c While RNA silencing is a potent antiviral defense in plants, well-adapted plant viruses are known to encode suppressors of RNA silencing (VSR) that can neutralize the effectiveness of RNA silencing. As a result, most plant genes involved in antiviral silencing were identified by using debilitated viruses lacking silencing suppression capabilities. Therefore, it remains to be resolved whether RNA silencing plays a significant part in defending plants against wild-type viruses. We report here that, at a higher plant growth temperature (26°C) that permits rigorous replication of Turnip crinkle virus (TCV) in Arabidopsis, plants containing loss-of-function mutations within the Dicer-like 2 (DCL2), Argonaute 2 (AGO2), and HEN1 RNA methyltransferase genes died of TCV infection, whereas the wild-type Col-0 plants survived to produce viable seeds. To account for the critical role of DCL2 in ensuring the survival of wild-type plants, we established that higher temperature upregulates the activity of DCL2 to produce viral 22-nucleotide (nt) small interfering RNAs (vsRNAs). We further demonstrated that DCL2-produced 22-nt vsRNAs were fully capable of silencing target genes, but that this activity was suppressed by the TCV VSR. Finally, we provide additional evidence supporting the notion that TCV VSR suppresses RNA silencing through directly interacting with AGO2. Together, these results have revealed a specialized RNA silencing pathway involving DCL2, AGO2, and HEN1 that provides the host plants with a competitive edge against adapted viruses under environmental conditions that facilitates robust virus reproduction.
Highlights d RNA polymerase IV, RDR2, and DCL3 are sufficient for siRNA synthesis in vitro d Nontemplate-strand-induced Pol IV termination triggers RDR2 synthesis of dsRNA d RDR2 adds an untemplated terminal nucleotide to its transcripts' 3 0 ends d DCL3 generates 24-and 23-nt siRNAs; 23-nt siRNAs often have untemplated termini
In 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. KeywordsNuclear RNA Polymerase IV, noncoding RNA, RNA silencing, RNA-directed DNA methylation, transcription termination, dicing, ncRNA processing mismatched nucleotides and the short size of Pol IV transcripts (Zhai et al., 2015). However, RDR2 has terminal transferase activity that can add untemplated nucleotides to RNA 3' ends, suggesting an alternative hypothesis for the mismatched nucleotides (Blevins et al., 2015).Whether RDR2's terminal transferase activity might act on Pol IV transcripts, RDR2 transcripts, or both is unknown.Pol IV transcribes single-stranded (ss) DNA but lacks significant activity using sheared double-stranded (ds) DNA in vitro Onodera et al., 2005). Our current study provides an explanation, showing that when Pol IV is engaged in transcription of a ssDNA strand it terminates within 12-18 nt after encountering dsDNA. Importantly, Pol IV termination induced in this manner is key to channeling the transcript to RDR2, which converts the Pol IV transcript into dsRNA. We show that single-stranded M13 bacteriophage DNA can template siRNA biogenesis in vitro, with Pol IV synthesizing first strand transcripts, RDR2 synthesizing the second strands and DCL3 dicing the duplexes into both 24 bp and 23bp siRNAs, as in vivo.DNA-mismatched nucleotides are present at precursor and siRNA 3' ends, as in vivo, with sequencing showing these to be hallmarks of RDR2 transcripts, not Pol IV transcripts.Collectively, the reactions of Pol IV, RDR2 and DCL3 are necessary and sufficient for siRNA biogenesis and can account for the short length of P4R2 RNAs, the origin of untemplated 3' nucleotides, the mechanism of Pol IV-RDR2 coupling and the channeling of RNAs from DNA template transcription to siRNA strand discrimination.
