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4. The Eighth Central European Conference 'Chemistry towards Biology': Snapshot

Author

Perczel, A., Atanasov, A. G., Sklenář, V., Nováček, J., Papoušková, V., Kadeřávek, P., Žídek, L., Kozłowski, H., Wątły, J., Hecel, A., Kołkowska, P., Koča, J., Svobodová-Vařeková, R., Pravda, L., Sehnal, D., Horský, V., Geidl, S., Enriz, R. D., Matějka, P., Jeništová, A., Dendisová, M., Kokaislová, A., Weissig, V., Olsen, M., Coffey, A., Ajuebor, J., Keary, R., Sanz-Gaitero, M., Raaij, M. J., Mcauliffe, O., Waltenberger, B., Andrei Mocan, Šmejkal, K., Heiss, E. H., Diederich, M., Musioł, R., Košmrlj, J., Polański, J., Jampílek, J., Consejo Superior de Investigaciones Científicas (España), and Ministerio de Economía y Competitividad (España)

Subjects
proteins and nucleic acids, synthesis, drug design, chemical biology, biological chemistry, Article, lcsh:QD241-441, drug delivery systems, lcsh:Organic chemistry, ADME, natural compounds, nanoparticles, ADME, drug delivery systems, targeting, biomaterials
Abstract

The Eighth Central European Conference “Chemistry towards Biology” was held in Brno, Czech Republic, on August 28–September 1, 2016 to bring together experts in biology, chemistry and design of bioactive compounds; promote the exchange of scientific results, methods and ideas; and encourage cooperation between researchers from all over the world. The topics of the conference covered “Chemistry towards Biology”, meaning that the event welcomed chemists working on biology-related problems, biologists using chemical methods, and students and other researchers of the respective areas that fall within the common scope of chemistry and biology. The authors of this manuscript are plenary speakers and other participants of the symposium and members of their research teams. The following summary highlights the major points/topics of the meeting., The 8th Central European Conference “Chemistry towards Biology” was supported by the sponsors: Angelini Pharma, Nicolet CZ, Sigma-Aldrich, GrapeNet as well as Pragolab, Lach-Ner and VWR. Atanas Atanasov’s research group acknowledges the support by the Austrian Science Fund (FWF) project P25971-B23. The results of the research of Vladimír Sklenáˇr’s research team as well as Jaroslav Koˇca’s research team have been obtained within the CEITEC 2020 (LQ1601) project with financial contributions made by the Ministry of Education, Youths and Sports of the Czech Republic with special support paid by the National Programme for Sustainability II funds. András Perczel’s research group acknowledges the financial support of the Hungarian National Science Fund (OTKA NK101072) and MedinProt. Financial support from the specific university research (MSMT No 20-SVV/2016) and the University of Chemistry and Technology Prague is gratefully acknowledged by Pavel Matˇejka’s research team. Aidan Coffey’s research group acknowledges the financial support of the Spanish Ministry of Economy and Competitiveness (BFU2014-53425-P). Marc Diederich thanks the Research Institute of Pharmaceutical Sciences, College of Pharmacy, Seoul National University, the National Research Fund by the MEST of Korea for Tumour Microenvironment (GCRC 2012-0001184 grant), the Seoul National University Research Grant (2016; Funding number: 800-20160150) and the BK21 PLUS program. The research of Robert Musioł’s research team was funded by grant 2013/09/B/NZ7/00423 of the National Centre of Science of Poland and by the Wroclaw Centre of Biotechnology, programme “The Leading National Research Centre (KNOW)” for the years 2014–2018. Also the project of Henryk Kozłowski’s research team was supported by the Wroclaw Centre of Biotechnology, programme “The Leading National Research Centre (KNOW)” for the years 2014–2018. Financial support from the Ministry of Education, Science and Sport, Republic of Slovenia, the Slovenian Research Agency (Grant P1-0230), is gratefully acknowledged by Janez Košmrlj’s research team. Jarosław Pola ́nski’s research team kindly thanks the financial support of NCBR grants: ORGANOMET No. PBS2/A5/40/2014 and TANGO1/266384/NCBR/2015. We acknowledge support by the CSIC Open Access Publication Initiative through its Unit of Information Resources for Research (URICI).

