The role of MnSOD and sirtuin 3 in thymocyte responses to radiation and lymphomagenesis

Mao, Gaowei

01 May 2013

Manganese superoxide dismutase (MnSOD), is a mitochondria-localized antioxidant enzyme that scavenges superoxide anions generated in the respiratory chains, has been known to play an important role in the radioprotection, and function as a tumor suppressor gene in many types of cancer. Sirtuin 3 (Sirt3) is a mitochondrial NAD+-dependent deacetylase that regulates mitochondrial oxidative metabolism, MnSOD activity, and tumorigenesis. The current study was designed to examine the role of MnSOD and Sirt3 in regulating mitochondrial metabolism and steady-state levels of O2*- in thymocyte responses to ionizing radiation (IR) and lymphomagenesis. Loss of MnSOD in thymocytes resulted in the decreased levels of viability when mice were exposed to 0.1 or 1 Gy 137Cs radiation. In contrast, loss of Sirt3 did not affect thymocyte radiosensitivity or radiation-induced superoxide levels when mice were exposed to a single dose of 137Cs radiation (0.1 or 1 Gy). Interestingly, the Sirt3-/- thymocytes demonstrated a compromised ability to induce an adaptive response following whole body exposure to a 0.1 Gy dose of 137Cs radiation when challenged 4 h later with a 1.5 Gy dose of 137Cs radiation. Of note, both Sirt3-/- and MnSOD-/- thymocytes did not demonstrate increased T cell lymphoma in C57BL/6 mice at 15-18 months following low dose (0.1 Gy or 1 Gy) radiation exposure to low linear energy transfer (LET) 137Cs or high LET 300 MeV/n Silicon (67 kev/µM) irradiation. Interestingly, the loss of Sirt3 in Bax overexpressing transgenic thymocytes did cause significant alterations in mitochondrial oxidative metabolism including increased levels of superoxide, increased mitochondrial membrane potential, and increased oxygen consumption, as well as decreased levels of MnSOD activity and decreased steady-state levels of ATP. Sirt3 was also found to be upregulated in Lck-Bax transgenic pre-malignant thymocytes, and downregulation of Sirt3 was noted in lymphomas from Lck-Bax mice. Furthermore, a significant acceleration of thymic lymphoma development was observed in Lck-Bax transgenic animals lacking Sirt3. In conclusion, the data presented here support the hypothesis that increased levels of superoxide in thymocytes induced by loss of Sirt3 or MnSOD and/or exposure to low dose radiation was not sufficient to induce T cell lymphomas. However, loss of Sirt3 significantly accelerated thymic lymphoma formation induced in Lck-Bax overexpressing C57BL/6 mice, showing that Sirt3 could act as a tumor suppressor in this model system. These results also support the speculation that mitochondrial oxidative metabolism regulated by Sirt3 leads to increased steady-state levels of O2*- and may contribute to the promotion of carcinogenesis in the Lck-Bax model of T cell lymphoma development.

Lymphoma

MnSOD

Radiation

Sirtuin 3

Superoxide

Thymocyte

Manganese superoxide dismutase (MnSOD) 3'-untranslated region: a novel molecular sensor for environmental stress

