δ15N) and internal concentration of biomagnifying contaminants can be established and used for regulatory purposes. However, the exposure of organisms to xenobiotics incurs physiological costs, and the stable isotope signature of a consumer reflects not only diet but also a physiological state. The latter raises questions regarding the interpretation of stable isotope signatures in contaminated areas. Therefore, the aim of this Thesis was to evaluate the behaviour of consumers’ stable isotope signatures in stressed systems, with a primary focus on the effects of environmental contaminants. In paper I, the physiological costs of chemical exposure were found to alter incorporation rates of dietary nitrogen and carbon in a consumer by influencing both growth and metabolic turnover, with resulting changes in isotope signatures relative to a control system. In paper II, the diet-consumer discrimination factors for 15N and 13C were confirmed to increase under chemical exposure mediated via increased metabolic costs. However, the physiological response was low and translated into only minor shifts in the δ13C and δ15N. The predictability of exposure effects on the stable isotope signature was demonstrated in paper III, in which animals exposed to a chemical with a known mode of action presented expected effects on elemental composition, body size, biomarkers of oxidative stress and the stable isotope signatures. Moreover, consumers’ oxidative balance was found to be related to their δ15N values, thus providing evidence of the kinetic isotope effect on the oxidative status. However, despite the alterations in stable isotope signatures observed in laboratory settings (papers I-III), the effect of xenobiotics on the TP estimates was nil or minor in the field-collected animals. Moreover, the TP values were not significantly different between the animals in the contaminated and the reference habitats because of the high overall uncertainties in the TP estimates (paper IV). Also, the TP estimates based on δ15N in bulk material were more similar between the contaminated and the reference systems than TP estimates based on δ15N values in amino acids. Therefore, the latter method appears more sensitive towards xenobiotics (and, possibly, other environmental stressors) and thus less suitable for TP assessment in contaminated areas. This Thesis improved the overall understanding of the applicability of SIA in stressed systems by establishing relationships between various exposure regimes, physiological responses and the stable isotope signatures in consumers. In model species at low trophic levels, the exposure to xenobiotics was found to significantly affect δ13C and δ15N values, which can be expected whenever physiological responses are detected. However, because of the overall high uncertainty in TP estimates, no significant differences between contaminated and control systems were detected, although the estimated TP were consistently higher in the contaminated systems. Future research should focus on higher trophic levels, in which effects of a greater magnitude can be expected. Moreover, the effects in entire food webs should be addressed rather than single prey–consumer relationships as well as other environmental variables that may contribute to the stable isotope variability in and among systems under various environmental pressures. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 3: Manuscript. Paper 4: Manuscript.</p>

Stable isotope analysis

trophic position

chemical exposure

oxidative stress

Daphnia magna

Gammarus spp.

Limecola balthica

Uticaj γ-zračenja na antioksidativni sistem odabranih genotipova soje i pojava oksidativnog stresa / Influence of γ-radiation on antioxidant system of selected genotypes of soybean and oxidative stress appearance