9. Protein Data Bank: the single global archive for 3D macromolecular structure data

Author

Masashi Yokochi, Ju Yaen Kim, Chenghua Shao, John M. Berrisford, Hongyang Yao, Miron Livny, Stephen Anyango, Abhik Mukhopadhyay, Romana Gáborová, Yi-Ping Tao, Monica Sekharan, Aleksandras Gutmanas, Jose M. Dana, Mandar Deshpande, Charmi Bhikadiya, Yannis Ioannidis, Pedro Romero, Jonathan R. Wedell, Eldon L. Ulrich, Gert-Jan Bekker, Chris Randle, Chunxiao Bi, Jeffrey C. Hoch, Nurul Nadzirin, Jaroslav Koča, Yumiko Kengaku, Jasmine Young, Cole Christie, John D. Westbrook, Naohiro Kobayashi, Alexander S. Rose, Sameer Velankar, David Sehnal, Lukáš Pravda, David R. Armstrong, Hasumi Cho, Genji Kurisu, Lora Mak, John L. Markley, Saqib Mir, Sutapa Ghosh, Ardan Patwardhan, Zukang Feng, Stephen K. Burley, Robert Lowe, David S. Goodsell, Hirofumi Suzuki, Maria Voigt, Paul Gane, Jose M. Duarte, Osman Salih, Irina Periskova, Matthew J. Conroy, Toshimichi Fujiwara, Yasuyo Ikegawa, Takahiro Kudou, Dimitri Maziuk, Typhaine Paysan-Lafosse, Brian P. Hudson, Christine Zardecki, Sreenath Nair, Gerard J. Kleywegt, Marina A. Zhuravleva, Shuchismita Dutta, Dmytro Guzenko, Kumaran Baskaran, Rachel Kramer Green, Ezra Peisach, Li Chen, Reiko Yamashita, Vladimir Guranovic, Yu-He Liang, Takeshi Iwata, Atsushi Nakagawa, Haruki Nakamura, Junko Sato, Radka Svobodová Vařeková, Helen M. Berman, Deepti Gupta, Luigi Di Costanzo, Mihaly Varadi, Yana Valasatava, Burley, S. K., Berman, H. M., Bhikadiya, C., Bi, C., Chen, L., DI COSTANZO, Luigi, Addeo, PIETRO FRANCESCO BRUNO CHRISTI, Duarte, J. M., Dutta, S., Feng, Z., Ghosh, S., Goodsell, D. S., Green, R. K., Guranovic, V., Guzenko, D., Hudson, B. P., Liang, Y., Lowe, R., Peisach, E., Periskova, I., Randle, C., Rose, A., Sekharan, M., Shao, C., Tao, Y. -P., Valasatava, Y., Voigt, M., Westbrook, J., Young, J., Zardecki, C., Zhuravleva, M., Kurisu, G., Nakamura, H., Kengaku, Y., Cho, H., Sato, J., Kim, J. Y., Ikegawa, Y., Nakagawa, A., Yamashita, R., Kudou, T., Bekker, G. -J., Suzuki, H., Iwata, T., Yokochi, M., Kobayashi, N., Fujiwara, T., Velankar, S., Kleywegt, G. J., Anyango, S., Armstrong, D. R., Berrisford, J. M., Conroy, M. J., Dana, J. M., Deshpande, M., Gane, P., Gaborova, R., Gupta, D., Gutmanas, A., Koca, J., Mak, L., EL MIR, Abdelouahad, Mukhopadhyay, A., Nadzirin, N., Nair, S., Patwardhan, A., Paysan-Lafosse, T., Pravda, L., Salih, O., Sehnal, D., Varadi, M., Varekova, R., Markley, J. L., Hoch, J. C., Romero, P. R., Baskaran, K., Maziuk, D., Ulrich, E. L., Wedell, J. R., Sicong, Yao, Livny, M., and Ioannidis, Y. E.

Subjects
Models, Molecular, Protein Conformation, Molecular Conformation, Protein Data Bank (RCSB PDB), Master data, Biology, computer.software_genre, 03 medical and health sciences, 0302 clinical medicine, Genetics, Database Issue, RDF, Databases, Protein, 030304 developmental biology, Structure (mathematical logic), 0303 health sciences, Database, Experimental data, DNA, computer.file_format, Atomic coordinates, Protein Data Bank, Metadata, Metals, Nucleic Acid Conformation, RNA, computer, 030217 neurology & neurosurgery
Abstract

The Protein Data Bank (PDB) is the single global archive of experimentally determined three-dimensional (3D) structure data of biological macromolecules. Since 2003, the PDB has been managed by the Worldwide Protein Data Bank (wwPDB; wwpdb.org), an international consortium that collaboratively oversees deposition, validation, biocuration, and open access dissemination of 3D macromolecular structure data. The PDB Core Archive houses 3D atomic coordinates of more than 144 000 structural models of proteins, DNA/RNA, and their complexes with metals and small molecules and related experimental data and metadata. Structure and experimental data/metadata are also stored in the PDB Core Archive using the readily extensible wwPDB PDBx/mmCIF master data format, which will continue to evolve as data/metadata from new experimental techniques and structure determination methods are incorporated by the wwPDB. Impacts of the recently developed universal wwPDB OneDep deposition/validation/biocuration system and various methods-specific wwPDB Validation Task Forces on improving the quality of structures and data housed in the PDB Core Archive are described together with current challenges and future plans.

Published
2018

10. Mesoscale explorer: Visual exploration of large-scale molecular models.

Author

Rose A, Sehnal D, Goodsell DS, and Autin L

Subjects
Viruses chemistry, Viruses ultrastructure, Models, Molecular, Cryoelectron Microscopy methods, Software
Abstract

The advent of cryo-electron microscopy (cryo-EM) and cryo-electron tomography (cryo-ET), coupled with computational modeling, has enabled the creation of integrative 3D models of viruses, bacteria, and cellular organelles. These models, composed of thousands of macromolecules and billions of atoms, have historically posed significant challenges for manipulation and visualization without specialized molecular graphics tools and hardware. With the recent advancements in GPU rendering power and web browser capabilities, it is now feasible to render interactively large molecular scenes directly on the web. In this work, we introduce Mesoscale Explorer, a web application built using the Mol* framework, dedicated to the visualization of large-scale molecular models ranging from viruses to cell organelles. Mesoscale Explorer provides unprecedented access and insight into the molecular fabric of life, enhancing perception, streamlining exploration, and simplifying visualization of diverse data types, showcasing the intricate details of these models with unparalleled clarity., (© 2024 The Author(s). Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published
2024
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11. Describing and Sharing Molecular Visualizations Using the MolViewSpec Toolkit.

Author

Bittrich S, Midlik A, Varadi M, Velankar S, Burley SK, Young JY, Sehnal D, and Vallat B

Subjects
Imaging, Three-Dimensional, Macromolecular Substances chemistry, Models, Molecular, Software
Abstract

With the ever-expanding toolkit of molecular viewers, the ability to visualize macromolecular structures has never been more accessible. Yet, the idiosyncratic technical intricacies across tools and the integration complexities associated with handling structure annotation data present significant barriers to seamless interoperability and steep learning curves for many users. The necessity for reproducible data visualizations is at the forefront of the current challenges. Recently, we introduced MolViewSpec (homepage: https://molstar.org/mol-view-spec/, GitHub project: https://github.com/molstar/mol-view-spec), a specification approach that defines molecular visualizations, decoupling them from the varying implementation details of different molecular viewers. Through the protocols presented herein, we demonstrate how to use MolViewSpec and its 3D view-building Python library for creating sophisticated, customized 3D views covering all standard molecular visualizations. MolViewSpec supports representations like cartoon and ball-and-stick with coloring, labeling, and applying complex transformations such as superposition to any macromolecular structure file in mmCIF, BinaryCIF, and PDB formats. These examples showcase progress towards reusability and interoperability of molecular 3D visualization in an era when handling molecular structures at scale is a timely and pressing matter in structural bioinformatics as well as research and education across the life sciences. © 2024 The Authors. Current Protocols published by Wiley Periodicals LLC. Basic Protocol 1: Creating a MolViewSpec view using the MolViewSpec Python package Basic Protocol 2: Creating a MolViewSpec view with reference to MolViewSpec annotation files Basic Protocol 3: Creating a MolViewSpec view with labels and other advanced features Support Protocol 1: Computing rotation and translation vectors Support Protocol 2: Creating a MolViewSpec annotation file., (© 2024 The Author(s). Current Protocols published by Wiley Periodicals LLC.)

