Modeling Protein Loops Using a Phi I + 1, Psi I Dimer Database

Overview

Journal Protein Sci

Specialty Biochemistry

Date 1995 Jul 1

PMID 7670382

Citations 14

Authors

S Sudarsanam

R F DuBose

C J March

S Srinivasan

Affiliations

Soon will be listed here.

Abstract

We present an automated method for modeling backbones of protein loops. The method samples a database of phi i + 1 and psi i angles constructed from a nonredundant version of the Protein Data Bank (PDB). The dihedral angles phi i + 1 and psi i completely define the backbone conformation of a dimer when standard bond lengths, bond angles, and a trans planar peptide configuration are used. For the 400 possible dimers resulting from 20 natural amino acids, a list of allowed phi i + 1, psi i pairs for each dimer is created by pooling all such pairs from the loop segments of each protein in the nonredundant version of the PDB. Starting from the N-terminus of the loop sequence, conformations are generated by assigning randomly selected pairs of phi i + 1, psi i for each dimer from the respective pool using standard bond lengths, bond angles, and a trans peptide configuration. We use this database to simulate protein loops of lengths varying from 5 to 11 amino acids in five proteins of known three-dimensional structures. Typically, 10,000-50,000 models are simulated for each protein loop and are evaluated for stereochemical consistency. Depending on the length and sequence of a given loop, 50-80% of the models generated have no stereochemical strain in the backbone atoms. We demonstrate that, when simulated loops are extended to include flanking residues from homologous segments, only very few loops from an ensemble of sterically allowed conformations orient the flanking segments consistent with the protein topology. The presence of near-native backbone conformations for loops from five different proteins suggests the completeness of the dimeric database for use in modeling loops of homologous proteins. Here, we take advantage of this observation to design a method that filters near-native loop conformations from an ensemble of sterically allowed conformations. We demonstrate that our method eliminates the need for a loop-closure algorithm and hence allows for the use of topological constraints of the homologous proteins or disulfide constraints to filter near-native loop conformations.

Citing Articles

MOLS sampling and its applications in structural biophysics.

Ramya L, Nehru Viji S, Arun Prasad P, Kanagasabai V, Gautham N Biophys Rev. 2017; 2(4):169-179.

PMID: 28510038 PMC: 5425679. DOI: 10.1007/s12551-010-0039-y.

Generation of a flexible loop structural ensemble and its application to induced-fit structural changes following ligand binding.

Watanabe Y, Fukunishi Y, Nakamura H Biophysics (Nagoya-shi). 2016; 2:1-12.

PMID: 27857555 PMC: 5036648. DOI: 10.2142/biophysics.2.1.

The importance of slow motions for protein functional loops.

Skliros A, Zimmermann M, Chakraborty D, Saraswathi S, Katebi A, Leelananda S Phys Biol. 2012; 9(1):014001.

PMID: 22314977 PMC: 3783528. DOI: 10.1088/1478-3975/9/1/014001.

Protein loop closure using orientational restraints from NMR data.

Tripathy C, Zeng J, Zhou P, Donald B Proteins. 2011; 80(2):433-53.

PMID: 22161780 PMC: 3305838. DOI: 10.1002/prot.23207.

Near-native protein loop sampling using nonparametric density estimation accommodating sparcity.

Joo H, Chavan A, Day R, Lennox K, Sukhanov P, Dahl D PLoS Comput Biol. 2011; 7(10):e1002234.

PMID: 22028638 PMC: 3197639. DOI: 10.1371/journal.pcbi.1002234.

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