Исследование антирадикальной активности природных и синтетических антиоксидантов методом ЭПР-спектроскопии : магистерская диссертация / Research of antiradical activity of natural and synthetic antioxidants by EPR spectroscopy

Вежливцев, Е. А., Vezhlivtsev, E. A.

January 2016

Вещества, обладающие антирадикальной активностью (АРА) играют ведущую роль в системе защиты организма от свободных радикалов. Общие недостатки известных способов оценки АРА выражаются в том, что измерения проводятся непрямыми методами, что затрудняет количественно оценивать содержание веществ с антирадикальными свойствами. Результаты измерений представляются в относительных единицах, в качестве эталонных веществ чаще всего используются: тролокс, галловая и аскорбиновая кислоты, проявляющие разную АРА, что не позволяет сравнивать результаты между собой. Таким образом, существует необходимость в разработке прямого, безэталонного метода оценки антирадикальной активности. Одним из потенциально возможных решений данной проблемы является метод ЭПР-спектроскопии на модели 2,2-дифенил-1-пикрилгидразил. Цель и задачи исследования. Исследование безэталонным методом оценки антирадикальной активности природных и синтетических антиоксидантов на модели 2,2-дифенил-1-пикрилгидразил с использованием ЭПР-спектроскопии. Отработка методики определения антирадикальной активности на модели ДФПГ методом ЭПР-спектроскопии. Получение и анализ значений антирадикальной активности для ряда веществ с антирадикальными свойствами. Сравнение с результатами полученными методом потенциометрического определения антиоксидантной активности с использованием медиаторной системы. Полученные результаты. Установлены оптимальные условия для проведения анализа. Проведено исследование - новым, безэталонным методом оценки антирадикальной активности, ряда природных и синтетических антиоксидантов. Установлены значения антирадикальной активности ряда природных и синтетических антиоксидантов. Рассмотрены различные варианты механизмов ингибирования свободных радикалов и их зависимость от структуры антиоксиданта. / Substances with anti-radical activity (ARA) play a leading role in the body's defense system against free radicals. General disadvantages of the known methods of evaluating the APA expressed in the fact that measurements are carried out by indirect methods, making it difficult to quantify the content of substances with antiradical properties. The measurement results are presented in relative units, as reference substances are most often used: Trolox, ascorbic and gallic acid, exhibit different ARA, which does not allow to compare the results with each other. Thus, there is a need to develop direct, reference-free method of evaluating anti-radical activity. One possible solution to this potential problem is the method of EPR model 2,2-diphenyl-1-picrylhydrazyl. The purpose and objectives of the study. Study standardless method for assessing the antiradical activity of natural and synthetic antioxidants model 2,2-diphenyl-1-picrylhydrazyl using EPR spectroscopy. Testing methods for determining the anti-radical activity in the DPPH model EPR spectroscopy. Obtaining and analyzing anti-radical activity values for a number of substances with antiradical properties. Comparison with the results obtained by potentiometric determination of antioxidant activity using a mediator system Results. The optimum conditions for analysis. The research - the new reference-free method of evaluating anti-radical activity, a number of natural and synthetic antioxidants. Established values antiradical activity of natural and synthetic antioxidants. Various embodiments of the mechanisms of inhibition of free radicals and their antioxidant dependency structure.

СВОБОДНЫЕ РАДИКАЛЫ

ЭПР СПЕКТРОСКОПИЯ

ДФПГ

MASTER'S THESIS

ANTIOXIDANT ACTIVITY

FREE RADICALS

EPR SPECTROSCOPY

DPPH

Role of Oxidative Stress in Diabetes Mellitus

Vinayak, Anubhav

21 May 2018

No description available.

Aging

Biochemistry

Biology

Gerontology

Health

Health Care

Health Sciences

Nutrition

Radiation induced graft copolymerization in wood

Werezak, G.N.

