Only one of four possible secondary structures of the central conserved region of potato spindle tuber viroid is a substrate for processing in a potato nuclear extract

Progress in 50 years of viroid research-Molecular structure, pathogenicity, and host adaptation

Viroids are non-encapsidated, single-stranded, circular RNAs consisting of 246-434 nucleotides. Despite their non-protein-encoding RNA nature, viroids replicate autonomously in host cells. To date, more than 25 diseases in more than 15 crops, including vegetables, fruit trees, and flowers, have been reported. Some are pathogenic but others replicate without eliciting disease. Viroids were shown to have one of the fundamental attributes of life to adapt to environments according to Darwinian selection, and they are likely to be living fossils that have survived from the pre-cellular RNA world. In 50 years of research since their discovery, it was revealed that viroids invade host cells, replicate in nuclei or chloroplasts, and undergo nucleotide mutation in the process of adapting to new host environments. It was also demonstrated that structural motifs in viroid RNAs exert different levels of pathogenicity by interacting with various host factors. Despite their small size, the molecular mechanism of viroid pathogenicity turned out to be more complex than first thought.

Direct visualization of the native structure of viroid RNAs at single-molecule resolution by atomic force microscopy

Viroids are small infectious, non-protein-coding circular RNAs that replicate independently and, in some cases, incite diseases in plants. They are classified into two families: Pospiviroidae, composed of species that have a central conserved region (CCR) and replicate in the cell nucleus, and Avsunviroidae, containing species that lack a CCR and whose multimeric replicative intermediates of either polarity generated in plastids self-cleave through hammerhead ribozymes. The compact, rod-like or branched, secondary structures of viroid RNAs have been predicted by RNA folding algorithms and further examined using different in vitro and in vivo experimental techniques. However, direct data about their native tertiary structure remain scarce. Here we have applied atomic force microscopy (AFM) to image at single-molecule resolution different variant RNAs of three representative viroids: potato spindle tuber viroid (PSTVd, family Pospiviroidae), peach latent mosaic viroid and eggplant latent viroid (PLMVd and ELVd, family Avsunviroidae). Our results provide a direct visualization of their native, three-dimensional conformations at 0 and 4 mM Mg2+ and highlight the role that some elements of tertiary structure play in their stabilization. The AFM images show that addition of 4 mM Mg2+ to the folding buffer results in a size contraction in PSTVd and ELVd, as well as in PLMVd when the kissing-loop interaction that stabilizes its 3D structure is preserved.

Enrichment of midsized RNAs with manganese chloride precipitation

Enrichment of specific RNAs is important for RNA analysis. MnCl₂ has been used previously to enrich viroid RNA fractions from total RNA from infected plants. We have expanded this method to show that MnCl₂ can enrich single-stranded as well as structured RNAs of 450 nt and below from a total RNA preparation. We have applied this method to map the transcription start sites of a PSTVd transcript from total RNA from yeast under conditions where the RNA was previously undetectable.

CNBP Homologues Gis2 and Znf9 Interact with a Putative G-Quadruplex-Forming 3' Untranslated Region, Altering Polysome Association and Stress Tolerance in Cryptococcus neoformans

Stress adaptation is fundamental to the success of Cryptococcus neoformans as a human pathogen and requires a reprogramming of the translating pool of mRNA. This reprogramming begins with the regulated degradation of mRNAs encoding the translational machinery. The mechanism by which these mRNAs are specified has not been determined. This study has identified a cis element within a G-quadruplex structure that binds two C. neoformans homologues of cellular nucleic acid binding protein (CNBP). These proteins regulate the polysome association of the target mRNA but perform functions related to sterol homeostasis which appear independent of ribosomal protein mRNAs. The presence of two CNBP homologues in C. neoformans suggests a diversification of function of these proteins, one of which appears to regulate sterol biosynthesis and fluconazole sensitivity.

In Cryptococcus neoformans, mRNAs encoding ribosomal proteins (RP) are rapidly and specifically repressed during cellular stress, and the bulk of this repression is mediated by deadenylation-dependent mRNA decay. A motif-finding approach was applied to the 3′ untranslated regions (UTRs) of RP transcripts regulated by mRNA decay, and a single, significant motif, GGAUG, was identified. Znf9, a small zinc knuckle RNA binding protein identified by mass spectrometry, was found to interact specifically with the RPL2 3′-UTR probe. A second, homologous protein, Gis2, was identified in the genome of C. neoformans and also bound the 3′-UTR probe, and deletion of both genes resulted in loss of binding in cell extracts. The RPL2 3′ UTR contains four G-triplets (GGG) that have the potential to form a G-quadruplex, and temperature gradient gel electrophoresis revealed a potassium-dependent structure consistent with a G-quadruplex that was abrogated by mutation of G-triplets. However, deletion of G-triplets did not abrogate the binding of either Znf9 or Gis2, suggesting that these proteins either bind irrespective of structure or act to prevent structure formation. Deletion of both GIS2 and ZNF9 resulted in a modest increase in basal stability of the RPL2 mRNA which resulted in an association with higher-molecular-weight polysomes under unstressed conditions. The gis2Δ mutant and gis2Δ znf9Δ double mutant exhibited sensitivity to cobalt chloride, fluconazole, and oxidative stress, and although transcriptional induction of ERG25 was similar to that of the wild type, analysis of sterol content revealed repressed levels of sterols in the gis2Δ and gis2Δ znf9Δ double mutant, suggesting a role in translational regulation of sterol biosynthesis.

