Schuck Protein Interactions

1;Contents;6
2;Contributors;8
3;Preface;11
4;The Characterization of Biomolecular Interactions Using Fluorescence Fluctuation Techniques;13
4.1;1.1. INTRODUCTION;13
4.2;1.2. ADVANTAGES OF FLUCTUATION SPECTROSCOPY;15
4.3;1.3. FLUORESCENCE CORRELATION SPECTROSCOPY, AND MOLECULAR DIFFUSION;17
4.4;1.4. CROSS-CORRELATION AND HETEROLOGOUS ASSOCIATIONS;21
4.5;1.5. PHOTON STATISTICS;25
4.6;1.6. EXAMPLES OF THE USE OF FLUCTUATION SPECTROSCOPY TO STUDY BIOMOLECULAR INTERACTIONS;31
4.7;1.7. LIMITATIONS OF FCS;37
4.8;1.8. CONCLUSION;44
4.9;REFERENCES;44
5;Characterization of Protein– Protein Interactions Using Atomic Force Microscopy;51
5.1;2.1. INTRODUCTION;51
5.2;2.2. USE OF AFM;52
5.3;2.3. CHARACTERIZATION OF PROTEIN–PROTEIN COMPLEXES;60
5.4;2.4. CONCLUDING REMARKS;81
5.5;ACKNOWLEDGMENTS;81
5.6;REFERENCES;81
6;Combined Solid-Phase Detection Techniques for Dissecting Multiprotein Interactions on Membranes;90
6.1;3.1. INTRODUCTION;90
6.2;3.2. LABEL-FREE DETECTION TECHNIQUES;91
6.3;3.3. SIMULTANEOUS LABEL-FREE AND FLUORESCENCE DETECTION;93
6.4;3.4. CONCLUSIONS;104
6.5;REFERENCES;105
7;Surface Plasmon Resonance Biosensing in the Study of Ternary Systems of Interacting Proteins;108
7.1;4.1. INTRODUCTION;108
7.2;4.2. SURFACE PLASMON RESONANCE BASICS;110
7.3;4.3. LIMITATIONS OF USING SURFACE-IMMOBILIZED SITES TO STUDY PROTEIN– PROTEIN INTERACTIONS;117
7.4;4.4. STUDYING INTERACTING SYSTEMS WITH MULTIPLE COMPONENTS, BINDING SITES, OR CONFORMATIONAL STATES;123
7.5;4.5. A PRACTICAL APPLICATION TO THE STUDY OF MULTIPROTEIN COMPLEXES;135
7.6;4.6. CONCLUSIONS;144
7.7;ACKNOWLEDGMENT;145
7.8;REFERENCES;145
8;Mass Spectrometry for Studying Protein Modifications and for Discovery of Protein Interactions;153
8.1;5.1. INTRODUCTION;153
8.2;5.2. MASS SPECTROMETRY;154
8.3;5.3. PROTEIN IDENTIFICATION AND CHARACTERIZATION BY MASS SPECTROMETRY;165
8.4;5.4. ANALYSIS OF PROTEIN COMPLEXES BY MASS SPECTROMETRY;169
8.5;REFERENCES;175
9;H/2H Exchange Mass Spectrometry of Protein Complexes;178
9.1;6.1. INTRODUCTION;178
9.2;6.2. TYPES OF AMIDE EXCHANGE EXPERIMENTS ON PROTEIN COMPLEXES;180
9.3;6.3. THE BASIC EXPERIMENTAL METHOD;185
9.4;6.4. CONFORMATIONAL CHANGES ON PROTEIN– PROTEIN INTERACTION;191
9.5;REFERENCES;194
10;Elucidation of Protein–Protein and Protein– Ligand Interactions by NMR Spectroscopy;197
10.1;7.1. INTRODUCTION;197
10.2;7.2. PRINCIPLES OF NMR STRUCTURE DETERMINATION;198
10.3;7.3. NMR-BASED METHODS FOR THE STUDY OF PROTEIN– PROTEIN AND PROTEIN– LIGAND INTERACTIONS;207
10.4;REFERENCES;228
11;Application of Isothermal Titration Calorimetry in Exploring the Extended Interface;238
11.1;8.1. INTRODUCTION;238
11.2;8.2. ISOTHERMAL TITRATION CALORIMETRY: GENERAL PRINCIPLES;239
11.3;8.3. BINDING AND RELEASE OF SOLVENT IONS;241
11.4;8.4. CHANGES IN HEAT CAPACITY REVEAL THE EXTENDED INTERFACE;244
11.5;8.5. THERMODYNAMIC EFFECTS OF PROTEIN STRUCTURAL PERTURBATION ON BINDING;249
11.6;8.6. SUMMARY;258
11.7;REFERENCES;259
