Pumps, Channels and Transporters (eBook, PDF)
Methods of Functional Analysis
Redaktion: Clarke, Ronald J.; Khalid, Mohammed A. A.
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Pumps, Channels and Transporters (eBook, PDF)
Methods of Functional Analysis
Redaktion: Clarke, Ronald J.; Khalid, Mohammed A. A.
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Describes experimental methods for investigating the function of pumps, channels and transporters
Covers new emerging analytical methods used to study ion transport membrane proteins such as single-molecule spectroscopy | Details a wide range of electrophysiological techniques and spectroscopic methods used to analyze the function of ion channels, ion pumps and transporters | Covers state-of-the art analytical methods to study ion pumps, channels, and transporters, and where analytical chemistry can make further contributions
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- Covers new emerging analytical methods used to study ion transport membrane proteins such as single-molecule spectroscopy
- Details a wide range of electrophysiological techniques and spectroscopic methods used to analyze the function of ion channels, ion pumps and transporters
- Covers state-of-the art analytical methods to study ion pumps, channels, and transporters, and where analytical chemistry can make further contributions
Dieser Download kann aus rechtlichen Gründen nur mit Rechnungsadresse in D ausgeliefert werden.
- Produktdetails
- Verlag: Jossey-Bass
- Erscheinungstermin: 16. September 2015
- Englisch
- ISBN-13: 9781119085133
- Artikelnr.: 43833493
- Verlag: Jossey-Bass
- Erscheinungstermin: 16. September 2015
- Englisch
- ISBN-13: 9781119085133
- Artikelnr.: 43833493
- Herstellerkennzeichnung Die Herstellerinformationen sind derzeit nicht verfügbar.
1-Subunit 102 4.4.2.1 Probing Voltage-Dependent Conformational Changes of Na+,K+-ATPase 103 4.4.2.2 The Influence of Intracellular Na+ Concentrations 107 4.4.3 The Rat Gastric H+,K+-ATPase S806C Sensor Construct 108 4.4.3.1 Voltage-Dependent Conformational Shifts of the H+,K+-ATPase Sensor Construct S806C During the H+ Transport Branch 109 4.4.3.2 An Intra- or Extracellular Access Channel of the Proton Pump? 110 4.4.3.3 Effects of Extracellular Ligands: K+ and Na+ 111 4.4.4 Probing Intramolecular Distances by Double Labeling and FRET 113 4.5 Conclusions and Perspectives 116 References 117 5 Patch Clamp Analysis of Transporters via Pre-Steady-State Kinetic Methods 121 Christof Grewer 5.1 Introduction 121 5.2 Patch Clamp Analysis of Secondary-Active Transporter Function 122 5.2.1 Patch Clamp Methods 122 5.2.2 Whole-Cell Recording 124 5.2.3 Recording from Excised Patches 124 5.3 Perturbation Methods 125 5.3.1 Concentration Jumps 126 5.3.2 Voltage Jumps 129 5.4 Evaluation and Interpretation of Pre-Steady-State Kinetic Data 130 5.4.1 Integrating Rate Equations that Describe Mechanistic Transport Models 131 5.4.2 Assigning Kinetic Components to Elementary processes in the Transport Cycle 131 5.5 Mechanistic Insight into Transporter Function 133 5.5.1 Sequential Binding Mechanism 133 5.5.2 Electrostatics 134 5.5.3 Structure-Function Analysis 134 5.6 Case Studies 136 5.6.1 Glutamate Transporter Mechanism 136 5.6.2 Electrogenic Charge Movements Associated with the Electroneutral Amino Acid Exchanger ASCT2 137 5.7 Conclusions 139 References 139 6 Recording of Pump and Transporter