IMPORTANCE Stress adaptation is fundamental to the success of Cryptococcus neoformans as a human pathogen and requires a reprogramming of the translating pool of mRNA. This reprogramming begins with the regulated degradation of mRNAs encoding the translational machinery. The mechanism by which these mRNAs are specified has not been determined. This study has identified a cis element within a G-quadruplex structure that binds two C. neoformans homologues of cellular nucleic acid binding protein (CNBP). These proteins regulate the polysome association of the target mRNA but perform functions related to sterol homeostasis which appear independent of ribosomal protein mRNAs. The presence of two CNBP homologues in C. neoformans suggests a diversification of function of these proteins, one of which appears to regulate sterol biosynthesis and fluconazole sensitivity.

Processing of Potato Spindle Tuber Viroid RNAs in Yeast, a Nonconventional Host

Potato spindle tuber viroid (PSTVd) is a circular, single-stranded, noncoding RNA plant pathogen that is a useful model for studying the processing of noncoding RNA in eukaryotes. Infective PSTVd circles are replicated via an asymmetric rolling circle mechanism to form linear multimeric RNAs. An endonuclease cleaves these into monomers, and a ligase seals these into mature circles. All eukaryotes may have such enzymes for processing noncoding RNA. As a test, we investigated the processing of three PSTVd RNA constructs in the yeast Saccharomyces cerevisiae Of these, only one form, a construct that adopts a previously described tetraloop-containing conformation (TL), produces circles. TL has 16 nucleotides of the 3' end duplicated at the 5' end and a 3' end produced by self-cleavage of a delta ribozyme. The other two constructs, an exact monomer flanked by ribozymes and a trihelix-forming RNA with requisite 5' and 3' duplications, do not produce circles. The TL circles contain nonnative nucleotides resulting from the 3' end created by the ribozyme and the 5' end created from an endolytic cleavage by yeast at a site distinct from where potato enzymes cut these RNAs. RNAs from all three transcripts are cleaved in places not on path for circle formation, likely representing RNA decay. We propose that these constructs fold into distinct RNA structures that interact differently with host cell RNA metabolism enzymes, resulting in various susceptibilities to degradation versus processing. We conclude that PSTVd RNA is opportunistic and may use different processing pathways in different hosts.IMPORTANCE In higher eukaryotes, the majority of transcribed RNAs do not encode proteins. These noncoding RNAs are responsible for mRNA regulation, control of the expression of regulatory microRNAs, sensing of changes in the environment by use of riboswitches (RNAs that change shape in response to environmental signals), catalysis, and more roles that are still being uncovered. Some of these functions may be remnants from the RNA world and, as such, would be part of the evolutionary past of all forms of modern life. Viroids are noncoding RNAs that can cause disease in plants. Since they encode no proteins, they depend on their own RNA and on host proteins for replication and pathogenicity. It is likely that viroids hijack critical host RNA pathways for processing the host's own noncoding RNA. These pathways are still unknown. Elucidating these pathways should reveal new biological functions of noncoding RNA.

Structure and Associated Biological Functions of Viroids

Mature viroids consist of a noncoding, covalently closed circular RNA that is able to autonomously infect respective host plants. Thus, they must utilize proteins of the host for most biological functions such as replication, processing, transport, and pathogenesis. Therefore, viroids can be regarded as minimal parasites of the host machinery. They have to present to the host machinery the appropriate signals based on either their sequence or their structure. Here, we summarize such sequence and structural features critical for the biological functions of viroids.

The RNA strands of the plus and minus polarities of peach latent mosaic viroid fold into different structures

It is believed that peach latent mosaic viroid (PLMVd) strands of both the plus and minus polarities fold into similar secondary and tertiary structures. In order to verify this hypothesis, the behavior of both strands in three biophysical assays was examined. PLMVd transcripts of plus and minus polarity were found to exhibit distinct electrophoretic mobility properties under native conditions, to precipitate differently in the presence of lithium chloride, and to possess variable thermal denaturation profiles. Subsequently, the structure of PLMVd transcripts of minus polarity was elucidated by biochemical methods, thereby permitting comparison to the known structure of the plus polarity. Specifically, enzymatic probing, electrophoretic mobility shift assay, and ribonuclease H hydrolysis were performed in order to resolve the secondary structure of the minus polarity. The left domains of the strands of both polarities appear to be similar, while the right domain exhibited several differences even though they both adopted a branched structure. The pseudoknot P8 formed in the plus strand seemed not formed in the minus strands. The structural differences between the two polarities might have important implications in various steps of the PLMVd life cycle.

RNA conformational changes in the life cycles of RNA viruses, viroids, and virus-associated RNAs

The rugged nature of the RNA structural free energy landscape allows cellular RNAs to respond to environmental conditions or fluctuating levels of effector molecules by undergoing dynamic conformational changes that switch on or off activities such as catalysis, transcription or translation. Infectious RNAs must also temporally control incompatible activities and rapidly complete their life cycle before being targeted by cellular defenses. Viral genomic RNAs must switch between translation and replication, and untranslated subviral RNAs must control other activities such as RNA editing or self-cleavage. Unlike well characterized riboswitches in cellular RNAs, the control of infectious RNA activities by altering the configuration of functional RNA domains has only recently been recognized. In this review, we will present some of these molecular rearrangements found in RNA viruses, viroids and virus-associated RNAs, relating how these dynamic regions were discovered, the activities that might be regulated, and what factors or conditions might cause a switch between conformations.

