High Resolution EPR (eBook)
XXV, 666 Seiten
Springer New York (Verlag)
978-0-387-84856-3 (ISBN)
Metalloproteins comprise approximately 30% of all known proteins, and are involved in a variety of biologically important processes, including oxygen transport, biosynthesis, electron transfer, biodegradation, drug metabolism, proteolysis, and hydrolysis of amides and esters, environmental sulfur and nitrogen cycles, and disease mechanisms. EPR spectroscopy has an important role in not only the geometric structural characterization of the redox cofactors in metalloproteins but also their electronic structure, as this is crucial for their reactivity. The advent of x-ray crystallographic snapshots of the active site redox cofactors in metalloenzymes in conjunction with high-resolution EPR spectroscopy has provided detailed structural insights into their catalytic mechanisms.
This volume was conceived in 2005 at the Rocky Mountain Conference on Analytical Chemistry (EPR Symposium) to highlight the importance of high-resolution EPR spectroscopy to the structural (geometric and electronic) characterization of redox active cofactors in metalloproteins. We have been fortunate to have enlisted internationally recognized experts in this joint venture to provide the scientific community with an overview of high-resolution EPR and its application to metals in biology. This volume, High-Resolution EPR: Applications to Metalloenzymes and Metals in Medicine, covers high-resolution EPR methods, iron proteins, nickel and copper enzymes, and metals in medicine. An eloquent synopsis of each chapter is provided by John Pilbrow in the Introduction. A second volume, Metals in Biology: Applications of High-Resolution EPR to Metalloenzymes, will appear later this year covering the complement of other metalloproteins.
One of the pioneers in the development of pulsed EPR and its application to metalloproteins was Arthur Schweiger, whose contribution we include in this volume. Unfortunately, he passed away suddenly during the preparation of this volume. The editors and coauthors are extremely honored to dedicate this volume to the memory of Arthur Schweiger in recognition of his technical advances and insights into pulsed EPR and its application to metalloproteins. Arthur was extremely humble and treated everyone with equal respect. He was a gifted educator with an ability to explain complex phenomena in terms of simple intuitive pictures, had a delightful personality, and continues to be sadly missed by the community.
It is an honor for the editors to facilitate the dissemination of these excellent contributions to the scientific community. Suggestions for future volumes are always appreciated.
Prof. Graeme Hanson, located in the Centre for Magnetic Resonance at the University of Queensland, has applied a unique synergistic approach involving both theoretical and experimental aspects of multifrequency continuous wave and pulsed EPR spectroscopy to structurally (geometric and electronic) characterise the metal binding sites in metalloenzymes and transition metal ion complexes. The development and commercialisation of the XSophe-Sophe-XeprView (CW EPR) and Molecular Sophe(CW EPR, Pulsed EPR and ENDOR) computer simulation software suites has been crucial in the characterisation of these biological inorganic systems.
Dr. Lawrence J. Berliner is currently at the Department of Chemistry and Biochemistry, University of Denver, where he was Professor and Chair for the past 8 years. He retired from The Ohio State University, where he spent a 32-year career in the area of biological magnetic resonance (EPR and NMR). He has been recognized by the International EPR Society with the Silver Medal for Biology/Medicine in 2000. He also received the Lifetime Achievement Award in Biological EPR Spectroscopy at EPR-2005. He is the Series Editor for Biological Magnetic Resonance, which he launched in 1979.
Metalloproteins comprise approximately 30% of all known proteins, and are involved in a variety of biologically important processes, including oxygen transport, biosynthesis, electron transfer, biodegradation, drug metabolism, proteolysis, and hydrolysis of amides and esters, environmental sulfur and nitrogen cycles, and disease mechanisms. EPR spectroscopy has an important role in not only the geometric structural characterization of the redox cofactors in metalloproteins but also their electronic structure, as this is crucial for their reactivity. The advent of x-ray crystallographic snapshots of the active site redox cofatcors in metalloenzymes in conjunction with high-resolution EPR spectroscopy has provided detailed structural insights into their catalytic mechanisms.This volume was conceived in 2005 at the Rocky Mountain Conference on Analytical Chemistry (EPR Symposium) to highlight the importance of highresolution EPR spectroscopy to the structural (geometric and electronic) characterization of redox active cofactors in metalloproteins. We have been fortunate to have enlisted internationally recognized experts in this joint venture to provide the scientific community with an overview of high-resolution EPR and its application to metals in biology. This volume, High-Resolution EPR: Applications to Metalloenzymes and Metals in Medicine, covers high-resolution EPR methods, iron proteins, nickel and copper enzymes, and metals in medicine. An eloquent synopsis of each chapter is provided by John Pilbrow in the Introduction which follows. A second volume, Metals in Biology: Applications of High-Resolution EPR to Metalloenzymes, will appear later this year covering the complement of other metalloproteins.One of the pioneers in the development of pulsed EPR and its application to metalloproteins was Arthur Schweiger, whose contribution we include in this volume. Unfortunately, he passed away suddenly during the preparation of this volume. The editors and coauthors are extremely honored to dedicate this volume to the memory of Arthur Schweiger in recognition of his technical advances and insights into pulsed EPR and its application to metalloproteins. Arthur was extremely humble and treated everyone with equal respect. He was a gifted educator with an ability to explain complex phenomena in terms of simple intuitive pictures, had a delightful personality, and continues to be sadly missed by the community.It is an honor for the editors to facilitate the dissemination of these excellent contributions to the scientific community. Suggestions for future volumes are always appreciated.
