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9. Thiyl Radical Reaction with Amino Acid Side Chains:  Rate Constants for Hydrogen Transfer and Relevance for Posttranslational Protein Modification

Author

Nauser, T., Pelling, J., and Schoneich, C.

Abstract

Thiyl radicals are prominent intermediates during biological conditions of oxidative stress and have been suggested to be involved in the mutagenic effects of thiols. While several enzymatic processes rely on the formation and selective reactions of protein thiyl radicals with substrates, such reactions may represent a source for biological damage when occurring uncontrolled during oxidative stress. For example, intramolecular hydrogen transfer reactions to protein cysteine thiyl radicals may lead to secondary amino acid oxidation products, which may represent starting points for protein aggregation and/or fragmentation. Here, we have used a kinetic NMR method to determine rate constants, ksc, for hydrogen transfer reactions between thiyl radicals and amino acid side chain C−H bonds at 37 °C. Rate constants cover a range between ksc ≤ 1 × 103 M-1 s-1 (Val) and ksc = 1.6 × 105 M-1 s-1 (Ser). On the basis of these values and earlier data, model calculations are performed, which will demonstrate that protein thiyl radicals may attack protein C−H bonds via intramolecular hydrogen transfer at physiological conditions, potentially resulting in irreversible protein damage.

Published
2004

10. UV Photolysis of 3-Nitrotyrosine Generates Highly Oxidizing Species:  A Potential Source of Photooxidative Stress

Author

Nauser, T., Koppenol, W. H., Pelling, J., and Schoneich, C.

Abstract

Laser flash photolysis at 266 nm of 3-nitrotyrosine and N-acetyl-3-nitrotyrosine ethyl ester generates an oxidizing species, which shows all of the characteristics of a hydroxyl radical. This species reacts with Br- to yield Br2-, via an intermediate, that is kinetically identified as HOBr-. Moreover, the formation of Br2- can be suppressed by methanol; competition kinetics yield relative rate constants for the reaction of the reactive species with Br- and methanol that are similar to those for the hydroxyl radical. Parallel time-resolved UV/vis spectroscopy suggests the formation of phenoxyl radicals, consistent with the formation of hydroxyl radicals. Laser flash photolysis at 355 nm also generates reactive intermediates that oxidize Br- to Br2- but appear not to be hydroxyl radicals.

Published
2004

11. Thiyl Radical Reaction with Thymine:  Absolute Rate Constant for Hydrogen Abstraction and Comparison to Benzylic C−H Bonds

Author

Nauser, T. and Schoneich, C.

Abstract

Free radical damage of DNA is a well-known process affecting biological tissue under conditions of oxidative stress. Thiols can repair DNA-derived radicals. However, the product thiyl radicals may also cause biological damage. To obtain quantitative information on the potential reactivity with DNA components, we measured the rate constant for hydrogen abstraction by cysteamine thiyl radicals from thymine C5−CH3, k = (1.2 ± 0.8) × 104 M-1 s-1, and thymidine-5‘-monophosphate, k = (0.9 ± 0.6) × 104 M-1 s-1. Hence, the hydrogen abstraction from C5−CH3 occurs with rate constants similar to the hydrogen abstraction from the carbohydrate moieties. Especially at low oxygen concentration such as that found in skeletal muscle, such hydrogen abstraction processes by thiyl radicals may well compete against other dioxygen-dependent reactions. The rate constants for hydrogen abstraction at thymine C5−CH3 were compared to those with benzylic substrates, toluenesulfonic acid, and benzyl alcohol.

Published
2003

12. Formation and Properties of Peroxynitrite as Studied by Laser Flash Photolysis, High-Pressure Stopped-Flow Technique, and Pulse Radiolysis

Author

Kissner, R., Nauser, T., Bugnon, P., Lye, P. G., and Koppenol, W. H.

Abstract

Flash photolysis of alkaline peroxynitrite solutions results in the formation of nitrogen monoxide and superoxide. From the rate of recombination it is concluded that the rate constant of the reaction of nitrogen monoxide with superoxide is (l.9 ± 0.2) × 1010 M-1 s-1. The pKa of hydrogen oxoperoxonitrate is dependent on the medium. With the stopped-flow technique a value of 6.5 is found at millimolar phosphate concentrations, while at 0.5 M phosphate the value is 7.5. The kinetics of decay do not follow first-order kinetics when the pH is larger than the pKa, combined with a total peroxynitrite and peroxynitrous acid concentration that exceeds 0.1 mM. An adduct between ONOO- and ONOOH is formed with a stability constant of (1.0 ± 0.l) × 104 M. The kinetics of the decay of hydrogen oxoperoxonitrate are not very pressure-dependent:  from stopped-flow experiments up to 152 MPa, an activation volume of 1.7 ± 1.0 cm3 mol-1 was calculated. This small value is not compatible with homolysis of the O−O bond to yield free nitrogen dioxide and the hydroxyl radical. Pulse radiolysis of alkaline peroxynitrite solutions indicates that the hydroxyl radical reacts with ONOO- to form [(HO)ONOO]- with a rate constant of 5.8 × l09 M-1 s-1. This radical absorbs with a maximum at 420 nm (ε = 1.8 × 103 M-1 cm-1) and decays by second-order kinetics, k = 3.4 × l06 M-1 s-1. Improvements to the biomimetic synthesis of peroxynitrite with solid potassium superoxide and gaseous nitrogen monoxide result in higher peroxynitrite to nitrite yields than in most other syntheses.

Published
1997

14. Structure and enzymatic properties of molecular dendronized polymer-enzyme conjugates and their entrapment inside giant vesicles

Author

Thomas Nauser, Fabio Mavelli, Jozef Adamcik, A. Dieter Schlüter, Emiliano Altamura, Andrea Grotzky, Raffaele Mezzenga, Paolo Carrara, Peter Walde, Pasquale Stano, Grotzky, A., Altamura, E., Adamcik, J., Carrara, P., Stano, Pasquale, Mavelli, F., Nauser, T., Mezzenga, R., Schlüter, A. D., and Walde, P.

Subjects
Polymers, polymer, Efficiency, Cu ,Zn superoxide dismutase, chemistry, Animal, Microscopy, Atomic Force, Horseradish peroxidase, Oxygen, Enzymes, horseradish peroxidase, superoxide dismutase, animal, Cascade reaction, Bovine erythrocyte, Electrochemistry, Animals, Phospholipid vesicles, Atomic force microscopy, General Materials Science, Membrane-permeable, Spectroscopy, Horseradish Peroxidase, chemistry.chemical_classification, Aqueous solution, atomic force microscopy, biology, Chemistry, Superoxide Dismutase, article, Surfaces and Interfaces, Condensed Matter Physics, Dendronized polymer, Liposome, Enzyme, Biochemistry, cattle, Enzymatic propertie, biology.protein, Biophysics, Dismutase, Cattle, Macromolecule, Conjugate
Abstract

Macromolecular hybrid structures were prepared in which two types of enzymes, horseradish peroxidase (HRP) and bovine erythrocytes Cu,Zn-superoxide dismutase (SOD), were linked to a fluorescently labeled, polycationic, dendronized polymer (denpol). Two homologous denpols of first and second generation were used and compared, and the activities of HRP and SOD of the conjugates were measured in aqueous solution separately and in combination. In the latter case the efficiency of the two enzymes in catalyzing a two-step cascade reaction was evaluated. Both enzymes in the two types of conjugates were highly active and comparable to free enzymes, although the efficiency of the enzymes bound to the second-generation denpol was significantly lower (up to a factor of 2) than the efficiency of HRP and SOD linked to the first-generation denpol. Both conjugates were analyzed by atomic force microscopy (AFM), confirming the expected increase in object size compared to free denpols and demonstrating the presence of enzyme molecules localized along the denpol chains. Finally, giant phospholipid vesicles with diameters of up to about 20 μm containing in their aqueous interior pool a first-generation denpol-HRP conjugate were prepared. The HRP of the entrapped conjugate was shown to remain active toward externally added, membrane-permeable substrates, an important prerequisite for the development of vesicular multienzyme reaction systems.

