Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence

Xiangda Peng; Michael Baxa; Nabil Faruk; Joseph R. Sachleben; Sebastian Pintscher; Isabelle A. Gagnon; Scott Houliston; Cheryl H. Arrowsmith; Karl F. Freed; Gabriel J. Rocklin; Tobin R. Sosnick

doi:10.1021/acs.jctc.1c00960

Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence

Xiangda Peng, Michael Baxa, Nabil Faruk, Joseph R. Sachleben, Sebastian Pintscher, Isabelle A. Gagnon, Scott Houliston, Cheryl H. Arrowsmith, Karl F. Freed, Gabriel J. Rocklin, Tobin R. Sosnick^*

^*Corresponding author for this work

Pharmacology

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

9 Scopus citations

Abstract

The denaturant dependence of hydrogen-deuterium exchange (HDX) is a powerful measurement to identify the breaking of individual H-bonds and map the free energy surface (FES) of a protein including the very rare states. Molecular dynamics (MD) can identify each partial unfolding event with atomic-level resolution. Hence, their combination provides a great opportunity to test the accuracy of simulations and to verify the interpretation of HDX data. For this comparison, we use Upside, our new and extremely fast MD package that is capable of folding proteins with an accuracy comparable to that of all-atom methods. The FESs of two naturally occurring and two designed proteins are so generated and compared to our NMR/HDX data. We find that Upside's accuracy is considerably improved upon modifying the energy function using a new machine-learning procedure that trains for proper protein behavior including realistic denatured states in addition to stable native states. The resulting increase in cooperativity is critical for replicating the HDX data and protein stability, indicating that we have properly encoded the underlying physiochemical interactions into an MD package. We did observe some mismatch, however, underscoring the ongoing challenges faced by simulations in calculating accurate FESs. Nevertheless, our ensembles can identify the properties of the fluctuations that lead to HDX, whether they be small-, medium-, or large-scale openings, and can speak to the breadth of the native ensemble that has been a matter of debate.

Original language	English (US)
Pages (from-to)	550-561
Number of pages	12
Journal	Journal of Chemical Theory and Computation
Volume	18
Issue number	1
DOIs	https://doi.org/10.1021/acs.jctc.1c00960
State	Published - Jan 11 2022

Funding

We thank W. Yu for his advice on HDX calculations and the Protein Production Core (Lauren Carter, director) at the University of Washington Institute for Protein Design for providing labeled EHEE_rd2_0005 and HEEH_rd4_0097 for NMR studies. This work is supported by NIGMS grants GM55694 (T.R.S., K.F.F.) and R01 GM130122 (T.R.S., P. Clark), NSF grants MCB-1517221 (B. Roux) and MCB-2023077 (T.R.S.), Natural Sciences, and the Princess Margaret Cancer Centre. NMR spectroscopy was performed in the Biomolecular NMR Core Facility at the University of Chicago. The Structural Genomics Consortium is a registered charity (no: 1097737) that receives funds from Bayer AG, Boehringer Ingelheim, Bristol Myers Squibb, Genentech, Genome Canada through Ontario Genomics Institute [OGI-196], EU/EFPIA/OICR/McGill/KTH/Diamond Innovative Medicines Initiative 2 Joint Undertaking [EUbOPEN grant 875510], Janssen, Merck KGaA (aka EMD in Canada and US), Pfizer, and Takeda.

