Publications
1997
Auffinger P, Westhof E
RNA hydration: three nanoseconds of multiple molecular dynamics simulations of the solvated tRNA(Asp) anticodon hairpin Journal Article
In: J Mol Biol, vol. 269, no. 3, pp. 326-341, 1997, ISBN: 9199403, (0022-2836 Journal Article).
Abstract | Links | BibTeX | Tags: Anticodon/*chemistry Base Composition *Computer Simulation Guanine/chemistry Hydrogen Bonding Models, Asp/*chemistry/metabolism Ribose/chemistry/metabolism Support, Molecular Nucleic Acid Conformation RNA, Non-U.S. Gov't Uridine/chemistry Water/*chemistry/metabolism, Transfer, Unité ARN
@article{,
title = {RNA hydration: three nanoseconds of multiple molecular dynamics simulations of the solvated tRNA(Asp) anticodon hairpin},
author = {P Auffinger and E Westhof},
url = {http://www.ncbi.nlm.nih.gov/entrez/query.fcgi?cmd=Retrieve&db=PubMed&dopt=Citation&list_uids=9199403},
isbn = {9199403},
year = {1997},
date = {1997-01-01},
journal = {J Mol Biol},
volume = {269},
number = {3},
pages = {326-341},
abstract = {The hydration of the tRNA(Asp) anticodon hairpin was investigated through the analysis of six 500 ps multiple molecular dynamics (MMD) trajectories generated by using the particle mesh Ewald method for the treatment of the long-range electrostatic interactions. Although similar in their dynamical characteristics, these six trajectories display different local hydration patterns reflecting the landscape of the "theoretical" conformational space being explored. The statistical view gained through the MMD strategy allowed us to characterize the hydration patterns around important RNA structural motifs such as a G-U base-pair, the anticodon U-turn, and two modified bases: pseudouridine and 1-methylguanine. The binding of ammonium counterions to the hairpin has also been investigated. No long-lived hydrogen bond between water and a 2'-hydroxyl has been observed. Water molecules with long-residence times are found bridging adjacent pro-Rp phosphate atoms. The conformation of the pseudouridine is stiffened by a water-mediated base-backbone interaction and the 1-methylguanine is additionally stabilized by long-lived hydration patterns. Such long-lived hydration patterns are essential to ensure the structural integrity of this hairpin motif. Consequently, our simulations confirm the conclusion reached from an analysis of X-ray crystal structures according to which water molecules form an integral part of nucleic acid structure. The fact that the same conclusion is reached from a static and a dynamic point of view suggests that RNA and water together constitute the biologically relevant functional entity.},
note = {0022-2836
Journal Article},
keywords = {Anticodon/*chemistry Base Composition *Computer Simulation Guanine/chemistry Hydrogen Bonding Models, Asp/*chemistry/metabolism Ribose/chemistry/metabolism Support, Molecular Nucleic Acid Conformation RNA, Non-U.S. Gov't Uridine/chemistry Water/*chemistry/metabolism, Transfer, Unité ARN},
pubstate = {published},
tppubtype = {article}
}
The hydration of the tRNA(Asp) anticodon hairpin was investigated through the analysis of six 500 ps multiple molecular dynamics (MMD) trajectories generated by using the particle mesh Ewald method for the treatment of the long-range electrostatic interactions. Although similar in their dynamical characteristics, these six trajectories display different local hydration patterns reflecting the landscape of the "theoretical" conformational space being explored. The statistical view gained through the MMD strategy allowed us to characterize the hydration patterns around important RNA structural motifs such as a G-U base-pair, the anticodon U-turn, and two modified bases: pseudouridine and 1-methylguanine. The binding of ammonium counterions to the hairpin has also been investigated. No long-lived hydrogen bond between water and a 2'-hydroxyl has been observed. Water molecules with long-residence times are found bridging adjacent pro-Rp phosphate atoms. The conformation of the pseudouridine is stiffened by a water-mediated base-backbone interaction and the 1-methylguanine is additionally stabilized by long-lived hydration patterns. Such long-lived hydration patterns are essential to ensure the structural integrity of this hairpin motif. Consequently, our simulations confirm the conclusion reached from an analysis of X-ray crystal structures according to which water molecules form an integral part of nucleic acid structure. The fact that the same conclusion is reached from a static and a dynamic point of view suggests that RNA and water together constitute the biologically relevant functional entity.