Your search keyword '"Padhorny D"' showing total 29 results

1. Efficient search for the possible mutual arrangements of two rigid bodies with the use of the generalized five-dimensional Fourier transform

Author

Kazennov, A. M., Alekseenko, A. E., Kozakov, D., Padhorny, D. N., and Kholodov, Y. A.

Published

2015

2. Allostery in Its Many Disguises: From Theory to Applications

Author

Wodak, S, Paci, E, Dokholyan, N, Berezovsky, I, Horovitz, A, Li, J, Hilser, V, Bahar, I, Karanicolas, J, Stock, G, Hamm, P, Stote, R, Eberhardt, J, Chebaro, Y, Dejaegere, A, Cecchini, M, Changeux, J, Bolhuis, P, Vreede, J, Faccioli, P, Orioli, S, Ravasio, R, Yan, L, Brito, C, Wyart, M, Gkeka, P, Rivalta, I, Palermo, G, Mccammon, J, Panecka-Hofman, J, Wade, R, Di Pizio, A, Niv, M, Nussinov, R, Tsai, C, Jang, H, Padhorny, D, Kozakov, D, Mcleish, T, Wodak, Shoshana J, Paci, Emanuele, Dokholyan, Nikolay V, Berezovsky, Igor N, Horovitz, Amnon, Li, Jing, Hilser, Vincent J, Bahar, Ivet, Karanicolas, John, Stock, Gerhard, Hamm, Peter, Stote, Roland H, Eberhardt, Jerome, Chebaro, Yassmine, Dejaegere, Annick, Cecchini, Marco, Changeux, Jean-Pierre, Bolhuis, Peter G, Vreede, Jocelyne, Faccioli, Pietro, Orioli, Simone, Ravasio, Riccardo, Yan, Le, Brito, Carolina, Wyart, Matthieu, Gkeka, Paraskevi, Rivalta, Ivan, Palermo, Giulia, McCammon, J Andrew, Panecka-Hofman, Joanna, Wade, Rebecca C, Di Pizio, Antonella, Niv, Masha Y, Nussinov, Ruth, Tsai, Chung-Jung, Jang, Hyunbum, Padhorny, Dzmitry, Kozakov, Dima, McLeish, Tom, Wodak, S, Paci, E, Dokholyan, N, Berezovsky, I, Horovitz, A, Li, J, Hilser, V, Bahar, I, Karanicolas, J, Stock, G, Hamm, P, Stote, R, Eberhardt, J, Chebaro, Y, Dejaegere, A, Cecchini, M, Changeux, J, Bolhuis, P, Vreede, J, Faccioli, P, Orioli, S, Ravasio, R, Yan, L, Brito, C, Wyart, M, Gkeka, P, Rivalta, I, Palermo, G, Mccammon, J, Panecka-Hofman, J, Wade, R, Di Pizio, A, Niv, M, Nussinov, R, Tsai, C, Jang, H, Padhorny, D, Kozakov, D, Mcleish, T, Wodak, Shoshana J, Paci, Emanuele, Dokholyan, Nikolay V, Berezovsky, Igor N, Horovitz, Amnon, Li, Jing, Hilser, Vincent J, Bahar, Ivet, Karanicolas, John, Stock, Gerhard, Hamm, Peter, Stote, Roland H, Eberhardt, Jerome, Chebaro, Yassmine, Dejaegere, Annick, Cecchini, Marco, Changeux, Jean-Pierre, Bolhuis, Peter G, Vreede, Jocelyne, Faccioli, Pietro, Orioli, Simone, Ravasio, Riccardo, Yan, Le, Brito, Carolina, Wyart, Matthieu, Gkeka, Paraskevi, Rivalta, Ivan, Palermo, Giulia, McCammon, J Andrew, Panecka-Hofman, Joanna, Wade, Rebecca C, Di Pizio, Antonella, Niv, Masha Y, Nussinov, Ruth, Tsai, Chung-Jung, Jang, Hyunbum, Padhorny, Dzmitry, Kozakov, Dima, and McLeish, Tom

Abstract

Allosteric regulation plays an important role in many biological processes, such as signal transduction, transcriptional regulation, and metabolism. Allostery is rooted in the fundamental physical properties of macromolecular systems, but its underlying mechanisms are still poorly understood. A collection of contributions to a recent interdisciplinary CECAM (Center Européen de Calcul Atomique et Moléculaire) workshop is used here to provide an overview of the progress and remaining limitations in the understanding of the mechanistic foundations of allostery gained from computational and experimental analyses of real protein systems and model systems. The main conceptual frameworks instrumental in driving the field are discussed. We illustrate the role of these frameworks in illuminating molecular mechanisms and explaining cellular processes, and describe some of their promising practical applications in engineering molecular sensors and informing drug design efforts.

