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Molecular Basis of Oxidative Stress: Chemistry, Mechanisms, and Disease Pathogenesis
Molecular Basis of Oxidative Stress: Chemistry, Mechanisms, and Disease Pathogenesis
Molecular Basis of Oxidative Stress: Chemistry, Mechanisms, and Disease Pathogenesis
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Molecular Basis of Oxidative Stress: Chemistry, Mechanisms, and Disease Pathogenesis

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Sets the stage for the development of better diagnostic techniques and therapeutics

Featuring contributions from an international team of leading clinicians and biomedical researchers, Molecular Basis of Oxidative Stress reviews the molecular and chemical bases of oxidative stress, describing how oxidative stress can lead to the development of cancer and cardiovascular and neurodegenerative diseases. Moreover, it explains the potential role of free radicals in both the diagnosis and the development of therapeutics to treat disease.

Molecular Basis of Oxidative Stress is logically organized, beginning with a comprehensive discussion of the fundamental chemistry of reactive species. Next, the book:

  • Presents new mechanistic insights into how oxidative damage of biomolecules occurs
  • Examines how these oxidative events effect cellular metabolism
  • Investigates the role of oxidative stress in the pathogenesis of cancer, neurodegenerative disease, cardiovascular disease, and cystic fibrosis
  • Explores opportunities to improve the diagnosis of disease and the design of new therapeutic agents

Readers will find much novel information, including new radical chemistries and the latest discoveries of how free radicals react with biomolecules. The contributors also present recent findings that help us better understand the initiation of oxidative stress and the mechanisms leading to the pathogenesis of various diseases.

Throughout the book, the use of molecular structures helps readers better understand redox chemistry. In addition, plenty of detailed figures illustrate the mechanisms of oxidative stress and disease pathogenesis.

Examining everything from the basic chemistry of oxidative stress to the pathogenesis of disease, Molecular Basis of Oxidative Stress will help readers continue to explore the nature of oxidative stress and then use that knowledge to develop new approaches to prevent, detect, and treat a broad range of disease conditions.

LanguageEnglish
PublisherWiley
Release dateJun 6, 2013
ISBN9781118355879
Molecular Basis of Oxidative Stress: Chemistry, Mechanisms, and Disease Pathogenesis
Author

Frederick A. Villamena

Prof. Villamena received his Ph.D. in chemistry from Georgetown University and joined Ohio State in 2001. He has held a number of positions there, including several years as a research scientist/principal investigator in the Center for EPR Spectroscopy and Imaging (electron paramagnetic resonance). His current research interest is in the advancement of free radical detection and identification by EPR spectroscopy focusing mainly on the development of new spin traps and probes for chemical, biological, and biomedical imaging applications. Prof. Villamena publishes and lectures widely on this subject and has chaired the Free Radicals Session at the Rocky Mountain Conference on Analytical Chemistry for the past three years. He is an ad hoc grant reviewer for NIH and international funding agencies for the development of radical probes, and regularly reviews manuscripts on radical-related topics.

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    Molecular Basis of Oxidative Stress - Frederick A. Villamena

    About the Contributors

    D. Allan Butterfield was born in Maine. He obtained his PhD in Physical Chemistry from Duke University, followed by an NIH Postdoctoral Fellowship in Neurosciences at the Duke University School of Medicine. He then joined the Department of Chemistry at the University of Kentucky in 1975, rising to Full Professor in eight years. He is now the UK Alumni Association Endowed Professor of Biological Chemistry, Director of the Center of Membrane Sciences, Director of the Free Radical Biology in Cancer Core of the UK Markey Cancer Center, and Faculty of the Sanders-Brown Center on Aging at the University of Kentucky. He has published more than 550 refereed papers on his principal NIH-supported research areas of oxidative stress and redox proteomics in all phases of Alzheimer disease and in mechanisms of chemotherapy-induced cognitive dysfunction (referred to by patients as chemobrain). His chapter contribution was coauthored by Rukhsana Sultana and Giovanna Cenini.

    Giovanna Cenini received her PhD in Pharmacology from the University of Brescia in Italy. After spending two years in the Butterfield laboratory as a predoctoral fellow and two years as a postdoctoral scholar, Dr. Cenini is now a postdoctoral scholar in Biochemistry at the University of Bonn. She has published approximately 15 papers from her time in the Butterfield laboratory mostly on oxidative stress and p53 in Alzheimer disease and Down syndrome.

    Yeong-Renn Chen was born in Taipei, Taiwan, and received his PhD in Biochemistry from Oklahoma State University. Following as NIH-NIEHS IRTA postdoctoral fellow (under the mentorship of Dr. Ronald P. Mason), he joined the Internal Medicine Department of the Ohio State University, where he was promoted to the rank of Associate Professor. He is currently an Associate Professor of Physiology and Biochemistry at the Department of Integrative Medical Sciences of Northeast Ohio Medical University. His research focuses on mitochondrial redox, the mechanism of mitochondria-derived oxygen free radical production, and their role in the disease mechanisms of myocardial ischemia and reperfusion injury.

    Joseph Darling received his BS in Chemistry from Lake Superior State University, and his doctoral research focuses on the role and specificity of posttranslational modifications involved in peptide hormone signaling.

    Sean S. Davies was born in Honolulu, Hawaii. He obtained his PhD in Experimental Pathology from the University of Utah, followed by a postdoctoral fellowship in Clinical Pharmacology at Vanderbilt University, where he is now an Assistant Professor of Pharmacology. His research centers on the role of lipid mediators in chronic diseases including atherosclerosis and diabetes with an emphasis on mediators derived nonenzymatically by lipid peroxidation. His goal is to develop pharmacological strategies to modulate levels of these mediators and thereby treat disease. His chapter contribution was coauthored with Lilu Guo.

    Brian J. Day was born in Montana. He obtained his PhD in Pharmacology and Toxicology from Purdue University, followed by an NIH Postdoctoral Fellowship in Pulmonary and Toxicology at Duke University. He then joined the Department of Medicine at National Jewish Health, Denver, Colorado in 1997 and is currently a Full Professor and Vice Chair of Research. He has published more than 120 refereed papers on his principal NIH-supported research areas of oxidative stress and lung disease. He is also a founder of Aeolus Pharmaceuticals and inventor on its product pipeline. He currently serves as Chief Scientific Officer for Aeolus Pharmaceuticals that is developing metalloporphyrins as therapeutic agents. His chapter contribution was coauthored by Neal Gould.

    Grégory Durand was born in Avignon, France. He obtained his PhD in Organic Chemistry from the Université d'Avignon in 2002. In 2003 he was appointed Maître de Conférences at the Université d'Avignon where he obtained his Habilitation Thesis in 2009. In 2007 and 2009 he spent one semester at the Davis Heart & Lung Research Institute (The Ohio State University) as a visiting scholar. He is currently the Director of the Chemistry Department of the Université d'Avignon. His research focuses on the synthesis of novel nitrone compounds as probes and therapeutics. He is also involved in the development of surfactant-like molecules for handling membrane proteins.

    Susan Flynn received her BS in Medicinal Chemistry and B.A. in Chemistry and from SUNY-University at Buffalo, and her doctoral research focuses on determining the substrate reactivity requirements for in vivo posttranslational modification and activation of associated cellular pathways.

    Rodrigo Franco was born in Mexico, City, Mexico, and received his BS in Science and his PhD in Biomedical Sciences from the National Autonomous University of Mexico, Mexico City. His postdoctoral training was done at the National Institute of Environmental Health Sciences-NIH in NC. Then, he joined the Redox Biology Center and the School of Veterinary and Biomedical Sciences at the University of Nebraska-Lincoln, where he is currently an Assistant Professor. His research is focused on the role of oxidative stress and thiol-redox signaling in neuronal cell death.

    Aracely Garcia-Garcia coauthored the chapter by Rodrigo Franco. Born in Monterrey, Mexico, she received her PhD in Morphology from Autonomous University of Nuevo Leon. Following as Research Scholar at University of Louisville, KY, she joined the School of Veterinary Medicine and Biomedical Sciences of the University of Nebraska-Lincoln, where she is currently Postdoctoral Fellow Associate. Her research encompasses the understanding of the mechanisms of oxidative stress and autophagy in experimental Parkinson's disease models.

