Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement

Research output: Contribution to journalJournal articleResearch

Standard

Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement. / Pedersen, Bjørn Panyella; Gourdon, Pontus Emanuel; Liu, Xiangyu; Karlsen, Jesper Lykkegaard; Nissen, Poul.

In: arXiv, 28.03.2014, p. 1-19.

Research output: Contribution to journalJournal articleResearch

Harvard

Pedersen, BP, Gourdon, PE, Liu, X, Karlsen, JL & Nissen, P 2014, 'Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement', arXiv, pp. 1-19.

APA

Pedersen, B. P., Gourdon, P. E., Liu, X., Karlsen, J. L., & Nissen, P. (2014). Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement. arXiv, 1-19.

Vancouver

Pedersen BP, Gourdon PE, Liu X, Karlsen JL, Nissen P. Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement. arXiv. 2014 Mar 28;1-19.

Author

Pedersen, Bjørn Panyella ; Gourdon, Pontus Emanuel ; Liu, Xiangyu ; Karlsen, Jesper Lykkegaard ; Nissen, Poul. / Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement. In: arXiv. 2014 ; pp. 1-19.

Bibtex

@article{35995aa3bb81479fb73fe95964a3afe3,
title = "Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement",
abstract = "To obtain an electron-density map from a macromolecular crystal the phase-problem needs to be solved, which often involves the use of heavy-atom derivative crystals and concomitantly the determination of the heavy atom substructure. This is customarily done by direct methods or Patterson-based approaches, which however may fail when only poorly diffracting derivative crystals are available, as often the case for e.g. membrane proteins. Here we present an approach for heavy atom site identification based on a Molecular Replacement Parameter Matrix (MRPM) search. It involves an n-dimensional search to test a wide spectrum of molecular replacement parameters, such as clusters of different conformations. The result is scored by the ability to identify heavy-atom positions, from anomalous difference Fourier maps, that allow meaningful phases to be determined. The strategy was successfully applied in the determination of a membrane protein structure, the CopA Cu+-ATPase, when other methods had failed to resolve the heavy atom substructure. MRPM is particularly suited for proteins undergoing large conformational changes where multiple search models should be generated, and it enables the identification of weak but correct molecular replacement solutions with maximum contrast to prime experimental phasing efforts.",
keywords = "q-bio.BM",
author = "Pedersen, {Bj{\o}rn Panyella} and Gourdon, {Pontus Emanuel} and Xiangyu Liu and Karlsen, {Jesper Lykkegaard} and Poul Nissen",
year = "2014",
month = mar,
day = "28",
language = "English",
pages = "1--19",
journal = "Journal of Communications and Networks",
issn = "1229-2370",
publisher = "Cornell University Library",

}

RIS

TY - JOUR

T1 - Initiating Heavy-atom Based Phasing by Multi-Dimensional Molecular Replacement

AU - Pedersen, Bjørn Panyella

AU - Gourdon, Pontus Emanuel

AU - Liu, Xiangyu

AU - Karlsen, Jesper Lykkegaard

AU - Nissen, Poul

PY - 2014/3/28

Y1 - 2014/3/28

N2 - To obtain an electron-density map from a macromolecular crystal the phase-problem needs to be solved, which often involves the use of heavy-atom derivative crystals and concomitantly the determination of the heavy atom substructure. This is customarily done by direct methods or Patterson-based approaches, which however may fail when only poorly diffracting derivative crystals are available, as often the case for e.g. membrane proteins. Here we present an approach for heavy atom site identification based on a Molecular Replacement Parameter Matrix (MRPM) search. It involves an n-dimensional search to test a wide spectrum of molecular replacement parameters, such as clusters of different conformations. The result is scored by the ability to identify heavy-atom positions, from anomalous difference Fourier maps, that allow meaningful phases to be determined. The strategy was successfully applied in the determination of a membrane protein structure, the CopA Cu+-ATPase, when other methods had failed to resolve the heavy atom substructure. MRPM is particularly suited for proteins undergoing large conformational changes where multiple search models should be generated, and it enables the identification of weak but correct molecular replacement solutions with maximum contrast to prime experimental phasing efforts.

AB - To obtain an electron-density map from a macromolecular crystal the phase-problem needs to be solved, which often involves the use of heavy-atom derivative crystals and concomitantly the determination of the heavy atom substructure. This is customarily done by direct methods or Patterson-based approaches, which however may fail when only poorly diffracting derivative crystals are available, as often the case for e.g. membrane proteins. Here we present an approach for heavy atom site identification based on a Molecular Replacement Parameter Matrix (MRPM) search. It involves an n-dimensional search to test a wide spectrum of molecular replacement parameters, such as clusters of different conformations. The result is scored by the ability to identify heavy-atom positions, from anomalous difference Fourier maps, that allow meaningful phases to be determined. The strategy was successfully applied in the determination of a membrane protein structure, the CopA Cu+-ATPase, when other methods had failed to resolve the heavy atom substructure. MRPM is particularly suited for proteins undergoing large conformational changes where multiple search models should be generated, and it enables the identification of weak but correct molecular replacement solutions with maximum contrast to prime experimental phasing efforts.

KW - q-bio.BM

M3 - Journal article

SP - 1

EP - 19

JO - Journal of Communications and Networks

JF - Journal of Communications and Networks

SN - 1229-2370

ER -

ID: 126104200