Your search keyword '"Joseph H Lubin"' showing total 17 results

1. Corrigendum to 'Computational design of nanomolar-binding antibodies specific to multiple SARS-CoV-2 variants by engineering a specificity switch of antibody 80R using RosettaAntibodyDesign (RAbD) results in potential generalizable therapeutic antibodies for novel SARS-CoV-2 virus' [Heliyon 9(4) (April 2023) e15032]

Author

Nancy E. Hernandez, Wojciech Jankowski, Rahel Frick, Simon P. Kelow, Joseph H. Lubin, Vijaya Simhadri, Jared Adolf-Bryfogle, Sagar D. Khare, Roland L. Dunbrack, Jr., Jeffrey J. Gray, and Zuben E. Sauna

Subjects

Science (General), Q1-390, Social sciences (General), H1-99

Published

2023

2. Modeling of ACE2 and antibodies bound to SARS-CoV-2 provides insights into infectivity and immune evasion

Author

Joseph H. Lubin, Christopher Markosian, D. Balamurugan, Minh T. Ma, Chih-Hsiung Chen, Dongfang Liu, Renata Pasqualini, Wadih Arap, Stephen K. Burley, and Sagar D. Khare

Subjects

COVID-19, Medicine

Abstract

Given the COVID-19 pandemic, there is interest in understanding ligand-receptor features and targeted antibody-binding attributes against emerging SARS-CoV-2 variants. Here, we developed a large-scale structure-based pipeline for analysis of protein-protein interactions regulating SARS-CoV-2 immune evasion. First, we generated computed structural models of the Spike protein of 3 SARS-CoV-2 variants (B.1.1.529, BA.2.12.1, and BA.5) bound either to a native receptor (ACE2) or to a large panel of targeted ligands (n = 282), which included neutralizing or therapeutic monoclonal antibodies. Moreover, by using the Barnes classification, we noted an overall loss of interfacial interactions (with gain of new interactions in certain cases) at the receptor-binding domain (RBD) mediated by substituted residues for neutralizing complexes in classes 1 and 2, whereas less destabilization was observed for classes 3 and 4. Finally, an experimental validation of predicted weakened therapeutic antibody binding was performed in a cell-based assay. Compared with the original Omicron variant (B.1.1.529), derivative variants featured progressive destabilization of antibody-RBD interfaces mediated by a larger set of substituted residues, thereby providing a molecular basis for immune evasion. This approach and findings provide a framework for rapidly and efficiently generating structural models for SARS-CoV-2 variants bound to ligands of mechanistic and therapeutic value.

Published

2023

3. Computational design of nanomolar-binding antibodies specific to multiple SARS-CoV-2 variants by engineering a specificity switch of antibody 80R using RosettaAntibodyDesign (RAbD) results in potential generalizable therapeutic antibodies for novel SARS-CoV-2 virus

Author

Nancy E. Hernandez, Wojciech Jankowski, Rahel Frick, Simon P. Kelow, Joseph H. Lubin, Vijaya Simhadri, Jared Adolf-Bryfogle, Sagar D. Khare, Roland L. Dunbrack, Jr., Jeffrey J. Gray, and Zuben E. Sauna

Subjects

Protein engineering, Coronavirus Disease 2019, Computational antibody design, Monoclonal antibody therapeutics, Diagnostic, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

The human infectious disease COVID-19 caused by the SARS-CoV-2 virus has become a major threat to global public health. Developing a vaccine is the preferred prophylactic response to epidemics and pandemics. However, for individuals who have contracted the disease, the rapid design of antibodies that can target the SARS-CoV-2 virus fulfils a critical need. Further, discovering antibodies that bind multiple variants of SARS-CoV-2 can aid in the development of rapid antigen tests (RATs) which are critical for the identification and isolation of individuals currently carrying COVID-19. Here we provide a proof-of-concept study for the computational design of high-affinity antibodies that bind to multiple variants of the SARS-CoV-2 spike protein using RosettaAntibodyDesign (RAbD). Well characterized antibodies that bind with high affinity to the SARS-CoV-1 (but not SARS-CoV-2) spike protein were used as templates and re-designed to bind the SARS-CoV-2 spike protein with high affinity, resulting in a specificity switch. A panel of designed antibodies were experimentally validated. One design bound to a broad range of variants of concern including the Omicron, Delta, Wuhan, and South African spike protein variants.