Popović Boris

15 December 2006

<p>U radu su prikazani rezultati ispitivanja uticaja niskih doza &gamma;-zračenja (do 200 Gy) na antioksidantne osobine i parametre oksidativnog stresa u različitim fazama razvoja soje i uticaja srednjih doza &gamma;-zračenja (1-10 kGy) na neke antioksidantne osobine semena soje. Vr&scaron;ena su određivanja aktivnosti antioksidantnih enzima (SOD,CAT,GPx,GSH-Px), količine hidroksil radikala, malonildialdehida i redukovanog glutationa, sadržaja rastvorljivih proteina, ukupnih fenola i tanina, intenziteta oksidacije proteina, ukupne antioksidantne aktivnosti FRAP metodom, DPPH-skevindžer aktivnosti i inhibicije NO radikala. ESR spektroskopijom praćen je uticaj ekstrakata ozračene i neozračene soje na količinu hidroksil radikala u Fentonovom model sistemu. Pomoću HPLC analize određen je sadržaj izoflavona u semenu ozračene i neozračene soje.</p><p>Upoređivanjem antioksidantnih statusa ozračenih i neozračenih genotipova soje može se zaključiti da je &gamma;-zračenje, kojim je bilo izloženo seme, dovelo do stimulacije antioksidantnog sistema soje u različitim fazama razvoja kroz dve generacije. Utvrđeno je da promene aktivnosti pojedinih komponenti antioksidantnog sistema zavise od doze primenjenog zračenja, genotipa kao i od faze razvoja biljke.</p><p>Na osnovu lipidne peroksidacije kao kriterijuma (biomarkera) osetljivosti na radijacioni i&nbsp;<br />oksidativni stress, ispitivani genotipovi se mogu svrstati u dve grupe: radiosenzitivni genotipovi Venera i Ana i radiorezistentni genotipovi Meli i Novosađanka. Rezultati ESR &nbsp;spektroskopije su potvrdili da su genotipovi Ana i Venera osetljiviji na radijacioni i oksidativni stres od genotipova Meli i Novosađanka. Na&scaron;i rezultati ukazuju da srednje doze &gamma;-zračenja poseduju izvesno &bdquo;antioksidantno dejstvo&ldquo; koje se manifestuje povećanjem DPPH skevindžer aktivnosti i smanjenjem intenziteta oksidacije proteina u&nbsp;<br />semenu soje. Nije utvrđena ni jedna negativna posledica na ispitivane nutritivne karakteristike semena soje.</p> / <p>The results obtained through the investigation about the influence of low level doses of &gamma;-radiation (up to 200 Gy) on the antioxidant properties and oxidative stress parameters in different phases of soy development and the influence of the middle level doses of &gamma;-radiation (from 1 kGy to 10 kGy) on some antioxidant parameters of soybean seed were presented in this paper. The investigation of the antioxidant enzymes (SOD,CAT,GPx,GSH-Px), hydroxyl-radical, malonyldialdehide and reduced glutathione quantities, soluble protein and total phenol and tannin content, protein oxidation intensity, total antioxidant activity by FRAP-method, DPPH scavenger ability and NO radical inhibition was performed. ESR spectroscopy was used to follow the change of hydroxyl radical quantities in the Phenton model system. HPLC was used to analyse the isoflavone content in the irradiated and nonirradiated soybean.</p><p>By comparison of antioxidant statuses of irradiated and nonirradiated soy, it was established that the &gamma;-irradiation of soybean stimulated the antioxidant system of soy during the development through two generations. It was observed that the changes in antioxidant activities of different components of antioxidant system of soybean depend on dose of radiation, genotype and phase of the development.<br />On the basis of lipid peroxidation as criterion (biomarker) of sensitivity on radiation and oxidative stress, investigated genotypes can be classified intotwo groups: radiosensitive genotypes Venera and Ana and radioresistant genotypes Meli and Novosađanka. Results of ESR spectroscopy confirmed that genotypes Ana and Venera are more sensitive to radiation and oxidative stress than genotypes Meli and<br />Novosađanka.</p><p>Our results indicate that middle doses of &gamma;-radiation possess such &bdquo;antioxidant activity&ldquo; which is manifestated with the increase of DPPH scavenger activity and decrease of protein oxidation intensity in soybean seed. We did not establish any negative implication on investigated nutritive characteristics of soybean seed.</p>

Study of two mouse mutants to identify novel neurodegenerative pathways

Finelli, Mattea J.