Published
2024
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12. ChannelsDB 2.0: a comprehensive database of protein tunnels and pores in AlphaFold era.

Author

Špačková A, Vávra O, Raček T, Bazgier V, Sehnal D, Damborský J, Svobodová R, Bednář D, and Berka K

Subjects
Amino Acids, Protein Conformation, Databases, Protein, Proteins chemistry, Software
Abstract

ChannelsDB 2.0 is an updated database providing structural information about the position, geometry and physicochemical properties of protein channels-tunnels and pores-within deposited biomacromolecular structures from PDB and AlphaFoldDB databases. The newly deposited information originated from several sources. Firstly, we included data calculated using a popular CAVER tool to complement the data obtained using original MOLE tool for detection and analysis of protein tunnels and pores. Secondly, we added tunnels starting from cofactors within the AlphaFill database to enlarge the scope of the database to protein models based on Uniprot. This has enlarged available channel annotations ∼4.6 times as of 1 September 2023. The database stores information about geometrical features, e.g. length and radius, and physico-chemical properties based on channel-lining amino acids. The stored data are interlinked with the available UniProt mutation annotation data. ChannelsDB 2.0 provides an excellent resource for deep analysis of the role of biomacromolecular tunnels and pores. The database is available free of charge: https://channelsdb2.biodata.ceitec.cz., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2024
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13. Analysis and Visualization of Protein Channels, Tunnels, and Pores with MOLEonline and ChannelsDB 2.0.

Author

Špačková A, Bazgier V, Raček T, Sehnal D, Svobodová R, and Berka K

Subjects
Protein Conformation, User-Computer Interface, Models, Molecular, Ion Channels metabolism, Ion Channels chemistry, Computational Biology methods, Proteins chemistry, Proteins metabolism, Web Browser, Software, Databases, Protein
Abstract

Channels, tunnels, and pores serve as pathways for the transport of molecules and ions through protein structures, thus participating to their functions. MOLEonline ( https://mole.upol.cz ) is an interactive web-based tool with enhanced capabilities for detecting and characterizing channels, tunnels, and pores within protein structures. MOLEonline has two distinct calculation modes for analysis of channel and tunnels or transmembrane pores. This application gives researchers rich analytical insights into channel detection, structural characterization, and physicochemical properties. ChannelsDB 2.0 ( https://channelsdb2.biodata.ceitec.cz/ ) is a comprehensive database that offers information on the location, geometry, and physicochemical characteristics of tunnels and pores within macromolecular structures deposited in Protein Data Bank and AlphaFill databases. These tunnels are sourced from manual deposition from literature and automatic detection using software tools MOLE and CAVER. MOLEonline and ChannelsDB visualization is powered by the LiteMol Viewer and Mol* viewer, ensuring a user-friendly workspace. This chapter provides an overview of user applications and usage., (© 2024. The Author(s), under exclusive license to Springer Science+Business Media, LLC, part of Springer Nature.)

Published
2024
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14. PDBImages: a command-line tool for automated macromolecular structure visualization.

Author

Midlik A, Nair S, Anyango S, Deshpande M, Sehnal D, Varadi M, and Velankar S

Subjects
Molecular Structure, Software, Computational Biology methods
Abstract

Summary: PDBImages is an innovative, open-source Node.js package that harnesses the power of the popular macromolecule structure visualization software Mol*. Designed for use by the scientific community, PDBImages provides a means to generate high-quality images for PDB and AlphaFold DB models. Its unique ability to render and save images directly to files in a browserless mode sets it apart, offering users a streamlined, automated process for macromolecular structure visualization. Here, we detail the implementation of PDBImages, enumerating its diverse image types, and elaborating on its user-friendly setup. This powerful tool opens a new gateway for researchers to visualize, analyse, and share their work, fostering a deeper understanding of bioinformatics., Availability and Implementation: PDBImages is available as an npm package from https://www.npmjs.com/package/pdb-images. The source code is available from https://github.com/PDBeurope/pdb-images., (© The Author(s) 2023. Published by Oxford University Press.)

Published
2023
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15. Mol* Volumes and Segmentations: visualization and interpretation of cell imaging data alongside macromolecular structure data and biological annotations.

Author

Chareshneu A, Midlik A, Ionescu CM, Rose A, Horský V, Cantara A, Svobodová R, Berka K, and Sehnal D

Subjects
Macromolecular Substances, Internet, Microscopy, Image Processing, Computer-Assisted, Software
Abstract

Segmentation helps interpret imaging data in a biological context. With the development of powerful tools for automated segmentation, public repositories for imaging data have added support for sharing and visualizing segmentations, creating the need for interactive web-based visualization of 3D volume segmentations. To address the ongoing challenge of integrating and visualizing multimodal data, we developed Mol* Volumes and Segmentations (Mol*VS), which enables the interactive, web-based visualization of cellular imaging data supported by macromolecular data and biological annotations. Mol*VS is fully integrated into Mol* Viewer, which is already used for visualization by several public repositories. All EMDB and EMPIAR entries with segmentation datasets are accessible via Mol*VS, which supports the visualization of data from a wide range of electron and light microscopy experiments. Additionally, users can run a local instance of Mol*VS to visualize and share custom datasets in generic or application-specific formats including volumes in .ccp4, .mrc, and .map, and segmentations in EMDB-SFF .hff, Amira .am, iMod .mod, and Segger .seg. Mol*VS is open source and freely available at https://molstarvolseg.ncbr.muni.cz/., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2023
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16. PDBe and PDBe-KB: Providing high-quality, up-to-date and integrated resources of macromolecular structures to support basic and applied research and education.