Published
2013
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15. In Vitro Fossilization for High Spatial Resolution Quantification of Elements in Plant-Tissue Using LA-ICP-TOFMS.

Author

Becker P, Nauser T, Wiggenhauser M, Aeschlimann B, Frossard E, and Günther D

Subjects
Crops, Agricultural, Agriculture, Soil, Laser Therapy
Abstract

Laser ablation in combination with an inductively coupled plasma time-of-flight mass spectrometer (LA-ICP-TOFMS) is an upcoming method for rapid quantitative element mapping of various samples. While widespread in geological applications, quantification of elements in biotissues remains challenging. In this study, a proof-of-concept sample preparation method is presented in which plant-tissues are fossilized in order to solidify the complex biotissue matrix into a mineral-like matrix. This process enables quantification of elements by using silicone as an internal standard for normalization while also providing consistent ablation processes similar to minerals to reduce image blurring. Furthermore, it allows us to generate a quantitative image of the element composition at high spatial resolution. The feasibility of the approach is demonstrated on leaves of sunflowers ( Helianthus annuus ), soy beans ( Glycine max ), and corn ( Zea mays ) as representatives for common crops, which were grown on both nonspiked and cadmium-spiked agricultural soil. The quantitative results achieved during imaging were validated with digestion of whole leaves followed by ICP-OES analysis. LA-ICP-TOFMS element mapping of conventionally dried samples can provide misleading trends due to the irregular ablation behavior of biotissue because high signals caused by high ablation rates are falsely interpreted as enrichment of elements. Fossilization provides the opportunity to correct such phenomena by standardization with Si as an internal standard. The method demonstrated here allows for quantitative image acquisition without time-consuming sample preparation steps by using comparatively safe chemicals. The diversity of tested samples suggests that this sample preparation method is well-suited to achieve reproducible and quantitative element maps of various plant samples.

Published
2024
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16. A Nature-Inspired Antioxidant Strategy based on Porphyrin for Aromatic Hydrocarbon Containing Fuel Cell Membranes.

Author

de Wild T, Wurm J, Becker P, Günther D, Nauser T, Schmidt TJ, Gubler L, and Nemeth T

Abstract

The use of hydrocarbon-based proton conducting membranes in fuel cells is currently hampered by the insufficient durability of the material in the device. Membrane aging is triggered by the presence of reactive intermediates, such as HO⋅, which attack the polymer and eventually lead to chain breakdown and membrane failure. An adequate antioxidant strategy tailored towards hydrocarbon-based ionomers is therefore imperative to improve membrane lifetime. In this work, we perform studies on reaction kinetics using pulse radiolysis and γ-radiolysis as well as fuel cell experiments to demonstrate the feasibility of increasing the stability of hydrocarbon-based membranes against oxidative attack by implementing a Nature-inspired antioxidant strategy. We found that metalated-porphyrins are suitable for damage transfer and can be used in the fuel cell membrane to reduce membrane aging with a low impact on fuel cell performance., (© 2023 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published
2023
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17. Electron-Driven Nitration of Unsaturated Hydrocarbons.

Author

Patra S, Mosiagin I, Giri R, Nauser T, and Katayev D

Abstract

Herein, we introduce an electrochemically assisted generation of nitryl radicals from ferric nitrate under mild reaction conditions using a simple setup with inexpensive graphite and stainless-steel electrodes. The mechanism of the reaction is supported by detailed spectroscopic and experimental studies. Powered by electricity and driven by electrons, the synthetic diversity of this reaction has been demonstrated through the development of highly efficient nitration protocols of various unsaturated hydrocarbons. In addition to a broad application area, these protocols are easy to scale for decagram quantities, and exhibit exceptional substrate generality and functional-group compatibility., (© 2023 The Authors. Angewandte Chemie International Edition published by Wiley-VCH GmbH.)

Published
2023
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18. On the Radical-Induced Degradation of Quaternary Ammonium Cations for Anion-Exchange Membrane Fuel Cells and Electrolyzers.

Author

Nemeth T, Nauser T, and Gubler L

Abstract

Four benzylic-type quaternary ammonium (QA) compounds with different electron density at the phenyl group were evaluated for their susceptibility against degradation by radicals. Time-resolved absorption spectroscopy indicated that radicals with oxidizing and reducing character were formed upon oxidation by HO⋅ and O⋅ - (conjugate base of HO⋅). It was estimated that, dependent on the QA, 18-41 % of the formed radicals were oxidizing with standard electrode potentials (E 0 ) above 0.276 V and 13-23 % exceeded 0.68 V, while 13-48 % were reducing with E 0 <-0.448 V. The stability of these model compounds against oxidation and reductive dealkylation was evaluated at both neutral and strongly alkaline conditions, pH 14. Under both conditions, electron-donating groups promoted radical degradation, while electron-withdrawing ones increased stability. Therefore, durability against radical-induced degradation shows an opposite trend to alkaline stability and needs to be considered during the rational design of novel anion-exchange membranes for fuel cells and electrolyzers., (© 2022 The Authors. ChemSusChem published by Wiley-VCH GmbH.)

Published
2022
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19. EPR Study on the Oxidative Degradation of Phenyl Sulfonates, Constituents of Aromatic Hydrocarbon-Based Proton-Exchange Fuel Cell Membranes.

Author

Nemeth T, Agrachev M, Jeschke G, Gubler L, and Nauser T

Abstract

Sulfonated aromatic hydrocarbon-based ionomers are potential constituents of next-generation polymer electrolyte fuel cells (PEFCs). Widespread application is currently limited due to their susceptibility to radical-initiated oxidative degradation that, among other intermediates, involves the formation of highly reactive aromatic cation radicals. The intermediates undergo chain cleavage (dealkylation/dearylation) and the loss of protogenic sulfonate groups, all leading to performance loss and eventual membrane failure. Laser flash photolysis experiments indicated that cation radicals can also be formed via direct electron ejection. We aim to establish the major degradation pathway of proton-exchange membranes (PEMs). To this end, we irradiated aqueous solutions of phenyl sulfonate-type model compounds with a Xe arc lamp, thus generating radicals. The radicals were trapped by 5,5-dimethyl-1-pyrroline N -oxide (DMPO), and the formed adducts were observed by electron paramagnetic resonance (EPR). The formed DMPO spin adducts were assigned and relative adduct concentrations were quantified by simulation of the experimental EPR spectra. Through the formation of the DMPO/ SO 3 - adduct, we established that desulfonation dominates for monoaromatic phenyl sulfonates. We observed that diaryl ether sulfonates readily undergo homolytic C-O scission that produces DMPO/ aryl adducts. Our results support the notion that polyphenylene sulfonates are the most stable against oxidative attack and effectively transfer electrons from DMPO, forming DMPO/ OH. Our findings help to identify durable moieties that can be used as building blocks in the development of next-generation PEMs., Competing Interests: The authors declare no competing financial interest., (© 2022 The Authors. Published by American Chemical Society.)

