Optimized SQE atomic charges for peptides accessible via a web application

Optimized SQE atomic charges for peptides accessible via a web application

Abstract Background Partial atomic charges find many applications in computational chemistry, chemoinformatics, bioinformatics, and nanoscience. Currently, frequently used methods for charge calculation are the Electronegativity Equalization Method (EEM), Charge Equilibration method (QEq), and Exten...

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Main Authors: Ondřej Schindler, Tomáš Raček, Aleksandra Maršavelski, Jaroslav Koča, Karel Berka, Radka Svobodová
Format: Article
Language:English
Published: BMC 2021-06-01
Series:Journal of Cheminformatics
Subjects:
Partial atomic charges
Parameterization
Empirical methods
Web service
Online Access:https://doi.org/10.1186/s13321-021-00528-w
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spelling doaj-169dbc18d0964272ae4286310036a6f82021-07-04T11:44:28ZengBMCJournal of Cheminformatics1758-29462021-06-0113111110.1186/s13321-021-00528-wOptimized SQE atomic charges for peptides accessible via a web applicationOndřej Schindler0Tomáš Raček1Aleksandra Maršavelski2Jaroslav Koča3Karel Berka4Radka Svobodová5CEITEC-Central European Institute of Technology, Masaryk UniversityCEITEC-Central European Institute of Technology, Masaryk UniversityDivision of Biochemistry, Department of Chemistry, Faculty of Science, University of ZagrebCEITEC-Central European Institute of Technology, Masaryk UniversityDepartment of Physical Chemistry, Faculty of Science, Palacký University OlomoucCEITEC-Central European Institute of Technology, Masaryk UniversityAbstract Background Partial atomic charges find many applications in computational chemistry, chemoinformatics, bioinformatics, and nanoscience. Currently, frequently used methods for charge calculation are the Electronegativity Equalization Method (EEM), Charge Equilibration method (QEq), and Extended QEq (EQeq). They all are fast, even for large molecules, but require empirical parameters. However, even these advanced methods have limitations—e.g., their application for peptides, proteins, and other macromolecules is problematic. An empirical charge calculation method that is promising for peptides and other macromolecular systems is the Split-charge Equilibration method (SQE) and its extension SQE+q0. Unfortunately, only one parameter set is available for these methods, and their implementation is not easily accessible. Results In this article, we present for the first time an optimized guided minimization method (optGM) for the fast parameterization of empirical charge calculation methods and compare it with the currently available guided minimization (GDMIN) method. Then, we introduce a further extension to SQE, SQE+qp, adapted for peptide datasets, and compare it with the common approaches EEM, QEq EQeq, SQE, and SQE+q0. Finally, we integrate SQE and SQE+qp into the web application Atomic Charge Calculator II (ACC II), including several parameter sets. Conclusion The main contribution of the article is that it makes SQE methods with their parameters accessible to the users via the ACC II web application ( https://acc2.ncbr.muni.cz ) and also via a command-line application. Furthermore, our improvement, SQE+qp, provides an excellent solution for peptide datasets. Additionally, optGM provides comparable parameters to GDMIN in a markedly shorter time. Therefore, optGM allows us to perform parameterizations for charge calculation methods with more parameters (e.g., SQE and its extensions) using large datasets. Graphic Abstracthttps://doi.org/10.1186/s13321-021-00528-wPartial atomic chargesParameterizationEmpirical methodsWeb service
collection DOAJ
language English
format Article
sources DOAJ
author Ondřej Schindler
Tomáš Raček
Aleksandra Maršavelski
Jaroslav Koča
Karel Berka
Radka Svobodová
spellingShingle Ondřej Schindler
Tomáš Raček
Aleksandra Maršavelski
Jaroslav Koča
Karel Berka
Radka Svobodová
Optimized SQE atomic charges for peptides accessible via a web application
Journal of Cheminformatics
Partial atomic charges
Parameterization
Empirical methods
Web service
author_facet Ondřej Schindler
Tomáš Raček
Aleksandra Maršavelski
Jaroslav Koča
Karel Berka
Radka Svobodová
author_sort Ondřej Schindler
title Optimized SQE atomic charges for peptides accessible via a web application
title_short Optimized SQE atomic charges for peptides accessible via a web application
title_full Optimized SQE atomic charges for peptides accessible via a web application
title_fullStr Optimized SQE atomic charges for peptides accessible via a web application
title_full_unstemmed Optimized SQE atomic charges for peptides accessible via a web application
title_sort optimized sqe atomic charges for peptides accessible via a web application
publisher BMC
series Journal of Cheminformatics
issn 1758-2946
publishDate 2021-06-01
description Abstract Background Partial atomic charges find many applications in computational chemistry, chemoinformatics, bioinformatics, and nanoscience. Currently, frequently used methods for charge calculation are the Electronegativity Equalization Method (EEM), Charge Equilibration method (QEq), and Extended QEq (EQeq). They all are fast, even for large molecules, but require empirical parameters. However, even these advanced methods have limitations—e.g., their application for peptides, proteins, and other macromolecules is problematic. An empirical charge calculation method that is promising for peptides and other macromolecular systems is the Split-charge Equilibration method (SQE) and its extension SQE+q0. Unfortunately, only one parameter set is available for these methods, and their implementation is not easily accessible. Results In this article, we present for the first time an optimized guided minimization method (optGM) for the fast parameterization of empirical charge calculation methods and compare it with the currently available guided minimization (GDMIN) method. Then, we introduce a further extension to SQE, SQE+qp, adapted for peptide datasets, and compare it with the common approaches EEM, QEq EQeq, SQE, and SQE+q0. Finally, we integrate SQE and SQE+qp into the web application Atomic Charge Calculator II (ACC II), including several parameter sets. Conclusion The main contribution of the article is that it makes SQE methods with their parameters accessible to the users via the ACC II web application ( https://acc2.ncbr.muni.cz ) and also via a command-line application. Furthermore, our improvement, SQE+qp, provides an excellent solution for peptide datasets. Additionally, optGM provides comparable parameters to GDMIN in a markedly shorter time. Therefore, optGM allows us to perform parameterizations for charge calculation methods with more parameters (e.g., SQE and its extensions) using large datasets. Graphic Abstract
topic Partial atomic charges
Parameterization
Empirical methods
Web service
url https://doi.org/10.1186/s13321-021-00528-w
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