Chaudhuri, Leena

01 December 2010

Eukaryotic gene expression is a complex process and can be controlled at the level of transcription, post-transcription or translation and post-translation. In recent years, there is a growing interest in understanding the role of 3'-untranslated region (UTR) in regulating mRNA turnover and translation. The 3'-UTR harbors the poly(A) signal and post-transcriptional regulatory sequences like miRNA and AU-rich elements (AREs). The presence of multiple poly(A) sites often results in multiple transcripts; shorter transcripts correlating with more protein abundance. Manganese superoxide dismutase (MnSOD) is a nuclear encoded and mitochondrial matrix localized antioxidant enzyme that converts mitochondrial generated superoxide to hydrogen peroxide. Human MnSOD has two poly(A) sites resulting in two transcripts: 1.5 and 4.2 kb. We hypothesize that the 3'-UTR of MnSOD regulates its mRNA and protein levels as well as activity in response to growth states and environmental stress. Results from a Q-RT-PCR assay showed a preferential accumulation of the shorter MnSOD transcript during quiescence, which correlated with an increase in MnSOD activity. The accumulation of the longer MnSOD transcript during proliferation was associated with a decrease in MnSOD activity. Log transformed expression ratio of the longer to shorter transcript was also higher in proliferating epithelial non-cancerous (mammary: MCF-10A) and cancer cells (mammary: MB-231, SUM 159; oral squamous: SQ20B, FaDu, Cal27; and lung: A549, H292), suggesting that the abundance of the longer transcript is independent of cellular transformation status, instead it is dependent on cellular growth state. Interestingly, the abundance of the longer transcript directly correlated with percent S-phase (R2=0.86). The shorter transcript was enriched in irradiated MB-231 cells. MCF-10A cells exposed to 2-(4-chlorophenyl)benzo-1,4-quinone (4-Cl-BQ), a metabolite of the environmental pollutant polychlorinated biphenyl 3, showed a significant decrease in the abundance of the 4.2 kb transcript due to a faster mRNA turnover, 14 h compared to 20 h in untreated control cells. The decrease in the 4.2 kb transcript levels was associated with a corresponding decrease in MnSOD protein levels and activity, which resulted in a significant inhibition of quiescent cells entry into the proliferative cycle. Deletion and reporter assays showed: (a) a significant decrease in reporter activity in constructs carrying multiple AREs that are present in the 3'-UTR of the longer MnSOD transcript; (b) irradiation increased the reporter activity of the constructs carrying the 3'-UTR sequence of the shorter MnSOD transcript and (c) N-acetyl-cysteine increased the reporter activity of constructs carrying multiple AREs. Because the longer transcript carries AREs, our results identified redox sensitive AREs as novel regulators of MnSOD transcript levels. We conclude that MnSOD 3'-UTR is a novel molecular sensor regulating MnSOD mRNA levels in response to different growth states and environmental stress. A better understanding of the 3'-UTR regulating gene expression could lead to the development of new molecular biology-based redox therapy designed to treat proliferative disorders.

3'-untranslated region

Cancer

Cell cycle

Manganese superoxide dismutase

Tumor suppressor

Sirtuin 3 is a critical regulator of liver superoxide metabolism during early and late effects of whole body irradiation

Coleman, Mitchell Carl

01 December 2012

Mitochondrial superoxide production during the early and late radiation response is increasingly recognized as a critical driver of oxidative damage and injury processes in mammalian cells. The role of Sirtuin 3, a key mitochondrial regulatory deacetylase, in preventing mitochondrial superoxide generation in conditions of nutrient and oxidative stress may be critical during the radiation response in mammalian liver. Because several tumor types express lower than normal levels of Sirtuin 3, the involvement of Sirtuin 3 in the radiation response may also provide clues to improving cancer radiation therapy and understanding the process of carcinogenesis. Studies of how the SIRT3 loss impacts the hepatic radiation response may also provide insight into the role of superoxide in normal liver physiology as well as in conditions of pathology. Increased superoxide production has largely been associated with disease, but oftentimes without clear demonstration of mechanism or even clear descriptions of pathogenesis. Here we identify a target of Sirtuin 3, the mitochondrial antioxidant enzyme manganese superoxide dismutase, and delineate the role that Sirtuin 3-mediated increases in manganese superoxide dismutase may be playing in the prevention of injury following biologically relevant doses of low linear energy transfer and high linear energy transfer radiation types including Cs-137 and Fe and Si particle radiation. Loss of Sirtuin 3 appears to correlate with decreases in hepatocellular carcinoma 16 months after 0.1 and 1 Gy doses of particle radiation known to increase hepatocellular carcinoma rates. These results indicate that Sirtuin 3 is a critical regulator of superoxide metabolism in the liver following whole body irradiation.

Free Radicals

Liver Injury

Oxidative Stress

Radiation

Sirtuin 3

Superoxide

Copper-zinc superoxide dismutase and glucose metabolism as redox targets for bortezomib resistance in multiple myeloma

