Specificity of antitermination mechanisms. Suppression of the terminator cluster T1-T2 of Escherichia coli ribosomal RNA operon, rrnB, by phage lambda antiterminators.

Transcription of the ribosomal RNA operons (rrn) in Escherichia coli is subject to an antitermination mechanism whereby RNA polymerase is modified to a termination-resistant form during transit through the rrn leader region. This antitermination mechanism is unable to overcome the T1-T2 terminator cluster located at the end of an rrn operon, such as rrnB. We have tested the specificity with which the T1-T2 terminators override an antitermination mechanism, by placing the terminator cluster downstream from the nut and qut sites recognized by phage lambda N and Q gene antiterminators, respectively. Measurement of downstream gene expression shows that RNA polymerase modified by either N or Q reads through the T1-T2 terminators quite efficiently. This supports the view that T1-T2 are not superterminators, and that the rrn antitermination mechanism may have a restricted terminator specificity.

Sequence-specific recognition of RNA hairpins by bacteriophage antiterminators requires a conserved arginine-rich motif.

We have dissected the protein and nucleic acid determinants that direct a group of transcriptional antiterminators to their specific target operons. These antiterminators, the N gene products of phages lambda, 21, and P22, function solely with their respective recognition sites, nut, to modify RNA polymerase to a termination-resistant form. We demonstrate that a unique hairpin sequence within each nut site, called boxB, confers genome specificity by interacting with a small amino-terminal domain of the cognate N protein. This interaction is dependent upon an arginine-rich subdomain, which is conserved not only among the N proteins but also in many RNA binding proteins from ribosomes and RNA virus capsids. Notably, this motif constitutes an essential domain of the HIV protein Tat whose function as a trans-activator requires a specific hairpin sequence.