    Alexandros G. Georgakilas is an Associate Professor of Biology at East Carolina University (ECU) in Greenville, NC and recently elected Assistant Professor at the Physics Department, National Technical University of Athens (NTUA), Greece. At ECU, he has been responsible for the DNA Damage and Repair laboratory and having trained several graduate (1 PhD and 8 MSc) and undergraduate students. His work has been funded by various sources like East Carolina University, NC Biotechnology Center, European Union and International Cancer Control (UICC), which is the largest cancer fighting organization of its kind, with more than 400 member organizations across 120 countries. He holds several editorial positions in scientific journals. His research work has been published in more than 50 peer-reviewed high-profile journals like Cancer Research, Journal of Cell Biology, and Proceedings of National Academy of Sciences USA and more 1000 citations. Ultimately, he hopes to translate his work of basic research into clinical applications using DNA damage clusters as cancer or radiation biomarkers for oxidative stress. Prof. Georgakila coauthored his chapter with Thomas Kryston.

    Neal S. Gould received his PhD in Toxicology from the University of Colorado at Denver in 2011, and he is currently a Postdoctoral Fellow at the University of Pennsylvania in Dr. Ischiropoulos' research group. He has published seven refereed papers in the area of oxidative stress and lung disease.

    Lilu Guo received her PhD in Chemistry from the University of Montana, and she is currently a postdoctoral research fellow in the Davies lab. Her research utilizes mass spectrometry and other biochemical techniques to characterize biologically active phosphatidylethanolamines modified by lipid peroxidation products.

    James L. Hougland was born in Rock Island, Illinois. He obtained his PhD in Chemistry from the University of Chicago, followed by an NIH Postdoctoral Fellowship in Chemistry and Biological Chemistry at the University of Michigan, Ann Arbor. He then joined the Department of Chemistry at Syracuse University in 2010 as an assistant professor. His research focuses on protein posttranslational modification, in particular the specificity of enzymes that catalyze protein modification and the impact of those modifications on biological function. His chapter contribution was coauthored by Joseph Darling and Susan Flynn.

    Xueting Jiang is currently a doctoral student at the Department of Human Nutrition, Ohio State University, and focusing on dietary oxidized lipids and oxidative stress. She is the recipient of the AHA predoctoral fellowship, and is pursuing her PhD in Dr. Sampath Parthasarathy’s research group.

    Amy R. Jones was born in Cincinnati, OH. She received a BA degree majoring in Chemistry from the University of Cincinnati. She is currently pursuing an MS degree in Biochemistry at the University of Cincinnati. Her research, under the direction of Dr. Edward J. Merino and Dr. Stephanie M. Rollmann, involves exploring the biochemisty of cytotoxic antioxidants.

    Thomas B. Kryston, was born in Saint Petersburg, Florida, and received his MS in Molecular Biology and Biotechnology at East Carolina University. His graduate work focused on Oxidative Clustered DNA Lesions as potential biomarkers for cancer. Following his graduate studies, he was employed by The Mayo Clinic where his research interests were with Hexanucleotide expansions in ALS patients.

    Yunbo Li is a professor and chair of the Department of Pharmacology and assistant dean for biomedical research at Campbell University School of Osteopathic Medicine. He is an adjunct professor at the Department of Biomedical Sciences and Pathobiology at Virginia Polytechnic Institute and State University, and an affiliate professor at Virginia Tech-Wake Forest University School of Biomedical Engineering and Sciences. He currently serves as Co-Editor-in-Chief for Toxicology Letters and on the editorial boards of Cardiovascular Toxicology, Experimental Biology and Medicine, Molecular and Cellular Biochemistry, Neurochemical Research, and Spinal Cord. Dr. Li is an active researcher in the areas of free radicals, antioxidants, and drug discovery, and the author of over 100 peer-reviewed publications and two recent monographs: Antioxidants in Biology and Medicine: Essentials, Advances, and Clinical Applications; and Free radical Biomedicine: Principles, Clinical Correlations, and Methodologies. The research in his laboratories has been funded by the United States National Cancer Institute (NCI), National Heart, Lung and Blood Institute (NHLBI), National Institute of Diabetes and Digestive and Kidney Diseases (NIDDK), American Institute for Cancer Research (AICR), and Harvey W. Peters Research Center Foundation. Dr. Li was joined by Hong Zhu, Jianmin Wang, and Aben Santo in his chapter.

    Dmitry Litvinov received his PhD in Engelhardt Institute of Molecular Biology, Russia. He is currently working as a postdoctoral fellow at the University of Central Florida in Dr. Sampath Parthasarathy’s research group.

    Aimin Liu was born in China. He obtained his PhD from Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences and from Stockholm University. He did postdoctoral research at Xiamen University, University of Newcastle upon Tyne, and University of Minnesota. He started his independent research career at University of Mississippi Medical Center in October 2002, rising to Associate Professor in 2008 with tenure. He joined the chemistry faculty of Georgia State University in 2008 and was promoted to tenured Full Professor in 2012. He has published more than 60 refereed papers reporting mechanisms of oxygen activation by metalloproteins and metal-mediated signal transduction. His chapter is coauthored by Imran Rehmani and Fange Liu.

    Fange Liu was born in Beijing, China. After obtaining her Bachelors degree with honors, she joined Georgia State University in 2008 to pursue her PhD degree in the area of redox regulation by metalloproteins in cell signaling.

    Margaret M. Loniewska is currently a doctoral student in toxicology in the Department of Pharmaceutical Sciences at the University of Toronto, focusing upon the role of glucose-6-phosphate dehydrogenase in neurodegeneration.

    Edward J. Merino was born San Diego, CA and received his PhD in Bio-organic Chemistry from the University of North Carolina at Chapel Hill. Following as postdoctoral fellow at the California Institute of Technology, he joined the Chemistry Department of the University of Cincinnati, where he is currently an Assistant Professor. His research encompasses DNA damage, specifically DNA-protein cross-links and evaluation of DNA repair signaling, induced from reactive oxygen species and the design of novel cytotoxic antioxidants. His chapter contribution was coauthored by Dessalegn B. Nemera and Amy R. Jones.

    Chandrakala Aluganti Narasimhulu received her PhD in Immunology from Sri Krishnadevarya University, India; and she is currently a postdoctoral fellow at the University of Central Florida in Dr. Sampath Parthasarathy’s research group. She has published 13 peer-reviewed publications, 5 of which are in the area of oxidative stress and cardiovascular disease.

    Dessalegn B. Nemera, is a predoctoral fellow in the lab of EJM. He immigrated to the United States from Ethiopia eight years ago. Dessalegn completed both an associate degree, from Cincinnati State Community College, and a Bachelor of Science, from the University of Cincinnati, with honors. He is studying the propensity of oxidative DNA-protein cross-links to form.

    Mihalis I. Panayiotidis was born in Athens, Greece and received his PhD in Toxicology from the School of Pharmacy at the University of Colorado, USA. After completion of an NIEHS-IRTA postdoctoral fellowship, he followed with Assistant Professor positions at the Department of Nutrition and the School of Community Health Sciences at the University of North Carolina-Chapel Hill, USA and the University of Nevada-Reno, USA, respectively. Currenty, he has joined the Laboratory of Pathological Anatomy, University of Ioannina, Greece where he is an Assistant Professor of Molecular Pathology. His research encompasses the role of oxidative stress and natural products in cancer formation and prevention, respectively.

    Aglaia Pappa was born in Ioannina, Greece and received her PhD in Biological Chemistry & Pharmacology from the University of Ioannina, Greece. After completion of a postdoctoral training at the School of Pharmacy, University of Colorado, USA, she has joined the Department of Molecular Biology & Genetics, Democritus University of Thrace, Greece as an Assistant Professor of Molecular Physiology & Pharmacology. Her research encompasses the role of oxidative stress in human disease, including carcinogenesis.

    Sampath Parthasarathy obtained his PhD degree from the Indian Institute of Science, Bangalore, India in 1974. He spent one year at the Kyoto University, Japan as a postdoctoral fellow and subsequently joined the Duke University at Durham, NC. He then joined the Hormel Institute, University of Minnesota and became an Assistant Professor. From 1983–1993 Dr. Parthasarathy was a member of the faculty and reached the rank of professor at the University of California at San Diego. He developed the concept of oxidized LDL with his colleagues. In 1993, he was invited to become the Director of Research Division in the Department of Gynecology and Obstetrics at Emory University as the McCord-Cross professor. After serving 10 years at Emory, he joined Louisiana State University Health Science Center at New Orleans in November 2003 as Frank Lowe Professor of Graduate Studies and as Professor of Pathology. During 2006–2011, he served as the Klassen Chair in Cardiothoracic Surgery at the Ohio State University and was instrumental in developing a large animal model of heart failure. Currently, he is the Florida Hospital Chair in Cardiovascular Sciences and serves as Associate Director of Research at the Burnett School of Biomedical Sciences at the University of Central Florida in Orlando. Dr. Parthasarathy has published over 240 articles and has also written a book Modified Lipoproteins in the Pathogenesis of Atherosclerosis.