Published

2019

3. Allostery in Its Many Disguises: From Theory to Applications

Author

Yassmine Chebaro, Annick Dejaegere, Ruth Nussinov, Rebecca C. Wade, Simone Orioli, Jocelyne Vreede, Riccardo Ravasio, Paraskevi Gkeka, Jing Li, Gerhard Stock, Chung-Jung Tsai, Ivet Bahar, Emanuele Paci, Pietro Faccioli, Joanna Panecka-Hofman, John Karanicolas, Peter G. Bolhuis, Jean-Pierre Changeux, Shoshana J. Wodak, Masha Y. Niv, Antonella Di Pizio, Giulia Palermo, Roland H. Stote, Tom McLeish, Matthieu Wyart, Carolina Brito, Peter Hamm, J. Andrew McCammon, Vincent J. Hilser, Amnon Horovitz, Jerome Eberhardt, Ivan Rivalta, Nikolay V. Dokholyan, Igor N. Berezovsky, Marco Cecchini, Le Yan, Hyunbum Jang, Dima Kozakov, Dzmitry Padhorny, VIB-VUB Center for Structural Biology [Bruxelles], VIB [Belgium], Institut de Génétique et de Biologie Moléculaire et Cellulaire (IGBMC), Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA), Institut de Chimie de Strasbourg, Université de Strasbourg (UNISTRA)-Centre National de la Recherche Scientifique (CNRS), Institut Pasteur [Paris], Collège de France (CdF), Physics Department and INFN, University of Trento [Trento], Universidade Federal do Rio Grande do Sul [Porto Alegre] (UFRGS), Ecole Polytechnique Fédérale de Lausanne (EPFL), Laboratoire de Chimie - UMR5182 (LC), École normale supérieure - Lyon (ENS Lyon)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), Molecular and Cellular Modeling Group, Heidelberg Institute for Theoretical Studies (HITS ), Department of Biomedical Engineering [Boston], Boston University [Boston] (BU), University of Leeds, University of North Carolina at Chapel Hill, University of North Carolina [Chapel Hill] (UNC), University of North Carolina System (UNC)-University of North Carolina System (UNC), National University of Singapore (NUS), Weizmann Institute of Science [Rehovot, Israël], Johns Hopkins University (JHU), University of Pittsburgh (PITT), Pennsylvania Commonwealth System of Higher Education (PCSHE), Université de Strasbourg (UNISTRA)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS), Centre National de la Recherche Scientifique (CNRS)-Université Louis Pasteur - Strasbourg I-Institut de Chimie du CNRS (INC), Collège de France (CdF (institution)), Institute of Condensed Matter Physics [Lausanne], University of California [Santa Barbara] (UCSB), University of California, Centre National de la Recherche Scientifique (CNRS)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-École normale supérieure - Lyon (ENS Lyon)-Institut de Chimie du CNRS (INC), Cancer and Inflammation Program, Leidos Biomedical Research Inc., Frederick National Laboratory, Frederick National Laboratory for Cancer Research (FNLCR), Stony Brook University [SUNY] (SBU), State University of New York (SUNY), University of York [York, UK], European Union's Horizon 2020 Research and Innovation Program under grant agreement no. 720270 (HBP SGA1)NIH grants R01GM114015, R01GM064803, and R01GM123247, grants P41GM103712 and P30DA035778Marie Curie Reintegration Grant (FP7-PEOPLE-2009-RG, no. 256533), European Project: 720270,H2020 Pilier Excellent Science,H2020-Adhoc-2014-20,HBP SGA1(2016), European Project: 256533,EC:FP7:PEOPLE,FP7-PEOPLE-2009-RG,COMPUT DRUG DESIGN(2010), Simulation of Biomolecular Systems (HIMS, FNWI), Wodak, Shoshana J, Paci, Emanuele, Dokholyan, Nikolay V, Berezovsky, Igor N, Horovitz, Amnon, Li, Jing, Hilser, Vincent J, Bahar, Ivet, Karanicolas, John, Stock, Gerhard, Hamm, Peter, Stote, Roland H, Eberhardt, Jerome, Chebaro, Yassmine, Dejaegere, Annick, Cecchini, Marco, Changeux, Jean-Pierre, Bolhuis, Peter G, Vreede, Jocelyne, Faccioli, Pietro, Orioli, Simone, Ravasio, Riccardo, Yan, Le, Brito, Carolina, Wyart, Matthieu, Gkeka, Paraskevi, Rivalta, Ivan, Palermo, Giulia, McCammon, J Andrew, Panecka-Hofman, Joanna, Wade, Rebecca C, Di Pizio, Antonella, Niv, Masha Y, Nussinov, Ruth, Tsai, Chung-Jung, Jang, Hyunbum, Padhorny, Dzmitry, Kozakov, Dima, McLeish, Tom, Wodak, S, Paci, E, Dokholyan, N, Berezovsky, I, Horovitz, A, Li, J, Hilser, V, Bahar, I, Karanicolas, J, Stock, G, Hamm, P, Stote, R, Eberhardt, J, Chebaro, Y, Dejaegere, A, Cecchini, M, Changeux, J, Bolhuis, P, Vreede, J, Faccioli, P, Orioli, S, Ravasio, R, Yan, L, Brito, C, Wyart, M, Gkeka, P, Rivalta, I, Palermo, G, Mccammon, J, Panecka-Hofman, J, Wade, R, Di Pizio, A, Niv, M, Nussinov, R, Tsai, C, Jang, H, Padhorny, D, Kozakov, D, Mcleish, T, and Centre National de la Recherche Scientifique (CNRS)-Université de Strasbourg (UNISTRA)

Subjects

Transcription, Genetic, Computer science, nuclear receptors, Biosensing Techniques, allosteric switche, Structural Biology, chemical rescue, Allostery, ComputingMilieux_MISCELLANEOUS, Cognitive science, mechanisms, 0303 health sciences, Protein function, ligand-binding, elastic network model, molecular dynamic, dynamic allostery, 030302 biochemistry & molecular biology, regulation, protein function, Biological Sciences, [SDV.BIBS]Life Sciences [q-bio]/Quantitative Methods [q-bio.QM], [CHIM.THEO]Chemical Sciences/Theoretical and/or physical chemistry, modulation, Generic Health Relevance, elastic network models, Thermodynamics, Transcription, Allosteric Site, Metabolic Networks and Pathways, signal transduction, Signal Transduction, 1.1 Normal biological development and functioning, Biophysics, allosteric drug, Molecular Dynamics Simulation, Article, 03 medical and health sciences, protein conformational changes, Genetic, Allosteric Regulation, Underpinning research, conformational-changes, Information and Computing Sciences, Animals, Humans, Molecular Biology, Elastic network models, allosteric material, 030304 developmental biology, pathway, energy landscape, Proteins, allosteric switches, molecular dynamics, protein conformational change, allosteric drugs, Conceptual framework, Gene Expression Regulation, Drug Design, network, Chemical Sciences, protein

Abstract

Allosteric regulation plays an important role in many biological processes, such as signal transduction, transcriptional regulation, and metabolism. Allostery is rooted in the fundamental physical properties of macromo-lecular systems, but its underlying mechanisms are still poorly understood. A collection of contributions to a recent interdisciplinary CECAM (Center Européen de Calcul Atomique et Moléculaire) workshop is used here to provide an overview of the progress and remaining limitations in the understanding of the mechanistic foundations of allostery gained from computational and experimental analyses of real protein systems and model systems. The main conceptual frameworks instrumental in driving the field are discussed. We illustrate the role of these frameworks in illuminating molecular mechanisms and explaining cellular processes, and describe some of their promising practical applications in engineering molecular sensors and informing drug design efforts.

Published

2019

4. Predicting multiple conformations of ligand binding sites in proteins suggests that AlphaFold2 may remember too much.

Author

Lazou M, Khan O, Nguyen T, Padhorny D, Kozakov D, Joseph-McCarthy D, and Vajda S

Subjects

Binding Sites, Ligands, Models, Molecular, Sequence Alignment, Software, Crystallography, X-Ray, Protein Binding, Computational Biology methods, Protein Conformation, Proteins chemistry, Proteins metabolism, Databases, Protein

Abstract

The goal of this paper is predicting the conformational distributions of ligand binding sites using the AlphaFold2 (AF2) protein structure prediction program with stochastic subsampling of the multiple sequence alignment (MSA). We explored the opening of cryptic ligand binding sites in 16 proteins, where the closed and open conformations define the expected extreme points of the conformational variation. Due to the many structures of these proteins in the Protein Data Bank (PDB), we were able to study whether the distribution of X-ray structures affects the distribution of AF2 models. We have found that AF2 generates both a cluster of open and a cluster of closed models for proteins that have comparable numbers of open and closed structures in the PDB and not too many other conformations. This was observed even with default MSA parameters, thus without further subsampling. In contrast, with the exception of a single protein, AF2 did not yield multiple clusters of conformations for proteins that had imbalanced numbers of open and closed structures in the PDB, or had substantial numbers of other structures. Subsampling improved the results only for a single protein, but very shallow MSA led to incorrect structures. The ability of generating both open and closed conformations for six out of the 16 proteins agrees with the success rates of similar studies reported in the literature. However, we showed that this partial success is due to AF2 "remembering" the conformational distributions in the PDB and that the approach fails to predict rarely seen conformations., Competing Interests: Competing interests statement:The authors declare no competing interest.

