RNA intermediates in potato spindle tuber viroid replication

Resistance of the CRISPR-Cas13a Gene-Editing System to Potato Spindle Tuber Viroid Infection in Tomato and Nicotiana benthamiana

Gene-editing technology, specifically the CRISPR-Cas13a system, has shown promise in breeding plants resistant to RNA viruses. This system targets RNA and, theoretically, can also combat RNA-based viroids. To test this, the CRISPR-Cas13a system was introduced into tomato plants via transient expression and into Nicotiana benthamiana through transgenic methods, using CRISPR RNAs (crRNAs) targeting the conserved regions of both sense and antisense genomes of potato spindle tuber viroid (PSTVd). In tomato plants, the expression of CRISPR-Cas13a and crRNAs substantially reduced PSTVd accumulation and alleviated disease symptoms. In transgenic N. benthamiana plants, the PSTVd levels were lower as compared to wild-type plants. Several effective crRNAs targeting the PSTVd genomic RNA were also identified. These results demonstrate that the CRISPR-Cas13a system can effectively target and combat viroid RNAs, despite their compact structures.

New Insights into Hop Latent Viroid Detection, Infectivity, Host Range, and Transmission

Hop latent viroid (HLVd), a subviral pathogen from the family Pospiviroidae, is a major threat to the global cannabis industry and is the causative agent for "dudding disease". Infected plants can often be asymptomatic for a period of growth and then develop symptoms such as malformed and yellowing leaves, as well as stunted growth. During flowering, HLVd-infected plants show reduced levels of valuable metabolites. This study was undertaken to expand our basic knowledge of HLVd infectivity, transmission, and host range. HLVd-specific primers were used for RT-PCR detection in plant samples and were able to detect HLVd in as little as 5 picograms of total RNA. A survey of hemp samples obtained from a diseased production system proved sole infection of HLVd (72%) with no coexistence of hop stunt viroid. HLVd was infectious through successive passage assays using a crude sap or total RNA extract derived from infected hemp. HLVd was also highly transmissible through hemp seeds at rates of 58 to 80%. Host range assays revealed new hosts for HLVd: tomato, cucumber, chrysanthemum, Nicotiana benthamiana, and Arabidopsis thaliana (Col-0). Sequence analysis of 77 isolates revealed only 3 parsimony-informative sites, while 10 sites were detected among all HLVd isolates available in the GenBank. The phylogenetic relationship among HLVd isolates allowed for inferring two major clades based on the genetic distance. Our findings facilitate further studies on host-viroid interaction and viroid management.

Viroids: Non-Coding Circular RNAs Able to Autonomously Replicate and Infect Higher Plants

Viroids are a unique type of infectious agent, exclusively composed of a relatively small (246-430 nt), highly base-paired, circular, non-coding RNA. Despite the small size and non-coding nature, the more-than-thirty currently known viroid species infectious of higher plants are able to autonomously replicate and move systemically through the host, thereby inducing disease in some plants. After recalling viroid discovery back in the late 60s and early 70s of last century and discussing current hypotheses about their evolutionary origin, this article reviews our current knowledge about these peculiar infectious agents. We describe the highly base-paired viroid molecules that fold in rod-like or branched structures and viroid taxonomic classification in two families, Pospiviroidae and Avsunviroidae, likely gathering nuclear and chloroplastic viroids, respectively. We review current knowledge about viroid replication through RNA-to-RNA rolling-circle mechanisms in which host factors, notably RNA transporters, RNA polymerases, RNases, and RNA ligases, are involved. Systemic movement through the infected plant, plant-to-plant transmission and host range are also discussed. Finally, we focus on the mechanisms of viroid pathogenesis, in which RNA silencing has acquired remarkable importance, and also for the initiation of potential biotechnological applications of viroid molecules.

Viroids as a Tool to Study RNA-Directed DNA Methylation in Plants

Viroids are plant pathogenic, circular, non-coding, single-stranded RNAs (ssRNAs). Members of the Pospiviroidae family replicate in the nucleus of plant cells through double-stranded RNA (dsRNA) intermediates, thus triggering the host’s RNA interference (RNAi) machinery. In plants, the two RNAi pillars are Post-Transcriptional Gene Silencing (PTGS) and RNA-directed DNA Methylation (RdDM), and the latter has the potential to trigger Transcriptional Gene Silencing (TGS). Over the last three decades, the employment of viroid-based systems has immensely contributed to our understanding of both of these RNAi facets. In this review, we highlight the role of Pospiviroidae in the discovery of RdDM, expound the gradual elucidation through the years of the diverse array of RdDM’s mechanistic details and propose a revised RdDM model based on the cumulative amount of evidence from viroid and non-viroid systems.

Current view and perspectives in viroid replication

Viroids are single-stranded circular noncoding RNAs that infect plants. The noncoding nature indicates that viroids must harness their RNA genomes to redirect host machinery for infection. Therefore, the viroid model provides invaluable opportunities for delineating fundamental principles of RNA structure-function relationships and for dissecting the composition and mechanism of RNA-related cellular machinery. There are two viroid families, Pospiviroidae and Avsunviroidae. Members of both families replicate via the RNA-based rolling-circle mechanism with some variations. Viroid replication is generally divided into three steps: transcription, cleavage, and ligation. Decades of studies have uncovered numerous viroid RNA structures with a regulatory role in replication and multiple enzymes critical for the three replication steps. This review discusses these findings and highlights the latest discoveries. Future studies will continue to elucidate regulatory factors and mechanism of host machinery exploited by viroids and provide new insights into host-viroid interactions in the context of pathogenesis.