05 1900

1. Investigations of styrene polymerized in wood using ionizing radiation as the chain initiator indicate that property improvements are of the same order as for thermally initiated polymerization. 2. Free radicals have been detected in irradiated cellulose, Dioxane lignin, Spruce Periodate lignin and Beaun’s “Isolated Native Lignin” as well as in wood subjected to radiation. Consequently, wood radical identification is not possible. 3. Analysis of radical concentrations and decay suggest the presence of one or more decaying radical species in irradiated wood. The persistent maximum in radical concentration found corresponds to one or two unique radical sites per molecule; possibly the terminal hydroxyl group. 4. Results suggest that in the grafting reaction the initiation is a direct radical-monomer couple and does not involve decomposing peroxides. / Thesis / Master of Engineering (ME)

radiation

graft copolymerization

wood

styrene

dioxane lignin

spruce periodate lignin

radical concentration

free radicals

Lipidomics of oxidized polyunsaturated fatty acids.

Massey, Karen A., Nicolaou, Anna

06 1900

No / Lipid mediators are produced from the oxidation of polyunsaturated fatty acids through enzymatic and free radical-mediated reactions. When subject to oxygenation via cyclooxygenases, lipoxygenases, and cytochrome P450 monooxygenases, polyunsaturated fatty acids give rise to an array of metabolites including eicosanoids, docosanoids, and octadecanoids. These potent bioactive lipids are involved in many biochemical and signaling pathways, with inflammation being of particular importance. Moreover, because they are produced by more than one pathway and substrate, and are present in a variety of biological milieus, their analysis is not always possible with conventional assays. Liquid chromatography coupled to electrospray mass spectrometry offers a versatile and sensitive approach for the analysis of bioactive lipids, allowing specific and accurate quantitation of multiple species present in the same sample. Here we explain the principles of this approach to mediator lipidomics and present detailed protocols for the assay of enzymatically produced oxygenated metabolites of polyunsaturated fatty acids that can be tailored to answer biological questions or facilitate assessment of nutritional and pharmacological interventions.

Cyclooxygenase

Lipoxygenase

Cytochrome P450

Tandem mass spectrometry

Bioactive lipids

Eicosanoids

Docosanoids

Octadecanoids

Free radicals

Molecular Probes for Biologically Important Molecules: A Study of Thiourea, Hydroxyl radical, Peroxynitrite and Hypochlorous acid

Chakraborty, Sourav

14 May 2010

Numerous chemical species are important to the health of biological systems. Some species can be beneficial at low doses and harmful at high doses. Other species are highly reactive and trigger serious cell damage. Improved methods to detect the presence and activity of such species are needed. In this work, several biologically important species were studied using appropriate analytical techniques. Fluoride is an important species in human physiology. It strengthens teeth and gives protection against dental caries. However, elevated concentrations of fluoride in the body can lead to health problems such as dental and skeletal fluorosis. Reported fluoride sensors used fluorescence quenching methods in determining fluoride concentration. Our study explored synthesis and characterization of 1,8-bis(phenylthioureido) naphthalene (compound 1) as a fluoride sensing molecule. Compound 1 showed a remarkable 40 fold enhancement in fluorescence with 5 eq of fluoride addition. Compound 1 also showed possibility of visual colorimetric sensing with fluoride. Free radical mediated oxidations of biomolecules are responsible for different pathological conditions in the human body. Superoxide is generated in cells and tissues during oxidative burst. Moderately reactive superoxide is converted to peroxyl, alkoxyl and hydroxyl radicals by various enzymatic, chemical, and biochemical processes. Hydroxyl radical imparts rapid, non specific oxidative damage to biomolecules such as proteins and lipids. Superoxide also reacts with nitric oxide in cells to yield peroxynitrite, which is highly reactive and damages biomolecules. Both hydroxyl radical and peroxynitrite readily react with amino acids containing aromatic side chains. Low density lipoprotein (LDL) carries cholesterol in the human body. Elevated concentration of LDL is a potential risk factor for atherosclerosis. Previous research drew a strong correlation between oxidized low density lipoprotein (ox-LDL) and plaque formation in the arterial wall. More importantly, oxidative damage causes structural changes to the LDL protein (apo B-100) which might facilitate the uptake of LDL by macrophages. In this study LDL was exposed to various concentrations of hydroxyl radical peroxynitrite and hypochlorite. Thereafter oxidized amino acid residues in apo B-100 were mapped by LC-MS/MS methods. We found widely distributed oxidative modifications in the apo B-100 amino acid sequence.

fluoride

fluorescence enhancement

thiourea

chromogenic sensing

low density lipoproteins (LDL)

