Membrane Protein Structure

1. Front Matter

   Pages i-x

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2. The Nature of the Membrane Protein Structure Problem

   1. Front Matter

      Pages 1-1

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   2. Membrane Protein Structure and Stability: Implications of the First Crystallographic Analyses

      • D. C. Rees, A. J. Chirino, K.-H. Kim, H. Komiya

      Pages 3-26

   3. Decoding the Signals of Membrane Protein Sequences

      • Gunnar von Heijne

      Pages 27-40

   4. Folding and Assembly of Integral Membrane Proteins: An Introduction

      • Jean-Luc Popot, Catherine de Vitry, Ariane Atteia

      Pages 41-96

   5. Hydropathy Plots and the Prediction of Membrane Protein Topology

      • Stephen H. White

      Pages 97-124

3. Biochemical and Molecular Biological Approaches: Protein Topology

   1. Front Matter

      Pages 125-126

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   2. Experimental Determination of the Topography of Membrane Proteins: Lessons from the Nicotinic Acetylcholine Receptor, a Multisubunit Polytopic Protein

      • David S. Cafiso

      Pages 127-143

   3. Use of Gene Fusions to Determine Membrane Protein Topology

      • Dana Boyd

      Pages 144-163

   4. Structure of F0F1ATPases Determined by Direct and Indirect Methods

      • L. Mario Amzel, Mario A. Blanchet, Peter L. Pedersen

      Pages 164-177

4. Direct Structural Approaches

   1. Front Matter

      Pages 179-180

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   2. Experimental Determination of Membrane Protein Secondary Structure Using Vibrational and CD Spectroscopies

      • Robert W. Williams

      Pages 181-205

   3. High-Resolution Electron Crystallography of Membrane Proteins

      • Werner Kühlbrandt

      Pages 206-223

   4. Site-Directed Spin Labeling of Membrane Proteins

      • Wayne L. Hubbell, Christian Altenbach

      Pages 224-248

   5. Nuclear Magnetic Resonance Approaches to Membrane Protein Structure

      • Stanley J. Opella

      Pages 249-267

   6. Structure of Integral Membrane Proteins within Membranes via X-Ray and Neutron Diffraction: From Oriented Multilayers to a Single Monolayer

      • J. Kent Blasie

      Pages 268-280

5. Model and Physicochemical Approaches

   1. Front Matter

      Pages 281-281

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   2. Physical Studies of Peptide—Bilayer Interactions

      • Lukas K. Tamm

      Pages 283-313

   3. Membrane Protein Structure: Lessons from Gramicidin

      • G. Andrew Woolley, B. A. Wallace

      Pages 314-334

   4. Use of Synthetic Peptides for the Study of Membrane Protein Structure

      • J. D. Lear, Z. R. Wasserman, W. F. Degrado

      Pages 335-354

Studies of receptors, ion channels, and other membrane proteins require a solid understanding of the structural principles of these important biomolecules. Membrane protein structure is, however, a very challenging field. The structures of only three types of transmembrane proteins have been determined to moderate or high resolution during the last two decades, a period during which the amino acid sequences of hundreds, if not thousands, of membrane proteins have been reported. As a result, the creation of structural models to serve as guides for studies of receptors, channels, and other membrane proteins has become crucially important. This book has been assembled in order to share the experiences and findings of expert researchers in protein structure and structure-prediction methods as well as membrane biophysics and lipid physical chemistry, whose work establishes the basis for the development of suitable model structures. The reviews presented here emphasize fundamental ideas and provide an entry to the diverse and complex literature. The four major sections deal with the general nature of the membrane protein structure problem, biochemical and molecular biological approaches to protein topology, direct structural methods, and model and physicochemical approaches. The work will be of interest to physiologists, cellular and molecular biologists, biophysicists, and biochemists working on the function of membrane proteins such as receptors, ion channels, and transporters, as well as senior graduate students and independent investigators.

• biomolecules
• biophysics
• gene
• membrane
• physiology
• protein structure
• proteins
• topology

• College of Medicine, Department of Physiology and Biophysics, University of California, Irvine, Irvine, USA

  Stephen H. White

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