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.

Evaluation of Disease Severity and Global Transcriptome Response Induced by Citrus bark cracking viroid, Hop latent viroid, and Their Co-Infection in Hop (Humulus lupulus L.)

Viroids are small non-capsidated, single-stranded, covalently-closed circular noncoding RNA replicons of 239-401 nucleotides that exploit host factors for their replication, and some cause disease in several economically important crop plants, while others appear to be benign. The proposed mechanisms of viroid pathogenesis include direct interaction of the genomic viroid RNA with host factors and post-transcriptional or transcriptional gene silencing via viroid-derived small RNAs (vd-sRNAs) generated by the host defensive machinery. Humulus lupulus (hop) plants are hosts to several viroids among which Hop latent viroid (HLVd) and Citrus bark cracking viroid (CBCVd) are attractive model systems for the study of viroid-host interactions due to the symptomless infection of the former and severe symptoms induced by the latter in this indicator host. To better understand their interactions with hop plant, a comparative transcriptomic analysis based on RNA sequencing (RNA-seq) was performed to reveal the transcriptional alterations induced as a result of single HLVd and CBCVd infection in hop. Additionally, the effect of HLVd on the aggressiveness of CBCVd that underlies severe stunting in hop in a mixed infection was studied by transcriptomic analysis. Our analysis revealed that CBCVd infection resulted in dynamic changes in the activity of genes as compared to single HLVd infection and their mixed infection. The differentially expressed genes that are involved in defense, phytohormone signaling, photosynthesis and chloroplasts, RNA regulation, processing and binding; protein metabolism and modification; and other mechanisms were more modulated in the CBCVd infection of hop. Nevertheless, Gene Ontology (GO) classification and pathway enrichment analysis showed that the expression of genes involved in the proteolysis mechanism is more active in a mixed infection as compared to a single one, suggesting co-infecting viroids may result in interference with host factors more prominently. Collectively, our results provide a deep transcriptome of hop and insight into complex single HLVd, CBCVd, and their coinfection in hop-plant interactions.

Low Temperature Treatment Affects Concentration and Distribution of Chrysanthemum Stunt Viroid in Argyranthemum

Chrysanthemum stunt viroid (CSVd) can infect Argyranthemum and cause serious economic loss. Low temperature treatment combined with meristem culture has been applied to eradicate viroids from their hosts, but without success in eliminating CSVd from diseased Argyranthemum. The objectives of this work were to investigate (1) the effect of low temperature treatment combined with meristem culture on elimination of CSVd, (2) the effect of low temperature treatment on CSVd distribution pattern in shoot apical meristem (SAM), and (3) CSVd distribution in flowers and stems of two infected Argyranthemum cultivars. After treatment with low temperature combined with meristem tip culture, two CSVd-free plants were found in 'Border Dark Red', but none in 'Yellow Empire'. With the help of in situ hybridization, we found that CSVd distribution patterns in the SAM showed no changes in diseased 'Yellow Empire' following 5°C treatment, compared with non-treated plants. However, the CSVd-free area in SAM was enlarged in diseased 'Border Dark Red' following prolonged 5°C treatment. Localization of CSVd in the flowers and stems of infected 'Border Dark Red' and 'Yellow Empire' indicated that seeds could not transmit CSVd in these two cultivars, and CSVd existed in phloem. Results obtained in the study contributed to better understanding of the distribution of CSVd in systemically infected plants and the combination of low temperature treatment and meristem tip culture for production of viroid-free plants.

Discovery of replicating circular RNAs by RNA-seq and computational algorithms

Replicating circular RNAs are independent plant pathogens known as viroids, or act to modulate the pathogenesis of plant and animal viruses as their satellite RNAs. The rate of discovery of these subviral pathogens was low over the past 40 years because the classical approaches are technical demanding and time-consuming. We previously described an approach for homology-independent discovery of replicating circular RNAs by analysing the total small RNA populations from samples of diseased tissues with a computational program known as progressive filtering of overlapping small RNAs (PFOR). However, PFOR written in PERL language is extremely slow and is unable to discover those subviral pathogens that do not trigger in vivo accumulation of extensively overlapping small RNAs. Moreover, PFOR is yet to identify a new viroid capable of initiating independent infection. Here we report the development of PFOR2 that adopted parallel programming in the C++ language and was 3 to 8 times faster than PFOR. A new computational program was further developed and incorporated into PFOR2 to allow the identification of circular RNAs by deep sequencing of long RNAs instead of small RNAs. PFOR2 analysis of the small RNA libraries from grapevine and apple plants led to the discovery of Grapevine latent viroid (GLVd) and Apple hammerhead viroid-like RNA (AHVd-like RNA), respectively. GLVd was proposed as a new species in the genus Apscaviroid, because it contained the typical structural elements found in this group of viroids and initiated independent infection in grapevine seedlings. AHVd-like RNA encoded a biologically active hammerhead ribozyme in both polarities, and was not specifically associated with any of the viruses found in apple plants. We propose that these computational algorithms have the potential to discover novel circular RNAs in plants, invertebrates and vertebrates regardless of whether they replicate and/or induce the in vivo accumulation of small RNAs.

