Dityrosine as a biomarker of free radical induced oxidative damage in diseases of ageing

Bucknall, Martin Paul, Medical Sciences, Faculty of Medicine, UNSW

January 2006

o,o???-Dityrosine (dityrosine), an oxidation product of tyrosine produced by reaction between tyrosyl radicals, is becoming established as a biomarker of free radical oxidative protein damage in vivo. Attempts to measure dityrosine concentrations in various physiological and pathological systems have produced varied and often contradictory results. Dityrosine concentrations in urine, plasma, cerebrospinal fluid (CSF) and brain tissue varying over three orders of magnitude have been reported, together with inconsistent claims of significant dityrosine elevation in several ageing-related pathologies. Some of these findings have contributed to the implication of free radical activity in the pathology of several neurodegenerative disorders, vascular and ocular abnormalities and in phagocyte response to infection. The aim of this study was to test the hypothesis that dityrosine levels are elevated in ageing and ageing-related disease. The study also aims to determine the utility of dityrosine measurement as an index of oxidative damage, and elucidate possible explanations for the inconsistent levels reported. An assay for the quantification of dityrosine was developed using capillary HPLC with electrospray tandem quadrupole mass spectrometry (HPLC-MS/MS). The assay was highly specific for dityrosine and has the highest absolute sensitivity for dityrosine of any method reported to date, with a detection limit of 3 femtomoles of dityrosine on-column. Urine samples from volunteers of different age and from hospital patients with various pathologies were analysed. Plasma protein hydrolysates from control, Alzheimer???s and stroke subjects were analysed, together with hydrolysates of post mortem brain tissue from Alzheimer???s and control subjects. Urinary dityrosine level is elevated in states of acute infection and inflammation, but does not correlate with age or chronic disease. Protein dityrosine in four sections of Alzheimer???s brain was not significantly different from control sections. Dityrosine was present in human plasma and tissue proteins at approximately 5-35 residues per million tyrosine residues, and in normal urine at 5-25 micromol/mol creatinine or 20-200 nM. Most of the discrepancies in the literature relate to inadequate specificity of the analytical method. Interpretation of published data with critical appraisal of measurement technology specificity is essential in developing an accurate understanding of the role of free radicals in ageing and disease.

Tyrosine--Measurement

Free radicals (Chemistry)--Analysis

Active oxygen--Physiological effect.

The Emulsion Polymerization of Vinyl Acetate

De Bruyn, Hank

January 1999

Abstract This work investigates the kinetics of the emulsion polymerization of vinyl acetate. Several aspects of this system have been clarified, including the induced decomposition of persulfate, retardation by oxygen and entry by, and analysis of, the aqueous phase oligomeric radicals. It has been shown that the retardation period observed in the emulsion polymerization of VAc can be explained by the effect of traces of oxygen (< 10-6 M) on the entry efficiency of the initiator-derived aqueous-phase oligomeric radicals. Comparison of rates of polymerization in V and persulfate -initiated polymerizations together with electrospray mass spectrometry of aqueous phase oligomers, has shown that the mechanism for the induced decomposition of persulfate by vinyl acetate is chain transfer to initiator from aqueous-phase oligomeric radicals. A value has been determined for the rate coefficient for transfer to initiator, by fitting literature data to a model based on this mechanism. The reported independence of the rate of polymerization from the monomer concentration in the emulsion polymerization of vinyl acetate has been investigated. Possible explanations for this behaviour have been proposed and tested in this work, by measuring radical-loss rates directly with y-relaxation techniques. Although the Y relaxations were found to be affected by experimental artefacts, it has been demonstrated that rapid exit is not responsible for the high radical-loss rates in this system. The major artefact identified in the y relaxations was the significant effect of relatively small exotherms on relaxation behaviour, Methodologies were developed for correcting affected data and for avoiding exotherms under certain conditions. Arrhenius parameters were determined for the rate coefficient for chain transfer to monomer using the In^M method, which utilises the whole MWD. This section of the work is incomplete, for reasons detailed in chapter 5. However, as a preliminary indication it was found that the frequency factor was 106.38 M-1 s-1 and the activation energy was 38.8 kJ mol-1.