January 2010

Neurodegenerative disorders (NDD) are an ever-increasing burden on healthcare; consequently, elucidating the mechanisms underlying neurodegeneration (ND) is critical for the development of effective treatments for these diseases. In order to unravel the molecular pathways underlying movement disorders and identify new genes involved in ND, two ataxic mouse mutants characterised by cell death in the cerebellum were studied in detail using a combination of in vitro and in vivo techniques. The robotic mouse demonstrated the key role of a transcription factor, Af4, in Purkinje cell (PC) survival and how only small changes in the levels of a single transcriptional cofactor could deleteriously affect normal cerebellum function. Expression array studies of the robotic PCs revealed the first confirmed targets of Af4-mediated transcription, including insulin-like growth factor 1 (Igf-1). It was demonstrated that Igf-1 is critical for PC survival, highlighting the role of the IGF-1 signalling pathway as a potential therapeutic target for the treatment of cerebellar ataxia in humans. Detailed analysis of the bella mutant demonstrated that ataxia and apoptotic cerebellar degeneration is caused by loss of the oxidative resistance 1 (Oxr1) gene. In vitro modelling experiments went on to show that the levels of this previously uncharacterised gene are critical for controlling the sensitivity of neuronal cells to oxidative stress (OS). Moreover, this study showed that Oxr1 was up-regulated both in human and pre-symptomatic mouse models of amyotrophic lateral sclerosis (ALS), demonstrating that Oxr1 was an early marker of ROS defence, prior to pathology, and potentially a novel neuroprotective factor in NDD. Preliminary interaction studies show that Oxr1 is likely to be a multi-functional protein that forms complexes with proteins known to be mutated in NDD. Thus, the study of both the robotic and the bella mouse has demonstrated the value of the phenotype-driven approach to investigate novel neurodegenerative pathways.

616.8

The role of plasma and vascular tetrahydrobiopterin in vascular disease states

Cunnington, Colin

January 2011

The endothelial nitric oxide synthase (eNOS) co-factor tetrahydrobiopterin (BH4) has been shown to play a pivotal role in maintaining endothelial function in experimental vascular disease models. In BH4-deficient states, eNOS becomes enzymatically ‘uncoupled’, generating reactive oxygen species instead of nitric oxide, thus promoting endothelial dysfunction. In humans with coronary artery disease (CAD), higher vascular BH4 levels have been shown to be associated with improved endothelial function, and genetic variation in endogenous BH4 synthesis has implicated a causal role. Accordingly, BH4 has been proposed as a potential therapeutic target in vascular disease states. The work in this thesis aims to further elucidate the roles of exogenous and endogenous BH4 in humans. In a randomised, placebo-controlled clinical trial of oral BH4 therapy in patients with CAD, exogenous BH4 had no effect on endothelial function or vascular oxidative stress. Subsequent pharmacokinetic and pharmacodynamic analysis revealed that oral BH4 significantly augmented BH4 levels in plasma and in venous tissue (but not in arterial tissue), but also increased levels of the oxidation product dihydrobiopterin (BH2), which lacks eNOS cofactor activity. Thus, there was a null effect on overall biopterin redox status. To further understand the mechanics of exogenous BH4 oxidation, ex vivo studies of human blood and vascular tissue demonstrated that exogenous BH4 is very rapidly oxidised to BH2; co-administration with an antioxidant had only a modest effect on preventing BH4 oxidation in blood, with no beneficial effect on biopterin redox state in the vasculature. Finally, using a “Mendelian randomisation” approach, I studied the effects of a haplotype of GCH1 (the gene encoding the rate limiting enzyme in BH4 synthesis) on endogenous BH4 bioavailability and vascular function in healthy individuals. In patients with CAD, this haplotype has been associated with decreased BH4 bioavailability and eNOS uncoupling, however in healthy individuals the haplotype exerted no significant effect, likely due to reduced inflammatory stimulation of GCH1.