Activity Using Solid-Supported Membranes (SSM-Based Electrophysiology) 147 Francesco Tadini-Buoninsegni and Klaus Fendler 6.1 Introduction 147 6.2 The Instrument 148 6.2.1 Rapid Solution Exchange Cuvette 149 6.2.2 Setup and Flow Protocols 150 6.2.3 Protein Preparations 151 6.2.4 Commercial Instruments 152 6.3 Measurement Procedures, Data Analysis, and Interpretation 152 6.3.1 Current Measurement, Signal Analysis, and Reconstruction of Pump Currents 152 6.3.2 Voltage Measurement 156 6.3.3 Solution Exchange Artifacts 157 6.4 P-Type Atp ases Investigated by Ssm-Based Electrophysiology 159 6.4.1 Sarcoplasmic Reticulum Ca2+-ATPase 159 6.4.2 Human Cu+-ATPases ATP7A and ATP7B 163 6.5 Secondary Active Transporters 165 6.5.1 Antiport: Assessing the Forward and Reverse Modes of the NhaA Na+/H+ Exchanger of E. coli 166 6.5.2 Cotransport: A Sugar-Induced Electrogenic Partial Reaction in the Lactose Permease LacY of E. coli 168 6.5.3 The Glutamate Transporter EAAC1: A Robust Electrophysiological Assay with High Information Content 170 6.6 Conclusions 172 References 173 7 Stopped-Flow Fluorimetry Using Voltage-Sensitive Fluorescent Membrane Probes 179 Ronald J. Clarke and Mohammed A. A. Khalid 7.1 Introduction 179 7.2 Basics of the Stopped-Flow Technique 181 7.2.1 Flow Cell Design 181 7.2.2 Rapid Data Acquisition 181 7.2.3 Dead Time 183 7.3 Covalent Versus Noncovalent Fluorescence Labeling 184 7.3.1 Intrinsic Fluorescence 185 7.3.2 Covalently Bound Extrinsic Fluorescent Probes 186 7.3.3 Noncovalently Bound Extrinsic Fluorescent Probes 187 7.4 Classes of Voltage-Sensitive Dyes 188 7.4.1 Slow Dyes 188 7.4.2 Fast Dyes 190 7.5 Measurement of the Kinetics of the Na+,K+-Atpase 193 7.5.1 Dye Concentration 194 7.5.2 Excitation Wavelength and Light Source 197 7.5.3 Monochromators and Filters 198 7.5.4 Photomultiplier and Voltage Supply 199 7.5.5 Reactions Detected by RH421 200 7.5.6 Origin of the RH421 Response 202 7.6 Conclusions 204 References 204 8 Nuclear Magnetic Resonance Spectroscopy 211 Philip W. Kuchel 8.1 Introduction 211 8.1.1 Definition of NMR 212 8.1.2 Why So Useful? 212 8.1.3 Magnetic Polarization 212 8.1.4 Larmor Equation 213 8.1.5 Chemical Shift 213 8.1.6 Free Induction Decay 214 8.1.7 Pulse Excitation 215 8.1.8 Relaxation Times 217 8.1.9 Splitting of Resonance Lines 217 8.1.10 Measuring Membrane Transport 217 8.2 Covalently-Induced Chemical Shift Differences 218 8.2.1 Arginine Transport 218 8.2.2 Other Examples 220 8.3 Shift-Reagent-Induced Chemical Shift Differences 220 8.3.1 DyPPP 220 8.3.2 TmDTPA and TmDOTP 220 8.3.3 Fast Cation Exchange 220 8.4 pH-Induced Chemical Shift Differences 223 8.4.1 Orthophosphate 223 8.4.2 Methylphosphonate 224 8.4.3 Triethylphosphate: 31P Shift Reference 224 8.5 Hydrogen-Bond-Induced Chemical Shift Differences 225 8.5.1 Phosphonates: DMMP 225 8.5.2 HPA 225 8.5.3 Fluorides 227 8.6 Ionic-Environment-Induced Chemical Shift Differences 229 8.6.1 Cs+ Transport 229 8.7 Relaxation Time Differences 229 8.7.1 Mn2+ Doping 229 8.8 Diffusion Coefficient Differences 231 8.8.1 Stejskal-Tanner Plot 231 8.8.2 Andrasko's Method 231 8.9 Some Subtle Spectral Effects 233 8.9.1 Scalar (J) Coupling Differences 233 8.9.2 Endogenous Magnetic Field Gradients 233 8.9.2.1 Magnetic Induction and Magnetic Field Strength 234 8.9.2.2 Magnetic Field Gradients Across Cell Membranes and CO Treatment of RBCs 234 8.9.2.3 Exploiting Magnetic Field Gradients in Membrane Transport Studies 235 8.9.3 Residual Quadrupolar (