Published

2024

5. MHC-Fine: Fine-tuned AlphaFold for precise MHC-peptide complex prediction.

Author

Glukhov E, Kalitin D, Stepanenko D, Zhu Y, Nguyen T, Jones G, Patsahan T, Simmerling C, Mitchell JC, Vajda S, Dill KA, Padhorny D, and Kozakov D

Subjects

Major Histocompatibility Complex, Histocompatibility Antigens Class I chemistry, Histocompatibility Antigens Class I metabolism, Histocompatibility Antigens Class I immunology, Protein Binding, Peptides chemistry, Peptides metabolism, Models, Molecular

Abstract

The precise prediction of major histocompatibility complex (MHC)-peptide complex structures is pivotal for understanding cellular immune responses and advancing vaccine design. In this study, we enhanced AlphaFold's capabilities by fine-tuning it with a specialized dataset consisting of exclusively high-resolution class I MHC-peptide crystal structures. This tailored approach aimed to address the generalist nature of AlphaFold's original training, which, while broad-ranging, lacked the granularity necessary for the high-precision demands of class I MHC-peptide interaction prediction. A comparative analysis was conducted against the homology-modeling-based method Pandora as well as the AlphaFold multimer model. Our results demonstrate that our fine-tuned model outperforms others in terms of root-mean-square deviation (median value for Cα atoms for peptides is 0.66 Å) and also provides enhanced predicted local distance difference test scores, offering a more reliable assessment of the predicted structures. These advances have substantial implications for computational immunology, potentially accelerating the development of novel therapeutics and vaccines by providing a more precise computational lens through which to view MHC-peptide interactions., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024. Published by Elsevier Inc.)

Published

2024

6. MHC-Fine: Fine-tuned AlphaFold for Precise MHC-Peptide Complex Prediction.

Author

Glukhov E, Kalitin D, Stepanenko D, Zhu Y, Nguyen T, Jones G, Simmerling C, Mitchell JC, Vajda S, Dill KA, Padhorny D, and Kozakov D

Abstract

The precise prediction of Major Histocompatibility Complex (MHC)-peptide complex structures is pivotal for understanding cellular immune responses and advancing vaccine design. In this study, we enhanced AlphaFold's capabilities by fine-tuning it with a specialized dataset comprised by exclusively high-resolution MHC-peptide crystal structures. This tailored approach aimed to address the generalist nature of AlphaFold's original training, which, while broad-ranging, lacked the granularity necessary for the high-precision demands of MHC-peptide interaction prediction. A comparative analysis was conducted against the homology-modeling-based method Pandora [13], as well as the AlphaFold multimer model [8]. Our results demonstrate that our fine-tuned model outperforms both in terms of RMSD (median value is 0.65 Å) but also provides enhanced predicted lDDT scores, offering a more reliable assessment of the predicted structures. These advances have substantial implications for computational immunology, potentially accelerating the development of novel therapeutics and vaccines by providing a more precise computational lens through which to view MHC-peptide interactions.

Published

2023

7. Accurate ligand-protein docking in CASP15 using the ClusPro LigTBM server.

Author

Kotelnikov S, Ashizawa R, Popov KI, Khan O, Ignatov M, Li SX, Hassan M, Coutsias EA, Poda G, Padhorny D, Tropsha A, Vajda S, and Kozakov D

Subjects

Protein Conformation, Molecular Docking Simulation, Ligands, Protein Binding, Binding Sites, Software, Proteins chemistry

Abstract

In the ligand prediction category of CASP15, the challenge was to predict the positions and conformations of small molecules binding to proteins that were provided as amino acid sequences or as models generated by the AlphaFold2 program. For most targets, we used our template-based ligand docking program ClusPro ligTBM, also implemented as a public server available at https://ligtbm.cluspro.org/. Since many targets had multiple chains and a number of ligands, several templates, and some manual interventions were required. In a few cases, no templates were found, and we had to use direct docking using the Glide program. Nevertheless, ligTBM was shown to be a very useful tool, and by any ranking criteria, our group was ranked among the top five best-performing teams. In fact, all the best groups used template-based docking methods. Thus, it appears that the AlphaFold2-generated models, despite the high accuracy of the predicted backbone, have local differences from the x-ray structure that make the use of direct docking methods more challenging. The results of CASP15 confirm that this limitation can be frequently overcome by homology-based docking., (© 2023 Wiley Periodicals LLC.)

Published

2023

8. Impact of AlphaFold on structure prediction of protein complexes: The CASP15-CAPRI experiment.

Author

Lensink MF, Brysbaert G, Raouraoua N, Bates PA, Giulini M, Honorato RV, van Noort C, Teixeira JMC, Bonvin AMJJ, Kong R, Shi H, Lu X, Chang S, Liu J, Guo Z, Chen X, Morehead A, Roy RS, Wu T, Giri N, Quadir F, Chen C, Cheng J, Del Carpio CA, Ichiishi E, Rodriguez-Lumbreras LA, Fernandez-Recio J, Harmalkar A, Chu LS, Canner S, Smanta R, Gray JJ, Li H, Lin P, He J, Tao H, Huang SY, Roel-Touris J, Jimenez-Garcia B, Christoffer CW, Jain AJ, Kagaya Y, Kannan H, Nakamura T, Terashi G, Verburgt JC, Zhang Y, Zhang Z, Fujuta H, Sekijima M, Kihara D, Khan O, Kotelnikov S, Ghani U, Padhorny D, Beglov D, Vajda S, Kozakov D, Negi SS, Ricciardelli T, Barradas-Bautista D, Cao Z, Chawla M, Cavallo L, Oliva R, Yin R, Cheung M, Guest JD, Lee J, Pierce BG, Shor B, Cohen T, Halfon M, Schneidman-Duhovny D, Zhu S, Yin R, Sun Y, Shen Y, Maszota-Zieleniak M, Bojarski KK, Lubecka EA, Marcisz M, Danielsson A, Dziadek L, Gaardlos M, Gieldon A, Liwo A, Samsonov SA, Slusarz R, Zieba K, Sieradzan AK, Czaplewski C, Kobayashi S, Miyakawa Y, Kiyota Y, Takeda-Shitaka M, Olechnovic K, Valancauskas L, Dapkunas J, Venclovas C, Wallner B, Yang L, Hou C, He X, Guo S, Jiang S, Ma X, Duan R, Qui L, Xu X, Zou X, Velankar S, and Wodak SJ

Subjects

Protein Conformation, Protein Binding, Molecular Docking Simulation, Computational Biology methods, Software, Protein Interaction Mapping methods, Algorithms

Abstract

We present the results for CAPRI Round 54, the 5th joint CASP-CAPRI protein assembly prediction challenge. The Round offered 37 targets, including 14 homodimers, 3 homo-trimers, 13 heterodimers including 3 antibody-antigen complexes, and 7 large assemblies. On average ~70 CASP and CAPRI predictor groups, including more than 20 automatics servers, submitted models for each target. A total of 21 941 models submitted by these groups and by 15 CAPRI scorer groups were evaluated using the CAPRI model quality measures and the DockQ score consolidating these measures. The prediction performance was quantified by a weighted score based on the number of models of acceptable quality or higher submitted by each group among their five best models. Results show substantial progress achieved across a significant fraction of the 60+ participating groups. High-quality models were produced for about 40% of the targets compared to 8% two years earlier. This remarkable improvement is due to the wide use of the AlphaFold2 and AlphaFold2-Multimer software and the confidence metrics they provide. Notably, expanded sampling of candidate solutions by manipulating these deep learning inference engines, enriching multiple sequence alignments, or integration of advanced modeling tools, enabled top performing groups to exceed the performance of a standard AlphaFold2-Multimer version used as a yard stick. This notwithstanding, performance remained poor for complexes with antibodies and nanobodies, where evolutionary relationships between the binding partners are lacking, and for complexes featuring conformational flexibility, clearly indicating that the prediction of protein complexes remains a challenging problem., (© 2023 The Authors. Proteins: Structure, Function, and Bioinformatics published by Wiley Periodicals LLC.)