616.12306

Importance du stress oxydant dans le diabète secondaire à la fibrose kystique

Ntimbane, Thierry

12 1900

Introduction : La fibrose kystique (FK) est une maladie génétique mortelle qui touche principalement les poumons et l’appareil digestif. Elle est causée par des mutations sur le gène codant la protéine du CFTR, un canal chlore exprimé à la surface des organes à sécrétions exocrines. Les fonctions principales du CFTR sont les suivantes: 1) la régulation de l’homéostasie ionique des sécrétions; 2) le maintien de la fluidité des sécrétions et; 3) le transport du glutathion. Le dysfonctionnement de la protéine du CFTR rend les sécrétions visqueuses et épaisses, avec des phénomènes obstructifs qui sont responsables de l’apparition de fibrose au sein des divers organes. Dans le poumon, l’accumulation du mucus épais rend difficile l’élimination des bactéries inhalées, ces dernières établissent alors des cycles d’infection qui endommagent les tissus pulmonaires à travers des processus inflammatoires. Dans le tube digestif, le mucus épais entrave l’absorption d’une quantité suffisante d’éléments nutritifs incluant les principaux antioxydants. L’infection et l’inflammation des poumons favorisent l’apparition d’un stress oxydant qui détruit davantage le tissu pulmonaire. Le déficit en glutathion, probablement lié au dysfonctionnement de la proteine du CFTR, et la malabsorption des antioxydants favorisent l’augmentation du stress oxydant. Une augmentation du stress oxydant a été démontrée au cours du diabète et les produits dérivés du stress oxydant ont été mis en évidence dans la pathogenèse des complications associées au diabète. Une augmentation du stress oxydant a également été montrée durant la FK, mais sans pour autant expliquer la survenue du diabète secondaire à la FK dont la prévalence augmente sans cesse. Objectifs : Notre étude consiste à évaluer l’impact du stress oxydant dans les anomalies du métabolisme du glucose durant la FK, et à étudier son rôle dans les mécanismes de sécrétion d’insuline induite par le glucose. Pour ce faire, nous avons déterminé l’impact de la peroxydation lipidique sur la tolérance au glucose et la défense antioxydante globale, in vivo, chez des patients FK présentant une altération du métabolisme du glucose. De plus, nous avons évalué le rôle du stress oxydatif sur la synthèse et la sécrétion d’insuline, in vitro, dans les cellules pancréatiques βTC-tet. Résultats : Dans l’étude in vivo, nous avons démontré que l’intolérance au glucose et le diabète étaient associés à une augmentation de la peroxydation lipidique, traduite par la hausse des niveaux sanguins de 4-hydroxynonenal lié aux protéines (HNE-P). La défense antioxydante évaluée par la mesure du glutathion sanguin démontre que les niveaux de glutathion oxydé restent également élevés avec l’intolérance au glucose. Dans l’étude in vitro, nos résultats ont mis en évidence que l’exposition de la cellule βTC-tet au stress oxydant: 1) induit un processus de peroxydation lipidique; 2) augmente la sécrétion basale d’insuline; 3) diminue la réponse de la sécrétion d’insuline induite par le glucose; et 4) n’affecte que légèrement la synthèse de novo de l’insuline. Nous avons aussi démontré que les cellules pancréatiques βTC-tet résistaient au stress oxydant en augmentant leur synthèse en glutathion tandis que la présence d’un antioxydant exogène pouvait restaurer la fonction sécrétoire de ces cellules. Conclusion : Le stress oxydant affecte le fonctionnement de la cellule pancréatique β de plusieurs manières : 1) il inhibe le métabolisme du glucose dont les dérivés sont nécessaires à la sécrétion d’insuline; 2) il active la voie de signalisation impliquant les gènes pro-inflammatoires et; 3) il affecte l’intégrité membranaire en induisant le processus de peroxydation lipidique. / Introduction: Cystic fibrosis (CF) is the most prevalent lethal genetic disorder affecting mostly lungs and the gastro-intestinal tract. CF is caused by mutations in the gene encoding the CFTR protein, a chloride channel expressed in organs with exocrine secretions. The main functions of the CFTR channel are the following: 1) regulation of electrolyte composition of secretions; 2) maintenance of fluid secretions and; 3) transport of glutathione. The CFTR protein dysfunction leads to thick and viscous secretions with obstructive phenomena responsible for fibrosis occurence in various organs. In the lungs, accumulation of the thick mucus reduces their capacity to eliminate inhaled bacteria responsible for repeated infections and pulmonary tissue damage through inflammatory processes. In the gastro-intestinal tract, the thicknened micus leads to nutritive elements and the major antioxidants malabsorption. Increased oxidative stress has been associated with the onset of diabetes and oxidative stress by-products have been involved in the pathogenesis of diabetic complications. Increased oxidative stress has also been shown in CF but the relationship between oxidative stress and the occurrence of CF-related diabetes (CFRD) remains unclear. Objectives: Our study aims to investigate the role of oxidative stress in the impaired glucose metabolism in CF patients and its relation with the altered glucose-stimulated insulin secretion process. We first determined the impact of lipid peroxidation on glucose tolerance and the antioxidant status in CF patients with altered glucose tolerance. Secondly, we evaluated the role of oxidative stress on insulin synthesis and secretion in the murine pancreatic β-cell line βTC-tet. Results: In CF patients, we demonstrated that conditions of glucose intolerance and diabetes are associated with increased lipid peroxidation as seen with increased blood levels of 4-hydroxynonenal bound to proteins (HNE-P). The antioxidant status evaluated with blood levels of glutathione showed a strong correlation between levels of oxidized glutathione and glucose intolerance. Acute exposure of βTC-tet to oxidative stress led to: 1) increased lipid peroxidation marker levels; 2) increased insulin release in basal conditions; 3) altered glucose-stimulated insulin secretion process and; 4) no effect on the insulin synthessis pathway. We also demonstrated that pancreatic βTC-tet cells can fight against oxidative stress by upregulating their glutathione synthesis whereas the presence of an exogenous antioxidant can restore their secretory function. Conclusion: Oxidative stress can induce β-cell dysfunction through many pathways: 1) it inhibits the glucose metabolism and its by-products which are required for insulin secretion, 2) it activates the signalling pathway involving the pro-inflammatory genes and; 3) it damages the cell structure by inducting the lipid peroxidation process.