Processing of nuclear viroids in vivo: an interplay between RNA conformations

Replication of viroids, small non-protein-coding plant pathogenic RNAs, entails reiterative transcription of their incoming single-stranded circular genomes, to which the (+) polarity is arbitrarily assigned, cleavage of the oligomeric strands of one or both polarities to unit-length, and ligation to circular RNAs. While cleavage in chloroplastic viroids (family Avsunviroidae) is mediated by hammerhead ribozymes, where and how cleavage of oligomeric (+) RNAs of nuclear viroids (family Pospiviroidae) occurs in vivo remains controversial. Previous in vitro data indicated that a hairpin capped by a GAAA tetraloop is the RNA motif directing cleavage and a loop E motif ligation. Here we have re-examined this question in vivo, taking advantage of earlier findings showing that dimeric viroid (+) RNAs of the family Pospiviroidae transgenically expressed in Arabidopsis thaliana are processed correctly. Using this methodology, we have mapped the processing site of three members of this family at equivalent positions of the hairpin I/double-stranded structure that the upper strand and flanking nucleotides of the central conserved region (CCR) can form. More specifically, from the effects of 16 mutations on Citrus exocortis viroid expressed transgenically in A. thaliana, we conclude that the substrate for in vivo cleavage is the conserved double-stranded structure, with hairpin I potentially facilitating the adoption of this structure, whereas ligation is determined by loop E and flanking nucleotides of the two CCR strands. These results have deep implications on the underlying mechanism of both processing reactions, which are most likely catalyzed by enzymes different from those generally assumed: cleavage by a member of the RNase III family, and ligation by an RNA ligase distinct from the only one characterized so far in plants, thus predicting the existence of at least a second plant RNA ligase.

Structural differences within the loop E motif imply alternative mechanisms of viroid processing

Viroids replicate via a rolling circle mechanism, and cleavage/ligation requires extensive rearrangement of the highly base-paired native structure. For Potato spindle tuber viroid (PSTVd), the switch from cleavage to ligation is driven by the change from a multibranched tetraloop structure to a loop E conformation. Here we present evidence that processing of Citrus viroid III (CVd-III), a member of a related group of viroids that also replicate in the nucleus, may proceed via a distinct pathway. Chemical probing of PSTVd and CVd-III miniRNAs with DMS and CMCT revealed that the loop E motifs of these two viroids have quite different tertiary structures. As shown by temperature gradient gel electrophoresis, the presence of two likely Watson-Crick GC pairs results in a significant overall stabilization of the CVd-III loop E-like motif. Unlike PSTVd, the upper strand of the CVd-III loop E-like motif cannot fold into a GNRA tetraloop, and comparison of suboptimal structures indicates that the initial cleavage event could occur on the 5' side of the only GU wobble pair in a helix involving a nearby pair of inverted repeats. According to our model, rearrangement of 3' sequences into a hairpin stem containing an identical arrangement of GC, GU, and CG base pairs and a second cleavage event is followed by formation of loop E, which serves to align the 5' and 3' termini of the CVd-III monomer prior to ligation. Because ligation would occur within loop E itself, stabilization of this motif may be needed to hold the 5' and 3' termini of CVd-III in position for the host ligase.

Viroid: a useful model for studying the basic principles of infection and RNA biology

Viroids are small, circular, noncoding RNAs that currently are known to infect only plants. They also are the smallest self-replicating genetic units known. Without encoding proteins and requirement for helper viruses, these small RNAs contain all the information necessary to mediate intracellular trafficking and localization, replication, systemic trafficking, and pathogenicity. All or most of these functions likely result from direct interactions between distinct viroid RNA structural motifs and their cognate cellular factors. In this review, we discuss current knowledge of these RNA motifs and cellular factors. An emerging theme is that the structural simplicity, functional versatility, and experimental tractability of viroid RNAs make viroid-host interactions an excellent model to investigate the basic principles of infection and further the general mechanisms of RNA-templated replication, intracellular and intercellular RNA trafficking, and RNA-based regulation of gene expression. We anticipate that significant advances in understanding viroid-host interactions will be achieved through multifaceted secondary and tertiary RNA structural analyses in conjunction with genetic, biochemical, cellular, and molecular tools to characterize the RNA motifs and cellular factors associated with the processes leading to systemic infection.

Tertiary structural and functional analyses of a viroid RNA motif by isostericity matrix and mutagenesis reveal its essential role in replication

RNA-templated RNA replication is essential for viral or viroid infection, as well as for regulation of cellular gene expression. Specific RNA motifs likely regulate various aspects of this replication. Viroids of the Pospiviroidae family, as represented by the Potato spindle tuber viroid (PSTVd), replicate in the nucleus by utilizing DNA-dependent RNA polymerase II. We investigated the role of the loop E (sarcin/ricin) motif of the PSTVd genomic RNA in replication. A tertiary-structural model of this motif, inferred by comparative sequence analysis and comparison with nuclear magnetic resonance and X-ray crystal structures of loop E motifs in other RNAs, is presented in which core non-Watson-Crick base pairs are precisely specified. Isostericity matrix analysis of these base pairs showed that the model accounts for the reported natural sequence variations and viable experimental mutations in loop E motifs of PSTVd and other viroids. Furthermore, isostericity matrix analysis allowed us to design disruptive, as well as compensatory, mutations of PSTVd loop E. Functional analyses of such mutants by in vitro and in vivo experiments demonstrated that loop E structural integrity is crucial for replication, specifically during transcription. Our results suggest that the PSTVd loop E motif exists and functions in vivo and provide loss-of-function genetic evidence for the essential role of a viroid RNA three-dimensional motif in rolling-circle replication. The use of isostericity matrix analysis of non-Watson-Crick base pairing to rationalize mutagenesis of tertiary motifs and systematic in vitro and in vivo functional assays of mutants offers a novel, comprehensive approach to elucidate the tertiary-structure-function relationships for RNA motifs of general biological significance.