Published
2022
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20. Impact of substitution on reactions and stability of one-electron oxidised phenyl sulfonates in aqueous solution.

Author

Nemeth T, de Wild T, Gubler L, and Nauser T

Abstract

Highly reactive aromatic cation radicals have been invoked lately in synthetic routes and in the degradation pathways of hydrocarbon-based polymers. Changes in the electron density of aromatic compounds are expected to alter the reaction pathway following one electron oxidation through altering the p K a of the formed intermediate cation radical. Electron-donating groups increase its stability, however, little experimental data are known. While, in theory, the cation radical can be repaired by simple electron transfer, electron transfer to or from its deprotonated form, the hydroxycyclohexadienyl radical, will cause permanent modification or degradation. Time-resolved absorption spectroscopy indicates a p K a ≈ 2-3 for the 4-( tert -butyl)-2-methoxyphenylsulfonate (BMPS) radical cation, while its parent compound 4-( tert -butyl) phenylsulfonate (BPS) is much more acidic. The stability of both compounds towards oxidation by HO˙ was evaluated under air at pH 5 and pH 0. At pH 5, both BMPS and BPS are unstable, and superstoichiometric degradation was observed. Degradation was slightly reduced for BPS at pH 0. In contrast, the more electron rich BMPS showed 80% lower degradation. We unambigously showed that in the presence of Ce(III) and H 2 O 2 at pH 0 both BMPS and BPS could be catalytically repaired via one electron reduction, resulting in further damage moderation.

Published
2022
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21. Initiation and Prevention of Biological Damage by Radiation-Generated Protein Radicals.

Author

Gebicki JM and Nauser T

Subjects
Antioxidants metabolism, Kinetics, Solutions, Free Radicals metabolism, Proteins metabolism, Radiation, Ionizing
Abstract

Ionizing radiations cause chemical damage to proteins. In aerobic aqueous solutions, the damage is commonly mediated by the hydroxyl free radicals generated from water, resulting in formation of protein radicals. Protein damage is especially significant in biological systems, because proteins are the most abundant targets of the radiation-generated radicals, the hydroxyl radical-protein reaction is fast, and the damage usually results in loss of their biological function. Under physiological conditions, proteins are initially oxidized to carbon-centered radicals, which can propagate the damage to other molecules. The most effective endogenous antioxidants, ascorbate, GSH, and urate, are unable to prevent all of the damage under the common condition of oxidative stress. In a promising development, recent work demonstrates the potential of polyphenols, their metabolites, and other aromatic compounds to repair protein radicals by the fast formation of less damaging radical adducts, thus potentially preventing the formation of a cascade of new reactive species.

Published
2021
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22. Fast Antioxidant Reaction of Polyphenols and Their Metabolites.

Author

Gebicki JM and Nauser T

Abstract

The negative correlation between diets rich in fruits and vegetables and the occurrence of cardiovascular disease, stroke, cancer, atherosclerosis, cognitive impairment and other deleterious conditions is well established, with flavonoids and other polyphenols held to be partly responsible for the beneficial effects. Initially, these effects were explained by their antioxidant ability, but the low concentrations of polyphenols in tissues and relatively slow reaction with free radicals suggested that, instead, they act by regulating cell signalling pathways. Here we summarise results demonstrating that the abandonment of an antioxidant role for food polyphenols is based on incomplete knowledge of the mechanism of the polyphenol-free radical reaction. New kinetic measurements show that the reaction is up to 1000 times faster than previously reported and lowers the damaging potential of the radicals. The results also show that the antioxidant action does not require phenolic groups, but only a carbon-centred free radical and an aromatic molecule. Thus, not only food polyphenols but also many of their metabolites are effective antioxidants, significantly increasing the antioxidant protection of cells and tissues. By restoring an important antioxidant role for food polyphenols, the new findings provide experimental support for the advocacy of diets rich in plant-derived food.

Published
2021
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23. Unexpected Disparity in Photoinduced Reactions of C 60 and C 70 in Water with the Generation of O 2 •- or 1 O 2 .

Author

Liosi K, Stasyuk AJ, Masero F, Voityuk AA, Nauser T, Mougel V, Solà M, and Yamakoshi Y

Abstract

Well-defined fullerene-PEG conjugates, C 60 -PEG ( 1 ) and two C 70 -PEG ( 2 and 3 with the addition sites on ab- [6,6] and cc- [6,6]-junctions), were prepared from their corresponding Prato monoadduct precursors. The resulting highly water-soluble fullerene-PEG conjugates 1 - 3 were evaluated for their DNA-cleaving activities and reactive oxygen species (ROS) generation under visible light irradiation. Unexpectedly, photoinduced cleavage of DNA by C 60 -PEG 1 was much higher than that by C 70 -PEG 2 and 3 with higher absorption intensity, especially in the presence of an electron donor (NADH). The preference of photoinduced ROS generation from fullerene-PEG conjugates 1 - 3 via the type II (energy transfer) or the type I (electron transfer) photoreaction was found to be dependent on the fullerene core (between C 60 and C 70 ) and functionalization pattern of C 70 (between 2 and 3 ). This was clearly supported by the electron transfer rate obtained from cyclic voltammetry data and computationally estimated relative rate of each step of the type II and the type I reactions, with the finding that type II energy transfer reactions occurred in the inverted Marcus regime while type I electron transfer reactions proceeded in the normal Marcus regime. This finding on the disparity in the pathways of photoinduced reactions ( type I versus type II ) provides insights into the behavior of photosensitizers in water and the design of photodynamic therapy drugs., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published
2021
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24. Addition of carbon-centered radicals to aromatic antioxidants: mechanistic aspects.

Author

Nauser T and Gebicki JM

Abstract

Several recent studies have shown that the rates of formation of adduct radicals between carbon-centred radicals and aromatic molecules are virtually diffusion-controlled and reversible. This contrasts with "radical addition", the well-known multistep reaction in preparative organic chemistry where the rate-determining initial formation of radical adducts is perceived to be several orders of magnitude slower and virtually irreversible. Using pulse radiolysis and spectroscopic analysis, we have now re-examined parts of this complex mechanism. The results have significant implications for biological systems: electron-rich, aromatic structures may act like buffers for radicals, moderating their reactivity resulting in a much slower reaction determining the overall rate of oxidation. In vivo, an organism would gain time for an appropriate antioxidant reaction.

Published
2020
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25. Thermochemical unification of molecular descriptors to predict radical hydrogen abstraction with low computational cost.

