Your search keyword '"Tunde Aderinwale"' showing total 4 results

1. Real-time structure search and structure classification for AlphaFold protein models

Author

Tunde Aderinwale, Vijay Bharadwaj, Charles Christoffer, Genki Terashi, Zicong Zhang, Rashidedin Jahandideh, Yuki Kagaya, and Daisuke Kihara

Subjects

Biology (General), QH301-705.5

Abstract

3D-AF-Surfer is presented as a computational resource for real-time protein structure comparison search between AlphaFold2 models and PDB entries within seconds to a few minutes.

Published

2022

2. RL-MLZerD: Multimeric protein docking using reinforcement learning

Author

Tunde Aderinwale, Charles Christoffer, and Daisuke Kihara

Subjects

protein docking, multiple protein docking, reinforcement learning, docking order prediction, protein bioinformatics, Biology (General), QH301-705.5

Abstract

Numerous biological processes in a cell are carried out by protein complexes. To understand the molecular mechanisms of such processes, it is crucial to know the quaternary structures of the complexes. Although the structures of protein complexes have been determined by biophysical experiments at a rapid pace, there are still many important complex structures that are yet to be determined. To supplement experimental structure determination of complexes, many computational protein docking methods have been developed; however, most of these docking methods are designed only for docking with two chains. Here, we introduce a novel method, RL-MLZerD, which builds multiple protein complexes using reinforcement learning (RL). In RL-MLZerD a multi-chain assembly process is considered as a series of episodes of selecting and integrating pre-computed pairwise docking models in a RL framework. RL is effective in correctly selecting plausible pairwise models that fit well with other subunits in a complex. When tested on a benchmark dataset of protein complexes with three to five chains, RL-MLZerD showed better modeling performance than other existing multiple docking methods under different evaluation criteria, except against AlphaFold-Multimer in unbound docking. Also, it emerged that the docking order of multi-chain complexes can be naturally predicted by examining preferred paths of episodes in the RL computation.

Published

2022

3. LZerD webserver for pairwise and multiple protein–protein docking

Author

Daisuke Kihara, Tunde Aderinwale, Vijay Bharadwaj, Siyang Chen, Matin Hormati, Vidhur Kumar, and Charles Christoffer

Subjects

Web server, AcademicSubjects/SCI00010, Interface (Java), Biology, computer.software_genre, 03 medical and health sciences, Bacterial Proteins, Antigens, CD, DOCK, Genetics, Humans, Macromolecular docking, Representation (mathematics), 030304 developmental biology, Internet, 0303 health sciences, business.industry, 030302 biochemistry & molecular biology, Pattern recognition, Enoyl-(Acyl-Carrier-Protein) Reductase (NADH), Molecular Docking Simulation, Docking (molecular), Multiprotein Complexes, Web Server Issue, Pairwise comparison, Geometric hashing, Artificial intelligence, business, Cell Adhesion Molecules, computer, Software

Abstract

Protein complexes are involved in many important processes in living cells. To understand the mechanisms of these processes, it is necessary to solve the 3D structures of the protein complexes. When protein complex structures have not yet been determined by experiment, protein-protein docking tools can be used to computationally model the structures of these complexes. Here, we present a webserver which provides access to LZerD and Multi-LZerD protein docking tools. The protocol provided by the server have performed consistently among the top in the CAPRI blind evaluation. LZerD docks pairs of structures, while Multi-LZerD can dock three or more structures simultaneously. LZerD uses a soft protein surface representation with 3D Zernike descriptors and explores the binding pose space using geometric hashing. Multi-LZerD performs multi-chain docking by combining pairwise solutions by LZerD. Both methods output full-atom docked models of the input proteins. Users can also input distance constraints between interacting or non-interacting residues as well as residues that locate at the interface or far from the interface. The webserver is equipped with a user-friendly panel that visualizes the distribution and structures of binding poses of top scoring models. The LZerD webserver is available at https://lzerd.kiharalab.org., Graphical Abstract Graphical AbstractThe LZerD Protein Docking Server provides pairwise docking with LZerD and multi-chain docking with Multi-LZerD.

Published

2021

4. Detecting protein and DNA/RNA structures in cryo-EM maps of intermediate resolution using deep learning

Author

Tunde Aderinwale, Xiao Wang, Eman Alnabati, Daisuke Kihara, Sai Raghavendra Maddhuri Venkata Subramaniya, and Genki Terashi

Subjects

0301 basic medicine, Models, Molecular, Cryo-electron microscopy, Science, Biophysics, General Physics and Astronomy, computer.software_genre, 01 natural sciences, Convolutional neural network, General Biochemistry, Genetics and Molecular Biology, Article, Protein Structure, Secondary, 03 medical and health sciences, Computational biophysics, Protein structure, Deep Learning, Voxel, Cryoelectron microscopy, Protein secondary structure, Physics, Multidisciplinary, 010405 organic chemistry, business.industry, Deep learning, Resolution (electron density), RNA, Computational Biology, General Chemistry, DNA, 0104 chemical sciences, 030104 developmental biology, Nucleic Acid Conformation, Artificial intelligence, Biological system, business, computer, Software, Macromolecule

Abstract

An increasing number of density maps of macromolecular structures, including proteins and DNA/RNA complexes, have been determined by cryo-electron microscopy (cryo-EM). Although lately maps at a near-atomic resolution are routinely reported, there are still substantial fractions of maps determined at intermediate or low resolutions, where extracting structure information is not trivial. Here, we report a new computational method, Emap2sec+, which identifies DNA or RNA as well as the secondary structures of proteins in cryo-EM maps of 5 to 10 Å resolution. Emap2sec+ employs the deep Residual convolutional neural network. Emap2sec+ assigns structural labels with associated probabilities at each voxel in a cryo-EM map, which will help structure modeling in an EM map. Emap2sec+ showed stable and high assignment accuracy for nucleotides in low resolution maps and improved performance for protein secondary structure assignments than its earlier version when tested on simulated and experimental maps., It is challenging to extract structural information from EM density maps at intermediate or low resolutions. Here, the authors present Emap2sec+, a program for detecting nucleotides and protein secondary structures in EM density maps at 5 to 10 Å resolution.

Published

2021