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2. ELIXIR and Toxicology: a community in development [version 2; peer review: 2 approved]

Author

Martens, M., Stierum, R., Schymanski, E.L., Evelo, C.T., Aalizadeh, R., Aladjov, H., Arturi, K., Audouze, K., Babica, P., Berka, K., Bessems, J., Blaha, L., Bolton, E.E., Cases, M., Damalas, D.E., Dave, K., Dilger, M., Exner, T., Geerke, D.P., Grafström, R., Gray, A., Hancock, J.M., Hollert, H., Jeliazkova, N., Jennen, D., Jourdan, F., Kahlem, P., Klanova, J., Kleinjans, J., Kondic, T., Kone, B., Lynch, I., Maran, U., Martinez Cuesta, S., Ménager, H., Neumann, S., Nymark, P., Oberacher, H., Ramirez, N., Remy, S., Rocca-Serra, P., Salek, R.M., Sallach, B., Sansone, S.-A., Sanz, F., Sarimveis, H., Sarntivijai, S., Schulze, Tobias, Slobodnik, J., Spjuth, O., Tedds, J., Thomaidis, N., Weber, R.J.M., van Westen, G.J.P., Wheelock, C.E., Williams, A.J., Witters, H., Zdrazil, B., Županič, A., Willighagen, E.L., Martens, M., Stierum, R., Schymanski, E.L., Evelo, C.T., Aalizadeh, R., Aladjov, H., Arturi, K., Audouze, K., Babica, P., Berka, K., Bessems, J., Blaha, L., Bolton, E.E., Cases, M., Damalas, D.E., Dave, K., Dilger, M., Exner, T., Geerke, D.P., Grafström, R., Gray, A., Hancock, J.M., Hollert, H., Jeliazkova, N., Jennen, D., Jourdan, F., Kahlem, P., Klanova, J., Kleinjans, J., Kondic, T., Kone, B., Lynch, I., Maran, U., Martinez Cuesta, S., Ménager, H., Neumann, S., Nymark, P., Oberacher, H., Ramirez, N., Remy, S., Rocca-Serra, P., Salek, R.M., Sallach, B., Sansone, S.-A., Sanz, F., Sarimveis, H., Sarntivijai, S., Schulze, Tobias, Slobodnik, J., Spjuth, O., Tedds, J., Thomaidis, N., Weber, R.J.M., van Westen, G.J.P., Wheelock, C.E., Williams, A.J., Witters, H., Zdrazil, B., Županič, A., and Willighagen, E.L.

Abstract

Toxicology has been an active research field for many decades, with academic, industrial and government involvement. Modern omics and computational approaches are changing the field, from merely disease-specific observational models into target-specific predictive models. Traditionally, toxicology has strong links with other fields such as biology, chemistry, pharmacology and medicine. With the rise of synthetic and new engineered materials, alongside ongoing prioritisation needs in chemical risk assessment for existing chemicals, early predictive evaluations are becoming of utmost importance to both scientific and regulatory purposes. ELIXIR is an intergovernmental organisation that brings together life science resources from across Europe. To coordinate the linkage of various life science efforts around modern predictive toxicology, the establishment of a new ELIXIR Community is seen as instrumental. In the past few years, joint efforts, building on incidental overlap, have been piloted in the context of ELIXIR. For example, the EU-ToxRisk, diXa, HeCaToS, transQST, and the nanotoxicology community have worked with the ELIXIR TeSS, Bioschemas, and Compute Platforms and activities. In 2018, a core group of interested parties wrote a proposal, outlining a sketch of what this new ELIXIR Toxicology Community would look like. A recent workshop (held September 30th to October 1st, 2020) extended this into an ELIXIR Toxicology roadmap and a shortlist of limited investment-high gain collaborations to give body to this new community. This Whitepaper outlines the results of these efforts and defines our vision of the ELIXIR Toxicology Community and how it complements other ELIXIR activities.

Published
2021

4. PDBe-KB: a community-driven resource for structural and functional annotations

Author

Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Varadi, M., Berrisford, J., Deshpande, M., Nair, S. S., Gutmanas, A., Armstrong, D., Pravda, L., Al-Lazikani, B., Anyango, S., Barton, G. J., Berka, K., Blundell, T., Borkakoti, N., Dana, J., Das, S., Dey, S., Micco, P. D., Fraternali, F., Gibson, T., Helmer-Citterich, M., Hoksza, David, Huang, L. C., Jain, R., Jubb, H., Kannas, C., Kannan, N., Koca, J., Krivak, R., Kumar, M., Levy, E. D., Madeira, F., Madhusudhan, M. S., Martell, H. J., MacGowan, S., McGreig, J. E., Mir, S., Mukhopadhyay, A., Parca, L., Paysan-Lafosse, T., Radusky, L., Ribeiro, A., Serrano, L., Sillitoe, I., Singh, G., Skoda, P., Svobodova, R., Tyzack, J., Valencia, A., Fernandez, E. V., Vranken, W., Wass, M., Thornton, J., Sternberg, M., Orengo, C., Velankar, S., Luxembourg Centre for Systems Biomedicine (LCSB): Bioinformatics Core (R. Schneider Group) [research center], Varadi, M., Berrisford, J., Deshpande, M., Nair, S. S., Gutmanas, A., Armstrong, D., Pravda, L., Al-Lazikani, B., Anyango, S., Barton, G. J., Berka, K., Blundell, T., Borkakoti, N., Dana, J., Das, S., Dey, S., Micco, P. D., Fraternali, F., Gibson, T., Helmer-Citterich, M., Hoksza, David, Huang, L. C., Jain, R., Jubb, H., Kannas, C., Kannan, N., Koca, J., Krivak, R., Kumar, M., Levy, E. D., Madeira, F., Madhusudhan, M. S., Martell, H. J., MacGowan, S., McGreig, J. E., Mir, S., Mukhopadhyay, A., Parca, L., Paysan-Lafosse, T., Radusky, L., Ribeiro, A., Serrano, L., Sillitoe, I., Singh, G., Skoda, P., Svobodova, R., Tyzack, J., Valencia, A., Fernandez, E. V., Vranken, W., Wass, M., Thornton, J., Sternberg, M., Orengo, C., and Velankar, S.

Abstract

The Protein Data Bank in Europe-Knowledge Base (PDBe-KB, https://pdbe-kb.org) is a community-driven, collaborative resource for literature-derived, manually curated and computationally predicted structural and functional annotations of macromolecular structure data, contained in the Protein Data Bank (PDB). The goal of PDBe-KB is two-fold: (i) to increase the visibility and reduce the fragmentation of annotations contributed by specialist data resources, and to make these data more findable, accessible, interoperable and reusable (FAIR) and (ii) to place macromolecular structure data in their biological context, thus facilitating their use by the broader scientific community in fundamental and applied research. Here, we describe the guidelines of this collaborative effort, the current status of contributed data, and the PDBe-KB infrastructure, which includes the data exchange format, the deposition system for added value annotations, the distributable database containing the assembled data, and programmatic access endpoints. We also describe a series of novel web-pages—the PDBe-KB aggregated views of structure data—which combine information on macromolecular structures from many PDB entries. We have recently released the first set of pages in this series, which provide an overview of available structural and functional information for a protein of interest, referenced by a UniProtKB accession.

