Accurate prediction of protein structures and interactions using a three-track neural network M Baek, F DiMaio, I Anishchenko, J Dauparas, S Ovchinnikov, GR Lee, ... Science 373 (6557), 871-876, 2021 | 3377 | 2021 |
Improved protein structure prediction using predicted interresidue orientations J Yang, I Anishchenko, H Park, Z Peng, S Ovchinnikov, D Baker Proceedings of the National Academy of Sciences 117 (3), 1496-1503, 2020 | 1263 | 2020 |
Robust deep learning–based protein sequence design using ProteinMPNN J Dauparas, I Anishchenko, N Bennett, H Bai, RJ Ragotte, LF Milles, ... Science 378 (6615), 49-56, 2022 | 528 | 2022 |
De novo protein design by deep network hallucination I Anishchenko, SJ Pellock, TM Chidyausiku, TA Ramelot, S Ovchinnikov, ... Nature 600 (7889), 547-552, 2021 | 409 | 2021 |
Computed structures of core eukaryotic protein complexes IR Humphreys, J Pei, M Baek, A Krishnakumar, I Anishchenko, ... Science 374 (6573), eabm4805, 2021 | 362 | 2021 |
The trRosetta server for fast and accurate protein structure prediction Z Du, H Su, W Wang, L Ye, H Wei, Z Peng, I Anishchenko, D Baker, ... Nature protocols 16 (12), 5634-5651, 2021 | 350 | 2021 |
Scaffolding protein functional sites using deep learning J Wang, S Lisanza, D Juergens, D Tischer, JL Watson, KM Castro, ... Science 377 (6604), 387-394, 2022 | 236 | 2022 |
Protein interaction networks revealed by proteome coevolution Q Cong, I Anishchenko, S Ovchinnikov, D Baker Science 365 (6449), 185-189, 2019 | 233 | 2019 |
Improved protein structure refinement guided by deep learning based accuracy estimation N Hiranuma, H Park, M Baek, I Anishchenko, J Dauparas, D Baker Nature communications 12 (1), 1340, 2021 | 207 | 2021 |
Origins of coevolution between residues distant in protein 3D structures I Anishchenko, S Ovchinnikov, H Kamisetty, D Baker Proceedings of the National Academy of Sciences 114 (34), 9122-9127, 2017 | 182 | 2017 |
Prediction of homoprotein and heteroprotein complexes by protein docking and template‐based modeling: a CASP‐CAPRI experiment MF Lensink, S Velankar, A Kryshtafovych, SY Huang, ... Proteins: Structure, Function, and Bioinformatics 84, 323-348, 2016 | 166 | 2016 |
De novo design of luciferases using deep learning AHW Yeh, C Norn, Y Kipnis, D Tischer, SJ Pellock, D Evans, P Ma, ... Nature 614 (7949), 774-780, 2023 | 160 | 2023 |
Protein sequence design by conformational landscape optimization C Norn, BIM Wicky, D Juergens, S Liu, D Kim, D Tischer, B Koepnick, ... Proceedings of the National Academy of Sciences 118 (11), e2017228118, 2021 | 160* | 2021 |
Protein contact prediction using metagenome sequence data and residual neural networks Q Wu, Z Peng, I Anishchenko, Q Cong, D Baker, J Yang Bioinformatics 36 (1), 41-48, 2020 | 93 | 2020 |
Dockground: a comprehensive data resource for modeling of protein complexes PJ Kundrotas, I Anishchenko, T Dauzhenka, I Kotthoff, D Mnevets, ... Protein Science 27 (1), 172-181, 2018 | 83 | 2018 |
Computational model of the HIV-1 subtype A V3 loop: study on the conformational mobility for structure-based anti-AIDS drug design AM Andrianov, IV Anishchenko Journal of Biomolecular Structure and Dynamics 27 (2), 179-193, 2009 | 52 | 2009 |
ProteinGCN: Protein model quality assessment using graph convolutional networks S Sanyal, I Anishchenko, A Dagar, D Baker, P Talukdar BioRxiv, 2020.04. 06.028266, 2020 | 47 | 2020 |
Protein tertiary structure prediction and refinement using deep learning and Rosetta in CASP14 I Anishchenko, M Baek, H Park, N Hiranuma, DE Kim, J Dauparas, ... Proteins: Structure, Function, and Bioinformatics 89 (12), 1722-1733, 2021 | 44 | 2021 |
Design of proteins presenting discontinuous functional sites using deep learning D Tischer, S Lisanza, J Wang, R Dong, I Anishchenko, LF Milles, ... Biorxiv, 2020.11. 29.402743, 2020 | 41 | 2020 |
High‐accuracy refinement using Rosetta in CASP13 H Park, GR Lee, DE Kim, I Anishchenko, Q Cong, D Baker Proteins: Structure, Function, and Bioinformatics 87 (12), 1276-1282, 2019 | 41 | 2019 |