Published

2023

9. Parallelized multidimensional analytic framework applied to mammary epithelial cells uncovers regulatory principles in EMT.

Author

Paul I, Bolzan D, Youssef A, Gagnon KA, Hook H, Karemore G, Oliphant MUJ, Lin W, Liu Q, Phanse S, White C, Padhorny D, Kotelnikov S, Chen CS, Hu P, Denis GV, Kozakov D, Raught B, Siggers T, Wuchty S, Muthuswamy SK, and Emili A

Subjects

Epithelial Cells metabolism, Signal Transduction, Transforming Growth Factor beta metabolism, Epithelial-Mesenchymal Transition genetics, Hedgehog Proteins metabolism

Abstract

A proper understanding of disease etiology will require longitudinal systems-scale reconstruction of the multitiered architecture of eukaryotic signaling. Here we combine state-of-the-art data acquisition platforms and bioinformatics tools to devise PAMAF, a workflow that simultaneously examines twelve omics modalities, i.e., protein abundance from whole-cells, nucleus, exosomes, secretome and membrane; N-glycosylation, phosphorylation; metabolites; mRNA, miRNA; and, in parallel, single-cell transcriptomes. We apply PAMAF in an established in vitro model of TGFβ-induced epithelial to mesenchymal transition (EMT) to quantify >61,000 molecules from 12 omics and 10 timepoints over 12 days. Bioinformatics analysis of this EMT-ExMap resource allowed us to identify; -topological coupling between omics, -four distinct cell states during EMT, -omics-specific kinetic paths, -stage-specific multi-omics characteristics, -distinct regulatory classes of genes, -ligand-receptor mediated intercellular crosstalk by integrating scRNAseq and subcellular proteomics, and -combinatorial drug targets (e.g., Hedgehog signaling and CAMK-II) to inhibit EMT, which we validate using a 3D mammary duct-on-a-chip platform. Overall, this study provides a resource on TGFβ signaling and EMT., (© 2023. The Author(s).)

Published

2023

10. Opinion: Protein folds vs. protein folding: Differing questions, different challenges.

Author

Chen SJ, Hassan M, Jernigan RL, Jia K, Kihara D, Kloczkowski A, Kotelnikov S, Kozakov D, Liang J, Liwo A, Matysiak S, Meller J, Micheletti C, Mitchell JC, Mondal S, Nussinov R, Okazaki KI, Padhorny D, Skolnick J, Sosnick TS, Stan G, Vakser I, Zou X, and Rose GD

Subjects

Thermodynamics, Proteins metabolism, Protein Folding

Published

2023

11. Scalable multiplex co-fractionation/mass spectrometry platform for accelerated protein interactome discovery.

Author

Havugimana PC, Goel RK, Phanse S, Youssef A, Padhorny D, Kotelnikov S, Kozakov D, and Emili A

Subjects

Chemical Fractionation, Mass Spectrometry methods, Workflow, Proteome analysis, Proteomics methods

Abstract

Co-fractionation/mass spectrometry (CF/MS) enables the mapping of endogenous macromolecular networks on a proteome scale, but current methods are experimentally laborious, resource intensive and afford lesser quantitative accuracy. Here, we present a technically efficient, cost-effective and reproducible multiplex CF/MS (mCF/MS) platform for measuring and comparing, simultaneously, multi-protein assemblies across different experimental samples at a rate that is up to an order of magnitude faster than previous approaches. We apply mCF/MS to map the protein interaction landscape of non-transformed mammary epithelia versus breast cancer cells in parallel, revealing large-scale differences in protein-protein interactions and the relative abundance of associated macromolecules connected with cancer-related pathways and altered cellular processes. The integration of multiplexing capability within an optimized workflow renders mCF/MS as a powerful tool for systematically exploring physical interaction networks in a comparative manner., (© 2022. The Author(s).)

Published

2022

12. Elucidation of protein function using computational docking and hotspot analysis by ClusPro and FTMap.

Author

Jones G, Jindal A, Ghani U, Kotelnikov S, Egbert M, Hashemi N, Vajda S, Padhorny D, and Kozakov D

Subjects

Computer Simulation, Molecular Docking Simulation, Protein Conformation, Proteins chemistry

Abstract

Starting with a crystal structure of a macromolecule, computational structural modeling can help to understand the associated biological processes, structure and function, as well as to reduce the number of further experiments required to characterize a given molecular entity. In the past decade, two classes of powerful automated tools for investigating the binding properties of proteins have been developed: the protein-protein docking program ClusPro and the FTMap and FTSite programs for protein hotspot identification. These methods have been widely used by the research community by means of publicly available online servers, and models built using these automated tools have been reported in a large number of publications. Importantly, additional experimental information can be leveraged to further improve the predictive power of these approaches. Here, an overview of the methods and their biological applications is provided together with a brief interpretation of the results., (open access.)

Published

2022

13. Side-chain Packing Using SE(3)-Transformer.

Author

Jindal A, Kotelnikov S, Padhorny D, Kozakov D, Zhu Y, Chowdhury R, and Vajda S

Subjects

Humans, Models, Molecular, Protein Conformation, Computational Biology, Proteins genetics

Abstract

Predicting protein side-chains is important for both protein structure prediction and protein design. Modeling approaches to predict side-chains such as SCWRL4 have become one of the most widely used tools of its type due to fast and highly accurate predictions. Motivated by the recent success of AlphaFold2 in CASP14, our group adapted a 3D equivariant neural network architecture to predict protein side-chain conformations, specifically within a protein-protein interface, a problem that has not been fully addressed by AlphaFold2.

Published

2022

14. Assessing the binding properties of CASP14 targets and models.

Author

Egbert M, Ghani U, Ashizawa R, Kotelnikov S, Nguyen T, Desta I, Hashemi N, Padhorny D, Kozakov D, and Vajda S

Subjects

Computational Biology, Ligands, Molecular Docking Simulation, Protein Conformation, Software, Binding Sites, Models, Molecular, Protein Binding, Protein Interaction Domains and Motifs, Proteins chemistry, Proteins metabolism

Abstract

An important question is how well the models submitted to CASP retain the properties of target structures. We investigate several properties related to binding. First we explore the binding of small molecules as probes, and count the number of interactions between each residue and such probes, resulting in a binding fingerprint. The similarity between two fingerprints, one for the X-ray structure and the other for a model, is determined by calculating their correlation coefficient. The fingerprint similarity weakly correlates with global measures of accuracy, and GDT_TS higher than 80 is a necessary but not sufficient condition for the conservation of surface binding properties. The advantage of this approach is that it can be carried out without information on potential ligands and their binding sites. The latter information was available for a few targets, and we explored whether the CASP14 models can be used to predict binding sites and to dock small ligands. Finally, we tested the ability of models to reproduce protein-protein interactions by docking both the X-ray structures and the models to their interaction partners in complexes. The analysis showed that in CASP14 the quality of individual domain models is approaching that offered by X-ray crystallography, and hence such models can be successfully used for the identification of binding and regulatory sites, as well as for assembling obligatory protein-protein complexes. Success of ligand docking, however, often depends on fine details of the binding interface, and thus may require accounting for conformational changes by simulation methods., (© 2021 Wiley Periodicals LLC.)