    Mark T. Quinn was born in San Jose, CA and received a PhD in Physiology and Pharmacology from the University of California at San Diego. Following postdoctoral training at The Scripps Research Institute, he joined the Department of Chemistry and Biochemistry at Montana State University. Subsequently, he moved to the Department of Microbiology and then to the Department of Immunology of Infectious Diseases, where he is currently a Professor and Department Head. His research is focused on understanding innate immunity, with specific focus on neutrophil NADPH oxidase structure and function and regulation of phagocytic leukocyte activation during inflammation.

    Annmarie Ramkissoon obtained her PhD in toxicology in 2011 from the University of Toronto, where she focused upon drug bioactivation and antioxidative responses in neurodegeneration. Dr. Ramkissoon received several honors including a national graduate student scholarship from the Canadian Institutes of Health Research (CIHR) and the Rx&D Health Research Foundation. She is currently a postdoctoral fellow in the Division of Oncology in the Cancer and Blood Diseases Institute at the Cincinnati Children's Hospital Medical Center.

    Imran Rehmani was born in St. Louis, Missouri. He obtained his Bachelors degree at the University of Mississippi in 2007. He researched at Georgia Tech and Georgia Health Sciences University before entering Georgia State University in 2010 under the advisement of Aimin Liu. He recently graduated with an MS in Chemistry. He will be joining Centers for Disease Control and Prevention as an ORISE research fellow.

    Arben Santo is a professor and chair of the Department of Pathology at VCOM of Virginia Tech Corporate Research Center. His research is centered on pathology of cardiovascular diseases and inflammatory disorders.

    Aaron M. Shapiro received his MSc degree in interdisciplinary studies and toxicology from the University of Northern British Columbia in 2008, and is currently a doctoral student in toxicology in the Department of Pharmaceutical Sciences at the University of Toronto, focusing upon the role of oxidative stress and DNA repair in neurodevelopmental deficits. Aaron has won several awards for his research, including a national Frederick Banting and Charles Best Graduate Scholarship from the CIHR.

    Rukhsana Sultana received her PhD in Life Sciences from the University of Hyderabad. After spending time as a postdoctoral scholar and research associate in the Butterfield laboratory, Dr. Sultana is now Research Assistant Professor of Biological Chemistry at the University of Kentucky. She has coauthored more than 100 refereed scientific papers, mostly on oxidative stress in Alzheimer disease.

    Murugesan Velayutham was born in Tamil Nadu, India, and received his PhD in Physical Chemistry (Magnetic Resonance Spectroscopy) from the Indian Institute of Technology Madras, Chennai, India. He did his postdoctoral training at North Carolina State University and Johns Hopkins University. Currently, he is a research scientist at the Davis Heart Lung Research Institute, The Ohio State University College of Medicine. His research interests have been focused on understanding the roles of free radicals/reactive oxygen species and nitric oxide in biological systems as well as measuring and mapping molecular oxygen levels and redox state in in vitro and in vivo systems using EPR spectroscopy/oximetry/imaging techniques. He is a cofounding member of the Asia-Pacific EPR/ESR Society and a member of The International EPR Society.

    Frederick A. Villamena was born in Manila, Philippines, and received his PhD in Physical Organic Chemistry from Georgetown University. Following as ORISE, CNRS, and NIH-NRSA postdoctoral fellow, he joined the Pharmacology Department of the Ohio State University, where he is currently an Associate Professor. His research encompasses design and synthesis of nitrone-based antioxidants and their application toward understanding the mechanisms of oxidative stress and cardiovascular therapeutics.

    Jianmin Wang is the president of Beijing Lab Solutions Pharmaceutical Inc. His research interest focuses on drug discovery and development.

    Peter G. Wells obtained his PharmD degree from the University of Minnesota in 1977, received postdoctoral research training in toxicology and clinical pharmacology in the Department of Pharmacology at Vanderbilt University from 1977 to 1980, and joined the University of Toronto Faculty of Pharmacy in 1980, where he is currently a professor in the Division of Biomolecular Sciences in the Faculty of Pharmacy, and cross-appointed to the Department of Pharmacology and Toxicology in the Faculty of Medicine. Dr. Wells' research has focused upon the toxicology of drugs that are bioactivated to a reactive intermediate, more recently in the areas of developmental toxicity, cancer, and neurodegeneration. He has received several honors for the research of his laboratory, most recently a Pfizer Research Career Award from the Association of Faculties of Pharmacy of Canada in 2011.

    Zhaohui Yang is currently an associate professor in Wuhan University with a doctoral degree in Medical Science from Wuhan University. He worked as a postdoctoral fellow in Dr. Sampath Parthasarthy's research group from 2010 to 2012.

    Hong Zhu is an assistant professor of physiology and pharmacology at VCOM of Virginia Tech Corporate Research Center. Dr. Zhu has authored over 50 peer-reviewed publications in the general areas of biochemistry, physiology, pharmacology, and toxicology. Her research currently funded by NIH is related to the inflammatory and oxidative basis of degenerative disorders and mechanistically based intervention.

    Jay L. Zweier was born in Baltimore, Maryland, and received his baccalaureate degrees in Physics and Mathematics from Brandeis University. After PhD training in Biophysics at the Albert Einstein College of Medicine, he pursued medical training at the University of Maryland, School of Medicine and received his MD in 1980. Subsequently, he completed his residency in internal medicine followed by his cardiology fellowship at Johns Hopkins University. In 1987, he joined the faculty of The Johns Hopkins University School of Medicine. In 1998, he was promoted to the rank of Professor and in 2000 was appointed as Chief of Cardiology Research, at the Johns Hopkins Bayview Campus. He was elected as a fellow in the American College of Cardiology in 1995 and the American Society of Clinical Investigation in 1994. In July of 2002, Dr. Zweier joined The Ohio State University College of Medicine as Director of the Davis Heart & Lung Research Institute and the John H. and Mildred C. Lumley Chair in Medicine. Dr. Zweier is currently Professor of Internal Medicine, Physiology, and Biochemistry, Director of the Center for Environmental and Smoking Induced Disease and the Ischemia and Metabolism Program of the Davis Heart & Lung Research Institute. He has published over 400 peer-reviewed manuscripts in the fields of cardiovascular research, free radical biology, and magnetic resonance.