Published
2019

7. Tools and data services registry: a community effort to document bioinformatics resources

Author

Ison, J., Rapacki, K., Menager, H., Kalas, M., Rydza, E., Chmura, P., Anthon, C., Beard, N., Berka, K., Bolser, D., Booth, T., Bretaudeau, A., Brezovsky, J., Casadio, R., Cesareni, G., Coppens, F., Cornell, M., Cuccuru, G., Davidsen, K., Vedova, G.D., Dogan, T., Doppelt-Azeroual, O., Emery, L., Gasteiger, E., Gatter, T., Goldberg, T., Grosjean, M., Gruning, B., Helmer-Citterich, M., Ienasescu, H., Ioannidis, V., Jespersen, M.C., Jimenez, R., Juty, N., Juvan, P., Koch, M., Laibe, C., Li, J.W., Licata, L., Mareuil, F., Micetic, I., Friborg, R.M., Moretti, S., Morris, C., Moller, S., Nenadic, A., Peterson, H., Profiti, G., Rice, P., Romano, P., Roncaglia, P., Saidi, R., Schafferhans, A., Schwammle, V., Smith, C., Sperotto, M.M., Stockinger, H., Varekova, R.S., Tosatto, S.C., Torre, V., Uva, P., Via, A., Yachdav, G., Zambelli, F., Vriend, G., Rost, B., Parkinson, H., Longreen, P., Brunak, S., Ison, J., Rapacki, K., Menager, H., Kalas, M., Rydza, E., Chmura, P., Anthon, C., Beard, N., Berka, K., Bolser, D., Booth, T., Bretaudeau, A., Brezovsky, J., Casadio, R., Cesareni, G., Coppens, F., Cornell, M., Cuccuru, G., Davidsen, K., Vedova, G.D., Dogan, T., Doppelt-Azeroual, O., Emery, L., Gasteiger, E., Gatter, T., Goldberg, T., Grosjean, M., Gruning, B., Helmer-Citterich, M., Ienasescu, H., Ioannidis, V., Jespersen, M.C., Jimenez, R., Juty, N., Juvan, P., Koch, M., Laibe, C., Li, J.W., Licata, L., Mareuil, F., Micetic, I., Friborg, R.M., Moretti, S., Morris, C., Moller, S., Nenadic, A., Peterson, H., Profiti, G., Rice, P., Romano, P., Roncaglia, P., Saidi, R., Schafferhans, A., Schwammle, V., Smith, C., Sperotto, M.M., Stockinger, H., Varekova, R.S., Tosatto, S.C., Torre, V., Uva, P., Via, A., Yachdav, G., Zambelli, F., Vriend, G., Rost, B., Parkinson, H., Longreen, P., and Brunak, S.

Abstract

Contains fulltext : 171819.pdf (publisher's version ) (Open Access), Life sciences are yielding huge data sets that underpin scientific discoveries fundamental to improvement in human health, agriculture and the environment. In support of these discoveries, a plethora of databases and tools are deployed, in technically complex and diverse implementations, across a spectrum of scientific disciplines. The corpus of documentation of these resources is fragmented across the Web, with much redundancy, and has lacked a common standard of information. The outcome is that scientists must often struggle to find, understand, compare and use the best resources for the task at hand.Here we present a community-driven curation effort, supported by ELIXIR-the European infrastructure for biological information-that aspires to a comprehensive and consistent registry of information about bioinformatics resources. The sustainable upkeep of this Tools and Data Services Registry is assured by a curation effort driven by and tailored to local needs, and shared amongst a network of engaged partners.As of November 2015, the registry includes 1785 resources, with depositions from 126 individual registrations including 52 institutional providers and 74 individuals. With community support, the registry can become a standard for dissemination of information about bioinformatics resources: we welcome everyone to join us in this common endeavour. The registry is freely available at https://bio.tools.

Published
2016

8. Tools and data services registry: A community effort to document bioinformatics resources

Author

Ison, J, Rapacki, K, Ménager, H, Kalaš, M, Rydza, E, Chmura, P, Anthon, C, Beard, N, Berka, K, Bolser, D, Booth, T, Bretaudeau, A, Brezovsky, J, Casadio, R, Cesareni, G, Coppens, F, Cornell, M, Cuccuru, G, Davidsen, K, DELLA VEDOVA, G, Dogan, T, Doppelt Azeroual, O, Emery, L, Gasteiger, E, Gatter, T, Goldberg, T, Grosjean, M, Grüning, B, Helmer Citterich, M, Ienasescu, H, Ioannidis, V, Jespersen, M, Jimenez, R, Juty, N, Juvan, P, Koch, M, Laibe, C, Li, J, Licata, L, Mareuil, F, Mičetić, I, Friborg, R, Moretti, S, Morris, C, Möller, S, Nenadic, A, Peterson, H, Profiti, G, Rice, P, Romano, P, Roncaglia, P, Saidi, R, Schafferhans, A, Schwämmle, V, Smith, C, Sperotto, M, Stockinger, H, Vařeková, R, Tosatto, S, de la Torre, V, Uva, P, Via, A, Yachdav, G, Zambelli, F, Vriend, G, Rost, B, Parkinson, H, Løngreen, P, Brunak, S, DELLA VEDOVA, GIANLUCA, Brunak, S., Ison, J, Rapacki, K, Ménager, H, Kalaš, M, Rydza, E, Chmura, P, Anthon, C, Beard, N, Berka, K, Bolser, D, Booth, T, Bretaudeau, A, Brezovsky, J, Casadio, R, Cesareni, G, Coppens, F, Cornell, M, Cuccuru, G, Davidsen, K, DELLA VEDOVA, G, Dogan, T, Doppelt Azeroual, O, Emery, L, Gasteiger, E, Gatter, T, Goldberg, T, Grosjean, M, Grüning, B, Helmer Citterich, M, Ienasescu, H, Ioannidis, V, Jespersen, M, Jimenez, R, Juty, N, Juvan, P, Koch, M, Laibe, C, Li, J, Licata, L, Mareuil, F, Mičetić, I, Friborg, R, Moretti, S, Morris, C, Möller, S, Nenadic, A, Peterson, H, Profiti, G, Rice, P, Romano, P, Roncaglia, P, Saidi, R, Schafferhans, A, Schwämmle, V, Smith, C, Sperotto, M, Stockinger, H, Vařeková, R, Tosatto, S, de la Torre, V, Uva, P, Via, A, Yachdav, G, Zambelli, F, Vriend, G, Rost, B, Parkinson, H, Løngreen, P, Brunak, S, DELLA VEDOVA, GIANLUCA, and Brunak, S.

Abstract

Life sciences are yielding huge data sets that underpin scientific discoveries fundamental to improvement in human health, agriculture and the environment. In support of these discoveries, a plethora of databases and tools are deployed, in technically complex and diverse implementations, across a spectrum of scientific disciplines. The corpus of documentation of these resources is fragmented across the Web, with much redundancy, and has lacked a common standard of information. The outcome is that scientists must often struggle to find, understand, compare and use the best resources for the task at hand. Here we present a community-driven curation effort, supported by ELIXIR-the European infrastructure for biological information-that aspires to a comprehensive and consistent registry of information about bioinformatics resources. The sustainable upkeep of this Tools and Data Services Registry is assured by a curation effort driven by and tailored to local needs, and shared amongst a network of engaged partners. As of November 2015, the registry includes 1785 resources, with depositions from 126 individual registrations including 52 institutional providers and 74 individuals. With community support, the registry can become a standard for dissemination of information about bioinformatics resources: we welcome everyone to join us in this common endeavour. The registry is freely available at https://bio.tools.

Published
2016

11. The Role of Protein-Protein and Protein-Membrane Interactions on P450 Function

Author

Scott, E. E., primary, Wolf, C. R., additional, Otyepka, M., additional, Humphreys, S. C., additional, Reed, J. R., additional, Henderson, C. J., additional, McLaughlin, L. A., additional, Paloncyova, M., additional, Navratilova, V., additional, Berka, K., additional, Anzenbacher, P., additional, Dahal, U. P., additional, Barnaba, C., additional, Brozik, J. A., additional, Jones, J. P., additional, Estrada, D. F., additional, Laurence, J. S., additional, Park, J. W., additional, and Backes, W. L., additional

Published
2016
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14. Measurement of the characteristics of the quantitative resistance in plum to the plum pox virus and evidence for their interrelations.

Author

Meyer, U., Kleinhempel, H., Berka, K., Gruntzig, Maria Gruntzig, and Kegler, H.