Published

2023

4. Prediction and Design of Protease Specificity Using a Structure-Aware Graph Convolutional Network

Author

Changpeng Lu, Joseph H. Lubin, Vidur V. Sarma, Samuel Z. Stentz, Guanyang Wang, Sijian Wang, and Sagar D. Khare

Subjects

protease specificity, protease design, deep learning

Abstract

Specific molecular recognition of substrates by enzymes, e.g., proteases, is critical for maintaining the robustness of crucial life processes. The ability to predictably tailor protease specificity would enable targeted proteolytic cleavage of any chosen target protein. Current methods for predicting protease specificity rely on sequence pattern recognition in experimentally-derived cleavage data obtained for libraries of substrates. We reasoned that a more semantically rich and robust model of protease specificity could be developed by incorporating the three-dimensional structure and energetics of molecular interactions between protease and substrates. We present a Protein Graph Convolutional Network (PGCN), which uses a physically-grounded, structure-based molecular interaction graph representation that describes molecular topology and energetics to predict specificity. PGCN was shown to accurately predict the specificity landscapes of several variants of two model proteases: the NS3/4 protease from the Hepatitis C virus (HCV) and the Tobacco Etch Virus (TEV) proteases. Node and edge ablation tests identified key graph elements for specificity prediction, some of which are consistent with known biochemical constraints for protease:substrate recognition. We used a pre-trained PGCN model to guide the design of TEV protease libraries for cleaving two non-canonical substrates and found high correspondence between PGCN prediction and experimental cleavage results for 19 designed protease variants. The described methodology should be applicable to the construction of tailor-made proteases for site-selectively cleaving chosen substrate sequences, enabling broad applications in protein design. Here is a brief description of each file: protease-gcnn-pytorch.zip PGCN codes. See the latest version here: https://github.com/Nucleus2014/protease-gcnn-pytorch train_val_test_graph_datasets.zip Datasets for the training process of PGCN. Statistics of them are shown in Table 1. tev_design_for_validation_pdbstructures.zip Final selected designs for experimental testing tev_oydv_design_candidates_pdbstructures.zip Candidate designs made by Rosetta, We acknowledge NSF Molecular Foundations of Biotechnology grant CHE2226816 (to S.D.K and S.W). Joseph H. Lubin was funded by the Rutgers National Institutes of Health Biotechnology Training Program (T32 GM008339 and GM135141). Samuel Stentz was funded by the Rosetta Commons Research Experience for Undergraduates.

Published

2023

5. Prediction and Design of Protease Enzyme Specificity Using a Structure-Aware Graph Convolutional Network

Author

Changpeng Lu, Joseph H. Lubin, Vidur V. Sarma, Samuel Z. Stentz, Guanyang Wang, Sijian Wang, and Sagar D. Khare

Subjects

Article

Abstract

Site-specific proteolysis by the enzymatic cleavage of small linear sequence motifs is a key post-translational modification involved in physiology and disease. The ability to robustly and rapidly predict protease substrate specificity would also enable targeted proteolytic cleavage – editing – of a target protein by designed proteases. Current methods for predicting protease specificity are limited to sequence pattern recognition in experimentally-derived cleavage data obtained for libraries of potential substrates and generated separately for each protease variant. We reasoned that a more semantically rich and robust model of protease specificity could be developed by incorporating the three-dimensional structure and energetics of molecular interactions between protease and substrates into machine learning workflows. We present Protein Graph Convolutional Network (PGCN), which develops a physically-grounded, structure-based molecular interaction graph representation that describes molecular topology and interaction energetics to predict enzyme specificity. We show that PGCN accurately predicts the specificity landscapes of several variants of two model proteases: the NS3/4 protease from the Hepatitis C virus (HCV) and the Tobacco Etch Virus (TEV) proteases. Node and edge ablation tests identified key graph elements for specificity prediction, some of which are consistent with known biochemical constraints for protease:substrate recognition. We used a pre-trained PGCN model to guide the design of TEV protease libraries for cleaving two non-canonical substrates, and found good agreement with experimental cleavage results. Importantly, the model can accurately assess designs featuring diversity at positions not present in the training data. The described methodology should enable the structure-based prediction of specificity landscapes of a wide variety of proteases and the construction of tailor-made protease editors for site-selectively and irreversibly modifying chosen target proteins.

