Four plant Dicers mediate viral small RNA biogenesis and DNA virus induced silencing

Like other eukaryotes, plants use DICER-LIKE (DCL) proteins as the central enzymes of RNA silencing, which regulates gene expression and mediates defense against viruses. But why do plants like Arabidopsis express four DCLs, a diversity unmatched by other kingdoms? Here we show that two nuclear DNA viruses (geminivirus CaLCuV and pararetrovirus CaMV) and a cytoplasmic RNA tobamovirus ORMV are differentially targeted by subsets of DCLs. DNA virus-derived small interfering RNAs (siRNAs) of specific size classes (21, 22 and 24 nt) are produced by all four DCLs, including DCL1, known to process microRNA precursors. Specifically, DCL1 generates 21 nt siRNAs from the CaMV leader region. In contrast, RNA virus infection is mainly affected by DCL4. While the four DCLs are partially redundant for CaLCuV-induced mRNA degradation, DCL4 in conjunction with RDR6 and HEN1 specifically facilitates extensive virus-induced silencing in new growth. Additionally, we show that CaMV infection impairs processing of endogenous RDR6-derived double-stranded RNA, while ORMV prevents HEN1-mediated methylation of small RNA duplexes, suggesting two novel viral strategies of silencing suppression. Our work highlights the complexity of virus interaction with host silencing pathways and suggests that DCL multiplicity helps mediate plant responses to diverse viral infections

Involvement of RDR6 in short-range intercellular RNA silencing in Nicotiana benthamiana

In plants, non-cell autonomous RNA silencing spreads between cells and over long distances. Recent work has revealed insight on the genetic and molecular components essential for cell-to-cell movement of RNA silencing in Arabidopsis. Using a local RNA silencing assay, we report on a distinct mechanism that may govern the short-range (6–10 cell) trafficking of virus-induced RNA silencing from epidermal to neighbouring palisade and spongy parenchyma cells in Nicotiana benthamiana. This process involves a previously unrecognised function of the RNA-dependent RNA polymerase 6 (RDR6) gene. Our data suggest that plants may have evolved distinct genetic controls in intercellular RNA silencing among different types of cells

Antiviral Silencing and Suppression of Gene Silencing in Plants

RNA silencing is an evolutionary conserved sequence-specific gene inactivation mechanism that contributes to the control of development, maintains heterochromatin, acts in stress responses, DNA repair and defends against invading nucleic acids like transposons and viruses. In plants RNA silencing functions as one of the main immune systems. RNA silencing process involves the small RNAs and trans factor components like Dicers, Argonautes and RNA-dependent RNA poly- merases. To deal with host antiviral silencing responses viruses evolved mecha- nisms to avoid or counteract this, most notably through expression of viral suppressors of RNA silencing. Due to the overlap between endogenous and antiviral silencing pathways while blocking antiviral pathways viruses also impact endogenous silencing processes. Here we provide an overview of antiviral silencing pathway, host factors implicated in it and the crosstalk between antiviral and endogenous branches of silencing. We summarize the current status of knowledge about the viral counter-defense strategies acting at various steps during virus infection in plants with the focus on representative, well studied silencing suppres- sor proteins. Finally we discuss future challenges of the antiviral silencing and counter-defense research field

EFFECTS OF TYROSINE AND PLANT GROWTH REGULATORS ON GROWTH AND DEVELOPMENT OF GLORIOSA SUPERBA LINN., A MEDICINAL PLANT, IN VITRO

The study of effects of tyrosine and plant growth regulators on rhizome cultures was carried out on modified Murashige Skoog medium. The sterile rhizomes were cut and cultured on MS medium, supplemented with 1 mg/l 2,4-D, 1 mg/l BA and various concentrations of tyrosine under light and dark condition. The experimental data showed that the highest percentage of callus formation was on the medium with 50 mg/l tyrosine, in the dark condition (100%) and in the light condition (85%). The average fresh weight of callus cultured in the dark for 16 weeks was 6.25 g. Shoot induction was performed using the combination of NAA and BA for 36 weeks. The experimental data revealed that the shoot regeneration from callus was 100% on the medium with 4 mg/l BA and 4 mg/l NAA. Comparison among various concentrations of BA and NAA showed that shoot formation was 83% and 50% on the medium containing 4 mg/l BA and 4 mg/l kinetin, respectively. The chromosome number from the root tip obtained from the tissue culture was 2n = 22. Acknowledgements: Dept. of Biology, Khon Kaen University provided funding and all participants in this project

Virus-induced gene silencing as a reverse genetics tool to study gene function

Reverse genetics has proven to be a powerful approach to elucidating gene function in plants, particularly in Arabidopsis. Virus-induced gene silencing (VIGS) is one such method and achieves reductions in target gene expression as the vector moves into newly formed tissues of inoculated plants. VIGS is especially useful for plants that are recalcitrant for transformation and for genes that cause embryo lethality. VIGS provides rapid, transient knockdowns as a complement to other reverse genetics tools and can be used to screen sequences for RNAi prior to stable transformation. High-throughput, forward genetic screening is also possible by cloning libraries of short gene fragments directly into a VIGS plasmid DNA vector, inoculating, and then looking for a phenotype of interest. VIGS is especially useful for studying genes in crop species, which currently have few genetic resources. VIGS facilitates a rapid comparison of knockdown phenotypes of the same gene in different breeding lines or mutant backgrounds, as the same vector is easily inoculated into different plants. In this chapter, we briefly discuss how to choose or construct a VIGS vector and then how to design and carry out effective experiments using VIGS

DICER-LIKE 4 functions in trans-acting small interfering RNA biogenesis and vegetative phase change in Arabidopsis thaliana

Arabidopsis thaliana contains four DICER-LIKE (DCL) genes with specialized functions in small RNA biogenesis for RNA interference-related processes. A mutant with defects in DCL4 was identified and analyzed for microRNA- and endogenous, small interfering RNA (siRNA)-related functions. The dcl4-2 mutant contained normal or near-normal levels of microRNAs (21 nt) and heterochromatin-associated siRNAs (24 nt). In contrast, this mutant lacked each of three families of 21-nt trans-acting siRNAs (ta-siRNAs) and possessed elevated levels of ta-siRNA target transcripts. The dcl4-2 mutant resembled an rna-dependent RNA polymerase 6 mutant in that both mutants lacked ta-siRNAs and displayed heterochronic defects in which vegetative phase change was accelerated. Double mutant analyses with dcl2-1, dcl3-1, and dcl4-2 alleles revealed hierarchical redundancy among DCL activities, leading to alternative processing of ta-siRNA precursors in the absence of DCL4. These data support the concept that plants have specialized and compartmentalized DCL functions for biogenesis of distinct small RNA classes