Subjects
PLANT diseases, DISEASED plants, VIRUS diseases of plants, PLANT viruses, AGRICULTURAL virology
Abstract

Two plum clones, with different degrees of susceptibility towards the plum pox virus (PPV), were inoculated with either a weakly or strongly pathegonic strain of PPV. The symptoms which developed in the older leaves (i.e. the 3rd to 5th basal leaves) were measured by visual rating as well as with the aid of a UV-VIS-spectralphotometer SPECORD M 40. Additionally, the relative virus concentrations in these leaves were determined by ELISA. Significant differences were established between the infected leaves of the PPV-sensitive and PPV-resistant plum clones, irrespective of the method of measurement. The values recorded for the weakly and strongly pathogenic PPV strains were significantly different only with the PPV-sensitive clone. A significant correlation was established between the visual ratings and the colormetrical values or the ELISA-values, as well as between the individual colormetrical values a, L and b. In the system plum-PPV, the b-values are the most important in the evaluation of the severity of the symptoms and in the qualitative color changes. [ABSTRACT FROM AUTHOR]

Published
1989
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21. Tools and data services registry: a community effort to document bioinformatics resources

Author

Callum Smith, Paolo Uva, Thomas Gatter, Peter Løngreen, Peter Juvan, Hans Ienasescu, Giuseppe Profiti, Aleksandra Nenadic, Kristoffer Rapacki, Chris Morris, Paola Roncaglia, Steffen Möller, Laura Emery, Søren Brunak, Maria Maddalena Sperotto, Heinz Stockinger, Kristian Davidsen, Federico Zambelli, Helen Parkinson, Olivia Doppelt-Azeroual, Luana Licata, Tatyana Goldberg, Andrea Schafferhans, Elisabeth Gasteiger, Emil Karol Rydza, Camille Laibe, Victor De La Torre, Marie Grosjean, Manuela Helmer-Citterich, Hervé Ménager, Radka Svobodová Vařeková, Rafael C. Jimenez, Martin Closter Jespersen, Anthony Bretaudeau, Jan Brezovsky, Tunca Doğan, Matúš Kalaš, Peter M. Rice, Ivan Mičetić, Rune Møllegaard Friborg, Maximilian Koch, Silvio C. E. Tosatto, Nick Juty, Björn Grüning, Gianmauro Cuccuru, Frederik Coppens, Gianni Cesareni, Jon Ison, Rabie Saidi, Sébastien Moretti, Rita Casadio, Gert Vriend, Guy Yachdav, Niall Beard, Timothy F. Booth, Michael Cornell, Piotr Jaroslaw Chmura, Veit Schwämmle, Karel Berka, Dan Bolser, Vassilios Ioannidis, Jing-Woei Li, Burkhard Rost, Gianluca Della Vedova, Fabien Mareuil, Hedi Peterson, Allegra Via, Paolo Romano, Christian Anthon, Technical University of Denmark [Lyngby] (DTU), Institut Pasteur de Madagascar, Réseau International des Instituts Pasteur (RIIP), University of Bergen (UIB), University of Copenhagen = Københavns Universitet (KU), University of Manchester, Palacky University, European Bioinformatics Institute, NEBC Wallingford, Institut de Génétique, Environnement et Protection des Plantes (IGEPP), Institut National de la Recherche Agronomique (INRA)-Université de Rennes 1 (UR1), Université de Rennes (UNIV-RENNES)-Université de Rennes (UNIV-RENNES)-AGROCAMPUS OUEST, Masaryk University, University of Bologna, Università degli Studi di Roma Tor Vergata [Roma], Ghent University [Belgium] (UGENT), Flanders Institute for Biotechnology, CRS4 Bioinformat, Università degli studi di Milano-Bicocca, Swiss Institute of Bioinformatics, Universität Bielefeld = Bielefeld University, Tumor Biology Center, Centre National de la Recherche Scientifique (CNRS), University of Freiburg, University of Ljubljana, The Chinese University of Hong Kong [Hong Kong], Universita degli Studi di Padova, Bioinformatics Research Centre, Université de Lausanne, CCLRC Daresbury Laboratory, Universität zu Lübeck [Lübeck] - University of Lübeck [Lübeck], Universität Rostock, University of Tartu, Imperial College London, IRCCS Azienda Ospedaliera Universitaria Integrata San Martino (IRCCS AOU San Martino), University of Southern Denmark (SDU), WTCHG, Central European Institute of Technology [Brno] (CEITEC), Instituto Nacional de Bioinformática, Sapienza University of Rome (DIAG), Consiglio Nazionale delle Ricerche, University of Milan, Radboud University Nijmegen, Ison, J, Rapacki, K, Ménager, H, Kalaš, M, Rydza, E, Chmura, P, Anthon, C, Beard, N, Berka, K, Bolser, D, Booth, T, Bretaudeau, A, Brezovsky, J, Casadio, R, Cesareni, G, Coppens, F, Cornell, M, Cuccuru, G, Davidsen, K, DELLA VEDOVA, G, Dogan, T, Doppelt Azeroual, O, Emery, L, Gasteiger, E, Gatter, T, Goldberg, T, Grosjean, M, Grüning, B, Helmer Citterich, M, Ienasescu, H, Ioannidis, V, Jespersen, M, Jimenez, R, Juty, N, Juvan, P, Koch, M, Laibe, C, Li, J, Licata, L, Mareuil, F, Mičetić, I, Friborg, R, Moretti, S, Morris, C, Möller, S, Nenadic, A, Peterson, H, Profiti, G, Rice, P, Romano, P, Roncaglia, P, Saidi, R, Schafferhans, A, Schwämmle, V, Smith, C, Sperotto, M, Stockinger, H, Vařeková, R, Tosatto, S, de la Torre, V, Uva, P, Via, A, Yachdav, G, Zambelli, F, Vriend, G, Rost, B, Parkinson, H, Løngreen, P, Brunak, S, University of Bergen (UiB), Palacky University Olomouc, Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro)-Institut national d'enseignement supérieur pour l'agriculture, l'alimentation et l'environnement (Institut Agro), Masaryk University [Brno] (MUNI), Universiteit Gent = Ghent University [Belgium] (UGENT), Università degli Studi di Milano-Bicocca [Milano] (UNIMIB), Swiss Institute of Bioinformatics [Lausanne] (SIB), Université de Lausanne (UNIL), Universität zu Lübeck [Lübeck], Central European Institute of Technology [Brno] (CEITEC MU), Brno University of Technology [Brno] (BUT), Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome], Danmarks Tekniske Universitet = Technical University of Denmark (DTU), University of Copenhagen = Københavns Universitet (UCPH), Institut National de la Recherche Agronomique (INRA)-Université de Rennes (UR)-AGROCAMPUS OUEST, University of Bologna/Università di Bologna, Universiteit Gent = Ghent University (UGENT), Università degli Studi di Milano-Bicocca = University of Milano-Bicocca (UNIMIB), Université de Lausanne = University of Lausanne (UNIL), Università degli Studi di Padova = University of Padua (Unipd), Universität zu Lübeck = University of Lübeck [Lübeck], Università degli Studi di Roma 'La Sapienza' = Sapienza University [Rome] (UNIROMA), Università degli Studi di Milano = University of Milan (UNIMI), Ison, Jon, Rapacki, Kristoffer, Ménager, Hervé, Kalaš, Matúš, Rydza, Emil, Chmura, Piotr, Anthon, Christian, Beard, Niall, Berka, Karel, Bolser, Dan, Booth, Tim, Bretaudeau, Anthony, Brezovsky, Jan, Casadio, Rita, Cesareni, Gianni, Coppens, Frederik, Cornell, Michael, Cuccuru, Gianmauro, Davidsen, Kristian, Vedova, Gianluca Della, Dogan, Tunca, Doppelt-Azeroual, Olivia, Emery, Laura, Gasteiger, Elisabeth, Gatter, Thoma, Goldberg, Tatyana, Grosjean, Marie, Grüning, Björn, Helmer-Citterich, Manuela, Ienasescu, Han, Ioannidis, Vassilio, Jespersen, Martin Closter, Jimenez, Rafael, Juty, Nick, Juvan, Peter, Koch, Maximilian, Laibe, Camille, Li, Jing-Woei, Licata, Luana, Mareuil, Fabien, Mičetić, Ivan, Friborg, Rune Møllegaard, Moretti, Sebastien, Morris, Chri, Möller, Steffen, Nenadic, Aleksandra, Peterson, Hedi, Profiti, Giuseppe, Rice, Peter, Romano, Paolo, Roncaglia, Paola, Saidi, Rabie, Schafferhans, Andrea, Schwämmle, Veit, Smith, Callum, Sperotto, Maria Maddalena, Stockinger, Heinz, Vařeková, Radka Svobodová, Tosatto, Silvio C E, de la Torre, Victor, Uva, Paolo, Via, Allegra, Yachdav, Guy, Zambelli, Federico, Vriend, Gert, Rost, Burkhard, Parkinson, Helen, Løngreen, Peter, and Brunak, Søren