Published

2023

6. A comprehensive survey of coronaviral main protease active site diversity in 3D: Identifying and analyzing drug discovery targets in search of broad specificity inhibitors for the next coronavirus pandemic

Author

Joseph H. Lubin, Samantha G. Martinusen, Christine Zardecki, Cassandra Olivas, Mickayla Bacorn, MaryAgnes Balogun, Ethan W. Slaton, Amy Wu Wu, Sarah Sakeer, Brian P. Hudson, Carl A. Denard, Stephen K. Burley, and Sagar D. Khare

Abstract

Although the rapid development of therapeutic responses to combat SARS-CoV-2 represents a great human achievement, it also demonstrates untapped potential for advanced pandemic preparedness. Cross-species efficacy against multiple human coronaviruses by the main protease (MPro) inhibitor nirmatrelvir raises the question of its breadth of inhibition and our preparedness against future coronaviral threats. Herein, we describe sequence and structural analyses of 346 unique MPro enzymes from all coronaviruses represented in the NCBI Virus database. Cognate substrates of these representative proteases were inferred from their polyprotein sequences. We clustered MPro sequences based on sequence identity and AlphaFold2-predicted structures, showing approximate correspondence with known viral subspecies. Predicted structures of five representative MPros bound to their inferred cognate substrates showed high conservation in protease:substrate interaction modes, with some notable differences. Yeast-based proteolysis assays of the five representatives were able to confirm activity of three on inferred cognate substrates, and demonstrated that of the three, only one was effectively inhibited by nirmatrelvir. Our findings suggest that comprehensive preparedness against future potential coronaviral threats will require continued inhibitor development. Our methods may be applied to candidate coronaviral MPro inhibitors to evaluate in advance the breadth of their inhibition and identify target coronaviruses potentially meriting advanced development of alternative countermeasures.

Published

2023

7. Evolution of the <scp>SARS‐CoV</scp> ‐2 proteome in three dimensions (3D) during the first 6 months of the <scp>COVID</scp> ‐19 pandemic

Author

Charlotte Labrie-Cleary, Jitendra Singh, Steven Arnold, Andrew Sam, Mark Dresel, Luz Helena Alfaro Alvarado, Rebecca Roberts, Emily Fingar, Jennifer Jiang, Paul Craig, Jean Baum, Eddy Arnold, Christine Zardecki, Grace Brannigan, Julia R. Koeppe, Elizabeth M Hennen, Alan Trudeau, Joseph H Lubin, Thejasvi Venkatachalam, Jonathan K. Williams, Kevin Catalfano, Stephen K. Burley, Brian P. Hudson, Isaac Paredes, Sagar D. Khare, Yana Bromberg, Katherine See, Evan Lenkeit, Shuchismita Dutta, J. Steen Hoyer, Erika McCarthy, Michael J. Pikaart, Santiago Soto Zapata, Jenna Currier, Stephanie Laporte, Jay A. Tischfield, Siobain Duffy, Britney Dyszel, Maria Voigt, Changpeng Lu, Bonnie L. Hall, Jesse Sandberg, Kailey Martin, Aaliyah Khan, Stephen A. Mills, Sophia Staggers, Allison Rupert, Elliott M Dolan, Vidur Sarma, Lindsey Whitmore, Helen Zheng, Ashish Duvvuru, David S. Goodsell, Michael Kirsch, Melanie Ortiz-Alvarez de la Campa, Ali A Khan, Matthew Benedek, Francesc X. Ruiz, John D. Westbrook, Marilyn Orellana, Lingjun Xie, Zhuofan Shen, Baleigh Wheeler, and Brea Tinsley

Subjects

Proteome, databases, Viral protein, coronavirus, Computational biology, pandemics, Biology, medicine.disease_cause, Biochemistry, Article, Virus, SARS‐CoV‐2, Protein structure, COVID‐19, Structural Biology, Molecular evolution, evolution, medicine, Humans, Prospective Studies, molecular, Amino Acids, Molecular Biology, Research Articles, chemistry.chemical_classification, SARS-CoV-2, Drug discovery, COVID-19, Robustness (evolution), computer.file_format, Protein Data Bank, Amino acid, viral proteins, chemistry, protein, computer, Function (biology), Research Article

