RNA-guided RNA silencing by an Asgard archaeal Argonaute

Structural basis of ssDNA-guided NADase activation of prokaryotic SPARTA system

Short prokaryotic Argonaute and the associated TIR-APAZ (SPARTA) proteins constitute a prokaryotic immune system, mediating RNA- or DNA-guided target single-stranded DNA (ssDNA) to activate NADase activity and induce cell death by degrading NAD+ in response to invading plasmids. Although the guide RNA-mediated targeting mechanism of SPARTA has been established, the functional role and mechanisms of guide DNA-mediated SPARTA remain poorly understood. Here, we report two crystal structures of Crenotalea thermophila SPARTA complexes with 5'-phosphorylated 21-nt guide DNA and complementary target ssDNA lengths of 15 or 20 nt. The structures demonstrate specific recognition of the 5'-OH or 3'-OH groups in target DNA by SPARTA, while not recognizing the 5'-P group in guide DNA. This suggests distinct recognition models for guide DNA and guide RNA, indicating different activation mechanisms. Furthermore, these two structures reveal disparate models for recognizing guide DNA and target DNA, providing insights into the length requirement for SPARTA activation.

miRNA-target complementarity in cnidarians resembles its counterpart in plants

microRNAs (miRNAs) are important post-transcriptional regulators that activate silencing mechanisms by annealing to mRNA transcripts. While plant miRNAs match their targets with nearly-full complementarity leading to mRNA cleavage, miRNAs in most animals require only a short sequence called 'seed' to inhibit target translation. Recent findings showed that miRNAs in cnidarians, early-branching metazoans, act similarly to plant miRNAs, by exhibiting full complementarity and target cleavage; however, it remained unknown if seed-based regulation was possible in cnidarians. Here, we investigate the miRNA-target complementarity requirements for miRNA activity in the cnidarian Nematostella vectensis. We show that bilaterian-like complementarity of seed-only or seed and supplementary 3' matches are insufficient for miRNA-mediated knockdown. Furthermore, miRNA-target mismatches in the cleavage site decrease knockdown efficiency. Finally, miRNA silencing of a target with three seed binding sites in the 3' untranslated region that mimics typical miRNA targeting was repressed in zebrafish but not in Nematostella and another cnidarian, Hydractinia symbiolongicarpus. Altogether, these results unravel striking similarities between plant and cnidarian miRNAs supporting a possible common evolutionary origin of miRNAs in plants and animals.

Structural and mechanistic insights into the activation of a short prokaryotic argonaute system from archaeon Sulfolobus islandicus

Prokaryotic Argonaute proteins (pAgos) defend the host against invading nucleic acids, including plasmids and viruses. Short pAgo systems confer immunity by inducing cell death upon detecting invading nucleic acids. However, the activation mechanism of the SiAgo system, comprising a short pAgo from the archaeon Sulfolobus islandicus and its associated proteins SiAga1 and SiAga2, remains largely unknown. Here, we determined the cryo-electron microscopy structures of the SiAgo-Aga1 apo complex and the RNA-DNA-bound SiAgo-Aga1 complex at resolutions of 2.7 and 3.0 Å, respectively. Our results revealed that a positively charged pocket is generated from the interaction between SiAgo and SiAga1, exhibiting an architecture similar to APAZ-pAgo of short pAgo systems and accommodating the nucleic acids. Further investigation elucidated the conserved mechanism of nucleic acid recognition by SiAgo-Aga1. Both the SiAgo-Aga1 interaction and nucleic acid recognition by the complex are essential for antiviral defense. Biochemical and structural analyses demonstrated that SiAgo-Aga1 undergoes extensive conformational changes upon binding to the RNA-DNA duplex, thereby licensing its interaction with the effector SiAga2 to trigger the immune response. Overall, our findings highlight the evolutionary conservation of Agos across phylogenetic clades and provide structural insights into the activation mechanism of the SiAgo system.

The role of prokaryotic argonautes in resistance to type II topoisomerases poison ciprofloxacin

Argonaute proteins are programmable nucleases found in all domains of life. Eukaryotic argonautes (eAgos) participate in genetic regulation, antiviral response, and transposon silencing during RNA interference. Prokaryotic argonautes (pAgos) are much more diverse than eAgos and have been implicated in defense against invading genetic elements. Recently, it was shown that pAgos protect bacterial cells from a topoisomerase poison ciprofloxacin, raising a possibility that they may play a role in DNA replication and/or repair. Here, we discuss possible models of pAgo-mediated ciprofloxacin resistance. We propose that pAgos could (i) participate in chromosome decatenation as a backup to topoisomerases; (ii) participate in the processing of DNA repair intermediates formed after topoisomerase poisoning, or (iii) induce SOS response that generally affects DNA repair and antibiotic resistance. These hypotheses should guide future investigations of the involvement of pAgos in the emergence of resistance to ciprofloxacin and, possibly, other antibiotics.

Asgard archaea defense systems and their roles in the origin of eukaryotic immunity

Dozens of new antiviral systems have been recently characterized in bacteria. Some of these systems are present in eukaryotes and appear to have originated in prokaryotes, but little is known about these defense mechanisms in archaea. Here, we explore the diversity and distribution of defense systems in archaea and identify 2610 complete systems in Asgardarchaeota, a group of archaea related to eukaryotes. The Asgard defense systems comprise 89 unique systems, including argonaute, NLR, Mokosh, viperin, Lassamu, and CBASS. Asgard viperin and argonaute proteins have structural homology to eukaryotic proteins, and phylogenetic analyses suggest that eukaryotic viperin proteins were derived from Asgard viperins. We show that Asgard viperins display anti-phage activity when heterologously expressed in bacteria. Eukaryotic and bacterial argonaute proteins appear to have originated in Asgardarchaeota, and Asgard argonaute proteins have argonaute-PIWI domains, key components of eukaryotic RNA interference systems. Our results support that Asgardarchaeota played important roles in the origin of antiviral defense systems in eukaryotes.