Simulations of a Protein Crystal: Explicit Treatment of Crystallization Conditions Links Theory and Experiment in the Streptavidin-biotin Complex

Overview

Journal Biochemistry

Specialty Biochemistry

Date 2008 Oct 28

PMID 18950193

Citations 26

Authors

David S Cerutti

Isolde Le Trong

Ronald E Stenkamp

Terry P Lybrand

Affiliations

Soon will be listed here.

Abstract

A 250 ns molecular dynamics simulation of the biotin-liganded streptavidin crystal lattice, including cryoprotectant molecules and crystallization salts, is compared to a 250 ns simulation of the lattice solvated with pure water. The simulation using detailed crystallization conditions preserves the initial X-ray structure better than the simulation using pure water, even though the protein molecules display comparable mobility in either simulation. Atomic fluctuations computed from the simulation with crystallization conditions closely reproduce fluctuations derived from experimental temperature factors (correlation coefficient of 0.88, omitting two N-terminal residues with very high experimental B-factors). In contrast, fluctuations calculated from the simulation with pure water were less accurate, particularly for two of the streptavidin loops exposed to solvent in the crystal lattice. Finally, we obtain good agreement between the water and cryoprotectant densities obtained from the simulated crystallization conditions and the electron density due to solvent molecules in the X-ray structure. Our results suggest that detailed lattice simulations with realistic crystallization conditions can be used to assess potential function parameters, validate simulation protocols, and obtain valuable insights that solution-phase simulations do not easily provide. We anticipate that this will prove to be a powerful strategy for molecular dynamics simulations of biomolecules.

Citing Articles

Functional protein dynamics in a crystal.

Klyshko E, Kim J, McGough L, Valeeva V, Lee E, Ranganathan R Nat Commun. 2024; 15(1):3244.

PMID: 38622111 PMC: 11018856. DOI: 10.1038/s41467-024-47473-4.

Functional Protein Dynamics in a Crystal.

Klyshko E, Kim J, McGough L, Valeeva V, Lee E, Ranganathan R bioRxiv. 2023; .

PMID: 37461732 PMC: 10350071. DOI: 10.1101/2023.07.06.548023.

Brewing COFFEE: A sequence-specific coarse-grained energy function for simulations of DNA-protein complexes.

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Simulating diffraction photographs based on molecular dynamics trajectories of a protein crystal: a new option to examine structure-solving strategies in protein crystallography.

Liu N, Mikhailovskii O, Skrynnikov N, Xue Y IUCrJ. 2023; 10(Pt 1):16-26.

PMID: 36598499 PMC: 9812212. DOI: 10.1107/S2052252522011198.

LAWS: Local alignment for water sites-Tracking ordered water in simulations.

Klyshko E, Kim J, Rauscher S Biophys J. 2022; 122(14):2871-2883.

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