Abstract

Three-dimensional structures of SARS-CoV-2 and other coronaviral proteins archived in the Protein Data Bank were used to analyze viral proteome evolution during the first six months of the COVID-19 pandemic. Analyses of spatial locations, chemical properties, and structural and energetic impacts of the observed amino acid changes in >48,000 viral proteome sequences showed how each one of the 29 viral study proteins have undergone amino acid changes. Structural models computed for every unique sequence variant revealed that most substitutions map to protein surfaces and boundary layers with a minority affecting hydrophobic cores. Conservative changes were observed more frequently in cores versus boundary layers/surfaces. Active sites and protein-protein interfaces showed modest numbers of substitutions. Energetics calculations showed that the impact of substitutions on the thermodynamic stability of the proteome follows a universal bi-Gaussian distribution. Detailed results are presented for six drug discovery targets and four structural proteins comprising the virion, highlighting substitutions with the potential to impact protein structure, enzyme activity, and functional interfaces. Characterizing the evolution of the virus in three dimensions provides testable insights into viral protein function and should aid in structure-based drug discovery efforts as well as the prospective identification of amino acid substitutions with potential for drug resistance.

Published

2021

8. Review for 'A novel consensus‐based computational pipeline for screening of antibody therapeutics for efficacy against SARS‐CoV‐2 variants of concern including Omicron variant'

Author

null Joseph H. Lubin

Published

2022

9. Genetic and Structural Analysis of SARS-CoV-2 Spike Protein for Universal Epitope Selection

Author

Christopher Markosian, Daniela I. Staquicini, Prashant Dogra, Esteban Dodero-Rojas, Joseph H. Lubin, Fenny H.F. Tang, Tracey L. Smith, Vinícius G. Contessoto, Steven K. Libutti, Zhihui Wang, Vittorio Cristini, Sagar D. Khare, Paul C. Whitford, Stephen K. Burley, José N. Onuchic, Renata Pasqualini, and Wadih Arap

Subjects

Genetics, Molecular Biology, Ecology, Evolution, Behavior and Systematics

Abstract

Evaluation of immunogenic epitopes for universal vaccine development in the face of ongoing SARS-CoV-2 evolution remains a challenge. Herein, we investigate the genetic and structural conservation of an immunogenically relevant epitope (C662–C671) of spike (S) protein across SARS-CoV-2 variants to determine its potential utility as a broad-spectrum vaccine candidate against coronavirus diseases. Comparative sequence analysis, structural assessment, and molecular dynamics simulations of C662–C671 epitope were performed. Mathematical tools were employed to determine its mutational cost. We found that the amino acid sequence of C662–C671 epitope is entirely conserved across the observed major variants of SARS-CoV-2 in addition to SARS-CoV. Its conformation and accessibility are predicted to be conserved, even in the highly mutated Omicron variant. Costly mutational rate in the context of energy expenditure in genome replication and translation can explain this strict conservation. These observations may herald an approach to developing vaccine candidates for universal protection against emergent variants of coronavirus.

Published

2022

10. Bioinformatics and 3D Structural Analysis of the Coronavirus Main Protease Active Site Diversity

Author

Amy Wu Wu, Joseph H. Lubin, Cassandra Olivas, Christine Zardecki, MaryAgnes Balogun, Mickayla L. Bacorn, Sagar D. Khare, and Stephen K. Burley

Subjects

Genetics, Molecular Biology, Biochemistry, Biotechnology

Published

2022

11. Structural models of SARS-CoV-2 Omicron variant in complex with ACE2 receptor or antibodies suggest altered binding interfaces

Author

Joseph H, Lubin, Christopher, Markosian, D, Balamurugan, Renata, Pasqualini, Wadih, Arap, Stephen K, Burley, and Sagar D, Khare

