Produktbild: Cooperativity Theory in Biochemistry

Cooperativity Theory in Biochemistry Steady-State and Equilibrium Systems

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Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

26.09.2011

Verlag

Springer Us

Seitenzahl

460

Maße (L/B/H)

23.5/15.5/2.6 cm

Gewicht

751 g

Auflage

Softcover reprint of the original 1st ed. 1985

Sprache

Englisch

ISBN

978-1-4612-9555-6

Beschreibung

Produktdetails

Einband

Taschenbuch

Erscheinungsdatum

26.09.2011

Verlag

Springer Us

Seitenzahl

460

Maße (L/B/H)

23.5/15.5/2.6 cm

Gewicht

751 g

Auflage

Softcover reprint of the original 1st ed. 1985

Sprache

Englisch

ISBN

978-1-4612-9555-6

Herstelleradresse

Springer-Verlag KG
Sachsenplatz 4-6
1201 Wien
AT

Email: GPSR Kontakt

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  • Produktbild: Cooperativity Theory in Biochemistry
  • I. Systems without Explicit Interactive Cooperativity.- 1. Preliminary Background Material.- 1. Canonical and Grand Partition Functions.- 2. Effective Partition Functions for Solute Molecules in a Solvent.- 3. The Equilibrium Constant for Binding.- 4. Rate Constants for Binding and Escape.- 5. Perturbation of Rate Constants.- 2. Simple Equilibrium Binding.- 6. Binding of a Ligand on Independent Equivalent Sites.- 7. Two Variations on Simple Binding.- 3. Introduction to Steady-State Systems.- 8. Illustrative Steady-State Systems.- 9. Two-State Steady-State System.- 10. Three-State Steady-State System.- 4. Equilibrium Systems without Explicit Interactions.- 11. Single Conformation Binding Models.- 12. Two Conformations Modulated by Length-Tension and Ligand Binding.- 13. Two Conformations Modulated by an Electric Field and Ligand Binding.- 14. Multisubunits with Two Conformations and Ligand Binding.- 15. Systems with Symmetrical Binding Isotherms.- 5. Steady-State Systems without Explicit Interactions.- 16. Perturbations of a Single Enzyme Molecule.- 17. One-Conformation Complexes with Strong Interactions: Missing States.- 18. One-Conformation Complexes with Strong Interactions: Missing Transitions.- 19. Two-Conformation Complexes with Strong Interactions.- 20. Functional Interactions between Subunits.- 21. Coupled Enzyme Systems in a Vesicular Membrane.- II. Small Systems or Complexes with Explicit Interactive Cooperativity.- 6. Equilibrium Small Systems with Explicit Interactions.- 22. Simple Equilibrium Binding, with Interactions, on a Group of Sites.- 23. More General Models for Binding on Subunits or Sites.- 24. Binding on Subunits with Two Conformations.- 25. Binding of Two Ligands with Induced Conformational Changes.- 26. Rate Constant Perturbations in Equilibrium Systems.- 7. Steady-State Small Systems with Explicit Interactions.- 27. Simple Membrane Transport Models with Interactions.- 28. Simple Complexes with Direct Transfer of Small Molecules.- 29. Complexes with Two One-Conformation Subunits.- 30. Interactions that Affect Rate Constants but Not Equilibrium Constants..- 31. Dimers with Two-Conformation Subunits.- 32. Two Simple Trimeric Enzyme Complexes.- 33. Calcium-ATPase as an Example.- II. One- or Two-Dimensional Lattices of Units with Explicit Interactive Cooperativity.- 8. One-Dimensional Lattices of Interacting Units at Equilibrium.- 34. The Matrix Method in One-Dimensional Equilibrium Problems.- 35. Several One- Dimensional Binding Problems.- 36. Cooperativity in the Tropomyosin-Actin-Myosin (SI) System.- 9. One-Dimensional Array of Interacting Two-State Units at Steady State.- 37. One-Dimensional Lattice in a Quasiequilibrium Steady State.- 38. The Exact Linear Flux-Force Coefficient.- 39. Simple Model for Regulation of Muscle Contraction by Calcium.- 10. Monte Carlo Study of Equilibrium and Steady-State Two-Dimensional Lattices.- 40. The Model and the Monte Carlo Method.- 41. Reference Monte Carlo Calculations at Equilibrium.- 42. Steady-State Monte Carlo Calculations at F = 4 andF = ?.- 43. Steady-State Calculations at F = ? with Other Choices of f? andf?.- 44. Steady-State Monte Carlo Calculations with f? = f? = -1/2.- 45. Steady-State One-Dimensional System with F = ?,f?= 1, f?= 1/2.- 46. Monte Carlo Treatment of a One-Way Three-State Enzyme Lattice.- 11. The Bragg-Williams or Mean-Field Approximation in Steady-State Systems.- 47. Introduction to the Steady-State BW Approximation.- 48. Maxwell Equal-Area Theorem for Two-State Cycles.- 49. Location of a Phase Transition for BW Systems with Three-State Cycles.- 50. Steady-State Phase Transitions Among Biochemical Cycles.