Q) Coupling 235 8.10 A Case Study: The Stoichiometric Relationship Between the Number of Na+ Ions Transported per Molecule of Glucose Consumed in Human Rbcs 236 8.11 Conclusions 239 References 239 9 Time-Resolved and Surface-Enhanced Infrared Spectroscopy 245 Joachim Heberle 9.1 Introduction 245 9.2 Basics of Ir Spectroscopy 246 9.2.1 Vibrational Spectroscopy 246 9.2.2 FTIR Spectroscopy 247 9.2.3 IR Spectra of Biological Compounds 248 9.2.4 Difference Spectroscopy 250 9.3 Reflection Techniques 250 9.3.1 Attenuated Total Reflection 250 9.3.2 Surface-Enhanced IR Absorption 251 9.4 Application to Electron-Transferring Proteins 252 9.4.1 Cytochrome c 252 9.4.2 Cytochrome c Oxidase 253 9.5 Time-Resolved ir Spectroscopy 254 9.5.1 The Rapid-Scan Technique 254 9.5.2 The Step-Scan Technique 255 9.5.3 Tunable QCLs 255 9.6 Applications to Retinal Proteins 256 9.6.1 Bacteriorhodopsin 256 9.6.2 Channelrhodopsin 260 9.7 Conclusions 263 References 264 10 Analysis of Membrane-Protein Complexes by Single-Molecule Methods 269 Katia Cosentino, Stephanie Bleicken, and Ana J. García-Sáez 10.1 Introduction 269 10.2 Fluorophores for Single Particle Labeling 270 10.3 Principles of Fluorescence Correlation Spectroscopy 271 10.3.1 Analysis of Molecular Complexes by Two-Color FCS 275 10.3.2 FCS Variants to Study Lipid Membranes 275 10.3.3 FCS Applications to Membranes 278 10.4 Principle and Analysis of Single-Molecule Imaging 279 10.4.1 TIRF Microscopy 280 10.4.2 Single-Molecule Detection 282 10.4.3 Single Particle Tracking and Trajectory Analysis 284 10.5 Complex Dynamics and Stoichiometry by Single-Molecule Microscopy 285 10.5.1 Application to Single-Molecule Stoichiometry Analysis 285 10.5.2 Application to Kinetics Processes in Cell Membranes 290 10.6 Fcs Versus Spt 291 References 291 11 Probing Channel, Pump, and Transporter Function Using Single-Molecule Fluorescence 299 Eve E. Weatherill, John S. H. Danial, and Mark I. Wallace 11.1 Introduction 299 11.1.1 Basic Principles 300 11.2 Practical Considerations 300 11.2.1 Observables 301 11.2.2 Apparatus 301 11.2.3 Labels 302 11.2.4 Bilayers 303 11.3 smf Imaging 303 11.3.1 Fluorescence Colocalization 304 11.3.2 Conformational Changes 306 11.3.3 Superresolution Microscopy 307 11.4 Single Molecule Förster Resonance Energy Transfer 308 11.4.1 Interactions/Stoichiometry 308 11.4.2 Conformational Changes 309 11.5 Single-Molecule Counting by Photobleaching 312 11.6 Optical Channel Recording 314 11.7 Simultaneous Techniques 315 11.8 Summary 318 References 318 12 Electron Paramagnetic Resonance: Site-Directed Spin Labeling 327 Louise J. Brown and Joanna E. Hare 12.1 Introduction 327 12.1.1 Development of EPR as a Tool for Structural Biology 329 12.1.2 SDSL-EPR: A Complementary Approach to Determine Structure-Function Relationships 330 12.2 Basics of the Epr Method 331 12.2.1 Physical Basis of the EPR Signal 331 12.2.2 Spin Labeling 333 12.2.3 EPR Instrumentation 336 12.3 Structural and Dynamic Information from Sdsl-Epr 336 12.3.1 Mobility Measurements 336 12.3.2 Solvent Accessibility 341 12.4 Distance Measurements 345 12.4.1 Interspin Distance Measurements 345 12.4.2 Continuous Wave 347 12.4.3 Pulsed Methods: DEER 349 12.5 Challenges 353 12.5.1 New Labels 353 12.5.2 Spin-Label Flexibility 355 12.5.3 Production and Reconstitution Challenges: Nanodiscs 355 12.6 Conclusions 356 References 357 13 Radioactivity-Based Analysis of Ion Transport 367 Ingolf Bernhardt and J. Clive Ellory 13.1 Introduction 367 13.2 Membrane Permeability for Electroneutral Substances and Ions 368 13.3 Kinetic Considerations 370 13.4 Techniques for Ion Flux Measurements 371 13.4.1 Conventional Methods 371 13.4.2 Alternative Method 373 13.5 Kinetic Analysis of Ion Transporter Properties 375 13.6 Selected Cation Transporter Studies on Red Blood Cells 376 13.6.1 K+,Cl