Summary Plant multisubunit RNA Polymerase V transcription recruits Argonaute-siRNA complexes that specify sites of RNA-directed DNA methylation (RdDM) for gene silencing. Pol V’s largest subunit, NRPE1, evolved from the largest subunit of Pol II but has a distinctive carboxyl-terminal domain (CTD). We show that the Pol V CTD is dispensable for catalytic activity in vitro, yet essential in vivo. One CTD subdomain (DeCL) is required for Pol V function at virtually all loci. Other CTD subdomains have locus-specific effects. In a yeast two-hybrid screen, the 3′–>5′ exoribonuclease, RRP6L1 was identified as an interactor with the DeCL and glutamine-serine-rich (QS) subdomains located downstream from an Argonaute-binding subdomain. Experimental evidence indicates that RRP6L1 trims the 3′ ends of Pol V transcripts sliced by ARGONAUTE 4 (AGO4), suggesting a model whereby the CTD enables the spatial and temporal coordination of AGO4 and RRP6L1 RNA processing activities.
In plants, selfish genetic elements including retrotransposons and DNA viruses are transcriptionally silenced by RNA-directed DNA methylation. Guiding the process are short interfering RNAs (siRNAs) cut by DICER-LIKE 3 (DCL3) from double-stranded precursors of ~30 bp that are synthesized by NUCLEAR RNA POLYMERASE IV (Pol IV) and RNA-DEPENDENT RNA POLYMERASE 2 (RDR2). We show that Pol IV's choice of initiating nucleotide, RDR2's initiation 1-2 nt internal to Pol IV transcript ends and RDR2's terminal transferase activity collectively yield a code that influences which precursor end is diced and whether 24 or 23 nt siRNAs are produced. By diversifying the size, sequence, and strand specificity of siRNAs derived from a given precursor, alternative patterns of DCL3 dicing allow for maximal siRNA coverage at methylated target loci.
RNA-guided surveillance systems constrain the activity of transposable elements (TEs) in host genomes. In plants, RNA polymerase IV (Pol IV) transcribes TEs into primary transcripts from which RDR2 synthesizes double-stranded RNA precursors for small interfering RNAs (siRNAs) that guide TE methylation and silencing. How the core subunits of Pol IV, homologs of RNA polymerase II subunits, diverged to support siRNA biogenesis in a TE-rich, repressive chromatin context is not well understood. Here we studied the N-terminus of Pol IV’s largest subunit, NRPD1. Arabidopsis lines harboring missense mutations in this N-terminus produce wild-type (WT) levels of NRPD1, which co-purifies with other Pol IV subunits and RDR2. Our in vitro transcription and genomic analyses reveal that the NRPD1 N-terminus is critical for robust Pol IV-dependent transcription, siRNA production and DNA methylation. However, residual RNA-directed DNA methylation observed in one mutant genotype indicates that Pol IV can operate uncoupled from the high siRNA levels typically observed in WT plants. This mutation disrupts a motif uniquely conserved in Pol IV, crippling the enzyme's ability to inhibit retrotransposon mobilization. We propose that the NRPD1 N-terminus motif evolved to regulate Pol IV function in genome surveillance.
Liposomes are widely used as synthetic analogues of cell membranes and for drug delivery. Lipid-binding DNA nanostructures can modify the shape, porosity and reactivity of liposomes, mediated by cholesterol modifications. DNA nanostructures can also be designed to switch conformations by DNA strand displacement. However, the optimal conditions to facilitate stable, high-yield DNA–lipid binding while allowing controlled switching by strand displacement are not known. Here, we characterized the effect of cholesterol arrangement, DNA structure, buffer and lipid composition on DNA–lipid binding and strand displacement. We observed that binding was inhibited below pH 4, and above 200 mM NaCl or 40 mM MgCl2, was independent of lipid type, and increased with membrane cholesterol content. For simple motifs, binding yield was slightly higher for double-stranded DNA than single-stranded DNA. For larger DNA origami tiles, four to eight cholesterol modifications were optimal, while edge positions and longer spacers increased yield of lipid binding. Strand displacement achieved controlled removal of DNA tiles from membranes, but was inhibited by overhang domains, which are used to prevent cholesterol aggregation. These findings provide design guidelines for integrating strand displacement switching with lipid-binding DNA nanostructures. This paves the way for achieving dynamic control of membrane morphology, enabling broader applications in nanomedicine and biophysics.
Recombinant DNA technology was successfully used to engineer an scFv-based immunoadsorbent. Use of immobilized scFvs during hemodialysis may minimize loss of valuable proteins and facilitate the removal of macromolecules that are significantly larger than the molecular weight cut-off of the membrane.
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