EC Number   |
Reference |
|---|
   5.4.99.12 | - |
648863 |
| 5.4.99.12 | crystal structures of TruA in complex with two different leucyl-tRNAs to 3.5-4.0 A resolution, in conjunction with functional assays and computer simulation. The structures capture three stages of the TruA-�tRNA reaction, TruA utilizes the intrinsic flexibility of the anticodon stem loop for site promiscuity and also to select against intrinsically stable tRNAs to avoid their overstabilization through pseudouridylation, thereby maintaining the balance between the flexibility and stability required for its biological function |
681882 |
| 5.4.99.12 | hanging-drop vapor diffusion method at 293 K. The crystals have a stick-like shape, and belong to the space group P4(1)2(1)2, with unit cell dimensions of a = b = 91.5 A and c = 164.0 A. Crystal structure is determined at 2.25 A resolution |
682845 |
| 5.4.99.12 | hanging-drop vapor diffusion method at room temperature. It is attempted to obtain structures of Escherichia coli TruA complexed with three Escherichia coli tRNAs representing all of the target sites: tRNALeu1 with uridine at 39, tRNALeu2 with uridine at 38 and 40, and tRNALeu3 with uridine at 38. These tRNAs are type II tRNAs with a 15 nucleotide variable loop. Three crystal forms are obtained from similar buffer conditions, containing the complex of the wild-type TruA and full-length tRNALeu1 in crystal I, and the complex of wild-type TruA and tRNALeu3 in crystal forms II and III. No crystals are obtained with tRNALeu2 |
681882 |
| 5.4.99.12 | native protein, to 1.5 A resolution, and several derivatives. Structure reveals a dimeric protein that contains two positively charged, RNA-binding clefts along the surface of the protein. Each cleft contains a highly conserved aspartic acid located at its center. The structure suggests that a dimeric enzyme is required for binding transfer RNA and subsequent pseudouridine formation |
648863 |
| 5.4.99.12 | to 2.25 A resolution. Structure reveals the remarkably flexible structural features in the tRNA-binding cleft, which may be responsible for the primary tRNA interaction. The charged residues occupying the intermediate positions in the cleft may lead the tRNA to the active site for catalysis. The tRNA probably makes the melting base pairs move into the cleft, and a conformational change of the substrate tRNA may be necessary to facilitate access to the active site aspartate residue, deep within the cleft |
682845 |