Molecular biology of viroid-host interactions and disease control strategies

Viroids are single-stranded, covalently closed, circular, highly structured noncoding RNAs that cause disease in several economically important crop plants. They replicate autonomously and move systemically in host plants with the aid of the host machinery. In addition to symptomatic infections, viroids also cause latent infections where there is no visual evidence of infection in the host; however, transfer to a susceptible host can result in devastating disease. While there are non-hosts for viroids, no naturally occurring durable resistance has been observed in most host species. Current effective control methods for viroid diseases include detection and eradication, and cultural controls. In addition, heat or cold therapy combined with meristem tip culture has been shown to be effective for elimination of viroids for some viroid-host combinations. An understanding of viroid-host interactions, host susceptibility, and non-host resistance could provide guidance for the design of viroid-resistant plants. Efforts to engineer viroid resistance into host species have been underway for several years, and include the use of antisense RNA, antisense RNA plus ribozymes, a dsRNase, and siRNAs, among others. The results of those efforts and the challenges associated with creating viroid resistant plants are summarized in this review.

Mutational analysis of potato spindle tuber viroid reveals complex relationships between structure and infectivity

Viroids are single-stranded, covalently closed circular RNA pathogens that can be isolated from certain higher plants afflicted with specific diseases. Their small size (246-375 nucleotides; M(r) 0.8-1.3 x 10(5)) and ability to replicate autonomously make viroids a unique model system in which to study the relationships between the structure of an RNA and its biological function. The demonstrated infectivity of certain cloned viroid cDNAs allows the use of site-specific mutagenesis techniques to probe structure-function relationships suggested by comparative sequence analysis. Several site-specific mutations that disrupt base pairing in either the native structure or secondary hairpin I destroyed the ability of potato spindle tuber viroid cDNA to initiate infection. Alterations in the terminal loops of the native structure also abolished cDNA infectivity. One pseudorevertant, a mutant cDNA containing compensating changes that restore base pairing in the native structure, was marginally infectious; a second pseudorevertant in which base pairing was restored within the stem of secondary hairpin I was not infectious. The behavior of these mutants dramatically demonstrates the effect of remarkably small structural changes on viroid infectivity and emphasizes the importance of the conserved rod-like native structure for viroid function.

A viroid RNA with a specific structural motif inhibits chloroplast development

Peach latent mosaic viroid (PLMVd) is a chloroplast-replicating RNA that propagates in its natural host, peach (Prunus persica), as a complex mixture of variants, some of which are endowed with specific structural and pathogenic properties. This is the case of variant PC-C40, with an insertion of 12 to 13 nucleotides that folds into a hairpin capped by a U-rich loop, which is responsible for an albino-variegated phenotype known as peach calico (PC). We have applied a combination of ultrastructural, biochemical, and molecular approaches to dissect the pathogenic effects of PC-C40. Albino sectors of leaves infected with variant PC-C40 presented palisade cells that did not completely differentiate into a columnar layer and altered plastids with irregular shape and size and with rudimentary thylakoids, resembling proplastids. Furthermore, impaired processing and accumulation of plastid rRNAs and, consequently, of the plastid translation machinery was observed in the albino sectors of leaves infected with variant PC-C40 but not in the adjacent green areas or in leaves infected by mosaic-inducing or latent variants (including PC-C40Delta, in which the 12- to 13-nucleotide insertion was deleted). Protein gel blot and RT-PCR analyses showed that the altered plastids support the import of nucleus-encoded proteins, including a chloroplast RNA polymerase, the transcripts of which were detected. RNA gel blot and in situ hybridizations revealed that PLMVd replicates in the albino leaf sectors and that it can invade the shoot apical meristem and induce alterations in proplastids, bypassing the RNA surveillance system that restricts the entry of a nucleus-replicating viroid and most RNA viruses. Therefore, a non-protein-coding RNA with a specific structural motif can interfere with an early step of the chloroplast developmental program, leading ultimately to an albino-variegated phenotype resembling that of certain variegated mutants in which plastid rRNA maturation is also impaired. Our results highlight the potential of viroids for further dissection of RNA trafficking and pathogenesis in plants.

Discovering viroids--a personal perspective

During 1970 and 1971, I discovered that a devastating disease of potato plants is not caused by a virus, as had been assumed, but by a new type of subviral pathogen, the viroid. Viroids are so small--one fiftieth of the size of the smallest viruses--that many scientists initially doubted their existence. We now know that viroids cause many damaging diseases of crop plants. Fortunately, new methods that are based on the unique properties of viroids now promise effective control.

Arabidopsis thaliana has the enzymatic machinery for replicating representative viroid species of the family Pospiviroidae

Viroids, subviral noncoding RNAs, replicate, move, and incite diseases in plants. Viroids replicate through a rolling-circle mechanism in which oligomeric RNAs of one or both polarities are cleaved and ligated into the circular monomers. Attempts to transmit viroids to Arabidopsis have failed for unknown reasons. To tackle this question, Arabidopsis was transformed with cDNAs expressing dimeric (+) transcripts of representative species of the families Pospiviroidae and Avsunviroidae, which replicate in the nucleus and the chloroplast, respectively. Correct processing to the circular (+) monomers was always observed, demonstrating that Arabidopsis has the appropriate RNase and RNA ligase. Northern blot hybridization also revealed the multimeric (-) RNAs of Citrus exocortis viroid and Hop stunt viroid (HSVd) of the family Pospiviroidae, but not of Avocado sunblotch viroid of the family Avsunviroidae, showing that the first RNA-RNA transcription of the rolling-circle mechanism occurs in Arabidopsis for the two nuclear viroids and that their multimeric (-) RNAs remain unprocessed as in typical hosts. Moreover, transgenic Arabidopsis expressing HSVd dimeric (-) transcripts accumulated the circular (+) monomers, although at low levels, together with the unprocessed primary transcript that served as the template for the second RNA-RNA transcription. Agroinoculation of Arabidopsis with the dimeric (+) Citrus exocortis viroid, HSVd, and Coleus blumei viroid 1 cDNAs showed that these viroids could not move to distal plant parts, in contrast with the situation observed in their experimental hosts. Therefore, deficiencies in movement or low replication appear to be the factors limiting infectivity of some viroids in Arabidopsis.