Salem, Kelley

01 December 2014

Multiple myeloma (MM) is a prevalent B-cell neoplasm that remains incurable with currently available chemotherapeutic drugs. Existing drug regimens result in initial disease remission but MM often relapses with an aggressive, drug resistant phenotype with uniform mortality. Bortezomib (BTZ, proteasome inhibitor) is a frontline anti-MM drug that is used for treatment of newly diagnosed and relapsed MM. However both intrinsic and acquired BTZ resistance is observed. Hence, gaining a mechanistic understanding of BTZ-resistance can provide novel targets to increase and restore BTZ cytotoxicity in MM. Studies show that BTZ-mediated proteasome inhibition generates oxidative stress therefore, BTZ resistance can be caused by an increase in cellular antioxidant capacity of MM cells. Antioxidants like superoxide dismutases (SODs), glutathione (GSH), and glutathione peroxidases (GPxs) can maintain cellular redox homeostasis and confer resistance to oxidative stress. Additionally, an increased glucose metabolism can assist in maintaining low reactive oxygen species (ROS) levels formed as by-products of endogenous or therapy induced oxidative stress. This led us to test the hypothesis that BTZ resistance in MM is linked to redox regulation via the antioxidant network and generation of reducing equivalents. Retrospective analysis of clinically annotated MM dataset shows a correlation between SOD1 gene expression, MM progression, and poor overall and event free survival. In a MM cell line model with intrinsic or acquired BTZ resistance, our results show a correlation between half maximal inhibitory concentration (IC50) of BTZ and CuZnSOD activity. Upon inhibition of CuZnSOD activity with a clinically approved drug, disulfiram (DSF, Antabuse), BTZ cytotoxicity was increased. Furthermore, enforced overexpression of CuZnSOD conferred BTZ resistance in an otherwise BTZ sensitive MM cell line. MM cell lines with differential intrinsic BTZ cytotoxicity displayed a correlation between BTZ IC50 and GSH levels as well as GPx-1 activity. Gene expression profiling data from patients showed that poor prognosis associates with increased glycolytic gene expression in MM. Also, MM cell lines with intrinsic resistance toward BTZ exhibited increased glucose uptake, increased mRNA expression and activity of glucose-6-phosphate dehydrogenase (G6PD) with increased cytotoxicity with glucose deprivation or 2-deoxyglucose (2-DG) treatment. In conclusion, our results provide a rationale for utilizing redox-based combination protocols of clinically approved drugs (i.e. DSF and 2-DG) with BTZ to improve MM therapy responses.

publicabstract

Glucose

Multiple Myeloma

Redox

Superoxide Dismutase

Influence of haem availability on the viability of Porphyromonas gingivalis and Prevotella intermedia, following exposure to reactive oxygen species

