Helix-bundle membrane protein fold templates

JAMES U. BOWIE

doi:10.1110/ps.8.12.2711

Abstract

In the fold recognition approach to structure prediction, a sequence is tested for compatibility with an already known fold. For membrane proteins, however, few folds have been determined experimentally. Here the feasibility of computing the vast majority of likely membrane protein folds is tested. The results indicate that conformation space can be effectively sampled for small numbers of helices. The vast majority of potential monomeric membrane protein structures can be represented by about 30-folds for three helices, but increases exponentially to about 1,500,000 folds for seven helices. The generated folds could serve as templates for fold recognition or as starting points for conformational searches that are well distributed throughout conformation space.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Schulz, Georg E 2000. β-Barrel membrane proteins. Current Opinion in Structural Biology, Vol. 10, Issue. 4, p. 443.

Hirokawa, Takatsugu Uechi, Junichi Sasamoto, Hiroyuki Suwa, Makiko and Mitaku, Shigeki 2000. A triangle lattice model that predicts transmembrane helix configuration using a polar jigsaw puzzle. Protein Engineering, Design and Selection, Vol. 13, Issue. 11, p. 771.

Taylor, William R May, Alex C W Brown, Nigel P and Aszódi, András 2001. Protein structure: geometry, topology and classification. Reports on Progress in Physics, Vol. 64, Issue. 4, p. 517.

Kessel, Amit and Ben-Tal, Nir 2002. Peptide-Lipid Interactions. Vol. 52, Issue. , p. 205.

Liang, Jie 2002. Experimental and computational studies of determinants of membrane-protein folding. Current Opinion in Chemical Biology, Vol. 6, Issue. 6, p. 878.

Hiramoto, Takeshi Nemoto, Wataru Kikuchi, Takeshi and Fujita, Norihisa 2002. Construction of Hypothetical Three-Dimensional Structure of P2Y1 Receptor Based on Fourier Transform Analysis. Journal of Protein Chemistry, Vol. 21, Issue. 8, p. 537.

Dobbs, H. Orlandini, E. Bonaccini, R. and Seno, F. 2002. Optimal potentials for predicting inter‐helical packing in transmembrane proteins. Proteins: Structure, Function, and Bioinformatics, Vol. 49, Issue. 3, p. 342.

Schulz, Georg E. 2002. The structure of bacterial outer membrane proteins. Biochimica et Biophysica Acta (BBA) - Biomembranes, Vol. 1565, Issue. 2, p. 308.

Schulz, Georg E 2003. Membrane Proteins. Vol. 63, Issue. , p. 47.

Faulon, Jean‐Loup Sale, Ken and Young, Malin 2003. Exploring the conformational space of membrane protein folds matching distance constraints. Protein Science, Vol. 12, Issue. 8, p. 1750.

Kim, Sanguk Chamberlain, Aaron K. and Bowie, James U. 2003. A Simple Method for Modeling Transmembrane Helix Oligomers. Journal of Molecular Biology, Vol. 329, Issue. 4, p. 831.

White, Stephen H. 2003. Translocons, thermodynamics, and the folding of membrane proteins. FEBS Letters, Vol. 555, Issue. 1, p. 116.

Gray, Genetha Anne Kolda, Tamara G. Sale, Ken and Young, Malin M. 2004. Optimizing an Empirical Scoring Function for Transmembrane Protein Structure Determination. INFORMS Journal on Computing, Vol. 16, Issue. 4, p. 406.

Sale, Ken Faulon, Jean‐Loup Gray, Genetha A. Schoeniger, Joseph S. and Young, Malin M. 2004. Optimal bundling of transmembrane helices using sparse distance constraints. Protein Science, Vol. 13, Issue. 10, p. 2613.

2004. Protein Geometry, Classification, Topology and Symmetry. Vol. 20042949, Issue. ,

Brown, W. Michael Faulon, Jean-Loup and Sale, Ken 2005. A deterministic algorithm for constrained enumeration of transmembrane protein folds. Computational Biology and Chemistry, Vol. 29, Issue. 2, p. 143.

Tu, Liyu Kong, Xiang-Peng Sun, Tung-Tien and Kreibich, Gert 2006. Integrity of all four transmembrane domains of the tetraspanin uroplakin Ib is required for its exit from the ER. Journal of Cell Science, Vol. 119, Issue. 24, p. 5077.

Hildebrand, Peter Werner Lorenzen, Stephan Goede, Andrean and Preissner, Robert 2006. Analysis and prediction of helix–helix interactions in membrane channels and transporters. Proteins: Structure, Function, and Bioinformatics, Vol. 64, Issue. 1, p. 253.

Martin‐Galiano, Antonio J. and Frishman, Dmitrij 2006. Defining the fold space of membrane proteins: The CAMPS database. Proteins: Structure, Function, and Bioinformatics, Vol. 64, Issue. 4, p. 906.

Speers, Anna E. and Wu, Christine C. 2007. Proteomics of Integral Membrane ProteinsTheory and Application. Chemical Reviews, Vol. 107, Issue. 8, p. 3687.

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Helix-bundle membrane protein fold templates

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