Differential subnuclear localization of RNA strands of opposite polarity derived from an autonomously replicating viroid

The wide variety of RNAs produced in the nucleus must be localized correctly to perform their functions. However, the mechanism of this localization is poorly understood. We report here the differential subnuclear localization of RNA strands of opposite polarity derived from the replicating Potato spindle tuber viroid (PSTVd). During replication, (+)- and (-)-strand viroid RNAs are produced. We found that in infected cultured cells and plants, the (-)-strand RNA was localized in the nucleoplasm, whereas the (+)-strand RNA was localized in the nucleolus as well as in the nucleoplasm with distinct spatial patterns. Furthermore, the presence of the (+)-PSTVd in the nucleolus caused the redistribution of a small nucleolar RNA. Our results support a model in which (1) the synthesis of the (-)- and (+)-strands of PSTVd RNAs occurs in the nucleoplasm, (2) the (-)-strand RNA is anchored in the nucleoplasm, and (3) the (+)-strand RNA is transported selectively into the nucleolus. Our results imply that the eukaryotic cell has a machinery that recognizes and localizes the opposite strands of an RNA, which may have broad ramifications in the RNA regulation of gene expression and the infection cycle of pathogenic RNAs and in the development of RNA-based methods to control gene expression as well as pathogen infection.

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.

An extra nucleotide in the consensus catalytic core of a viroid hammerhead ribozyme: implications for the design of more efficient ribozymes

Hammerhead ribozymes catalyze self-cleavage of oligomeric RNAs generated in replication of certain viroid and viroid-like RNAs. Previous studies have defined a catalytic core conserved in most natural hammerheads, but it is still unknown why some present deviations from the consensus. We have addressed this issue in chrysanthemum chlorotic mottle viroid (CChMVd), whose (+) hammerhead has an extra A (A10) between the conserved A9 and the quasi-conserved G10.1. Effects of insertions at this position on hammerhead kinetics have not hitherto been examined. A10 caused a moderate decrease of the trans-cleaving rate constant with respect to the CChMVd (+) hammerhead without this residue, whereas A10-->C and A10-->G substitutions had major detrimental effects, likely because they favor catalytically inactive foldings. By contrast, A10-->U substitution induced a 3-4-fold increase of the rate constant, providing an explanation for the extra U10 present in two natural hammerheads. Because A10 also occupies a singular and indispensable position in the global CChMVd conformation, as revealed by bioassays, these results show that some hammerheads deviate from the consensus due to the involvement of certain residues in critical function(s) other than self-cleavage. Incorporation of the extra U10 into a model hammerhead also caused a similar increase in the rate constant, providing data for a deeper understanding of the hammerhead structural requirements and for designing more efficient ribozymes.

Characterization of the initiation sites of both polarity strands of a viroid RNA reveals a motif conserved in sequence and structure

Viroids replicate through a rolling-circle mechanism in which the infecting circular RNA and its complementary (-) strand are transcribed. The precise site at which transcription starts was investigated for the avocado sunblotch viroid (ASBVd), the type species of the family of viroids with hammerhead ribozymes. Linear ASBVd (+) and (-) RNAs begin with a UAAAA sequence that maps to similar A+U-rich terminal loops in their predicted quasi-rod-like secondary structures. The sequences around the initiation sites of ASBVd, which replicates and accumulates in the chloroplast, are similar to the promoters of a nuclear-encoded chloroplastic RNA polymerase (NEP), supporting the involvement of an NEP-like activity in ASBVd replication. Since RNA folding appears to be kinetically determined, the specific location of both ASBVd initiation sites provides a mechanistic insight into how the nascent ASBVd strands may fold in vivo. The approach used here, in vitro capping and RNase protection assays, may be useful for investigating the initiation sites of other small circular RNA replicons.

Avsunviroidae family: viroids containing hammerhead ribozymes

This chapter focuses on the second viroid family, whose members are also referred to as hammerhead viroids, taking into account their most outstanding feature. If the word “small” is the first to come to mind when considering viroids, perhaps the second word is “hammerhead,” because this class of ribozymes, which because of its structural simplicity has an enormous biotechnological potential, is described in avocado sunblotch viroid (ASBVd) as well as in a viroid-like satellite RNA. The most outstanding feature of the Avsunviroidae members is their potential to adopt hammerhead structures in both polarity strands and to self-cleave in vitro accordingly. Viroids differ from viruses not only in their genome size but also in other fundamental aspects, prominent among which is the lack of messenger activity of both viroid RNAs and their complementary strands.

