1.Chemistry of reactive oxygen species (ROS) 2. Sources, defense mechanisms and pathological consequences 3. A survey of pathological conditions connected.

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Presentation transcript:

1.Chemistry of reactive oxygen species (ROS) 2. Sources, defense mechanisms and pathological consequences 3. A survey of pathological conditions connected with ROS 4. Antioxidants in aging and disease

1. Chemistry of reactive oxygen species (ROS) Fig. 1 Generation of reactive oxygen metabolites

Superoxide radical O.- is produced by a single electron transfer onto molecular O2, which is thus reduced. Its main effect is an electron transfer onto further molecules, e.g., Fe3, Cu2, ferricytochrom c atd. Superoxide radical is a source for hydrogen peroxide and hydroxyl radical Hydrogen peroxide H2O2 is produced sponateously or under the catalytic influence of superoxid dismutase from the superoxide radical. No radical, mildly reactive. However, it may penetrate freely through membranes and is a source of potent oxidants as, e.g., of hydroxyl radical and oxidative iron compounds

Most potent from ROS and highly reactive is hydroxyl radical (HO  ). It may be produced - indirectly by decomposition of hydrogen peroxide by means of Fenton reaction catalyzed by iron or cooper - by interaction of nitric oxide NO with O. - by radiation hydrolysis of water A “normal” form of O2 is s.c. triplet oxygen 3O2. Activation energy transfer to the triplet oxygen  spin inversion  producing singlet oxygen 1O2 or O2*. It is a potent oxidant with extremely short life span. In biological systems formed via photosensitized reactions, chemiexcitation processes and enzymatic reactions. It may produce serious tissue damage

2. Sources, protective mechanisms and pathological consequences Fig. 2 Schematic overview of the main sources of ROS and their biological effects: oxidation of bioconstituents, stimulation of „repair“ mechanisms, and induction of protein synthesis

Sources: Superoxide radical and hydrogen peroxide are produced by biological sources. Modestly reactive, but via different redox reactions  highly reactive species (e.g., hydroxyl radical). 1. Aerobic metabolism: - electron-transfer chain in mitochondria  hydrogen peroxide - heart mitochondria  superoxide radical - activity of various oxidases, e.g., - xanthine oxidase  O.- (ischemia – reperfusion, Fig. 3: Ischemia anf reperfusion as sources of ROS) - microsomal electron transfer chain

2. Environmental factors: airborn pollutants, photochemic smog, industrial chemicals, ionizing radiation, metabolism of xenobiotics. Further, ischemia and reperfusion, traumas and infections (Tab. 1). 3. Specialized physiological reactions: NADP(H) oxidases in phagocytes, releasing of EDRF, autooxidation of hemoglobin in erythrocytes etc.

Protective mechanisms: Three types: 1. Primary antioxidants: some vitamins, micronutrients and enzymes 2. Secondary antioxidants: „repair“ enzymes scavenging non-functional cellular components (proteolytic and lipolytic enzymes) or really repairing the macromolecules (DNA-repair systems) 3. Proteins inducible by oxidative stress

3. A survey of pathological conditions connected with ROS Tab. Disorders associated with oxidative stress