The Crystal Structure Of The Ternary Complex Of Phenylalanyl-Trna Synthetase With Trna(Phe) And A Phenylalanyl-Adenylate Analogue Reveals A Conformational Switch Of The Cca End

The crystal structure of the ternary complex of (alpha beta)(2) heterotetrameric phenylalanyl-tRNA synthetase (PheRS) from Thermus thermophilus with cognate tRNA(Phe) and a nonhydrolyzable phenylalanyl-adenylate analogue (PheOH-AMP) has been determined at 3.1 angstrom resolution. It reveals conformational changes in tRNAPhe induced by the PheOH-AMP binding. The single-stranded 3' end exhibits a hairpin conformation in contrast to the partial unwinding observed previously in the binary PheRS, tRNAPhe complex. The CCA end orientation is stabilized by extensive base-specific interactions of A76 and C75 with the protein and by intra-RNA interactions of A73 with adjacent nucleotides. The 4-amino group of the "bulged out" C75 is trapped by two negatively charged residues of the beta subunit (Glu beta 31 and Asp beta 33), highly conserved in eubacterial PheRSs. The position of the A76 base is stabilized by interactions with His alpha 212 of motif 2 (universally conserved in PheRSs) and class II-invariant Arg alpha 321 of motif 3. Important conformational changes induced by the binding of tRNA(Phe) and PheOH-AMP are observed in the catalytic domain: the motif 2 loop and a "helical" loop (residues 139-152 of the alpha subunit) undergo coordinated displacement; Met alpha 148 of the helical loop adopts a conformation preventing the 2'-OH group of A76 from approaching the alpha-carbonyl carbon of PheOH-AMP. The unfavorable position of the terminal ribose stems from the absence of the alpha-carbonyl oxygen in the analogue. Our data suggest that the idiosyncratic feature of PheRS, which aminoacylates the 2'-OH group of the terminal ribose, is dictated by the system-specific topology of the CCA end-binding site.