CryoFold: Determining protein structures and data-guided ensembles from cryo-EM density maps

Mrinal Shekhar; Genki Terashi; Chitrak Gupta; Daipayan Sarkar; Gaspard Debussche; Nicholas J. Sisco; Jonathan Nguyen; Arup Mondal; John Vant; Petra Fromme; Wade D. Van Horn; Emad Tajkhorshid; Daisuke Kihara; Ken Dill; Alberto Perez; Abhishek Singharoy

doi:10.1016/j.matt.2021.09.004

CryoFold: Determining protein structures and data-guided ensembles from cryo-EM density maps

Mrinal Shekhar, Genki Terashi, Chitrak Gupta, Daipayan Sarkar, Gaspard Debussche, Nicholas J. Sisco, Jonathan Nguyen, Arup Mondal, John Vant, Petra Fromme, Wade D. Van Horn, Emad Tajkhorshid, Daisuke Kihara, Ken Dill, Alberto Perez, Abhishek Singharoy

Molecular Sciences, School of (SMS)

Research output: Contribution to journal › Article › peer-review

22 Scopus citations

Abstract

Cryoelectron microscopy requires molecular modeling for refinement of structures. Ensemble models arrive at low free-energy molecular structures, but are computationally expensive and limited to resolving only small proteins. We introduce CryoFold, a pipeline of molecular dynamics simulations that determines ensembles of protein structures by integrating density data of varying sparsity at 3–5 Å resolution with sequence information and coarse-grained topological knowledge of the protein folds. We present six examples, folding proteins between 72 and 2,000 residues, including large membrane and multi-domain systems, and results from two Electron Microscopy Data Bank (EMDB) competitions. Driven by data from a single state, CryoFold discovers ensembles of common low-energy models together with rare low-probability structures that capture the equilibrium distribution of proteins constrained by the density maps. Many of these conformations are experimentally validated and functionally relevant. We arrive at a set of best practices for data-guided protein folding that are controlled using a Python graphical user interface (GUI).

Original language	English (US)
Pages (from-to)	3195-3216
Number of pages	22
Journal	Matter
Volume	4
Issue number	10
DOIs	https://doi.org/10.1016/j.matt.2021.09.004
State	Published - Oct 6 2021

Keywords

ATP synthase
CryoEM modeling
MAP3: Understanding
computations
cryoelectron microscopy
ensemble refinement
integrative modeling
molecular dynamics simulations
protein folding ensemble

ASJC Scopus subject areas

General Materials Science

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10.1016/j.matt.2021.09.004

Cite this

Shekhar, M., Terashi, G., Gupta, C., Sarkar, D., Debussche, G., Sisco, N. J., Nguyen, J., Mondal, A., Vant, J., Fromme, P., Van Horn, W. D., Tajkhorshid, E., Kihara, D., Dill, K., Perez, A., & Singharoy, A. (2021). CryoFold: Determining protein structures and data-guided ensembles from cryo-EM density maps. Matter, 4(10), 3195-3216. https://doi.org/10.1016/j.matt.2021.09.004

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title = "CryoFold: Determining protein structures and data-guided ensembles from cryo-EM density maps",

abstract = "Cryoelectron microscopy requires molecular modeling for refinement of structures. Ensemble models arrive at low free-energy molecular structures, but are computationally expensive and limited to resolving only small proteins. We introduce CryoFold, a pipeline of molecular dynamics simulations that determines ensembles of protein structures by integrating density data of varying sparsity at 3–5 {\AA} resolution with sequence information and coarse-grained topological knowledge of the protein folds. We present six examples, folding proteins between 72 and 2,000 residues, including large membrane and multi-domain systems, and results from two Electron Microscopy Data Bank (EMDB) competitions. Driven by data from a single state, CryoFold discovers ensembles of common low-energy models together with rare low-probability structures that capture the equilibrium distribution of proteins constrained by the density maps. Many of these conformations are experimentally validated and functionally relevant. We arrive at a set of best practices for data-guided protein folding that are controlled using a Python graphical user interface (GUI).",

keywords = "ATP synthase, CryoEM modeling, MAP3: Understanding, computations, cryoelectron microscopy, ensemble refinement, integrative modeling, molecular dynamics simulations, protein folding ensemble",

author = "Mrinal Shekhar and Genki Terashi and Chitrak Gupta and Daipayan Sarkar and Gaspard Debussche and Sisco, {Nicholas J.} and Jonathan Nguyen and Arup Mondal and John Vant and Petra Fromme and {Van Horn}, {Wade D.} and Emad Tajkhorshid and Daisuke Kihara and Ken Dill and Alberto Perez and Abhishek Singharoy",

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doi = "10.1016/j.matt.2021.09.004",

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AU - Shekhar, Mrinal

AU - Terashi, Genki

AU - Gupta, Chitrak

AU - Sarkar, Daipayan

AU - Debussche, Gaspard

AU - Sisco, Nicholas J.

AU - Nguyen, Jonathan

AU - Mondal, Arup

AU - Vant, John

AU - Fromme, Petra

AU - Van Horn, Wade D.

AU - Tajkhorshid, Emad

AU - Kihara, Daisuke

AU - Dill, Ken

AU - Perez, Alberto

AU - Singharoy, Abhishek

PY - 2021/10/6

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N2 - Cryoelectron microscopy requires molecular modeling for refinement of structures. Ensemble models arrive at low free-energy molecular structures, but are computationally expensive and limited to resolving only small proteins. We introduce CryoFold, a pipeline of molecular dynamics simulations that determines ensembles of protein structures by integrating density data of varying sparsity at 3–5 Å resolution with sequence information and coarse-grained topological knowledge of the protein folds. We present six examples, folding proteins between 72 and 2,000 residues, including large membrane and multi-domain systems, and results from two Electron Microscopy Data Bank (EMDB) competitions. Driven by data from a single state, CryoFold discovers ensembles of common low-energy models together with rare low-probability structures that capture the equilibrium distribution of proteins constrained by the density maps. Many of these conformations are experimentally validated and functionally relevant. We arrive at a set of best practices for data-guided protein folding that are controlled using a Python graphical user interface (GUI).

AB - Cryoelectron microscopy requires molecular modeling for refinement of structures. Ensemble models arrive at low free-energy molecular structures, but are computationally expensive and limited to resolving only small proteins. We introduce CryoFold, a pipeline of molecular dynamics simulations that determines ensembles of protein structures by integrating density data of varying sparsity at 3–5 Å resolution with sequence information and coarse-grained topological knowledge of the protein folds. We present six examples, folding proteins between 72 and 2,000 residues, including large membrane and multi-domain systems, and results from two Electron Microscopy Data Bank (EMDB) competitions. Driven by data from a single state, CryoFold discovers ensembles of common low-energy models together with rare low-probability structures that capture the equilibrium distribution of proteins constrained by the density maps. Many of these conformations are experimentally validated and functionally relevant. We arrive at a set of best practices for data-guided protein folding that are controlled using a Python graphical user interface (GUI).

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KW - cryoelectron microscopy

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KW - molecular dynamics simulations

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CryoFold: Determining protein structures and data-guided ensembles from cryo-EM density maps

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Keywords

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