Structural Bioinformatics and Deep Learning of Metalloproteins: Recent Advances and Applications

Andreini, Claudia; Rosato, Antonio

doi:10.3390/ijms23147684

Cited by 8 publications

(6 citation statements)

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“…Aer this, for each metalloprotein, we retrieved the ChEMBL database to identify its active ligands. The following rules were utilized to lter the raw records: (1) the active ligands should be labeled with clear activity data (K i , K d or IC 50 ); (2) the molecular weight of the active ligands should be in the range from 200 to 800; (3) to guarantee the diversity of the active ligands, the total number of the identied active ligands for a protein should be greater than 100. Eventually, the independent test dataset contains about 25 000 active ligands toward 22 metalloproteins.…”

Section: Construction Of Benchmark Datasetsmentioning

confidence: 99%

“…As for the catalytic role, some metal ions located in the active sites of enzymes can facilitate catalysis. Additionally, it has been reported that at least 40% of enzymes require metal ions for their bioactivities, 3 and such enzymes can be categorized as metalloenzymes. [4][5][6] The extensive effects of metal ions have made metalloproteins widely involved in a wide variety of biological processes (such as enzymatic catalysis and signal transcription) and pathologies (such as cancer and inammation).…”

Section: Introductionmentioning

confidence: 99%

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MetalProGNet: a structure-based deep graph model for metalloprotein–ligand interaction predictions

Jiang

Hsieh

et al. 2023

Chem. Sci.

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Section: Construction Of Benchmark Datasetsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

MetalProGNet: a structure-based deep graph model for metalloprotein–ligand interaction predictions

Jiang

Hsieh

et al. 2023

Chem. Sci.

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“…13 Moreover, it is estimated that at least 40% of all enzymes need metal ions for their bioactivities. 14 Despite their relevance and potential as targets, the search for highaffinity ligands targeting metalloproteins has been delayed. 15 Concerning, docking programs, only a few of them, such as GPDOCK, 16 FlexX, 17 AutoDockZn, 18 MpsDockZn, 19 and GM-DockZn, 20 are specially developed for metalloproteins, and most of them are predominantly specific for zinc metalloproteins.…”

Section: Introductionmentioning

confidence: 99%

“…Metalloproteins, which refer to proteins with at least one metal ion in their structure, comprise close to half of the human proteome and perform structural, regulatory, and catalytic functions . Moreover, it is estimated that at least 40% of all enzymes need metal ions for their bioactivities . Despite their relevance and potential as targets, the search for high-affinity ligands targeting metalloproteins has been delayed .…”

Section: Introductionmentioning

confidence: 99%

Unlocking Precision Docking for Metalloproteins

Clemente,

Prieto,

Martí

2024

J. Chem. Inf. Model.

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Metalloproteins play a fundamental role in molecular biology, contributing to various biological processes. However, the discovery of highaffinity ligands targeting metalloproteins has been delayed due, in part, to a lack of suitable tools and data. Molecular docking, a widely used technique for virtual screening of small-molecule ligand interactions with proteins, often faces challenges when applied to metalloproteins due to the particular nature of the ligand metal bond. To address these limitations associated with docking metalloproteins, we introduce a knowledge-driven docking approach known as "metalloprotein bias docking" (MBD), which extends the AutoDock Bias technique. We assembled a comprehensive data set of metalloprotein−ligand complexes from 15 different metalloprotein families, encompassing Ca, Co, Fe, Mg, Mn, and Zn metal ions. Subsequently, we conducted a performance analysis of our MBD method and compared it to the conventional docking (CD) program AutoDock4, applied to various metalloprotein targets within our data set. Our results demonstrate that MBD outperforms CD, significantly enhancing accuracy, selectivity, and precision in ligand pose prediction. Additionally, we observed a positive correlation between our predicted ligand free energies and the corresponding experimental values. These findings underscore the potential of MBD as a valuable tool for the effective exploration of metalloprotein−ligand interactions.

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“…Numerous databases exist that address MPs either in general or some specific aspects of their chemistry and biology (Zhang & Zheng, 2020;Andreini & Rosato, 2022). Of particular relevance for this work are MetalPDB (Andreini et al, 2013;Putignano et al, 2018) and MESPEUS (Lin et al, 2024;Hsin et al, 2008), both of which address the structural and functional properties of all metal-binding sites present in the PDB.…”

Section: Introductionmentioning

confidence: 99%

A database overview of metal-coordination distances in metalloproteins

Bazayeva,

Andreini,

Rosato

2024

Acta Cryst Sect D Struct Biol

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Metalloproteins are ubiquitous in all living organisms and take part in a very wide range of biological processes. For this reason, their experimental characterization is crucial to obtain improved knowledge of their structure and biological functions. The three-dimensional structure represents highly relevant information since it provides insight into the interaction between the metal ion(s) and the protein fold. Such interactions determine the chemical reactivity of the bound metal. The available PDB structures can contain errors due to experimental factors such as poor resolution and radiation damage. A lack of use of distance restraints during the refinement and validation process also impacts the structure quality. Here, the aim was to obtain a thorough overview of the distribution of the distances between metal ions and their donor atoms through the statistical analysis of a data set based on more than 115 000 metal-binding sites in proteins. This analysis not only produced reference data that can be used by experimentalists to support the structure-determination process, for example as refinement restraints, but also resulted in an improved insight into how protein coordination occurs for different metals and the nature of their binding interactions. In particular, the features of carboxylate coordination were inspected, which is the only type of interaction that is commonly present for nearly all metals.

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Structural Bioinformatics and Deep Learning of Metalloproteins: Recent Advances and Applications

Cited by 8 publications

References 98 publications

MetalProGNet: a structure-based deep graph model for metalloprotein–ligand interaction predictions

MetalProGNet: a structure-based deep graph model for metalloprotein–ligand interaction predictions

Unlocking Precision Docking for Metalloproteins

A database overview of metal-coordination distances in metalloproteins

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