Subjects
0301 basic medicine, [SDV]Life Sciences [q-bio], registry, Bioinformatics, computer.software_genre, Matematikk og naturvitenskap: 400::Informasjons- og kommunikasjonsvitenskap: 420::Systemutvikling og -arbeid: 426 [VDP], Task (project management), Documentation, Data and Information, Database Issue, Registries, bioinformatique, Data Curation, base de données, Settore BIO/11, gestion de données, tool, SOFTWARE-DEVELOPMENT, bioinformatics, ddc, outil informatique, Tools and data services registry, SEQANSWERS, Web service, MOLECULAR-BIOLOGY, Biology, Ecology and Environment, 03 medical and health sciences, SDG 3 - Good Health and Well-being, Genetics, Implementation, Dissemination, Bioinformatikk / Bioinformatics, Data curation, bioinformatic, business.industry, Computational Biology, Software, Software development, bioinformatics, tools, registry, elixir, Biology and Life Sciences, Mathematics and natural scienses: 400::Information and communication science: 420::System development and design: 426 [VDP], FRAMEWORK, ELIXIR, Settore BIO/18 - Genetica, 030104 developmental biology, tools, Data as a service, COMPILATION, business, COLLECTION, Nanomedicine Radboud Institute for Molecular Life Sciences [Radboudumc 19], computer, WEB SERVICES, LIFE SCIENCES
Abstract

Contains fulltext : 171819.pdf (Publisher’s version ) (Open Access) Life sciences are yielding huge data sets that underpin scientific discoveries fundamental to improvement in human health, agriculture and the environment. In support of these discoveries, a plethora of databases and tools are deployed, in technically complex and diverse implementations, across a spectrum of scientific disciplines. The corpus of documentation of these resources is fragmented across the Web, with much redundancy, and has lacked a common standard of information. The outcome is that scientists must often struggle to find, understand, compare and use the best resources for the task at hand.Here we present a community-driven curation effort, supported by ELIXIR-the European infrastructure for biological information-that aspires to a comprehensive and consistent registry of information about bioinformatics resources. The sustainable upkeep of this Tools and Data Services Registry is assured by a curation effort driven by and tailored to local needs, and shared amongst a network of engaged partners.As of November 2015, the registry includes 1785 resources, with depositions from 126 individual registrations including 52 institutional providers and 74 individuals. With community support, the registry can become a standard for dissemination of information about bioinformatics resources: we welcome everyone to join us in this common endeavour. The registry is freely available at https://bio.tools.

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22. Meta-Analysis of Permeability Literature Data Shows Possibilities and Limitations of Popular Methods.

Author

Storchmannová K, Balouch M, Juračka J, Štěpánek F, and Berka K

Subjects
Humans, Caco-2 Cells, Dogs, Animals, Cell Membrane Permeability physiology, Madin Darby Canine Kidney Cells, Blood-Brain Barrier metabolism, Membranes, Artificial, Permeability, Liposomes chemistry
Abstract

Permeability is an important molecular property in drug discovery, as it co-determines pharmacokinetics whenever a drug crosses the phospholipid bilayer, e.g., into the cell, in the gastrointestinal tract, or across the blood-brain barrier. Many methods for the determination of permeability have been developed, including cell line assays (CACO-2 and MDCK), cell-free model systems like parallel artificial membrane permeability assay (PAMPA) mimicking, e.g., gastrointestinal epithelia or the skin, as well as the black lipid membrane (BLM) and submicrometer liposomes. Furthermore, many in silico approaches have been developed for permeability prediction: meta-analysis of publicly available databases for permeability data (MolMeDB and ChEMBL) was performed to establish their usability. Four experimental and two computational methods were evaluated. It was shown that repeatability of the reported permeability measurement is not great even for the same method. For the PAMPA method, two different permeabilities are reported: intrinsic and apparent. They can vary in degrees of magnitude; thus, we suggest being extra cautious using literature data on permeability. When we compared data for the same molecules using different methods, the best agreement was between cell-based methods and between BLM and computational methods. Existence of unstirred water layer (UWL) permeability limits the data agreement between cell-based methods (and apparent PAMPA) with data that are not limited by UWL permeability (computational methods, BLM, intrinsic PAMPA). Therefore, different methods have different limitations. Cell-based methods provide results only in a small range of permeabilities (-8 to -4 in cm/s), and computational methods can predict a wider range of permeabilities beyond physical limitations, but their precision is therefore limited. BLM with liposomes can be used for both fast and slow permeating molecules, but its usage is more complicated than standard transwell techniques. To sum up, when working with in-house measured or published permeability data, we recommend caution in interpreting and combining them.

Published
2025
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23. Liposomal Copermeation Assay Reveals Unexpected Membrane Interactions of Commonly Prescribed Drugs.

Author

Odehnalová K, Balouch M, Storchmannová K, Petrová E, Konefał M, Zadražil A, Berka K, Brus J, and Štěpánek F

Subjects
Lipid Bilayers metabolism, Humans, Phospholipids chemistry, Prescription Drugs pharmacokinetics, Prescription Drugs chemistry, Fluorescent Dyes pharmacokinetics, Fluorescent Dyes chemistry, Cell Membrane metabolism, Permeability, Liposomes chemistry
Abstract

The permeation of small molecules across biological membranes is a crucial process that lies at the heart of life. Permeation is involved not only in the maintenance of homeostasis at the cell level but also in the absorption and biodistribution of pharmacologically active substances throughout the human body. Membranes are formed by phospholipid bilayers that represent an energy barrier for permeating molecules. Crossing this energy barrier is assumed to be a singular event, and permeation has traditionally been described as a first-order kinetic process, proportional only to the concentration gradient of the permeating substance. For a given membrane composition, permeability was believed to be a unique property dependent only on the permeating molecule itself. We provide experimental evidence that this long-held view might not be entirely correct. Liposomes were used in copermeation experiments with a fluorescent probe, where simultaneous permeation of two substances occurred over a single phospholipid bilayer. Using an assay of six commonly prescribed drugs, we have found that the presence of a copermeant can either enhance or suppress the permeation rate of the probe molecule, often more than 2-fold in each direction. This can have significant consequences for the pharmacokinetics and bioavailability of commonly prescribed drugs when used in combination and provide new insight into so-far unexplained drug-drug interactions as well as changing the perspective on how new drug candidates are evaluated and tested.

Published
2024
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24. 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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25. 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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26. Expanding the squaramide library as mycobacterial ATP synthase inhibitors: Innovative synthetic pathway and biological evaluation.