Author

Nolte TM, Nauser T, Gubler L, Hendriks AJ, and Peijnenburg WJGM

Abstract

Chemistry describes transformation of matter with reaction equations and corresponding rate constants. However, accurate rate constants are not always easy to get. Here we focus on radical oxidation reactions. Analysis of over 500 published rate constants of hydroxyl radicals led us to hypothesize that a modified linear free-energy relationship (LFER) could be used to predict rate constants speedily, reliably and accurately. LFERs correlate the Gibbs activation-energy with the Gibbs energy of reaction. We calculated the latter as the sum of one-electron transfer and, if appropriate, proton transfer. We parametrized specific transition state effects to orbital delocalizability and the polarity of the reactant. The calculation time for 500 reactions is less than 8 hours on a standard desktop-PC. Rate constants were also calculated for hydrogen and methyl radicals; these controls show that the predictions are applicable to a broader set of oxidizing radicals. An accuracy of 30-40% (standard deviation) with reference to reported experimental values was found suitable for the screening of complex chemical systems for possibly relevant reactions. In particular, potentially relevant reactions can be singled out and scrutinized in detail when prioritizing chemicals for environmental risk assessment.

Published
2020
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26. Synthesis, Characterization, and Reactivity of a Hypervalent-Iodine-Based Nitrooxylating Reagent.

Author

Calvo R, Le Tellier A, Nauser T, Rombach D, Nater D, and Katayev D

Abstract

Herein, the synthesis and characterization of a hypervalent-iodine-based reagent that enables a direct and selective nitrooxylation of enolizable C-H bonds to access a broad array of organic nitrate esters is reported. This compound is bench stable, easy-to-handle, and delivers the nitrooxy (-ONO 2 ) group under mild reaction conditions. Activation of the reagent by Brønsted and Lewis acids was demonstrated in the synthesis of nitrooxylated β-keto esters, 1,3-diketones, and malonates, while its activity under photoredox catalysis was shown in the synthesis of nitrooxylated oxindoles. Detailed mechanistic studies including pulse radiolysis, Stern-Volmer quenching studies, and UV/Vis spectroelectrochemistry reveal a unique single-electron-transfer (SET)-induced concerted mechanistic pathway not reliant upon generation of the nitrate radical., (© 2020 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2020
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27. Thinking Outside the Cage: A New Hypothesis That Accounts for Variable Yields of Radicals from the Reaction of CO 2 with ONOO .

Author

Koppenol WH, Serrano-Luginbuehl S, Nauser T, and Kissner R

Subjects
Free Radicals chemistry, Kinetics, Solvents chemistry, Carbon Dioxide chemistry, Free Radicals chemical synthesis, Peroxynitrous Acid chemistry
Abstract

In biology, the reaction of ONOO - with CO 2 is the main sink for ONOO - . This reaction yields CO 3 •- , NO 2 , NO 3 - , and CO 2 . There is a long-standing debate with respect to the yield of the radicals relative to ONOO - . The reaction of ONOO - with CO 2 results at first in ONOOCO 2 - . According to one hypothesis, ONOOCO 2 - is extremely short-lived and devolves into a solvent cage that contains CO 3 •- and NO 2 . Of these solvent cages, approximately two/thirds result in NO 3 - and CO 2 , and approximately one/third release CO 3 •- and NO 2 that oxidize the substrate. According to our hypothesis, ONOOCO 2 - is formed much faster, is relatively long-lived, and may also be an oxidant; the limited yield is the result of ONOOCO 2 - being scavenged by a second CO 2 under conditions of a high CO 2 concentration. We disagree with the first hypothesis for three reasons: First, it is based on an estimated K for the reaction of ONOO - with CO 2 to form ONOOCO 2 - of ∼1 M -1 , while experiments yield a value of 4.5 × 10 3 M -1 . Second, we argue that the solvent cage as proposed is physically not realistic. Given the less than diffusion-controlled rate constant of CO 3 •- with NO 2 , all radicals would escape from the solvent cage. Third, the reported ∼33% radical is not supported by an experiment where mass balance was established. We propose here a hybrid mechanism. After formation of ONOOCO 2 - , it undergoes homolysis to yield CO 3 •- with NO 2 , or, depending on [CO 2 ], it is scavenged by a second CO 2 ; CO 3 •- oxidizes ONOO - , if present. These reactions allow us to successfully simulate the reaction of ONOO - with CO 2 over a wide range of ONOO - /CO 2 ratios. At lower ratios, fewer radicals are formed, while at higher ratios, radical yields between 30% and 40% are predicted. The differences in radical yields reported may thus be traced to the experimental ONOO - /CO 2 ratios. Given a physiological [CO 2 ] of 1.3 mM, the yield of CO 3 •- and NO 2 is 19%, and lower if ONOOCO 2 - has a significant reactivity of its own.

Published
2020
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28. Attack of hydroxyl radicals to α-methyl-styrene sulfonate polymers and cerium-mediated repair via radical cations.

Author

Nolte TM, Nauser T, and Gubler L

Abstract

Both synthetic polymers (membranes, coatings, packaging) and natural polymers (DNA, proteins) are subject to radical-initiated degradation. In order to mitigate the deterioration of the polymer properties, antioxidant strategies need to be devised. We studied the reactions of poly(α-methylstyrene sulfonate), a model compound for fuel cell membrane materials, with different degrees of polymerization with OH˙ radicals as well as subsequent reactions. We observed the resulting OH˙-adducts to react with oxygen and eliminate H 2 O, the relative likelihood of which is determined by pH and molecular weight. The resulting radical cations can be reduced back to the parent molecule by cerium(iii). This 'repair' reaction is also dependent on molecular weight likely because of intramolecular stabilization. The results from this study provide a starting point for the development of new hydrocarbon-based ionomer materials for fuel cells that are more resistant to radical induced degradation through the detoxification of intermediates via damage transfer and repair pathways. Furthermore, a more fundamental understanding of the mechanisms behind conventional antioxidants in medicine, such as ceria nanoparticles, is achieved.

Published
2020
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29. Antioxidants and radical damage in a hydrophilic environment: chemical reactions and concepts.

Author

Nauser T and Gebicki JM

Subjects
Oxidation-Reduction, Antioxidants chemistry, Hydroxyl Radical chemistry
Abstract

Known endogenous antioxidants are unlikely to prevent radical damage due to oxidative stress or achieve complete repair by established reaction mechanisms. While near complete prevention seems very unrealistic, some of the initial damage can be repaired. Depending on tissue, this may be even a large fraction. Antioxidants, however, will efficiently break radical reaction chains and, therefore, certainly limit the damage caused by radicals. It is not clear if chemical antioxidant action is strictly limited to electron-transfer processes or if additional reaction mechanisms may contribute., (© 2020 The Author(s). Published by Portland Press Limited on behalf of the Biochemical Society.)

Published
2020
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30. Profiling the oxidative activation of DMSO-F 6 by pulse radiolysis and translational potential for radical C-H trifluoromethylation.

Author

Santschi N, Jelier BJ, Stähelin S, and Nauser T

Abstract

The oxidative activation of the perfluorinated analogue of dimethyl sulfoxide, DMSO-F 6 , by hydroxyl radicals efficiently produces trifluoromethyl radicals based on pulse radiolysis, laboratory scale experiments, and comparison of rates of reaction for analogous radical systems. In comparison to commercially available precursors, DMSO-F 6 proved to be more stable, easier to handle and overall more convenient than leading F 3 C-reagents and may therefore be an ideal surrogate to study F 3 C radicals for time-resolved kinetics studies. In addition, we present an improved protocol for the preparation of this largely unexplored reagent.

