Reaction coordinates for RNA conformational changes

Mohan, Srividya

06 April 2009

This work investigates pathways of conformational transitions in ubiquitous RNA structural motifs. In our lab, we have developed multi-scale structural datamining techniques for identification of three-dimensional structural patterns in high-resolution crystal structures of globular RNA. I have applied these techniques to identify variations in the conformations of RNA double-helices and tetraloops. The datamined structural information is used to propose reaction coordinates for conformational transitions involved in double-strand helix propagation and tetraloop folding in RNA. I have also presented an algorithm to identify stacked RNA bases. In this work, experimentally derived thermodynamic evaluation of the conformations has been used to as an additional parameter to add detail to RNA structural transitions. RNA conformational transitions help control processes in small systems such as riboswitches and in large systems such as ribosomes. Adopting functional conformations by globular RNA during a folding process also involves structural transitions. RNA double-helices and tetraloops are common, ubiquitous structural motifs in globular RNA that independently fold in to a thermodynamically stable conformation. Folding models for these motifs are proposed in this work with probable intermediates ordered along the reaction coordinates. We hypothesize that frequently observed structural states in crystals structures are analogous in conformation to stable thermodynamic â on-pathwayâ folded states. Conversely, we hypothesize that conformations that are rarely observed are improbable folding intermediates, i.e., these conformational states are â off-pathwayâ states. In general on-pathway states are assumed to be thermodynamically more stable than off-pathway states, with the exception of kinetic traps. Structural datamining shows that double helices in RNA may propagate by the â stack-ratchetâ mechanism proposed here instead of the commonly accepted zipper mechanism. Mechanistic models for RNA tetraloop folding have been proposed and validated with experimentally derived thermodynamic data. The extent of stacking between bases in RNA is variable, indicating that stacking may not be a two-state phenomenon. A novel algorithm to define and identify stacked bases at atomic resolution has also been presented in this work.

Tetraloop folding

Helix propagation

Base stacking

RNA structure

RNA

Bioinformatics

Data mining

Helices (Algebraic topology)

Computer simulation of secondary structure of biological and synthetic macromolecules

Zhang, Wei

14 May 2009

RNA tetraloop is the smallest, simplest and the most frequent motif which is involved in numerous important biological functions. A local deviation from the RNA standard tetraloop, d2 tetraloop, has been identified with high abundance in 5S, 16S and 23S rRNAs. The presence of d2 tetraloops in highly conserved regions of 16S and 23S rRNAs suggests their functional importance. With one less residue in the loop, d2 tetraloops are considered more energetically restrained and less stable than standard tetraloops. The deletion at position j+2 in the loop is always correlated with adjacent stem distortion. MD simulations of 314-d2-tetraloop (a sample structure of d2 tetraloops) and cutd2-tetraloop (an artificially built perfect d2 tetraloop with no stem defects) have shown that stem defects are the stabilizing factor of d2 tetraloops. Simulations have also revealed that the insertion residue 318C (an example of stem defect) is stabilizing 314-d2-tetraloop by forming hydrogen bonding interactions with both the loop and the stem. When these two hydrogen bonding interactions are eliminated, the structure remained relatively stable compared to cutd2-tetraloop where the insertion residue was completely removed from the stem. This suggests the insertion residue is also stabilizing 314-d2-tetraloop by providing some conformational relaxation in the stem. Investigation of RNA standard tetraloop high temperature unfolding has revealed that the d2 tetraloop is possibly a kinetically trapped intermediate state during the folding of the standard tetraloop. High temperature unfolding simulations of standard tetraloop have shown a three-state folding behavior: a folded state, an intermediate state and an unfolded state. The folding of standard tetraloop starts with the formation of the loop. The closing base pair forms first, followed by the loop and the stem which form critical interactions such as base pairing and stacking that make a tetraloop. ROMP PNB has been investigated as supports to immobilize homogeneous catalysts to achieve both high reactivity and selectivity and easy separation. Polymers with intermediate conformational order can increase the accessibility of tethered homogeneous catalysts. Simulations of ROMP PNBDC_UD have shown the importance of bulky side groups in enabling the polymer to adopt a helical conformation. Such helical conformations have been associated with intermediate structural order in similar polymers such as PNB made by non-ROMP mechanisms. This intermediate order manifests itself as a split in the amorphous halo of WAXD pattern. Bulk simulations generated WAXD patterns that are close to the experimentally generated WAXD patterns where there are two split peaks: lower angle peak representing intermolecular interaction and higher angle peak representing intramolecular interaction.

Computer simulation

Molecular dynamics

RNA