    Contributors

    D. Allan Butterfield, University of Kentucky,

    Lexington, Kentucky

    Giovanna Cenini, University of Kentucky‚

    Lexington, Kentucky

    Yeong-Renn Chen, Northeast Ohio Medical University‚

    Rootstown, Ohio

    Joseph Darling, Syracuse University‚

    Syracuse, New York

    Sean S. Davies, Vanderbilt University‚

    Nashville, Tennessee

    Brian J. Day, National Jewish Health‚

    Denver, Colorado

    Grégory Durand, Université d′Avignon et des Pays de Vaucluse‚

    Avignon, France

    Susan Flynn, Syracuse University‚

    Syracuse, New York

    Rodrigo Franco, University of Nebraska-Lincoln‚

    Lincoln, Nebraska

    Aracely Garcia-Garcia, University of Nebraska-Lincoln‚

    Lincoln, Nebraska

    Alexandros G. Georgakilas, East Carolina University‚

    Greenville, North Carolina

    Neal S. Gould, Children's Hospital of Philadelphia‚

    Philadelphia, Pennsylvania

    Lilu Guo, Vanderbilt University‚

    Nashville, Tennessee

    James L. Hougland, Syracuse University‚

    Syracuse, New York

    Xueting Jiang, University of Central Florida‚

    Orlando, Florida

    Amy R. Jones, University of Cincinnati‚

    Cincinnati, Ohio

    Thomas B. Kryston, East Carolina University‚

    Greenville, North Carolina

    Yunbo Li, Edward Via Virginia College of Osteopathic Medicine‚

    Blacksburg, Virginia

    Dmitry Litvinov, University of Central Florida‚

    Orlando, Florida

    Aimin Liu, Georgia State University‚

    Atlanta, Georgia

    Fange Liu, Georgia State University‚

    Atlanta, Georgia

    Margaret M. Loniewska, University of Toronto‚

    Toronto, Ontario, Canada

    Edward J. Merino, University of Cincinnati‚

    Cincinnati, Ohio

    Chandrakala Aluganti Narasimhulu, University of Central Florida‚

    Orlando, Florida

    Dessalegn B. Nemera, University of Cincinnati‚

    Cincinnati, Ohio

    Mihalis I. Panayiotidis, University of Ioannina‚

    Ioannina, Greece

    Aglaia Pappa, Democritus University of Thrace‚

    Alexandroupolis, Greece

    Sampath Parthasarathy, University of Central Florida‚

    Orlando, Florida

    Mark T. Quinn, Montana State University‚

    Bozeman, Montana

    Annmarie Ramkissoon,

    Cincinnati Children's Hospital Medical Center‚

    Cincinnati, Ohio

    Imran Rehmani, Centers for Disease Control and Prevention‚

    Atlanta, Georgia

    Arben Santo, Edward Via Virginia College of Osteopathic Medicine‚

    Blacksburg, Virginia

    Aaron M. Shapiro, University of Toronto‚

    Toronto, Ontario, Canada

    Rukhsana Sultana, University of Kentucky‚

    Lexington, Kentucky

    Murugesan Velayutham, The Ohio State University

    Columbus, Ohio

    Frederick A. Villamena, The Ohio State University‚

    Columbus, Ohio

    Jianmin Wang, Beijing Labsolutions Pharmaceuticals‚

    Beijing, China

    Peter G. Wells, University of Toronto‚

    Toronto, Ontario, Canada

    Zhaohui Yang, Wuhan University, Hubei Province, China

    Hong Zhu, Edward Via Virginia College of Osteopathic Medicine‚

    Blacksburg, Virginia

    Jay L. Zweier, The Ohio State University‚

    Columbus, Ohio

    1

    Chemistry of Reactive Species

    Frederick A. Villamena

    1.1 Redox Chemistry

    Electron is an elementary subatomic particle that carries a negative charge. The ease of electron flow to and from atoms, ions or molecules defines the reactivity of a species. As a consequence, an atom, or in the case of molecules, a particular atom of a reactive species undergoes a change in its oxidation state or oxidation number. During reaction, oxidation and reduction can be broadly defined as decrease or increase in electron density on a particular atom, respectively. A more direct form of oxidation and reduction processes is the loss or gain of electrons on a particular atom, respectively, which is often referred to as electron transfer. Electron transfer can be a one- or two-electron process. One common example of a one-electron reduction process is the transfer of one electron to a molecule of oxygen (O2) resulting in the formation of a superoxide radical anion (O2•−) (Eq. 1.1). Further one-electron reduction of O2•− yields the peroxide anion (O2²−) (Eq. 1.2):

    (1.1) c1-math-0001

    (1.2) c1-math-0002

    Conversely, two-electron oxidation of metallic iron (Fe⁰) leads to the formation of Fe²+ (Eq. 1.3) and further one-electron oxidation of Fe²+ leads to the formation of Fe³+ (Eq. 1.4). Electrons in this case can be introduced electrochemically or through reaction with reducing or oxidizing agents:

    (1.3) c1-math-0003

    (1.4) c1-math-0004

    Another method by which oxidation state on a particular atom can be altered is through change in bond polarity. Electronegative atoms have the capability of attracting electrons (or electron density) toward itself. Listed below are the biologically relevant atoms according to their decreasing electronegativities (revised Pauling): F (3.98) > O (3.44) > Cl (3.16) > N (3.04) > Br (2.96) > S > (2.58) > C = Se (2.55) > H (2.20) > P (2.19). Therefore, changing the electronegativity (or electropositivity) of an atom attached to an atomic center of interest can result in the reversal of the polarization of the bond. By applying the whose-got-the-electron-rule will be beneficial in identifying atomic centers that underwent changes in their oxidation states. For example, based on the electronegativity listed above, one can examine the relative oxidation states of a carbon atom in a molecule (Fig. 1.1). Since carbon belongs to group 14 of the periodic table, the carbon atom has 4 valence electrons. When carbon is bonded to an atom that is less electronegative to it (e.g., hydrogen atom), the carbon atom tend to pull the electron density toward itself, making it electron-rich. The two electrons that it shares with each hydrogen atom are counted toward the number of electrons the carbon atom can claim. In the first example, methane has four hydrogen atoms attached to it. Since hydrogen is less electronegative than carbon, all eight shared electrons can be claimed by carbon, but since carbon is only entitled to four electrons by virtue of its valence electron, it has an excess of four electrons, making its oxidation state −4. However, when a carbon atom is covalently bound to a more electronegative atom (e.g., oxygen and chlorine), the spin density distribution around the carbon atom decreases and are polarized toward the more electronegative atoms. In this case, the electrons shared by carbon with a more electronegative atom are counted toward the more electronegative atom. In the case of formyl chloride, only the two electrons it shares with hydrogen can be counted toward the total number electrons the carbon atom can claim since the four electrons it shares with oxygen and the two electrons it shares with chlorine cannot be counted toward the carbon because these electrons are polarized toward the more electronegative atoms. Hence, the carbon becomes deficient in electron density, and by virtue of its four valence electrons, it can only claim two electrons from the hydrogen atom, therefore, the net oxidation state can be calculated to be +2. The increasing positivity of the carbon from methane to formyl chloride indicates oxidation of carbon and therefore, oxidation can now be broadly defined as (1) loss of electron; (2) loss of hydrogen atom; and (3) gain of oxygen or halogen atoms, while reduction can be defined as (1) gain of electron; (2) gain of hydrogen atom; and (3) loss of oxygen or halogen atoms.

    Figure 1.1 Oxidation states of the carbon atom calculated as number of valence electrons for the carbon atom (i.e., 4 e−) minus the number of electrons that carbon can claim in a molecule. Order of increasing electronegativity: H < C < O < Cl.

    c1-fig-0001

    1.2 Classification of Reactive Species

    Definition. Free radicals are integral part of many chemical and biological processes. They play a major role in determining the lifetime of air pollution in our atmosphere¹ and are widely exploited in the design of polymeric, conductive, or magnetic materials.² In biological systems, free radicals have been implicated in the development of various diseases.³ So what are free radicals? The word radical came from the Latin word radix meaning root. In the mid-1800s, chemists began to use the word radical to refer to a group of atoms. How the word radical had become a chemical terminology is not clear, but one could only speculate that these groups of atoms that make up a molecule was figuratively referred to as roots" or basic foundation of an entity. In the early 1900s, early literature referred to metallic atoms as basic radicals and nonmetallic ones as acid radicals, for example, in Mg(OH)2 or H2S, respectively. During this time, radicals are still referred to as group entities that are part of a compound but not until Gomberg had demonstrated during this same time that radicals can indeed exist by themselves as exemplified by his synthesis of the stable triphenylmethyl radical 2 from the reduction of triphenylchloromethane 1 by Zn (Eq. 1.5):⁴

    (1.5)

    c1-fig-5033

    In the late 1950s, the electron paramagnetic resonance spectrum of 2 had been obtained, further confirming the radical nature of trityl which can indeed be stable enough to exist by itself and be spectroscopically detected.⁵ Radical is defined in modern times as a finite chemical entity by its own that is capable of undergoing chemical reaction. Radicals carry an odd number of electrons in the form of an atom, neutral or ionic molecule. By virtue of Pauli's exclusion principle, the number of electrons occupying an atomic or molecular orbital is limited to two provided that they have different spin quantum number. This pairing of electron results in the formation of a chemical bond between atoms, existence of lone pair of electron or completion of the inner core nonbonding electrons. For radicals, electrons are typically on an open shell configuration in which the atomic or molecular orbitals are not completely filled with electrons, making them thermodynamically more energetic species than atoms or molecules with closed shell configuration or with filled orbitals. For example, the noble gases He, Ne, or Ar, with filled atomic orbitals, 1s² (He), 1s²2s²2px²2py²2pz² (Ne), 1s²2s²2p⁶3s²3px²3py²3pz² (Ar), are known to be inert, while the atomic H, N, or Cl with electron configurations of 1s¹ (H), 1s²2s²2px²2py¹2pz⁰ (N), and 1s²2s²2p⁶3s²3px²3py²3pz¹ (Cl) are known to be highly reactive and hence exist as diatomic molecules. Similarly, molecules with open shell molecular orbital configurations are more reactive than molecules with closed shell configuration. For example, hydroxyl radical has an open shell configuration of σpz² px²py¹ while the hydroxide anion has a closed shell configuration of σpz² px²py², making the former more reactive than the latter.

