Your search keyword '"T4 LYSOZYME"' showing total 4 results

1. Exploring the Structure of the 100 Amino-Acid Residue Long N-Terminus of the Plant Antenna Protein CP29

Author

Herbert van Amerongen, Maryam Hashemi Shabestari, Martina Huber, Cor J. A. M. Wolfs, and Ruud B. Spruijt

Subjects

distance measurements, t4 lysozyme, Molecular Sequence Data, Arabidopsis, Biophysics, Molecular Dynamics Simulation, Biology, light-harvesting complex, law.invention, Chloroplast Proteins, Residue (chemistry), electron-paramagnetic-resonance, energy-transfer, law, conformational-changes, Amino Acid Sequence, Electron paramagnetic resonance, Peptide sequence, labeled side-chains, Arabidopsis Proteins, Pulsed EPR, Rotational diffusion, comprehensive software package, structure prediction, Protein Structure, Tertiary, N-terminus, Crystallography, Biofysica, Ribonucleoproteins, Membrane protein, photosystem-ii, Thylakoid, Mutation, Proteins and Nucleic Acids

Abstract

The structure of the unusually long (∼100 amino-acid residues) N-terminal domain of the light-harvesting protein CP29 of plants is not defined in the crystal structure of this membrane protein. We studied the N-terminus using two electron paramagnetic resonance (EPR) approaches: the rotational diffusion of spin labels at 55 residues with continuous-wave EPR, and three sets of distances with a pulsed EPR method. The N-terminus is relatively structured. Five regions that differ considerably in their dynamics are identified. Two regions have low rotational diffusion, one of which shows α-helical character suggesting contact with the protein surface. This immobile part is flanked by two highly dynamic, unstructured regions (loops) that cover residues 10–22 and 82–91. These loops may be important for the interaction with other light-harvesting proteins. The region around residue 4 also has low rotational diffusion, presumably because it attaches noncovalently to the protein. This section is close to a phosphorylation site (Thr-6) in related proteins, such as those encoded by the Lhcb4.2 gene. Phosphorylation might influence the interaction with other antenna complexes, thereby regulating the supramolecular organization in the thylakoid membrane.

Published

2014

2. Protein dynamics derived from clusters of crystal structures

Author

Herman J. C. Berendsen, John B. C. Findlay, Andrea Amadei, D.A. Conn, D.M.F. van Aalten, B. L. de Groot, Molecular Dynamics, and Faculty of Science and Engineering

Subjects

Models, Molecular, Protein Conformation, Biophysics, Crystal structure, FORMS, Crystallography, X-Ray, Biophysical Phenomena, MYOGLOBIN, Quantitative Biology::Subcellular Processes, Molecular dynamics, Protein structure, T4 LYSOZYME, Computational chemistry, EGG-WHITE LYSOZYME, MOTIONS, Animals, Quantitative Biology::Biomolecules, IDENTIFICATION, Basis (linear algebra), Chemistry, CRYSTALLOGRAPHY, Protein dynamics, Dynamics (mechanics), Proteins, Nuclear magnetic resonance spectroscopy, Ligand (biochemistry), SIMULATIONS, MOLECULAR-DYNAMICS, Chemical physics, NMR-SPECTROSCOPY, Thermodynamics, Crystallization, Research Article

Abstract

A method is presented to mathematically extract concerted structural transitions in proteins from collections of crystal structures. The ''essential dynamics'' procedure is used to filter out small-amplitude fluctuations from such a set of structures; the remaining large conformational changes describe motions such as those important for the uptake/release of substrate/ligand and in catalytic reactions. The method is applied to sets of x-ray structures for a number of proteins, and the results are compared with the results from essential dynamics as applied to molecular dynamics simulations of those proteins. A significant degree of similarity is found, thereby providing a direct experimental basis for the application of such simulations to the description of large concerted motions in proteins.

Published

1997

3. Protein dynamics derived from clusters of crystal structures

Subjects

IDENTIFICATION, MOLECULAR-DYNAMICS, T4 LYSOZYME, NMR-SPECTROSCOPY, CRYSTALLOGRAPHY, EGG-WHITE LYSOZYME, MOTIONS, FORMS, SIMULATIONS, MYOGLOBIN

Abstract

A method is presented to mathematically extract concerted structural transitions in proteins from collections of crystal structures. The ''essential dynamics'' procedure is used to filter out small-amplitude fluctuations from such a set of structures; the remaining large conformational changes describe motions such as those important for the uptake/release of substrate/ligand and in catalytic reactions. The method is applied to sets of x-ray structures for a number of proteins, and the results are compared with the results from essential dynamics as applied to molecular dynamics simulations of those proteins. A significant degree of similarity is found, thereby providing a direct experimental basis for the application of such simulations to the description of large concerted motions in proteins.

Published

1997

4. Protein dynamics derived from clusters of crystal structures

Subjects

Quantitative Biology::Subcellular Processes, Quantitative Biology::Biomolecules, IDENTIFICATION, MOLECULAR-DYNAMICS, T4 LYSOZYME, NMR-SPECTROSCOPY, CRYSTALLOGRAPHY, EGG-WHITE LYSOZYME, MOTIONS, FORMS, SIMULATIONS, MYOGLOBIN

Abstract

A method is presented to mathematically extract concerted structural transitions in proteins from collections of crystal structures. The ''essential dynamics'' procedure is used to filter out small-amplitude fluctuations from such a set of structures; the remaining large conformational changes describe motions such as those important for the uptake/release of substrate/ligand and in catalytic reactions. The method is applied to sets of x-ray structures for a number of proteins, and the results are compared with the results from essential dynamics as applied to molecular dynamics simulations of those proteins. A significant degree of similarity is found, thereby providing a direct experimental basis for the application of such simulations to the description of large concerted motions in proteins.

Published

1997