Mackie, Tasha A, n/a

January 2007

Objectives: This investigation adapted the LIVE/DEAD� Baclight[TM] bacterial viability stain for the quantitative determination of bacterial cell viability of the aerotolerant anaerobes Porphyromonas gingivalis ATCC 33277 and Prevotella intermedia ATCC 25611. The Live/Dead stain was used to determine the influence of haem availability on the resistance of P. gingivalis and P. intermedia to the reactive oxygen species (ROS) superoxide anion and hydrogen peroxide and compare the sensitivities between the haem-requiring periodontal bacteria to ROS. Neutrophils use oxidative and non-oxidative killing mechanisms. During phagocytosis, neutrophils kill bacteria via a respiratory burst, producing ROS. P. gingivalis and P. intermedia are oxygen-tolerant gram-negative bacteria found in the gingival crevice. These bacteria express superoxide dismutase (SOD) activity, which extends some protection against superoxide radicals. Methods: Initially, experiments were performed to validate the reliability and accuracy of the fluorogenic Live/Dead stain using Escherichia coli ATCC 10798 (K-12), followed by experiments using P. gingivalis. The Live/Dead stain distinguishes viable:non-viable proportions of bacteria using mixtures of green (SYTO 9) and red (propidium iodide) fluorescent nucleic acid stains respectively. Bacterial cell viability was assessed with fluorescence microscopy and subsequently quantitative measurement using a fluorescence microplate reader (BMG Fluorostar plus Optima). P. gingivalis and P. intermedia colonies were subcultured from frozen cultures, in Tryptic soy broth (TSB) (Difco) and incubated anaerobically for approximately five days. They were further subcultured in pre-reduced TSB, supplemented with menadione 0.5[mu]g/ml (TSB-M) and either 5 [mu]g/ml haemin (Haem 5), 50 [mu]g/ml haemin (Haem 50) or without supplemental haemin (Haem 0). Cultures were grown anaerobically at 37�C to early stationary phase (approximately 48 hours). For experimental purposes, bacteria were harvested, washed and resuspended in 10 mM Tris-buffered saline (pH 7.5) containing peptone (TBS-P) (0.1 mg/ml), with a final adjustment to OD₅₄₀ [approximately equals] 2.0 (which corresponds to 1 x 10⁹ bacteria/ml). Bacterial suspensions were diluted ([approximately equals] 10⁸/ml) into TBS-P containing the fluorogenic viability stain (BacLight, Molecular Probes). Either pyrogallol (0.02 - 2 mM) or hydrogen peroxide (0.01 - 100 mM) was added (except to control tubes); tubes were vortexed for ten seconds and incubated at 37�C. Viability was monitored fluorimetrically for three hours. Results: For both P. gingivalis and P. intermedia, a pyrogallol concentration of 0.2 mM resulted in 80 to 90% cell death; and a hydrogen peroxide concentration of 10 mM killed approximately 80 to 90% of cells. Irrespective of the haem status, no significant difference was determined between the overall maximum rate of killing of P. gingivalis and P. intermedia, in their response to either superoxide or hydrogen peroxide; with the exception that the P. intermedia Haem 0 group was significantly less susceptible to hydrogen peroxide than the P. gingivalis Haem 0 group. For the majority of the experiments, there was no significant difference between final bacterial cell viability in the Haem 0 and Haem 5 cells for both species, after 3 hours exposure to various concentrations of ROS. However, the Haem 50 cells showed a significant increased susceptibility (albeit, a small difference) to both hydrogen peroxide and superoxide. Conclusions: The Live/Dead bacterial viability stain provided a valuable method to monitor "real-time" killing, avoiding the difficulties associated with culture-based methods for assessing viability. Haem availability had no clear influence on the resistance to ROS of either P. gingivalis or P. intermedia Haem 0 and Haem 5 cells. The Haem 50 cells showed a very slight increase in susceptibility to hydrogen peroxide and superoxide. Although P. intermedia may be isolated in significant numbers from healthy gingivae, as well as from periodontally diseased sites, it was no more resistant to ROS than was P. gingivalis, which is associated with periodontal lesions and difficult to cultivate from relatively healthy (more oxygenated) sites. This suggests that resistance to ROS does not contribute to the ecological distinction between these two species. The finding that haem availability did not influence sensitivity implies that these bacteria do not accumulate haem for the purpose of protection from ROS.

porphyromonas gingivalis

prevotella intermedia

active oxygen

superoxide

hydrogen peroxide

bacterial

cell surfaces

Oxy radicals and control of inflammation / by Leslie G. Cleland

Cleland, Leslie G. (Leslie Glenn)

January 1984

Bibliography: leaves 161-204 / xv, 204 leaves : / Title page, contents and abstract only. The complete thesis in print form is available from the University Library. / Thesis (M.D.)--University of Adelaide, Dept. of Medicine and Pathology, 1985

616.0473 19

Inflammation Etiology.

Superoxide dismutase Metabolism.

Prostaglandins Metabolism.

Leukotrienes Synthesis.

Anti-inflammatory agents.

Les risques de l'amiante dans les Alpes occidentales: utilisation des champignons du sol pour la bioremediation des fibres d'amiante présentes dans l'environnement; une analyse chimico-moléculaire.

Daghino, Stefania

16 December 2005

L'étude de l'impact des champignons sur les processus géologiques qui altèrent les mineraux s'appelle la “géo-mycologie”. <br />Les serpentinites sont des roches de la famille des ophiolites et peuvent contenir du chrysotile (amiante serpentine).<br />La réactivité des fibres d'amiante est due à la composition chimique de surface et principalement à la présence d'ions métalliques qui peuvent catalyser des réactions chimiques dangereuses. L'amiante est un problème ambiantale à cause de la présence de roches contenant ce minéral mais aussi à cause des anciennes mines d'amiante. La revalorisation (remediation) de ces sites naturellement contaminés passe par la modification de la toxicité des fibres. Les champignons sont des bons candidats pour la bioremediation de l'amiante.<br />L'objectif de cette thèse est l'isolement de souches fongiques à partir de sols serpentiniques afin de savoir quelles sont les espèces fongiques les plus abondantes dans ces sols et de sélectionner les souches les plus efficaces pour leur interaction avec les fibres d'amiantes. Les modifications des fibres et l'altération du métabolisme fongique ont été considérés.<br />Verticillium leptobactrum semble être l'espèce fongique dominante dans tous les sols serpentiniques examinés : cette espèce n'avait jusque là été que rarement isolée, ce qui rend ces résultats intéressants. <br />Trois espèces fongique peuvent extraire Fe et Mg des fibres de amiante (chrysotile et crocidolite), en modifiant la composition et la réactivité chimique de la surface de fibres et la génotoxicité mesuré dans un système acellulaire.<br />Les champignons expriment, en présence des fibres, des enzymes liés à la réponse aux stress oxydants.