Theoretical Investigations of Radical-Mediated Protein Oxidation

Wood, Geoffrey Paul Farra

January 2006

Doctor of Philosophy (PhD) / This thesis primarily details the application of high-level ab initio quantum chemistry techniques in order to understand aspects of free-radical mediated protein oxidation. Traditionally, product analysis and electron paramagnetic resonance (EPR) spectroscopy are the primary means for elucidating the chemistry of protein oxidation. However, in experiments involving relatively small proteins reacting with a controlled radical-flux, a vast array of compounds can be produced, which are often difficult to analyse. Quantum chemical techniques on the other hand, can calculate the properties of any particular species directly, without suffering from the problems associated with experiment, such as side-reactions and chain processes. The results presented in this thesis are aimed at elucidating mechanistic details of protein oxidation, which might otherwise be difficult to probe experimentally. Chapter 1 gives an overview of the free-radical hypothesis of disease and ageing. Protein-derived radicals can undergo a variety of reactions, with the particular reaction that occurs depending on numerous aspects. Many types of reactions have been identified through radiolysis experiments of amino acids, and these are detailed in this chapter. In addition, the key reactive species are characterized and their different chemistries explained. Chapter 2 details the theoretical tools used throughout this thesis. Species with unpaired electrons (radicals) present unique problems for quantum chemistry to handle, thus an appropriate choice of theoretical technique is needed. The approach taken in this thesis is to use high-level compound methods, many of which have been directly formulated to give improved results for radical species, to provide benchmark quality results by which other less demanding techniques can be assessed. During the course of this study, it became apparent there was a void in the armoury of tools that could be used for the theoretical chemistry calculations. Chapter 3 details the formulation of a new tool in an attempt to fill this gap. Historically, the formulation of this new procedure came after much of the work in this thesis had been carried out. Thus, for the study of many of the reactions of this thesis the new method has not been used. However, it is most appropriate to place its formulation after summarizing the current status of techniques in common use today. Chapters 4 and 5 detail computations carried out on models of peptides containing backbone carbon- and nitrogen-centered radicals. A number of different theoretical techniques are used in these chapters, ranging from the highly accurate and computationally intensive to the less reliable and less demanding. The highly accurate techniques are used to gauge the accuracy of the other less demanding theoretical techniques so that the latter can be used with confidence in larger systems. Not only is the choice of theoretical technique important but also the judicious choice of model is essential. With this in mind, models are incrementally built until convergence of the particular property of interest is reached. Chapters 6 and 7 detail the calculations of β-scission reactions of alkoxyl radicals, which are a particular class of reaction known to occur on peptide backbones. Alkoxyl radicals are particularly difficult for theory to describe correctly. Therefore, Chapter 6 extensively assesses and then identifies the theoretical methods needed to portray them. Chapter 7 uses the techniques identified in the previous chapter in order to predict how the preference for a particular type of β-scission reaction changes.

Proteins -- Oxidation

Free radical reactions

Free radicals (Chemistry)