    1.2.1 Type of Orbitals

    Radicals can be classified according to the type of orbital (SOMO) that bears the unpaired electron as σ− or π−radicals. Radical stability is governed by the extent of electron delocalization within the atomic orbitals. In general, due to the restricted spin delocalization in the σ−radicals, these radicals are more reactive than the π−radicals. Examples of σ−radicals are H•, formyl-, vinyl-, or phenyl-radicals (Fig. 1.2).

    Figure 1.2 Hydrogen, formyl, and vinyl σ-radicals.

    c1-fig-0002

    Almost all of the radical-based reactive oxygen species (ROS) that will be discussed in this chapter fall under the π−type category but each will differ only on the extent of spin delocalization within the molecule. Examples of π−radicals with restricted spin delocalization are •CH3, •SH, and HO• and are relatively less stable than π−radicals with extended spin delocalization (e.g., HOO•, O2•−, and NO) (Fig. 1.3).

    Figure 1.3 Methyl, thiyl, hydroxyl, hydroperoxyl, superoxide, and nitric oxide as examples of π−radicals.

    c1-fig-0003

    1.2.2 Stability of Radicals

    Radicals can also be categorized according to their stability as stable, persistent, and unstable (or transient). Although the terms stable and persistent are often used interchangeably, free radical chemists agree that persistent radicals refer to the thermodynamic favorability of being monomeric as opposed to being dimeric as formed via radical–radical reaction in solution. Radical-based ROS are not persistent (or stable) making their detection in solution very difficult. ROS detection is commonly accomplished by detecting secondary products arising from their redox or addition reaction with a reagent as will be discussed in Section 1.5. Figure 1.4 shows examples of dimer formation from HO•, HO2•, TEMPO, and trityl, and their respective approximate dissociation enthalpies. Rates of ROS decomposition in solution, of course, depend on the type of substrates that are present in solution but lifetimes of these radicals vary in solution since even one of the most stable radicals such as the trityl radical for example is not stable in the presence of some oxido-reductants.

    Figure 1.4 Dissociation enthalpies (ΔH⁰ in kcal/mol) of various dimers showing nitroxide to be the most stable radical and the methyl radical being the least stable.

    c1-fig-0004

    Classification of reactive species is sometimes cumbersome since, for example, a number of molecules contain more than one atom whose oxidation states are altered during reaction. Nitric oxide (NO), for example, can react with hydroxyl radical (HO•) to form nitrous acid (HNO2), but in order to classify whether NO is a reactive nitrogen or oxygen species, one has to carefully examine the oxidation states of the relevant atoms of the reactants and the product (Fig. 1.5).

    Figure 1.5 Reaction of nitric oxide with hydroxyl radical to produce nitrous acid showing pertinent oxidation states of the atoms undergoing redox transformation.

    web_c1-fig-0005

    Using the whose-got-the-electron-rule mentioned earlier, one can assign the oxidation states for each of the species involved in the transformation. The nitrogen atom of NO underwent an oxidation since its oxidation state has increased from +2 to +3 in HNO2, while the oxygen of HO• (not of NO) underwent reduction (from −1 to −2). We can therefore classify NO as reactive nitrogen species (RNS) while HO• as ROS since it was the nitrogen atom of NO and the oxygen atom of HO• that underwent oxidation state modification after reaction. Figure 1.6 shows the various reactive oxygen, nitrogen, and sulfur species with their respective oxidation states.

    Figure 1.6 Reaction of nitric oxide with hydroxyl radical to produce nitrous acid showing pertinent oxidation states of the atoms undergoing redox transformation.

    c1-fig-0006

    1.2.3 ROS

    1.2.3.1 Oxygen Molecule (O2, Triplet Oxygen, Dioxygen)

    The electronic ground state of molecular oxygen is the triplet state, O2(X³Σg−). Dioxygen's molecular orbital O2(X³Σg−) has the two unpaired electrons occupying each of the two degenerate antibonding πg-orbitals and whose spin states are the same or are parallel with each other (Fig. 1.7).

    Figure 1.7 Molecular orbital diagram of dioxygen showing its biradical nature.

    c1-fig-0007

    Owing to dioxygen's biradical (open-shell) property, it exhibits a radical-type behavior in many chemical reactions. Elevated physiological concentrations of O2 (hyperoxia) have been shown to be toxic to cultured epithelial cells due to necrosis, while lethal concentrations of H2O2 and O2•− cause apoptosis, suggesting that the mechanism of O2 toxicity is distinct from other oxidants. However, in in vivo systems, apoptosis is predominantly the main mechanism of cell death in the lung upon breathing 99.9% O2.⁶

    Chlorinated aromatics have been widely used as biocides and as industrial raw materials, and they are ubiquitous as environmental pollutants. The toxicology of polychlorinated biphenyls (PCBs) have been shown to be due to the formation H2O2 and O2•− from one-electron oxidation or reduction by molecular oxygen of reactive hydroquinone and quinone products, respectively, via formation of semiquinone radicals (Eq. 1.6).⁷ Oxygenation of pentachlorophenol⁸ (PCP) also leads to the formation of superoxide via the same mechanisms (Eq. 1.7):

    (1.6)

    c1-fig-5001

    (1.7)

    c1-fig-5002

    Oxygen addition to 1,4-semiquinone radicals was observed to be more facile than their addition to 1,2-semiquinones with free energies of reaction of 7.4 and 10.3 kcal/mol, respectively (Eq. 1.8 and Eq. 1.9).⁹ The experimental rate constants for the reaction of O2 with 2,5-di-tert-butyl-1,4-semiquinone radicals were 2.4 × 10⁵ M−1 s−1and 2.0 × 10⁶ M−1 s−1 in acetonitrile and chlorobenzene, respectively, similar to that observed in aqueous media at pH 7. The formation of quinones was suggested to occur via a two-step mechanism in which O2 adds to the aromatic ring followed by an intramolecular H-atom transfer to the peroxyl moiety and concomitant release of HO2•. This reactivity of O2 to semiquinone to yield HO2• underlies the pro-oxidant activity of hydroquinones:¹⁰

    (1.8) c1-fig-5003

    (1.9) c1-fig-5004

    Perhaps one of the most important reactions of O2, although reversible in most cases, is its addition to carbon- or sulfur-centered radicals which is relevant in the propagation steps in lipid peroxidation processes or thiol oxidation, respectively. The reaction of dioxygen with lipid and thiyl radicals form peroxyl (LOO•) and thiol peroxyl (RSOO•) radicals, respectively, (Eq. 1.10 and Eq. 1.11):

    (1.10) c1-math-0010

    (1.11) c1-math-0011

    1.2.3.2 Superoxide Radical Anion (O2•−)

    Superoxide is the main precursor of the most highly oxidizing or reducing species in biological system. The one-electron reduction of triplet dioxygen forms O2•− and initiates oxidative cascade. The molecular orbital of O2•− shows one unpaired electron in the antibonding πg-orbital (Fig. 1.8) and is delocalized between the π* orbitals of the two oxygen atoms.

    Figure 1.8 Molecular orbital diagram of O2•−.

    c1-fig-0008

    Dismutation Reaction

    By virtue of superoxide's oxidation state, O2•− can either undergo oxidation or reduction to form dioxygen or hydrogen peroxide, respectively (Eq. 1.12),

    (1.12) c1-math-0012

    thereby allowing O2•− to dismutate to H2O2 and O2 according to Equation 1.13:

    (1.13) c1-math-0013

    The dismutation of two O2•− in the absence of proton is slow with k < 0.3 M−1 s−1 due to repulsive effects between the negative charges. However, in acidic medium, the rate O2•− dismutation significantly increases due to the formation of the neutral HO2• (Eq. 1.14 and Eq. 1.15) in which electron transfer between the radicals becomes more facile:

    (1.14)

    c1-math-0014

    (1.15)

    c1-math-0015

    The pKa of the conjugate acid of O2•− was determined to be 4.69, which indicates that O2•− is a poor base but O2•− has strong propensity to abstract proton from protic substrates. For example, O2•− addition to water results in the formation of HO2− and HO−, with an equilibrium constant equivalent to 0.9 × 10⁹.¹⁰ This indicates that O2•− can undergo proton abstraction from substrates to an extent equivalent to a conjugate base of an acid with a pKa of 24 (Eq. 1.16):¹⁰

    (1.16)

    c1-math-0016

    This ability of O2•− to act as strong base is due to its slow initial self-dismutation to O2 and peroxide (O2²−) that can drive the equilibrium further right to form the hydroperoxide, HO2−. Since the pKa of H2O2 is ∼11.75,¹¹ the basicity of HO2− can approach those of RS−.