Author

Chasák J, Oorts L, Dak M, Šlachtová V, Bazgier V, Berka K, De Vooght L, Smiejkowska N, Calster KV, Van Moll L, Cappoen D, Cos P, and Brulíková L

Subjects
Humans, Adenosine Triphosphate metabolism, Antitubercular Agents chemistry, Mitochondrial Proton-Translocating ATPases chemistry, Mitochondrial Proton-Translocating ATPases metabolism, Mycobacterium tuberculosis, Tuberculosis, Multidrug-Resistant
Abstract

Mycobacterial ATP synthase is a validated therapeutic target for combating drug-resistant tuberculosis. Inhibition of this enzyme has been featured as an efficient strategy for the development of new antimycobacterial agents against drug-resistant pathogens. In this study, we synthesised and explored two distinct series of squaric acid analogues designed to inhibit mycobacterial ATP synthase. Among the extensive array of compounds investigated, members of the phenyl-substituted sub-library emerged as primary hits. To gain deeper insights into their mechanisms of action, we conducted advanced biological studies, focusing on the compounds displaying a direct binding of a nitrogen heteroatom to the phenyl ring, resulting in the highest potency. Our investigations into spontaneous mutants led to the validation of a single point mutation within the atpB gene (Rv1304), responsible for encoding the ATP synthase subunit a. This genetic alteration sheds light on the molecular basis of resistance to squaramides. Furthermore, we explored the possibility of synergy between squaramides and the reference drug clofazimine using a checkerboard assay, highlighting the promising avenue for enhancing the effectiveness of existing treatments through combined therapeutic approaches. This study contributes to the expansion of investigating squaramides as promising drug candidates in the ongoing battle against drug-resistant tuberculosis., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 Elsevier Ltd. All rights reserved.)

Published
2023
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27. ELIXIR and Toxicology: a community in development.

Author

Martens M, Stierum R, Schymanski EL, Evelo CT, Aalizadeh R, Aladjov H, Arturi K, Audouze K, Babica P, Berka K, Bessems J, Blaha L, Bolton EE, Cases M, Damalas DΕ, Dave K, Dilger M, Exner T, Geerke DP, Grafström R, Gray A, Hancock JM, Hollert H, Jeliazkova N, Jennen D, Jourdan F, Kahlem P, Klanova J, Kleinjans J, Kondic T, Kone B, Lynch I, Maran U, Martinez Cuesta S, Ménager H, Neumann S, Nymark P, Oberacher H, Ramirez N, Remy S, Rocca-Serra P, Salek RM, Sallach B, Sansone SA, Sanz F, Sarimveis H, Sarntivijai S, Schulze T, Slobodnik J, Spjuth O, Tedds J, Thomaidis N, Weber RJM, van Westen GJP, Wheelock CE, Williams AJ, Witters H, Zdrazil B, Županič A, and Willighagen EL

Subjects
Europe, Risk Assessment, Biological Science Disciplines
Abstract

Toxicology has been an active research field for many decades, with academic, industrial and government involvement. Modern omics and computational approaches are changing the field, from merely disease-specific observational models into target-specific predictive models. Traditionally, toxicology has strong links with other fields such as biology, chemistry, pharmacology and medicine. With the rise of synthetic and new engineered materials, alongside ongoing prioritisation needs in chemical risk assessment for existing chemicals, early predictive evaluations are becoming of utmost importance to both scientific and regulatory purposes. ELIXIR is an intergovernmental organisation that brings together life science resources from across Europe. To coordinate the linkage of various life science efforts around modern predictive toxicology, the establishment of a new ELIXIR Community is seen as instrumental. In the past few years, joint efforts, building on incidental overlap, have been piloted in the context of ELIXIR. For example, the EU-ToxRisk, diXa, HeCaToS, transQST, and the nanotoxicology community have worked with the ELIXIR TeSS, Bioschemas, and Compute Platforms and activities. In 2018, a core group of interested parties wrote a proposal, outlining a sketch of what this new ELIXIR Toxicology Community would look like. A recent workshop (held September 30th to October 1st, 2020) extended this into an ELIXIR Toxicology roadmap and a shortlist of limited investment-high gain collaborations to give body to this new community. This Whitepaper outlines the results of these efforts and defines our vision of the ELIXIR Toxicology Community and how it complements other ELIXIR activities., Competing Interests: No competing interests were disclosed., (Copyright: © 2023 Martens M et al.)

Published
2023
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28. Small change - big consequence: The impact of C15-C16 double bond in a D‑ring of estrone on estrogen receptor activity.

Author

Vonka P, Rarova L, Bazgier V, Tichy V, Kolarova T, Holcakova J, Berka K, Kvasnica M, Oklestkova J, Kudova E, Strnad M, and Hrstka R

Subjects
Humans, Female, Fulvestrant pharmacology, Fulvestrant therapeutic use, Receptors, Estrogen metabolism, Molecular Docking Simulation, Cell Line, Tumor, Tamoxifen pharmacology, Estrogen Receptor alpha genetics, Estrogen Receptor alpha metabolism, Estradiol pharmacology, Estradiol therapeutic use, Estrone pharmacology, Breast Neoplasms drug therapy, Breast Neoplasms metabolism
Abstract

Estrogen receptor alpha (ER) is a key biomarker for breast cancer, and the presence or absence of ER in breast and other hormone-dependent cancers decides treatment regimens and patient prognosis. ER is activated after ligand binding - typically by steroid. 2682 steroid compounds were used in a molecular docking study to identify novel ligands for ER and to predict compounds that may show anticancer activity. The effect of the most promising compounds was determined by a novel luciferase reporter assay. Two compounds, 7 and 12, showing ER inhibitory activity comparable to clinical inhibitors such as tamoxifen or fulvestrant were selected. We propose that the inhibitory effect of compounds 7 and 12 on ER is related to the presence of a double bond in their D-ring, which may protect against ER activation by reducing the electron density of the keto group, or may undergo metabolism leading to an active compound. Western blotting revealed that compound 12 decreased the level of ER in the breast cancer cell line MCF7, which was associated with reduced expression of both isoforms of the progesterone receptor, a well-known downstream target of ER. However, compound 12 has a different mechanism of action from fulvestrant. Furthermore, we found that compound 12 interferes with mitochondrial functions, probably by disrupting the electron transport chain, leading to induction of the intrinsic apoptotic pathway even in ER-negative breast cancer cells. In conclusion, the combination of computational and experimental methods shown here represents a rapid approach to determine the activity of compounds towards ER. Our data will not only contribute to research focused on the regulation of ER activity but may also be useful for the further development of novel steroid receptor-targeted drugs applicable in clinical practice., Competing Interests: Declaration of Competing Interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier Ltd.. All rights reserved.)

Published
2023
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29. 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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30. αCharges: partial atomic charges for AlphaFold structures in high quality.

Author

Schindler O, Berka K, Cantara A, Křenek A, Tichý D, Raček T, and Svobodová R

Subjects
Humans, Algorithms, Proteome, Protein Conformation, Software, Proteins chemistry, Computational Biology instrumentation, Computational Biology methods
Abstract

The AlphaFold2 prediction algorithm opened up the possibility of exploring proteins' structural space at an unprecedented scale. Currently, >200 million protein structures predicted by this approach are deposited in AlphaFoldDB, covering entire proteomes of multiple organisms, including humans. Predicted structures are, however, stored without detailed functional annotations describing their chemical behaviour. Partial atomic charges, which map electron distribution over a molecule and provide a clue to its chemical reactivity, are an important example of such data. We introduce the web application αCharges: a tool for the quick calculation of partial atomic charges for protein structures from AlphaFoldDB. The charges are calculated by the recent empirical method SQE+qp, parameterised for this class of molecules using robust quantum mechanics charges (B3LYP/6-31G*/NPA) on PROPKA3 protonated structures. The computed partial atomic charges can be downloaded in common data formats or visualised via the powerful Mol* viewer. The αCharges application is freely available at https://alphacharges.ncbr.muni.cz with no login requirement., (© The Author(s) 2023. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2023
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31. Computational Prodrug Design Methodology for Liposome Formulability Enhancement of Small-Molecule APIs.