Author

Varadi M, Anyango S, Appasamy SD, Armstrong D, Bage M, Berrisford J, Choudhary P, Bertoni D, Deshpande M, Leines GD, Ellaway J, Evans G, Gaborova R, Gupta D, Gutmanas A, Harrus D, Kleywegt GJ, Bueno WM, Nadzirin N, Nair S, Pravda L, Afonso MQL, Sehnal D, Tanweer A, Tolchard J, Abrams C, Dunlop R, and Velankar S

Subjects
Databases, Protein, Europe, Protein Conformation, Nucleic Acids, Proteins chemistry
Abstract

The archiving and dissemination of protein and nucleic acid structures as well as their structural, functional and biophysical annotations is an essential task that enables the broader scientific community to conduct impactful research in multiple fields of the life sciences. The Protein Data Bank in Europe (PDBe; pdbe.org) team develops and maintains several databases and web services to address this fundamental need. From data archiving as a member of the Worldwide PDB consortium (wwPDB; wwpdb.org), to the PDBe Knowledge Base (PDBe-KB; pdbekb.org), we provide data, data-access mechanisms, and visualizations that facilitate basic and applied research and education across the life sciences. Here, we provide an overview of the structural data and annotations that we integrate and make freely available. We describe the web services and data visualization tools we offer, and provide information on how to effectively use or even further develop them. Finally, we discuss the direction of our data services, and how we aim to tackle new challenges that arise from the recent, unprecedented advances in the field of structure determination and protein structure modeling., (© 2022 The Authors. Protein Science published by Wiley Periodicals LLC on behalf of The Protein Society.)

Published
2022
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17. NAChRDB: A Web Resource of Structure-Function Annotations to Unravel the Allostery of Nicotinic Acetylcholine Receptors.

Author

Chareshneu A, Pant P, Tristão Ramos RJ, Sehnal D, Gökbel T, Ionescu CM, and Koča J

Abstract

Nicotinic acetylcholine receptors (nAChRs) comprise a large and ancient family of allosteric ion channels mediating synaptic transmission. The vast knowledge about nAChRs has become difficult to navigate. NAChRDB is a web-accessible resource of curated residue-level functional annotations of neuromuscular nAChRs. Interactive three-dimensional (3D) visualization and sequence alignment give further context to this rich and growing collection of experimental observations and computational predictions. NAChRDB is freely available at https://crocodile.ncbr.muni.cz/Apps/NAChRDB/, with interactive tutorials and regular updates to the content and web interface. No installation or user registration is required. NAChRDB is accessible through any modern internet browser on desktops and mobile devices. By providing immediate and systematic access to practical knowledge gained through decades of research, NAChRDB represents a powerful educational tool and helps guide discovery by revealing gaps in current knowledge and aiding the interpretation of results of molecular and structural biology experiments or computational studies., Competing Interests: The authors declare no competing financial interest., (© 2021 The Authors. Published by American Chemical Society.)

Published
2021
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18. Mol* Viewer: modern web app for 3D visualization and analysis of large biomolecular structures.

Author

Sehnal D, Bittrich S, Deshpande M, Svobodová R, Berka K, Bazgier V, Velankar S, Burley SK, Koča J, and Rose AS

Subjects
Internet, Protein Conformation, Macromolecular Substances chemistry, Models, Molecular, Software
Abstract

Large biomolecular structures are being determined experimentally on a daily basis using established techniques such as crystallography and electron microscopy. In addition, emerging integrative or hybrid methods (I/HM) are producing structural models of huge macromolecular machines and assemblies, sometimes containing 100s of millions of non-hydrogen atoms. The performance requirements for visualization and analysis tools delivering these data are increasing rapidly. Significant progress in developing online, web-native three-dimensional (3D) visualization tools was previously accomplished with the introduction of the LiteMol suite and NGL Viewers. Thereafter, Mol* development was jointly initiated by PDBe and RCSB PDB to combine and build on the strengths of LiteMol (developed by PDBe) and NGL (developed by RCSB PDB). The web-native Mol* Viewer enables 3D visualization and streaming of macromolecular coordinate and experimental data, together with capabilities for displaying structure quality, functional, or biological context annotations. High-performance graphics and data management allows users to simultaneously visualise up to hundreds of (superimposed) protein structures, stream molecular dynamics simulation trajectories, render cell-level models, or display huge I/HM structures. It is the primary 3D structure viewer used by PDBe and RCSB PDB. It can be easily integrated into third-party services. Mol* Viewer is open source and freely available at https://molstar.org/., (© The Author(s) 2021. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2021
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20. High-performance macromolecular data delivery and visualization for the web.

Author

Sehnal D, Svobodová R, Berka K, Rose AS, Burley SK, Velankar S, and Koča J

Subjects
Computer Graphics, Internet, Macromolecular Substances chemistry, Software, User-Computer Interface
Abstract

Biomacromolecular structural data make up a vital and crucial scientific resource that has grown not only in terms of its amount but also in its size and complexity. Furthermore, these data are accompanied by large and increasing amounts of experimental data. Additionally, the macromolecular data are enriched with value-added annotations describing their biological, physicochemical and structural properties. Today, the scientific community requires fast and fully interactive web visualization to exploit this complex structural information. This article provides a survey of the available cutting-edge web services that address this challenge. Specifically, it focuses on data-delivery problems, discusses the visualization of a single structure, including experimental data and annotations, and concludes with a focus on the results of molecular-dynamics simulations and the visualization of structural ensembles., (open access.)

Published
2020
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21. BinaryCIF and CIFTools-Lightweight, efficient and extensible macromolecular data management.