Transgenic potato expressing a double-stranded RNA-specific ribonuclease is resistant to potato spindle tuber viroid

We have produced transgenic potato lines expressing the yeast-derived double-stranded RNA-specific ribonuclease pac1. Five lines of pac1 potato (Solanum tuberosum L., cultivar Russet Burbank) challenged with potato spindle tuber viroid (PSTVd) suppressed PSTVd infection and accumulation. All of the progeny potato tubers produced by resistant plants were also free of PSTVd. Because the pac1 gene product digested PSTVd in vitro, double-stranded regions in PSTVd molecule and/or replicative intermediates may be targeted by pac1 gene product in the transgenic potato plant.

A 451-nucleotide circular RNA from cherry with hammerhead ribozymes in its strands of both polarities

The sequence of 451 nucleotides of a cherry small circular RNA (csc RNA1) associated with a cherry disease has been determined. Both csc RNA1 and its complementary strand can form hammerhead structures similar to those found previously in other plant and animal small RNAs. In the branched secondary structure of lowest free energy of csc RNA1, the sequences involved in the hammerhead structures, which comprise approximately one-fourth of this RNA, are found opposite each other, forming part of a rod-like segment. Plus- and minus-strand full-length transcripts of csc RNA1 self-cleaved during transcription and after purification, as predicted by the hammerhead structures, which are stable and very probably act as single hammerhead structures. The minus-strand hammerhead structure of csc RNA1 is exceptional in having a central loop with only 11 conserved nucleotides, a situation previously observed in only one other natural hammerhead structure. Both hammerhead structures of csc RNA1 are also peculiar in having an A instead of a C preceding the self-cleavage sites. The in vivo concentration of the plus strand of csc RNA1 is only slightly higher than that of its complementary strand, and significant fractions of both strands are extracted from the tissue in the form of a complex. csc RNA1 has sequence similarities to viroids and especially to some viroid-like satellite RNAs; they also share some characteristics of their corresponding hammerhead structures with these satellite RNAs. These observations, together with the association in symptomatic tissue of csc RNA1 with a set of presumably viral double-stranded RNAs, suggest that csc RNA1 is a new viroid-like satellite RNA.

Mexican papita viroid: putative ancestor of crop viroids

The potato spindle tuber disease was first observed early in the 20th century in the northeastern United States and shown, in 1971, to be incited by a viroid, potato spindle tuber viroid (PSTVd). No wild-plant PSTVd reservoirs have been identified; thus, the initial source of PSTVd infecting potatoes has remained a mystery. Several variants of a novel viroid, designated Mexican papita viroid (MPVd), have now been isolated from Solanum cardiophyllum Lindl. (papita güera, cimantli) plants growing wild in the Mexican state of Aguascalientes. MPVd's nucleotide sequence is most closely related to those of the tomato planta macho viroid (TPMVd) and PSTVd. From TPMVd, MPVd may be distinguished on the basis of biological properties, such as replication and symptom formation in certain differential hosts. Phylogenetic and ecological data indicate that MPVd and certain viroids now affecting crop plants, such as TPMVd, PSTVd, and possibly others, have a common ancestor. We hypothesize that commercial potatoes grown in the United States have become viroid-infected by chance transfer of MPVd or a similar viroid from endemically infected wild solanaceous plants imported from Mexico as germplasm, conceivably from plants known to have been introduced from Mexico to the United States late in the 19th century in efforts to identify genetic resistance to the potato late blight fungus, Phytophthora infestans.

Origin and evolution of viroids and viroid-like satellite RNAs

Viroids, the smallest and simplest agents of infectious disease, cause a number of economically important diseases of crop plants. Present evidence indicates that most of these diseases originated recently (in the 20th century) by chance transfer of viroids from endemically infected wild plants or by use of viroid-infected germplasm during plant breeding. Modern agricultural practices, such as widespread monoculture of genetically identical plants, and worldwide distribution of planting material, has made it possible for the pathogens to maintain themselves in the crop plants and to conquer new territories. Phylogenetic analysis of their nucleotide sequences indicates that viroids and satellite RNAs represent a monophyletic group, with all but the two self-cleaving viroids forming one cluster and the satellite RNAs another. The two self-cleaving viroids are phylogenetically distant from either cluster; they may represent ancestral forms. Results from site-directed mutagenesis experiments indicate that, upon exposure to selective pressures, viroids can evolve extremely rapidly, with another, fitter, component of the quasi-species often becoming dominant within days or weeks. This extreme plasticity of their nucleotide sequences establishes viroids as the most rapidly evolving biological system known.

Replication of avocado sunblotch viroid: evidence for a symmetric pathway with two rolling circles and hammerhead ribozyme processing

The structure of a series of RNAs extracted from avocado infected by the 247-nt avocado sunblotch viroid (ASBVd) was investigated. The identification of multistranded complexes containing circular ASBVd RNAs of (+) and (-) polarity suggests that replication of ASBVd proceeds through a symmetric pathway with two rolling circles where these two circular RNAs are the templates. This is in contrast to the replication of potato spindle tuber viroid and probably of most of its related viroids, which proceeds via an asymmetric pathway where circular (+)-strand and linear multimeric (-)-strand RNAs are the two templates. Linear (+) and (-) ASBVd RNAs of subgenomic length (137 nt and about 148 nt, respectively) and one linear (+)-strand ASBVd RNA of supragenomic length (383-384 nt) were also found in viroid-infected tissue. The two linear (+)-strand RNAs have the same 5'- and 3'-terminal sequences, with the supragenomic species being a fusion product of the monomeric and subgenomic (+)-strand ASBVd RNAs. The 3' termini of these two (+)-strand molecules, which at least in the subgenomic RNA has an extra nontemplate cytidylate residue, could represent sites of either premature termination of the (+)-strands or specific initiation of the (-)-strands. The 5' termini of sub- and supragenomic (+)-strand and the 5' terminus of the subgenomic (-)-strand ASBVd RNA are identical to those produced in the in vitro self-cleavage reactions of (+) and (-) dimeric ASBVd RNAs, respectively. These observations strongly suggest that the hammerhead structures which mediate the in vitro self-cleavage reactions are also operative in vivo.