Conformational changes involved in initiation of minus-strand synthesis of a virus-associated RNA

Synthesis of wild-type levels of turnip crinkle virus (TCV)-associated satC complementary strands by purified, recombinant TCV RNA-dependent RNA polymerase (RdRp) in vitro was previously determined to require 3' end pairing to the large symmetrical internal loop of a phylogenetically conserved hairpin (H5) located upstream from the hairpin core promoter. However, wild-type satC transcripts, which fold into a single detectable conformation in vitro as determined by temperature-gradient gel electrophoresis, do not contain either the phylogenetically inferred H5 structure or the 3' end/H5 interaction. This implies that conformational changes are required to produce the phylogenetically inferred H5 structure for its pairing with the 3' end, which takes place subsequent to the initial conformation assumed by the RNA and prior to transcription initiation. The DR region, located 140 nucleotides upstream from the 3' end and previously determined to be important for transcription in vitro and replication in vivo, is proposed to have a role in the conformational switch, since stabilizing the phylogenetically inferred H5 structure decreases the negative effects of a DR mutation in vivo. In addition, high levels of aberrant transcription correlate with a specific conformational change in the Pr while maintaining the same conformation of the 3' terminus. These results suggest that a series of events that promote conformational changes is needed to expose the 3' terminus to the RdRp for accurate synthesis of wild-type levels of complementary strands in vitro.

The N-glycosidase activity of the ribosome-inactivating protein ME1 targets single-stranded regions of nucleic acids independent of sequence or structural motifs

ME(1), a type I ribosome-inactivating protein (RIP), belongs to a family of enzymes long believed to possess rRNA N-glycosidase activity directed solely at the universally conserved residue A4324 in the sarcin/ricin loop of large eukaryotic and prokaryotic rRNAs. We have investigated the effect of modifying the structure of nonribosomal RNA substrates on their interaction with ME(1) and other RIPs. ME(1) was shown to depurinate a variety of partially denatured nucleic acids, randomly removing adenine residues from single-stranded regions and, to a lesser extent, guanine residues from wobble base-pairs in hairpin stems. A defined sequence motif was not required for recognition of non-paired adenosines and cleavage of the N-glycosidic bond. Substrate recognition and ME(1) activity appeared to depend on the physical availability of nucleotides, and denaturation of nucleic acid substrates increased their interaction with ME(1). Pretreatment of mRNA at 75 degrees C rather than 60 degrees C, for example, lowered the apparent K(D) from 87.1 to 73.9 nm, making it more vulnerable to depurination by RIPs. Exposure to ME(1) in vitro completely abolished the infectivity of partially denatured RNA transcripts of the potato spindle tuber viroid, suggesting that RIPs may target invading nucleic acids before they reach host ribosomes in vivo. Our data suggest that the extensive folding of many potential substrates interferes with their ability to interact with RIPs, thereby blocking their inactivation by ME(1) (or other RIPs).

Characterization of the RNA motif responsible for the specific interaction of potato spindle tuber viroid RNA (PSTVd) and the tomato protein Virp1

Viroids are small non-coding parasitic RNAs that are able to infect their host plants systemically. This circular naked RNA makes use of host proteins to accomplish its proliferation. Here we analyze the specific binding of the tomato protein Virp1 to the terminal right domain of potato spindle tuber viroid RNA (PSTVd). We find that two asymmetric internal loops within the PSTVd (+) RNA, each composed of the sequence elements 5'-ACAGG and CUCUUCC-5', are responsible for the specific RNA-protein interaction. In view of the nucleotide composition we call this structural element an 'RY motif'. The RY motif located close to the terminal right hairpin loop of the PSTVd secondary structure has an approximately 5-fold stronger binding affinity than the more centrally located RY motif. Simultaneous sequence alterations in both RY motifs abolished the specific binding to Virp1. Mutations in any of the two RY motifs resulted in non-infectious viroid RNA, with the exception of one case, where reversion to sequence wild type took place. In contrast, the simultaneous exchange of two nucleotides within the terminal right hairpin loop of PSTVd had only moderate influence on the binding to Virp1. This variant was infectious and sequence changes were maintained in the progeny. The relevance of the phylogenetic conservation of the RY motif, and sequence elements therein, amongst various genera of the family Pospiviroidae is discussed.

Identification of a novel structural interaction in Columnea latent viroid

Pairwise sequence comparisons suggest that Columnea latent viroid (CLVd) may have originated from a recombination event involving Potato spindle tuber viroid (PSTVd) and Hop stunt viroid (HSVd). To examine the role of specific structural features in determining the host range of CLVd, we constructed a series of interspecific chimeras by replacing increasing portions of its terminal left and pathogenicity domains with the corresponding portions of PSTVd. Exchanges involving the left side of the pathogenicity domain led to lower rates of progeny accumulation in tomato, but one of the resulting chimeras was still able to replicate in cucumber. Exchanges involving the right side of the pathogenicity domain severely inhibited replication in tomato and appeared to abolish replication in cucumber. To identify potential interactions between nucleotides comprising the right side of the pathogenicity domain and other portions of CLVd, melting behaviors of circularized CLVd and PSTVd RNA transcripts were compared using a combination of temperature gradient gel electrophoresis and structural calculations. These analyses revealed an unexpected complementarity between the upper portion of the pathogenicity and terminal right domains of CLVd that facilitates breakdown of the rod-like native structure and formation of secondary hairpin II. Unlike secondary hairpin II, CLVd hairpin IV appears likely to act within the context of the genomic RNA.

