Characterization of nuclear import of potato spindle tuber viroid RNA in permeabilized protoplasts

Most viroids replicate in the nuclei of infected plant cells. Nuclear import of the incoming RNA thus represents a key control point for establishment of a systemic infection. However, little is known about the mechanisms by which viroids are transported into the nucleus. We have characterized nuclear import of infectious, fluorescein-labeled potato spindle tuber viroid (F-PSTVd) in permeabilized tobacco BY2 cells. Import was observed for F-PSTVd but not for mRNA fragments of the same size or two viroids believed to replicate in the chloroplasts. Import of F-PSTVd was inhibited by addition of a 10-fold excess of non-fluorescent PSTVd but not by similar amounts of control RNAs. Import was not inhibited by pre-incubation with GTP-γ-S or GDP-β-S, however. Disruption of microtubules and actin filaments with oryzalin or cytochalasin D did not inhibit F-PSTVd import. Taken together, our results indicate that (i) PSTVd possesses a sequence and/or structural motif for nuclear import and (ii) the import is a cytoskeleton-independent process that is mediated by a specific and saturable receptor. Insensitivity to GTP-γ-S and GDP-β-S treatment suggests that PSTVd import is not coupled to Ran GTPase cycle, which mediates nuclear transport of many proteins and nucleic acids. To our knowledge, our studies are the first to examine the mechanisms of nuclear transport of RNA in plants.     

RNAi-mediated resistance to Potato spindle tuber viroid in transgenic tomato expressing a viroid hairpin RNA construct

Because of their highly ordered structure, mature viroid RNA molecules are assumed to be resistant to degradation by RNA interference (RNAi). In this article, we report that transgenic tomato plants expressing a hairpin RNA (hpRNA) construct derived from Potato spindle tuber viroid (PSTVd) sequences exhibit resistance to PSTVd infection. Resistance seems to be correlated with high-level accumulation of hpRNA-derived short interfering RNAs (siRNAs) in the plant. Thus, although small RNAs produced by infecting viroids [small RNAs of PSTVd (srPSTVds)] do not silence viroid RNAs efficiently to prevent their replication, hpRNA-derived siRNAs (hp-siRNAs) appear to effectively target the mature viroid RNA. Genomic mapping of the hp-siRNAs revealed an unequal distribution of 21- and 24-nucleotide siRNAs of both (+)- and (–)-strand polarities along the PSTVd genome. These data suggest that RNAi can be employed to engineer plants for viroid resistance, as has been well established for viruses.     

Unraveling the mystery of viroid nuclear import

Viroids are closed-circular infectious RNAs that are known to infect plants. Despite their small noncoding genome, they have the ability to cause disease. The nuclear import mechanism of nucleus replicating viroids is not well understood. Ma et al. have recently highlighted the route of viroid entry into the nucleus.     

Fatal Yellowing of Oil Palms: Search for Viroids and Double-Stranded RNA

Fatal yellowing is a serious disease of still unknown origin affecting oil palms in several regions of Central and South America. In this study a search for viroids and viroid-like RNAs in oil palms was performed using two-dimensional gel electrophoresis and return gel electrophoresis of nucleic acid extracts. Although RNAs showing viroid-like gel-electrophoretic properties were detected, the presence of the known viroids was excluded by hybridization experiments using probes specific for potato spindle tuber viroid (PSTVd), coconut cadang-cadang viroid (CCCVd), or Coleus blumei viroid 1 (CbVd1). By using double-stranded RNA (dsRNA) specific monoclonal antibodies, which do not react with viroid RNA, we were able to show that oil palm RNAs, migrating like viroids are double-stranded RNA species. Since the same dsRNA pattern was found in extracts from diseased as well as from healthy oil palms, the dsRNAs can neither be part of the causative agent of fatal yellowing, nor are they associated with the disease. Their possible origin is discussed. In addition to the standard electrophoretic methods, which have been used for identification of viroids and viroid-like RNAs, we describe additional control experiments to differentiate unequivocally between circular single stranded and linear dsRNA.     