Fenton Chemistry

free radicals

hydroxyl radical

peroxynitrite

hypochlorus acid

surface mapping

proteomics

LC-MS/MS

natural variants

Efeitos do tempol sobre a interação entre peroxinitrito/CO2 com albumina e macrófagos: inibição da nitração de tirosinas e da oxidação de cisteínas e amplificação da nitrosação de cisteínas / Effects of tempol on the interaction between peroxynitrite/CO2 with albumin and macrophages: Inhibition of the nitration of tyrosine and oxidation of cysteine and amplification of cysteine nitrosation

Fernandes, Denise de Castro

19 February 2004

O tempol (TP) tem se mostrado um eficiente protetor em modelos inflamatórios. Os mecanismos de proteção contra espécies reativas de oxigênio foi bastante estudado mas sua interação com espécies reativas de nitrogênio ainda permanece pouco explorada. Recentemente, propusemos que o TP re-direciona a nitração de fenol mediada por peroxintrito (PN)/CO2 para nitrosação, pela sua reação com o radical CO3•‾. O produto desta reação, o cátion oxamônio, oxidaria PN para O2 e •NO. Este último produziria uma espécie nitrosante (N2O3) pela reação com o radical derivado do PN, •NO2 [Bonini e col. (2002) Chem. Res. Tox. 15: 506]. Para examinar se este mecanismo poderia operar in vivo, estudamos os efeitos do TP na reatividade do PN/CO2 frente a albumina (BSA) e macrófagos. Os efeitos do TP se apresentaram dependentes de sua concentração e da concentração de Cys. Apesar do TP não se mostrar catalítico, ele inibiu a oxidação de Cys (20-50%) e nitração de Tyr (70-90%) da BSA e aumentou a nitrosação de Cys (200-400%). No caso dos macrófagos tratados com PN/CO2, o tempol também inibiu a nitração (90%) e aumentou a nitrosação (300%). Assim, em condições fisiológicas, concentrações sub-estequiométricas de TP seriam capazes de redirecionar a reatividade dos radicais derivados PN, de oxidação de Cys proteica e nitração de Tyr para nitrosação de Cys. Desta forma, o TP poderia inibir a injúria em inflamações. / Tempol has been shown to protect animals from oxidative stress conditions. Tempol\'s protective mechanisms against reactive oxygen species have been extensively studied but its interactions with reactive nitrogen species remain little explored. Recently, we proposed that tempol diverts peroxynitrite/CO2 mediated phenol nitration to nitrosation by reacting with CO3•‾ to produce tempol oxamonium cation that oxidizes peroxynitrite to O2 and •NO. The latter produces a nitrosating species by reacting with peroxynitrite-derived •NO2 [Bonini et al. (2002) Chem. Res. Toxicol. 15: 506]. To examine wether this mechanism operates in biological environments, we studied the effects of tempol on peroxynitrite/CO2 reactivity towards a protein, BSA, and cells, macrophages. Tempol\'s effects were dependent on its own and BSA-cys concentration. Although not a true catalyst, it inhibited BSA-cys oxydation (20-50%) and BSA-tyr nitration (70-90%) while increasing BSA-cys nitrosation (200-400%). In the case of macrophages treated with peroxynitrite/CO2, tempol also inhibited protein-tyr nitration (90%) and increased protein-cys nitrosation (300%). Then, under physiological conditions, a substoichiometric amount of tempol is able to divert peroxynitrite-derived radicais reactivity from protein-cys oxidation and protein-tyr nitration to protein-cys nitrosation. This may be the mechanism by wich tempol inhibits injury in inflammatory conditions.

Albumin (Interaction)

Albuminas (Interação)

Biochemistry

Bioquímica

BSA

BSA

Free radicals

Nitration

Nitration

Nitrosation

Nitrosation

Nitroxide

Nitroxide

Peroxynitrite

Peroxynitrite

Radicais livres

Tempol

Tempol

Lesões em DNA promovidas por ácido 5-aminolevulínico: uma proposta de bases moleculares para hepatomos associados a porfirinopatias / DNA damage induced by 5-aminolevulinic acid: a molecular basis proposal for the hepatomas associated to porphyrinopathies

