An RNA Molecular Switch: Intrinsic Flexibility of 23S rRNA Helices 40 and 68 5′-UAA/5′-GAN Internal Loops Studied by Molecular Dynamics Methods

Réblová, Kamila; Střelcová, Zora; Kulhánek, Petr; Beššeová, Ivana; Mathews, David H.; Nostrand, Keith Van; Yildirim, Ilyas; Turner, Douglas H.; Šponer, Jiřı́

doi:10.1021/ct900440t

Cited by 45 publications

(40 citation statements)

References 93 publications

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“…This method has been successfully applied to a number of biological processes of similar complexity. 51,52 We have used the NEB approach to model the pathway for cholesterol transfer between the NPC1(NTD) and NPC2 Figure 9, discussed in more detail in the text. The colors of the arrows match the colors of the cholesterol molecule in the images shown in Figure 9 for different steps of the transfer.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

Computational Studies of the Cholesterol Transport between NPC2 and the N-Terminal Domain of NPC1 (NPC1(NTD))

2013

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The transport of cholesterol from NPC2 to NPC1 is essential for the maintenance of cholesterol homeostasis in late endosomes. On the basis of a rigid docking model of the crystal structures of the N-terminal cholesterol binding domain of NPC1(NTD) and the soluble NPC2 protein, models of the NPC1(NTD)-NPC2-cholesterol complexes at the beginning and the end of the transport as well as the unligated NPC1(NTD)-NPC2 complex were studied using 86 ns MD simulations. Significant differences in the cholesterol binding mode and the overall structure of the two proteins compared to the crystal structures of the cholesterol binding separate units were obtained. Relevant residues for the binding are identified using MM/GBSA calculations and the influence of the mutations analyzed by modeling them in silico, rationalizing the results of previous mutagenesis experiments. From the calculated energies and the NEB (nudged elastic band) evaluation of the cholesterol transfer mechanism, an atomistic model is proposed of the transfer of cholesterol from NPC2 to NPC1(NTD) through the formation of an intermediate NPC1(NTD)-NPC2 complex.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Computational Studies of the Cholesterol Transport between NPC2 and the N-Terminal Domain of NPC1 (NPC1(NTD))

2013

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“…The parm99 and parmbsc0 force fields appear to provide equivalent (within the limits of the sampling achieved in our work) description of most parts of the present system, in agreement with other recent tests. 62,63 The parmbsc0 obviously penalizes the γ-trans backbone substates. This, however, usually does not have a substantial effect on the RNA behavior, and we cannot make any recommendation which of the two force fields is closer to reality.…”

Section: Discussionmentioning

confidence: 99%

Structural Dynamics of the Box C/D RNA Kink-Turn and Its Complex with Proteins: The Role of the A-Minor 0 Interaction, Long-Residency Water Bridges, and Structural Ion-Binding Sites Revealed by Molecular Simulations

2010

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Kink-turns (K-turns) are recurrent elbow-like RNA motifs that participate in protein-assisted RNA folding and contribute to RNA dynamics. We carried out a set of molecular dynamics (MD) simulations using parm99 and parmbsc0 force fields to investigate structural dynamics of the box C/D RNA and its complexes with two proteins: native archaeal L7ae protein and human 15.5 kDa protein, originally bound to very similar structure of U4 snRNA. The box C/D RNA forms K-turn with A-minor 0 tertiary interaction between its canonical (C) and noncanonical (NC) stems. The local K-turn architecture is thus different from the previously studied ribosomal K-turns 38 and 42 having A-minor I interaction. The simulations reveal visible structural dynamics of this tertiary interaction involving altogether six substates which substantially contribute to the elbow-like flexibility of the K-turn. The interaction can even temporarily shift to the A-minor I type pattern; however, this is associated with distortion of the G/A base pair in the NC-stem of the K-turn. The simulations show reduction of the K-turn flexibility upon protein binding. The protein interacts with the apex of the K-turn and with the NC-stem. The protein-RNA interface includes long-residency hydration sites. We have also found long-residency hydration sites and major ion-binding sites associated with the K-turn itself. The overall topology of the K-turn remains stable in all simulations. However, in simulations of free K-turn, we observed instability of the key C16(O2')-A7(N1) H-bond, which is a signature interaction of K-turns and which was visibly more stable in simulations of K-turns possessing A-minor I interaction. It may reflect either some imbalance of the force field or it may be a correct indication of early stages of unfolding since this K-turn requires protein binding for its stabilization. Interestingly, the 16(O2')-7(N1) H- bond is usually not fully lost since it is replaced by a water bridge with a tightly bound water, which is adenine-specific similarly as the original interaction. The 16(O2')-7(N1) H-bond is stabilized by protein binding. The stabilizing effect is more visible with the human 15.5 kDa protein, which is attributed to valine to arginine substitution in the binding site. The behavior of the A-minor interaction is force-field-dependent because the parmbsc0 force field attenuates the A-minor fluctuations compared to parm99 simulations. Behavior of other regions of the box C/D RNA is not sensitive to the force field choice. Simulation with net-neutralizing Na(+) and 0.2 M excess salt conditions appear in all aspects equivalent. The simulations show loss of a hairpin tetraloop, which is not part of the K-turn. This was attributed to force field limitations.