    Dismutation has also been reported to be catalyzed by SOD mimetics, fullerene derivatives, nitroxides, and metal complexes. Superoxide dismutation should meet the following criteria: (1) no structural or chemical modification of the mimetic upon reaction with O2•−; (2) regeneration of O2; (3) production of H2O2; and (4) absence of paramagnetic primary by-products. Tris-malonyl-derivatives of fullerene (C60) have been shown to exhibit SOD mimetic properties with rate constants in the order of 10⁶ M−1 s−1 compared to dismutation rates imparted by SODs (i.e., ∼10⁹ M−1 s−1).¹² In vivo studies using SOD2–/– knockout mice indicate increased life span by 300% and show localization in the mitochondria functioning as MnSOD.¹³ Computational studies show that electron density around the malonyl groups is low, thereby making this region more susceptible to nucleophilic attack by O2•− via electrostatic effects.¹³ Osuna et al.¹⁴ suggested a dismutation mechanism by which O2•− interacts with the fullerene surface and is stabilized by a counter-cation and water molecules. An electron is transferred from O2•− to the fullerene-producing O2 and fullerene radical anion. Subsequent electron transfer from fullerene radical anion to another molecule of O2•− gives the fullerene–O2²− complex, and protonation of the peroxide by the malonic acid groups gives fullerene–H2O2, where H2O2 is released along with the regenerated fullerene (Fig. 1.9).

    Figure 1.9 SOD mimetic property of tris-malonyl-derivative of fullerene (C60).

    c1-fig-0009

    SOD exists in two major forms: as a Cu,ZnSOD that is primarily present in cytosol while MnSOD is located in the mitochondria. There is also an FeSOD that has chemical similarities with MnSOD such as being susceptible to deactivation at high pH and resistance to CN− inactivation. Over the past years, the synthesis of metal-complexes-based SOD mimetics involved the use of Ni(II),¹⁵ Cu(II),⁸ Mn(III),¹⁶ Mn(II),¹⁷ Fe(II), and Fe(III).¹⁸ The overall dismutation reaction of metal-SOD/SOD mimetic involves the following redox reaction (Fig. 1.10):

    Figure 1.10 SOD mimetic property of metal-complexes.

    c1-fig-0010

    Activation of O2•− by metal ions via the formation of metal-peroxo adduct (M(n+1)–O2²−):

    (1.17) c1-math-0017

    Formation of M(n+1)–O2²− can also be achieved through several pathways such as combination of M(n−1) and O2, M(n+1) and O2²−, or M(n), O2, and e-.¹⁹ Protonation of metal-peroxo adducts can proceed via two different pathways, depending on the metabolizing enzyme involved. For example with SOD, release of H2O2 occurs with the metal oxidation state unchanged, while in the case of catalase, peroxidases, and cytochrome P450, O–O bond cleavage occurs with the formation of a high valent metal oxo-species (Fig. 1.11).¹⁹

    Figure 1.11 Activation of O2•− by metal ions.

    c1-fig-0011

    Electrostatic effect plays an important role in enhancing SOD mimetic activity by introducing positively charged moieties.¹³ For example, studies show that the presence of guanidinium derivative of an imidazolate-bridged dinuclear copper moiety enhances SOD activity by 30% compared to when the guanidinium is lacking.⁸ Also, increasing the number of positive charge on the ligand and its proximity around the metal center give higher SOD mimetic activity by several-fold compared to the singly-charged analogue.²⁰

    Nitroxide or aminoxyl-type compounds have also been shown to impart SOD-mimetic properties with catalytic rates that are in the order of 10⁵ M−1 s−1 at pH 7.²¹,²² The mechanism was suggested to be catalyzed by formation of an oxoammonium intermediate which in turn converts O2•− to molecular O2 according to the following reactions shown in Equation 1.18:

    (1.18) c1-fig-5005

    Nucleophilic Substitution Reaction

    Nucleophilic substitution reaction has also been observed for O2•− with alkyl halides and tosylates in DMSO leading to the formation of alkylperoxy radicals then to peroxy anions via one-electron reduction (Eq. 1.19):²³,²⁴

    (1.19) c1-fig-5006

    Addition Reactions

    Reaction of O2•− with tyrosyl radical generated from sperm whale myoglobin was investigated, and results show that O2•− prevented myoglobin dimer formation as a mechanism for repairing protein tyrosyl radical.²⁵ Moroever, an addition product with O2•− at Tyr151 was identified using mass spectrometry as a more preferred reaction compared to dimer formation, and this addition reaction was enhanced in the presence of exogenously added lysine.²⁵ This study further supports previous observations on the formation of tyrosyl hydroperoxide generated from O2•− and tyrosyl radical as enhanced by the presence of H-bond donors.²⁶,²⁷ Addition of O2•− and tyrosyl radical at the ortho-position is the most thermodynamically preferred addition product (Eq. 1.20).²⁷ In aprotic solvents, reaction of O2•− with α-dicarbonyl carbon involves nucleophilic addition to the carbonyl carbon followed by dioxetane formation via addition of the terminal O to the other carbonyl carbon. Reductive cleavage by the second O2•− yields benzoate and oxygen:²⁸

    (1.20) c1-fig-5007

    Proton-Radical Transfer

    By virtue of the pKa of the conjugate acid of O2•− of 4.8, O2•− is considered a weak base. However, proton and radical transfer pathways have been proposed for the antioxidant property of monophenols and polyphenols, respectively, against O2•−.²⁹ For monophenols, electrogenerated O2•− acts as weak base and the phenolic compound (PhOH) acting as Bronsted acid according to Equation 1.21 in which the formation of phenoxide PhO− and HO2• though thermodynamically unfavorable, can be driven to completion by the subsequent electron transfer reaction between HO2• and O2•−, to form HO2− (a very strong base) and O2 in which the former can further abstract proton from phenol to form the phenoxide (PhO−) according to Equation 1.21:

    (1.21) c1-fig-5008

    Polyphenols, however, undergo radical (or H-atom) transfer reaction with O2•− to form the phenoxyl radical (PhO•) and HO2−; similarly with monophenols, HO2− can also abstract proton from PhOH to form phenoxide (PhO−). The fate of PhO• was shown to form nonradical products via dimerization or oligomerization, or semiquinone formation. This difference in the pathway between monophenols and polyphenol decomposition with O2•− can be due to the stabilization of the radical in polyphenols via resonance as evidenced by the higher reactivity of polyphenols containing o-diphenol rings with O2•− according to Equation 1.22:

    (1.22)

    c1-fig-5009

    Reactivity of O2•− was also reported with cardiovascular drugs such as 1,4-dihydropyridine analogues of nifedipine to form pyridine (Eq. 1.23).³⁰ The proposed mechanism involves a two-electron oxidation of DHP to form the pyridine and hydrogen peroxide:

    (1.23) c1-fig-5010

    Reaction of O2•− with thiols were found to be highest for acidic thiols with approximated rate constants in the orders of 10–10³ M−1 s−1.³¹ Oxygen uptake shows concomitant formation of H2O2 in some thiols such as peniciallamine and cysteine via a complex radical chain reaction with the formation of oxidized thiols (Fig. 1.12), but this mechanism was not observed for GSH, DTT, cysteamine, and N-acetylcysteine. This difference in mechanisms among thiols for H2O2 formation is not clear but was proposed to be due to the nature of the thiol oxidation products formed during the propagation step and of the termination products; thus, stoichiometry could play an important factor in product formation.

    Figure 1.12 Various pathways for the reaction of O2•− with thiols.

    c1-fig-0012

    Computational studies show that reaction of O2•− with MeSH to give MeSO• and HO− (Pathway 1) as the most favorable mechanism with ΔGaq of −170.5 kcal/mol compared to the formation of MeS• and HO2− (Pathway 2) with endoergic ΔGaq of 68.2 kcal/mol.³² However, the free energies for the formation of MeSO− + HO• and MeS− + HO2• are ΔGaq = −52.5 and 32.2 kcal/mol, respectively. Therefore, the proposed Pathway 2 is unfavorable unless the reacting species is HO2• to give MeS• and H2O2 with ΔGaq = −11.3 kcal/mol but formation of MeSO• and H2O from HO2− and MeSH is far more favorable with ΔGaq = −278.7 kcal/mol. As previously suggested,³² the reactivity of other oxidants such as H2O2 and HO• to thiols should also be considered and may involve a more complex mechanistic pathway.

