P. Arun Prasad scite author profile

P. Arun Prasad

5Publications

61Citation Statements Received

221Citation Statements Given

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University of Madras

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A new peptide docking strategy using a mean field technique with mutually orthogonal Latin square sampling

Prasad

Gautham

2008

J Comput Aided Mol Des

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The theoretical prediction of the association of a flexible ligand with a protein receptor requires efficient sampling of the conformational space of the ligand. Several docking methodologies are currently available. We propose a new docking technique that performs well at low computational cost. The method uses mutually orthogonal Latin squares to efficiently sample the docking space. A variant of the mean field technique is used to analyze this sample to arrive at the optimum. The method has been previously applied to explore the conformational space of peptides and identify structures with low values for the potential energy. Here we extend this method to simultaneously identify both the low energy conformation as well as a 'high-scoring' docking mode. Application of the method to 56 protein-peptide complexes, in which the length of the peptide ligand ranges from three to seven residues, and comparisons with Autodock 3.05, showed that the method works well.

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Protein−Ligand Docking Using Mutually Orthogonal Latin Squares (MOLSDOCK)

Viji

Prasad

Gautham

2009

J. Chem. Inf. Model.

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The theoretical prediction of the association of a flexible ligand with a protein receptor requires efficient sampling of the conformational space of the ligand. Several docking methodologies are currently available. We have proposed a docking technique that performs well at low computational cost. The method uses mutually orthogonal Latin squares to efficiently sample the docking space. A variant of the mean field technique is used to analyze this sample to arrive at the optimum. The method has been previously applied to search through both the conformational space of a peptide as well its docking space. Here we extend this method to simultaneously identify both the low energy conformation as well as a high scoring docking mode for the small organic ligand molecules. Application of the method to 45 protein-ligand complexes, in which the number of rotatable torsions varies from 2 to 19, and comparisons with AutoDock 4.0, showed that the method works well.

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Exploring the conformational space of protein loops using a mean field technique with MOLS sampling

et al. 2007

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We have recently developed a computational technique that uses mutually orthogonal Latin square sampling to explore the conformational space of oligopeptides in an exhaustive manner. In this article, we report its use to analyze the conformational spaces of 120 protein loop sequences in proteins, culled from the PDB, having the length ranging from 5 to 10 residues. The force field used did not have any information regarding the sequences or structures that flanked the loop. The results of the analyses show that the native structure of the loop, as found in the PDB falls at one of the low energy points in the conformational landscape of the sequences. Thus, a large portion of the structural determinants of the loop may be considered intrinsic to the sequence, regardless of either adjacent sequences or structures, or the interactions that the atoms of the loop make with other residues in the protein or in neighboring proteins.

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Exploring conformational space using a mean field technique with MOLS sampling

et al. 2007

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The computational identification of all the low energy structures of a peptide given only its sequence is not an easy task even for small peptides,due to the multiple-minima problem and combinatorial explosion. We have developed an algorithm, called the MOLS technique,that addresses this problem, and have applied it to a number of different aspects of the study of peptide and protein structure. Conformational studies of oligopeptides, including loop sequences in proteins have been carried out using this technique. In general the calculations identified all the folds determined by previous studies,and in addition picked up other energetically favorable structures. The method was also used to map the energy surface of the peptides. In another application, we have combined the MOLS technique, using it to generate a library of low energy structures of an oligopeptide, with a genetic algorithm to predict protein structures. The method has also been applied to explore the conformational space of loops in protein structures.Further, it has been applied to the problem of docking a ligand in its receptor site, with encouraging results.

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ChemInform Abstract: Protein—Ligand Docking Using Mutually Orthogonal Latin Squares (MOLSDOCK).

2010

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P. Arun Prasad

A new peptide docking strategy using a mean field technique with mutually orthogonal Latin square sampling

Protein−Ligand Docking Using Mutually Orthogonal Latin Squares (MOLSDOCK)

Exploring the conformational space of protein loops using a mean field technique with MOLS sampling

Exploring conformational space using a mean field technique with MOLS sampling

ChemInform Abstract: Protein—Ligand Docking Using Mutually Orthogonal Latin Squares (MOLSDOCK).

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