Inhibition of cell growth and shoot development by a specific nucleotide sequence in a noncoding viroid RNA

Viroids are small noncoding and infectious RNAs that replicate autonomously and move systemically throughout an infected plant. The RNAs of the family Pospiviroidae contain a central conserved region (CCR) that has long been thought to be involved in replication. Here, we report that the CCR of Potato spindle tuber viroid (PSTVd) also plays a role in pathogenicity. A U257A change in the CCR converted the intermediate strain PSTVd(Int) to a lethal strain that caused severe growth stunting and premature death of infected plants. PSTVd with nucleotide U257 changed to C or G did not cause such symptoms. The pathogenic effect of the U257A substitution was abolished by a C259U substitution in the same RNA. Analyses of the pathogenic effects of the U257A substitution in three other PSTVd variants established A257 as a new pathogenicity determinant that functions independently and synergistically with the classic pathogenicity domain. The U257A substitution did not alter PSTVd secondary structure, replication levels, or tissue tropism. The stunted growth of PSTVd(Int)U257A-infected tomato plants resulted from restricted cell expansion but not cell division or differentiation. This was correlated positively with the downregulated expression of an expansin gene, LeExp2. Our results demonstrate that specific nucleotides in a noncoding, pathogenic RNA have a profound effect in altering distinct cellular responses, which then lead to well-defined alterations in plant growth and developmental patterns. The feasibility of correlating viroid RNA sequence/structure with the altered expression of specific host genes, cellular processes, and developmental patterns makes viroid infection a valuable system in which to investigate host factors for symptom expression and perhaps also to characterize the mechanisms of RNA regulation of gene expression in plants.     

A structured viroid RNA serves as a substrate for dicer-like cleavage to produce biologically active small RNAs but is resistant to RNA-induced silencing complex-mediated degradation

RNA silencing is a potent means of antiviral defense in plants and animals. A hallmark of this defense response is the production of 21- to 24-nucleotide viral small RNAs via mechanisms that remain to be fully understood. Many viruses encode suppressors of RNA silencing, and some viral RNAs function directly as silencing suppressors as counterdefense. The occurrence of viroid-specific small RNAs in infected plants suggests that viroids can trigger RNA silencing in a host, raising the question of how these noncoding and unencapsidated RNAs survive cellular RNA-silencing systems. We address this question by characterizing the production of small RNAs of Potato spindle tuber viroid (srPSTVds) and investigating how PSTVd responds to RNA silencing. Our molecular and biochemical studies provide evidence that srPSTVds were derived mostly from the secondary structure of viroid RNAs. Replication of PSTVd was resistant to RNA silencing, although the srPSTVds were biologically active in guiding RNA-induced silencing complex (RISC)-mediated cleavage, as shown with a sensor system. Further analyses showed that without possessing or triggering silencing suppressor activities, the PSTVd secondary structure played a critical role in resistance to RISC-mediated cleavage. These findings support the hypothesis that some infectious RNAs may have evolved specific secondary structures as an effective means to evade RNA silencing in addition to encoding silencing suppressor activities. Our results should have important implications in further studies on RNA-based mechanisms of host-pathogen interactions and the biological constraints that shape the evolution of infectious RNA structures.     

Potato spindle tuber viroid as inducer of RNA silencing in infected tomato.

Potato spindle tuber viroid (PSTVd), an RNA plant pathogen encoding no known proteins, induces systemic symptoms on tomato plants. We report detection of small RNAs of approximately 25 nucleotides with sequence specificity to PSTVd in infected plants: an indication of the presence of RNA silencing. RNA silencing, however, did not appear to be responsible for the differing symptoms induced by a mild and a severe strain of PSTVd. The unique structural and biological features of viroids make them attractive experimental tools to investigate mechanisms of RNA silencing and pathogen counterdefense.     

Scion on a Stock Producing siRNAs of Potato Spindle Tuber Viroid (PSTVd) Attenuates Accumulation of the Viroid

Plants can attenuate the replication of plant viruses and viroids by RNA silencing induced by virus and viroid infection. In higher plants, silencing signals such as small interfering RNAs (siRNAs) produced by RNA silencing can be transported systemically through phloem, so it is anticipated that antiviral siRNA signals produced in a stock would have the potential to attenuate propagation of viruses or viroids in the scion. To test whether this is indeed the case, we prepared transgenic tobacco (Nicotiana benthamiana) expressing a hairpin RNA (hpRNA) of Potato spindle tuber viroid (PSTVd) in companion cells by using a strong companion cell-specific promoter. A grafting experiment of the wild type tobacco scion on the top of the transgenic tobacco stock revealed that accumulation of PSTVd challenge-inoculated into the scion was apparently attenuated compared to the control grafted plants. These results indicate that genetically modified rootstock expressing viroid-specific siRNAs can attenuate viroid accumulation in a non-genetically modified scion grafted on the stock.     