    Reaction with Iron–Sulfur [Fe–S] Cluster

    Iron–sulfur clusters are important cofactors in biological system. They serve as active sites in various metalloproteins catalyzing electron-transfer reactions and plays a role in other biological functions such as O2 sensing ability (e.g., by the transcription factor FNR).³³ The ubiquitousness of [Fe–S] clusters in enzymatic systems such as in Complex II and III of the mitochondrial electron transport chain, ferredoxins, NADH dehydrogenase, nitrogenase, or hydro-lyases underlies their susceptibility for inactivation by ROS specifically by O2•− through formation of unstable oxidation state of the [Fe–S] cluster and their subsequent degradation (Fig. 1.13). For example, hydro-lyase enzymes such as dihydroxy-acid dehydratase, fumarase A and B and aconitase can be inactivated by O2•− with a second-order rate constant of 10⁶–10⁷ M−1 s−1 while the rate of their inactivation by O2 is orders of magnitude lower (10² M−1 s−1).³⁴ This difference in the rates of inactivation of O2•− versus O2 can be accounted to the favorability of the initial steps in the oxidation of a [4Fe-4S]²+ by O2•− and O2 with ΔG of −10.1 kcal/mol and 17.6 kcal/mol, respectively.³⁴ However, these initial steps only represent formation of Fe²+, H2O2, or O2•− and can further undergo redox reactions to form H2O as end product. The overall free energies of oxidation of [4Fe-4S]²+ by O2•− and O2 leading to the formation of the most stable product (H2O) and Fe³+ are comparable with ΔG of −27.1 kcal/mol and −23.5 kcal/mol, respectively.

    Figure 1.13 Free energies (in kcal/mol) of the reaction of O2•− and O2 with [4Fe-4S]²+ cluster.

    c1-fig-0013

    1.2.3.3 Hydroperoxyl Radical (HO2•)

    Protonation of O2•− leads to the formation of HO2• whose concentration in biological pH exists a hundred times smaller than that of O2•−; however, the presence of small equilibrium concentration of HO2• (pKa = 4.8) can contribute to the O2•− instability in neutral pH due to dismutation reaction shown in Equation 1.14. In acidosis condition, the reactivity of HO2• is expected to be more relevant than O2•−. Electrochemical reduction of O2 in the presence of strong or weak acids such as HClO4 or phenol, respectively, generates HO2•.³⁵ Hydroperoxyl radical is a stronger oxidizer than O2•− with Eo′ = 1.06 and 0.94 V, respectively, and due to its neutral charge, it is capable of penetrating the lipid bilayer and hence, it has been suggested that HO2• is capable of H-atom abstraction from PUFAs or from the lipids present in low-density lipoproteins. Cheng and Li³⁶ argued against the role of HO2• in LPO initiation since the concentration of HO2• at physiological pH is less than 1% of the generated O2•− and that SOD have little effect on peroxidation in liposomal or microsomal systems. However, it has been demonstrated that LOOH is more likely the preferred species for HO2• attack and not the LPO initiation process. H-atom abstraction from peroxyl-OOH and not from the alkyl C–H backbone is the preferred mechanism of HO2• reactivity, and therefore, HO2• is more important than O2•− in initiating LOOH-dependent LPO, but not as the H-abstraction initiator in LPO.³⁶

    Relevant to the antioxidant activity of catechols or hydroquinones (QH2), the reactivity of HO2• with QH2 involves H-atom transfer reaction to form semiquinone radical and H2O2 with a rate constant of 4.7 × 10⁴ M−1 s−1 for 1,2-dihydroquinone (Eq. 1.24):³⁷

    (1.24) c1-fig-5011

    1.2.3.4 Hydrogen Peroxide (H2O2)

    Hydrogen peroxide is perhaps one of the most ubiquitous ROS present in biological systems due to its relative stability with an oxidation potential of 1.8 V compared to other ROS such as O2•−, HO2•, or HO•. Hydrogen peroxide is the protonated form of the two-electron reduction product of molecular oxygen and is a nonradical ROS with all the antibonding orbitals occupied by paired electrons (Fig. 1.14). Hydrogen peroxide undergoes highly exoergic disproportionation reaction to form two equivalents of water and one equivalent of oxygen where the rate of disproportionation is temperature dependent.

    Figure 1.14 Molecular orbital diagram of H2O2.

    c1-fig-0014

    Perhaps the most common reaction of H2O2 is its metal-catalyzed reaction to produce HO• and HO2• (the Fenton chemistry) as proposed by Haber and Weiss (Eq. 1.25, Eq. 1.26, Eq. 1.27, Eq.1.28, Eq.1.29, Eq.1.30, Eq. 1.31, and 1.32).³⁸ Perez-Benito³⁹ proposed that this reaction can undergo propagation in which the HO• can further react with H2O2 to produce HO2• according to Equation 1.26. Depending on the pH, the equilibrium concentrations of HO2• and O2•− can vary (Eq. 1.27), and it has been suggested³⁹ that HO2• and O2•− are involved in the reduction and oxidation of Fe³+ (Eq. 1.28) and Fe²+ (Eq. 1.29), respectively. Iron (III) reaction with H2O2 can also lead to HO• production in acidic pH via formation of FeOOH²+ complex and its subsequent decomposition to Fe²+ and HO2• (Eq. 1.30 and Eq. 1.31) in which the formed Fe²+ can propagate the cycle to produce HO• as shown in Equation 1.25, Equation 1.26, Equation 1.27, Equation 1.28, and Equation 1.29:

    (1.25) c1-math-0025

    (1.26) c1-math-0026

    (1.27) c1-math-0027

    (1.28) c1-math-0028

    (1.29) c1-math-0029

    (1.30) c1-math-0030

    (1.31) c1-math-0031

    Shown in Figure 1.15 is the metal-independent generation of HO• from H2O2, which was proposed to be formed from tetrachlo-bezoquinones (TCBQ)⁸ through nucleophilic substitution reaction forming the hydroperoxyl-TCNQ and O–O homolytic cleavage to yield HO• and TCBQ-O•. Subsequent disproportionation TCBQ-O• yields TCBQ-O−, which can further react with excess H2O2 to produce HO•.

    Figure 1.15 Metal-independent generation of HO• from H2O2.

    c1-fig-0015

    Hydrogen peroxide oxidation of anions is not favorable. For example, oxidation of Cl− to HOCl by H2O2 is highly endoergic with ∼30 kcal/mol. However, myeloperoxidase-mediated oxidation of Cl− in the presence of H2O2 gave rate constants that are dependent on the Cl− concentration. It was proposed that Cl− reacts with MPO-I (an active intermediate formed from the reaction of MPO with excess H2O2) to form the chlorinating intermediate MPO-I–Cl−. The rate-limiting step is [Cl−] dependent; that is, at low [Cl−], k2 is the rate-limiting step with k2 = 2.2 × 10⁶ M−1 s−1 and k3 = 5.2 × 10⁴ s−1 (Eq. 1.32):⁴⁰

    (1.32) c1-math-0032

    In the absence of ionic substrates, myeloperoxidase has been reported to degrade H2O2 to oxygen and water thereby imparting a catalase activity.⁴¹ Kinetic analysis show that there is 1 mol of oxygen produced per 2 mol of H2O2 consumed with a rate constant of ~ 2 × 10⁶ M−1 s−1 which is an order of magnitude slower than the rate constant observed for catalase of 3.5 × 10⁷ M−1 s−1. Oxidation of nitrite to nitrate by H2O2 in the presence of catalase has been reported.⁴² In the absence of catalase, nitrite reacts with H2O2 to form peroxynitrite.⁴³ Hydroxylation and nitration of tyrosine and salicylic acid by H2O2 in the presence of nitrite occur between the pHs of 2–4 and 5–6, respectively, as mediated by peroxynitrite formation.⁴⁴

