Structural basis for the interaction of Escherichia coli NusA with protein N of phage lambda.

The C terminus of transcription factor NusA from Escherichia coli comprises two repeat units, which bind during antitermination to protein N from phage lambda. To delineate the structural basis of the NusA-lambdaN interaction, we attempted to crystallize the NusA C-terminal repeats in complex with a lambdaN peptide (residues 34-47). The two NusA domains became proteolytically separated during crystallization, and crystals contained two copies of the first repeat unit in contact with a single lambdaN fragment. The NusA modules employ identical regions to contact the peptide but approach the ligand from opposite sides. In contrast to the alpha-helical conformation of the lambdaN N terminus in complex with boxB RNA, residues 34-40 of lambdaN remain extended upon interaction with NusA. Mutational analyses indicated that only one of the observed NusA-lambdaN interaction modes is biologically significant, supporting an equimolar ratio of NusA and lambdaN in antitermination complexes. Solution studies indicated that additional interactions are fostered by the second NusA repeat unit, consistent with known compensatory mutations in NusA and lambdaN. Contrary to the RNA polymerase alpha subunit, lambdaN binding does not stimulate RNA interaction of NusA. The results demonstrate that lambdaN serves as a scaffold to closely oppose NusA and the mRNA in antitermination complexes.

RNA DNA discrimination by the antitermination protein NusB.

The regulation of ribosomal RNA biosynthesis in Escherichia coli by antitermination requires binding of NusB protein to a dodecamer sequence designated boxA on the nascent RNA. The affinity of NusB protein for boxA RNA exceeds that for the homologous DNA segment by more than three orders of magnitude as shown by surface plasmon resonance measurements. DNA RNA discrimination by NusB protein was shown to involve methyl groups (i.e. discrimination of uracil versus thymine) and 2' hydroxyl groups (i.e. discrimination of ribose versus deoxyribose side-chains) in the RNA motif. Ligand perturbation experiments monitored by 1H15N correlation NMR experiments identified amide NH groups whose chemical shifts are affected selectively by ribose/deoxyribose exchange in the 5' and the central part of the dodecameric boxA motif respectively. The impact of structural modification of the boxA motif on the affinity for NusB protein as observed by 1H15N heterocorrelation was analysed by a generic algorithm.

Transcriptional regulation by antitermination. Interaction of RNA with NusB protein and NusB/NusE protein complex of Escherichia coli.

A recombinant heterodimeric NusB/NusE protein complex of Escherichia coli was expressed under the control of a synthetic mini operon. Surface plasmon resonance measurements showed that the heterodimer complex has substantially higher affinity for the boxA RNA sequence motif of the ribosomal RNA (rrn) operons of E.coli as compared to monomeric NusB protein. Single base exchanges in boxA RNA reduced the affinity of the protein complex up to 15-fold. The impact of base exchanges in the boxA RNA on the interaction with NusB protein was studied by (1)H,(15)N heterocorrelation NMR spectroscopy. Spectra obtained with modified RNA sequences were analysed by a novel generic algorithm. Replacement of bases in the terminal segments of the boxA RNA motif caused minor chemical shift changes as compared to base exchanges in the central part of the dodecameric boxA motif.