[SDV:OT] Life Sciences/Other

amiante

champignons

fer

ADN

radicaux libres

siderophores

superoxide-dismutase

bioremediation

On the Role of Mitochondria in the Regulation of Calcium in Motor Nerve Terminals During Repetitive Stimulation

Garcia-Chacon, Luis Ernesto

20 April 2008

During repetitive stimulation of motor nerve terminals, mitochondrial Ca2+ uptake limits increases in free cytosolic [Ca2+] and helps ensure faithful neuromuscular transmission. Changes in cytosolic [Ca2+] and in mitochondrial [Ca2+] as well as changes in mitochondrial membrane potential (Psi m) were studied in mouse motor nerve terminals using Ca2+ sensitive indicator and potentiometric dyes, respectively. Trains of action potentials (APs) at 50 to 100 Hz produced a rapid increase in mitochondrial [Ca2+] followed by a plateau which usually continued beyond the end of stimulation. After stimulation, mitochondrial [Ca2+] decayed back to baseline over the course of tens of seconds to minutes. Increasing the Ca2+ load delivered to the terminal by increasing the number of stimuli (500-2000), increasing bath [Ca2+], or prolonging the AP with 3,4-diaminopyridine (3-4, DAP, 100 micromolar), prolonged the post-stimulation decay of mitochondrial [Ca2+] without increasing the amplitude of the plateau. Inhibiting openings of the mitochondrial permeability transition pore with cyclosporin A (5 micromolar) had no significant effect on the decay of mitochondrial [Ca2+]. Inhibition of the mitochondrial Na+-Ca2+ exchanger with CGP-37157 (50 micromolar) dramatically prolonged the post-stimulation decay of mitochondrial [Ca2+], reduced post-stimulation residual cytosolic [Ca2+], and reduced the amplitude of end-plate potentials evoked after the end of stimulation. Stimulation-induced mitochondrial Ca2+ uptake resulted in Psi m depolarizations that were small or undetectable at near-physiological temperatures (~30 degrees C). Their amplitude became larger at lower temperatures (~20 degrees C), or when AP duration was increased with 3,4-DAP (20 micromolar). Psi m depolarizations were inhibited by lowering bath [Ca2+] or by blocking P/Q-type Ca2+ channels with omega-agatoxin (0.3 micromolar). Partial inhibition of complex I of the electron transport chain (ETC) with rotenone (50 nM) increased the amplitude of stimulation-induced Psi m depolarizations. These findings suggest that: (1) Ca2+ extrusion from motor terminal mitochondria occurs primarily via the Na+-Ca2+ exchanger and helps sustain post-tetanic transmitter release, and (2) that the depolarization of Psi m that accompanies Ca2+ uptake is limited by accelerated proton extrusion via the ETC.

Proteinmultischichten und Proteinmutanten für neuartige empfindliche Superoxidbiosensoren / Protein Multilayers and Protein Mutants for novel sensitive Superoxide Biosensors

