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Volume 5, Issue 1, Pages (January 1997)

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1 Volume 5, Issue 1, Pages 59-68 (January 1997)
The crystal structure of phenylalanyl-tRNA synthetase from Thermus thermophilus complexed with cognate tRNAPhe  Yehuda Goldgur, Lidia Mosyak, Ludmila Reshetnikova, Valentina Ankilova, Olga Lavrik, Svetlana Khodyreva, Mark Safro  Structure  Volume 5, Issue 1, Pages (January 1997) DOI: /S (97)

2 Figure 1 General view of PheRS–tRNAPhe complex structure. The intramolecular twofold axis goes vertically in the plane of the drawing. Domains and their designating inscriptions are the same colour. ‘CC’ stands for the coiled-coil domain of the α subunit. (Figure was drawn using MOLSCRIPT [36].) Structure 1997 5, 59-68DOI: ( /S (97) )

3 Figure 2 Comparison of the Th. thermophilus tRNAPhe bound to PheRS with the free yeast tRNAPhe. (a) Cloverleaf representation of Th. thermophilus tRNAPhe. Deviations from the sequence of yeast tRNAPhe are outlined in bold (completely different nucleotides) and in italics (different modifications of identical bases). Nucleosides that are in contact with the enzyme are boxed. Those forming base-specific contacts are shaded. The structural elements of PheRS interacting with the corresponding nucleosides of tRNAPhe are denoted. The structural elements of tRNAPhe are labeled in blue. Nucleoside marked A∗ may be ms2i5A or i5A (there are two types of tRNAPhe in Th. thermophilus). Watson–Crick pairs are marked by dots. The structural elements of the second heterodimer are marked with an asterisk. (b) Stereoview of the phosphate backbone of the bound Th. thermophilus tRNAPhe (black) superimposed on that of free yeast tRNAPhe (grey). In the bound state the angle between the acceptor and anticodon stems of the tRNA is about 120° versus 97° in free yeast tRNAPhe. The angle is achieved by the smooth bending of the stems, starting from base pairs 6–67 and 27–43. (Figure 2b was drawn using MOLSCRIPT [36].) (c) Schematic diagram of interactions between the bases of Th. thermophilus tRNAPhe in the region of T-Ψ and D loops. (Figure 2c was drawn with GRASP [38].) Structure 1997 5, 59-68DOI: ( /S (97) )

4 Figure 2 Comparison of the Th. thermophilus tRNAPhe bound to PheRS with the free yeast tRNAPhe. (a) Cloverleaf representation of Th. thermophilus tRNAPhe. Deviations from the sequence of yeast tRNAPhe are outlined in bold (completely different nucleotides) and in italics (different modifications of identical bases). Nucleosides that are in contact with the enzyme are boxed. Those forming base-specific contacts are shaded. The structural elements of PheRS interacting with the corresponding nucleosides of tRNAPhe are denoted. The structural elements of tRNAPhe are labeled in blue. Nucleoside marked A∗ may be ms2i5A or i5A (there are two types of tRNAPhe in Th. thermophilus). Watson–Crick pairs are marked by dots. The structural elements of the second heterodimer are marked with an asterisk. (b) Stereoview of the phosphate backbone of the bound Th. thermophilus tRNAPhe (black) superimposed on that of free yeast tRNAPhe (grey). In the bound state the angle between the acceptor and anticodon stems of the tRNA is about 120° versus 97° in free yeast tRNAPhe. The angle is achieved by the smooth bending of the stems, starting from base pairs 6–67 and 27–43. (Figure 2b was drawn using MOLSCRIPT [36].) (c) Schematic diagram of interactions between the bases of Th. thermophilus tRNAPhe in the region of T-Ψ and D loops. (Figure 2c was drawn with GRASP [38].) Structure 1997 5, 59-68DOI: ( /S (97) )

5 Figure 2 Comparison of the Th. thermophilus tRNAPhe bound to PheRS with the free yeast tRNAPhe. (a) Cloverleaf representation of Th. thermophilus tRNAPhe. Deviations from the sequence of yeast tRNAPhe are outlined in bold (completely different nucleotides) and in italics (different modifications of identical bases). Nucleosides that are in contact with the enzyme are boxed. Those forming base-specific contacts are shaded. The structural elements of PheRS interacting with the corresponding nucleosides of tRNAPhe are denoted. The structural elements of tRNAPhe are labeled in blue. Nucleoside marked A∗ may be ms2i5A or i5A (there are two types of tRNAPhe in Th. thermophilus). Watson–Crick pairs are marked by dots. The structural elements of the second heterodimer are marked with an asterisk. (b) Stereoview of the phosphate backbone of the bound Th. thermophilus tRNAPhe (black) superimposed on that of free yeast tRNAPhe (grey). In the bound state the angle between the acceptor and anticodon stems of the tRNA is about 120° versus 97° in free yeast tRNAPhe. The angle is achieved by the smooth bending of the stems, starting from base pairs 6–67 and 27–43. (Figure 2b was drawn using MOLSCRIPT [36].) (c) Schematic diagram of interactions between the bases of Th. thermophilus tRNAPhe in the region of T-Ψ and D loops. (Figure 2c was drawn with GRASP [38].) Structure 1997 5, 59-68DOI: ( /S (97) )

6 Figure 3 Stereoview of the anticodon-binding domain of PheRS (grey) with the anticodon loop of tRNAPhe (cyan). Residues in contact with tRNA are depicted as ball-and-stick models. Hydrogen bonds are shown as thin magenta lines. (Figure was drawn using MOLSCRIPT [36] and RASTER3D [37].) Structure 1997 5, 59-68DOI: ( /S (97) )

7 Figure 4 View of the CCA end of tRNAPhe in the active-site cavity of the enzyme. The dashed lines represent the hydrogen bonds. The letters A and B before residue numbers indicate the enzyme subunits. The relatively short distance (∼3.8 Å) between the N6 group of A73 (ADE73) and the phosphate group of C72 (CYT72) indicates that their intramolecular interaction may help to stabilize the conformation of the CCA end in a way that resembles tRNAGln [4]. However, the conformation of tRNAPhe in this region differs from that of tRNAGln. The letters A and B before residue numbers indicate the enzyme subunits. (Figure was drawn using MOLSCRIPT [36].) Structure 1997 5, 59-68DOI: ( /S (97) )

8 Figure 5 The α subunit of PheRS (gray) and a monomer of SerRS (yellow) after the superposition of their catalytic folds. The corresponding helical arms are oppositely directed. However, the orientation of the helical arms from α∗ subunit of PheRS and the second monomer (mon2) of SerRS with respect to the referenced catalytic folds is similar. (Figure was drawn using MOLSCRIPT [36] and RASTER3D [37].) Structure 1997 5, 59-68DOI: ( /S (97) )

9 Figure 6 Stereoview of the electron-density maps at the region of interaction between the anticodon loop of tRNA and B8. (a) A difference ‘omit’ map contoured at 1σ. The calculated amplitudes and phases are based on the model of free PheRS that was subjected to slow cool from 4000K using weak harmonic restraints on all atomic positions, as suggested by Kleywegt and Jones [39]. This map is completely unbiased by the tRNA model. (b) The final (2Fo–Fc) map calculated at 3.28 Å resolution and contoured at 0.7 σ. Stacking of Tyrβ∗731 on G34 (GUA34) is clearly seen. Atoms are shown in standard colors. (Figure 6 was drawn with the program O [34].) Structure 1997 5, 59-68DOI: ( /S (97) )

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