Onuki, Janice

01 August 2000

O ácido 5-aminolevulínico (ALA) é o primeiro precursor do grupo heme acumulado, principalmente no fígado, em alguns tipos de porfirias hepáticas hereditárias (porfiria aguda intermitente-AIP e tirosinemia) ou adquiridas (intoxicação por chumbo) devido à diminuição da atividade da enzima porfobilinogênio deaminase. Amostras de biópsias de fígado de pacientes portadores de AIP revelaram alterações estruturais nas mitocôndrias e no retículo endoplasmático, acúmulo de lipofuscina, gordura e corpúsculos de ferritina. Têm sido demonstrado que mutações mitocondriais induzidas por pró-oxidantes também contribuem para o envelhecimento celular e para o desenvolvimento do câncer. Esses dados podem estar relacionados à maior incidência de carcinoma hepatocelular (HCC) em pacientes sintomáticos de AIP. In vitro, ALA produz espécies reativas de oxigênio (ROS), através da oxidação catalisada por metais, e pode ser visto como uma fonte endógena de ROS, iniciando danos oxidativos a estruturas celulares como o DNA, podendo estar envolvido na iniciação e promoção do câncer. Além disso, o produto final de oxidação do ALA, o ácido 4,5-dioxovalérico (DOVA) é capaz de induzir modificações nas bases do DNA como outros derivados carbonílicos reativos. Neste estudo, demonstramos que o ALA é capaz de produzir danos ao DNA como quebras de fita de DNA plasmidial, aumento do nível de 8-oxo-7,8- dihidro-2\'-desoxiguanosina e 5-hidroxi-2´-desoxicitidina em DNA de órgãos de ratos tratados com ALA e aumento da formação de diversas bases modificadas em DNA de timo de bezerro. O DOVA reagiu com 2´-desoxiguanosina e DNA de timo de bezerro isolado produzindo dois adutos diastereoisômeros. O ALA e o DOVA foram capazes de aumentar a mutagenicidade em S. typhimurium TA104 e induzir resposta SOS em E. coli PQ37. Danos ao DNA mitocondrial e nuclear também foram detectados através da técnica de reação quantitativa em cadeia da polimerase em fibroblastos humanos transformados tratados com ALA. Todos esses dados fornecem informações referentes ao potencial genotóxico do ALA e permitem estabelecer uma proposta de bases moleculares para conectar as lesões ao DNA promovidas pelo ALA com a maior incidência de carcinoma hepatocelular em pacientes sintomáticos de AIP. / 5-Aminolevulinic acid (ALA) is a heme precursor accumulated in some inborn (acute intermittent porphyria-AIP and tyrosinosis) or acquired (lead poisoning) types of hepatic porphyria. In AIP patients, ALA is overproduced and accumulated in the liver. Liver biopsy samples of AIP patients revealed mitochondrial and endoplasmic reticulum structural alterations and accumulation of lipofucsin, fat and ferritin bodies. Mitochondrial mutations induced by pro- oxidants were suggested to contribute to cellular aging and cancer. These findings may be connected to the higher frequency of hepatocellular carcinoma (HCC) associated to symptomatic AIP patients. In vitro, ALA produces reactive oxygen species (ROS) upon metal- catalyzed oxidation and can be viewed as a deleterious endogenous source of ROS, triggering oxidative damage to cell structures and organs and being involved in the initiation and promotion of cancer. Besides, the final oxidation product of ALA, the 4,5-dioxovaleric acid (DOVA) is expect to induce DNA base modifications as already shown for other reactive carbonyl derivatives. In this study we demonstrated that ALA is able to produce DNA lesions such as strand breaks in plasmid DNA, increased steady state level of 8-oxo-7,8- dihydro-2\'-deoxyguanosine and 5-hydroxy-2´-deoxycytidine in rat organs DNA of ALA-treated rats and increased formation of several modified DNA bases in calf thymus DNA. 4,5-Dioxovaleric acid was showed to react with 2\'-deoxyguanosine and isolated calf thymus DNA through Schiff?s base formation to produce two diastereisomeric adducts. Aminolevulinic acid and DOVA were able to increase mutagenicity of the S. typhimurim strain TA104 and induce SOS response in E. coli PQ37. The mitochondrial and nuclear DNA damage were also detected by quantitative polymerase chain reaction technique in transformed human fibroblasts treated with ALA. All these data provide additional information on the genotoxic potential of ALA and reinforce the hypothesis that ALA may be involved in the induction of HCC in symptomatic AIP patients.