Published

2021

15. Prediction of protein assemblies, the next frontier: The CASP14-CAPRI experiment.

Author

Lensink MF, Brysbaert G, Mauri T, Nadzirin N, Velankar S, Chaleil RAG, Clarence T, Bates PA, Kong R, Liu B, Yang G, Liu M, Shi H, Lu X, Chang S, Roy RS, Quadir F, Liu J, Cheng J, Antoniak A, Czaplewski C, Giełdoń A, Kogut M, Lipska AG, Liwo A, Lubecka EA, Maszota-Zieleniak M, Sieradzan AK, Ślusarz R, Wesołowski PA, Zięba K, Del Carpio Muñoz CA, Ichiishi E, Harmalkar A, Gray JJ, Bonvin AMJJ, Ambrosetti F, Vargas Honorato R, Jandova Z, Jiménez-García B, Koukos PI, Van Keulen S, Van Noort CW, Réau M, Roel-Touris J, Kotelnikov S, Padhorny D, Porter KA, Alekseenko A, Ignatov M, Desta I, Ashizawa R, Sun Z, Ghani U, Hashemi N, Vajda S, Kozakov D, Rosell M, Rodríguez-Lumbreras LA, Fernandez-Recio J, Karczynska A, Grudinin S, Yan Y, Li H, Lin P, Huang SY, Christoffer C, Terashi G, Verburgt J, Sarkar D, Aderinwale T, Wang X, Kihara D, Nakamura T, Hanazono Y, Gowthaman R, Guest JD, Yin R, Taherzadeh G, Pierce BG, Barradas-Bautista D, Cao Z, Cavallo L, Oliva R, Sun Y, Zhu S, Shen Y, Park T, Woo H, Yang J, Kwon S, Won J, Seok C, Kiyota Y, Kobayashi S, Harada Y, Takeda-Shitaka M, Kundrotas PJ, Singh A, Vakser IA, Dapkūnas J, Olechnovič K, Venclovas Č, Duan R, Qiu L, Xu X, Zhang S, Zou X, and Wodak SJ

Subjects

Binding Sites, Molecular Docking Simulation, Protein Interaction Domains and Motifs, Sequence Analysis, Protein, Computational Biology methods, Models, Molecular, Proteins chemistry, Proteins metabolism, Software

Abstract

We present the results for CAPRI Round 50, the fourth joint CASP-CAPRI protein assembly prediction challenge. The Round comprised a total of twelve targets, including six dimers, three trimers, and three higher-order oligomers. Four of these were easy targets, for which good structural templates were available either for the full assembly, or for the main interfaces (of the higher-order oligomers). Eight were difficult targets for which only distantly related templates were found for the individual subunits. Twenty-five CAPRI groups including eight automatic servers submitted ~1250 models per target. Twenty groups including six servers participated in the CAPRI scoring challenge submitted ~190 models per target. The accuracy of the predicted models was evaluated using the classical CAPRI criteria. The prediction performance was measured by a weighted scoring scheme that takes into account the number of models of acceptable quality or higher submitted by each group as part of their five top-ranking models. Compared to the previous CASP-CAPRI challenge, top performing groups submitted such models for a larger fraction (70-75%) of the targets in this Round, but fewer of these models were of high accuracy. Scorer groups achieved stronger performance with more groups submitting correct models for 70-80% of the targets or achieving high accuracy predictions. Servers performed less well in general, except for the MDOCKPP and LZERD servers, who performed on par with human groups. In addition to these results, major advances in methodology are discussed, providing an informative overview of where the prediction of protein assemblies currently stands., (© 2021 Wiley Periodicals LLC.)

Published

2021

16. Actionable Cytopathogenic Host Responses of Human Alveolar Type 2 Cells to SARS-CoV-2.

Author

Hekman RM, Hume AJ, Goel RK, Abo KM, Huang J, Blum BC, Werder RB, Suder EL, Paul I, Phanse S, Youssef A, Alysandratos KD, Padhorny D, Ojha S, Mora-Martin A, Kretov D, Ash PEA, Verma M, Zhao J, Patten JJ, Villacorta-Martin C, Bolzan D, Perea-Resa C, Bullitt E, Hinds A, Tilston-Lunel A, Varelas X, Farhangmehr S, Braunschweig U, Kwan JH, McComb M, Basu A, Saeed M, Perissi V, Burks EJ, Layne MD, Connor JH, Davey R, Cheng JX, Wolozin BL, Blencowe BJ, Wuchty S, Lyons SM, Kozakov D, Cifuentes D, Blower M, Kotton DN, Wilson AA, Mühlberger E, and Emili A

Published

2021

17. Actionable Cytopathogenic Host Responses of Human Alveolar Type 2 Cells to SARS-CoV-2.

Author

Hekman RM, Hume AJ, Goel RK, Abo KM, Huang J, Blum BC, Werder RB, Suder EL, Paul I, Phanse S, Youssef A, Alysandratos KD, Padhorny D, Ojha S, Mora-Martin A, Kretov D, Ash PEA, Verma M, Zhao J, Patten JJ, Villacorta-Martin C, Bolzan D, Perea-Resa C, Bullitt E, Hinds A, Tilston-Lunel A, Varelas X, Farhangmehr S, Braunschweig U, Kwan JH, McComb M, Basu A, Saeed M, Perissi V, Burks EJ, Layne MD, Connor JH, Davey R, Cheng JX, Wolozin BL, Blencowe BJ, Wuchty S, Lyons SM, Kozakov D, Cifuentes D, Blower M, Kotton DN, Wilson AA, Mühlberger E, and Emili A

Subjects

Alveolar Epithelial Cells pathology, Alveolar Epithelial Cells virology, Animals, Antiviral Agents, COVID-19 genetics, COVID-19 pathology, Chlorocebus aethiops, Cytopathogenic Effect, Viral, Cytoskeleton, Drug Evaluation, Preclinical, Humans, Induced Pluripotent Stem Cells metabolism, Induced Pluripotent Stem Cells pathology, Induced Pluripotent Stem Cells virology, Phosphoproteins genetics, Protein Transport, Proteome genetics, SARS-CoV-2 genetics, Signal Transduction, Vero Cells, COVID-19 Drug Treatment, Alveolar Epithelial Cells metabolism, COVID-19 metabolism, Phosphoproteins metabolism, Proteome metabolism, SARS-CoV-2 metabolism

Abstract

Human transmission of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), causative pathogen of the COVID-19 pandemic, exerts a massive health and socioeconomic crisis. The virus infects alveolar epithelial type 2 cells (AT2s), leading to lung injury and impaired gas exchange, but the mechanisms driving infection and pathology are unclear. We performed a quantitative phosphoproteomic survey of induced pluripotent stem cell-derived AT2s (iAT2s) infected with SARS-CoV-2 at air-liquid interface (ALI). Time course analysis revealed rapid remodeling of diverse host systems, including signaling, RNA processing, translation, metabolism, nuclear integrity, protein trafficking, and cytoskeletal-microtubule organization, leading to cell cycle arrest, genotoxic stress, and innate immunity. Comparison to analogous data from transformed cell lines revealed respiratory-specific processes hijacked by SARS-CoV-2, highlighting potential novel therapeutic avenues that were validated by a high hit rate in a targeted small molecule screen in our iAT2 ALI system., Competing Interests: Declaration of Interests B.L.W. declares a position as CSO of Aquinnah Pharmaceuticals. A.E. and D.N.K. declare industry funding from Johnson & Johnson, Merck, and Novartis., (Copyright © 2020 Elsevier Inc. All rights reserved.)