A mini-RNA containing the tetraloop, wobble-pair and loop E motifs of the central conserved region of potato spindle tuber viroid is processed into a minicircle

A Mini-RNA from potato spindle tuber viroid (PSTVd) was constructed specifically for cleavage and ligation to circles in vitro. It contains the C-domain with the so-called central conserved region (CCR) of PSTVd with a 17 nt duplication in the upper strand and hairpin structures at the left and rights ends of the secondary structure. The CCR was previously shown to be essential for processing of in vitro transcripts. When folded under conditions which favor formation of a kinetically controlled conformation and incubated in a potato nuclear extract, the Mini-RNA is cleaved correctly at the 5'- and the 3'-end and ligated to a circle. Thus, the CCR obviously contains all structural and functional requirements for correct processing and therefore may be regarded as 'processing domain' of PSTVd. Using the Mini-RNA as a model substrate, the structural and functional relevance of its conserved non-canonical motifs GAAA tetraloop, loop E and G:U wobble base pair were studied by mutational analysis. It was found that (i) the conserved GAAA tetraloop is essential for processing by favoring the kinetically controlled conformation, (ii) a G:U wobble base pair at the 5'-cleavage site contributes to its correct recognition and (iii) an unpaired nucleotide in loop E, which is different from the corresponding nucleotide in the conserved loop E motif, is essential for ligation of the 5'- with the 3'-end. Hence all three structural motifs are functional elements for processing in a potato nuclear extract.

Detection and analysis of hairpin II, an essential metastable structural element in viroid replication intermediates

In (-)-stranded replication intermediates of the potato spindle tuber viroid (PSTVd) a thermodynamically metastable structure containing a specific hairpin structure (HP II) has been proposed to be essential for viroid replication. In the present work a method was devised allowing the direct detection of the HP II structure in vitro and in vivo using a biophysical approach. An RNA oligonucleotide was constructed which specifically binds to the HP II loop region in transient (-)-strand intermediates. Analysis of the resulting oligonucleotide/HP II complexes on temperature-gradient gels enabled us to follow the formation of HP II during in vitro transcription by T7 RNA polymerase. Moreover, we were able to demonstrate the formation of HP II during viroid replication in potato (Solanum tuberosum) cells.

RNA editing in hepatitis delta virus genotype III requires a branched double-hairpin RNA structure

RNA editing at the amber/W site plays a central role in the replication scheme of hepatitis delta virus (HDV), allowing the virus to produce two functionally distinct forms of the sole viral protein, hepatitis delta antigen (HDAg), from the same open reading frame. Editing is carried out by a cellular activity known as ADAR (adenosine deaminase), which acts on RNA substrates that are at least partially double stranded. In HDV genotype I, editing requires a highly conserved base-paired structure that occurs within the context of the unbranched rod structure characteristic of HDV RNA. This base-paired structure is disrupted in the unbranched rod of HDV genotype III, which is the most distantly related of the three known HDV genotypes and is associated with the most severe disease. Here I show that RNA editing in HDV genotype III requires a branched double-hairpin structure that deviates substantially from the unbranched rod structure, involving the rearrangement of nearly 80 bp. The structure includes a UNCG RNA tetraloop, a highly stable structural motif frequently involved in the folding of large RNAs such as rRNA. The double-hairpin structure is required for editing, and hence for virion formation, but not for HDV RNA replication, which requires the unbranched rod structure. HDV genotype III thus relies on a dynamic conformational switch between the two different RNA structures: the unbranched rod characteristic of HDV RNA and a branched double-hairpin structure that is required for RNA editing. The different mechanisms of editing in genotypes I and III underscore their functional differences and may be related to pathogenic differences as well.

Novel cross-strand three-purine stack of the highly conserved 5'-GA/AAG-5' internal loop at the 3'-end termini of Parvovirus genomes

We have used two-dimensional nuclear magnetic resonance (2D-NMR), distance geometry (DG) and molecular dynamics / energy minimization (MD/EM) methods to study a 2 x 3 asymmetric internal loop structure of the highly conserved 5'-(GA)/(AAG)-5' bubble' present at the 3'-end hairpin of the single-stranded DNA genome of parvoviruses. This motif contains an unpaired adenosine stacked between two bracketed sheared G.A pairs. However, the phenomenal cross-strand G-G and A-A stacking in the tandem sheared G.A pairs has undergone considerable change. A novel three-purine stacking pattern is observed instead; the inserted A18 base is completely un-stacked from its neighboring G 17 and A 19 bases, but well stacked with the cross-strand A4 and G3 bases to form a novel A4/A18/G3 stack that is different from the double G/G, A/A or quadruple G/G/G/G stack present in the 5'-(GA)/(AG)-5' or 5'-(GGA)/(AGG)-5' motifs. Unlike the bulged purine residue that usually causes about 20 degree kink in the helical axis of the parent helix when bracketed by canonical G.C or A.T base pairs, no significant kink is observed in the present helix containing a bulged-adenine that is bracketed by sheared G.A pairs. The phosphodiesters connecting G3-A4 and G17-A18 residues adopt unusual zeta torsional angles close to the trans domain, yet that connecting A18-A19 residues resumes the normal zeta(g-) value. The well structured '5'-(GAA)/(AG)-5" internal loop in the parvovirus genomes explains its resistance to single-strand specific endonuclease susceptibility.

Transcription of potato spindle tuber viroid by RNA polymerase II starts predominantly at two specific sites

Pospiviroidae, with their main representative potato spindle tuber viroid (PSTVd), are replicated via a rolling circle mechanism by the host-encoded DNA-dependent RNA polymerase II (pol II). In the first step, the (+)-strand circular viroid is transcribed into a (-)-strand oligomer intermediate. As yet it is not known whether transcription is initiated by promotors at specific start sites or is distributed non-specifically over the whole circle. An in vitro transcription extract was prepared from a non-infected potato cell culture which exhibited transcriptional activity using added circular PSTVd (+)-strand RNA as template. In accordance with pol II activity, transcription could be inhibited by alpha-amanitin. RT-PCR revealed the existence of at least two different start sites and primer extension identified these as nucleotides A(111) and A(325). The sequences of the first 7 nt transcribed are very similar, (105)GGAGCGA(111) and (319)GGGGCGA(325). GC-boxes are located at a distance of 15 and 16 nt upstream, respectively, in the native viroid structure, which may act to facilitate initiation. The GC-boxes may have a similar function to the GC-rich hairpin II in the (-)-strand intermediate, as described previously. The results are compared with the corresponding features of avocado sunblotch viroid, which belongs to a different family of viroids and exhibits different transcription initiation properties.