Ácido 5-aminolevulínico

Acute intermittent porphyria

Aminolevulinic acid

Cancer

Câncer

DNA

DNA

Free radicals

Hepatoma

Hepatoma

Porfiria aguda intermitente

Radicais livres

Mecanismo de oxidação aeróbica de acetoacetato e 2-metilacetoacetato catalisada por mioglobina: implicações em desordens cetogênicas / Mechanism of the aerobic oxidation of acetoacetate and 2- methylacetoacetate catalyzed by Mb: implications for ketogenic disorders

Silva, Douglas Ganini da

20 April 2011

Acetoacetato (AA) e 2-metilacetoacetato (MAA) são compostos β-cetoácidos acumulados em diversas desordens metabólicas como no diabetes e na isoleucinemia, respectivamente. Examinamos o mecanismo de oxidação aeróbica de AA e MAA iniciada por intermediários reativos de mioglobina de coração de cavalo (Mb) gerados pela adição de H2O2. Uma rota quimioluminescente que envolve um intermediário dioxetânico cuja termólise gera espécies α-dicarbonílicas (metilglioxal e biacetilo) foi proposta e estudada. Emissão de luz ultra fraca acompanha a reação, e sua intensidade aumenta linearmente pelo aumento da concentração tanto de Mb (10-500 µM) quando AA (10-100 mM). Estudos de consumo de oxigênio mostraram que MAA é, como esperado, quase uma ordem de grandeza mais reativo que AA. Estudos de EPR com captação de spin, utilizando MNP, possibilitaram detectar adutos de MAA atribuíveis a um radical centrado no Cα (aN = 1.55 mT) e ao radical acetila (aN = 0.83 mT). O sinal do radical acetila é totalmente suprimido por sorbato, um conhecido e eficiente supressor de espécies tripletes, o que é consistente com uma rota reacional envolvendo um intermediário dioxetânico. Clivagem-α da ligação carbonila-carbonila do produto biacetilo triplete produziria, de fato, radicais acetila. Além disso, utilizando AA como substrato para Mb/H2O2, um sinal de EPR atribuível ao aduto MNP-AA• (aN = 1.46 mT e aH = 0.34 mT) foi observado e confirmado por efeito isotópico. O consumo de oxigênio e o rendimento de compostos α-dicarbonílicos foram dose-dependentes à concentração de AA ou MAA (1-50 mM) bem como à concentração de H2O2 adicionado às misturas de reação contendo Mb (até 1:10 quando medido o consumo de oxigênio, e até 1:25 quando medido o rendimento de compostos α-dicarbonílicos) e tert-butilhidroperóxido (até 1:200). Os perfis de pH (5,8-7,8) para consumo de oxigênio e rendimento de compostos α-dicarbonílicos mostraram maiores rendimentos para baixos valores de pH, indicativo de ferrilMb formada no ciclo peroxidático da proteína. Avaliando os níveis de lesão de Mb, os β-cetoácidos diminuíram o nível de desorganização protéica na estrutura secundária e terciária elicitada por H2O2. Ainda, houve maior preservação da estrutura primária da proteína, sendo que MAA protegeu mais em comparação a AA, embora quando utilizado este último composto, foi mostrado que há acetilação dose-dependente de Mb. Acetoacetato aumentou a velocidade de descoramento da hemeproteína, provavelmente por ataque de espécies tripletes geradas no sistema. Músculos de rato, plantar e sóleo, expostos ex vivo a concentrações citotóxicas de glicose oxidase (GOX, gera H2O2 em fluxo), foram protegidas pelos ésteres etílicos AAE e MAAE. Foi detectado biacetilo no meio intracelular em músculos expostos a MAAE e GOX. A concentração deste composto α-dicarbonílico é claramente relacionada à abundância de Mb em cada um dos tipos de músculos estudados. Em resumo, Mb tratada com metabólitos β-cetoácidos (AA e MAA) gera radicais centrados