Prof. Graeme Hanson, located in the Centre for Magnetic Resonance at the University of Queensland, has applied a unique synergistic approach involving both theoretical and experimental aspects of multifrequency continuous wave and pulsed EPR spectroscopy to structurally (geometric and electronic) characterise the metal binding sites in metalloenzymes and transition metal ion complexes. The development and commercialisation of the XSophe-Sophe-XeprView (CW EPR) and Molecular Sophe(CW EPR, Pulsed EPR and ENDOR) computer simulation software suites has been crucial in the characterisation of these biological inorganic systems. Dr. Lawrence J. Berliner is currently at the Department of Chemistry and Biochemistry, University of Denver, where he was Professor and Chair for the past 8 years. He retired from The Ohio State University, where he spent a 32-year career in the area of biological magnetic resonance (EPR and NMR). He has been recognized by the International EPR Society with the Silver Medal for Biology/Medicine in 2000. He also received the Lifetime Achievement Award in Biological EPR Spectroscopy at EPR-2005. He is the Series Editor for Biological Magnetic Resonance, which he launched in 1979.
CONTRIBUTORS 6
PREFACE 11
CONTENTS 13
LIST OF COLOR FIGURES 22
ABOUT THE EDITORS 23
INTRODUCTION 24
HIGH-RESOLUTION EPR METHODS 34
ADVANCED PULSE EPR METHODS FOR THE CHARACTERIZATION OF METALLOPROTEINS 35
PROBING STRUCTURAL AND ELECTRONIC PARAMETERS IN RANDOMLY ORIENTED METALLOPROTEINS BY ORIENTATION-SELECTIVE ENDOR SPECTROSCOPY 84
MOLECULAR SOPHE: AN INTEGRATED APPROACH TO THE STRUCTURAL CHARACTERIZATION OF METALLOPROTEINS: THE NEXT GENERATION OF COMPUTER SIMULATION SOFTWARE 125
SPIN-HAMILTONIAN PARAMETERS FROM FIRST PRINCIPLE CALCULATIONS:THEORY AND APPLICATION 194
IRON PROTEINS 249
EPR OF MONONUCLEAR NON-HEME IRON PROTEINS 250
BINUCLEAR NON-HEME IRON ENZYMES 286
PROBING THE STRUCTURE–FUNCTION RELATIONSHIP OF HEME PROTEINS USING MULTIFREQUENCY PULSE EPR TECHNIQUES 413
EPR STUDIES OF THE CHEMICAL DYNAMICS OF NO AND HEMOGLOBIN INTERACTIONS 434
NICKEL AND COPPER ENZYMES 454
EPR INVESTIGATION OF [NIFE] HYDROGENASES 455
UNIQUE SPECTROSCOPIC FEATURES AND ELECTRONIC STRUCTURES OF COPPER PROTEINS: RELATION TO REACTIVITY 485
METALS IN MEDICINE 519
INSULIN-ENHANCING VANADIUM PHARMACEUTICALS: THE ROLE OF ELECTRON PARAMAGNETIC RESONANCE METHODS IN THE EVALUATION OF ANTIDIABETIC POTENTIAL 520
CHROMIUM IN CANCER AND DIETARY SUPPLEMENTS 563
HIGH-FREQUENCY EPR AND ENDOR CHARACTERIZATION OF MRI CONTRAST AGENTS 592
CONTENTS OF PREVIOUS VOLUMES 633
INDEX 660
Erscheint lt. Verlag | 19.6.2009 |
---|---|
Reihe/Serie | Biological Magnetic Resonance | Biological Magnetic Resonance |
Zusatzinfo | XXV, 666 p. |
Verlagsort | New York |
Sprache | englisch |
Themenwelt | Medizin / Pharmazie ► Physiotherapie / Ergotherapie ► Orthopädie |
Medizin / Pharmazie ► Studium | |
Technik ► Bauwesen | |
Technik ► Maschinenbau | |
Technik ► Medizintechnik | |
Schlagworte | Chemistry • Dynamics • Magnetic Resonance • Medicine • proteins • spectroscopy • X-Ray |
ISBN-10 | 0-387-84856-8 / 0387848568 |
ISBN-13 | 978-0-387-84856-3 / 9780387848563 |
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