Author

Sehnal D, Bittrich S, Velankar S, Koča J, Svobodová R, Burley SK, and Rose AS

Subjects
Databases, Chemical, Macromolecular Substances chemistry, Macromolecular Substances ultrastructure, Crystallography methods, Data Compression methods, Models, Molecular, Software
Abstract

3D macromolecular structural data is growing ever more complex and plentiful in the wake of substantive advances in experimental and computational structure determination methods including macromolecular crystallography, cryo-electron microscopy, and integrative methods. Efficient means of working with 3D macromolecular structural data for archiving, analyses, and visualization are central to facilitating interoperability and reusability in compliance with the FAIR Principles. We address two challenges posed by growth in data size and complexity. First, data size is reduced by bespoke compression techniques. Second, complexity is managed through improved software tooling and fully leveraging available data dictionary schemas. To this end, we introduce BinaryCIF, a serialization of Crystallographic Information File (CIF) format files that maintains full compatibility to related data schemas, such as PDBx/mmCIF, while reducing file sizes by more than a factor of two versus gzip compressed CIF files. Moreover, for the largest structures, BinaryCIF provides even better compression-factor ten and four versus CIF files and gzipped CIF files, respectively. Herein, we describe CIFTools, a set of libraries in Java and TypeScript for generic and typed handling of CIF and BinaryCIF files. Together, BinaryCIF and CIFTools enable lightweight, efficient, and extensible handling of 3D macromolecular structural data., Competing Interests: The authors have declared that no competing interests exist.

Published
2020
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22. PDBe: improved findability of macromolecular structure data in the PDB.

Author

Armstrong DR, Berrisford JM, Conroy MJ, Gutmanas A, Anyango S, Choudhary P, Clark AR, Dana JM, Deshpande M, Dunlop R, Gane P, Gáborová R, Gupta D, Haslam P, Koča J, Mak L, Mir S, Mukhopadhyay A, Nadzirin N, Nair S, Paysan-Lafosse T, Pravda L, Sehnal D, Salih O, Smart O, Tolchard J, Varadi M, Svobodova-Vařeková R, Zaki H, Kleywegt GJ, and Velankar S

Subjects
Cluster Analysis, Data Accuracy, Europe, Protein Conformation, User-Computer Interface, Databases, Protein, Software
Abstract

The Protein Data Bank in Europe (PDBe), a founding member of the Worldwide Protein Data Bank (wwPDB), actively participates in the deposition, curation, validation, archiving and dissemination of macromolecular structure data. PDBe supports diverse research communities in their use of macromolecular structures by enriching the PDB data and by providing advanced tools and services for effective data access, visualization and analysis. This paper details the enrichment of data at PDBe, including mapping of RNA structures to Rfam, and identification of molecules that act as cofactors. PDBe has developed an advanced search facility with ∼100 data categories and sequence searches. New features have been included in the LiteMol viewer at PDBe, with updated visualization of carbohydrates and nucleic acids. Small molecules are now mapped more extensively to external databases and their visual representation has been enhanced. These advances help users to more easily find and interpret macromolecular structure data in order to solve scientific problems., (© The Author(s) 2019. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2020
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23. Visualization and Analysis of Protein Structures with LiteMol Suite.

Author

Sehnal D, Svobodová R, Berka K, Pravda L, Midlik A, and Koča J

Subjects
Databases, Protein, Europe, Internet, Software, User-Computer Interface, Web Browser, Protein Conformation, Proteins chemistry
Abstract

LiteMol suite is an innovative solution that enables near-instant delivery of model and experimental biomacromolecular structural data, providing users with an interactive and responsive experience in all modern web browsers and mobile devices. LiteMol suite is a combination of data delivery services (CoordinateServer and DensityServer), compression format (BinaryCIF), and a molecular viewer (LiteMol Viewer). The LiteMol suite is integrated into Protein Data Bank in Europe (PDBe) and other life science web applications (e.g., UniProt, Ensemble, SIB, and CNRS services), it is freely available at https://litemol.org , and its source code is available via GitHub. LiteMol suite provides advanced functionality (annotations and their visualization, powerful selection features), and this chapter will describe their use for visual inspection of protein structures.

Published
2020
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24. Rapidly Display Glycan Symbols in 3D Structures: 3D-SNFG in LiteMol.

Author

Sehnal D and Grant OC

Subjects
Carbohydrates chemistry, Molecular Conformation, Polysaccharides chemistry, Software
Abstract

The representation of carbohydrates in 3D space using symbols is a powerful visualization method, but such representations are lacking in currently available visualization software. The work presented here allows researchers to display carbohydrate 3D structures as 3D-SNFG symbols using LiteMol from a web browser (e.g., v.litemol.org/?loadFromCS=5T3X ). Any PDB ID can be substituted at the end of the URL. Alternatively, the user may enter a PDB ID or upload a structure. LiteMol is available at https://v.litemol.org and automatically depicts any carbohydrate residues as 3D-SNFG symbols. To embed LiteMol in a webpage, visit https://github.com/dsehnal/LiteMol .

Published
2019
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25. MOLEonline: a web-based tool for analyzing channels, tunnels and pores (2018 update).

Author

Pravda L, Sehnal D, Toušek D, Navrátilová V, Bazgier V, Berka K, Svobodová Vareková R, Koca J, and Otyepka M

Subjects
Models, Molecular, Computational Biology, Internet, Protein Conformation, Software
Abstract

MOLEonline is an interactive, web-based application for the detection and characterization of channels (pores and tunnels) within biomacromolecular structures. The updated version of MOLEonline overcomes limitations of the previous version by incorporating the recently developed LiteMol Viewer visualization engine and providing a simple, fully interactive user experience. The application enables two modes of calculation: one is dedicated to the analysis of channels while the other was specifically designed for transmembrane pores. As the application can use both PDB and mmCIF formats, it can be leveraged to analyze a wide spectrum of biomacromolecular structures, e.g. stemming from NMR, X-ray and cryo-EM techniques. The tool is interconnected with other bioinformatics tools (e.g., PDBe, CSA, ChannelsDB, OPM, UniProt) to help both setup and the analysis of acquired results. MOLEonline provides unprecedented analytics for the detection and structural characterization of channels, as well as information about their numerous physicochemical features. Here we present the application of MOLEonline for structural analyses of α-hemolysin and transient receptor potential mucolipin 1 (TRMP1) pores. The MOLEonline application is freely available via the Internet at https://mole.upol.cz.