The brome mosaic virus RNA3 intergenic replication enhancer folds to mimic a tRNA TpsiC-stem loop and is modified in vivo

The genome of brome mosaic virus (BMV), a positive-strand RNA virus in the alphavirus-like superfamily, consists of three capped, messenger-sense RNAs. RNA1 and RNA2 encode viral replication proteins 1a and 2a, respectively. RNA3 encodes the 3a movement protein and the coat protein, which are essential for systemic infection in plants but dispensable for RNA3 replication in plants and yeast. A subset of the 250-base intergenic region (IGR), the replication enhancer (RE), contains all cis-acting signals necessary for a crucial, early template selection step, the 1a-dependent recruitment of RNA3 into replication. One of these signals is a motif matching the conserved box B sequence of RNA polymerase III transcripts. Using chemical modification with CMCT, kethoxal, DMS, DEPC, and lead, we probed the structure of the IGR in short, defined transcripts and in full-length RNA3 in vitro, in yeast extracts, and in whole yeast cells. Our results reveal a stable, unbranched secondary structure that is not dependent on the surrounding ORF sequences or on host factors within the cell. Functional 5' and 3' deletions that defined the minimal RE in earlier deletion studies map to the end of a common helical segment. The box B motif is presented as a hairpin loop of 7 nt closed by G:C base pairs in perfect analogy to the TpsiC-stem loop in tRNA(Asp). An adjacent U-rich internal loop, a short helix, and another pyrimidine-rich loop were significantly protected from base modifications. This same arrangement is conserved between BMV and cucumoviruses CMV, TAV, and PSV. In the BMV box B loop sequence, uridines corresponding to tRNA positions T54 and psi55 were found to be modified in yeast and plants to 5mU and pseudouridine. Together with the aminoacylated viral 3'-end, this is thus the second RNA replication signal within BMV where the virus has evolved a tRNA structural mimicry to a degree that renders it a substrate for classical tRNA modification reactions in vivo.

RNA folding pathway functional intermediates: their prediction and analysis

The massively parallel genetic algorithm (GA) for RNA structure prediction uses the concepts of mutation, recombination, and survival of the fittest to evolve a population of thousands of possible RNA structures toward a solution structure. As described below, the properties of the algorithm are ideally suited to use in the prediction of possible folding pathways and functional intermediates of RNA molecules given their sequences. Utilizing Stem Trace, an interactive visualization tool for RNA structure comparison, analysis of not only the solution ensembles developed by the algorithm, but also the stages of development of each of these solutions, can give strong insight into these folding pathways. The GA allows the incorporation of information from biological experiments, making it possible to test the influence of particular interactions between structural elements on the dynamics of the folding pathway. These methods are used to reveal the folding pathways of the potato spindle tuber viroid (PSTVd) and the host killing mechanism of Escherichia coli plasmid R1, both of which are successfully explored through the combination of the GA and Stem Trace. We also present novel intermediate folds of each molecule, which appear to be phylogenetically supported, as determined by use of the methods described below.

The variability of hop latent viroid as induced upon heat treatment

We have previously shown that heat treatment of hop plants infected by hop latent viroid (HLVd) reduces viroid levels. Here we investigate whether such heat treatment leads to the accumulation of sequence variability in HLVd. We observed a negligible level of mutated variants in HLVd under standard cultivation conditions. In contrast, the heat treatment of hop led to HLVd degradation and, simultaneously, to a significant increase in sequence variations, as judged from temperature gradient-gel electrophoresis analysis and cDNA library screening by DNA heteroduplex analysis. Thirty-one cDNA clones (9.8%) were identified as deviating forms. Sequencing showed mostly the presence of quadruple and triple mutants, suggesting an accumulation of mutations in HLVd during successive replication cycles. Sixty-nine percent of base changes were localised in the left half and 31% in the right half of the secondary structure proposed for this viroid. No mutations were found in the central part of the upper conserved region. A "hot spot" region was identified in a domain known as a "pathogenicity domain" in the group representative, potato spindle tuber viroid. Most mutations are predicted to destabilise HLVd secondary structure. All mutated cDNAs, however, were infectious and evolved into complex progeny populations containing molecular variants maintained at low levels.

Restoration of secondary hairpin II is associated with restoration of infectivity of a non-viable recombinant viroid

Mutagenesis and/or construction of recombinants by exchange of genomic regions between parental molecules constitute powerful tools for the study of viroids. However, a large proportion of such modifications results in molecules, which have lost their infectivity. Such is the case for a recombinant viroid named CECS, obtained by replacing the right half of a citrus exocortis viroid (CEVd) by the same region from chrysanthemum stunt viroid (CSVd). In an effort to recover viable infectious progeny from this recombinant, tomato plants were inoculated with an Agrobacterium strain carrying a dimer of the CECS viroid in positive orientation under the control of the CaMV 35S promoter. About 20% of the plants treated in this way were found to be infected with a replicating viroid, which was further propagated. Sequence analysis of six cloned full-length cDNAs derived from progeny molecules revealed the presence of mutations as compared with the parental CECS sequence. However, only two types of mutations were consistently recovered in all progeny molecules, the addition of a G in a string of four at positions 70-73, a mutation frequently observed in CEVd isolates and mutations leading to the restoration of the correct base pairing in secondary hairpin II. These results show that agro-infection is a suitable technique for the recovery of viable molecules from non-infectious viroid mutants and confirm that the ability to form secondary hairpin II is a prerequisite for viroid infectivity.