Subjects

Article

Abstract

There is enormous ongoing interest in characterizing the binding properties of the SARS-CoV-2 Omicron Variant of Concern (VOC) (B.1.1.529), which continues to spread towards potential dominance worldwide. To aid these studies, based on the wealth of available structural information about several SARS-CoV-2 variants in the Protein Data Bank (PDB) and a modeling pipeline we have previously developed for tracking the ongoing global evolution of SARS-CoV-2 proteins, we provide a set of computed structural models (henceforth models) of the Omicron VOC receptor-binding domain (omRBD) bound to its corresponding receptor Angiotensin-Converting Enzyme (ACE2) and a variety of therapeutic entities, including neutralizing and therapeutic antibodies targeting previously-detected viral strains. We generated bound omRBD models using both experimentally-determined structures in the PDB as well as machine learningbased structure predictions as starting points. Examination of ACE2-bound omRBD models reveals an interdigitated multi-residue interaction network formed by omRBD-specific substituted residues (R493, S496, Y501, R498) and ACE2 residues at the interface, which was not present in the original Wuhan-Hu-1 RBD-ACE2 complex. Emergence of this interaction network suggests optimization of a key region of the binding interface, and positive cooperativity among various sites of residue substitutions in omRBD mediating ACE2 binding. Examination of neutralizing antibody complexes for Barnes Class 1 and Class 2 antibodies modeled with omRBD highlights an overall loss of interfacial interactions (with gain of new interactions in rare cases) mediated by substituted residues. Many of these substitutions have previously been found to independently dampen or even ablate antibody binding, and perhaps mediate antibody-mediated neutralization escape (e.g., K417N). We observe little compensation of corresponding interaction loss at interfaces when potential escape substitutions occur in combination. A few selected antibodies (e.g., Barnes Class 3 S309), however, feature largely unaltered or modestly affected protein-protein interfaces. While we stress that only qualitative insights can be obtained directly from our models at this time, we anticipate that they can provide starting points for more detailed and quantitative computational characterization, and, if needed, redesign of monoclonal antibodies for targeting the Omicron VOC Spike protein. In the broader context, the computational pipeline we developed provides a framework for rapidly and efficiently generating retrospective and prospective models for other novel variants of SARS-CoV-2 bound to entities of virological and therapeutic interest, in the setting of a global pandemic.

Published

2021

12. Virtual Boot Camp: <scp>COVID</scp> ‐19 evolution and structural biology

Author

Christine Zardecki, Paul Craig, Sagar D. Khare, Jennifer Jiang, Siobain Duffy, Stephen K. Burley, Jitendra Singh, Yana Bromberg, Julia R. Koeppe, Jay A. Tischfield, Stephen A. Mills, Shuchismita Dutta, Rebecca Roberts, Bonnie L. Hall, Vidur Sarma, Lingjun Xie, Brian P. Hudson, Michael J. Pikaart, and Joseph H Lubin

Subjects

2019-20 coronavirus outbreak, Coronavirus disease 2019 (COVID-19), Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Biology, Biochemistry, Education, Distance, Evolution, Molecular, 03 medical and health sciences, Pandemic, Humans, Pandemics, Molecular Biology, Coronavirus 3C Proteases, 030304 developmental biology, Covid‐19, Boot camp, 0303 health sciences, SARS-CoV-2, Extramural, 05 social sciences, COVID-19, Computational Biology, 050301 education, Virology, Structural biology, Curriculum, 0503 education

Published

2020

13. A Parametric Rosetta Energy Function Analysis with LK Peptides on SAM Surfaces

Author

Joseph H. Lubin, Michael S. Pacella, and Jeffrey J. Gray

Subjects

Chemistry, Lysine, 02 engineering and technology, Surfaces and Interfaces, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, 0104 chemical sciences, Function analysis, Adsorption, Membrane protein, Monolayer, Electrochemistry, General Materials Science, 0210 nano-technology, Biological system, Spectroscopy, Function (biology), Energy (signal processing), Parametric statistics