ASJC Scopus subject areas

Computer Science Applications
Physical and Theoretical Chemistry

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10.1021/acs.jctc.1c00960

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Peng, X., Baxa, M., Faruk, N., Sachleben, J. R., Pintscher, S., Gagnon, I. A., Houliston, S., Arrowsmith, C. H., Freed, K. F., Rocklin, G. J., & Sosnick, T. R. (2022). Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence. Journal of Chemical Theory and Computation, 18(1), 550-561. https://doi.org/10.1021/acs.jctc.1c00960

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title = "Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence",

abstract = "The denaturant dependence of hydrogen-deuterium exchange (HDX) is a powerful measurement to identify the breaking of individual H-bonds and map the free energy surface (FES) of a protein including the very rare states. Molecular dynamics (MD) can identify each partial unfolding event with atomic-level resolution. Hence, their combination provides a great opportunity to test the accuracy of simulations and to verify the interpretation of HDX data. For this comparison, we use Upside, our new and extremely fast MD package that is capable of folding proteins with an accuracy comparable to that of all-atom methods. The FESs of two naturally occurring and two designed proteins are so generated and compared to our NMR/HDX data. We find that Upside's accuracy is considerably improved upon modifying the energy function using a new machine-learning procedure that trains for proper protein behavior including realistic denatured states in addition to stable native states. The resulting increase in cooperativity is critical for replicating the HDX data and protein stability, indicating that we have properly encoded the underlying physiochemical interactions into an MD package. We did observe some mismatch, however, underscoring the ongoing challenges faced by simulations in calculating accurate FESs. Nevertheless, our ensembles can identify the properties of the fluctuations that lead to HDX, whether they be small-, medium-, or large-scale openings, and can speak to the breadth of the native ensemble that has been a matter of debate.",

author = "Xiangda Peng and Michael Baxa and Nabil Faruk and Sachleben, {Joseph R.} and Sebastian Pintscher and Gagnon, {Isabelle A.} and Scott Houliston and Arrowsmith, {Cheryl H.} and Freed, {Karl F.} and Rocklin, {Gabriel J.} and Sosnick, {Tobin R.}",

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month = jan,

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doi = "10.1021/acs.jctc.1c00960",

language = "English (US)",

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Peng, X, Baxa, M, Faruk, N, Sachleben, JR, Pintscher, S, Gagnon, IA, Houliston, S, Arrowsmith, CH, Freed, KF, Rocklin, GJ & Sosnick, TR 2022, 'Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence', Journal of Chemical Theory and Computation, vol. 18, no. 1, pp. 550-561. https://doi.org/10.1021/acs.jctc.1c00960

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T1 - Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence

AU - Peng, Xiangda

AU - Baxa, Michael

AU - Faruk, Nabil

AU - Sachleben, Joseph R.

AU - Pintscher, Sebastian

AU - Gagnon, Isabelle A.

AU - Houliston, Scott

AU - Arrowsmith, Cheryl H.

AU - Freed, Karl F.

AU - Rocklin, Gabriel J.

AU - Sosnick, Tobin R.

PY - 2022/1/11

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AB - The denaturant dependence of hydrogen-deuterium exchange (HDX) is a powerful measurement to identify the breaking of individual H-bonds and map the free energy surface (FES) of a protein including the very rare states. Molecular dynamics (MD) can identify each partial unfolding event with atomic-level resolution. Hence, their combination provides a great opportunity to test the accuracy of simulations and to verify the interpretation of HDX data. For this comparison, we use Upside, our new and extremely fast MD package that is capable of folding proteins with an accuracy comparable to that of all-atom methods. The FESs of two naturally occurring and two designed proteins are so generated and compared to our NMR/HDX data. We find that Upside's accuracy is considerably improved upon modifying the energy function using a new machine-learning procedure that trains for proper protein behavior including realistic denatured states in addition to stable native states. The resulting increase in cooperativity is critical for replicating the HDX data and protein stability, indicating that we have properly encoded the underlying physiochemical interactions into an MD package. We did observe some mismatch, however, underscoring the ongoing challenges faced by simulations in calculating accurate FESs. Nevertheless, our ensembles can identify the properties of the fluctuations that lead to HDX, whether they be small-, medium-, or large-scale openings, and can speak to the breadth of the native ensemble that has been a matter of debate.

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Prediction and Validation of a Protein's Free Energy Surface Using Hydrogen Exchange and (Importantly) Its Denaturant Dependence

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