Formation of metastable RNA structures by sequential folding during transcription: time-resolved structural analysis of potato spindle tuber viroid (-)-stranded RNA by temperature-gradient gel electrophoresis

A model of functional elements critical for replication and infectivity of the potato spindle tuber viroid (PSTVd) was proposed earlier: a thermodynamically metastable structure containing a specific hairpin (HP II) in the (-)-strand replication intermediate is essential for template activity during (+)-strand synthesis. We present here a detailed kinetic analysis on how PSTVd (-)-strands fold during synthesis by sequential folding into a variety of metastable structures that rearrange only slowly into the structure distribution of the thermodynamic equilibrium. Synthesis of PSTVd (-)-strands was performed by T7-RNA-polymerase; the rate of synthesis was varied by altering the concentration of nucleoside triphosphates to mimic the in vivo synthesis rate of DNA-dependent RNA polymerase II. With dependence on rate and duration of the synthesis, the structure distributions were analyzed by temperature-gradient gel electrophoresis (TGGE). Metastable structures are generated preferentially at low transcription rates--similar to in vivo rates--or at short transcription times at higher rates. Higher transcription rates or longer transcription times lead to metastable structures in low or undetectable amounts. Instead different structures do gradually appear having a more rod-like shape and higher thermodynamic stability, and the thermodynamically optimal rod-like structure dominates finally. It is concluded that viroids are able to use metastable as well as stable structures for their biological functions.

Chemical mapping of co-existing RNA structures

In many cases RNA can assume co-existing or meta-stable structures preventing structure determination by chemical mapping. A novel method is described, by which RNA is modified with dimethyl sulphate without shifting the distribution of different structures. The different structures are then separated in native gel electrophoresis, and structure determination by primer extension can be carried out separately for each structure.

Precisely full length, circularizable, complementary RNA: an infectious form of potato spindle tuber viroid

The replication of many viral and subviral pathogens as well as the amplification of certain cellular genes proceeds via a rolling circle mechanism. For potato spindle tuber (PSTVd) and related viroids, the possible role of a circular (-)strand RNA as a template for synthesis of (+)strand progeny is unclear. Infected plants appear to contain only multimeric linear (-)strand RNAs, and attempts to initiate infection with multimeric (-)PSTVd RNAs generally have failed. To examine critically the infectivity of monomeric (-)strand viroid RNAs, we have developed a ribozyme-based expression system for the production of precisely full length (-)strand RNAs whose termini are capable of undergoing facile circularization in vitro. Mechanical inoculation of tomato seedlings with electrophoretically purified (-)PSTVd RNA led to a small fraction of plants becoming infected whereas parallel assays with an analogous tomato planta macho viroid (-)RNA resulted in a much larger fraction of infected plants. Ribozyme-mediated production of (-)PSTVd RNA in transgenic plants led to the appearance of monomeric circular (-)PSTVd RNA and large amounts of (+)PSTVd progeny. No monomeric circular (-)PSTVd RNA could be detected in naturally infected plants by using either ribonuclease protection or electrophoresis under partially denaturing conditions. Although not a component of the normal replicative pathway, precisely full length (-)PSTVd RNA appears to contain all of the structural and regulatory elements necessary for initiation of viroid replication.

Specific RNA self-cleavage in coconut cadang cadang viroid: potential for a role in rolling circle replication

The rolling circle replication of the small, single-stranded viroid RNAs requires a specific processing reaction to produce monomeric RNAs that are ligated into the final circular form. For avocado sunblotch viroid, peach latent mosaic viroid, and chrysanthemum chlorotic mottle viroid, the hammerhead self-cleavage reaction is considered to provide this processing reaction. We have searched for a similar type of reaction in the 246-nt coconut cadang cadang viroid, the smallest viroid of the 24-member potato spindle tuber viroid (PSTV) group. RNA transcripts prepared from the cloned central or C domain of this viroid self-cleaved specifically after denaturation with methylmercuric hydroxide followed by incubation in the presence of spermidine but in the absence of added magnesium ions. The unique cleavage site was located in the bottom strand of the C domain within a potential hairpin structure that is conserved within members of all three subgroups of the PSTV group of viroids.

Dynamic competition between alternative structures in viroid RNAs simulated by an RNA folding algorithm

The folding pathways of viroid RNAs were studied using computer simulations by the genetic algorithm for RNA folding. The folding simulations were performed for PSTVd RNAs of both polarities, using the wild-type sequence and some previously known mutants with suggested changes in the stable or metastable structures. It is shown that metastable multihairpin foldings in the minus strand replicative intermediates are established due to the specific folding pathway that ensures the absence of the most stable rod-like structure. Simulations of the PSTVd minus strand folding during transcription reveal a metastable hairpin, formed in the left terminal domain region of the PSTVd. Despite high sequence variability, this hairpin is conserved in all known large viroids of both subgroups of PSTVd type, and is presumably necessary to guide the folding of the HPII hairpin which is functional in the minus strand. The folding simulations are able to demonstrate the changes in the balance between metastable and stable structures in mutant PSTVd RNAs. The stable rod-like structure of the circular viroid (+) RNA is also folded via a dynamic folding pathway. Furthermore, the simulations show that intermediate steps in the forced evolution of a shortened PSTVd replicon may be reconstructed by a mechanistic model of different folding pathway requirements in plus- and minus-strand RNAs. Thus the formation of viroid RNA structure strongly depends on dynamics of competition between alternative RNA structures. This also suggests that the replication efficiency of viroid sequences may be estimated by a simulation of the folding process.