Beissenhirtz, Moritz Karl

January 2005

Das Superoxidradikal kann mit fast allen Bestandteilen von Zellen reagieren und diese schädigen. Die medizinische Forschung stellte eine Beteiligung des Radikals an Krebs, Herzinfarkten und neuraler Degeneration fest. Ein empfindlicher Superoxidnachweis ist daher zum besseren Verständnis von Krankheitsverläufen wichtig. Dabei stellen die geringen typischen Konzentrationen und seine kurze Lebensdauer große Anforderungen. Ziel dieser Arbeit war es zum einen, zwei neuartige Proteinarchitekturen auf Metallelektroden zu entwickeln und deren elektrochemisches Ansprechverhalten zu charakterisieren. Zum anderen waren diese Elektroden zur empfindlichen quantitativen Superoxiddetektion einzusetzen. Im ersten Teil der Arbeit wurde eine Protein-Multischichtelektrode aus Cytochrom c und dem Polyelektrolyten Poly(anilinsulfonsäure) nach dem Layer-by-layer-Verfahren aufgebaut. Für zwei bis 15 Schichten an Protein wurde eine deutliche Zunahme an elektrodenaktivem Cytochrom c mit jedem zusätzlichen Aufbringungsschritt nachgewiesen. Die Zunahme verlief linear und ergab bei 15 Schichten eine Zunahme der redoxaktiven Proteinmenge um deutlich mehr als eine Größenordnung. Während das formale Potential im Multischichtsystem sich im Vergleich zur Monoschichtelektrode nicht veränderte, wurde für die Kinetik eine Abhängigkeit der Geschwindigkeit des Elektronentransfers von der Zahl der Proteinschichten beobachtet. Mit zunehmender Scangeschwindigkeit trat ein reversibler Kontaktverlust zu den äußeren Schichten auf. Die lineare Zunahme an elektroaktivem Protein mit steigender Zahl an Depositionsschritten unterscheidet sich deutlich von in der Literatur beschriebenen Protein/Polyelektrolyt-Multischichtelektroden, bei denen ab etwa 6-8 Schichten keine Zunahme an elektroaktivem Protein mehr festgestelltwurde. Auch ist bei diesen die Zunahme an kontaktierbaren Proteinmolekülen auf das Zwei- bis Fünffache limitiert. <br><br> Diese Unterschiede des neu vorgestellten Systems zu bisherigen Multischichtassemblaten erklärt sich aus einem in dieser Arbeit für derartige Systeme erstmals beschriebenen Elektronentransfermechanismus. Der Transport von Elektronen zwischen der Elektrodenoberfläche und den Proteinmolekülen in den Schichten verläuft über einen Protein-Protein-Elektronenaustausch. Dieser Mechanismus beruht auf dem schnellen Selbstaustausch von Cytochrom c-Molekülen und einer verbleibenden Rotationsflexibilität des Proteins im Multischichtsystem. Die Reduzierung des Proteins durch das Superoxidradikal und eine anschließende Reoxidation durch die Elektrode konnten nachgewiesen werden. In einem amperometrischen Messansatz wurde das durch Superoxidradikale hervorgerufene elektrochemische Signal in Abhängigkeit von der Zahl an Proteinschichten gemessen. Ein maximales Ansprechverhalten auf das Radikal wurde mit 6-Schichtelektroden erzielt. Die Empfindlichkeit der 6-Schichtelektroden wurde im Vergleich zum Literaturwert der Monoschichtelektrode um Faktor 14, also mehr als eine Größenordnung, verbessert. <br><br> Somit konnte eine Elektrode mit 6 Schichten aus Cytochrom c und Poly(anilinsulfonsäure) als neuartiger Superoxidsensor mit einer 14-fachen Verbesserung der Empfindlichkeit im Vergleich zum bislang benutzten System entwickelt werden. <br><br> Der zweite Teil dieser Arbeit beschreibt die Auswahl, Gewinnung und Charakterisierung von Mutanten des Proteins Cu,Zn-Superoxiddismutase zur elektrochemischen Quantifizierung von Superoxidradikalen. Monomere Mutanten des humanen dimeren Enzyms wurden entworfen, die durch Austausch von Aminosäuren ein oder zwei zusätzliche Cysteinreste besaßen, mit welchem sie direkt auf der Goldelektrodenoberfläche chemisorbieren sollten. 6 derartige Mutanten konnten in ausreichender Menge und Reinheit in aktiver Form gewonnen werden. Die Bindung der Superoxiddismutase-Mutanten an Goldoberflächen konnte durch Oberflächen-plasmonresonanz und Impedanzspektroskopie nachgewiesen werden. Alle Mutanten wiesen einen quasi-reversiblen Elektronentransfer zwischen SOD und Elektrode auf. Durch Untersuchung von kupferfreien SOD-Mutanten sowie des Wildtyps konnte nachgewiesen werden, das die Mutanten über die eingefügten Cysteinreste auf der Elektrode chemisorptiv gebunden wurden und der Elektronentransfer zwischen der Elektrode und dem Kupfer im aktiven Zentrum der SOD erfolgte. <br><br> Die Superoxiddismutase katalysiert die Zersetzung von Superoxidmolekülen durch Oxidation und durch Reduktion der Radikale. Somit sind beide Teilreaktionen von