Learning to Identify Physiological and Adventitious Metal-Binding Sites in the Three-Dimensional Structures of Proteins by Following the Hints of a Deep Neural Network

Laveglia, Vincenzo; Giachetti, Andrea; Sala, Davide; Andreini, Claudia; Rosato, Antonio

doi:10.1021/acs.jcim.2c00522

Cited by 11 publications

(5 citation statements)

References 55 publications

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“…Discrimination of physiological and adventitious zinc-binding sites in MPs using a recurrent neural network (RNN) [98] Table 1 summarizes the resources and applications mentioned in this contribution, in the order in which they were described.…”

Section: Discussionmentioning

confidence: 99%

“…In a very recent application, our own research team developed a DL classifier that can discriminate physiological and adventitious zinc-binding sites in the 3D structures of MPs with an accuracy of about 90% [ 98 ]. In order to develop the tool, we trained a recurrent neural network (RNN) using a dataset of 1944 physiological and 3352 adventitious zinc-binding sites extracted from MetalPDB and manually annotated.…”

Section: Ai Methods Applied To Metalloproteinsmentioning

confidence: 99%

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

Andreini

Rosato

2022

IJMS

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All living organisms require metal ions for their energy production and metabolic and biosynthetic processes. Within cells, the metal ions involved in the formation of adducts interact with metabolites and macromolecules (proteins and nucleic acids). The proteins that require binding to one or more metal ions in order to be able to carry out their physiological function are called metalloproteins. About one third of all protein structures in the Protein Data Bank involve metalloproteins. Over the past few years there has been tremendous progress in the number of computational tools and techniques making use of 3D structural information to support the investigation of metalloproteins. This trend has been boosted by the successful applications of neural networks and machine/deep learning approaches in molecular and structural biology at large. In this review, we discuss recent advances in the development and availability of resources dealing with metalloproteins from a structure-based perspective. We start by addressing tools for the prediction of metal-binding sites (MBSs) using structural information on apo-proteins. Then, we provide an overview of the methods for and lessons learned from the structural comparison of MBSs in a fold-independent manner. We then move to describing databases of metalloprotein/MBS structures. Finally, we summarizing recent ML/DL applications enhancing the functional interpretation of metalloprotein structures.

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Section: Discussionmentioning

confidence: 99%

Section: Ai Methods Applied To Metalloproteinsmentioning

confidence: 99%

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

Andreini

Rosato

2022

IJMS

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“…Validation software such as PROCHECK 74 , MolProbity 75 , and Coot 76 and servers like CheckMyBlob 77 and CheckMyMetal 78 facilitate the automated assessment of structural parameters. Moreover, the biological context and functional relevance are crucial when analyzing protein structures 33,79-80 .…”

Section: Methodsmentioning

confidence: 99%

Prediction of Ca²⁺binding site in proteins with a fast and accurate method based on statistical mechanics and analysis of crystal structures

Basit,

Choudhury,

Bandyopadhyay

2024

Preprint

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Predicting the precise locations of metal binding sites within metalloproteins is a crucial challenge in biophysics. It is challenging for both experimental and computational approaches. In the current work, we have predicted the location of Ca2+ ions in calcium-binding proteins using a physics-based method with an all-atom description of the proteins, which is substantially faster than the molecular dynamics simulation-based methods with accuracy as good as data-driven approaches. Our methodology uses the three-dimensional reference interaction site model (3D-RISM), a statistical mechanical theory, to calculate Ca2+ ion density around protein structures. We have taken previously used datasets to assess the efficacy of our method as compared to previous works. Our accuracy is found to be 88%, comparable with the FEATURE program, one of the well-known data-driven methods. Moreover, our method being physical, the reasons for failures can be ascertained in most cases. We have thoroughly examined the failed cases using different structural and crystallographic measures, such as B-factor, R-factor, electron density map, and geometry at the binding site. It has been found that X-ray structures have issues in many of the failed cases. Our algorithm, along with the checks for structural accuracy, is a major step in predicting calcium ion positions in metalloproteins.

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“…In a very recent application, our own research team developed a DL classifier that can discriminate physiological and adventitious zinc-binding sites in the 3D structures of MPs with an accuracy of about 90% [98]. In order to develop the tool, we trained a recurrent neural network (RNN) using a dataset of 1944 physiological and 3352 adventitious zincbinding sites extracted from MetalPDB and manually annotated.…”

Section: Ai Methods Applied To Metalloproteinsmentioning

confidence: 99%

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

Andreini¹,

Rosato²

2022

Preprint

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All living organisms require some metal ions for their energy production as well as metabolic and biosynthetic processes. Within cells, metal ions are involved in the formation of adducts interact with metabolites and macromolecules (proteins and nucleic acids). The proteins that require binding to one or more metal ions to be able to carry out their physiological function are called metalloproteins. About one third of all protein structures in the Protein Data Bank involve metalloproteins. Over the past few years there has been a tremendous progress in the number of computational tools and techniques making use of 3D structural information to support the investigation of metalloproteins. This trend has been boosted also by the successful applications of neural networks and deep learning approaches in molecular and structural biology at large. In this review, we discuss recent advances in the development and availability of resources dealing with metalloproteins from a structure-based perspective. We start by addressing tools for the prediction of metal-binding sites (MBSs) using structural information on apo-proteins. Then, we provide an overview of methods for and lessons learned from the structural comparison of MBSs in a fold-independent manner. We then move to describing databases of metalloprotein/MBS structures. Finally, we summarize recent DL applications enhancing the functional interpretation of metalloprotein structures.

show abstract

Learning to Identify Physiological and Adventitious Metal-Binding Sites in the Three-Dimensional Structures of Proteins by Following the Hints of a Deep Neural Network

Cited by 11 publications

References 55 publications

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

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

Prediction of Ca²⁺binding site in proteins with a fast and accurate method based on statistical mechanics and analysis of crystal structures

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

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Learning to Identify Physiological and Adventitious Metal-Binding Sites in the Three-Dimensional Structures of Proteins by Following the Hints of a Deep Neural Network

Cited by 11 publications

References 55 publications

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

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

Prediction of Ca2+binding site in proteins with a fast and accurate method based on statistical mechanics and analysis of crystal structures

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

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Product

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Prediction of Ca²⁺binding site in proteins with a fast and accurate method based on statistical mechanics and analysis of crystal structures