Movement of potato spindle tuber viroid reveals regulatory points of phloem-mediated RNA traffic

Increasing evidence indicates that the phloem mediates traffic of selective RNAs within a plant. How an RNA enters, moves in, and exits the phloem is poorly understood. Potato spindle tuber viroid (PSTVd) is a pathogenic RNA that does not encode proteins and is not encapsidated, and yet it replicates autonomously and traffics systemically within an infected plant. The viroid RNA genome must interact directly with cellular factors to accomplish these functions and is, therefore, an excellent probe to study mechanisms that regulate RNA traffic. Our analyses of PSTVd traffic in Nicotiana benthamiana yielded evidence that PSTVd movement within sieve tubes does not simply follow mass flow from source to sink organs. Rather, this RNA is transported into selective sink organs. Furthermore, two PSTVd mutants can enter the phloem to spread systemically but cannot exit the phloem in systemic leaves of tobacco (Nicotiana tabacum). A viroid most likely has evolved structural motifs that mimic endogenous plant RNA motifs so that they are recognized by cellular factors for traffic. Thus, analysis of PSTVd traffic functions may provide insights about endogenous mechanisms that control phloem entry, transport, and exit of RNAs.     

Prominent polypurine and polypyrimidine tracts in plant viroids and in RNA of the human hepatitis delta agent.

To seek patterns of nucleotide usage in the three types of circular subviral RNA pathogens, trimer frequencies and nearest-neighbor biases were studied in 12 plant viroid sequences; five sequences of circular plant viral satellite RNAs; and the sequence of RNA from the human hepatitis delta agent. The viroids and RNA of the delta agent contain tracts of polypurines and polypyrimidines which make up substantial portions of their genomes. Such tracts are not common in the virusoids or in the satellite RNA of tobacco ringspot virus. Viroids, the delta hepatitis agent, and the circular satellite RNAs of certain plant viruses have several features in common: all have circular genomic RNA and replicate through an RNA to RNA rolling circle replication cycle. However, virusoids and related satellite RNAs are directly or indirectly dependent on their helper viruses for replication, while the delta agent and viroids are not. The difference in the pattern of nucleotide usage between the plant viral satellite RNAs on the one hand, and viroids and delta RNA on the other, may relate to this difference in replication strategy.     

A chimeric satellite transgene sequence is inefficiently targeted by viroid-induced DNA methylation in tobacco

In plants, transgenes containing Potato spindle tuber viroid (PSTVd) cDNA sequences were efficient targets of PSTVd infection-mediated RNA-directed DNA methylation. Here, we demonstrate that in PSTVd-infected tobacco plants, a 134 bp PSTVd fragment (PSTVd-134) did not become densely methylated when it was inserted into a chimeric Satellite tobacco mosaic virus (STMV) construct. Only about 4–5% of all cytosines (Cs) of the PSTVd-134 were methylated when flanked by satellite sequences. In the same plants, C methylation was approximately 92% when the PSTVd-134 was in a PSTVd full length sequence context and roughly 33% when flanked at its 3′ end by a 19 bp PSTVd and at its 5′ end by a short viroid-unrelated sequence. In addition, PSTVd small interfering RNAs (siRNAs) produced from the replicating viroid failed to target PSTVd-134-containing chimeric STMV RNA for degradation. Satellite RNAs appear to have adopted secondary structures that protect them against RNA interference (RNAi)—mediated degradation. Protection can be extended to short non-satellite sequences residing in satellite RNAs, rendering them poor targets for nuclear and cytoplasmic RNAi induced in trans.     

Viroid RNA systemic spread may depend on the interaction of a 71-nucleotide bulged hairpin with the host protein VirP1

Viroids are noncoding circular single-stranded RNAs that are propagated systemically in plants. VirP1 is a protein from tomato, which is an excellent host for potato spindle tuber viroid (PSTVd), and it has been isolated by virtue of its specific in vitro binding to PSTVd RNA. We report on the specific in vivo interaction of VirP1 with full-length viroid RNA as well as with subfragments in the three-hybrid system. The terminal right domain (TR) of PSTVd was identified as a strong interacting partner for VirP1. A weaker partner is provided by a right-hand subfragment of hop stunt viroid (HSVd), a viroid that infects tomato poorly. We present a sequence and structural motif of the VirP1-interacting subfragments. The motif is disturbed in the replicative but nonspreading R+ mutant of the TR. According to our in vivo and in vitro binding assays, the interaction of this mutant with VirP1 is compromised. We propose that the AGG/CCUUC motif bolsters recognition of the TR by VirP1 to achieve access of the viroid to pathways that propagate endogenous RNA systemic signals in plants. Systemic trafficking has been suggested for miRNA precursors, of which the TR, as a stable bulged hairpin 71 nt long, is quite reminiscent.