Cotransport (KCC) 378 13.6.2 Residual Transport 378 13.7 Combination of Radioactive Isotope Studies with Methods using Fluorescent Dyes 379 13.8 Conclusions 382 References 383 14 Cation Uptake Studies with Atomic Absorption Spectrophotometry (Aas) 387 Thomas Friedrich 14.1 Introduction 387 14.2 Overview of the Technique of Aas 389 14.2.1 Historical Account of AAS with Flame Atomization 390 14.2.2 Element-Specific Radiation Sources 391 14.2.3 Electrothermal Atomization in Heated Graphite Tubes 392 14.2.4 Correction for Background Absorption 394 14.3 The Expression System of Xenopus laevis Oocytes for Cation Flux Studies: Practical Considerations 395 14.4 Experimental Outline of the Aas Flux Quantification Technique 395 14.5 Representative Results Obtained with the Aas Flux Quantification Technique 397 14.5.1 Reaction Cycle of P-Type ATPases 398 14.5.2 Rb+ Uptake Kinetics: Inhibitor Sensitivity 398 14.5.3 Dependence of Rb+ Transport of Gastric H+,K+-ATPase on Extra- and Intracellular pH 400 14.5.4 Determination of Na+,K+-ATPase Transport Stoichiometry and Voltage Dependence of H+,K+-ATPase Rb+ Transport 403 14.5.5 Effects of C-Terminal Deletions of the H+,K+-ATPase
-Subunit 404 14.5.6 Li+ and Cs+ Uptake Studies 405 14.6 Concluding Remarks 407 References 408 15 Long Timescale Molecular Simulations for Understanding Ion Channel Function 411 Ben Corry 15.1 Introduction 411 15.2 Fundamentals of Md Simulation 412 15.2.1 The Main Idea 412 15.2.2 Force Fields 414 15.2.3 O ther Simulation Considerations 416 15.2.4 Why Do MD Simulations Take So Much Computational Power? 416 15.2.4.1 Force Calculations 417 15.2.4.2 Time Step 417 15.3 Simulation Duration and Simulation Size 418 15.4 Historical Development of Long Md Simulations 421 15.5 Limitations and Challenges Facing Md Simulations 423 15.5.1 Force Field and Algorithm Accuracy 423 15.5.2 Sampling Problems 424 15.6 Example Simulations of Ion Channels 425 15.6.1 Simulations of Ion Permeation 425 15.6.2 Simulations of Ion Selectivity 428 15.6.3 Simulations of Channel Gating 432 15.7 Conclusions 433 References 436 Index 443 Chemical Analysis: A Series of Monographs on Analytical Chemistry and its Applications 461
1-Subunit 102 4.4.2.1 Probing Voltage-Dependent Conformational Changes of Na+,K+-ATPase 103 4.4.2.2 The Influence of Intracellular Na+ Concentrations 107 4.4.3 The Rat Gastric H+,K+-ATPase S806C Sensor Construct 108 4.4.3.1 Voltage-Dependent Conformational Shifts of the H+,K+-ATPase Sensor Construct S806C During the H+ Transport Branch 109 4.4.3.2 An Intra- or Extracellular Access Channel of the Proton Pump? 110 4.4.3.3 Effects of Extracellular Ligands: K+ and Na+ 111 4.4.4 Probing Intramolecular Distances by Double Labeling and FRET 113 4.5 Conclusions and Perspectives 116 References 117 5 Patch Clamp Analysis of Transporters via Pre-Steady-State Kinetic Methods 121 Christof Grewer 5.1 Introduction 121 5.2 Patch Clamp Analysis of Secondary-Active Transporter Function 122 5.2.1 Patch Clamp