Author

Balouch M, Storchmannová K, Štěpánek F, and Berka K

Subjects
Tissue Distribution, Lipid Bilayers chemistry, Fluorouracil, Permeability, Liposomes chemistry, Prodrugs chemistry
Abstract

Encapsulation into liposomes is a formulation strategy that can improve efficacy and reduce side effects of active pharmaceutical ingredients (APIs) that exhibit poor biodistribution or pharmacokinetics when administered alone. However, many APIs are unsuitable for liposomal formulations intended for parenteral administration due to their inherent physicochemical properties─lipid bilayer permeability and water-lipid equilibrium partitioning coefficient. Too high permeability results in premature leakage from liposomes, while too low permeability means the API is not able to pass across biological barriers. There are several options for solving this issue: (i) change of the lipid bilayer composition, (ii) addition of a permeability enhancer, or (iii) modification of the chemical structure of the API to design a prodrug. The latter approach was taken in the present work, and the effect of small changes in the molecular structure of the API on its permeation rate across a lipidic bilayer was systematically explored utilizing computer simulations. An in silico methodology for prodrug design based on the COSMOperm approach has been proposed and applied to four APIs (abiraterone, cytarabine, 5-fluorouracil, and paliperidone). It is shown that the addition of aliphatic hydrocarbon chains via ester or amide bonds can render the molecule more lipophilic and increase its permeability by approximately 1 order of magnitude for each 2 carbon atoms added, while the formation of fructose adducts can provide a more hydrophilic character to the molecule and reduce its lipid partitioning. While partitioning was found to depend only on the size and type of the added group, permeability was found to depend also on the added group location. Overall, it has been shown that both permeability and lipid partitioning coefficient can be systematically shifted into the desired liposome formulability window by appropriate group contributions to the parental drug. This can significantly increase the portfolio of APIs for which liposome or lipid nanoparticle formulations become feasible.

Published
2023
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32. Novel heterocyclic hydroxamates as inhibitors of the mycobacterial zinc metalloprotease Zmp1 to probe its mechanism of function.

Author

Dak M, Šlachtová V, Šebela M, Bazgier V, Berka K, Smiejkowska N, Oorts L, Cappoen D, and Brulíková L

Subjects
Humans, Mice, Animals, Zinc metabolism, Metalloproteases metabolism, Bacterial Proteins, Hydroxamic Acids pharmacology, Mycobacterium tuberculosis, Thiazolidinediones pharmacology
Abstract

Mycobacterial zinc metalloprotease-1 (Zmp1) is an essential enzyme for intracellular survival and pathogenicity of Mycobacterium tuberculosis. However, the exact mechanism of function of this enzyme remains unclear. This paper examines the effect of novel organic molecules on the inhibition of Zmp1. We followed our previous results and synthesised three libraries of new hydroxamates. All compounds were studied for their inhibitory properties towards a recombinant Zmp1 from Mycobacterium tuberculosis by MALDI-TOF MS. Furthermore, a macrophage infection assay was performed to evaluate intracellular antimycobacterial activity. In the whole-cell assay, no direct activity of synthesised heterocyclic hydroxamates was observed against Mycobacterium tuberculosis and Mycobacterium bovis. No acute cellular toxicity was observed against the murine RAW 264.7 macrophage cell line and human MRC-5 lung fibroblast cell line. However, thiazolidinediones 2 showed the dose-dependent inhibition of intracellular survival of Mycobacterium tuberculosis H37Ra. The inhibition was structure-dependent, with the most active derivative 2f inducing an 83.2% reduction of bacterial survival within the macrophage host cell. The promising biological activity confirmed thiazolidinediones 2 as Zmp1 inhibitors that can be used as tool compounds for further exploration of the role of Zmp1 for in vivo pathogenicity. In the long run, thiazolidinediones 2 show the potential to act as a scaffold for Zmp1 inhibitors to target intracellular Mtb as a novel tuberculosis treatment strategy., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2022 Elsevier Masson SAS. All rights reserved.)

Published
2022
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33. OverProt: secondary structure consensus for protein families.

Author

Midlik A, Hutařová Vařeková I, Hutař J, Chareshneu A, Berka K, and Svobodová R

Subjects
Consensus, Protein Structure, Secondary, Computers, Software, Proteins chemistry
Abstract

Summary: Every protein family has a set of characteristic secondary structures. However, due to individual variations, a single structure is not enough to represent the whole family. OverProt can create a secondary structure consensus, showing the general fold of the family as well as its variation. Our server provides precomputed results for all CATH superfamilies and user-defined computations, visualized by an interactive viewer, which shows the secondary structure element type, length, frequency of occurrence, spatial variability and β-connectivity., Availability and Implementation: OverProt Server is freely available at https://overprot.ncbr.muni.cz., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2022. Published by Oxford University Press. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published
2022
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34. Antitumour drugs targeting tau R3 VQIVYK and Cys322 prevent seeding of endogenous tau aggregates by exogenous seeds.

Author

Annadurai N, Malina L, Salmona M, Diomede L, Bastone A, Cagnotto A, Romeo M, Šrejber M, Berka K, Otyepka M, Hajdúch M, and Das V

Subjects
Brain metabolism, Humans, tau Proteins genetics, tau Proteins metabolism, Alzheimer Disease drug therapy, Alzheimer Disease pathology, Antineoplastic Agents pharmacology, Prions
Abstract

Emerging experimental evidence suggests tau pathology spreads between neuroanatomically connected brain regions in a prion-like manner in Alzheimer's disease (AD). Tau seeding, the ability of prion-like tau to recruit and misfold naïve tau to generate new seeds, is detected early in human AD brains before the development of major tau pathology. Many antitumour drugs have been reported to confer protection against neurodegeneration, supporting the repurposing of approved and experimental or investigational oncology drugs for AD therapy. In this study, we evaluated whether antitumour drugs that abrogate the generation of seed-competent aggregates of tau Repeat 3 (R3) domain peptides can prevent tau seeding and toxicity in Tau-RD P301S FRET Biosensor cells and Caenorhabditis elegans. We demonstrate that drugs that interact with the N-terminal VQIVYK or the C-terminal region housing the Cys322 prevent R3 dimerisation, abolishing the generation of prion-like R3 seeds. Preformed R3 seeds (fibrils) capped with, or R3 seeds formed in the presence of VQIVYK- or Cys322-targeting drugs have a reduced potency to cause aggregation of naïve tau in biosensor cells and protect worms from aggregate toxicity. These findings indicate that VQIVYK- or Cys322-targeting drugs may act as prophylactic agents against tau seeding., (© 2021 Federation of European Biochemical Societies.)

Published
2022
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35. 2DProts: database of family-wide protein secondary structure diagrams.

Author

Hutařová Vařeková I, Hutař J, Midlik A, Horský V, Hladká E, Svobodová R, and Berka K

Subjects
Protein Structure, Secondary, Databases, Factual, Software, Proteins chemistry
Abstract

Summary: Secondary structures provide a deep insight into the protein architecture. They can serve for comparison between individual protein family members. The most straightforward way how to deal with protein secondary structure is its visualization using 2D diagrams. Several software tools for the generation of 2D diagrams were developed. Unfortunately, they create 2D diagrams based on only a single protein. Therefore, 2D diagrams of two proteins from one family markedly differ. For this reason, we developed the 2DProts database, which contains secondary structure 2D diagrams for all domains from the CATH and all proteins from PDB databases. These 2D diagrams are generated based on a whole protein family, and they also consider information about the 3D arrangement of secondary structure elements. Moreover, 2DProts database contains multiple 2D diagrams, which provide an overview of a whole protein family's secondary structures. 2DProts is updated weekly and is integrated into CATH., Availability and Implementation: Freely accessible at https://2dprots.ncbr.muni.cz. The web interface was implemented in JavaScript. The database was implemented in Python., Supplementary Information: Supplementary data are available at Bioinformatics online., (© The Author(s) 2021. Published by Oxford University Press.)