Published
2019
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31. Fast reaction of carbon free radicals with flavonoids and other aromatic compounds.

Author

Nauser T and Gebicki JM

Subjects
Humans, Kinetics, Pulse Radiolysis, Amino Acids chemistry, Carbon chemistry, Flavonoids chemistry, Free Radicals chemistry, Serum Albumin, Human chemistry
Abstract

Many theoretical and experimental studies have shown that the principal initial biological targets of free radicals are nucleic acids, lipids and proteins. The reaction normally generates carbon-centered radicals which can propagate molecular damage either directly or after formation of new reactive species following reaction with oxygen. Overall damage prevention is therefore best achieved by repair of the carbon radicals before they initiate further reactions. Recent studies have shown that the repair cannot be achieved by normal levels of the endogenous antioxidants glutathione, ascorbate or urate. Since their concentrations are well regulated and cannot be enhanced by oral intake, we have investigated the effectiveness of flavonoids and other polyphenols as potential carbon radical repair agents, because their levels in vivo can be significantly enhanced by diet. Pulse radiolysis measurements of the rate constants of repair of amino acid radicals by several polyphenols showed reversible formation of radical-polyphenol adducts 100-1000 times faster than previously reported for the bimolecular stoichiometric reactions of flavonoids i.e. with rate constants in the order of 10 10  M -1 s -1 . Adduct formation depended only on the presence of a carbon-centered radical and an aromatic moiety in the reactants, without the involvement of redox reactions at the phenolic groups. Formation of adducts lowered the reactivity of the radicals. Our results suggest that flavonoids, polyphenols and many of their metabolites can effectively reduce the damaging potential of carbon radicals at concentrations achievable in vivo by diets rich in fruits and vegetables., (Copyright © 2019 Elsevier Inc. All rights reserved.)

Published
2019
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32. Jumpstarting the cytochrome P450 catalytic cycle with a hydrated electron.

Author

Erdogan H, Vandemeulebroucke A, Nauser T, Bounds PL, and Koppenol WH

Subjects
Binding Sites physiology, Camphor 5-Monooxygenase physiology, Catalysis, Cytochrome P-450 Enzyme System metabolism, Electrons, Ferric Compounds metabolism, Kinetics, Models, Molecular, Oxidation-Reduction, Camphor 5-Monooxygenase chemistry, Camphor 5-Monooxygenase metabolism, Electron Transport physiology
Abstract

Cytochrome P450cam (CYP101Fe 3+ ) regioselectively hydroxylates camphor. Possible hydroxylating intermediates in the catalytic cycle of this well-characterized enzyme have been proposed on the basis of experiments carried out at very low temperatures and shunt reactions, but their presence has not yet been validated at temperatures above 0 °C during a normal catalytic cycle. Here, we demonstrate that it is possible to mimic the natural catalytic cycle of CYP101Fe 3+ by using pulse radiolysis to rapidly supply the second electron of the catalytic cycle to camphor-bound CYP101[FeO 2 ] 2+ Judging by the appearance of an absorbance maximum at 440 nm, we conclude that CYP101[FeOOH] 2+ (compound 0) accumulates within 5 μs and decays rapidly to CYP101Fe 3+ , with a k 440 nm of 9.6 × 10 4 s -1 All processes are complete within 40 μs at 4 °C. Importantly, no transient absorbance bands could be assigned to CYP101[FeO 2+ por •+ ] (compound 1) or CYP101[FeO 2+ ] (compound 2). However, indirect evidence for the involvement of compound 1 was obtained from the kinetics of formation and decay of a tyrosyl radical. 5-Hydroxycamphor was formed quantitatively, and the catalytic activity of the enzyme was not impaired by exposure to radiation during the pulse radiolysis experiment. The rapid decay of compound 0 enabled calculation of the limits for the Gibbs activation energies for the conversions of compound 0 → compound 1 → compound 2 → CYP101Fe 3+ , yielding a Δ G of 45, 39, and 39 kJ/mol, respectively. At 37 °C, the steps from compound 0 to the iron(III) state would take only 4 μs. Our kinetics studies at 4 °C complement the canonical mechanism by adding the dimension of time., (© 2017 by The American Society for Biochemistry and Molecular Biology, Inc.)

Published
2017
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33. An Experimental Radical Electrophilicity Index.

Author

Santschi N and Nauser T

Abstract

We present an experimental electrophilicity index (ϻ) for the classification of radicals. The ϻ-scale is based on the equilibrium constant determined for the reversible addition of a radical R . to an aromatic radicophile (HisNH 2 ). This experimental approach is in excellent agreement with the computed global electrophilicity index ω and serves to validate the latter., (© 2017 Wiley-VCH Verlag GmbH & Co. KGaA, Weinheim.)

Published
2017
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34. Reaction rates of glutathione and ascorbate with alkyl radicals are too slow for protection against protein peroxidation in vivo.

Author

Nauser T and Gebicki JM

Subjects
Kinetics, Oxidation-Reduction, Oxidative Stress, Oxygen chemistry, Peroxides chemistry, Pulse Radiolysis, Alanine analogs & derivatives, Antioxidants chemistry, Ascorbic Acid chemistry, Glutathione chemistry, Phenylalanine analogs & derivatives, Piperazines chemistry
Abstract

Reaction kinetics of amino acid and peptide alkyl radicals with GSH and ascorbate, the two most abundant endogenous antioxidants, were investigated by pulse radiolysis. Rate constants in the order of 10 6  M -1 s -1 were found. Alkyl radicals react at almost diffusion controlled rates and irreversibly with oxygen to form peroxyl radicals, and competition with this reaction is the benchmark for efficient repair in vivo. We consider repair of protein radicals and assume comparable rate constants for the reactions of GSH/ascorbate with peptide alkyl radicals and with alkyl radicals on a protein surface. Given physiological concentrations of oxygen, GSH and ascorbate, protein peroxyl radicals will always be a major product of protein alkyl radicals in vivo. Therefore, if they are formed by oxidative stress, protein alkyl radicals are a probable cause for biological damage., (Copyright © 2017 Elsevier Inc. All rights reserved.)

Published
2017
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35. Physiological Concentrations of Ascorbate Cannot Prevent the Potentially Damaging Reactions of Protein Radicals in Humans.

Author

Nauser T and Gebicki JM

Subjects
Gamma Rays, Humans, Insulin chemistry, Muramidase chemistry, Nitrogen Oxides chemistry, Pulse Radiolysis, Serum Albumin chemistry, Spectrophotometry, Ultraviolet, Tryptophan chemistry, Tyrosine chemistry, Ascorbic Acid chemistry, Free Radicals chemistry, Proteins chemistry
Abstract

The principal initial biological targets of free radicals formed under conditions of oxidative stress are the proteins. The most common products of the interaction are carbon-centered alkyl radicals which react rapidly with oxygen to form peroxyl radicals and hydroperoxides. All these species are reactive, capable of propagating the free radical damage to enzymes, nucleic acids, lipids, and endogenous antioxidants, leading finally to the pathologies associated with oxidative stress. The best chance of preventing this chain of damage is in early repair of the protein radicals by antioxidants. Estimate of the effectiveness of the physiologically significant antioxidants requires knowledge of the antioxidant tissue concentrations and rate constants of their reaction with protein radicals. Previous studies by pulse radiolysis have shown that only ascorbate can repair the Trp and Tyr protein radicals before they form peroxyl radicals under physiological concentrations of oxygen. We have now extended this work to other protein C-centered radicals generated by hydroxyl radicals because these and many other free radicals formed under oxidative stress can produce secondary radicals on virtually any amino acid residue. Pulse radiolysis identified two classes of rate constants for reactions of protein radicals with ascorbate, a faster one in the range (9-60) × 10 7 M -1 s -1 and a slow one with a range of (0.5-2) × 10 7 M -1 s -1 . These results show that ascorbate can prevent further reactions of protein radicals only in the few human tissues where its concentration exceeds about 2.5 mM.

