Studying ribosome dynamics with simplified models

•Molecular dynamics simulations with simplified energetic models allow for large-scale dynamics to be studied.•Simulations of the ribosome have revealed the critical influence of sterics and flexibility.•Experimental knowledge may be integrated within simplified models. With the broad accessibility...

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Veröffentlicht in:	Methods (San Diego, Calif.) Calif.), 2019-06, Vol.162-163, p.128-140
Hauptverfasser:	Levi, Mariana, Noel, Jeffrey K., Whitford, Paul C.
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Sprache:	eng
Schlagworte:	Structure based models tRNA
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container_title	Methods (San Diego, Calif.)
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creator	Levi, Mariana Noel, Jeffrey K. Whitford, Paul C.
description	•Molecular dynamics simulations with simplified energetic models allow for large-scale dynamics to be studied.•Simulations of the ribosome have revealed the critical influence of sterics and flexibility.•Experimental knowledge may be integrated within simplified models. With the broad accessibility of high-performance computing resources, the significance of a molecular dynamics simulation is now rarely limited by hardware and/or software availability. Rather, the scientific value of each calculation is determined by the principles that underlie the theoretical model. The current review addresses this topic in the context of simplified models applied to large-scale (∼20–100 Å) dynamics in the ribosome. Specifically, we focus on applications of the “SMOG” class of structure-based models, which can be used to simulate spontaneous (i.e. non-targeted) conformational rearrangements in complex molecular assemblies. Here, we aim to provide an entry-level assessment of the methods, which can help bridge conceptual and communication gaps between the experimental and computational communities. In addition, inspecting the strategies that have been deployed previously can provide guidelines for future computational investigations into the relationship between structure, energetics and dynamics in other assemblies.
doi_str_mv	10.1016/j.ymeth.2019.03.023
format	Article
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With the broad accessibility of high-performance computing resources, the significance of a molecular dynamics simulation is now rarely limited by hardware and/or software availability. Rather, the scientific value of each calculation is determined by the principles that underlie the theoretical model. The current review addresses this topic in the context of simplified models applied to large-scale (∼20–100 Å) dynamics in the ribosome. Specifically, we focus on applications of the “SMOG” class of structure-based models, which can be used to simulate spontaneous (i.e. non-targeted) conformational rearrangements in complex molecular assemblies. Here, we aim to provide an entry-level assessment of the methods, which can help bridge conceptual and communication gaps between the experimental and computational communities. 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With the broad accessibility of high-performance computing resources, the significance of a molecular dynamics simulation is now rarely limited by hardware and/or software availability. Rather, the scientific value of each calculation is determined by the principles that underlie the theoretical model. The current review addresses this topic in the context of simplified models applied to large-scale (∼20–100 Å) dynamics in the ribosome. Specifically, we focus on applications of the “SMOG” class of structure-based models, which can be used to simulate spontaneous (i.e. non-targeted) conformational rearrangements in complex molecular assemblies. Here, we aim to provide an entry-level assessment of the methods, which can help bridge conceptual and communication gaps between the experimental and computational communities. 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title	Studying ribosome dynamics with simplified models
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