Published
2018
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26. ChannelsDB: database of biomacromolecular tunnels and pores.

Author

Pravda L, Sehnal D, Svobodová Vareková R, Navrátilová V, Toušek D, Berka K, Otyepka M, and Koca J

Subjects
Amino Acids metabolism, Animals, Catalytic Domain, Coenzymes chemistry, Coenzymes metabolism, Cytochrome P-450 CYP2D6 genetics, Cytochrome P-450 CYP2D6 metabolism, Eukaryotic Cells cytology, Eukaryotic Cells enzymology, Gene Expression, Humans, Hydrophobic and Hydrophilic Interactions, Ion Channels genetics, Ion Channels metabolism, Mutation, Nuclear Pore genetics, Nuclear Pore metabolism, Prokaryotic Cells cytology, Prokaryotic Cells enzymology, Static Electricity, Amino Acids chemistry, Cytochrome P-450 CYP2D6 chemistry, Databases, Protein, Ion Channels chemistry, Nuclear Pore chemistry, Software
Abstract

ChannelsDB (http://ncbr.muni.cz/ChannelsDB) is a database providing information about the positions, geometry and physicochemical properties of channels (pores and tunnels) found within biomacromolecular structures deposited in the Protein Data Bank. Channels were deposited from two sources; from literature using manual deposition and from a software tool automatically detecting tunnels leading to the enzymatic active sites and selected cofactors, and transmembrane pores. The database stores information about geometrical features (e.g. length and radius profile along a channel) and physicochemical properties involving polarity, hydrophobicity, hydropathy, charge and mutability. The stored data are interlinked with available UniProt annotation data mapping known mutation effects to channel-lining residues. All structures with channels are displayed in a clear interactive manner, further facilitating data manipulation and interpretation. As such, ChannelsDB provides an invaluable resource for research related to deciphering the biological function of biomacromolecular channels., (© The Author(s) 2017. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2018
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27. PDBe: towards reusable data delivery infrastructure at protein data bank in Europe.

Author

Mir S, Alhroub Y, Anyango S, Armstrong DR, Berrisford JM, Clark AR, Conroy MJ, Dana JM, Deshpande M, Gupta D, Gutmanas A, Haslam P, Mak L, Mukhopadhyay A, Nadzirin N, Paysan-Lafosse T, Sehnal D, Sen S, Smart OS, Varadi M, Kleywegt GJ, and Velankar S

Subjects
Amino Acid Sequence, Computer Graphics, Databases as Topic, Europe, Humans, Information Dissemination, Internet, Models, Molecular, Molecular Sequence Annotation, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Proteins genetics, Proteins metabolism, Computational Biology methods, Databases, Protein, Proteins chemistry, Sequence Analysis, Protein methods, User-Computer Interface
Abstract

The Protein Data Bank in Europe (PDBe, pdbe.org) is actively engaged in the deposition, annotation, remediation, enrichment and dissemination of macromolecular structure data. This paper describes new developments and improvements at PDBe addressing three challenging areas: data enrichment, data dissemination and functional reusability. New features of the PDBe Web site are discussed, including a context dependent menu providing links to raw experimental data and improved presentation of structures solved by hybrid methods. The paper also summarizes the features of the LiteMol suite, which is a set of services enabling fast and interactive 3D visualization of structures, with associated experimental maps, annotations and quality assessment information. We introduce a library of Web components which can be easily reused to port data and functionality available at PDBe to other services. We also introduce updates to the SIFTS resource which maps PDB data to other bioinformatics resources, and the PDBe REST API., (© The Author(s) 2017. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2018
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29. The Eighth Central European Conference "Chemistry towards Biology": Snapshot.

Author

Perczel A, Atanasov AG, Sklenář V, Nováček J, Papoušková V, Kadeřávek P, Žídek L, Kozłowski H, Wątły J, Hecel A, Kołkowska P, Koča J, Svobodová-Vařeková R, Pravda L, Sehnal D, Horský V, Geidl S, Enriz RD, Matějka P, Jeništová A, Dendisová M, Kokaislová A, Weissig V, Olsen M, Coffey A, Ajuebor J, Keary R, Sanz-Gaitero M, van Raaij MJ, McAuliffe O, Waltenberger B, Mocan A, Šmejkal K, Heiss EH, Diederich M, Musioł R, Košmrlj J, Polański J, and Jampílek J

Subjects
Drug Delivery Systems, Drug Design, Epigenesis, Genetic, Structure-Activity Relationship, Systems Biology, Chemistry, Pharmaceutical methods, Proteins chemistry
Abstract

The Eighth Central European Conference "Chemistry towards Biology" was held in Brno, Czech Republic, on August 28-September 1, 2016 to bring together experts in biology, chemistry and design of bioactive compounds; promote the exchange of scientific results, methods and ideas; and encourage cooperation between researchers from all over the world. The topics of the conference covered "Chemistry towards Biology", meaning that the event welcomed chemists working on biology-related problems, biologists using chemical methods, and students and other researchers of the respective areas that fall within the common scope of chemistry and biology. The authors of this manuscript are plenary speakers and other participants of the symposium and members of their research teams. The following summary highlights the major points/topics of the meeting., Competing Interests: The authors declare no conflict of interest.

Published
2016
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30. AtomicChargeCalculator: interactive web-based calculation of atomic charges in large biomolecular complexes and drug-like molecules.

