Transcription elongation factor NusA is a general antagonist of Rho-dependent termination in Escherichia coli

NusA is an essential protein that binds to RNA polymerase and also to the nascent RNA and influences transcription by inducing pausing and facilitating the process of transcription termination/antitermination. Its participation in Rho-dependent transcription termination has been perceived, but the molecular nature of this involvement is not known. We hypothesized that, because both Rho and NusA are RNA-binding proteins and have the potential to target the same RNA, the latter is likely to influence the global pattern of the Rho-dependent termination. Analyses of the nascent RNA binding properties and consequent effects on the Rho-dependent termination functions of specific NusA-RNA binding domain mutants revealed an existence of Rho-NusA direct competition for the overlapping nut (NusA-binding site) and rut (Rho-binding site) sites on the RNA. This leads to delayed entry of Rho at the rut site that inhibits the latter's RNA release process. High density tiling microarray profiles of these NusA mutants revealed that a significant number of genes, together with transcripts from intergenic regions, are up-regulated. Interestingly, the majority of these genes were also up-regulated when the Rho function was compromised. These results provide strong evidence for the existence of NusA-binding sites in different operons that are also the targets of Rho-dependent terminations. Our data strongly argue in favor of a direct competition between NusA and Rho for the access of specific sites on the nascent transcripts in different parts of the genome. We propose that this competition enables NusA to function as a global antagonist of the Rho function, which is unlike its role as a facilitator of hairpin-dependent termination

Redundancy of primary RNA-binding functions of the bacterial transcription terminator Rho

The bacterial transcription terminator, Rho, terminates transcription at half of the operons. According to the classical model derived from in vitro assays on a few terminators, Rho is recruited to the transcription Elongation Complex (EC) by recognizing specific sites (rut) on the nascent RNA. Here, we explored the mode of in vivo recruitment process of Rho. We show that sequence specific recognition of the rut site, in majority of the Rho-dependent terminators, can be compromised to a great extent without seriously affecting the genome-wide termination function as well as the viability of Escherichia coli. These terminators function optimally only through a NusG-assisted recruitment and activation of Rho. Our data also indicate that at these terminators, Rho-EC-bound NusG interaction facilitates the isomerization of Rho into a translocase-competent form by stabilizing the interactions of mRNA with the secondary RNA binding site, thereby overcoming the defects of the primary RNA binding functions

Interaction with the nascent RNA is a prerequisite for the recruitment of Rho to the transcription elongation complex in vitro

In the conventional model of the Rho-dependent transcription termination, the terminator Rho binds to the rut (Rho utilization) site and translocates along the nascent RNA prior to making possible interactions with the elongating RNA Polymerase (RNAP). Even though the interaction between Rho and isolated RNAs was studied in great detail, the same has never been shown with the nascent RNA emerging from the transcription Elongation Complex (EC). Direct demonstration and requirement of the Rho–nascent RNA binding become even more important because of the recently proposed alternative model where Rho loads onto the RNAP prior to the formation of the nascent RNA. Here, we have measured the direct association of Rho in vitro with the free RNAP, RNAP–promoter binary complex and stalled ECs with varied length of RNA. We observed the association of Rho only with the ECs having the rut-site-containing long nascent RNA. This association was significantly reduced when either a Rho mutant, Y80C, defective for RNA binding or an antisense oligo to the rut site was used or when the rut site was eliminated by RNase digestion or replacement with a random RNA sequence. The presence of EC-bound NusG, the binding partner of Rho, did not facilitate this association. RNase footprinting of the Rho–EC complex revealed a clear Rho-mediated protection of the rut sites on the nascent RNA. We concluded that the nascent RNA loading of Rho and its interaction with the rut site are mandatory and prerequisites for its recruitment to the EC under in vitro experimental conditions