Thiyl radical reactions with alkynes in the absence and presence of oxygen

Tan, Kristine Joy Wei Mei

January 2009

This thesis is concerned with the reactions of sulfur-centred radicals and alkynes. The first objective of this work was to extend the scope of “self-terminating radical cyclisations” to sulfur-centred radicals, such as thiyl radicals. Preliminary experiments revealed that the reaction of thiyl radicals with alkynes was sensitive to residual oxygen. In the absence of oxygen, the reactions of photochemically generated phenylthiyl radicals with cyclodecyne (1) resulted in three isomeric sulfides, which were identified through a combination of techniques. (1S,6S)-2-phenylthiobicyclo[4.4.0]decane (trans-49a, unknown stereochemistry at C2) was identified by synthesis of an authentic sample, while the structure of (1S,2R,6S)-2-phenylthiobicyclo[4.4.0]decane (cis-49a1) was determined by X-ray analysis of the corresponding crystalline sulfone, cis-69. The third sulfide, (1S,2S,6S)-2-phenylthio-bicyclo[4.4.0]decane (cis-49a2), was assigned based on computational studies. / In addition, the reactions of benzylthiyl, tert-butylthiyl and allylthiyl radicals with cyclodecyne (1) were investigated. Various sources of thiyl radical generation were utilized, such as the photolysis of disulfides and thiols, hydrogen atom abstraction of thiols using radical initiators, as well as thiol autoxidation in the presence of oxygen. The radical cascade initiated by the addition of thiyl radicals to alkyne 1 was typically terminated by either reduction or disproportionation, whereas “self-termination” was only observed in one particular instance where the tert-butylthiyl radical was generated by autoxidation. However, this was only a minor pathway. / The second objective of this work was to investigate the reactions of thiyl radicals with alkynes in the presence of oxygen. For this purpose, phenylthiyl radicals were generated in the presence of diphenylacetylene (89) and molecular oxygen. Benzil (91), an α-diketone, and 1,2-diphenyl-2-(phenylthio)ethanone (93), an α-ketosulfide, were formed. The novel thiyl radical-mediated oxidation of diphenylacetylene to benzil mediated proceeds under mild and metal-free conditions, using various methods of thiyl radical generation. The product ratio of diketone to ketosulfide varied with the reaction conditions. Under photochemical conditions, benzil was formed but its photodegradation was also observed. Using autoxidation, moderate to good yields of both diketone 91 and ketosulfide 93 were obtained, although the product ratios varied with solvent and reaction conditions. Diketone 91 was the major product when the thiyl radical was generated electrochemically. Following investigation of the reaction mechanism using experimental and computational studies, the phenylthiyl peroxyl radical was identified as the key reactive intermediate. This represents the first synthetic application of thiyl peroxyl radicals. / Using autoxidation conditions, the oxidation was explored using substituted aromatic thiyl radicals, e.g. 2,6-dimethylbenzene, 2,4,6-tri-tert-butylbenzene, 4-methoxybenzene and 4-nitrobenzene thiyl radicals. Except for the case of 4-methoxybenzene thiyl radicals, where generation of the thiyl radicals was inefficient, diketone 91 was formed as the dominant product. This oxidation of alkynes to ketones, via thiyl radical-mediated activation of oxygen, was then applied to cyclodecyne (1). Bicyclic ketones 7/8 were found as the major products under photochemical conditions, while sulfides 152/trans-49a were the dominant products under autoxidation conditions. Bicyclic ketones 7/8 were formed due to the intramolecular radical processes directed by the transannular strain of the ten-membered carbon framework. Only trace amounts of the cyclic α-diketone 151 were detected under autoxidation conditions.

Analysis of free radical characteristics in biological systems based on EPR spectroscopy, employing blind source separation techniques

Ren, Jiyun.

January 2006

Thesis (Ph. D.)--University of Hong Kong, 2006. / Title proper from title frame. Also available in printed format.

The demonstration of electron-transfer reactions and their effect on model lignin condensation reactions under alkaline pulping conditions

Smith, Dean A.

01 January 1986

No description available.

Free radicals

Redox reactions

Lignins

Condensation

Reaction mechanisms

The autoxidation of methyl glycopyranosides

Church, John A.

01 January 1964

No description available.

Oxidation

Pyrans

Glucose

Nonautocatalytic reactions

Free radicals

Carbon-hydrogen bonds

Gemeinschaftsleben als Konstruktionsproblem Psychologische Untersuchung einer Gruppe der amerikanisch-jüdischen Gegenkultur /

Ahren, Yizhak.

January 1976

Inaugural Dissertation (Ph. D.)--Universität Köln, 1976. / Includes bibliographical references (p. 161-171).

