Protein NMR Spectroscopy: Practical Techniques and Applications
Nuclear Magnetic Resonance (NMR) spectroscopy, a physical phenomenon based upon the magnetic properties of certain atomic nuclei, has found a wide range of applications in life sciences over recent decades. This up-to-date volume covers NMR techniques and their application to proteins, with a focus on practical details. Providing newcomers to NMR with practical guidance to carry out successful experiments with proteins and analyze the resulting spectra, those familiar with the chemical applications of NMR will also find it useful in understanding the special requirements of protein NMR.

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Protein NMR Spectroscopy: Practical Techniques and Applications
Nuclear Magnetic Resonance (NMR) spectroscopy, a physical phenomenon based upon the magnetic properties of certain atomic nuclei, has found a wide range of applications in life sciences over recent decades. This up-to-date volume covers NMR techniques and their application to proteins, with a focus on practical details. Providing newcomers to NMR with practical guidance to carry out successful experiments with proteins and analyze the resulting spectra, those familiar with the chemical applications of NMR will also find it useful in understanding the special requirements of protein NMR.

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Protein NMR Spectroscopy: Practical Techniques and Applications

Protein NMR Spectroscopy: Practical Techniques and Applications

Protein NMR Spectroscopy: Practical Techniques and Applications
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Protein NMR Spectroscopy: Practical Techniques and Applications

Protein NMR Spectroscopy: Practical Techniques and Applications

Overview

Nuclear Magnetic Resonance (NMR) spectroscopy, a physical phenomenon based upon the magnetic properties of certain atomic nuclei, has found a wide range of applications in life sciences over recent decades. This up-to-date volume covers NMR techniques and their application to proteins, with a focus on practical details. Providing newcomers to NMR with practical guidance to carry out successful experiments with proteins and analyze the resulting spectra, those familiar with the chemical applications of NMR will also find it useful in understanding the special requirements of protein NMR.

Product Details

ISBN-13: 9781119972822
Publisher: Wiley
Publication date: 06/09/2011
Sold by: JOHN WILEY & SONS
Format: eBook
Pages: 368
File size: 8 MB

About the Author

Professor Gordon Roberts is Head of the School of Biological Sciences, University of Leicester.

Dr Christina Redfield is Reader, Oxford Centre for Molecular Sciences, University of Oxford.

Table of Contents

List of Contributors xiii

Introduction 1
Lu-Yun Lian and Gordon Roberts

References 4

1 Sample Preparation, Data Collection and Processing 5
Frederick W. Muskett

1.1 Introduction 5

1.2 Sample Preparation 5

1.3 Data Collection 11

1.4 Data Processing 17

2 Isotope Labelling 23
Mitsuhiro Takeda and Masatsune Kainosho

2.1 Introduction 23

2.2 Production Methods for Isotopically Labelled Proteins 24

2.3 Uniform Isotope Labelling of Proteins 29

2.4 Selective Isotope Labelling of Proteins 32

2.5 Segmental Labelling 37

2.6 SAIL Methods 38

2.7 Concluding Remarks 45

3 Resonance Assignments 55
Lu-Yun Lian and Igor L. Barsukov

3.1 Introduction 55

3.2 Resonance Assignment of Unlabelled Proteins 56

3.3 15N-Edited Experiments 60

3.4 Triple Resonance 62

3.5 Side-Chain Assignments 77

4 Measurement of Structural Restraints 83
Geerten W. Vuister, Nico Tjandra, Yang Shen, Alex Grishaev and Stephan Grzesiek

4.1 Introduction 83

4.2 NOE-Based Distance Restraints 84

4.3 Dihedral Restraints Derived from J-Couplings 96

4.4 Hydrogen Bond Restraints 103

4.5 Orientational Restraints 107

4.6 Chemical Shift Structural Restraints 129

4.7 Solution Scattering Restraints 137

5 Calculation of Structures from NMR Restraints 159
Peter Guntert

5.1 Introduction 159

5.2 Historical Development 161

5.3 Structure Calculation Algorithms 164

5.4 Automated NOE Assignment 173

5.5 Nonclassical Approaches 178

5.6 Fully Automated Structure Analysis 181

6 Paramagnetic Tools in Protein NMR 193
Peter H.J. Keizers and Marcellus Ubbink

6.1 Introduction 193

6.2 Types of Restraints 194

6.3 What Metals to Use? 200

6.4 Paramagnetic Probes 203

6.5 Examples 209

6.6 Conclusions and Perspective 212

7 Structural and Dynamic Information on Ligand Binding 221
Gordon Roberts

7.1 Introduction 221

7.2 Fundamentals of Exchange Effects on NMR Spectra 222

7.3 Measurement of Equilibrium and Rate Constants 229

7.4 Detecting Binding – NMR Screening 238

7.5 Mechanistic Information 241

7.6 Structural Information 246

8 Macromolecular Complexes 269
Paul C. Driscoll

8.1 Introduction 269

8.2 Spectral Simplification through Differential Isotope Labelling 270

8.3 Basic NMR Characterisation of Complexes 273

8.4 3D Structure Determination of Macromolecular Protein–Ligand Complexes 277

8.5 Literature Examples 297

9 Studying Partially Folded and Intrinsically Disordered Proteins Using NMR Residual Dipolar Couplings 319
Malene Ringkjøbing Jensen, Valery Ozenne, Loic Salmon, Gabrielle Nodet, Phineus Markwick, Pau Bernado´ and Martin Blackledge

9.1 Introduction 319

9.2 Ensemble Descriptions of Unfolded Proteins 320

9.3 Experimental Techniques for the Characterisation of IDPs 320

9.4 NMR Spectroscopy of Intrinsically Disordered Proteins 321

9.5 Residual Dipolar Couplings 323

9.6 Conclusions 340

References 340

Index 347

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