em carbono e produtos α-dicarbonílicos altamente reativos no estado triplete. Experimentos realizados com tecido muscular ex vivo sugerem que esta reação possivelmente ocorra in vivo. Levantamos a hipótese de que a geração de espécies carbonílicas reativas e seus adutos em condições de desbalanço metabólico possam contribuir para a compreensão das bases moleculares de desordens cetogênicas. / Acetoacetate (AA) and 2-methylacetoacetate (MAA) are β-ketoacids accumulated in several metabolic disorders such as diabetes and isoleucinemia, respectively. Here we examine the mechanism of AA and MAA aerobic oxidation initiated by the reactive enzyme intermediates formed by the reaction of muscle horse myoglobin (Mb) with H2O2. A chemiluminescent route involving a dioxetane intermediate whose thermolysis yields triplet α-dicarbonyl species (methylglyoxal and diacetyl) is envisaged. Accordingly, the ultraweak light emission that accompanies the reaction increases linearly by raising the concentration of both Mb (10-500 µM) and AA (10- 100 mM). Oxygen uptake studies revealed that MAA is, expectedly, almost one order of magnitude more reactive than AA. EPR spin-trapping studies with MNP detected spin adducts from MAA attributable to an α-carbon-centered radical (aN = 1.55 mT) and to an acetyl radical (aN = 0.83 mT). As the acetyl radical signal is totally suppressed by sorbate, a well-known efficient triplet species quencher, the dioxetane hypothesis seems to be reliable. The α-cleavage of the carbonyl-carbonyl bond of a putative excited triplet diacetyl product would, in fact, leads to an acetyl radical. Furthermore, using AA as substrate for Mb/H2O2, an EPR signal assignable to a MNP-AA• adduct (aN = 1.46 mT and aH = 0.34 mT) was observed and confirmed by isotope effect. Oxygen consumption and α-dicarbonyl yield were also dependent on AA or MAA concentrations (1-50 mM) as well as on the concentration of peroxide added to the Mb-containing reaction mixtures: H2O2 (up to 1:10 when measuring oxygen uptake and up to 1:25 when measuring the α-dicarbonyl yield) and t-butOOH (up to 1:200). The pH profiles (5.8-7.8) of oxygen consumption and α-dicarbonyl yield show higher reaction rates at lower pHs, indicative of a ferrylMb intermediate. Evaluating Mb lesion, both β-ketoacids reduced disorganization of the secondary and tertiary protein structure elicited by H2O2. Therefore, Mb primary structure was more preserved, and MAA was more protective than AA. Moreover using the later compound, it was shown that Mb acetylation is dose-dependent. Acetoacetate increased the rate of the hemeprotein bleaching, probably due to the attack of triplet products generated in the system. Plantaris and soleous rat muscles exposed to damaging concentrations of glucose oxidase (GOX, generates H2O2 in flux), was cytoprotected by AAE and MAAE. Intracellular diacetyl was detected in muscle samples exposed to MAAE and GOX. The α-dicarbonyl concentration is clearly related to the Mb abundance in the muscle types. In summary, Mb treated with peroxides reacts with β-ketoacid metabolites (AA and MAA), yielding carbon-centered radicals and highly reactive α-dicarbonyl products in the triplet state. Experiments carried out ex vivo with muscle tissue showed that this reaction possibly occurs in vivo. A new route for generation and accumulation of carbonyl reactive species and adducts is here proposed to occur in unbalanced metabolic situations, such as is the case of ketogenic disorders.

