Abstract
k-Turns are widespread key architectural elements that occur in many classes of RNA molecules. We have shown previously that their folding properties (whether or not they fold into their tightly kinked structure on addition of metal ions) and conformation depend on their local sequence, and we have elucidated a series of rules for prediction of these properties from sequence. In this work, we have expanded the rules for prediction of folding properties, and then applied the full set to predict the folding and conformation of four probable k-turns we have identified amongst 224 structured RNA species found in bacterial intergenenic regions by the Breaker lab (1). We have analyzed the ion-dependence of folding of the four k-turns using fluorescence resonance energy transfer, and determined the conformation of two of them using X-ray crystallography. We find that the experimental data fully conform to both the predicted folding and conformational properties. We conclude that our folding rules are robust, and can be applied to new k-turns of unknown characteristics with confidence.
Highlights
Cesses [4], and are implicated in disease [5]
H. marismortui Kt-7 (HmKt-7) is the best characterized kturn structure [11]. In free solution it folds into the k-turn conformation on addition of divalent metal ions, or the binding of A. fulgidus L7Ae (AfL7Ae) protein. 17 independent crystal structures in a variety of environments reveal that when not in situ in the 50S ribosomal subunit HmKt7 adopts the N3-conformation [18]
We have found previously that the base pair at the 3b:3n position is an important determinant of the ability of the RNA to fold into the k-turn conformation on addition of metal ions [12], as well as the N3- or N1-conformation adopted [18]
Summary
Cesses [4], and are implicated in disease [5]. they offer potential therapeutic targets. For the great majority of these species, only nucleotide sequence information is available, and 3D structures have been determined for very few of them. RNA secondary structure can be reduced to rigid helical sections that are connected by junctions, the conformations of which will determine the trajectory of the helices. These will set up the formation of longer-range tertiary interactions that generate the overall three-dimensional fold.
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