Viability and pathogenicity of intersubgroup viroid chimeras suggest possible involvement of the terminal right region in replication

To investigate the structural determinants regulating viroid replication and pathogenicity, we have examined the biological properties of four chimeric viroids containing sequences derived from hop stunt (HSVd) and citrus exocortis (CEVd) viroids. The viability of each chimera--CEHS (CEVd left half + HSVd right half), HSCE (HSVd left half + CEVd right half), CE/HS-TR (CEVd + HSVd right terminal loop), and HS/CE-TR (HSVd + CEVd right terminal loop)--was tested by inoculation onto cucumber and tomato seedlings. Chimeras CEHS and HSCE were not infectious, but CE/HS-TR and HS/CE-TR replicated stably and produced disease symptoms when inoculated onto tomato or cucumber, respectively. Progeny accumulation was reduced 10-fold or more compared to that of CEVd in tomato or HSVd in cucumber. The results suggested that the TR, like the TL and P regions, forms a relatively independent structural unit that contributes to the total function of a viroid. The effect of sequences in the right terminal loop on pathogenicity appears to be indirect, modulating the efficiency of viroid replication (or accumulation) efficiency rather than symptom expression per se.

Peach latent mosaic viroid is locked by a 2',5'-phosphodiester bond produced by in vitro self-ligation

Although some viroid-like satellite RNAs possess self-cleavage and self-ligation activities, we show that the peach latent mosaic viroid (PLMVd) is unique among all known viroids since it also has such activities. These catalytic activities should have important roles in the rolling circle replication of PLMVd. According to this proposed mechanism, self-cleavage of the multimeric strands occurs via hammerhead structures producing monomers possessing 2',3'-cyclic phosphate and 5'-hydroxyl termini. In the most stable predicted secondary structure for PLMVd these two extremities are juxtaposed, in order for self-ligation to occur. To establish the nature of the phosphodiester bond produced by self-ligation, we followed the classical procedure of complete enzymatic RNA hydrolysis coupled with thin layer chromatography fractionation. Using this procedure, we report that the self-ligation of PLMVd transcripts produces almost exclusively the 2',5' isomer (>96%). Primer extension assays also revealed that reverse transcriptase can read througth this 2', 5' linkage, suggesting that it does not prevent further replication of the viroid. Moreover, we have observed that this 2',5' linkage is resistant to the debranching activity contained in nuclear extracts, as well as being capable of preventing further viroid self-cleavage. Thus, if viroids do indeed self-ligate in vivo, the resulting 2', 5'-phosphodiester bond could contribute to the stability of these RNA species. Finally, an analysis of both the sequence and the structural requirements for hammerhead self-cleavage and self-ligation suggests that these two RNA processes may be interrelated. We hypothesize that the intramolecular self-ligation which produces circular conformers may contribute to the circularization step of the rolling circle replication, while the intermolecular non-enzymatic ligation is a potential mechanism for the sequence reassortment of viroids and viroid-like species.

Antiviral ribozymes. New jobs for ancient molecules

Catalytic RNAs are a genetic property not only of some particular viroids or viruses, but also are more common naturally among eukaryotes and even prokaryotes than earlier expected. However, the major interest in ribozymes results from their potential for development of "tailor-made" cDNA constructions designed to be transcribed into catalytic RNAs that will recognize by hybridization and destroy by specific cleavage their cellular or viral RNA targets. The efficiency of an antiviral ribozyme is determined by both the accessibility and sequence conservation of the target region, as well as the design of the ribozyme: its type, size, and composition of flanking sequences; expression rates; and cellular compartment localization. Until now the most frequently selected viral target is the human immunodeficiency virus, where an up to a 10(4)-fold inhibition in its progeny production has been achieved. Although the first generation ribozymes focused on improvements in basic design and expression rates, more recently the efficiency of antiviral catalytic activity has been increased by employing polyribozymes and/or multitarget ribozymes, as well as special constructions to enhance the cellular co-compartmentation of the ribozyme with its viral RNA target.

Plant pathogenic RNAs and RNA catalysis

The rolling circle replication of small circular plant pathogenic RNAs requires a processing step to convert multimeric intermediates to monomers which are then circularized. Eleven such RNAs are known so far, two are viroids, one is viroid-like and the remainder are satellite RNAs dependent on a helper virus for replication. The processing step is RNA-catalysed in all cases, at least in vitro. All plus forms of these RNAs self-cleave via the hammerhead structure whereas only eight of the minus RNAs self-cleave, five via the hammerhead structure and three via the hairpin structure. There are about 20 other viroids where the processing mechanism has yet to be determined but they are likely candidates for a new type of self-cleavage reaction which is predicted to be conserved in all these viroids. Hepatitis delta RNA is the only circular pathogenic RNA known to self-cleave in the animal kingdom. It is feasible that more single-stranded circular pathogenic RNAs are waiting to be discovered and these could be prospective for new types of self-cleavage reactions.

RNA structure and the regulation of gene expression

RNA secondary and tertiary structure is involved in post-transcriptional regulation of gene expression either by exposing specific sequences or through the formation of specific structural motifs. An overview of RNA secondary and tertiary structures known from biophysical studies is followed by a review of examples of the elements of RNA processing, mRNA stability and translation of the messenger. These structural elements comprise sense-antisense double-stranded RNA, hairpin and stem-loop structures, and more complex structures such as bifurcations, pseudoknots and triple-helical elements. Metastable structures formed during RNA folding pathway are also discussed. The examples presented are mostly chosen from plant systems, plant viruses, and viroids. Examples from bacteria or fungi are discussed only when unique regulatory properties of RNA structures have been elucidated in these systems.

Viroids proper can be distinguished from hammerhead viroids and satellite RNAs through their dinucleotide composition

G + C-rich viroids proper exhibit a unique dinucleotide composition in that AU and UA are much less frequent than expected. Thus, evaluation of the dinucleotide pattern allows a quick discrimination between viroids proper and similar RNAs from plants, such as hammerhead-containing viroids, satellite RNAs, and defective interfering RNAs. In addition to sequence alignment, this method might be useful for the classification of a newly found small RNA replicon.