Published
2021
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37. 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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38. Optimized SQE atomic charges for peptides accessible via a web application.

Author

Schindler O, Raček T, Maršavelski A, Koča J, Berka K, and Svobodová R

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.

Published
2021
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39. Uncovering of cytochrome P450 anatomy by SecStrAnnotator.

Author

Midlik A, Navrátilová V, Moturu TR, Koča J, Svobodová R, and Berka K

Subjects
Animals, Humans, Molecular Dynamics Simulation, Cytochrome P-450 Enzyme System chemistry, Sequence Analysis, Protein methods, Software
Abstract

Protein structural families are groups of homologous proteins defined by the organization of secondary structure elements (SSEs). Nowadays, many families contain vast numbers of structures, and the SSEs can help to orient within them. Communities around specific protein families have even developed specialized SSE annotations, always assigning the same name to the equivalent SSEs in homologous proteins. A detailed analysis of the groups of equivalent SSEs provides an overview of the studied family and enriches the analysis of any particular protein at hand. We developed a workflow for the analysis of the secondary structure anatomy of a protein family. We applied this analysis to the model family of cytochromes P450 (CYPs)-a family of important biotransformation enzymes with a community-wide used SSE annotation. We report the occurrence, typical length and amino acid sequence for the equivalent SSE groups, the conservation/variability of these properties and relationship to the substrate recognition sites. We also suggest a generic residue numbering scheme for the CYP family. Comparing the bacterial and eukaryotic part of the family highlights the significant differences and reveals a well-known anomalous group of bacterial CYPs with some typically eukaryotic features. Our workflow for SSE annotation for CYP and other families can be freely used at address https://sestra.ncbr.muni.cz .

Published
2021
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40. CATH: increased structural coverage of functional space.

Author

Sillitoe I, Bordin N, Dawson N, Waman VP, Ashford P, Scholes HM, Pang CSM, Woodridge L, Rauer C, Sen N, Abbasian M, Le Cornu S, Lam SD, Berka K, Varekova IH, Svobodova R, Lees J, and Orengo CA

Subjects
Amino Acid Sequence, COVID-19 epidemiology, COVID-19 prevention & control, COVID-19 virology, Computational Biology methods, Epidemics, Humans, Internet, Molecular Sequence Annotation, Proteins genetics, Proteins metabolism, SARS-CoV-2 genetics, SARS-CoV-2 metabolism, SARS-CoV-2 physiology, Sequence Analysis, Protein methods, Sequence Homology, Amino Acid, Viral Proteins chemistry, Viral Proteins genetics, Viral Proteins metabolism, Computational Biology statistics & numerical data, Databases, Protein statistics & numerical data, Protein Domains, Proteins chemistry
Abstract

CATH (https://www.cathdb.info) identifies domains in protein structures from wwPDB and classifies these into evolutionary superfamilies, thereby providing structural and functional annotations. There are two levels: CATH-B, a daily snapshot of the latest domain structures and superfamily assignments, and CATH+, with additional derived data, such as predicted sequence domains, and functionally coherent sequence subsets (Functional Families or FunFams). The latest CATH+ release, version 4.3, significantly increases coverage of structural and sequence data, with an addition of 65,351 fully-classified domains structures (+15%), providing 500 238 structural domains, and 151 million predicted sequence domains (+59%) assigned to 5481 superfamilies. The FunFam generation pipeline has been re-engineered to cope with the increased influx of data. Three times more sequences are captured in FunFams, with a concomitant increase in functional purity, information content and structural coverage. FunFam expansion increases the structural annotations provided for experimental GO terms (+59%). We also present CATH-FunVar web-pages displaying variations in protein sequences and their proximity to known or predicted functional sites. We present two case studies (1) putative cancer drivers and (2) SARS-CoV-2 proteins. Finally, we have improved links to and from CATH including SCOP, InterPro, Aquaria and 2DProt., (© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2021
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42. 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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43. Cytokinin fluoroprobe reveals multiple sites of cytokinin perception at plasma membrane and endoplasmic reticulum.

Author

Kubiasová K, Montesinos JC, Šamajová O, Nisler J, Mik V, Semerádová H, Plíhalová L, Novák O, Marhavý P, Cavallari N, Zalabák D, Berka K, Doležal K, Galuszka P, Šamaj J, Strnad M, Benková E, Plíhal O, and Spíchal L

Subjects
Arabidopsis cytology, Arabidopsis genetics, Arabidopsis metabolism, Arabidopsis Proteins genetics, Brefeldin A pharmacology, Cytokinins chemistry, Fluorescent Dyes metabolism, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Meristem cytology, Meristem metabolism, Plants, Genetically Modified, Protein Kinases genetics, Receptors, Cell Surface genetics, Recombinant Fusion Proteins genetics, Recombinant Fusion Proteins metabolism, Signal Transduction drug effects, Arabidopsis Proteins metabolism, Cell Membrane metabolism, Cytokinins metabolism, Endoplasmic Reticulum metabolism, Fluorescent Dyes chemistry, Protein Kinases metabolism, Receptors, Cell Surface metabolism
Abstract

Plant hormone cytokinins are perceived by a subfamily of sensor histidine kinases (HKs), which via a two-component phosphorelay cascade activate transcriptional responses in the nucleus. Subcellular localization of the receptors proposed the endoplasmic reticulum (ER) membrane as a principal cytokinin perception site, while study of cytokinin transport pointed to the plasma membrane (PM)-mediated cytokinin signalling. Here, by detailed monitoring of subcellular localizations of the fluorescently labelled natural cytokinin probe and the receptor ARABIDOPSIS HISTIDINE KINASE 4 (CRE1/AHK4) fused to GFP reporter, we show that pools of the ER-located cytokinin receptors can enter the secretory pathway and reach the PM in cells of the root apical meristem, and the cell plate of dividing meristematic cells. Brefeldin A (BFA) experiments revealed vesicular recycling of the receptor and its accumulation in BFA compartments. We provide a revised view on cytokinin signalling and the possibility of multiple sites of perception at PM and ER.

Published
2020
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44. Atomic Charge Calculator II: web-based tool for the calculation of partial atomic charges.

Author

Raček T, Schindler O, Toušek D, Horský V, Berka K, Koča J, and Svobodová R

Subjects
Hydrogen chemistry, Internet, Molecular Structure, Phenols chemistry, Receptors, Nicotinic chemistry, Static Electricity, bcl-2-Associated X Protein chemistry, Models, Molecular, Software
Abstract

Partial atomic charges serve as a simple model for the electrostatic distribution of a molecule that drives its interactions with its surroundings. Since partial atomic charges are frequently used in computational chemistry, chemoinformatics and bioinformatics, many computational approaches for calculating them have been introduced. The most applicable are fast and reasonably accurate empirical charge calculation approaches. Here, we introduce Atomic Charge Calculator II (ACC II), a web application that enables the calculation of partial atomic charges via all the main empirical approaches and for all types of molecules. ACC II implements 17 empirical charge calculation methods, including the highly cited (QEq, EEM), the recently published (EQeq, EQeq+C), and the old but still often used (PEOE). ACC II enables the fast calculation of charges even for large macromolecular structures. The web server also offers charge visualization, courtesy of the powerful LiteMol viewer. The calculation setup of ACC II is very straightforward and enables the quick calculation of high-quality partial charges. The application is available at https://acc2.ncbr.muni.cz., (© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published
2020
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45. Novel thiazolidinedione-hydroxamates as inhibitors of Mycobacterium tuberculosis virulence factor Zmp1.

