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Biophys. J. BioFAST: First Published January 26, 2007. doi:10.1529/biophysj.106.092601
© 2007 by the Biophysical Society.

A more recent version of this article appeared on April 15, 2007.
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BIOPHYSICAL THEORY AND MODELING

The conformational landscape of the ribosomal protein S15 and its influence on the protein interaction with 16S RNA

Thomas Créty 1 and Thérèse E Malliavin 1*

1 Institut de Biologie Physico-Chimique

* To whom correspondence should be addressed. E-mail: terez{at}pasteur.fr.

Submitted on July 4, 2006
Revised on August 14, 2006
Accepted on 13 December 2006


  Abstract
The interaction between the ribosomal protein S15 and its binding sites in the 16S RNA, was examined from two points of view. First, the isolated protein S15 was studied by comparing NMR conformer sets, available in the PDB and recalculated using the CNS-ARIA protocol. Molecular dynamics trajectories were then recorded starting from a conformer of each set. The recalculation of the S15 NMR structure, as well as the recording of MD trajectories, reveals that several orientations of the N terminal {alpha} helix {alpha}1 with respect to the structure core are populated. Molecular dynamics trajectories of the complex between the ribosomal protein S15 and RNA were also recorded in presence and in absence of ions Mg2+. The ions Mg2+ are hexa-coordinated by water and RNA oxygens. The coordination spheres mainly interact with the RNA phosphodiester backbone, reducing the RNA mobility and inducing electrostatic screening. When the ions Mg2+ are removed, the internal mobility of the RNA and of the protein increases at the interaction interface close to the RNA G-U/G-C motif, due to a gap between the phosphate groups in the UUCG capping tetraloop and to the disruption of S15-RNA hydrogen bonds in that region. On the other hand, several S15-RNA hydrogen bonds are reinforced and water bridges appear between the three way junction region and S15. The network of hydrogen bonds observed in the loop between {alpha}1 and {alpha}2 is consequently reorganized. In absence of Mg2+, this network has the same pattern as the network observed in the isolated protein, where the helix {alpha}1 is mobile with respect to the protein core. The presence of Magnesium ions may thus play a role in stabilizing the orientation of the helix {alpha}1 of S15.

Key Words: Magnesium, Molecular dynamics simulations, NMR structure determination, RNA, S15 ribosomal protein






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Copyright © 2007 by the Biophysical Society.