Published

2020

18. Modeling beta-sheet peptide-protein interactions: Rosetta FlexPepDock in CAPRI rounds 38-45.

Author

Khramushin A, Marcu O, Alam N, Shimony O, Padhorny D, Brini E, Dill KA, Vajda S, Kozakov D, and Schueler-Furman O

Subjects

Amino Acid Sequence, Animals, Binding Sites, Dyneins metabolism, Humans, Hydrogen Bonding, Ligands, Mice, Myelin-Associated Glycoprotein metabolism, Peptides metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Interaction Mapping, Protein Multimerization, Proteins metabolism, Research Design, Structural Homology, Protein, Thermodynamics, Dyneins chemistry, Molecular Docking Simulation, Myelin-Associated Glycoprotein chemistry, Peptides chemistry, Proteins chemistry, Software

Abstract

Peptide-protein docking is challenging due to the considerable conformational freedom of the peptide. CAPRI rounds 38-45 included two peptide-protein interactions, both characterized by a peptide forming an additional beta strand of a beta sheet in the receptor. Using the Rosetta FlexPepDock peptide docking protocol we generated top-performing, high-accuracy models for targets 134 and 135, involving an interaction between a peptide derived from L-MAG with DLC8. In addition, we were able to generate the only medium-accuracy models for a particularly challenging target, T121. In contrast to the classical peptide-mediated interaction, in which receptor side chains contact both peptide backbone and side chains, beta-sheet complementation involves a major contribution to binding by hydrogen bonds between main chain atoms. To establish how binding affinity and specificity are established in this special class of peptide-protein interactions, we extracted PeptiDBeta, a benchmark of solved structures of different protein domains that are bound by peptides via beta-sheet complementation, and tested our protocol for global peptide-docking PIPER-FlexPepDock on this dataset. We find that the beta-strand part of the peptide is sufficient to generate approximate and even high resolution models of many interactions, but inclusion of adjacent motif residues often provides additional information necessary to achieve high resolution model quality., (© 2020 Wiley Periodicals, Inc.)

Published

2020

19. ClusPro in rounds 38 to 45 of CAPRI: Toward combining template-based methods with free docking.

Author

Padhorny D, Porter KA, Ignatov M, Alekseenko A, Beglov D, Kotelnikov S, Ashizawa R, Desta I, Alam N, Sun Z, Brini E, Dill K, Schueler-Furman O, Vajda S, and Kozakov D

Subjects

Amino Acid Sequence, Benchmarking, Binding Sites, Humans, Ligands, Peptides metabolism, Protein Binding, Protein Conformation, alpha-Helical, Protein Conformation, beta-Strand, Protein Interaction Domains and Motifs, Protein Interaction Mapping, Protein Multimerization, Proteins metabolism, Research Design, Structural Homology, Protein, Thermodynamics, Molecular Docking Simulation, Peptides chemistry, Proteins chemistry, Software

Abstract

Targets in the protein docking experiment CAPRI (Critical Assessment of Predicted Interactions) generally present new challenges and contribute to new developments in methodology. In rounds 38 to 45 of CAPRI, most targets could be effectively predicted using template-based methods. However, the server ClusPro required structures rather than sequences as input, and hence we had to generate and dock homology models. The available templates also provided distance restraints that were directly used as input to the server. We show here that such an approach has some advantages. Free docking with template-based restraints using ClusPro reproduced some interfaces suggested by weak or ambiguous templates while not reproducing others, resulting in correct server predicted models. More recently we developed the fully automated ClusPro TBM server that performs template-based modeling and thus can use sequences rather than structures of component proteins as input. The performance of the server, freely available for noncommercial use at https://tbm.cluspro.org, is demonstrated by predicting the protein-protein targets of rounds 38 to 45 of CAPRI., (© 2020 Wiley Periodicals, Inc.)

Published

2020

20. Sampling and refinement protocols for template-based macrocycle docking: 2018 D3R Grand Challenge 4.

Author

Kotelnikov S, Alekseenko A, Liu C, Ignatov M, Padhorny D, Brini E, Lukin M, Coutsias E, Dill KA, and Kozakov D

Subjects

Amyloid Precursor Protein Secretases chemistry, Aspartic Acid Endopeptidases chemistry, Binding Sites, Humans, Ligands, Molecular Dynamics Simulation, Monte Carlo Method, Protein Binding, Thermodynamics, Amyloid Precursor Protein Secretases metabolism, Aspartic Acid Endopeptidases metabolism, Drug Design, Macrocyclic Compounds chemistry, Macrocyclic Compounds pharmacology, Molecular Docking Simulation

Abstract

We describe a new template-based method for docking flexible ligands such as macrocycles to proteins. It combines Monte-Carlo energy minimization on the manifold, a fast manifold search method, with BRIKARD for complex flexible ligand searching, and with the MELD accelerator of Replica-Exchange Molecular Dynamics simulations for atomistic degrees of freedom. Here we test the method in the Drug Design Data Resource blind Grand Challenge competition. This method was among the best performers in the competition, giving sub-angstrom prediction quality for the majority of the targets.

Published

2020

21. Template-based modeling by ClusPro in CASP13 and the potential for using co-evolutionary information in docking.

Author

Porter KA, Padhorny D, Desta I, Ignatov M, Beglov D, Kotelnikov S, Sun Z, Alekseenko A, Anishchenko I, Cong Q, Ovchinnikov S, Baker D, Vajda S, and Kozakov D

Subjects

Algorithms, Binding Sites genetics, Databases, Protein, Humans, Molecular Docking Simulation, Molecular Dynamics Simulation, Protein Interaction Mapping, Proteins chemistry, Proteins genetics, Structural Homology, Protein, Computational Biology, Protein Conformation, Proteins ultrastructure, Software

Abstract

As a participant in the joint CASP13-CAPRI46 assessment, the ClusPro server debuted its new template-based modeling functionality. The addition of this feature, called ClusPro TBM, was motivated by the previous CASP-CAPRI assessments and by the proven ability of template-based methods to produce higher-quality models, provided templates are available. In prior assessments, ClusPro submissions consisted of models that were produced via free docking of pre-generated homology models. This method was successful in terms of the number of acceptable predictions across targets; however, analysis of results showed that purely template-based methods produced a substantially higher number of medium-quality models for targets for which there were good templates available. The addition of template-based modeling has expanded ClusPro's ability to produce higher accuracy predictions, primarily for homomeric but also for some heteromeric targets. Here we review the newest additions to the ClusPro web server and discuss examples of CASP-CAPRI targets that continue to drive further development. We also describe ongoing work not yet implemented in the server. This includes the development of methods to improve template-based models and the use of co-evolutionary information for data-assisted free docking., (© 2019 Wiley Periodicals, Inc. The World Health Organization retains copyright and all other rights in the manuscript of this article as submitted for publication.)