Author

Ionescu CM, Sehnal D, Falginella FL, Pant P, Pravda L, Bouchal T, Svobodová Vařeková R, Geidl S, and Koča J

Abstract

Background: Partial atomic charges are a well-established concept, useful in understanding and modeling the chemical behavior of molecules, from simple compounds, to large biomolecular complexes with many reactive sites., Results: This paper introduces AtomicChargeCalculator (ACC), a web-based application for the calculation and analysis of atomic charges which respond to changes in molecular conformation and chemical environment. ACC relies on an empirical method to rapidly compute atomic charges with accuracy comparable to quantum mechanical approaches. Due to its efficient implementation, ACC can handle any type of molecular system, regardless of size and chemical complexity, from drug-like molecules to biomacromolecular complexes with hundreds of thousands of atoms. ACC writes out atomic charges into common molecular structure files, and offers interactive facilities for statistical analysis and comparison of the results, in both tabular and graphical form., Conclusions: Due to high customizability and speed, easy streamlining and the unified platform for calculation and analysis, ACC caters to all fields of life sciences, from drug design to nanocarriers. ACC is freely available via the Internet at http://ncbr.muni.cz/ACC.

Published
2015
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31. PatternQuery: web application for fast detection of biomacromolecular structural patterns in the entire Protein Data Bank.

Author

Sehnal D, Pravda L, Svobodová Vařeková R, Ionescu CM, and Koča J

Subjects
Binding Sites, Internet, Lectins chemistry, Macromolecular Substances chemistry, Models, Molecular, Protein Conformation, Zinc Fingers, Databases, Protein, Molecular Conformation, Software
Abstract

Well defined biomacromolecular patterns such as binding sites, catalytic sites, specific protein or nucleic acid sequences, etc. precisely modulate many important biological phenomena. We introduce PatternQuery, a web-based application designed for detection and fast extraction of such patterns. The application uses a unique query language with Python-like syntax to define the patterns that will be extracted from datasets provided by the user, or from the entire Protein Data Bank (PDB). Moreover, the database-wide search can be restricted using a variety of criteria, such as PDB ID, resolution, and organism of origin, to provide only relevant data. The extraction generally takes a few seconds for several hundreds of entries, up to approximately one hour for the whole PDB. The detected patterns are made available for download to enable further processing, as well as presented in a clear tabular and graphical form directly in the browser. The unique design of the language and the provided service could pave the way towards novel PDB-wide analyses, which were either difficult or unfeasible in the past. The application is available free of charge at http://ncbr.muni.cz/PatternQuery., (© The Author(s) 2015. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2015
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32. ValidatorDB: database of up-to-date validation results for ligands and non-standard residues from the Protein Data Bank.

Author

Sehnal D, Svobodová Vařeková R, Pravda L, Ionescu CM, Geidl S, Horský V, Jaiswal D, Wimmerová M, and Koča J

Subjects
Amino Acids chemistry, Internet, Ligands, Models, Molecular, Molecular Sequence Annotation, Protein Conformation, Reproducibility of Results, Databases, Protein, Proteins chemistry
Abstract

Following the discovery of serious errors in the structure of biomacromolecules, structure validation has become a key topic of research, especially for ligands and non-standard residues. ValidatorDB (freely available at http://ncbr.muni.cz/ValidatorDB) offers a new step in this direction, in the form of a database of validation results for all ligands and non-standard residues from the Protein Data Bank (all molecules with seven or more heavy atoms). Model molecules from the wwPDB Chemical Component Dictionary are used as reference during validation. ValidatorDB covers the main aspects of validation of annotation, and additionally introduces several useful validation analyses. The most significant is the classification of chirality errors, allowing the user to distinguish between serious issues and minor inconsistencies. Other such analyses are able to report, for example, completely erroneous ligands, alternate conformations or complete identity with the model molecules. All results are systematically classified into categories, and statistical evaluations are performed. In addition to detailed validation reports for each molecule, ValidatorDB provides summaries of the validation results for the entire PDB, for sets of molecules sharing the same annotation (three-letter code) or the same PDB entry, and for user-defined selections of annotations or PDB entries., (© The Author(s) 2014. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2015
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33. Anatomy of enzyme channels.

Author

Pravda L, Berka K, Svobodová Vařeková R, Sehnal D, Banáš P, Laskowski RA, Koča J, and Otyepka M

Subjects
Amino Acids genetics, Catalytic Domain, Enzymes genetics, Humans, Models, Molecular, Protein Conformation, Amino Acids chemistry, Enzymes chemistry, Ion Channels physiology
Abstract

Background: Enzyme active sites can be connected to the exterior environment by one or more channels passing through the protein. Despite our current knowledge of enzyme structure and function, surprisingly little is known about how often channels are present or about any structural features such channels may have in common., Results: Here, we analyze the long channels (i.e. >15 Å) leading to the active sites of 4,306 enzyme structures. We find that over 64% of enzymes contain two or more long channels, their typical length being 28 Å. We show that amino acid compositions of the channel significantly differ both to the composition of the active site, surface and interior of the protein., Conclusions: The majority of enzymes have buried active sites accessible via a network of access channels. This indicates that enzymes tend to have buried active sites, with channels controlling access to, and egress from, them, and that suggests channels may play a key role in helping determine enzyme substrate.

Published
2014
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34. MotiveValidator: interactive web-based validation of ligand and residue structure in biomolecular complexes.

Author

Vařeková RS, Jaiswal D, Sehnal D, Ionescu CM, Geidl S, Pravda L, Horský V, Wimmerová M, and Koča J

Subjects
Acetylglucosamine chemistry, Binding Sites, Cholic Acid chemistry, Ephrin-B3 chemistry, Glycoproteins chemistry, Internet, Ligands, Proteins chemistry, Macromolecular Substances chemistry, Software
Abstract

Structure validation has become a major issue in the structural biology community, and an essential step is checking the ligand structure. This paper introduces MotiveValidator, a web-based application for the validation of ligands and residues in PDB or PDBx/mmCIF format files provided by the user. Specifically, MotiveValidator is able to evaluate in a straightforward manner whether the ligand or residue being studied has a correct annotation (3-letter code), i.e. if it has the same topology and stereochemistry as the model ligand or residue with this annotation. If not, MotiveValidator explicitly describes the differences. MotiveValidator offers a user-friendly, interactive and platform-independent environment for validating structures obtained by any type of experiment. The results of the validation are presented in both tabular and graphical form, facilitating their interpretation. MotiveValidator can process thousands of ligands or residues in a single validation run that takes no more than a few minutes. MotiveValidator can be used for testing single structures, or the analysis of large sets of ligands or fragments prepared for binding site analysis, docking or virtual screening. MotiveValidator is freely available via the Internet at http://ncbr.muni.cz/MotiveValidator., (© The Author(s) 2014. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2014
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35. MOLE 2.0: advanced approach for analysis of biomacromolecular channels.