The RNAs of hepatitis delta virus are copied by RNA polymerase II in nuclear homogenates

Human hepatitis delta virus has a single-stranded circular RNA genome that replicates by RNA-directed RNA synthesis. The virus encodes only a single protein, the delta antigen, which both is small (22 kDa) and lacks sequence homology to known RNA polymerases, suggesting that the virus employs a cellular polymerase for replication. Consistent with this suggestion, we have used homogenized nuclei from a human hepatoma cell line, HepG2, to demonstrate RNA-directed RNA synthesis from both genomic hepatitis delta virus RNA and its complement, the antigenomic RNA. RNA polymerase II was responsible for this transcription because the reaction was inhibited both by low doses of alpha-amanitin and by a monoclonal antibody specific for polymerase II. In addition, it was found that the majority of the RNA products were processed, presumably by self-cleavage and self-ligation, to produce covalently closed circular molecules.

Subviral pathogens of plants: the viroids

Research during the last 15 years has conclusively shown that viroids are not only fundamentally different from viruses at the molecular level, but that they are most likely not directly related to viruses in an evolutionary sense. Today, viroids are among the most thoroughly studied biological macromolecules. Their molecular structures have been elucidated to a large extent, but much needs to be learned regarding the correlation between molecular structure and biological function. The availability of the tools of recombinant DNA technology in viroid research promises rapid progress in these areas of inquiry.

Structure of viroid replicative intermediates: physico-chemical studies on SP6 transcripts of cloned oligomeric potato spindle tuber viroid

The structure and structural transitions of transcripts of cloned oligomeric viroid were studied in physico-chemical experiments and stability calculations. Transcripts of (+) and (-) polarity, from unit up to sixfold length, were synthesized from DNA clones of the potato spindle tuber viroid (PSTV) with the SP6 transcription system. Their structural properties were investigated by optical denaturation curves, high performance liquid chromatography (HPLC), electron microscopy, sedimentation-diffusion equilibrium and velocity sedimentation. Secondary structures of the RNAs and theoretical denaturation curves were calculated using an energy optimization program. The secondary structure of lowest free energy for unit length and oligomeric transcripts is a rod-like structure similar to that of the mature circular viroids. When this structure is used as a model for calculations, there is a large degree of agreement between the theoretical and the experimental denaturation curves. At high temperatures, however, (+) strand transcripts exhibited a transition which was more stable than expected from the calculations or than was known from curves of mature viroids. This transition arises from a rearrangement of the central conserved region of viroids to a helical region of 28 stable base pairs either intermolecularly leading to bimolecular complexes, or intramolecularly giving rise to a branched secondary structure. The rearrangement could be detected by electron microscopy, HPLC, and analytical ultracentrifugation. The helical region serves to divide up the oligomeric (+) strand into structural units which may be recognized by cleavage and ligation enzymes which process the oligomeric intermediates to circular mature viroids.

Viroids and virusoids are related to group I introns

Group I introns are found in nuclear rRNA genes, mitochondrial mRNA and rRNA genes, and chloroplast tRNA genes. The hallmarks of this intron class are a 16-nucleotide consensus sequence and three sets of complementary sequences. The viroids (circular pathogenic plant RNAs) and the virusoids (plant satellite RNAs) also contain the consensus sequence and the three sets of complementary bases. Pairing of the complementary bases would generate a viroid structure resembling a group I intron, which might be stabilized in vivo through interactions with proteins. The Tetrahymena self-splicing rRNA intron further has sequences homologous with regions of potato spindle tuber viroid associated with the severity of viroid symptoms.

Self-cleavage of plus and minus RNA transcripts of avocado sunblotch viroid

Self-cleavage of both plus and minus RNA transcripts of the 247-residue avocado sunblotch viroid (ASBV), prepared from tandem dimeric cDNA clones, occurs specifically at two sites in each transcript to give monomeric plus and minus species. The cleavage reaction occurs both during transcription and on incubation of purified transcripts at pH 8 and 37 degrees C in the presence of magnesium ions to give a 3'-terminal 2',3'-cyclic phosphate and a 5'-terminal hydroxyl group. Although the self-cleavage occurs at different sites in the ASBV molecule for the plus and minus species, very similar secondary structures with high sequence homology can be drawn at each site. The results are considered to provide further evidence that ASBV is replicated in vivo by a rolling circle mechanism involving non-enzymic cleavage of high molecular weight RNA precursors of ASBV.

Viroid processing: a model involving the central conserved region and hairpin I

A model is proposed for the processing of oligomeric viroid replication intermediates into monomeric, circular progeny viroids. The model identifies a thermodynamically extremely stable base-paired configuration that partially or completely dimeric, as well as higher, viroid oligomers can assume and postulates that this structure, which involves structural features common to all viroids (the central conserved region and secondary hairpin I), is essential for precise cleavage and ligation. The model explains why recombinant plasmids containing tandem repeats of two or more viroid sequence equivalents are highly infectious when inoculated into viroid-susceptible plants, why certain plasmids containing partially duplicated viroid-specific inserts are less infectious, and why plasmids containing monomeric inserts are noninfectious or at best marginally infectious. The model also accounts for the fact that vector-derived sequences on either or both sides of the viroid sequence(s) of a restriction fragment are precisely excised and are lacking in progeny viroids.