Stress oxydant

Oxidative stress

Fibrose kystique

Cystic fibrosis

Diabète

Diabetes

Stress oxydatif, fonction mitochondriale et maladie inflammatoire de l'intestin

Taha, Rame

09 1900

CONTEXTE: Bien que la dysfunction mitochondriale et le stress oxydant jouent des rôles prépondérants dans plusieurs conditions pathologiques, ils n’ont pas été étudiés de façon extensive au niveau du tube digestif qui est constamment exposé aux oxydants (provenant de l’alimentation) et à divers agents pathogènes. L’ingestion simultanée de sels ferreux et d’acide ascorbique peut causer le dommage des macromolécules par oxydation. Le ‘’Nuclear factor erythroid 2 related factor’’ (Nrf2) est un important facteur de transcription sensible au potentiel redox et qui protège contre le stress oxydant en induisant des gènes anti-oxydants et de detoxification par sa liaison à l’élément de réponse antioxydante (ARE). Les fonctions anti-oxydantes et anti-inflammatoires de Nrf2 ont été décrites dans une variété de types cellulaires et de tissus. Cependant son rôle est très peu connu au niveau du tube digestif. OBJECTIFS: Les objectifs sont d’évaluer comment la peroxydation lipidique médiée par le fer/ascorbate (FE/ASC) affecte les fonctions mitochondriales dans les cellules Caco-2/15, et de déterminer l’ampleur de l’implication de Nrf2. MÉTHODES: Le stress oxydant a été induit dans les cellules Caco2/15 en les traitant avec 0.2mm/2mm de FE/ASC. L’augmentation de l’expression de Nrf2 a été obtenue suite au prétraitement des cellules Caco2/15 avec 50 μM d’Olitpraz (OPZ), un puissant activateur. L’invalidation du gène de Nrf2 a été réalisée dans les cellules par transfection avec un vecteur lentiviral contenant un shRNA contre Nrf2. RÉSULTATS: Nos résultats montrent que le traitement des cellules Caco-2/15 avec du FE/ASC (0.2 mm/2 mm) augmente les niveaux du malondialdehyde (MDA), réduit la production d’ATP, entraîne une surcharge mitochondriale de calcium, active l’expression protéique du cytochrome C et de l’AIF (apoptotic inducing factor), réduit l’activité des complexes I, II, 2 III et IV de la chaîne respiratoire mitochondriale, augmente les niveaux de 8-OHdG, un marqueur des dommages à l’ADN mitochondrial, diminue la DNA glycosylase, et altère les expressions génique et protéique des facteurs de transcription mitochondriaux (mtTFA, mtTFB1, mtTFB2). De plus, nos observations montrent que l’induction et l’activation de Nrf2 dans les cellules Caco-2/15 résultent en: une augmentation des enzymes anti-oxydantes endogènes (catalase, glutathion peroxydase, et superoxyde dismutase), une réduction du facteur nucléaire NFκβ et de TNF-α, une augmentation de la production d’ ATP et de l’activité des complexes respiratoires (I, II, III, IV) et de PGC-1α, et une régulation des niveaux de la prohibitine mitochondriale, du Bcl-2 anti-apoptotique et de l’occludine. CONCLUSION: Dans l’ensemble, nos résultats montrent que l’exposition aigüe des cellules Caco-2/15 à la peroxydation par le FE/ASC entraîne des effets pathologiques sur les fonctions mitochondriales et l’intégrité de l’ADN, qui sont abolis par l’induction de Nrf2. Il en ressort