Published
2017
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36. Mechanistic insight into the thermal activation of Togni's trifluoromethylation reagents.

Author

Santschi N, Jelier BJ, and Nauser T

Abstract

Herein we investigate the propensity of hypervalent iodine based electrophilic trifluoromethylating agents to undergo thermally induced fragmentation of the F 3 C-I-O motif. For the first time we are able to observe a dissociative electron transfer mechanism using mass spectroscopy techniques to generate and trap CF 3 radicals. Consistent with this mechanism, alkyl radical elimination from these reagents is in full support of an intermediate cyclic iodanyl radical and a reagent-specific temperature of maximum radical production was found to correlate with reported solution phase reactivity.

Published
2017
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37. Shielding effects in spacious macromolecules: a case study with dendronized polymers.

Author

Gstrein C, Walde P, Schlüter AD, and Nauser T

Subjects
Aniline Compounds chemistry, Free Radicals chemistry, Kinetics, Molecular Conformation, Dendrimers chemistry, Polymers chemistry
Abstract

Dendronized polymers exhibit defined structures with bulky side chains (dendrons) on a linear polymer backbone. Upon reaction with radicals, chromophores close to the backbone were bleached. The reaction rate and yield decreased with increasing dendron size, demonstrating that the inside of dendronized polymers can be "shielded" by bulky dendrons from access by reactive species.

Published
2016
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38. Electrode Potentials of l-Tryptophan, l-Tyrosine, 3-Nitro-l-tyrosine, 2,3-Difluoro-l-tyrosine, and 2,3,5-Trifluoro-l-tyrosine.

Author

Mahmoudi L, Kissner R, Nauser T, and Koppenol WH

Subjects
Electrodes, Tyrosine chemistry, Dipeptides chemistry, Electrochemical Techniques, Hydrocarbons, Fluorinated chemistry, Tyrosine analogs & derivatives
Abstract

Electrode potentials for aromatic amino acid radical/amino acid couples were deduced from cyclic voltammograms and pulse radiolysis experiments. The amino acids investigated were l-tryptophan, l-tyrosine, N-acetyl-l-tyrosine methyl ester, N-acetyl-3-nitro-l-tyrosine ethyl ester, N-acetyl-2,3-difluoro-l-tyrosine methyl ester, and N-acetyl-2,3,5-trifluoro-l-tyrosine methyl ester. Conditional potentials were determined at pH 7.4 for all compounds listed; furthermore, Pourbaix diagrams for l-tryptophan, l-tyrosine, and N-acetyl-3-nitro-l-tyrosine ethyl ester were obtained. Electron transfer accompanied by proton transfer is reversible, as confirmed by detailed analysis of the current waves, and because the slopes of the Pourbaix diagrams obey Nernst's law. E°'(Trp(•),H(+)/TrpH) and E°'(TyrO(•),H(+)/TyrOH) at pH 7 are 0.99 ± 0.01 and 0.97 ± 0.01 V, respectively. Pulse radiolysis studies of two dipeptides that contain both amino acids indicate a difference in E°' of approximately 0.06 V. Thus, in small peptides, we recommend values of 1.00 and 0.96 V for E°'(Trp(•),H(+)/TrpH) and E°'(TyrO(•),H(+)/TyrOH), respectively. The electrode potential of N-acetyl-3-nitro-l-tyrosine ethyl ester is higher, while because of mesomeric stabilization of the radical, those of N-acetyl-2,3-difluoro-l-tyrosine methyl ester and N-acetyl-2,3,5-trifluoro-l-tyrosine methyl ester are lower than that of tyrosine. Given that the electrode potentials at pH 7 of E°'(Trp(•),H(+)/TrpH) and E°'(TyrO(•),H(+)/TyrOH) are nearly equal, they would be, in principle, interchangeable. Proton-coupled electron transfer pathways in proteins that use TrpH and TyrOH are thus nearly thermoneutral.

Published
2016
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40. Protein thiyl radical reactions and product formation: a kinetic simulation.

Author

Nauser T, Koppenol WH, and Schöneich C

Subjects
Amino Acids chemistry, Amino Acids metabolism, Animals, Ascorbic Acid chemistry, Ascorbic Acid metabolism, Computer Simulation, Disulfides metabolism, Free Radicals metabolism, Glutathione chemistry, Glutathione metabolism, Humans, Kinetics, Models, Chemical, Oxidation-Reduction, Oxygen chemistry, Oxygen metabolism, Proteins metabolism, Sulfhydryl Compounds metabolism, Thermodynamics, Disulfides chemistry, Free Radicals chemistry, Hydrogen chemistry, Proteins chemistry, Sulfhydryl Compounds chemistry
Abstract

Protein thiyl radicals are important intermediates generated in redox processes of thiols and disulfides. Thiyl radicals efficiently react with glutathione and ascorbate, and the common notion is that these reactions serve to eliminate thiyl radicals before they can enter potentially hazardous processes. However, over the past years increasing evidence has been provided for rather efficient intramolecular hydrogen transfer processes of thiyl radicals in proteins and peptides. Based on rate constants published for these processes, we have performed kinetic simulations of protein thiyl radical reactivity. Our simulations suggest that protein thiyl radicals enter intramolecular hydrogen transfer reactions to a significant extent even under physiologic conditions, i.e., in the presence of 30 µM oxygen, 1 mM ascorbate, and 10 mM glutathione. At lower concentrations of ascorbate and glutathione, frequently observed when tissue is exposed to oxidative stress, the extent of irreversible protein thiyl radical-dependent protein modification increases., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published
2015
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41. Carbon-centered radicals add reversibly to histidine--implications.

Author

Nauser T and Carreras A

Subjects
Alcohols chemistry, Carbon chemistry, Oxidation-Reduction, Free Radicals chemistry, Histidine chemistry
Abstract

Carbon-centered radicals of alcohols commonly used as hydroxyl radical scavengers (MeOH, EtOH, i-PrOH and t-BuOH) add reversibly to histidine with equilibrium constants up to 3 × 10(3) M(-1) and rate constants on the order of 10(9) M(-1) s(-1). Similar equilibria may compromise determinations of one-electron (radical) electrode potentials.

Published
2014
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42. Why selenocysteine replaces cysteine in thioredoxin reductase: a radical hypothesis.

