STRUCTURES OF THERMUS THERMOPHILUS ELONGATION FACTOR TU MUTANTS LACKING CONSERVED HISTIDINE RESIDUES

Tanis Hogg1, Jeroen R. Mesters1, Annett Wagner1,2, Mathias Sprinzl2 and Rolf Hilgenfeld1

1 Institute of Molecular Biotechnology, Department of Structural Biology and Crystallography, Beutenbergstrasse 11, D-07745 Jena, Germany, e-mail: thogg@imb-jena.de
2 Laboratorium für Biochemie, Universität Bayreuth, Universitätsstrasse 30, D-95440 Bayreuth, Germany

Keywords: EF-Tu, protein biosynthesis, mutant structures

In order to accomplish its role in protein biosynthesis, prokaryotic elongation factor Tu (EF-Tu) shuttles through a complex cycle where it makes critical interactions with several different molecules. In most cases, these interactions are secured by means of specific residues which are highly conserved throughout different species. Two evolutionarily well-conserved histidine residues, His-67 and His-85, are suspected to maintain certain binding and catalytic properties of EF-Tu during this cycle. His-67 is fully conserved in prokaryotic EF-Tu and archaebacterial EF-1, with the exception of the prokaryotic chloroplast EF-Tu's (His->Thr) and the selenocysteine-specific elongation factor SelB, which carries a tyrosine residue at the equivalent position (1). In the GTP-bound state, His-67 forms part of the aa-tRNA binding site, where it is proposed to play a major role in stabilizing the ternary complex. Completely conserved in prokaryotic EF-Tu's, His-85 is situated in the "Switch II" region (residues 81-101). In the GTP-bound conformation, His-85 resides adjacent to the nucleotide binding pocket and is suggested to be involved in ribosome-stimulated GTP-hydrolysis (2). Extensive biochemical characterizations and mutational studies have been conducted in order to understand the specific activity of these residues (3-6), yet a direct mechanistic relationship between a single mutation and the observed biochemical changes cannot always be established (7). Accordingly, we have recently determined the X-ray crystal structures of two such mutants, His67Ala and His85Leu, analyzed to 2.7 A and 2.6 A resolution respectively. Solved in their GDP-bound states, these mutants reveal striking conformational peculiarities previously unobserved in other EF-Tu structures.

  1. R. Hilgenfeld, A. Böck & R. Wilting, Biochimie 78 (1996) 971-978
  2. H. Berchtold, L. Reshetnikova, C.O.A. Reiser, N.K. Schirmer, M. Sprinzl & R. Hilgenfeld, Nature 365 (1993) 126-132
  3. R.H. Cool & A. Parmeggiani, Biochemistry 30 (1993) 362-366
  4. C. Anderson & O. Wiborg, Eur. J. Biochem. 220 (1994) 739-744
  5. W. Zeidler, C. Egle, S. Ribeiro, A. Wagner, V. Katunin, R. Kreutzer, M. Rodnina, W. Wintermeyer & M. Sprinzl, Eur. J. Biochem. 229 (1995) 596-604
  6. G. Scarano, I.M. Krab, V. Bocchini & A. Parmeggiani, FEBS Lett. 365 (1995) 214-218
  7. R. Hilgenfeld, Nature Struct. Biol. 2 (1995) 3-6