Ozonation of erythromycin and the effects of pH, carbonate and phosphate buffers, and initial ozone dose

Huang, Ling, 1988-

29 September 2011

The ubiquitous presence and chronic effect of pharmaceuticals is one of the emerging issues in environmental field. As a result of incomplete removal by sewage treatment plants, pharmaceuticals are released into the environment and drinking water sources. On the other hand, conventional drinking water treatment processes such as coagulation, filtration and sedimentation are reported to be ineffective at removing pharmaceuticals. Therefore, the potential presence of pharmaceuticals in finished drinking water poses a threat on public health. Antibiotics, as an important group of pharmaceuticals, are given special concerns because the potential development of bacteria-resistance. Ozonation and advanced oxidation processes are demonstrated to be quite effective at removing pharmaceuticals. The oxidation of pharmaceuticals is caused by ozone itself and hydroxyl radicals that are generated from ozone decomposition. Whether ozone or hydroxyl radicals are the primary oxidant depends on the specific pharmaceutical of interest and the background water matrix. In this research, erythromycin, a macrolide antibiotic, was chosen as the target compound because of its high detection frequency in the environment and its regulation status. The objective of this research was to investigate the removal performance of erythromycin by ozonation from the standpoint of kinetics. The effects of pH, carbonate and phosphate buffers, and initial ozone dose on ozonation of erythromycin were also studied. The second-order rate constant for the reaction between deprotonated erythromycin and ozone was determined to be 4.44x10⁹ M⁻¹·s⁻¹ while protonated erythromycin did not react with ozone. Ozone was determined to be the primary oxidant for erythromycin removal by ozonation. pH was found to have great positive impact on the degradation of erythromycin by ozonation due to the deprotonation of erythromycin at high pH. Carbonate and phosphate buffers were found to have negligible effects on the degradation of erythromycin by ozonation. Initial ozone dose showed a positive impact on the total erythromycin removal rate by ozonation. / text

Pharmaceuticals

Ozonation

Erythromycin

Ozone

Hydroxyl radicals

Reaction rate constant

Kinetics

Microwave and Millimeter Wave Astrochemistry: Laboratory Studies of Transition Metal-Containing Free Radicals and Spectroscopic Observations of Molecular Interstellar Environments

Adande, Gilles Rapotchombo

January 2013

Progress in our understanding of the chemical composition of the interstellar medium leans both on laboratory analyses of high resolution rotational spectra from molecules that may be present in these regions, and on radio astronomical observations of molecular tracers to constrain astrochemical models. Due to the thermodynamic conditions in outer space, some molecules likely to be found in interstellar regions in relevant abundances are open shell radicals. In a series of laboratory studies, the pure rotational spectra of the transition metal containing radicals sulfur species ScS, YS, VS and ZnSH were obtained for the first time. In addition to accurate and precise rest frequencies for these species, bonding characteristics were determined from fine and hyperfine molecular parameters. It was found that these sulfides have a higher degree of covalent bonding than their mostly ionic oxide counterparts. Isomers and isotope ratios are excellent diagnostic tools for a variety of astrochemical models. From radio observations of isotopes of nitrile species, the galactic gradient of ¹⁴N/¹⁵N was accurately established. A further study of this ratio in carbon rich asymptotic giant branch stars provided observational evidence for an unknown process in J type carbon stars, and highlighted the need to update stellar nucleosynthesis models. Proper radiative transfer modeling of the emission spectra of interstellar molecules can yield a wealth of information about the abundance and distribution of these species within the observed sources. To model the asymmetric emission of SO and SO₂ in oxygen-rich supergiants, an in-house code was developed, and successfully applied to gain insight into circumstellar sulfur chemistry of VY Canis Majoris. It was concluded that current astrochemistry kinetic models, based on spherical symmetry assumptions, need to be revisited.

Radioastronomy

Rotational Spectroscopy

Small Radicals

Chemistry

Interstellar Medium