Author

Sehnal D, Svobodová Vařeková R, Berka K, Pravda L, Navrátilová V, Banáš P, Ionescu CM, Otyepka M, and Koča J

Abstract

Background: Channels and pores in biomacromolecules (proteins, nucleic acids and their complexes) play significant biological roles, e.g., in molecular recognition and enzyme substrate specificity., Results: We present an advanced software tool entitled MOLE 2.0, which has been designed to analyze molecular channels and pores. Benchmark tests against other available software tools showed that MOLE 2.0 is by comparison quicker, more robust and more versatile. As a new feature, MOLE 2.0 estimates physicochemical properties of the identified channels, i.e., hydropathy, hydrophobicity, polarity, charge, and mutability. We also assessed the variability in physicochemical properties of eighty X-ray structures of two members of the cytochrome P450 superfamily., Conclusion: Estimated physicochemical properties of the identified channels in the selected biomacromolecules corresponded well with the known functions of the respective channels. Thus, the predicted physicochemical properties may provide useful information about the potential functions of identified channels. The MOLE 2.0 software is available at http://mole.chemi.muni.cz.

Published
2013
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36. Predicting p Ka values from EEM atomic charges.

Author

Vařeková RS, Geidl S, Ionescu CM, Skřehota O, Bouchal T, Sehnal D, Abagyan R, and Koča J

Abstract

: The acid dissociation constant p Ka is a very important molecular property, and there is a strong interest in the development of reliable and fast methods for p Ka prediction. We have evaluated the p Ka prediction capabilities of QSPR models based on empirical atomic charges calculated by the Electronegativity Equalization Method (EEM). Specifically, we collected 18 EEM parameter sets created for 8 different quantum mechanical (QM) charge calculation schemes. Afterwards, we prepared a training set of 74 substituted phenols. Additionally, for each molecule we generated its dissociated form by removing the phenolic hydrogen. For all the molecules in the training set, we then calculated EEM charges using the 18 parameter sets, and the QM charges using the 8 above mentioned charge calculation schemes. For each type of QM and EEM charges, we created one QSPR model employing charges from the non-dissociated molecules (three descriptor QSPR models), and one QSPR model based on charges from both dissociated and non-dissociated molecules (QSPR models with five descriptors). Afterwards, we calculated the quality criteria and evaluated all the QSPR models obtained. We found that QSPR models employing the EEM charges proved as a good approach for the prediction of p Ka (63% of these models had R2 > 0.9, while the best had R2 = 0.924). As expected, QM QSPR models provided more accurate p Ka predictions than the EEM QSPR models but the differences were not significant. Furthermore, a big advantage of the EEM QSPR models is that their descriptors (i.e., EEM atomic charges) can be calculated markedly faster than the QM charge descriptors. Moreover, we found that the EEM QSPR models are not so strongly influenced by the selection of the charge calculation approach as the QM QSPR models. The robustness of the EEM QSPR models was subsequently confirmed by cross-validation. The applicability of EEM QSPR models for other chemical classes was illustrated by a case study focused on carboxylic acids. In summary, EEM QSPR models constitute a fast and accurate p Ka prediction approach that can be used in virtual screening.

Published
2013
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37. Predicting pK(a) values of substituted phenols from atomic charges: comparison of different quantum mechanical methods and charge distribution schemes.

Author

Svobodová Vareková R, Geidl S, Ionescu CM, Skrehota O, Kudera M, Sehnal D, Bouchal T, Abagyan R, Huber HJ, and Koca J

Subjects
Chemistry, Pharmaceutical statistics & numerical data, Computer Simulation, Kinetics, Models, Chemical, Models, Statistical, Molecular Conformation, Pharmaceutical Preparations chemistry, Phenols chemistry, Quantitative Structure-Activity Relationship, Quantum Theory, Static Electricity, Chemistry, Pharmaceutical methods, Pharmaceutical Preparations analysis, Phenols analysis
Abstract

The acid dissociation (ionization) constant pK(a) is one of the fundamental properties of organic molecules. We have evaluated different computational strategies and models to predict the pK(a) values of substituted phenols using partial atomic charges. Partial atomic charges for 124 phenol molecules were calculated using 83 approaches containing seven theory levels (MP2, HF, B3LYP, BLYP, BP86, AM1, and PM3), three basis sets (6-31G*, 6-311G, STO-3G), and five population analyses (MPA, NPA, Hirshfeld, MK, and Löwdin). The correlations between pK(a) and various atomic charge descriptors were examined, and the best descriptors were selected for preparing the quantitative structure-property relationship (QSPR) models. One QSPR model was created for each of the 83 approaches to charge calculation, and then the accuracy of all these models was analyzed and compared. The pK(a)s predicted by most of the models correlate strongly with experimental pK(a) values. For example, more than 25% of the models have correlation coefficients (R²) greater than 0.95 and root-mean-square errors smaller than 0.49. All seven examined theory levels are applicable for pK(a) prediction from charges. The best results were obtained for the MP2 and HF level of theory. The most suitable basis set was found to be 6-31G*. The 6-311G basis set provided slightly weaker correlations, and unexpectedly also, the STO-3G basis set is applicable for the QSPR modeling of pK(a). The Mulliken, natural, and Löwdin population analyses provide accurate models for all tested theory levels and basis sets. The results provided by the Hirshfeld population analysis were also acceptable, but the QSPR models based on MK charges show only weak correlations.

Published
2011
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