A distinctive RNA fold: the solution structure of an analogue of the yeast tRNAPhe T Psi C domain.Koshlap, K.M., Guenther, R., Sochacka, E., Malkiewicz, A., Agris, P.F.
(1999) Biochemistry 38: 8647-8656
- PubMed: 10393540
- DOI: 10.1021/bi990118w
- Structures With Same Primary Citation
- PubMed Abstract:
- Small Structural Ensembles for a 17-Nucleotide Mimic of the tRNA Tpsic-Loop Via Fitting Dipolar Relaxation Rates with the Quadratic Programming Algorithm
Schmitz, U., Donati, A., James, T.L., Ulyanov, N.B., Yao, L.
(1998) Biopolymers 46: 329
- The Dynamic NMR Structure of the T Psi C-Loop: Implications for the Specificity of tRNA Methylation
Yao, L.J., James, T.L., Kealey, J.T., Santi, D.V., Schmitz, U.
(1997) J Biomol NMR 3: 229
- Restrained Refinement of the Monoclinic Form of Yeast Phenylalanine Transfer RNA. Temperature Factors and Dynamics, Coordinated Waters, and Base-Pair Propeller Twist Angles
Westhof, E., Sundaralingam, M.
(1986) Biochemistry 25: 4868
The structure of an analogue of the yeast tRNAPhe T Psi C stem-loop has been determined by NMR spectroscopy and restrained molecular dynamics. The molecule contained the highly conserved modification ribothymidine at its naturally occurring position. ...
The structure of an analogue of the yeast tRNAPhe T Psi C stem-loop has been determined by NMR spectroscopy and restrained molecular dynamics. The molecule contained the highly conserved modification ribothymidine at its naturally occurring position. The ribothymidine-modified T Psi C stem-loop is the product of the m5U54-tRNA methyltransferase, but is not a substrate for the m1A58-tRNA methyltransferase. Site-specific substitutions and 15N labels were used to confirm the assignment of NOESY cross-peaks critical in defining the global fold of the molecule. The structure is unusual in that the loop folds far over into the major groove of the curved stem. This conformation is stabilized by both stacking interactions and hydrogen bond formation. Furthermore, this conformation appears to be unique among RNA hairpins of similar size. There is, however, a considerable resemblance to the analogous domain in the crystal structure of the full-length yeast tRNAPhe. We believe, therefore, that the structure we have determined may represent an intermediate in the folding pathway during the maturation of tRNA.
Department of Biochemistry, North Carolina State University, Raleigh 27695-7622, USA.