Allosteric mechanism of transcription inhibition by NusG-dependent pausing of RNA polymerase

Abstract

AbstractNusG is a transcription elongation factor that stimulates transcription pausing in Gram+ bacteria includingBacillus subtilisby sequence-specific interaction with a conserved pause-inducing-11TTNTTT-6motif found in the non-template DNA (ntDNA) strand within the transcription bubble. To reveal the structural basis of NusG-dependent pausing, we determined a cryo-EM structure of a paused transcription complex containing RNAP, NusG, and the TTNTTT motif in the ntDNA strand. Interaction of NusG with the ntDNA strand rearranges the transcription bubble by positioning three consecutive T residues in a cleft between NusG and the β-lobe domain of RNAP. We revealed that the RNAP swivel module rotation (swiveling), which widens (swiveled state) and narrows (non-swiveled state) a cleft between NusG and the β-lobe, is an intrinsic motion of RNAP and is directly linked to nucleotide binding at the active site and to trigger loop folding, an essential conformational change of all cellular RNAPs for the RNA synthesis reaction. We also determined cryo-EM structures of RNAP escaping from a paused transcription complex. These structures revealed the NusG-dependent pausing mechanism by which NusG-ntDNA interaction inhibits the transition from swiveled to non-swiveled states, thereby preventing trigger loop folding and RNA synthesis allosterically. This motion is also reduced by formation of an RNA hairpin within the RNA exit channel. Thus, the pause half-life can be modulated by the strength of the NusG-ntDNA interaction and/or the stability of the RNA hairpin. NusG residues that interact with the TTNTTT motif are widely conserved in bacteria, suggesting that NusG-dependent pausing of transcription is widespread.Significance statementTranscription pausing by RNA polymerase (RNAP) regulates gene expression where it controls co-transcriptional RNA folding, synchronizes transcription with translation, and provides time for binding of regulatory factors. Transcription elongation factor NusG stimulates pausing in Gram+ bacteria includingBacillus subtilisandMycobacterium tuberculosisby sequence-specific interaction with a conserved pause motif found in the non-template DNA (ntDNA) strand within the transcription bubble. Our structural and biochemical results revealed that part of the conserved TTNTTT motif in ntDNA is extruded and sandwiched between NusG and RNAP. Our results further demonstrate that an essential global conformational change in RNAP is directly linked to RNA synthesis, and that the NusG-ntDNA interaction pauses RNA synthesis by interfering with this conformational change.