analytischem Interesse. Zyklovoltammetrisch konnte sowohl die Oxidation als auch die Reduktion des Radikals durch die immobilisierten Superoxiddismutase-Mutanten nachgewiesen werden. In amperometrischen Messanordnungen konnten beide Teilreaktionen zur analytischen Quantifizierung von Superoxidradikalen genutzt werden. Im positiven Potentialfenster wurde die Empfindlichkeit um einen Faktor von etwa 10 gegenüber der Cytochrom c–Monoschichtelektrode verbessert. / The superoxide radical can react with almost all components of a cell and thus damage them. Enzymatic and non-enzymatic scavengers remove it from the body. An implication of the radical in cancer, heart disease, and neuronal degredation has been found in medical research. Therefore, a sensitive quantification of superoxide is necessary for a better understanding of diseases as well as for the study of biological degradation processes. <br><br> The aim of this work was to develop two new protein architectures on metal electrodes and to characterize their electrochemical behavior. Secondly, both electrodes were to be applied as superoxide biosensors. <br><br> In the first part of the work, a protein multilayer electrode consisting of cytochrome c and the polyelectrolyte poly(aniline sulfonated acid) was built up by the layer-by-layer procedure. SPR experiments proved the formation of multilayers. For 2 to 15 protein layers, a significant increase in electroactive protein was found with every deposition step in a linear fashion. For 15 layers, this increase was found to be more than one order of magnitude. While the formal potential did not change for the proteins in the layers, the rate of electron transfer was found to be dependent on the number of layers deposited. With increased scanning speed, a reversible loss of contact to the outer layers was noted. The linear increase in electroactive protein loading differed significantly from protein/polyelectrolyte electrodes described in the literature, where after 6-8 layers no further increase was found. Additionally, these systems increase the number of electroactive protein molecules only by a factor of 2 to 5. <br><br> These differences can be explained by an electron transfer mechanism which was demonstrated in this work for the first time. The transport of electrons between the electrode surface and the proteins in the layers takes place by a protein-protein electron transfer. This mechanism relies on the fast self-exchange of cytochrome c and a residual rotational flexibility of the protein molecules inside the structure. The reduction of the protein by the radical and its subsequent reoxidation by the electrode could be shown. In the amperometric mode, the sensor signal was determined for 2 to 15 layer electrodes. A maximum signal was found for 6 layers, where the sensitivity was improved by a factor of 14, compared to monolayer sensors. <br><br> The second part of this work describes the selection, production and characterization of mutants of the protein Cu,Zn-superoxide dismutase and their application as superoxide sensors. Monomeric mutants of the human dimeric enzyme were designed, which contained one ore two additional cysteines in order to chemisorb directly onto gold surfaces. 6 such mutants were gained in sufficient amount and purity. The binding to gold was characterized by surface plasmon resonance studies. All mutants showed quasi-reversible electrochemistry on gold electrodes. Experiments with copper-free mutants and the wildtype enzyme proved that the mutants bind to gold via the additional cysteines, while the electron transfer takes place between the electrode and the active site copper. Superoxide dismutases catalyze the removal of superoxide by both oxidation and reduction. Thus, both partial reactions are of analytical interest. In cyclic voltammetry, both oxidation and reduction of the radical could be proved. In amperometric experiments, both reactions were used for a quantification of superoxide concentrations. In the positive potential window, the sensitivity was found to be increased by about one order of magnitude, as compared to the cytochrome c monolayer electrode.<br> -----------<br><br> <b>Hinweis zum Copyright:</b><br>Einige Abbildungen dieser Arbeit sind in Artikeln des Verfassers in den Zeitschriften <i>Angewandte Chemie, Angewandte Chemie International Edition, Analytical Chemisty</i> und <i>Elektroanalysis</i> erschienen.<br> Ihre Darstellung im Rahmen dieser Arbeit erfolgt auch online mit ausdrücklicher Genehmigung der Verlage.