Methods 122 5.2.2 Whole-Cell Recording 124 5.2.3 Recording from Excised Patches 124 5.3 Perturbation Methods 125 5.3.1 Concentration Jumps 126 5.3.2 Voltage Jumps 129 5.4 Evaluation and Interpretation of Pre-Steady-State Kinetic Data 130 5.4.1 Integrating Rate Equations that Describe Mechanistic Transport Models 131 5.4.2 Assigning Kinetic Components to Elementary processes in the Transport Cycle 131 5.5 Mechanistic Insight into Transporter Function 133 5.5.1 Sequential Binding Mechanism 133 5.5.2 Electrostatics 134 5.5.3 Structure-Function Analysis 134 5.6 Case Studies 136 5.6.1 Glutamate Transporter Mechanism 136 5.6.2 Electrogenic Charge Movements Associated with the Electroneutral Amino Acid Exchanger ASCT2 137 5.7 Conclusions 139 References 139 6 Recording of Pump and Transporter Activity Using Solid-Supported Membranes (SSM-Based Electrophysiology) 147 Francesco Tadini-Buoninsegni and Klaus Fendler 6.1 Introduction 147 6.2 The Instrument 148 6.2.1 Rapid Solution Exchange Cuvette 149 6.2.2 Setup and Flow Protocols 150 6.2.3 Protein Preparations 151 6.2.4 Commercial Instruments 152 6.3 Measurement Procedures, Data Analysis, and Interpretation 152 6.3.1 Current Measurement, Signal Analysis, and Reconstruction of Pump Currents 152 6.3.2 Voltage Measurement 156 6.3.3 Solution Exchange Artifacts 157 6.4 P-Type Atp ases Investigated by Ssm-Based Electrophysiology 159 6.4.1 Sarcoplasmic Reticulum Ca2+-ATPase 159 6.4.2 Human Cu+-ATPases ATP7A and ATP7B 163 6.5 Secondary Active Transporters 165 6.5.1 Antiport: Assessing the Forward and Reverse Modes of the NhaA Na+/H+ Exchanger of E. coli 166 6.5.2 Cotransport: A Sugar-Induced Electrogenic Partial Reaction in the Lactose Permease LacY of E. coli 168 6.5.3 The Glutamate Transporter EAAC1: A Robust Electrophysiological Assay with High Information Content 170 6.6 Conclusions 172 References 173 7 Stopped-Flow Fluorimetry Using Voltage-Sensitive Fluorescent Membrane Probes 179 Ronald J. Clarke and Mohammed A. A. Khalid 7.1 Introduction 179 7.2 Basics of the Stopped-Flow Technique 181 7.2.1 Flow Cell Design 181 7.2.2 Rapid Data Acquisition 181 7.2.3 Dead Time 183 7.3 Covalent Versus Noncovalent Fluorescence Labeling 184 7.3.1 Intrinsic Fluorescence 185 7.3.2 Covalently Bound Extrinsic Fluorescent Probes 186 7.3.3 Noncovalently Bound Extrinsic Fluorescent Probes 187 7.4 Classes of Voltage-Sensitive Dyes 188 7.4.1 Slow Dyes 188 7.4.2 Fast Dyes 190 7.5 Measurement of the Kinetics of the Na+,K+-Atpase 193 7.5.1 Dye Concentration 194 7.5.2 Excitation Wavelength and Light Source 197 7.5.3 Monochromators and Filters 198 7.5.4 Photomultiplier and Voltage Supply 199 7.5.5 Reactions Detected by RH421 200 7.5.6 Origin of the RH421 Response 202 7.6 Conclusions 204 References 204 8 Nuclear Magnetic Resonance Spectroscopy 211 Philip W. Kuchel 8.1 Introduction 211 8.1.1 Definition of NMR 212 8.1.2 Why So Useful? 212 8.1.3 Magnetic Polarization 212 8.1.4 Larmor Equation 213 8.1.5 Chemical Shift 213 8.1.6 Free Induction Decay 214 8.1.7 Pulse Excitation 215 8.1.8 Relaxation Times 217 8.1.9 Splitting of Resonance Lines 217 8.1.10 Measuring Membrane Transport 217 8.2 Covalently-Induced Chemical Shift Differences 218 8.2.1 Arginine Transport 218 8.2.2 Other Examples 220 8.3 Shift-Reagent-Induced Chemical Shift Differences 220 8.3.1 DyPPP 220 8.3.2 TmDTPA and TmDOTP 220 8.3.3 Fast Cation Exchange 220 8.4 pH-Induced Chemical Shift Differences 