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8. Asymmetry and the Mechanism of the Red Cell Na-K Pump, Determined by Ouabain Binding

  • Joseph F. Hoffman
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Molecular Specialization and Symmetry in Membrane Function
This chapter is in the book Molecular Specialization and Symmetry in Membrane Function

Chapters in this book

  1. Frontmatter i
  2. Foreword v
  3. Preface ix
  4. Contents xiii
  5. PART ONE. Specialization at the Molecular Level
  6. 1. Membrane Biogenesis 3
  7. 2. Lipid–Protein Associations 31
  8. 3. Molecular Architecture of Oligomeric Membrane Proteins 61
  9. 4. Transmembrane Compositional Asymmetry of Lipids in Bilayers and Biomembranes 78
  10. 5. Ligand-Binding Properties of Membrane-Bound Cholinergic Receptors of Torpedo Mormorata 99
  11. 6. The Functional Roles of Band 3 Protein of the Red Blood Cell 128
  12. 7. Energetics and Molecular Biology of Membrane Transport 160
  13. PART TWO. Asymmetry in Transport
  14. 8. Asymmetry and the Mechanism of the Red Cell Na-K Pump, Determined by Ouabain Binding 191
  15. 9. Simultaneous or Consecutive Occupancy by Sodium and Potassium Ions of Their Membrane Pump 212
  16. 10. Proton Translocation in Submitochondrial Particles and Reconstituted Segments of the Respiratory Chain 222
  17. 11. Studies on the Molecular Mechanism of Anion Transport across the Red Blood Cell Membrane 229
  18. PART THREE. Polar Faces in Epithelia
  19. 12. The Double-Membrane Model for Transepithelial Ion Transport: Are Homocellular and Transcellular Ion Transport Related? 253
  20. 13. Differentiation of Cell Faces in Epithelia 272
  21. 14. Solute-Coupled Water Transport in the Kidney 294
  22. 15. Modes of Sodium Transport in the Kidney 316
  23. Index 333
https://doi.org/10.4159/harvard.9780674367227.c11

Chapters in this book

  1. Frontmatter i
  2. Foreword v
  3. Preface ix
  4. Contents xiii
  5. PART ONE. Specialization at the Molecular Level
  6. 1. Membrane Biogenesis 3
  7. 2. Lipid–Protein Associations 31
  8. 3. Molecular Architecture of Oligomeric Membrane Proteins 61
  9. 4. Transmembrane Compositional Asymmetry of Lipids in Bilayers and Biomembranes 78
  10. 5. Ligand-Binding Properties of Membrane-Bound Cholinergic Receptors of Torpedo Mormorata 99
  11. 6. The Functional Roles of Band 3 Protein of the Red Blood Cell 128
  12. 7. Energetics and Molecular Biology of Membrane Transport 160
  13. PART TWO. Asymmetry in Transport
  14. 8. Asymmetry and the Mechanism of the Red Cell Na-K Pump, Determined by Ouabain Binding 191
  15. 9. Simultaneous or Consecutive Occupancy by Sodium and Potassium Ions of Their Membrane Pump 212
  16. 10. Proton Translocation in Submitochondrial Particles and Reconstituted Segments of the Respiratory Chain 222
  17. 11. Studies on the Molecular Mechanism of Anion Transport across the Red Blood Cell Membrane 229
  18. PART THREE. Polar Faces in Epithelia
  19. 12. The Double-Membrane Model for Transepithelial Ion Transport: Are Homocellular and Transcellular Ion Transport Related? 253
  20. 13. Differentiation of Cell Faces in Epithelia 272
  21. 14. Solute-Coupled Water Transport in the Kidney 294
  22. 15. Modes of Sodium Transport in the Kidney 316
  23. Index 333
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