Assessing protein-ligand docking for the binding of organometallic compounds to proteins

Organometallic compounds are increasingly used as molecular scaffolds in drug development projects; their structural and electronic properties offering novel opportunities in protein–ligand complementarities. Interestingly, while protein–ligand dockings have long become a spearhead in computer assis...

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Veröffentlicht in:	Journal of computational chemistry 2014-01, Vol.35 (3), p.192-198
Hauptverfasser:	Ortega-Carrasco, Elisabeth, Lledos, Agusti, Marechal, Jean-Didier
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Benchmarks Binding Sites computational bioinorganics Computer Simulation Computer-Aided Design Crystallography, X-Ray Databases, Protein Design optimization Drug Design Enzyme Inhibitors - chemistry Humans kinase inhibition Kinetics Ligands metalodrugs Models, Molecular Molecular Docking Simulation Organic chemicals Organometallic Compounds - chemistry Protein Binding Protein Conformation Protein Kinases - chemistry protein-ligand dockings Proteins R&D Research & development Software Thermodynamics Trypsin - chemistry
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container_title	Journal of computational chemistry
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creator	Ortega-Carrasco, Elisabeth Lledos, Agusti Marechal, Jean-Didier
description	Organometallic compounds are increasingly used as molecular scaffolds in drug development projects; their structural and electronic properties offering novel opportunities in protein–ligand complementarities. Interestingly, while protein–ligand dockings have long become a spearhead in computer assisted drug design, no benchmarking nor optimization have been done for their use with organometallic compounds. Pursuing our efforts to model metal mediated recognition processes, we herein present a systematic study of the capabilities of the program GOLD to predict the interactions of protein with organometallic compounds. The study focuses on inert systems for which no alteration of the first coordination sphere of the metal occurs upon binding. Several scaffolds are used as test systems with different docking schemes and scoring functions. We conclude that ChemScore is the most robust scoring function with ASP and ChemPLP providing with good results too and GoldScore slightly underperforming. This study shows that current state‐of‐the‐art protein‐ligand docking techniques are reliable for the docking of inert organometallic compounds binding to protein. © 2013 Wiley Periodicals, Inc. Organometallic compounds are increasingly used as molecular scaffolds in drug development projects. In this study, the predictiveness of protein–ligand docking programs for the binding of inert organometallic scaffolds with protein receptors is investigated. Using the software GOLD as an illustrative case, scoring functions, preprocessing calculations, and flexibility schemes are tested. The work shows that actual methodologies are efficient for such systems without requiring major improvements.
doi_str_mv	10.1002/jcc.23472
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Interestingly, while protein–ligand dockings have long become a spearhead in computer assisted drug design, no benchmarking nor optimization have been done for their use with organometallic compounds. Pursuing our efforts to model metal mediated recognition processes, we herein present a systematic study of the capabilities of the program GOLD to predict the interactions of protein with organometallic compounds. The study focuses on inert systems for which no alteration of the first coordination sphere of the metal occurs upon binding. Several scaffolds are used as test systems with different docking schemes and scoring functions. We conclude that ChemScore is the most robust scoring function with ASP and ChemPLP providing with good results too and GoldScore slightly underperforming. This study shows that current state‐of‐the‐art protein‐ligand docking techniques are reliable for the docking of inert organometallic compounds binding to protein. © 2013 Wiley Periodicals, Inc. Organometallic compounds are increasingly used as molecular scaffolds in drug development projects. In this study, the predictiveness of protein–ligand docking programs for the binding of inert organometallic scaffolds with protein receptors is investigated. Using the software GOLD as an illustrative case, scoring functions, preprocessing calculations, and flexibility schemes are tested. 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Comput. Chem</addtitle><description>Organometallic compounds are increasingly used as molecular scaffolds in drug development projects; their structural and electronic properties offering novel opportunities in protein–ligand complementarities. Interestingly, while protein–ligand dockings have long become a spearhead in computer assisted drug design, no benchmarking nor optimization have been done for their use with organometallic compounds. Pursuing our efforts to model metal mediated recognition processes, we herein present a systematic study of the capabilities of the program GOLD to predict the interactions of protein with organometallic compounds. The study focuses on inert systems for which no alteration of the first coordination sphere of the metal occurs upon binding. Several scaffolds are used as test systems with different docking schemes and scoring functions. We conclude that ChemScore is the most robust scoring function with ASP and ChemPLP providing with good results too and GoldScore slightly underperforming. This study shows that current state‐of‐the‐art protein‐ligand docking techniques are reliable for the docking of inert organometallic compounds binding to protein. © 2013 Wiley Periodicals, Inc. Organometallic compounds are increasingly used as molecular scaffolds in drug development projects. In this study, the predictiveness of protein–ligand docking programs for the binding of inert organometallic scaffolds with protein receptors is investigated. Using the software GOLD as an illustrative case, scoring functions, preprocessing calculations, and flexibility schemes are tested. 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subjects	Algorithms Benchmarks Binding Sites computational bioinorganics Computer Simulation Computer-Aided Design Crystallography, X-Ray Databases, Protein Design optimization Drug Design Enzyme Inhibitors - chemistry Humans kinase inhibition Kinetics Ligands metalodrugs Models, Molecular Molecular Docking Simulation Organic chemicals Organometallic Compounds - chemistry Protein Binding Protein Conformation Protein Kinases - chemistry protein-ligand dockings Proteins R&D Research & development Software Thermodynamics Trypsin - chemistry
title	Assessing protein-ligand docking for the binding of organometallic compounds to proteins
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