Crystal structure of the N-terminal domain of the TyrR transcription factor responsible for gene regulation of aromatic amino acid biosynthesis and transport in Escherichia coli K12

The X-ray structure of the N-terminal domain of TyrR has been solved to a resolution of 2.3 Å. It reveals a modular protein containing an ACT domain, a connecting helix, a PAS domain and a C-terminal helix. Two dimers are present in the asymmetric unit with one monomer of each pair exhibiting a large rigid-body movement that results in a hinging around residue 74 of not, vert, similar50°. The structure of the dimer is discussed with reference to other transcription regulator proteins. Putative binding sites are identified for the aromatic amino acid cofactors

GlnK, a PII-homologue: Structure reveals ATP binding site and indicates how the T-loops may be involved in molecular recognition.

GlnK is a recently discovered homologue of the P(II) signal protein, an indicator of the nitrogen status of bacteria. P(II) occupies a central position in the dual cascade that regulates the activity of glutamine synthetase and the transcription of its gene. The complete role of Escherichia coli GlnK is yet to be determined, but already it is known that GlnK behaves like P(II) and can substitute for P(II) under some circumstances thereby adding to the subtleties of nitrogen regulation. There are also indications that the roles of the two proteins differ; the expression of P(II) is constitutive while that of GlnK is linked to the level of nitrogen in the cell. The discovery of GlnK begs the question of why E. coli has both GlnK and P(II). Clearly, the structural similarities and differences of GlnK and P(II) will lead to a better understanding of how P(II)-like proteins function in E. coli and other organisms. We have crystallised and solved the X-ray structure of GlnK at 2.0 Å resolution. The asymmetric unit has two independent copies of the GlnK subunit and both pack around 3-fold axes to form trimers. The trimers have a barrel-like core with recognition loops (the T-loops) that protrude from the top of the molecule. The two GlnK molecules have similar core structures to P(II) but differ significantly at the C terminus and the loops. The T-loops of the two GlnK molecules also differ from each other; one is disordered while the conformation of the other is stabilised by lattice contacts. The conformation of the ordered T-loop of GlnK differs from that observed in the P(II) structure despite the fact that their sequences are very similar. The structures suggest that the T-loops do not have a rigid structure and that they may be flexible in solution. The presence of a turn of