que Nrf2 joue un rôle majeur dans la protection de l’épithélium intestinal contre le stress oxydant. / Background: Although mitochondrial dysfunction and oxidative stress are key mechanisms in various pathological conditions, they have not been extensively studied in the gastrointestinal tract, which is known to be constantly exposed to luminal oxidants from ingested foods and pathogens. Key among these is the simultaneous ingestion of iron salts and ascorbic acid, which can cause oxidative damage to macromolecules. The protein ‘’Nuclear factorerythroid 2- related factor’’ (Nrf2) is an important redox-sensitive transcription factor, which protects against oxidative stress by inducing antioxidant and detoxifying genes through binding with antioxidant response element (ARE). Many of Nrf2 antioxidant protective and anti-inflammatory functions have been established in various cells and tissues. However, limited information is available on its role in the gastrointestinal tract. Objectives: The objectives are to evaluate how iron-ascorbate (FE/ASC)-mediated lipid peroxidation affects mitochondrion functioning in Caco-2/15 cells, and to mechanistically determine the role of Nrf2. Methods: Caco2/15 cells were treated with 0.2mm/2mm of FE/ASC to induce oxidative stress. To increase Nrf2 expression, cultured Caco2/15 cells were pre-treated with 50 μM Olitpraz (OPZ). To down regulate the Nrf2 function, Nrf2 gene was knocked down by transfecting Caco-2/15 cells with a pGFP-RS lentiviral vector containing shRNA against Nrf2. 4 RESULTS: Our results show that the treatment of Caco-2/15 cells with FE/ASC (0.2 mm/2 mm): increased the levels of malondialdehyde (MDA), a marker of oxidative stress; reduced ATP production; raised mitochondrial calcium content; regulated the protein expression of cytochrome C and apoptotic inducing factor (AIF); decreased mitochondrial respiratory chain complexes I, II, III and IV activity; prevented mtDNA damage as illustrated by the raised levels of 8-OHdG; lowered DNA Glycosylase, and altered the gene expression and protein mass of mitochondrial transcription factors (mtTFA, mtTFB1, mtTFB2). Furthermore, our observations indicate that the induction and activation of Nrf2 in Caco2/15 cells resulted in an augmentated endogenous antioxidants enzymes (catalase, glutathione peroxidase, and superoxide dismutase), a reduction of nuclear factor-kappaB (NFκβ) and Tumor Necrosis Factor- Alpha (TNF-α), an increase in the ATP production, mitochondrial respiratory complexes (I, II, III, VI), PGC1α , and a regulation of the mitochondrial Prohibitin, anti-apoptotic Bcl-2 protein, and Occludin level. CONCLUSION: Findings indicate that acute exposure of Caco-2/15 cells to FE/ASC-catalyzed peroxidation produces pathological effects on mitochondrial functions and DNA integrity, which were diminished by Nrf2 induction. It appears that Nrf2 plays a critical cytoprotective role in intestinal epithelial cells against oxidative stress.

Stress oxydatif

Oxidative stress

Mitochondrie

Mitochondria

Inflammation

NRF2

Identification and Characterization of Metal Uptake Loci in Porphyromonas gingivalis