Abstract

Although structures have been determined for many soluble proteins and an increasing number of membrane proteins, experimental structure determination methods are limited for complexes of proteins and solid surfaces. An economical alternative or complement to experimental structure determination is molecular simulation. Rosetta is one software suite that models protein-surface interactions, but Rosetta is normally benchmarked on soluble proteins. For surface interactions, the validity of the energy function is uncertain because it is a combination of independent parameters from energy functions developed separately for solution proteins and mineral surfaces. Here, we assess the performance of the RosettaSurface algorithm and test the accuracy of its energy function by modeling the adsorption of leucine/lysine (LK)-repeat peptides on methyl- and carboxy-terminated self-assembled monolayers (SAMs). We investigated how RosettaSurface predictions for this system compare with the experimental results, which showed that on both surfaces, LK-α peptides folded into helices and LK-β peptides held extended structures. Utilizing this model system, we performed a parametric analysis of Rosetta's Talaris energy function and determined that adjusting solvation parameters offered improved predictive accuracy. Simultaneously increasing lysine carbon hydrophilicity and the hydrophobicity of the surface methyl head groups yielded computational predictions most closely matching the experimental results. De novo models still should be interpreted skeptically unless bolstered in an integrative approach with experimental data.

Published

2018

14. Novel sampling strategies and a coarse-grained score function for docking homomers, flexible heteromers, and oligosaccharides using Rosetta in CAPRI Rounds 37–45

Author

Shourya S. Roy Burman, Morgan L. Nance, Jeliazko R. Jeliazkov, Jason W. Labonte, Jeffrey J. Gray, Joseph H. Lubin, and Naireeta Biswas

Subjects

Protein Conformation, alpha-Helical, Computer science, Oligosaccharides, Score, Ligands, Biochemistry, Article, 03 medical and health sciences, Critical Assessment of Prediction of Interactions, Structural Biology, Protein Interaction Mapping, Humans, Macromolecular docking, Protein Interaction Domains and Motifs, Amino Acid Sequence, Molecular Biology, Conformational isomerism, 030304 developmental biology, 0303 health sciences, Binding Sites, 030302 biochemistry & molecular biology, Scoring methods, Proteins, Molecular Docking Simulation, Research Design, Structural Homology, Protein, Docking (molecular), Protein Conformation, beta-Strand, Protein Multimerization, Peptides, Algorithm, Software, Protein Binding, Macromolecule

Abstract

Critical Assessment of PRediction of Interactions (CAPRI) rounds 37 through 45 introduced larger complexes, new macromolecules, and multistage assemblies. For these rounds, we used and expanded docking methods in Rosetta to model 23 target complexes. We successfully predicted 14 target complexes and recognized and refined near-native models generated by other groups for two further targets. Notably, for targets T110 and T136, we achieved the closest prediction of any CAPRI participant. We created several innovative approaches during these rounds. Since round 39 (target 122), we have used the new RosettaDock 4.0, which has a revamped coarse-grained energy function and the ability to perform conformer selection during docking with hundreds of pregenerated protein backbones. Ten of the complexes had some degree of symmetry in their interactions, so we tested Rosetta SymDock, realized its shortcomings, and developed the next-generation symmetric docking protocol, SymDock2, which includes docking of multiple backbones and induced-fit refinement. Since the last CAPRI assessment, we also developed methods for modeling and designing carbohydrates in Rosetta, and we used them to successfully model oligosaccharide-protein complexes in round 41. Although the results were broadly encouraging, they also highlighted the pressing need to invest in (a) flexible docking algorithms with the ability to model loop and linker motions and in (b) new sampling and scoring methods for oligosaccharide-protein interactions.

