Vicki B. Vance

HC-Pro Suppression of Transgene Silencing Eliminates the Small RNAs but Not Transgene Methylation or the Mobile Signal

Post-transcriptional gene silencing (PTGS) is a sequence-specific RNA degradation mechanism that is widespread in eukaryotic organisms. It is often associated with methylation of the transcribed region of the silenced gene and with accumulation of small RNAs (21 to 25 nucleotides) homologous to the silenced gene. In plants, PTGS can be triggered locally and then spread throughout the organism via a mobile signal that can cross a graft junction. Previously, we showed that the helper component–proteinase (HC-Pro) of plant potyviruses suppresses PTGS. Here, we report that plants in which PTGS has been suppressed by HC-Pro fail to accumulate the small RNAs associated with silencing. However, the transgene locus of these plants remains methylated. Grafting experiments indicate that HC-Pro prevents the plant from responding to the mobile silencing signal but does not eliminate its ability to produce or send the signal. These results demonstrate that HC-Pro functions downstream of transgene methylation and the mobile signal at a step preceding accumulation of the small RNAs.

A viral suppressor of RNA silencing differentially regulates the accumulation of short interfering RNAs and micro-RNAs in tobacco

Two major classes of small noncoding RNAs have emerged as important regulators of gene expression in eukaryotes, the short interfering RNAs (siRNAs) associated with RNA silencing and endogenous micro-RNAs (miRNAs) implicated in regulation of gene expression. Helper component-proteinase (HC-Pro) is a viral protein that blocks RNA silencing in plants. Here we examine the effect of HC-Pro on the accumulation of siRNAs and endogenous miRNAs. siRNAs were analyzed in transgenic tobacco plants silenced in response to three different classes of transgenes: sense-transgenes, inverted-repeat transgenes, and amplicon-transgenes. HC-Pro suppressed silencing in each line, blocking accumulation of the associated siRNAs and allowing accumulation of transcripts from the previously silenced loci. HC-Pro-suppression of silencing in the inverted-repeat- and amplicon-transgenic lines was accompanied by the apparent accumulation of long double-stranded RNAs and proportional amounts of small RNAs that are larger than the siRNAs that accumulate during silencing. Analysis of these results suggests that HC-Pro interferes with silencing either by inhibiting siRNA processing from double-stranded RNA precursors or by destabilizing siRNAs. In contrast to siRNAs, the accumulation of endogenous miRNAs was greatly enhanced in all of the HC-Pro-expressing lines. Thus, our results demonstrate that accumulation of siRNAs and miRNAs in plants can be differentially regulated by a viral protein. The fact that HC-Pro affects the miRNA pathway raises the possibility that this pathway is targeted by plant viruses as a means to control gene expression in the host.

RNA Silencing and the Mobile Silencing Signal

RNA silencing is a sequence-specific RNA degradation mechanism that occurs in a broad range of eukaryotic organisms including fungi (quelling), animals (RNA interference [RNAi]), and plants (post-transcriptional gene silencing). In all these organisms, the process is triggered by double-stranded RNA

RNA-based silencing strategies in plants.

In plants, double-stranded RNA can silence genes by triggering degradation of homologous RNA in the cytoplasm and by directing methylation of homologous nuclear DNA sequences. Analyses of Arabidopsis mutants and plant viral suppressors of silencing are unraveling RNA-silencing mechanisms, which require common proteins in diverse organisms, and are assessing the role of methylation in transcriptional and posttranscriptional gene silencing.

RNA viruses as inducers, suppressors and targets of post-transcriptional gene silencing

Post-transcriptional gene silencing (PTGS) is a fundamental regulatory mechanism operating in diverse types of organisms, but the cellular components of the gene silencing machinery and the regulation of the process are not understood. Recent findings that cytoplasmically replicating RNA viruses act as both targets and inducers of PTGS has led to the idea that PTGS may have evolved as an anti-viral defense mechanism in plants. Consistent with this hypothesis, it has been found that certain plant viruses encode proteins that suppress PTGS. From a practical standpoint, an understanding of the mechanisms by which viruses regulate PTGS may well lead to better ways to control gene expression in plants. It is often desirable to overexpress selected beneficial genes or to silence detrimental ones in order to confer a particular phenotype. Induction of PTGS using RNA viruses as vectors or as transgenes provides a reliable and efficient way to interfere with the expression of a specific gene or with a family of genes. Conversely, expression of viral suppressors has significant potential to improve yields in technologies that use plants to express beneficial gene products. Given the antiviral nature of gene silencing in plants and the indications that PTGS is an ancient mechanism in eukaryotic organisms, understanding the phenomenon in plants could well lead to the development of anti-viral strategies in both plants and animals.

Small RNAs in viral infection and host defense

Small RNAs are the key mediators of RNA silencing and related pathways in plants and other eukaryotic organisms. Silencing pathways couple the destruction of double-stranded RNA with the use of the resulting small RNAs to target other nucleic acid molecules that contain the complementary sequence. This discovery has revolutionized our ideas about host defense and genetic regulatory mechanisms in eukaryotes. Small RNAs can direct the degradation of mRNAs and single-stranded viral RNAs, the modification of DNA and histones, and the inhibition of translation. Viruses might even use small RNAs to do some targeting of their own to manipulate host gene expression. This review highlights the current understanding and new insights concerning the roles of small RNAs in virus infection and host defense in plants.

The amplicon-plus system for high-level expression of transgenes in plants.