Comparison of multimeric plus and minus forms of viroids and virusoids

In order to investigate the mechanism of replication of viroids and virusoids, we have compared the replication intermediates of three members of each group in nucleic acid extracts of infected plants. Viroids were avocado sunblotch viroid (ASBV), citrus exocortis viroid (CEV) and coconut cadang cadang viroid (CCCV). Virusoids were from velvet tobacco mottle virus (VTMoV), solanum nodiflorum mottle virus (SNMV) and lucerne transient streak virus (LTSV). Analysis of intermediates was by the Northern hybridization technique with single-strand DNA and RNA probes prepared from recombinant DNA clones. The results obtained are discussed in terms of current models of viroid and virusoid replication.The plus RNA species consisted of an oligomeric series up to decamers based on the unit of full-length viroid or virusoid, which was always the major component, except for CEV where only monomer and dimer species were found. In the case of ASBV and the virusoids of VTMoV and SNMV, a minor, multimeric series of components (X-bands) was superimposed on the main oligomeric series.The complementary minus species proved more difficult to detect and characterise, with each viroid and virusoid exhibiting a unique pattern on Northern hybridization. However, they all had greater than unit-length minus species. In addition, minus species analogous to the plus X-bands were found in ASBV and CEV. The experimental difficulties encountered in this work are discussed in terms of the problem of detecting minus species by Northern analysis in the presence of excess complementary plus species.

Domains in viroids: evidence of intermolecular RNA rearrangements and their contribution to viroid evolution

On the basis of sequence homology a model is proposed for five structural and functional domains in viroids. These domains include (i) a conserved central region capable of forming two alternative structures that may regulate two phases of the viroid replication cycle, (ii) a region associated with pathogenicity, (iii) a domain with high sequence variability, (iv and v) two terminal domains that are interchangeable between viroids. That the evolution of viroids has involved RNA rearrangements of domains is supported by the partial duplication of coconut cadang cadang viroid, which arises de novo during each infection. Similar RNA rearrangements have been established for animal viral defective interfering RNAs, which arise by some form of discontinuous transcription. This mechanism could account for the origin of viroids and also RNA viruses, whereby modules of genetic information may have undergone repeated exchange between RNA pathogens and the RNA of their hosts.

2' phosphomonoester, 3'-5' phosphodiester bond at a unique site in a circular viral RNA

Solanum nodiflorum mottle virus (SNMV) RNA2 is a single-stranded, covalently closed circular molecule. RNase T2 or nuclease P1 digests of this RNA contain a minor nucleotide of unusual chromatographic and electrophoretic mobility. This nucleotide is resistant to further digestion by T2 or P1 ribonucleases, or by alkali, but is sensitive to venom phosphodiesterase digestion. Alkaline phosphatase digestion yields a product which is RNase T2 and P1 sensitive. The products of these various digests show that the minor nucleotide is a ribonuclease-resistant dinucleotide carrying a 2' phosphomonoester group with the core structure C2'p3'p5'A. This dinucleotide is found in a unique RNase T1 product of SNMV RNA2, thus establishing a unique location in the sequence for the 2' phosphomonoester group at residue 49. Identical results have been obtained with a second related virus. The phosphomonoester group probably results from the RNA ligation event by which the molecules were circularised.

Synthesis of (+) and (-) RNA molecules of potato spindle tuber viroid (PSTV) in isolated nuclei and its impairment by transcription inhibitors

Transcription studies with highly purified potato cell nuclei in combination with a 'transcription-hybridization analysis' unequivocally demonstrate that the nucleus is the subcellular site where the entire process of PSTV replication takes place. Inhibition experiments with actinomycin D and alpha-amanitin furthermore suggest that the nuclear DNA-dependent RNA polymerases I and II are involved in the synthesis of PSTV (+) and (-) RNA, respectively.

A revised replication cycle for viroids: the role of longer than unit length RNA in viroid replication

Longer than unit length plus and minus strand RNAs were detected in hop stunt viroid (HSV) infected cucumber leaf tissues by Northern blot hybridization analysis using strand-specific probes. To elucidate the role of these longer than unit length RNAs in the viroid replication cycle, we synthesized tandemly repeated plus and minus strand HSV RNAs in vitro from cloned HSV cDNA and assayed their infectivities. Two and four unit tandemly repeated plus strand RNAs were infectious, but one unit plus, and one, two and four unit minus strands were noninfectious. Taking these data into consideration, we propose a revised rolling circle model for viroid replication.

A replication cycle for viroids and other small infectious RNA's

Experimental data concerning viroid-specific nucleic acids accumulating in tomato plants establish, together with earlier studies, the major features of a replication cycle for viroid RNA in plant cells. Many features of this pathway, which involves multimeric strands of both polarities, may be shared by other small infectious RNA's including certain satellite RNA's and "virusoid" RNA's which replicate in conjunction with conventional plant viruses. The presence, in host plans, of an elaborate machinery for replicating these disease agents suggests a role for endogenous small RNA's in cellular development.