Published

2019

22. Blind prediction of homo- and hetero-protein complexes: The CASP13-CAPRI experiment.

Author

Lensink MF, Brysbaert G, Nadzirin N, Velankar S, Chaleil RAG, Gerguri T, Bates PA, Laine E, Carbone A, Grudinin S, Kong R, Liu RR, Xu XM, Shi H, Chang S, Eisenstein M, Karczynska A, Czaplewski C, Lubecka E, Lipska A, Krupa P, Mozolewska M, Golon Ł, Samsonov S, Liwo A, Crivelli S, Pagès G, Karasikov M, Kadukova M, Yan Y, Huang SY, Rosell M, Rodríguez-Lumbreras LA, Romero-Durana M, Díaz-Bueno L, Fernandez-Recio J, Christoffer C, Terashi G, Shin WH, Aderinwale T, Maddhuri Venkata Subraman SR, Kihara D, Kozakov D, Vajda S, Porter K, Padhorny D, Desta I, Beglov D, Ignatov M, Kotelnikov S, Moal IH, Ritchie DW, Chauvot de Beauchêne I, Maigret B, Devignes MD, Ruiz Echartea ME, Barradas-Bautista D, Cao Z, Cavallo L, Oliva R, Cao Y, Shen Y, Baek M, Park T, Woo H, Seok C, Braitbard M, Bitton L, Scheidman-Duhovny D, Dapkūnas J, Olechnovič K, Venclovas Č, Kundrotas PJ, Belkin S, Chakravarty D, Badal VD, Vakser IA, Vreven T, Vangaveti S, Borrman T, Weng Z, Guest JD, Gowthaman R, Pierce BG, Xu X, Duan R, Qiu L, Hou J, Ryan Merideth B, Ma Z, Cheng J, Zou X, Koukos PI, Roel-Touris J, Ambrosetti F, Geng C, Schaarschmidt J, Trellet ME, Melquiond ASJ, Xue L, Jiménez-García B, van Noort CW, Honorato RV, Bonvin AMJJ, and Wodak SJ

Subjects

Algorithms, Binding Sites genetics, Databases, Protein, Models, Molecular, Protein Binding genetics, Protein Interaction Mapping, Proteins chemistry, Proteins genetics, Structural Homology, Protein, Computational Biology, Protein Conformation, Proteins ultrastructure, Software

Abstract

We present the results for CAPRI Round 46, the third joint CASP-CAPRI protein assembly prediction challenge. The Round comprised a total of 20 targets including 14 homo-oligomers and 6 heterocomplexes. Eight of the homo-oligomer targets and one heterodimer comprised proteins that could be readily modeled using templates from the Protein Data Bank, often available for the full assembly. The remaining 11 targets comprised 5 homodimers, 3 heterodimers, and two higher-order assemblies. These were more difficult to model, as their prediction mainly involved "ab-initio" docking of subunit models derived from distantly related templates. A total of ~30 CAPRI groups, including 9 automatic servers, submitted on average ~2000 models per target. About 17 groups participated in the CAPRI scoring rounds, offered for most targets, submitting ~170 models per target. The prediction performance, measured by the fraction of models of acceptable quality or higher submitted across all predictors groups, was very good to excellent for the nine easy targets. Poorer performance was achieved by predictors for the 11 difficult targets, with medium and high quality models submitted for only 3 of these targets. A similar performance "gap" was displayed by scorer groups, highlighting yet again the unmet challenge of modeling the conformational changes of the protein components that occur upon binding or that must be accounted for in template-based modeling. Our analysis also indicates that residues in binding interfaces were less well predicted in this set of targets than in previous Rounds, providing useful insights for directions of future improvements., (© 2019 Wiley Periodicals, Inc.)

Published

2019

23. Allostery in Its Many Disguises: From Theory to Applications.

Author

Wodak SJ, Paci E, Dokholyan NV, Berezovsky IN, Horovitz A, Li J, Hilser VJ, Bahar I, Karanicolas J, Stock G, Hamm P, Stote RH, Eberhardt J, Chebaro Y, Dejaegere A, Cecchini M, Changeux JP, Bolhuis PG, Vreede J, Faccioli P, Orioli S, Ravasio R, Yan L, Brito C, Wyart M, Gkeka P, Rivalta I, Palermo G, McCammon JA, Panecka-Hofman J, Wade RC, Di Pizio A, Niv MY, Nussinov R, Tsai CJ, Jang H, Padhorny D, Kozakov D, and McLeish T

Subjects

Allosteric Regulation, Animals, Gene Expression Regulation, Humans, Metabolic Networks and Pathways, Molecular Dynamics Simulation, Proteins genetics, Proteins metabolism, Signal Transduction, Thermodynamics, Transcription, Genetic, Allosteric Site, Biosensing Techniques, Drug Design, Proteins chemistry

Abstract

Allosteric regulation plays an important role in many biological processes, such as signal transduction, transcriptional regulation, and metabolism. Allostery is rooted in the fundamental physical properties of macromolecular systems, but its underlying mechanisms are still poorly understood. A collection of contributions to a recent interdisciplinary CECAM (Center Européen de Calcul Atomique et Moléculaire) workshop is used here to provide an overview of the progress and remaining limitations in the understanding of the mechanistic foundations of allostery gained from computational and experimental analyses of real protein systems and model systems. The main conceptual frameworks instrumental in driving the field are discussed. We illustrate the role of these frameworks in illuminating molecular mechanisms and explaining cellular processes, and describe some of their promising practical applications in engineering molecular sensors and informing drug design efforts., (Copyright © 2019. Published by Elsevier Ltd.)

Published

2019

24. Monte Carlo on the manifold and MD refinement for binding pose prediction of protein-ligand complexes: 2017 D3R Grand Challenge.

Author

Ignatov M, Liu C, Alekseenko A, Sun Z, Padhorny D, Kotelnikov S, Kazennov A, Grebenkin I, Kholodov Y, Kolosvari I, Perez A, Dill K, and Kozakov D

Subjects

Binding Sites, Computer-Aided Design, Crystallography, X-Ray, Databases, Protein, Drug Design, Ligands, Molecular Conformation, Molecular Dynamics Simulation, Protein Binding, Thermodynamics, Cathepsins antagonists & inhibitors, Molecular Docking Simulation methods, Monte Carlo Method

Abstract

Manifold representations of rotational/translational motion and conformational space of a ligand were previously shown to be effective for local energy optimization. In this paper we report the development of the Monte-Carlo energy minimization approach (MCM), which uses the same manifold representation. The approach was integrated into the docking pipeline developed for the current round of D3R experiment, and according to D3R assessment produced high accuracy poses for Cathepsin S ligands. Additionally, we have shown that (MD) refinement further improves docking quality. The code of the Monte-Carlo minimization is freely available at https://bitbucket.org/abc-group/mcm-demo .

Published

2019

25. Glucose regulation in the methylotrophic yeast Hansenula (Ogataea) polymorpha is mediated by a putative transceptor Gcr1.

