Reaction mechanisms of Pol IV, RDR2 and DCL3 drive RNA channeling in the siRNA-directed DNA methylation pathway

SummaryIn eukaryotes with multiple small RNA pathways the mechanisms that channel RNAs within specific pathways are unclear. Here, we reveal the reactions that account for channeling in the siRNA biogenesis phase of the Arabidopsis RNA-directed DNA methylation pathway. The process begins with template DNA transcription by NUCLEAR RNA POLYMERASE IV (Pol IV) whose atypical termination mechanism, induced by nontemplate DNA basepairing, channels transcripts to the associated RNA-dependent RNA polymerase, RDR2. RDR2 converts Pol IV transcripts into double-stranded RNAs then typically adds an extra untemplated 3’ terminal nucleotide to the second strands. The dicer endonuclease, DCL3 cuts resulting duplexes to generate 24 and 23nt siRNAs. The 23nt RNAs bear the untemplated terminal nucleotide of the RDR2 strand and are underrepresented among ARGONAUTE4-associated siRNAs. Collectively, our results provide mechanistic insights into Pol IV termination, Pol IV-RDR2 coupling and RNA channeling from template DNA transcription to siRNA guide strand/passenger strand discrimination.

Ebolavirus polymerase uses an unconventional genome replication mechanism

Most nonsegmented negative strand (NNS) RNA virus genomes have complementary 3′ and 5′ terminal nucleotides because the promoters at the 3′ ends of the genomes and antigenomes are almost identical to each other. However, according to published sequences, both ends of ebolavirus genomes show a high degree of variability, and the 3′ and 5′ terminal nucleotides are not complementary. If correct, this would distinguish the ebolaviruses from other NNS RNA viruses. Therefore, we investigated the terminal genomic and antigenomic nucleotides of three different ebolavirus species, Ebola (EBOV), Sudan, and Reston viruses. Whereas the 5′ ends of ebolavirus RNAs are highly conserved with the sequence ACAGG-5′, the 3′ termini are variable and are typically 3′-GCCUGU, ACCUGU, or CCUGU. A small fraction of analyzed RNAs had extended 3′ ends. The majority of 3′ terminal sequences are consistent with a mechanism of nucleotide addition by hairpin formation and back-priming. Using single-round replicating EBOV minigenomes, we investigated the effect of the 3′ terminal nucleotide on viral replication and found that the EBOV polymerase initiates replication opposite the 3′-CCUGU motif regardless of the identity of the 3′ terminal nucleotide(s) and of the position of this motif relative to the 3′ end. Deletion or mutation of the first residue of the 3′-CCUGU motif completely abolished replication initiation, suggesting a crucial role of this nucleotide in directing initiation. Together, our data show that ebolaviruses have evolved a unique replication strategy among NNS RNA viruses resulting in 3′ overhangs. This could be a mechanism to avoid antiviral recognition.

Polyuridylation in Eukaryotes: A 3′-End Modification Regulating RNA Life

In eukaryotes, mRNA polyadenylation is a well-known modification that is essential for many aspects of the protein-coding RNAs life cycle. However, modification of the 3′ terminal nucleotide within various RNA molecules is a general and conserved process that broadly modulates RNA function in all kingdoms of life. Numerous types of modifications have been characterized, which are generally specific for a given type of RNA such as the CCA addition found in tRNAs. In recent years, the addition of nontemplated uridine nucleotides or uridylation has been shown to occur in various types of RNA molecules and in various cellular compartments with significantly different outcomes. Indeed, uridylation is able to alter RNA half-life both in positive and in negative ways, highlighting the importance of the enzymes in charge of performing this modification. The present review aims at summarizing the current knowledge on the various processes leading to RNA 3′-end uridylation and on their potential impacts in various diseases.

Structure of a backtracked state reveals conformational changes similar to the state following nucleotide incorporation in human norovirus polymerase

The RNA-dependent RNA polymerase (RdRP) from norovirus (NV) genogroup II has previously been crystallized as an apoenzyme (APO1) in multiple crystal forms, as well as as a pre-incorporation ternary complex (PRE1) bound to Mn2+, various nucleoside triphosphates and an RNA primer-template duplex in an orthorhombic crystal form. When crystallized under near-identical conditions with a slightly different RNA primer/template duplex, however, the enzyme–RNA complex forms tetragonal crystals (anisotropic data,dmin≃ 1.9 Å) containing a complex with the primer/template bound in a backtracked state (BACK1) similar to a post-incorporation complex (POST1) in a step of the enzymatic cycle immediately following nucleotidyl transfer. The BACK1 conformation shows that the terminal nucleotide of the primer binds in a manner similar to the nucleoside triphosphate seen in the PRE1 complex, even though the terminal two phosphoryl groups in the triphosphate moiety are absent and a covalent bond is present between the α-phosphoryl group of the terminal nucleotide and the 3′-oxygen of the penultimate nucleotide residue. The two manganese ions bound at the active site coordinate to conserved Asp residues and the bridging phosphoryl group of the terminal nucleotide. Surprisingly, the conformation of the thumb domain in BACK1 resembles the open APO1 state more than the closed conformation seen in PRE1. The BACK1 complex thus reveals a hybrid state in which the active site is closed while the thumb domain is open. Comparison of the APO1, PRE1 and BACK1 structures of NV polymerase helps to reveal a more complete and complex pathway of conformational changes within a single RdRP enzyme system. These conformational changes lend insight into the mechanism of RNA translocation following nucleotidyl transfer and suggest novel approaches for the development of antiviral inhibitors.