Construction of infectious potato spindle tuber viroid cDNA clones

Contiguous restriction fragments from two cloned partial-length potato spindle tuber viroid (PSTV) cDNAs were used to construct recombinant DNAs containing full-length monomeric and dimeric PSTV cDNA. When five different PSTV cDNA plasmids and RNA isolated from E. coli cells harboring these plasmids were tested for infectivity on tomato, plasmid DNAs containing PSTV cDNA dimers were infectious. RNA transcripts containing the sequence of PSTV from these plasmids were also infectious. The sequences of the viroid progeny and the cloned DNA were identical. In vitro mutagenesis of infectious PSTV cDNAs will allow systematic investigation of the role of specific sequences in viroid replication and pathogenesis.

Structural similarities between viroids and transposable genetic elements

The primary structures of the tomato planta macho and tomato apical stunt viroids have been determined, and probable secondary structures are proposed. Both viroids can assume the rodlike conformation with extensive base-pairing characteristic of all known viroids. Sequence homologies between the two viroids (75%) and with members of the potato spindle tuber viroid group (73-83%) indicate that they both belong to this group. Comparative sequence analysis of all members of the group reveals striking similarities with the ends of transposable genetic elements. These similarities, the presence of inverted repeats often ending with the dinucleotides U-G and C-A, and flanking imperfect direct repeats suggest that viroids may have originated from transposable elements or retroviral proviruses by deletion of interior portions of the viral (or element) DNA.

Hop stunt viroid: molecular cloning and nucleotide sequence of the complete cDNA copy

The complete cDNA of hop stunt viroid (HSV) has been cloned by the method of Okayama and Berg (Mol.Cell.Biol.2,161-170. (1982] and the complete nucleotide sequence has been established. The covalently closed circular single-stranded HSV RNA consists of 297 nucleotides. The secondary structure predicted for HSV contains 67% of its residues base-paired. The native HSV can possess an extended rod-like structure characteristic of viroids previously established. The central region of the native HSV has a similar structure to the conserved region found in all viroids sequenced so far except for avocado sunblotch viroid. The sequence homologous to the 5'-end of U1a RNA is also found in the sequence of HSV but not in the central conserved region.

Contitions for optimal growth of a PSTV-infected potato cell suspension and detection of viroid-complementary longer-than-unit-length RNA in these cells

A suspension culture from potato spindle tuber viroid (PSTV)-infected cells of the wild type potato (Solanum demissum) has been established, which is a suitable model system for studying PSTV replicationin vivo. The conditions for rapid growth of these cells and for permanent extensive viroid biosynthesis within them are described. Biosynthesis of PSTV in the potato cells was demonstrated by(32)P-incorporation into nucleic acids and their subsequent electrophoretic analysis on polyacrylamide gels. Under optimum culture conditions the amount of(32)P-orthophosphate incorporation into PSTV reached 10% of that incorporated into the 2 M LiCl-soluble cellular RNA. (+)PSTV and its complementary form, i.e. (-)PSTV were identified after their electrophoretic separation on polyacrylamide and agarose gels by molecular hybridization. This analysis revealed the presence of six high molecular weight(-)PSTV species, which are possibly multimers of the unit length(+)PSTV molecule consisting of 359 nucleotides.

Oligomeric forms of potato spindle tuber viroid (PSTV) and of its complementary RNA are present in nuclei isolated from viroid-infected potato cells

Different oligomeric forms of PSTV are detected in nuclei isolated from PSTV-infected potato cells by means of molecular hybridization, using as probes synthetic oligodeoxyribonucleotides with sequence specificity for (+)PSTV and for (-)PSTV. In addition to several species of longer-than-unit-length (-)PSTV molecules, two oligomeric forms of (+)PSTV are detected, which correspond in size to RNA strands of approximately two and three times viroid unit-length. They must be considered as the precursors of the circular and linear (+)PSTV monomers accumulating in the cell nucleus.

Viroid RNA is accepted as a template for in vitro transcription by DNA-dependent DNA polymerase I and RNA polymerase from Escherichia coli

The RNA genome of potato spindle tuber viroid (PSTV) is transcribed in vitro into complementary DNA and RNA by DNA-dependent DNA polymerase I and RNA polymerase, respectively, from Escherichia coli. In vitro synthesis of complementary RNA produces distinct transcripts larger than unit length thus reflecting the in vivo mechanism of viroid replication. The influence of varying experimental conditions on the transcription process is studied; actinomycin D is found to drastically reduce complementary RNA synthesis from the PSTV RNA template by RNA polymerase.

Viroids and prions

Viroids are small "naked" infectious RNA molecules that are pathogens of higher plants. The potato spindle tuber viroid (PSTV) is composed of a covalently closed circular RNA molecule containing 359 ribonucleotides. The properties of PSTV were compared with those of the scrapie agent, which causes a degenerative neurological disease in animals. PSTV was inactivated by ribonuclease digestion, psoralen photoadduct formation, Zn2+ -catalyzed hydrolysis, and chemical modification with NH2OH. The scrapie agent resisted inactivation by these procedures, which modify nucleic acids. The scrapie agent was inactivated by proteinase K and trypsin digestion, chemical modification with diethylpyrocarbonate, and by exposure to phenol, NaDodSO4, KSCN, or urea. PSTV resisted inactivation by these procedures, which modify proteins. Earlier evidence suggested that the scrapie agent is smaller than PSTV. Its small size seems to preclude the presence of a genome coding for the protein(s) of a putative capsid. The properties of the scrapie agent distinguish it from both viroids and viruses and have prompted the introduction of the term "prion" to denote a small proteinaceous infectious particle that resists inactivation by procedures that modify nucleic acids.