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Efficient Algorithms to Explore Conformation Spaces of Flexible Protein Loops | IEEE Journals & Magazine | IEEE Xplore
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Journals & Magazines >IEEE/ACM Transactions on Comp... >Volume: 5 Issue: 4

Efficient Algorithms to Explore Conformation Spaces of Flexible Protein Loops

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Peggy Yao; Ankur Dhanik; Nathan Marz; Ryan Propper; Charles Kou; Guanfeng Liu
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Abstract:

Several applications in biology - e.g., incorporation of protein flexibility in ligand docking algorithms, interpretation of fuzzy X-ray crystallographic data, and homolo...Show More

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Abstract:

Several applications in biology - e.g., incorporation of protein flexibility in ligand docking algorithms, interpretation of fuzzy X-ray crystallographic data, and homology modeling - require computing the internal parameters of a flexible fragment (usually, a loop) of a protein in order to connect its termini to the rest of the protein without causing any steric clash. One must often sample many such conformations in order to explore and adequately represent the conformational range of the studied loop. While sampling must be fast, it is made difficult by the fact that two conflicting constraints - kinematic closure and clash avoidance - must be satisfied concurrently. This paper describes two efficient and complementary sampling algorithms to explore the space of closed clash-free conformations of a flexible protein loop. The "seed sampling" algorithm samples broadly from this space, while the "deformation sampling" algorithm uses seed conformations as starting points to explore the conformation space around them at a finer grain. Computational results are presented for various loops ranging from 5 to 25 residues. More specific results also show that the combination of the sampling algorithms with a functional site prediction software (FEATURE) makes it possible to compute and recognize calcium-binding loop conformations. The sampling algorithms are implemented in a toolkit (LoopTK), which is available at https://simtk.org/home/looptk.
Published in: IEEE/ACM Transactions on Computational Biology and Bioinformatics ( Volume: 5, Issue: 4, Oct.-Dec. 2008)
Page(s): 534 - 545
Date of Publication: 31 December 2008

ISSN Information:

PubMed ID: 18989041
DOI: 10.1109/TCBB.2008.96
Citations are not available for this document.
Contents

1 Introduction

Several applications in biology require exploring the conformation space of a flexible fragment (usually, a loop) of a protein. For example, upon binding with a small ligand, a fragment may undergo deformations to rearrange nonlocal contacts [23]. Incorporating such flexibility in docking algorithms is a major challenge [26]. In X-ray crystallography experiments, electron density maps (EDMs) often contain noisy regions caused by disorder in the crystalline sample, resulting in an initial model with missing fragments between resolved termini [28]. Similarly, in homology modeling [24], only parts of a protein structure can be reliably inferred from known structures with similar sequences. These applications share a common subproblem: to compute closed, clash-free conformations of an inner fragment of a protein chain. These conformations lie in a complex subset of the fragment's conformation space.

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