patGPCR: A Multitemplate Approach for Improving 3D Structure Prediction of Transmembrane Helices of G-Protein-Coupled Receptors

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Abstract

The structures of the seven transmembrane helices of G-protein-coupled receptors are critically involved in many aspects of these receptors, such as receptor stability, ligand docking, and molecular function. Most of the previous multitemplate approaches have built a “super” template with very little merging of aligned fragments from different templates. Here, we present a parallelized multitemplate approach, patGPCR, to predict the 3D structures of transmembrane helices of G-protein-coupled receptors. patGPCR, which employs a bundle-packing related energy function that extends on the RosettaMem energy, parallelizes eight pipelines for transmembrane helix refinement and exchanges the optimized helix structures from multiple templates. We have investigated the performance of patGPCR on a test set containing eight determined G-protein-coupled receptors. The results indicate that patGPCR improves the TM RMSD of the predicted models by 33.64% on average against a single-template method. Compared with other homology approaches, the best models for five of the eight targets built by patGPCR had a lower TM RMSD than that obtained from SWISS-MODEL; patGPCR also showed lower average TM RMSD than single-template and multiple-template MODELLER.

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Most cited references 38

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High-resolution crystal structure of an engineered human beta2-adrenergic G protein-coupled receptor.

Vadim Cherezov, Daniel M Rosenbaum, Michael A Hanson … (2007)

Heterotrimeric guanine nucleotide-binding protein (G protein)-coupled receptors constitute the largest family of eukaryotic signal transduction proteins that communicate across the membrane. We report the crystal structure of a human beta2-adrenergic receptor-T4 lysozyme fusion protein bound to the partial inverse agonist carazolol at 2.4 angstrom resolution. The structure provides a high-resolution view of a human G protein-coupled receptor bound to a diffusible ligand. Ligand-binding site accessibility is enabled by the second extracellular loop, which is held out of the binding cavity by a pair of closely spaced disulfide bridges and a short helical segment within the loop. Cholesterol, a necessary component for crystallization, mediates an intriguing parallel association of receptor molecules in the crystal lattice. Although the location of carazolol in the beta2-adrenergic receptor is very similar to that of retinal in rhodopsin, structural differences in the ligand-binding site and other regions highlight the challenges in using rhodopsin as a template model for this large receptor family.

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Protein structure homology modeling using SWISS-MODEL workspace.

Lorenza Bordoli, Florian Kiefer, Konstantin Arnold … (2009)

Homology modeling aims to build three-dimensional protein structure models using experimentally determined structures of related family members as templates. SWISS-MODEL workspace is an integrated Web-based modeling expert system. For a given target protein, a library of experimental protein structures is searched to identify suitable templates. On the basis of a sequence alignment between the target protein and the template structure, a three-dimensional model for the target protein is generated. Model quality assessment tools are used to estimate the reliability of the resulting models. Homology modeling is currently the most accurate computational method to generate reliable structural models and is routinely used in many biological applications. Typically, the computational effort for a modeling project is less than 2 h. However, this does not include the time required for visualization and interpretation of the model, which may vary depending on personal experience working with protein structures.

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Three-dimensional structures of membrane proteins from genomic sequencing.

Thomas A Hopf, Lucy Colwell, Robert Sheridan … (2012)

We show that amino acid covariation in proteins, extracted from the evolutionary sequence record, can be used to fold transmembrane proteins. We use this technique to predict previously unknown 3D structures for 11 transmembrane proteins (with up to 14 helices) from their sequences alone. The prediction method (EVfold_membrane) applies a maximum entropy approach to infer evolutionary covariation in pairs of sequence positions within a protein family and then generates all-atom models with the derived pairwise distance constraints. We benchmark the approach with blinded de novo computation of known transmembrane protein structures from 23 families, demonstrating unprecedented accuracy of the method for large transmembrane proteins. We show how the method can predict oligomerization, functional sites, and conformational changes in transmembrane proteins. With the rapid rise in large-scale sequencing, more accurate and more comprehensive information on evolutionary constraints can be decoded from genetic variation, greatly expanding the repertoire of transmembrane proteins amenable to modeling by this method. Copyright © 2012 Elsevier Inc. All rights reserved.

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Author and article information

Journal

Journal ID (nlm-ta): Comput Math Methods Med

Journal ID (iso-abbrev): Comput Math Methods Med

Journal ID (publisher-id): CMMM

Title: Computational and Mathematical Methods in Medicine

Publisher: Hindawi Publishing Corporation

ISSN (Print): 1748-670X

ISSN (Electronic): 1748-6718

Publication date (Print): 2013

Publication date (Electronic): 11 March 2013

Volume: 2013

Electronic Location Identifier: 486125

Affiliations

¹School of Computer Science and Technology, Soochow University, Suzhou 215006, China

²Jiangsu Provincial Key Lab for Information Processing Technologies, Suzhou 215006, China

³School of Electronic and Information Engineering, Suzhou University of Science and Technology, Suzhou 215009, China

Author notes

*Qiang Lü: qiang@ 123456suda.edu.cn

Academic Editor: Hong-Bin Shen

Article

DOI: 10.1155/2013/486125

PMC ID: 3608176

PubMed ID: 23554839

SO-VID: a69a0a1c-444e-4cc2-834d-f1ceb0056f99

License:

This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

History

Date received : 5 November 2012

Date revision received : 10 January 2013

Date accepted : 16 January 2013

patGPCR: A Multitemplate Approach for Improving 3D Structure Prediction of Transmembrane Helices of G-Protein-Coupled Receptors

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Most cited references 38

High-resolution crystal structure of an engineered human beta2-adrenergic G protein-coupled receptor.

Protein structure homology modeling using SWISS-MODEL workspace.

Three-dimensional structures of membrane proteins from genomic sequencing.

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