Published

2019

15. Macromolecular modeling and design in Rosetta: recent methods and frameworks

Author

Jack Maguire, Ragul Gowthaman, Marion F. Sauer, Georg Kuenze, Tanja Kortemme, Benjamin Basanta, Indigo Chris King, Jens Meiler, Rhiju Das, Ora Schueler-Furman, Nicholas A. Marze, Brandon Frenz, Christoffer Norn, Julia Koehler Leman, Jason W. Labonte, Kala Bharath Pilla, Lei Shi, Sergey Lyskov, Brian D. Weitzner, Nir London, Karen R. Khar, Jaume Bonet, Nawsad Alam, Andreas Scheck, Alexander M. Sevy, Lars Malmström, Thomas Huber, Christopher Bystroff, Lior Zimmerman, Lorna Dsilva, Bruno E. Correia, Roland L. Dunbrack, Sergey Ovchinnikov, Rocco Moretti, Scott Horowitz, Phil Bradley, Frank DiMaio, Noah Ollikainen, Brian Kuhlman, Jeffrey J. Gray, Melanie L. Aprahamian, Andrew Leaver-Fay, Santrupti Nerli, Brian Koepnick, Xingjie Pan, Manasi A. Pethe, Andrew M. Watkins, Summer B. Thyme, Enrique Marcos, Vikram Khipple Mulligan, Hahnbeom Park, Po-Ssu Huang, David K. Johnson, Daniel-Adriano Silva, Patrick Barth, Shannon Smith, Caleb Geniesse, Jason K. Lai, Patrick Conway, Amelie Stein, Jeliazko R. Jeliazkov, David Baker, Dominik Gront, Kalli Kappel, Firas Khatib, Robert Kleffner, Brian J. Bender, Richard Bonneau, Kyle A. Barlow, Joseph H. Lubin, Shourya S. Roy Burman, Nikolaos G. Sgourakis, Yuval Sedan, Ryan E. Pavlovicz, Kristin Blacklock, Seth Cooper, Barak Raveh, Alisa Khramushin, John Karanicolas, Justin B. Siegel, Sharon L. Guffy, Brian G. Pierce, Alex Ford, Darwin Y. Fu, Orly Marcu, Gideon Lapidoth, Brian Coventry, René M. de Jong, Shane O’Conchúir, Thomas W. Linsky, William R. Schief, Rebecca F. Alford, Scott E. Boyken, Sagar D. Khare, Maria Szegedy, Ray Yu-Ruei Wang, Steven M. Lewis, Hamed Khakzad, Timothy M. Jacobs, Frank D. Teets, Lukasz Goldschmidt, Daisuke Kuroda, Steffen Lindert, P. Douglas Renfrew, Yifan Song, Jared Adolf-Bryfogle, Michael S. Pacella, and Aliza B. Rubenstein

Subjects

atomic-accuracy, Models, Molecular, Computer science, Macromolecular Substances, Protein Conformation, Interoperability, computational design, Score, antibody structures, Biochemistry, Article, homing endonuclease specificity, 03 medical and health sciences, Software, Molecular Biology, 030304 developmental biology, 0303 health sciences, business.industry, Proteins, Usability, fold determination, Cell Biology, Molecular Docking Simulation, variable region, Docking (molecular), protein-structure prediction, small-molecule docking, Modeling and design, Peptidomimetics, User interface, Software engineering, business, de-novo design, sparse nmr data, Biotechnology

Abstract

The Rosetta software for macromolecular modeling, docking and design is extensively used in laboratories worldwide. During two decades of development by a community of laboratories at more than 60 institutions, Rosetta has been continuously refactored and extended. Its advantages are its performance and interoperability between broad modeling capabilities. Here we review tools developed in the last 5 years, including over 80 methods. We discuss improvements to the score function, user interfaces and usability. Rosetta is available at ., This Perspective reviews tools developed over the past five years in the macromolecular modeling, docking and design software Rosetta.

Published

2019

16. Bioinformatics and 3D structural analysis of the coronavirus main protease active site

Author

Sagar D. Khare, Mickayla Bacorn, Christine Zardecki, Stephen K. Burley, Joseph H. Lubin, Cassandra Olivas, Amy Wu Wu, and Mary-Agnes Balogun

Subjects

Protease, biology, medicine.medical_treatment, Active site, Condensed Matter Physics, medicine.disease_cause, Biochemistry, Virology, Inorganic Chemistry, Structural Biology, biology.protein, medicine, General Materials Science, Physical and Theoretical Chemistry, Coronavirus

Published

2021

17. Understanding the active site of the SARS-CoV-2 papain-like protease (PLPro)

Author

Christine Zardecki, Joseph H. Lubin, Mickayla Bacorn, Sagar D. Khare, Cassandra Olivas, Amy Wu Wu, Stephen K. Burley, and Mary-Agnes Balogun

Subjects

Protease, biology, medicine.medical_treatment, Severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2), Active site, Condensed Matter Physics, Biochemistry, Virology, Inorganic Chemistry, Papain, chemistry.chemical_compound, chemistry, Structural Biology, medicine, biology.protein, General Materials Science, Physical and Theoretical Chemistry

Published

2021