Biosensor

Superoxiddismutasen

Hyperoxide

Mutation

Cytochrom c

Polyelektrolyt

Biosensor

Cytochome c

Superoxide Dismutase

Mutations

Multilayers

Life sciences

Engineered human cytochrome c : investigation of superoxide and protein-protein interaction and application in bioelectronic systems

Wegerich, Franziska

January 2010

The aim of this thesis is the design, expression and purification of human cytochrome c mutants and their characterization with regard to electrochemical and structural properties as well as with respect to the reaction with the superoxide radical and the selected proteins sulfite oxidase from human and fungi bilirubin oxidase. All three interaction partners are studied here for the first time with human cyt c and with mutant forms of cyt c. A further aim is the incorporation of the different cyt c forms in two bioelectronic systems: an electrochemical superoxide biosensor with an enhanced sensitivity and a protein multilayer assembly with and without bilirubin oxidase on electrodes. The first part of the thesis is dedicated to the design, expression and characterization of the mutants. A focus is here the electrochemical characterization of the protein in solution and immobilized on electrodes. Further the reaction of these mutants with superoxide was investigated and the possible reaction mechanisms are discussed. In the second part of the work an amperometric superoxide biosensor with selected human cytochrome c mutants was constructed and the performance of the sensor electrodes was studied. The human wild-type and four of the five mutant electrodes could be applied successfully for the detection of the superoxide radical. In the third part of the thesis the reaction of horse heart cyt c, the human wild-type and seven human cyt c mutants with the two proteins sulfite oxidase and bilirubin oxidase was studied electrochemically and the influence of the mutations on the electron transfer reactions was discussed. Finally protein multilayer electrodes with different cyt form including the mutant forms G77K and N70K which exhibit different reaction rates towards BOD were investigated and BOD together with the wild-type and engineered cyt c was embedded in the multilayer assembly. The relevant electron transfer steps and the kinetic behavior of the multilayer electrodes are investigated since the functionality of electroactive multilayer assemblies with incorporated redox proteins is often limited by the electron transfer abilities of the proteins within the multilayer. The formation via the layer-by-layer technique and the kinetic behavior of the mono and bi-protein multilayer system are studied by SPR and cyclic voltammetry. In conclusion this thesis shows that protein engineering is a helpful instrument to study protein reactions as well as electron transfer mechanisms of complex bioelectronic systems (such as bi-protein multilayers). Furthermore, the possibility to design tailored recognition elements for the construction of biosensors with an improved performance is demonstrated. / Ziel dieser Arbeit ist es genetisch veränderte Formen von humanem Cytochrom c herzustellen und diese einerseits hinsichtlich der Reaktion mit dem Sauerstoff-Radikal Superoxid aber auch mit anderen Proteinen zu untersuchen. Zusätzlich sollen die verschiedenen Protein-Mutanten in neuartige bioelektronische Systeme eingebracht werden. Es wurden insgesamt 20 Cytochrome c Mutanten designt, rekombinant exprimiert und aufgereinigt. Es konnte in dieser Arbeit gezeigt werden, dass sich die Reaktion von Cytochrom c mit dem negativ geladenen Superoxid durch gezielte Mutationen, die zusätzliche positive Ladungen in das Molekül bringen, um bis zu 30 % erhöhen lässt. Es wurde aber auch deutlich, dass andere Eigenschaften des Proteins sowie dessen Struktur durch die Mutationen geändert werden können. Cytochrom c Mutanten mit einer erhöhten Reaktionsrate mit Superoxid konnten erfolgreich in einen Superoxid-Biosensor mit erhöhter Sensitivität eingebracht werden. Weiterhin wurde einige Mutanten hinsichtlich Ihrer Interaktion mit den zwei Enzymen Sulfitoxidase und Bilirubinoxidase untersucht. Hier konnten ebenfalls unterschiedliche Reaktivitäten festgestellt werden. Schließlich wurden ausgewählte Protein-Varianten mit und ohne den zuvor untersuchten Enzymen in ein Multischicht-Elektroden-System eingebettet und dessen kinetisches Verhalten untersucht. Es wurde gefunden, dass die Schnelligkeit mit der Cytochrom c mit sich selbst Elektronen austauschen kann, eine Limitierung der Größenordnung der katalytischen Ströme darstellt. Diese Selbstaustausschrate wurde durch die eingeführten Mutationen verändert. So verdeutlicht diese Arbeit, dass „Protein-Engineering“ ein gutes Hilfsmittel sein kann, um einerseits Proteinreaktionen und komplexe Elektronentransferreaktionen in Multischichten zu untersuchen, aber auch ein potentes Werkzeug darstellt mit dem zugeschnittene Biokomponenten für Sensoren mit erhöhter Leistungsfähigkeit generiert werden können.

Cytochrom c

Protein-Engineering

Elektrochemie

Biosensor

Superoxid

cytochrome c

protein engineering

electrochemistry

biosensor

superoxide

Life sciences