12;Solvent Mediated Protein– Protein Interactions;262
12.1;9.1. INTRODUCTION;262
12.2;9.2. THERMODYNAMICS BACKGROUND;264
12.3;9.3. DESCRIPTION OF THE SOLVATION OF MACROMOLECULES IN TWO- COMPONENT SOLVENT;266
12.4;9.4. MACROMOLECULE–MACROMOLECULE INTERACTIONS;271
12.5;9.5. LINKAGE BETWEEN PROTEIN–SOLVENT AND PROTEIN– PROTEIN INTERACTIONS;276
12.6;9.6. MODELS FOR DESCRIBING SOLVATION AND ITS ORIGINS;276
12.7;9.7. EXAMPLES OF PERTUBATION OF MACROMOLECULAR EQUILIBRIUM BY COSOLVENTS;279
12.8;9.8. METHODS THAT ALLOW THE CHARACTERIZATION OF THE PROTEIN AS A SOLVATED PARTICLE;284
12.9;ACKNOWLEDGMENT;290
12.10;REFERENCES;290
13;Sedimentation Equilibrium Analytical Ultracentrifugation for Multicomponent Protein Interactions;295
13.1;10.1. INTRODUCTION;295
13.2;10.2. BASIC PRINCIPLES;296
13.3;10.3. EXPERIMENTAL;299
13.4;10.4. THEORY;300
13.5;10.5. DATA ANALYSIS;306
13.6;10.6. APPLICATIONS;309
13.7;10.7. CONCLUSIONS;317
13.8;ACKNOWLEDGMENT;317
13.9;REFERENCES;317
14;Structure Analysis of Macromolecular Complexes by Solution Small- Angle Scattering;323
14.1;11.1. INTRODUCTION;323
14.2;11.2. MAIN THEORETICAL AND EXPERIMENTAL ASPECTS;324
14.3;11.3. RECENT DEVELOPMENTS IN DATA ANALYSIS METHODS;338
14.4;11.4. EXAMPLES OF PRACTICAL APPLICATIONS;346
14.5;11.5. CONCLUSIONS;363
14.6;REFERENCES;365
15;Fluorescence Detection of Proximity;372
15.1;12.1. INTRODUCTION;372
15.2;12.2. FRET;373
15.3;12.3. APPLICATIONS;383
15.4;12.4. CONCLUSION;396
15.5;ACKNOWLEDGMENTS;397
15.6;REFERENCES;397
16;Steady-State and Time-Resolved Emission Anisotropy;402
16.1;13.1. INTRODUCTION;402
16.2;13.2. THEORY OF TIME-RESOLVED EMISSION ANISOTROPY;402
16.3;13.3. EXPERIMENTAL;412
16.4;13.4. PROSPECTS;418
16.5;ACKNOWLEDGEMENTS;418
16.6;REFERENCES;419
17;Analysis of Protein–DNA Equilibria by Native Gel Electrophoresis;422
17.1;14.1. INTRODUCTION;422
17.2;14.2. CHOICE OF SUBSTRATE;423
17.3;14.3. DETECTION AND QUANTITATION OF COMPLEXES AND FREE DNA;425
17.4;14.4. STABILITY OF COMPLEXES DURING ELECTROPHORESIS;429
17.5;14.5. MEASUREMENT OF STOICHIOMETRY;434
17.6;14.6. MEASUREMENT OF BINDING ACTIVITY;438
17.7;14.7. MEASUREMENT OF ASSOCIATION CONSTANTS;438
17.8;14.8. A LOOK INTO THE FUTURE;445
17.9;REFERENCES;446
18;Electrospray Ionization Mass Spectrometry and the Study of Protein Complexes;452
18.1;15.1. INTRODUCTION;452
18.2;15.2. HISTORY AND DEVELOPMENT OF MASS SPECTROMETRY AS A TOOL FOR STUDYING PROTEIN COMPLEXES;453
18.3;15.3. PRINCIPLES OF ESI MASS SPECTROMETRY OF PROTEIN COMPLEXES;454
18.4;15.4. APPLICATIONS OF MASS SPECTROMETRY TO STRUCTURAL BIOLOGY;466
18.5;15.5. SUMMARY;471
18.6;REFERENCES;471
19;Sedimentation Velocity in the Study of Reversible Multiprotein Complexes;474
19.1;16.1. INTRODUCTION;474
19.2;16.2. EXPERIMENTAL SET-UP;476
19.3;16.3. BASIC PRINCIPLES OF SEDIMENTATION VELOCITY ANALYSIS;481
19.4;16.4. ASSESSING CONFORMATION OF PROTEINS AND PROTEIN COMPLEXES;492
19.5;16.5. SEDIMENTATION OF INTERACTING SYSTEMS;495
19.6;16.6. CONCLUSIONS;516
19.7;ACKNOWLEDGMENT;517
19.8;REFERENCES;517
20;Index;524