    Four major detoxification pathways for H2O2 operate intracellularly: (1) catalase; (2) gluthathione peroxidase; (3) peroxiredoxin enzymes; and (4) nonenzymatic mean via oxidation of protein thiol residues.⁴⁵ These pathways will be discussed in detail in the succeeding chapters. Probably one of the most important reactions in biological systems is the reaction of H2O2 with thiols. The cellular signaling property H2O2 is mainly dependent on the oxidation of intracellular protein thiols in which majority of these reactions form protein disulfides as opposed to S-glutathiolation.⁴⁵ The H2O2 reaction with thiols is free radical mediated and the rate is dependent on the pKa of the thiol in which the thiolate (RS−) is the reacting species to form the sulfenic acid (RSOH) intermediate according to Equation 1.33.³¹ The reported rate constant for the reaction of H2O2 with thiolates range from 18–26 M−1 s−1 which is relatively slow compared to the reaction of O2•− with thiols (>10⁵ M−1 s−1).³¹ Catalysis of RSSR formation with Cu(II) from peroxides has also been reported:⁴⁶

    (1.33) c1-math-0033

    1.2.3.5 Hydroxyl Radical (HO•)

    Hydroxyl radical originates from the three-electron reduction of oxygen. Among all the ROS, HO• perhaps is the most reactive and short-lived. Aside from the HO•'s significant role in controlling atmospheric chemistry, it plays a direct role in the initiation of oxidative damage to macromolecules in biological systems. Unlike O2•− and H2O2 whose reactions are limited due to their lower oxidizing ability, HO• can practically react with almost every organic molecules via H-atom abstraction, electrophilic addition, or radical–radical reactions, to name a few. The standard reduction potential for HO•aq/HO−aq couple was determined to be 1.77 V in neutral solution.⁴⁷ The half-life of HO• is ∼10−9 s compared to ∼10−5 s and ∼60 s for O2•− and H2O2, respectively.

    Reactivity with ROS/RNS. Radical–radical reaction of HO• proceeds at diffusion-controlled rate. For example, at neutral pH, reaction of HO• with various ROS and non-ROS radicals ranges between ∼10⁹ and 10¹⁰ M−1 s−1 (Eq. 1.34). The reactions are characteristic of addition of the hydroxyl-O to the heteroatoms. In the case of HO• reaction to O2•− and HO2•, their oxidation via electron transfer reactions to form O2 was observed (Eq. 1.35):

    (1.34) c1-math-0034

    (1.35) c1-math-0035

    Theoretical studies show that hydrogen bonding between HO• and H2O2 forms a five-membered ring structure with two distorted hydrogen bonds with a binding energy of ∼4 kcal/mol.⁴⁸ This HO•–H2O2 interaction leads to H-atom abstraction to yield O2•−. In pyridine, H2O2 reaction with HO• has a relatively slower rate of 3 × 10⁷ M−1 s−1 compared to most of HO• reactions.⁴⁹

    Reactivity with ions. Reaction of HO• to anions leads to a one-electron oxidation of the anion. It has been suggested that simple electron transfer mechanism from the anion to the HO• is not likely the mechanism due to the large energy associated with the formation of the hydrated hydroxide ion.⁵⁰ Instead, an intermediate HOX•− adduct is initially formed (Eq. 1.36). Reaction of HO• to cations can also result in an increase in the oxidation state of the ion, but unlike its reaction with anions, the reaction occurs at a much slower rate constants that is no more than ∼3 × 10⁸ M−1 s−1/s via H-atom abstraction from the metal-coordinated water (Eq. 1.37)⁵⁰:

    (1.36)

    c1-math-0036

    (1.37) c1-math-0037

    Modes of reaction with organic molecules. There are two main mechanisms of HO• reaction with organic compounds, that is, H-atom abstraction and addition reaction. With protic compounds such as alcohols, reaction of HO• proceeds via H-atom abstraction from C–H bond and not from the O–H to form water and the radical species. The general reaction for HO• with alcohol is HO• + RH → R• + H2O, and not HO• + ROH→ RO• + H2O. For example, ascorbate/ascorbic acid (AH-/AH2) react with HO• to form ascorbate radical anion (A•− ) and ascorbyl radical (HA•) with rate constants of 1.1 × 10¹⁰ M−1 s−1 (pH = 7) and 1.2 × 10¹⁰ M−1 s−1 (pH = 1), respectively.⁵⁰ EPR studies revealed formation of a C-centered radical.⁵¹ Reaction of HO• with aliphatic alcohols such as methanol and ethanol gave rate constants of 9.0 × 10⁸ M−1 s−1 and 2.2 × 10⁹ M−1 s−1, respectively, using pulse radiolysis.⁵² Preference to abstract H atom at the alpha position (i.e., the H attached to the C atom that is also attached to the OH group) was theoretically demonstrated and was found to be both kinetically and thermodynamically favorable. For example, the relative energies of H-atom abstraction as calculated at the CCSD(T) level of theory are as follows: α-H = −25.79 kcal/mol > β-H = −16.26 kcal/mol > OH = −15.67 kcal/mol.⁵³

    c1-fig-5012

    Reaction of HO• with deoxyribose forms a C-centered radical which further decomposes to form malonaldehyde (MDA) (Fig. 1.16).⁵⁴ MDA is a toxic by-product of polyunsaturated lipid degradation.⁵⁵,⁵⁶ Increase dose of HO• results in increase MDA-like products,⁵⁴ therefore, production of MDA in biological systems has become a popular biomarker of oxidative stress using thiobarbuturic acid (TBARS) via MDA electrophilic addition reaction to form an UV detectable adduct, TBARS-MDA. Radiolysis of

    d

    -glucose undergoes H-atom abstraction at the C-6 position and rearrangement leads to the initial elimination of two water molecules. Fragmentation yields MDA upon protonation and a dihydroxy-aldehyde radical species which can further undergo dehydration to form another molecule of MDA.⁵⁷

    Figure 1.16 Malonaldehdye (MDA) formation from the reaction of hydroxyl radical to deoxyribose.

    c1-fig-0016

    Reaction of HO• to ketones and aldehydes also gave preference to H-atom abstraction. Rate constants for H-atom abstraction in aqueous phase were faster 2.4–2.8 × 10⁹ M−1 s–1 for acetaldehyde and propionaldehyde, compared to acetone with k = 3.5 × 10⁷ M−1 s−1.⁵⁸ Computational studies show that for ketones with at least an ethyl group attached to the carbonyl carbon, the preference for H-atom abstraction is at the beta-position rather than the alpha position due to the presence of strong H-bond interaction forming 7-member ring transition state structure (Fig. 1.17)⁵⁹ In aldehydes, abstraction of the aldehydic-H was shown to be the most favored according to the equation, RHC = O + HO•• → [RC = O]• + H2O.⁶⁰

    Figure 1.17 Transition state H-bonding interaction of hydroxyl radical to carbonyl leading to H-atom abstraction at the beta position.

    c1-fig-0017

    Reaction of HO• to carboxylic acids is also that of H-atom abstraction of the acidic-H and alpha-H. There are two possible reactions in acetic acid/acetate system. One that involves H-atom abstraction from C–H and the other from OH according to Equation 1.38 and Equation 1.39, respectively:

    (1.38) c1-math-0038

    (1.39) c1-math-0039

    Rate constants for these reactions show that H-atom abstraction from C–H bond is 4× faster than abstraction from O–H in aqueous solution.⁶¹ The same trend in the relative reactivities of HO• with various acids and their respective conjugate base had been observed.⁶¹

    The reaction of HO• with alkenes is relevant in the initiation of lipid peroxidation processes and will be discussed in detail in the succeeding chapter. It has been demonstrated that increasing alkyl substitution on the C=C bond enhances its reaction rate with HO• by two orders of magnitude.⁶² In the gas phase, initial reaction of HO• to alkenes forms the HO-alkene adduct which in the presence of O2 gives the (β-hydroxylalkyl)peroxy radical. Further reaction with NO yields the β-hydroxyalkoxy radical and NO2 according to Fig. 1.18.⁶³

    Figure 1.18 Addition reaction of hydroxyl radical to alkenes and subsequent reaction of O2 and NO with the formed HO-alkene adduct.

    c1-fig-0018

    Reaction of HO• with aromatic hydrocarbons mainly proceeds via addition reaction. Laser flash photolytic study in acetonitrile gave rate constants ranging from 1.2–7.9 × 10⁸ M−1 s−1 for one-ringed aromatic hydrocarbons compared to 1.8–5.2 × 10⁹ M−1 s−1 for naphthalenic systems.⁶⁴ Experimental and computational studies indicate that the electrophilic nature of HO• addition was supported by the higher rate of HO• addition reaction in aqueous solution compare to acetonitrile by a factor of 65. The stabilized aromatic ring-OH complex in the transition state has the aromatic unit and assumes a radical cation-like form and that the HO* like a hydroxide anion. This can have implication in the HO• reactivity with DNA bases

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