Author

Šlachtová V, Šebela M, Torfs E, Oorts L, Cappoen D, Berka K, Bazgier V, and Brulíková L

Subjects
Antitubercular Agents chemical synthesis, Antitubercular Agents chemistry, Bacterial Proteins metabolism, Dose-Response Relationship, Drug, Humans, Hydroxamic Acids chemistry, Metalloproteases metabolism, Molecular Docking Simulation, Molecular Structure, Mycobacterium tuberculosis enzymology, Mycobacterium tuberculosis metabolism, Structure-Activity Relationship, Thiazolidinediones chemistry, Antitubercular Agents pharmacology, Bacterial Proteins antagonists & inhibitors, Hydroxamic Acids pharmacology, Metalloproteases antagonists & inhibitors, Mycobacterium tuberculosis drug effects, Thiazolidinediones pharmacology
Abstract

Zinc metalloprotease 1 (Zmp1) is an extracellular enzyme, which has been found essential for the intracellular survival and pathogenesis of Mycobacterium tuberculosis. In this work, we designed and synthesized a series of novel thiazolidinedione-hydroxamates and evaluated in silico their drug-likeness behavior. Then, their inhibitory properties towards a recombinant Zmp1 from Mycobacterium tuberculosis were analyzed by MALDI-TOF MS. Nine of the tested compounds were found to inhibit the enzymatic reaction more effectively than the generic metalloprotease inhibitor phosphoramidon. Furthermore, the synthesized thiazolidinedione-hydroxamate hybrids were evaluated for their in vitro antimycobacterial activity and acute cytotoxicity using whole-cell assays. Results showed that none of the hybrids exhibited acute cytotoxicity against RAW264.7 macrophages. Whereas extracellular antimycobacterial activity was limited, RAW264.7 macrophage infection results showed that a majority of the hybrids inhibited the intracellular growth of Mycobacterium tuberculosis at a concentration of 100 and 10 μM. The thiazolidinedione-hydroxamate compound 2n was considered to be the best candidate of the evaluated library., (Copyright © 2019 Elsevier Masson SAS. All rights reserved.)

Published
2020
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46. 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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47. In vitro testing of flash-frozen sublingual membranes for storage and reproducible permeability studies of macromolecular drugs from solution or nanofiber mats.

Author

Berka P, Stránská D, Semecký V, Berka K, and Doležal P

Subjects
Administration, Sublingual, Albumins administration & dosage, Animals, Caffeine administration & dosage, Dextrans administration & dosage, Fluorescein-5-isothiocyanate administration & dosage, Fluorescein-5-isothiocyanate analogs & derivatives, Freezing, Mucous Membrane anatomy & histology, Permeability, Solutions, Swine, Drug Delivery Systems, Mucous Membrane metabolism, Nanofibers administration & dosage
Abstract

Sublingual drug delivery allows systemic delivery of drug without difficulties connected with the gastrointestinal pathway. We developed a new simple protocol for easy-to-use processing and storage of porcine sublingual mucosal membrane for in vitro studies using "flash freezing" in liquid nitrogen. All the dextrans used as mucosal membrane integrity and permeability markers permeated only slowly through sublingual mucosa illustrating usability both the "fresh" and "flash frozen" sublingual membranes whereas conventional cold storage "frozen" membranes have shown significantly higher permeabilities for macromolecules due to the sustained damage. The permeability values were too low to expect dextrans to be potential carriers at this context. To test albumin as a drug carrier we compared FITC-albumin permeation from solutions vs. nanofiber mats donors. To increase the amounts and prolong the transport, we manufactured nanofiber mats loaded with fluorescently marked albumin using well-scalable electrospinning technology. Nanofiber mats have allowed albumin passage through the sublingual membrane in similar amounts as from the pure artificial saliva solution. Since salivary washout strictly limits the duration of liquid dosages, nanofiber mats may thus permit prolonged sublingual administration., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published
2019
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48. Synthesis of novel galeterone derivatives and evaluation of their in vitro activity against prostate cancer cell lines.

Author

Jorda R, Řezníčková E, Kiełczewska U, Maj J, Morzycki JW, Siergiejczyk L, Bazgier V, Berka K, Rárová L, and Wojtkielewicz A

Subjects
Androstadienes chemical synthesis, Androstadienes chemistry, Antineoplastic Agents chemical synthesis, Antineoplastic Agents chemistry, Benzimidazoles chemical synthesis, Benzimidazoles chemistry, Cell Line, Cell Proliferation drug effects, Cell Survival drug effects, Dose-Response Relationship, Drug, Drug Screening Assays, Antitumor, Humans, Male, Molecular Structure, PC-3 Cells, Prostatic Neoplasms metabolism, Prostatic Neoplasms pathology, Structure-Activity Relationship, Androstadienes pharmacology, Antineoplastic Agents pharmacology, Benzimidazoles pharmacology, Prostatic Neoplasms drug therapy
Abstract

Prostate cancer is one of the main causes of male cancer-related deaths worldwide and the suppression of androgen receptor signalling is established as an effective strategy for the treatment. A series of galeterone analogues including several steroid-fused azacycles, as well as 17-(benzimidazol-1-ylimino), 16α-(benzimidazol-2-ylamino), and 16α-(benzothiazol-2-ylamino) steroid derivatives, were synthesized and tested against prostate cancer cell lines. Candidate compound 3f was shown to reduce AR-regulated transcription in a dose-dependent manner in nanomolar ranges and suppress expression of AR-regulated proteins Nkx3.1 and PSA in 22Rv1-ARE14 and VCaP cancer cell lines. Flexible docking study revealed similar position of 3f within AR binding site in comparison of galeterone even with stronger binding energy., (Copyright © 2019 Elsevier Masson SAS. All rights reserved.)

Published
2019
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49. MolMeDB: Molecules on Membranes Database.

Author

Juračka J, Šrejber M, Melíková M, Bazgier V, and Berka K

Subjects
Humans, Membranes, Databases, Chemical
Abstract

Biological membranes act as barriers or reservoirs for many compounds within the human body. As such, they play an important role in pharmacokinetics and pharmacodynamics of drugs and other molecular species. Until now, most membrane/drug interactions have been inferred from simple partitioning between octanol and water phases. However, the observed variability in membrane composition and among compounds themselves stretches beyond such simplification as there are multiple drug-membrane interactions. Numerous experimental and theoretical approaches are used to determine the molecule-membrane interactions with variable accuracy, but there is no open resource for their critical comparison. For this reason, we have built Molecules on Membranes Database (MolMeDB), which gathers data about over 3600 compound-membrane interactions including partitioning, penetration and positioning. The data have been collected from scientific articles published in peer-reviewed journals and complemented by in-house calculations from high-throughput COSMOmic approach to set up a baseline for further comparison. The data in MolMeDB are fully searchable and browsable by means of name, SMILES, membrane, method or dataset and we offer the collected data openly for further reuse and we are open to further additions. MolMeDB can be a powerful tool that could help researchers better understand the role of membranes and to compare individual approaches used for the study of molecule/membrane interactions., (© The Author(s) 2019. Published by Oxford University Press.)

Published
2019
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50. Automated Family-Wide Annotation of Secondary Structure Elements.

Author

Midlik A, Hutařová Vařeková I, Hutař J, Moturu TR, Navrátilová V, Koča J, Berka K, and Svobodová Vařeková R

Subjects
Algorithms, Catalytic Domain genetics, Proteins genetics, Software, Amino Acid Motifs, Computational Biology methods, Molecular Sequence Annotation methods, Proteins chemistry
Abstract

Secondary structure elements (SSEs) are inherent parts of protein structures, and their arrangement is characteristic for each protein family. Therefore, annotation of SSEs can facilitate orientation in the vast number of homologous structures which is now available for many protein families. It also provides a way to identify and annotate the key regions, like active sites and channels, and subsequently answer the key research questions, such as understanding of molecular function and its variability.This chapter introduces the concept of SSE annotation and describes the workflow for obtaining SSE annotation for the members of a selected protein family using program SecStrAnnotator.

Published
2019
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