Many biotechnological applications require high-level expression of transgenes in plants. One strategy to achieve this goal was the production of potato virus X (PVX) “amplicon” lines: transgenic lines that encode a replicating RNA virus vector carrying a gene of interest. The idea was that transcription of the amplicon transgene would initiate viral RNA replication and gene expression, resulting in very high levels of the gene product of interest. This approach failed, however, because every amplicon transgene, in both tobacco and Arabidopsis thaliana, was subject to post-transcriptional gene silencing (PTGS). In PTGS, the transgene is transcribed but the transcripts fail to accumulate as a result of sequence-specific targeting and destruction. Even though the amplicon locus is silenced, the level of β-glucuronidase (GUS) activity in a PVX/GUS line is similar to that in some transgenic lines expressing GUS from a conventional (not silenced) GUS locus. This result suggested that the very high levels of expression originally envisioned for amplicons could be achieved if PTGS could be overcome and if the resulting plants did not suffer from severe viral disease. Here we report that high-level transgene expression can be achieved by pairing the amplicon approach with the use of a viral suppressor of PTGS, tobacco etch virus (TEV) helper component–proteinase (HC-Pro). Leaves of mature tobacco plants co-expressing HC-Pro and a PVX/GUS amplicon accumulate GUS to ∼3% of total protein. Moreover, high-level expression occurs without viral symptoms and, when HC-Pro is expressed from a mutant transgene, without detrimental developmental phenotypes.

DICER-LIKE2 plays a primary role in transitive silencing of transgenes in Arabidopsis.

Dicer-like (DCL) enzymes play a pivotal role in RNA silencing in plants, processing the long double-stranded RNA (dsRNA) that triggers silencing into the primary short interfering RNAs (siRNAs) that mediate it. The siRNA population can be augmented and silencing amplified via transitivity, an RNA-dependent RNA polymerase (RDR)-dependent pathway that uses the target RNA as substrate to generate secondary siRNAs. Here we report that Arabidopsis DCL2–but not DCL4-is required for transitivity in cell-autonomous, post-transcriptional silencing of transgenes. An insertion mutation in DCL2 blocked sense transgene-induced silencing and eliminated accumulation of the associated RDR-dependent siRNAs. In hairpin transgene-induced silencing, the dcl2 mutation likewise eliminated accumulation of secondary siRNAs and blocked transitive silencing, but did not block silencing mediated by primary siRNAs. Strikingly, in all cases, the dcl2 mutation eliminated accumulation of all secondary siRNAs, including those generated by other DCL enzymes. In contrast, mutations in DCL4 promoted a dramatic shift to transitive silencing in the case of the hairpin transgene and enhanced silencing induced by the sense transgene. Suppression of hairpin and sense transgene silencing by the P1/HC-Pro and P38 viral suppressors was associated with elimination of secondary siRNA accumulation, but the suppressors did not block processing of the stem of the hairpin transcript into primary siRNAs. Thus, these viral suppressors resemble the dcl2 mutation in their effects on siRNA biogenesis. We conclude that DCL2 plays an essential, as opposed to redundant, role in transitive silencing of transgenes and may play a more important role in silencing of viruses than currently thought.

Infiltration with Agrobacterium tumefaciens Induces Host Defense and Development-Dependent Responses in the Infiltrated Zone

Despite the widespread use of Agrobacterium tumefaciens to transfer genes into plant systems, host responses to this plant pathogen are not well understood. The present study shows that disarmed strains of Agrobacterium induce distinct host responses when infiltrated into leaves of Nicotiana tabacum. The responses are limited to the infiltrated zone and consist of i) induction of pathogenesis-related (PR) gene PR-1 expression and resistance to subsequent infection with tobacco mosaic virus, ii) chlorosis and loss of chloroplast rRNAs, and iii) inhibition of leaf expansion. Induction of the latter two sets of responses depends on the age of the leaf and is most apparent in young leaves. Strains with or without binary vectors induce all the responses, showing that DNA transfer is neither required nor inhibitory. A. tumefaciens cured of the tumor-inducing (Ti) plasmid is slightly defective for induction of the three responses, showing that Ti plasmid-encoded factors produced by the disarmed strains contribute only slightly. However, T-DNA-encoded factors alter at least one of the host responses, because infiltration with the oncogenic strain C58 induced more pronounced chlorosis than the disarmed control. Auxin is one of the T-DNA products responsible for disease induction by oncogenic A. tumefaciens. We found that C58-infiltrated zones-but not those infiltrated with the disarmed control-have increased levels of miR393, a microRNA that represses auxin signaling and contributes to antibacterial resistance.

The complete nucleotide sequence of pepper mottle virus genomic RNA : comparison of the encoded polyprotein with those of other sequenced potyviruses

The complete nucleotide sequence of a pepper mottle virus isolate from California (PepMoV C) has been determined from cloned viral cDNAs. The PepMoV C genomic RNA is 9640 nucleotides excluding the poly(A) tail and contains a long open reading frame starting at nucleotide 168 and potentially encoding a polyprotein of 3068 amino acids. Comparison of the PepMoV C presumptive polyprotein with those of other sequenced members of the potyvirus group, including tobacco etch virus (TEV), tobacco vein mottling virus (TVMV), plum pox virus (PPV), and potato virus Y (PVY), allowed localization of putative protein cleavage sites. A similar analysis was used to determine the position of conserved viral protein-coding regions along the viral genomic RNA. These analyses confirm previous work indicating that genome organization is conserved among members of the genus Potyvirus. The localization of one PepMoV C gene product, the nuclear inclusion body protein a (NIa protein), was analyzed by expressing PepMoV cDNA deletion clones in bacteria and assaying for appearance of mature-sized coat protein, a cleavage product of the NIa protease. Comparative sequence analyses of the putative PepMoV polyprotein with those of TEV, TVMV, PPV, and PVY served to identify regions of the potyviral polyproteins which have diverged within the genus, as well as highly conserved protein features which may play an important functional role in the potyviral life cycle.