Ranking Enzyme Structures in the PDB by Bound Ligand Similarity to Biological Substrates

Tyzack, Jonathan D.; Fernando, Laurent; Ribeiro, António J. M.; Borkakoti, Neera; Thornton, Janet M.

doi:10.1016/j.str.2018.02.009

Cited by 25 publications

(34 citation statements)

References 43 publications

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“…Interestingly, these considerations are, to some extent, in line with those reported in recent papers by Tyzack J.D. et al and Das S. et al, in which the authors compared ligand-enzyme complexes from the PDB on the basis of the similarity of the bound ligands and discussed on how such results could be used to select the most relevant complexes for structure-based drug design [41,42]. Nevertheless, the selection of the most suitable protein conformations on the basis of the similarity of the co-crystallized ligands obviously presents some limitations.…”

Section: Ligand-based Approaches In Protein Conformation Selectionsupporting

confidence: 81%

Selection of protein conformations for structure-based polypharmacology studies

Pinzi

Caporuscio

Rastelli

2018

Drug Discovery Today

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Several drugs exert their therapeutic effect through the modulation of multiple targets. Structure-based approaches hold great promise for identifying compounds with the desired polypharmacological profiles. These methods use knowledge of the protein binding sites to identify stereoelectronically complementary ligands. The selection of the most suitable protein conformations to be used in the design process is vital, especially for multitarget drug design in which the same ligand has to be accommodated in multiple binding pockets. Herein, we focus on currently available techniques for the selection of the most suitable protein conformations for multitarget drug design, compare the potential advantages and limitations of each method, and comment on how their combination could help in polypharmacology drug design.

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Section: Ligand-based Approaches In Protein Conformation Selectionsupporting

confidence: 81%

Selection of protein conformations for structure-based polypharmacology studies

Pinzi

Caporuscio

Rastelli

2018

Drug Discovery Today

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“…Small molecules that are structurally similar to the cofactor template molecules (Supplementary Table S3) are identified. A chemical structure similarity score is calculated using RDKit-based similarity-searching methods PARITY (Tyzack et al ., 2018) and SiteBinder (Sehnal et al ., 2012). Small molecules with a similarity score above a predefined cut-off specified for a particular cofactor class are tentatively selected for further manual inspection for appropriate structural equivalence with the template molecule (Supplementary Table S3) and are added to the list of small molecules in the corresponding cofactor classes.An automatic process obtains a list of PDB entries containing newly identified cofactor-like small molecule and enzymes associated with the corresponding cofactor classes.…”

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

“…Relying on the knowledge of reactions catalysed by these enzymes, the classification of cofactors into 27 classes in the CoFactor database (Fischer et al. , 2010) and a new method to measure molecular similarity (Tyzack et al ., 2018), we have developed a protocol to identify cofactors and cofactor-like molecules in cofactor-dependent enzymes.…”

Section: Introductionmentioning

confidence: 99%

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Finding enzyme cofactors in Protein Data Bank

et al. 2019

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Motivation Cofactors are essential for many enzyme reactions. The Protein Data Bank (PDB) contains >67 000 entries containing enzyme structures, many with bound cofactor or cofactor-like molecules. This work aims to identify and categorize these small molecules in the PDB and make it easier to find them. Results The Protein Data Bank in Europe (PDBe; pdbe.org) has implemented a pipeline to identify enzyme cofactor and cofactor-like molecules, which are now part of the PDBe weekly release process. Availability and implementation Information is made available on the individual PDBe entry pages at pdbe.org and programmatically through the PDBe REST API (pdbe.org/api). Supplementary information Supplementary data are available at Bioinformatics online.

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“…cognate and non-cognate) and (ii) differences in the characteristics of ligand binding between enzymes and nonenzymatic proteins. For example, it is known that non-cognate ligands can bind to different regions in a protein to those bound by the cognate ligands, reflecting different binding characteristics (Tyzack, Fernando, Ribeiro, Borkakoti, & Thornton, 2018). Figure 3d shows the performance of the LIG predictors on the LIG hold-out test set compared to the ConCavity ligand-binding site prediction method.…”

Section: Funsite-ligmentioning

confidence: 99%

CATH functional families predict protein functional sites

Das

Scholes

Orengo

2020

Preprint

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Motivation: Identification of functional sites in proteins is essential for functional characterisation, variant interpretation and drug design. Several methods are available for predicting either a generic functional site, or specific types of functional site. Here, we present FunSite, a machine learning predictor that identifies catalytic, ligand-binding and protein-protein interaction functional sites using features derived from protein sequence and structure, and evolutionary data from CATH functional families (Fun-Fams). Results: FunSite's prediction performance was rigorously benchmarked using cross-validation and a holdout dataset. FunSite outperformed all publicly-available functional site prediction methods. We show that conserved residues in FunFams are enriched in functional sites. We found FunSite's performance depends greatly on the quality of functional site annotations and the information content of FunFams in the training data. Finally, we analyse which structural and evolutionary features are most predictive for functional sites. Availability: The datasets and prediction models are available on request. Contact

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Ranking Enzyme Structures in the PDB by Bound Ligand Similarity to Biological Substrates

Cited by 25 publications

References 43 publications

Selection of protein conformations for structure-based polypharmacology studies

Selection of protein conformations for structure-based polypharmacology studies

Finding enzyme cofactors in Protein Data Bank

CATH functional families predict protein functional sites

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