2-methylacetoacetate

2-metilacetoacetato

Acetoacetate

Acetoacetato

Biacetilo

Cetose

Diacetyl

Espécies carbonílicas tripletes

Free radicals

Ketosis

Methylglyoxal

Metilglioxal

Mioglobina

Myoglobin

Radicais livres

Triplet carbonyls

Metabolimos radicalares do etanol e alquilação de ácidos nucleicos estudos in vitro e in vivo / Ethanol radicals and nucleic acid alkylation studies in vitro and in vivo studies

Nakao, Lia Sumie

31 January 2002

O consumo de álcool vem sendo associado a um aumento do risco de câncer e a uma situação de estresse oxidativo. Os metabólitos responsáveis por tais processos permanecem em discussão. Neste trabalho, caracterizamos novos metabólitos radicalares do etanol e examinamos suas interações com ácidos nucléicos. Primeiramente, demonstramos que os radicais 1-hidroxietila e 2-hidroxietila produzidos durante a oxidação do etanol por sistemas Fenton alquilam DNA e RNA in vitro produzindo os adutos 8-(1-HE)Gua e 8-(2-HE)Gua, respectivamente. Esses adutos foram sintetizados e caracterizados quimicamente. Também, demonstramos que acetaldeído, o principal metabólito do etanol, é oxidado por sistemas Fenton, peroxinitrito, xantina oxidase, partículas submitocondriais e ratos a radicais acetila e metila. Esses radicais foram caracterizados e seus mecanismos de formação elucidados, pelo menos in vitro. A possibilidade do radical 1-hidroxietila alquilar ácidos nucléicos in vivo foi também examinada. Inesperadamente, o aduto 8-(1-HE)Gua foi detectado em RNA e DNA do fígado de ratos controle e seus níveis não foram significativamente alterados após administração aguda de etanol. Esses resultados sugerem que os radicais 1-hidroxietila, acetila e metila são importantes metabólitos do etanol in vivo mas atacam preferencialmente outras biomoléculas que não ácidos nucléicos. / Alcohol consumption has been associated with increased cancer risk and an oxidative stress condition. Ethanol metabolites responsible for these processes remain debatable. Here, we characterized novel radical metabolites of ethanol and examined their interactions with nucleic acids. First, we demonstrated that the 1-hydroxyethyl and 2-hydroxyethyl radical produced from ethanol oxidation by Fenton systems alkylated DNA and RNA in vitro to produce 8-(1HE)Gua and 8-(2-HE)Gua, respectively. Both adducts were synthesized and structurally characterized. Next, we demonstrated that acetaldehyde, the main ethanol metabolite, is oxidized by Fenton systems, peroxynitrite, xanthine oxidase, submitochondrial particles and whole rats to acetyl and methyl radicals. These radicals were characterized and their production mechanisms in vitro elucidated. The possibility of the 1-hydroxyethyl radical alkylating nucleic acids in vivo was also examined. Unexpectedly, the adduct 8-(1-HE)Gua was detected in RNA and DNA from liver of control rats and their levels were not increased by acute ethanol treatment. Overall, the results suggest that the radicals 1-hydroxyethyl, acetyl and methyl are important ethanol metabolites in vivo but they preferentially attack biomolecules other than nucleic acids.

Acetaldehyde

Acetaldeído

Carcinogênese

Carcinogenesis

Danos a ácidos nucléicos

Ethanol metabolism

Free radicals

Metabolismo do etanol

Nucleic acid damage

Oxidação (Metabolismo)

Oxidation (Metabolism)

Radicais livres

Xenobiotic (Study)

Xenobiótico (Estudo)

Hidroperóxidos de lipídios como fontes de oxigênio molecular singlete (O2 [1Δg]), detecção e danos em biomoléculas / Lipid hidroperoxides as singlet molecular oxygen precursors (O2 [1Δg]), detection and damage to biomolecules