Author

Nauser T, Steinmann D, Grassi G, and Koppenol WH

Subjects
Catalytic Domain, Protein Binding physiology, Selenium chemistry, Selenocysteine metabolism, Sulfur chemistry, Thermodynamics, Thioredoxin-Disulfide Reductase metabolism, Cysteine metabolism, Models, Chemical, Selenocysteine chemistry, Thioredoxin-Disulfide Reductase chemistry
Abstract

Thioredoxin reductases, important biological redox mediators for two-electron transfers, contain either 2 cysteines or a cysteine (Cys) and a selenocysteine (Sec) at the active site. The incorporation of Sec is metabolically costly, and therefore surprising. We provide here a rationale: in the case of an accidental one-electron transfer to a S-S or a S-Se bond during catalysis, a thiyl or a selanyl radical, respectively would be formed. The thiyl radical can abstract a hydrogen from the protein backbone, which subsequently leads to the inactivation of the protein. In contrast, a selanyl radical will not abstract a hydrogen. Therefore, formation of Sec radicals in a GlyCysSecGly active site will less likely result in the destruction of a protein compared to a GlyCysCysGly active site.

Published
2014
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43. Rapid reaction of superoxide with insulin-tyrosyl radicals to generate a hydroperoxide with subsequent glutathione addition.

Author

Das AB, Nauser T, Koppenol WH, Kettle AJ, Winterbourn CC, and Nagy P

Subjects
Hydrogen Peroxide metabolism, Kinetics, Mass Spectrometry, Oxidation-Reduction, Pulse Radiolysis, Tyrosine metabolism, Glutathione metabolism, Insulin metabolism, Superoxides metabolism, Tyrosine analogs & derivatives
Abstract

Tyrosine (Tyr) residues are major sites of radical generation during protein oxidation. We used insulin as a model to study the kinetics, mechanisms, and products of the reactions of radiation-induced or enzyme-generated protein-tyrosyl radicals with superoxide to demonstrate the feasibility of these reactions under oxidative stress conditions. We found that insulin-tyrosyl radicals combined to form dimers, mostly via the tyrosine at position 14 on the α chain (Tyr14). However, in the presence of superoxide, dimerization was largely outcompeted by the reaction of superoxide with insulin-tyrosyl radicals. Using pulse radiolysis, we measured a second-order rate constant for the latter reaction of (6±1) × 10(8) M(-1) s(-1) at pH 7.3, representing the first measured rate constant for a protein-tyrosyl radical with superoxide. Mass-spectrometry-based product analyses revealed the addition of superoxide to the insulin-Tyr14 radical to form the hydroperoxide. Glutathione efficiently reduced the hydroperoxide to the corresponding monoxide and also subsequently underwent Michael addition to the monoxide to give a diglutathionylated protein adduct. Although much slower, conjugation of the backbone amide group can form a bicyclic Tyr-monoxide derivative, allowing the addition of only one glutathione molecule. These findings suggest that Tyr-hydroperoxides should readily form on proteins under oxidative stress conditions where protein radicals and superoxide are both generated and that these should form addition products with thiol compounds such as glutathione., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published
2014
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44. Structure and enzymatic properties of molecular dendronized polymer-enzyme conjugates and their entrapment inside giant vesicles.

Author

Grotzky A, Altamura E, Adamcik J, Carrara P, Stano P, Mavelli F, Nauser T, Mezzenga R, Schlüter AD, and Walde P

Subjects
Animals, Cattle, Horseradish Peroxidase chemistry, Microscopy, Atomic Force, Superoxide Dismutase chemistry, Polymers chemistry
Abstract

Macromolecular hybrid structures were prepared in which two types of enzymes, horseradish peroxidase (HRP) and bovine erythrocytes Cu,Zn-superoxide dismutase (SOD), were linked to a fluorescently labeled, polycationic, dendronized polymer (denpol). Two homologous denpols of first and second generation were used and compared, and the activities of HRP and SOD of the conjugates were measured in aqueous solution separately and in combination. In the latter case the efficiency of the two enzymes in catalyzing a two-step cascade reaction was evaluated. Both enzymes in the two types of conjugates were highly active and comparable to free enzymes, although the efficiency of the enzymes bound to the second-generation denpol was significantly lower (up to a factor of 2) than the efficiency of HRP and SOD linked to the first-generation denpol. Both conjugates were analyzed by atomic force microscopy (AFM), confirming the expected increase in object size compared to free denpols and demonstrating the presence of enzyme molecules localized along the denpol chains. Finally, giant phospholipid vesicles with diameters of up to about 20 μm containing in their aqueous interior pool a first-generation denpol-HRP conjugate were prepared. The HRP of the entrapped conjugate was shown to remain active toward externally added, membrane-permeable substrates, an important prerequisite for the development of vesicular multienzyme reaction systems.

Published
2013
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45. Peroxynitrous acid: controversy and consensus surrounding an enigmatic oxidant.

Author

Koppenol WH, Bounds PL, Nauser T, Kissner R, and Rüegger H

Subjects
Molecular Structure, Stereoisomerism, Temperature, Oxidants chemistry, Peroxynitrous Acid chemistry
Abstract

The isomerisation of ONOOH to NO(3)(-) and H(+), some oxidations and all hydroxylations and nitrations of aromatic compounds are first-order in ONOOH and zero-order in the compounds that are modified. These reactions are widely believed to proceed via homolysis of ONOOH into HO˙ and NO(2)˙ to an extent of ca. 30%. We review the evidence pro and contra homolysis in studies that involve (1) thermochemical considerations, (2) isomerisation to NO(3)(-) and H(+), (3) decomposition to NO(2)(-) and O(2), (4) HO˙ scavenger studies, (5) deuterium isotope effects, (6) (18)O-scrambling studies, (7) electrochemistry, (8) CIDNP NMR, and (9) photolysis. Our conclusion is that homolysis may be involved to a minor extent of ca. 5%. The initiation of ONOOH isomerisation may be visualised as an out-of-plane vibration of the terminal HO-group relative to the nitrogen. At ONOO(-) concentrations exceeding 0.1 mM and near neutral pH, disproportionation to NO(2)(-) and O(2) occurs; such disproportionations are typical for peroxy acids. For oxidation and nitration of organic substrates, we favour a mechanism involving initial formation of an adduct between the compound to be oxidised or nitrated and ONOOH.

Published
2012
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46. Hydrogen exchange equilibria in thiols.

Author

Hofstetter D, Thalmann B, Nauser T, and Koppenol WH

Subjects
2-Propanol chemistry, Amidines chemistry, Cysteine chemistry, Deuterium Exchange Measurement, Deuterium Oxide chemistry, Dipeptides chemistry, Free Radicals chemistry, Glutathione chemistry, Hydrogen-Ion Concentration, Magnetic Resonance Spectroscopy, Hydrogen chemistry, Sulfhydryl Compounds chemistry
Abstract

Cysteine, cysteinyl-glycine, glutathione, phenylalanyl-cysteinyl-glycine, and histidyl-cysteinyl-glycine were dissolved in acidic and neutral D(2)O in the presence of the radical generator 2,2'-azobis(2-methylpropionamidine) dihydrochloride and radical mediator compounds (benzyl alcohol and 2-propanol). An exchange of H-atoms by D-atoms took place in these peptides due to intramolecular H-abstraction equilibria. NMR measurements allow one to follow the extent of H-D exchanges and to identify the sites where these exchanges take place. Significant exchanges occur in acidic media in GSH at positions Glu-β and Glu-γ, in Phe-Cys-Gly at positions Phe ortho, Phe-β, Cys-α, Cys-β, and Gly-α, and in His-Cys-Gly at positions His H1, His H2, His β, Cys β, and Gly α. In neutral media, exchanges occur in Cys-Gly at position Cys β and in GSH at position Cys α. Phe-Cys-Gly and His-Cys-Gly were not examined in neutral media. Sites participating in the radical exchange equilibria are highly dependent on structure and pH; the availability of electron density in the form of lone pairs appears to increase the extent of exchange. Interestingly, and unexpectedly, 2D NMR experiments show that GSH rearranges itself in acidic solution: the signals shift, but their patterns do not change. The formation of a thiolactone from Gly and Cys residues matches the changes observed.