He, Jia

01 January 2007

Manganese and iron homeostasis play an important role in oxidative stress protection in a variety of organisms. However, the transport and role of these metals in the periodontal pathogen Porphyromonas gingivalis were not well understood. Analysis of the genome of P. gingivalis W83 revealed the presence of two genes encoding homologs of ferrous iron transport protein, FeoB1 and FeoB2. The goal of this study was to determine the role of these two putative transporters in metal transport, their contributions to resistance to oxygen radicals and intracellular survival as well as the regulation and genetic organization of these two loci. Isogenic mutant strains deficient in FeoB1 and FeoB2, respectively, were generated and used in this study. The transport ability for manganese and iron was assessed and compared in feoB1, feoB2 mutant and wild type strains using 55Fe2+ and 54Mn2+. We demonstrated that feoB2 encodes a major manganese transporter, while FeoB1 functions as a major ferrous iron transporter. The roles of P. gingivalis FeoB1 and FeoB2 in oxidative stress defense and intracellular survival in host cells were determined using an oxidative stress survival assay and an in vitro infection assay, respectively. The feoB2 mutant exhibited reduced survival after exposure to H2O2 and to atmospheric oxygen and inside the host cells compared to the wild-type strain and its revertant, while the feoB1 mutant survived as well as the wild type strain under oxidative stress and possessed better capability to adhere to and survive in the host cells. Our results demonstrate that FeoB2 is required for protection of the bacterium from oxidative stress and for intracellular survival of P. gingivalis in host cells. However, FeoB1 is dispensable for both processes. Quantitative RT-PCR analysis revealed that expression of feoB2 in P. gingivalis is induced by oxidative stress. However, expression of feoB1 increased 2-fold upon exposure to lower growth temperature. Both observed inductions were specific and not detected under other stress conditions. We have also showed in this study that feoB2 is the second gene transcribed in an operon that is composed of a total of five genes and feoB1 is only co-transcribed with one downstream gene encoding a hypothetical protein. Notably, we also identified tandem repeats with potential to form stable stem-loop RNA secondary structure within the feoB2 and feoB1 transcripts.To our knowledge, this study has demonstrated the first connection among metal homeostasis, oxidative stress resistance and response to host cells in the periodontal pathogen, P. gingivalis.

oxidative stress

porphyromonas gingivalis

periodontitis

ROS

iron

metal uptake

manganese

intracellular survival

Medicine and Health Sciences

The Impact of Mental Challenge on Indicators of Endothelial Function in Obese Individuals

Huang, Chun-Jung

01 January 2009

A number of investigators have examined psychological stress-induced endothelial dysfunction, however, the underlying mechanisms for these responses have not been clearly elucidated. The purpose of this study was to compare the effects of mental challenge on forearm blood flow, total antioxidant capacity (a measure of oxidative stress), the release of norepinephrine (NE; stress induced neurotransmitter), and pro-inflammatory cytokine responses [both lipopolysaccharide (LPS)-stimulated TNF-α and IL-6 cytokine and mRNA] in lean and obese individuals. Twelve subjects who had a BMI above 30 kg/m2 and were above 30% body fat were categorized as obese and twelve subjects with a BMI below 25 kg/m2 and were below 25% body fat were categorized as lean subjects. Blood samples were drawn and forearm blood flow was assessed prior to and following subjects’ participation in a mental challenge protocol consisting of a computer-based Stroop Color-Word task and mental arithmetic task, for a total of 20 minutes. The mental challenge elicited an elevation in HR and NE in both the lean and obese groups. Furthermore, both lean and obese groups demonstrated an increase in FBF following the mental challenge, whereas no changes in total antioxidant capacity were observed. In addition, the lean group exhibited an increase in LPS-stimulated TNF-α cytokine production from baseline to following the mental challenge, whereas the obese group demonstrated a decrease in LPS-stimulated TNF-α cytokines. This corresponded with a decrease in LPS-stimulated TNF-α mRNA expression in the obese group, although the obese subjects maintained higher levels of both measurements (LPS-stimulated TNF-α cytokine and mRNA expression) compared with the lean group. Furthermore, in the LPS-stimulated IL-6 cytokine response, the obese group demonstrated a greater increase than the lean group following the mental challenge, even though both groups showed an increase in LPS-stimulated IL-6 mRNA expression. These findings suggest that the magnitude and direction of LPS-stimulated TNF-α cytokine response and mRNA expression and LPS-stimulated IL-6 cytokine response to acute stress may be dependent upon the effects of the additional percentage of body fat seen in obese individuals.