Ângeli, José Pedro Friedmann

21 July 2011

O estudo do processo da peroxidação de lipídios tem aumentado nos últimos anos, principalmente devido à implicação dos hidroperóxidos de lipídios (LOOH) em diversos processos patológicos. A decomposição destes LOOH é capaz de gerar subprodutos capazes de promover danos em biomoléculas, incluindo proteínas e DNA. No presente trabalho, utilizando hidroperóxidos de ácido linoléico isotopicamente marcado com átomo de oxigênio-18 (LA18O18OH), fomos capazes de demonstrar que estas moléculas gerararam oxigênio singlete marcado [18(1O2)] em células em cultura. A detecção de tal espécie foi possível através da utilização de uma nova metodologia utilizando um derivado antracenico. Para este propósito foi utilizado o derivado de antraceno 3,3\'-(9,10-antracenodiil) bisacrilato (DADB), cujo produto especifico da reação com o 1O2 (o endoperóxido do DADB DADBO2) do pode ser facilmente detectado por HPLC-MS/MS. De forma a expandir a compreensão dos efeitos tóxicos desses LOOH, investigamos o efeito destes compostos gerados intracelularmente. Para tal, foi utilizado o Rosa bengala (RB), um fotosensibilizador que tem afinidade por espaços apolares como membranas e lisossomos. A fotosenssibilização deste composto foi capaz de induzir a morte celular, e esta morte estaria relacionada a uma maior formação de 1O2 e a um maior acumulo de peróxidos. Nestes estudos foi possível demonstrar que carotenóides e sistemas antioxidantes dependentes de glutationa foram capazes de proteger contra os efeitos tóxicos da fotosensibilização na presença de RB. Adicionalmente foram avaliados os efeitos da hemoglobina (Hb) e do hidroperóxido do ácido linoléico (LAOOH) em uma série de parâmetros toxicológicos, como citotoxicidade, estado redox, a peroxidação lipídica e dano ao DNA. Nós demonstramos que a pré-incubação das células com Hb e sua posterior exposição à LAOOH (Hb + LAOOH) levou a um aumento na morte celular, a oxidação do DCFH, formação de malonaldeído e fragmentação do DNA e que esses efeitos estavam relacionados com o grupo peróxido e ao heme presentes na Hb. Foi demonstrado que as células incubadas com LAOOH e Hb apresentaram um nível maior das lesões de DNA; 8-oxo-7,8-diidro-2 \'desoxiguanosina e 1,N2-etheno-2\'-desoxiguanosina. Além disso, as incubações com Hb levaram a um aumento nos níveis de ferro intracelular, e este alto nível de ferro correlacionada com a oxidação do DNA, avaliadas através da medida de sitios EndoIII e Fpg sensíveis. Nossos resultados comprovam que os LAOOHs apresentaram efeito citotóxico e genotóxico, mesmo em concentrações muito baixas, podendo contribuir para o desencadeamento de processos patologicos como o câncer e doenças cardiovasculares e neurodegenerativas. / The study of the process of lipid peroxidation has increased in recent years, mainly due to the involvement of lipid hydroperoxide (LOOH) in a series of pathological processes. The decomposition of LOOH is able to generate products that can promote damage to biomolecules, including proteins and DNA. In the present work, using linoleic acid hydroperoxide isotopically labeled with 18O2 (LA18O18OH), we demonstrate that these molecules were able to generate labeled singlet oxygen [18(1O2)] in cultured cells. The detection of such species was possible using a new methodology using an anthracene derivative .For this purpose we used the anthracene derivative of 3,3\'-(9,10-antracendiil) bisacrilate (DADB), whose specific reaction product with 1O2 (DADB endoperoxide DADBO2) can be easily detected by HPLC-MS/MS. In order to expand the understanding of the toxic effects of LOOH, we investigated the effect of these compounds generated intracellularly. For this porpoise, we used Rose Bengal (RB), a photosensitizer that has affinity for apolar spaces such as membranes and lysosomes. The photosensitization of this compound was able to induce cell death, and this death was related to increased formation of 1O2 and a higher accumulation of peroxides. In these studies we have shown that carotenoids and glutathione-dependent antioxidant systems were capable of protecting against the toxic effects of photosensitization in the presence of RB. Additionally, we evaluated the effects of hemoglobin (Hb) and linoleic acid hydroperoxide (LAOOH) in a series of toxicological endpoints such as cytotoxicity, redox status, lipid peroxidation and DNA damage. We demonstrated that preincubation of cells with Hb and its subsequent exposure to LAOOH (Hb + LAOOH) led to an increase in cell death, DCFH oxidation, formation of malonaldehyde and DNA fragmentation, and that these effects were related to the peroxide and the heme group. It was demonstrated that cells incubated with LAOOH and Hb showed a higher level of the DNA lesions, 8-oxo-7,8-dihydro-2\'deoxyguanosine and 1,N2-etheno-2\'-deoxyguanosine. Furthermore, incubations with Hb led to an increase in intracellular iron levels, and this high level of iron correlates with the oxidation of DNA, measured as EndoIII and Fpg-sensitive sites. Our results show that the LOOHs showed cytotoxic and genotoxic, even at very low concentrations and may contribute to the onset of chronic malignancies like cancer, cardiovascular and neurodegenerative diseases.

Anthracene derivatives

Derivados de antraceno

Free radicals

Genotoxicidade

Genotoxicity

Hemoglobin

Hemoglobina

Hidroperóxidos de lipídio

HPLC-MS/MS

HPLC-MS/MS

Lipid hidroperoxides

Oxigênio molecular singlete

Radicais livres

Singlet molecular oxygen