Published
2012
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47. Chemical characterization of the smallest S-nitrosothiol, HSNO; cellular cross-talk of H2S and S-nitrosothiols.

Author

Filipovic MR, Miljkovic JLj, Nauser T, Royzen M, Klos K, Shubina T, Koppenol WH, Lippard SJ, and Ivanović-Burmazović I

Subjects
Diffusion, Erythrocytes metabolism, Hemoglobins metabolism, Human Umbilical Vein Endothelial Cells, Humans, Nitrosation, S-Nitrosoglutathione metabolism, S-Nitrosothiols chemistry, Hydrogen Sulfide metabolism, Nitric Oxide metabolism, S-Nitrosothiols metabolism
Abstract

Dihydrogen sulfide recently emerged as a biological signaling molecule with important physiological roles and significant pharmacological potential. Chemically plausible explanations for its mechanisms of action have remained elusive, however. Here, we report that H(2)S reacts with S-nitrosothiols to form thionitrous acid (HSNO), the smallest S-nitrosothiol. These results demonstrate that, at the cellular level, HSNO can be metabolized to afford NO(+), NO, and NO(-) species, all of which have distinct physiological consequences of their own. We further show that HSNO can freely diffuse through membranes, facilitating transnitrosation of proteins such as hemoglobin. The data presented in this study explain some of the physiological effects ascribed to H(2)S, but, more broadly, introduce a new signaling molecule, HSNO, and suggest that it may play a key role in cellular redox regulation.

Published
2012
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48. A fluorescently labeled dendronized polymer-enzyme conjugate carrying multiple copies of two different types of active enzymes.

Author

Grotzky A, Nauser T, Erdogan H, Schlüter AD, and Walde P

Subjects
Chromatography, Gel, Horseradish Peroxidase metabolism, Models, Molecular, Spectrophotometry, Ultraviolet, Superoxide Dismutase metabolism, Dendrimers chemistry, Fluorescein chemistry, Fluorescent Dyes chemistry, Horseradish Peroxidase chemistry, Polymers chemistry, Superoxide Dismutase chemistry
Abstract

A hybrid structure of a synthetic dendronized polymer, two different types of enzymes (superoxide dismutase and horseradish peroxidase), and a fluorescent dye (fluorescein) was synthesized. Thereby, a single polymer chain carried multiple copies of the two enzymes and the fluorescein. The entire attachment chemistry is based on UV/vis-quantifiable bis-aryl hydrazone bond formation that allows direct quantification of bound molecules: 60 superoxide dismutase, 120 horseradish peroxidase, and 20 fluorescein molecules on an average polymer chain of 2000 repeating units. To obtain other enzyme ratios the experimental conditions were altered accordingly. Moreover, it could be shown that both enzymes remained fully active and catalyzed a two-step cascade reaction.

Published
2012
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49. Reversible hydrogen transfer reactions in thiyl radicals from cysteine and related molecules: absolute kinetics and equilibrium constants determined by pulse radiolysis.

Author

Nauser T, Koppenol WH, and Schöneich C

Subjects
Absorption, Disulfides chemistry, Electron Transport, Free Radicals chemistry, Kinetics, Propionates chemistry, Pulse Radiolysis, Cysteine chemistry, Hydrogen chemistry, Sulfhydryl Compounds chemistry
Abstract

The mercapto group of cysteine (Cys) is a predominant target for oxidative modification, where one-electron oxidation leads to the formation of Cys thiyl radicals, CysS(•). These Cys thiyl radicals enter 1,2- and 1,3-hydrogen transfer reactions, for which rate constants are reported in this paper. The products of these 1,2- and 1,3-hydrogen transfer reactions are carbon-centered radicals at position C(3) (α-mercaptoalkyl radicals) and C(2) ((•)C(α) radicals) of Cys, respectively. Both processes can be monitored separately in Cys analogues such as cysteamine (CyaSH) and penicillamine (PenSH). At acidic pH, thiyl radicals from CyaSH permit only the 1,2-hydrogen transfer according to equilibrium 12, (+)H(3)NCH(2)CH(2)S(• )⇌ (+)H(3)NCH(2)(•)CH-SH, where rate constants for forward and reverse reaction are k(12) ≈ 10(5) s(-1) and k(-12) ≈ 1.5 × 10(5)s(-1), respectively. In contrast, only the 1,3-hydrogen transfer is possible for thiyl radicals from PenSH according to equilibrium 14, ((+)H(3)N/CO(2)H)C(α)-C(CH(3))(2)-S(•) ⇌ ((+)H(3)N/CO(2)H)(•)C(α)-C(CH(3))(2)-SH, where rate constants for the forward and the reverse reaction are k(14) = 8 × 10(4) s(-1) and k(-14) = 1.4 × 10(6) s(-1). The (•)C(α) radicals from PenSH and Cys have the additional opportunity for β-elimination of HS(•)/S(•-), which proceeds with k(39) ≈ (3 ± 1) × 10(4) s(-1) from (•)C(α) radicals from PenSH and k(-34) ≈ 5 × 10(3) s(-1) from (•)C(α) radicals from Cys. The rate constants quantified for the 1,2- and 1,3-hydrogen transfer reactions can be used as a basis to calculate similar processes for Cys thiyl radicals in proteins, where hydrogen transfer reactions, followed by the addition of oxygen, may lead to the irreversible modification of target proteins.

Published
2012
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50. Why do proteins use selenocysteine instead of cysteine?

Author

Nauser T, Steinmann D, and Koppenol WH

Subjects
Cysteine chemistry, Kinetics, Oxidation-Reduction, Selenium chemistry, Selenium metabolism, Selenium Compounds chemistry, Selenium Compounds metabolism, Sulfur chemistry, Sulfur metabolism, Thermodynamics, Cysteine analogs & derivatives, Cysteine metabolism, Proteins chemistry, Proteins metabolism
Abstract

Selenocysteine is present in a variety of proteins and catalyzes the oxidation of thiols to disulfides and the reduction of disulfides to thiols. Here, we compare the kinetic and thermodynamic properties of cysteine with its selenium-containing analogon, selenocysteine. Reactions of simple selenols at pH 7 are up to four orders of magnitude faster than their sulfur analogs, depending on reaction type. In redox-related proteins, the use of selenium instead of sulfur can be used to tune electrode, or redox, potentials. Selenocysteine could also have a protective effect in proteins because its one-electron oxidized product, the selanyl radical, is not oxidizing enough to modify or destroy proteins, whereas the cysteine-thiyl radical can do this very rapidly.

Published
2012
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