An allosteric mechanism of Rho-dependent transcription termination

Abstract

Rho is a general transcription termination factor in bacteria, but the mechanism by which it disrupts the RNA polymerase (RNAP) elongation complex is unknown. Here, Rho is shown to bind tightly to RNAP throughout the transcription cycle, and RNAP is proposed to have an active function in Rho termination through an allosteric mechanism. The overall structure of elongation complexes has been preserved during evolution, from bacteria to humans, suggesting that this allosteric control mechanism may a characteristic of transcription systems in general. Rho is a general transcription termination factor in bacteria, but the mechanism by which it disrupts the RNA polymerase (RNAP) elongation complex is unknown. Here, Rho is shown to bind tightly to the RNAP throughout the transcription cycle, with the formation of the RNAP–Rho complex being crucial for termination. Furthermore, RNAP is proposed to have an active role in Rho termination through an allosteric mechanism. Rho is the essential RNA helicase that sets the borders between transcription units and adjusts transcriptional yield to translational needs in bacteria1,2,3. Although Rho was the first termination factor to be discovered4, the actual mechanism by which it reaches and disrupts the elongation complex (EC) is unknown. Here we show that the termination-committed Rho molecule associates with RNA polymerase (RNAP) throughout the transcription cycle; that is, it does not require the nascent transcript for initial binding. Moreover, the formation of the RNAP–Rho complex is crucial for termination. We show further that Rho-dependent termination is a two-step process that involves rapid EC inactivation (trap) and a relatively slow dissociation. Inactivation is the critical rate-limiting step that establishes the position of the termination site. The trap mechanism depends on the allosterically induced rearrangement of the RNAP catalytic centre by means of the evolutionarily conserved mobile trigger-loop domain, which is also required for EC dissociation. The key structural and functional similarities, which we found between Rho-dependent and intrinsic (Rho-independent) termination pathways, argue that the allosteric mechanism of termination is general and likely to be preserved for all cellular RNAPs throughout evolution.