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“…Moreover, the force field variants parm94, parm99, and parmbsc0 all resulted in overall similar descriptions of RNA structures in simulations of up to 100 ns length in previous studies. 54,55 Thus, we expect that the main results of our simulations will not be sensitive to the used Amber force field variant.…”

Section: Methodsmentioning

confidence: 99%

“…50,51 A recent reparameterization of the R and γ torsions in these force fields led to the parmbsc0 force field, 52 which improved the simulation of DNA duplexes on very long time scales (1 µs range). However, further tests on A-RNA duplexes 53 and UAA/GAN internal loops of 23S rRNA H40 54 revealed that the penalization of the R/γ transitions in the parmbsc0 force field may be too excessive for RNA structures and leads to a modest narrowing of the major groove due to the suppression of the γ-trans states. 54 In the present study, when investigating R and γ torsions sampled during MD and REMD simulations using parm94, we found only one to two transitions toward R/γ t/t substates, e.g., for nucleotides 20 and 28 in the two stem regions.…”

Section: Methodsmentioning

confidence: 99%

“…However, further tests on A-RNA duplexes 53 and UAA/GAN internal loops of 23S rRNA H40 54 revealed that the penalization of the R/γ transitions in the parmbsc0 force field may be too excessive for RNA structures and leads to a modest narrowing of the major groove due to the suppression of the γ-trans states. 54 In the present study, when investigating R and γ torsions sampled during MD and REMD simulations using parm94, we found only one to two transitions toward R/γ t/t substates, e.g., for nucleotides 20 and 28 in the two stem regions. This result agrees with the occasional finding of these substates in experimental structures 54 and, thus, supports the validity of our simulations.…”

Section: Methodsmentioning

confidence: 99%

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HIV-1 TAR RNA Spontaneously Undergoes Relevant Apo-to-Holo Conformational Transitions in Molecular Dynamics and Constrained Geometrical Simulations

Fulle

Christ

Kestner

et al. 2010

J. Chem. Inf. Model.

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We report all-atom molecular dynamics and replica exchange molecular dynamics simulations on the unbound human immunodeficiency virus type-1 (HIV-1) transactivation responsive region (TAR) RNA structure and three TAR RNA structures in bound conformations of, in total, ∼250 ns length. We compare the extent of observed conformational sampling with that of the conceptually simpler and computationally much cheaper constrained geometrical simulation approach framework rigidity optimized dynamic algorithm (FRODA). Atomic fluctuations obtained by replica-exchange molecular dynamics (REMD) simulations agree quantitatively with those obtained by molecular dynamics (MD) and FRODA simulations for the unbound TAR structure. Regarding the stereochemical quality of the generated conformations, backbone torsion angles and puckering modes of the sugar-phosphate backbone were reproduced equally well by MD and REMD simulations, but further improvement is needed in the case of FRODA simulations. Essential dynamics analysis reveals that all three simulation approaches show a tendency to sample bound conformations when starting from the unbound TAR structure, with MD and REMD simulations being superior with respect to FRODA. These results are consistent with the experimental view that bound TAR RNA conformations are transiently sampled in the free ensemble, following a conformation selection model. The simulation-generated TAR RNA conformations have been successfully used as receptor structures for docking. This finding has important implications for RNA-ligand docking in that docking into an ensemble of simulation-generated RNA structures is shown to be a valuable means to cope with large apo-to-holo conformational transitions of the receptor structure.

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An RNA Molecular Switch: Intrinsic Flexibility of 23S rRNA Helices 40 and 68 5′-UAA/5′-GAN Internal Loops Studied by Molecular Dynamics Methods

Cited by 45 publications

References 93 publications

Computational Studies of the Cholesterol Transport between NPC2 and the N-Terminal Domain of NPC1 (NPC1(NTD))

Computational Studies of the Cholesterol Transport between NPC2 and the N-Terminal Domain of NPC1 (NPC1(NTD))

Structural Dynamics of the Box C/D RNA Kink-Turn and Its Complex with Proteins: The Role of the A-Minor 0 Interaction, Long-Residency Water Bridges, and Structural Ion-Binding Sites Revealed by Molecular Simulations

HIV-1 TAR RNA Spontaneously Undergoes Relevant Apo-to-Holo Conformational Transitions in Molecular Dynamics and Constrained Geometrical Simulations

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