223 8.4.1 Orthophosphate 223 8.4.2 Methylphosphonate 224 8.4.3 Triethylphosphate: 31P Shift Reference 224 8.5 Hydrogen-Bond-Induced Chemical Shift Differences 225 8.5.1 Phosphonates: DMMP 225 8.5.2 HPA 225 8.5.3 Fluorides 227 8.6 Ionic-Environment-Induced Chemical Shift Differences 229 8.6.1 Cs+ Transport 229 8.7 Relaxation Time Differences 229 8.7.1 Mn2+ Doping 229 8.8 Diffusion Coefficient Differences 231 8.8.1 Stejskal-Tanner Plot 231 8.8.2 Andrasko's Method 231 8.9 Some Subtle Spectral Effects 233 8.9.1 Scalar (J) Coupling Differences 233 8.9.2 Endogenous Magnetic Field Gradients 233 8.9.2.1 Magnetic Induction and Magnetic Field Strength 234 8.9.2.2 Magnetic Field Gradients Across Cell Membranes and CO Treatment of RBCs 234 8.9.2.3 Exploiting Magnetic Field Gradients in Membrane Transport Studies 235 8.9.3 Residual Quadrupolar (
Q) Coupling 235 8.10 A Case Study: The Stoichiometric Relationship Between the Number of Na+ Ions Transported per Molecule of Glucose Consumed in Human Rbcs 236 8.11 Conclusions 239 References 239 9 Time-Resolved and Surface-Enhanced Infrared Spectroscopy 245 Joachim Heberle 9.1 Introduction 245 9.2 Basics of Ir Spectroscopy 246 9.2.1 Vibrational Spectroscopy 246 9.2.2 FTIR Spectroscopy 247 9.2.3 IR Spectra of Biological Compounds 248 9.2.4 Difference Spectroscopy 250 9.3 Reflection Techniques 250 9.3.1 Attenuated Total Reflection 250 9.3.2 Surface-Enhanced IR Absorption 251 9.4 Application to Electron-Transferring Proteins 252 9.4.1 Cytochrome c 252 9.4.2 Cytochrome c Oxidase 253 9.5 Time-Resolved ir Spectroscopy 254 9.5.1 The Rapid-Scan Technique 254 9.5.2 The Step-Scan Technique 255 9.5.3 Tunable QCLs 255 9.6 Applications to Retinal Proteins 256 9.6.1 Bacteriorhodopsin 256 9.6.2 Channelrhodopsin 260 9.7 Conclusions 263 References 264 10 Analysis of Membrane-Protein Complexes by Single-Molecule Methods 269 Katia Cosentino, Stephanie Bleicken, and Ana J. García-Sáez 10.1 Introduction 269 10.2 Fluorophores for Single Particle Labeling 270 10.3 Principles of Fluorescence Correlation Spectroscopy 271 10.3.1 Analysis of Molecular Complexes by Two-Color FCS 275 10.3.2 FCS Variants to Study Lipid Membranes 275 10.3.3 FCS Applications to Membranes 278 10.4 Principle and Analysis of Single-Molecule Imaging 279 10.4.1 TIRF Microscopy 280 10.4.2 Single-Molecule Detection 282 10.4.3 Single Particle Tracking and Trajectory Analysis 284 10.5 Complex Dynamics and Stoichiometry by Single-Molecule Microscopy 285 10.5.1 Application to Single-Molecule Stoichiometry Analysis 285 10.5.2 Application to Kinetics Processes in Cell Membranes 290 10.6 Fcs Versus Spt 291 References 291 11 Probing Channel, Pump, and Transporter Function Using Single-Molecule Fluorescence 299 Eve E. Weatherill, John S. H. Danial, and Mark I. Wallace 11.1 Introduction 299 11.1.1 Basic Principles 300 11.2 Practical Considerations 300 11.2.1 Observables 301 11.2.2 Apparatus 301 11.2.3 Labels 302 11.2.4 Bilayers 303 11.3 smf Imaging 303 11.3.1 Fluorescence Colocalization 304 11.3.2 Conformational Changes 306 11.3.3 Superresolution Microscopy 307 11.4 Single Molecule Förster Resonance Energy Transfer 308 11.4.1 Interactions/Stoichiometry 308 11.4.2 Conformational Changes 309 11.5 Single-Molecule Counting by Photobleaching 312 11.6 Optical Channel Recording 314 11.7 Simultaneous Techniques 315 11.8 Summary 318 References 318 12 Electron Paramagnetic Resonance: Site-Directed Spin Labeling 