Forearm Blood Flow

Psychological Stress

Obesity

Pro-inflammatory cytokines

Oxidative Stress

Gene expression

Education

ROLE OF OXIDATIVE REACTIVE SPECIES AND ANTIOXIDANTS IN METABOLISM AND TRANSPORT OF THERAPEUTIC DRUGS

Verenich, Svetlana

01 January 2010

Oxidative stress (OS) is a frequent complication of various disease conditions such as Alzheimer’s and Parkinson’s disease, atherosclerosis, preeclampsia, rheumatoid arthritis, diabetes including gestational diabetes, etc. OS is defined as an imbalance between the production of reactive species and the ability of an organism to detoxify the reactive intermediates and repair the damage. As a result of OS, the excess of reactive species such as oxygen superoxide (O2-), hydroxyl radical (OH), peroxynitrite (ONOO−), 4-hydroxynonenal (4HNE), etc., have a tendency to react with nearby proteins/nucleic acids/lipids changing their functionality or inactivating them completely. The organism has many ways to protect itself from the harmful effects of oxidants. One strategy employs antioxidants introduced to the body with food. The purpose of this thesis was to investigate the effect of reactive species on the active transport mediated by ABC efflux transporters as well as exploring the possibility of using antioxidants not as interceptors of reactive species but rather as inhibitors of metabolic enzymes and transporters. The BCRP/ABCG2 efflux transporter was selected for the investigation of the effect of reactive anion, ONOO−, generated during OS and the product of OS, 4HNE, formed after a series of chain reactions involving ROS. Experiments conducted with Sf9 membrane vesicles overexpressing BCRP/ABCG2 revealed that both species are capable of inactivating this ABC transporter with IC50 being 31 ± 2.7 μM and 92 ± 1.4 μM for ONOO− and 4HNE, respectively. In presence of 4HNE, Vmax decreased 4-fold and Km remained unchanged, suggesting a noncompetitive inhibition mechanism. However, with addition of 4HNE, positive cooperativity was also observed. With ONOO−, the situation was different: both Vmax and Km changed consistent with mixed type inhibition. Overall, OS-mediated BCRP/ABCG2 inactivation occurred at biologically relevant concentrations of the reactive species. Antioxidants are substances that are known to reduce the amount of ROS/RNS accumulated during OS, but this research considered the use of antioxidants not only as interceptors of ROS/RNS but rather as inhibitors of metabolic enzymes. The effect of the dietary antioxidant, quercetin (Qc), on the metabolism of 2-methoxyestradiol (2Me-E2), a promising potential anticancer agent was investigated. Qc possesses five hydroxyl groups, several of which are targets for UDP-glucuronosyltransferases (UGTs). Thus, the simultaneous presence of Qc and 2Me-E2 could result in decreased glucuronidation of 2Me-E2. Using the LS180 intestinal human colon adenocarcinoma cell line, glucuronidation of 2Me-E2 resulted in formation of only one major glucuronide, 2-Methoxyestradiol-3-glucuronide (2Me-E2-3G). Qc effectively reduced its formation (IC50 = 7.8 ± 0.26 μM) to a minimum level. The decrease in the activity of UGTs increased the intracellular concentration of parent 2Me-E2. Additional increase in cellular concentration of 2Me-E2 was achieved when LS180 cells were pre-incubated with Qc prior the addition of 2Me-E2. Transwell experiments with MDCKII – BCRP cells revealed that BCRP/ABCG2 did not appear to transport 2Me-E2. All in all, the present study showed that OS has a negative impact on active transport mediated by ABC transporters. This, in turn, can affect drug disposition and protection of endogenous organs and tissues. Antioxidants are one of the mechanisms that can effectively reduce the negative impact caused by oxidative species. Nevertheless, this research revealed that they can also be an effective tool to reduce the excessive metabolism of therapeutic drugs. Thus, Qc was found to be a dietary antioxidant that could reduce metabolism of 2Me-E2 and increase it intracellular concentration.

Oxidative stress

ABC transporters

Quercetin

2-Methoxyestradiol

Metabolism

Inhibition

Medicine and Health Sciences

Pharmacy and Pharmaceutical Sciences