Argonaute proteins are programmable nucleases that have defense and regulatory functions in both eukaryotes and prokaryotes. All known prokaryotic Argonautes (pAgos) characterized so far act on DNA targets. Here, we describe a new class of pAgos that uniquely use DNA guides to process RNA targets. The biochemical and structural analysis of Pseudooceanicola lipolyticus pAgo (PliAgo) reveals an unusual organization of the guide binding pocket that does not rely on divalent cations and the canonical set of contacts for 5’-end interactions. Unconventional interactions of PliAgo with the 5’-phosphate of guide DNA define its new position within pAgo and shift the site of target RNA cleavage in comparison with known Argonautes. The specificity for RNA over DNA is defined by ribonucleotide residues at the cleavage site. The analysed pAgos sense mismatches and modifications in the RNA target. The results broaden our understanding of prokaryotic defense systems and extend the spectrum of programmable nucleases with potential use in RNA technology.
Transcriptional pausing has emerged as an essential mechanism of genetic regulation in both bacteria and eukaryotes, where it serves to coordinate transcription with other cellular processes and to activate or halt gene expression rapidly in response to external stimuli. Deinococcus radiodurans, a highly radioresistant and stressresistant bacterium, encodes three members of the Gre family of transcription factors: GreA and two Gre factor homologs, Gfh1 and Gfh2. Whereas GreA is a universal bacterial factor that stimulates RNA cleavage by RNA polymerase (RNAP), the functions of lineage-specific Gfh proteins remain unknown. Here, we demonstrate that these proteins, which bind within the RNAP secondary channel, strongly enhance site-specific transcriptional pausing and intrinsic termination. Uniquely, the pause-stimulatory activity of Gfh proteins depends on the nature of divalent ions (Mg 2+ or Mn 2+ ) present in the reaction and is also modulated by the nascent RNA structure and the trigger loop in the RNAP active site. Our data reveal remarkable plasticity of the RNAP active site in response to various regulatory stimuli and highlight functional diversity of transcription factors that bind inside the secondary channel of RNAP.RNA polymerase | transcriptional pausing | Gfh factors | Deinococcus radiodurans | stress response C ellular RNA polymerases (RNAPs) are complex molecular machines whose activity during transcription is regulated by DNA-and RNA-encoded signals, protein factors, small molecules, and inhibitors. The catalytic cycle of RNAP can be interrupted by pauses of various natures that play important roles in genetic regulation in all organisms, from the classic systems of transcription attenuation and their variations in bacteria (1) to recently discovered widespread promoter-proximal pausing in eukaryotes (2). The pausing serves to activate or repress transcription rapidly at specific genomic sites in response to regulatory stimuli and to coordinate RNA synthesis with other genetic processes (e.g., DNA replication and repair, RNA translation in bacteria) (1,(3)(4)(5)(6)(7)(8).Recent structural and biochemical studies revealed distinct RNAP conformations corresponding to different functional states of the transcription elongation complex (TEC) during nucleotide addition, RNA proofreading, and pausing (9-11). The control of structural transitions between these states likely underlies the function of multiple regulatory factors acting on RNAP. However, the roles of individual RNAP conformations in transcription and the mechanisms of their switching by transcription factors remain only partially understood. During transcription, RNAP holds the DNA template and the RNA transcript within its main channel, whose opening is controlled by the mobile clamp/shelf module and the flap domain of RNAP (9-11). Nucleotide addition and TEC translocation depend on alternating cycles of the folding of the trigger loop (TL) and kinking of the bridge helix (BH) in the RNAP active site (9-11) (Fig. 1A). Analysis of the stru...
The bacterium Deinococcus radiodurans reveals extraordinary resistance to ionizing radiation, oxidative stress, desiccation, and other damaging conditions. In this review, we consider the main molecular mechanisms underlying such resistance, including the action of specific DNA repair and antioxidation systems, and transcription regulation during the anti-stress response.
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