327 Louise J. Brown and Joanna E. Hare 12.1 Introduction 327 12.1.1 Development of EPR as a Tool for Structural Biology 329 12.1.2 SDSL-EPR: A Complementary Approach to Determine Structure-Function Relationships 330 12.2 Basics of the Epr Method 331 12.2.1 Physical Basis of the EPR Signal 331 12.2.2 Spin Labeling 333 12.2.3 EPR Instrumentation 336 12.3 Structural and Dynamic Information from Sdsl-Epr 336 12.3.1 Mobility Measurements 336 12.3.2 Solvent Accessibility 341 12.4 Distance Measurements 345 12.4.1 Interspin Distance Measurements 345 12.4.2 Continuous Wave 347 12.4.3 Pulsed Methods: DEER 349 12.5 Challenges 353 12.5.1 New Labels 353 12.5.2 Spin-Label Flexibility 355 12.5.3 Production and Reconstitution Challenges: Nanodiscs 355 12.6 Conclusions 356 References 357 13 Radioactivity-Based Analysis of Ion Transport 367 Ingolf Bernhardt and J. Clive Ellory 13.1 Introduction 367 13.2 Membrane Permeability for Electroneutral Substances and Ions 368 13.3 Kinetic Considerations 370 13.4 Techniques for Ion Flux Measurements 371 13.4.1 Conventional Methods 371 13.4.2 Alternative Method 373 13.5 Kinetic Analysis of Ion Transporter Properties 375 13.6 Selected Cation Transporter Studies on Red Blood Cells 376 13.6.1 K+,Cl
Cotransport (KCC) 378 13.6.2 Residual Transport 378 13.7 Combination of Radioactive Isotope Studies with Methods using Fluorescent Dyes 379 13.8 Conclusions 382 References 383 14 Cation Uptake Studies with Atomic Absorption Spectrophotometry (Aas) 387 Thomas Friedrich 14.1 Introduction 387 14.2 Overview of the Technique of Aas 389 14.2.1 Historical Account of AAS with Flame Atomization 390 14.2.2 Element-Specific Radiation Sources 391 14.2.3 Electrothermal Atomization in Heated Graphite Tubes 392 14.2.4 Correction for Background Absorption 394 14.3 The Expression System of Xenopus laevis Oocytes for Cation Flux Studies: Practical Considerations 395 14.4 Experimental Outline of the Aas Flux Quantification Technique 395 14.5 Representative Results Obtained with the Aas Flux Quantification Technique 397 14.5.1 Reaction Cycle of P-Type ATPases 398 14.5.2 Rb+ Uptake Kinetics: Inhibitor Sensitivity 398 14.5.3 Dependence of Rb+ Transport of Gastric H+,K+-ATPase on Extra- and Intracellular pH 400 14.5.4 Determination of Na+,K+-ATPase Transport Stoichiometry and Voltage Dependence of H+,K+-ATPase Rb+ Transport 403 14.5.5 Effects of C-Terminal Deletions of the H+,K+-ATPase
-Subunit 404 14.5.6 Li+ and Cs+ Uptake Studies 405 14.6 Concluding Remarks 407 References 408 15 Long Timescale Molecular Simulations for Understanding Ion Channel Function 411 Ben Corry 15.1 Introduction 411 15.2 Fundamentals of Md Simulation 412 15.2.1 The Main Idea 412 15.2.2 Force Fields 414 15.2.3 O ther Simulation Considerations 416 15.2.4 Why Do MD Simulations Take So Much Computational Power? 416 15.2.4.1 Force Calculations 417 15.2.4.2 Time Step 417 15.3 Simulation Duration and Simulation Size 418 15.4 Historical Development of Long Md Simulations 421 15.5 Limitations and Challenges Facing Md Simulations 423 15.5.1 Force Field and Algorithm Accuracy 423 15.5.2 Sampling Problems 424 15.6 Example Simulations of Ion Channels 425 15.6.1 Simulations of Ion Permeation 425 15.6.2 Simulations of Ion Selectivity 428 15.6.3 Simulations of Channel Gating 432 15.7 Conclusions 433 References 436 Index 443 Chemical Analysis: A Series of Monographs on Analytical Chemistry and its Applications 461