Author

Stasyk OG, Denega IO, Padhorny D, Dmytruk KV, Kozakov D, Abbas C, and Stasyk OV

Subjects

Fungal Proteins genetics, Fungal Proteins metabolism, Gene Expression Regulation, Fungal, Glucose metabolism, Pichia genetics, Pichia metabolism, Receptors, G-Protein-Coupled genetics, Receptors, G-Protein-Coupled metabolism

Abstract

The HpGcr1, a hexose transporter homologue from the methylotrophic yeast Hansenula (Ogataea) polymorpha, was previously identified as being involved in glucose repression. Intriguingly, potential HpGcr1 orthologues are found only in the genomes of a few yeasts phylogenetically closely related to H. polymorpha, but are absent in all other yeasts. The other closest HpGcr1 homologues are fungal high-affinity glucose symporters or putative transceptors suggesting a possible HpGcr1 origin due to a specific archaic gene retention or via horizontal gene transfer from Eurotiales fungi. Herein we report that, similarly to other yeast non-transporting glucose sensors, the substitution of the conserved arginine residue converts HpGcr1 R165K into a constitutively signaling form. Synthesis of HpGcr1 R165K in gcr1Δ did not restore glucose transport or repression but instead profoundly impaired growth independent of carbon source used. Simultaneously, gcr1Δ was impaired in transcriptional induction of repressible peroxisomal alcohol oxidase and in growth on methanol. Overexpression of the functional transporter HpHxt1 in gcr1Δ partially restored growth on glucose and glucose repression but did not rescue impaired growth on methanol. Heterologous expression of HpGcr1 in a Saccharomyces cerevisiae hxt-null strain did not restore glucose uptake due to protein mislocalization. However, HpGcr1 overexpression in H. polymorpha led to increased sensitivity to extracellular 2-deoxyglucose, suggesting HpGcr1 is a functional glucose carrier. The combined data suggest that HpGcr1 represents a novel type of yeast glucose transceptor functioning also in the absence of glucose., (Copyright © 2018 Elsevier Ltd. All rights reserved.)

Published

2018

26. Protein-ligand docking using FFT based sampling: D3R case study.

Author

Padhorny D, Hall DR, Mirzaei H, Mamonov AB, Moghadasi M, Alekseenko A, Beglov D, and Kozakov D

Subjects

17-alpha-Hydroxyprogesterone chemistry, Binding Sites, Calcifediol chemistry, Computer-Aided Design, Drug Design, Humans, Ligands, Monte Carlo Method, Protein Binding, Proteins chemistry, 17-alpha-Hydroxyprogesterone pharmacology, Calcifediol pharmacology, Fourier Analysis, Molecular Docking Simulation, Proteins metabolism

Abstract

Fast Fourier transform (FFT) based approaches have been successful in application to modeling of relatively rigid protein-protein complexes. Recently, we have been able to adapt the FFT methodology to treatment of flexible protein-peptide interactions. Here, we report our latest attempt to expand the capabilities of the FFT approach to treatment of flexible protein-ligand interactions in application to the D3R PL-2016-1 challenge. Based on the D3R assessment, our FFT approach in conjunction with Monte Carlo minimization off-grid refinement was among the top performing methods in the challenge. The potential advantage of our method is its ability to globally sample the protein-ligand interaction landscape, which will be explored in further applications.

Published

2018

27. ClusPro-DC: Dimer Classification by the Cluspro Server for Protein-Protein Docking.

Author

Yueh C, Hall DR, Xia B, Padhorny D, Kozakov D, and Vajda S

Subjects

Databases, Protein, Escherichia coli chemistry, Protein Conformation, X-Rays, Molecular Docking Simulation, Protein Interaction Mapping, Proteins chemistry

Abstract

ClusPro-DC (https://cluspro.bu.edu/) implements a straightforward approach to the discrimination between crystallographic and biological dimers by docking the two subunits to exhaustively sample the interaction energy landscape. If a substantial number of low energy docked poses cluster in a narrow vicinity of the native structure of the dimer, then one can assume that there is a well-defined free energy well around the native state, which makes the interaction stable. In contrast, if the interaction sites in the docked poses do not form a large enough cluster around the native structure, then it is unlikely that the subunits form a stable biological dimer. The number of near-native structures is used to estimate the probability of a dimer being biological. Currently, the server examines only the stability of a given interface rather than generating all putative quaternary structures as accomplished by PISA or EPPIC, but it complements the information provided by these methods., (Copyright © 2016 Elsevier Ltd. All rights reserved.)

Published

2017

28. The ClusPro web server for protein-protein docking.

Author

Kozakov D, Hall DR, Xia B, Porter KA, Padhorny D, Yueh C, Beglov D, and Vajda S

Subjects

Algorithms, Databases, Protein, Heparin metabolism, Protein Multimerization, Protein Structure, Quaternary, Thermodynamics, Computational Biology methods, Internet, Protein Interaction Mapping methods

Abstract

The ClusPro server (https://cluspro.org) is a widely used tool for protein-protein docking. The server provides a simple home page for basic use, requiring only two files in Protein Data Bank (PDB) format. However, ClusPro also offers a number of advanced options to modify the search; these include the removal of unstructured protein regions, application of attraction or repulsion, accounting for pairwise distance restraints, construction of homo-multimers, consideration of small-angle X-ray scattering (SAXS) data, and location of heparin-binding sites. Six different energy functions can be used, depending on the type of protein. Docking with each energy parameter set results in ten models defined by centers of highly populated clusters of low-energy docked structures. This protocol describes the use of the various options, the construction of auxiliary restraints files, the selection of the energy parameters, and the analysis of the results. Although the server is heavily used, runs are generally completed in <4 h.

Published

2017

29. Protein-protein docking by fast generalized Fourier transforms on 5D rotational manifolds.

Author

Padhorny D, Kazennov A, Zerbe BS, Porter KA, Xia B, Mottarella SE, Kholodov Y, Ritchie DW, Vajda S, and Kozakov D

Subjects

Magnetic Resonance Spectroscopy methods, Protein Binding, Proteins metabolism, Reproducibility of Results, Rotation, Thermodynamics, Algorithms, Fourier Analysis, Molecular Docking Simulation methods, Protein Conformation, Proteins chemistry

Abstract

Energy evaluation using fast Fourier transforms (FFTs) enables sampling billions of putative complex structures and hence revolutionized rigid protein-protein docking. However, in current methods, efficient acceleration is achieved only in either the translational or the rotational subspace. Developing an efficient and accurate docking method that expands FFT-based sampling to five rotational coordinates is an extensively studied but still unsolved problem. The algorithm presented here retains the accuracy of earlier methods but yields at least 10-fold speedup. The improvement is due to two innovations. First, the search space is treated as the product manifold [Formula: see text], where [Formula: see text] is the rotation group representing the space of the rotating ligand, and [Formula: see text] is the space spanned by the two Euler angles that define the orientation of the vector from the center of the fixed receptor toward the center of the ligand. This representation enables the use of efficient FFT methods developed for [Formula: see text] Second, we select the centers of highly populated clusters of docked structures, rather than the lowest energy conformations, as predictions of the complex, and hence there is no need for very high accuracy in energy evaluation. Therefore, it is sufficient to use a limited number of spherical basis functions in the Fourier space, which increases the efficiency of sampling while retaining the accuracy of docking results. A major advantage of the method is that, in contrast to classical approaches, increasing the number of correlation function terms is computationally inexpensive, which enables using complex energy functions for scoring.

Published

2016