Construction of infectious potato spindle tuber viroid cDNA clones

Transcriptomic and Proteomic Approaches Reveal the Biological Functions of Two Novel Porcine-Origin Noncoding DNA Molecules

Porcine circovirus-like mini agents (PCVLs) with small circular noncoding DNA genomes have recently been discovered in animals. Currently, the biological activity of PCVLs remains unclear. In this study, we conducted transcriptomic and proteomic analyses to compare the differential expression of genes and proteins in the livers of PCVL258/PCVL264 molecular clone-infected and mock-infected BALB/c mice at 7 and 28 days postinfection (dpi). Gene Ontology/Kyoto Encyclopedia of Genes and Genomes association analysis of the transcriptome and proteome showed that the differentially expressed genes and proteins (DEGs and DEPs) in the livers of PCVL258-infected mice were predominantly enriched in metabolic, cancer, and neurodegenerative disease signaling pathways. On the other hand, the DEGs and DEPs in the livers of PCVL264-infected mice were principally related to metabolic, reproductive, and pancreatic-associated pathways. We present the first application of transcriptomics combined with proteomics to determine the biological activities of small pathogen-associated DNA molecules, thus providing valuable information for understanding small circular DNA molecules that cannot encode proteins in the generation of specific human diseases.

Precisely Monomeric Linear RNAs of Viroids Belonging to Pospiviroid and Hostuviroid Genera Are Infectious Regardless of Transcription Initiation Site and 5'-Terminal Structure

Infectious dimeric RNA transcripts are a powerful tool for reverse genetic analyses in viroid studies. However, the construction of dimeric cDNA clones is laborious and time consuming, especially in mutational analyses by in vitro mutagenesis. In this study, we developed a system to synthesize a precisely monomeric linear RNA that could be transcribed in vitro directly from the cDNA clones of four viroid species. The cDNA clones were constructed such that RNA transcription was initiated at the guanine nucleotide of a predicted processing and ligation site in the viroid replication process. Although the transcribed RNAs were considered to possess 5′-triphosphate and 3′-hydroxyl termini, the RNA transcripts were infectious even without in vitro modifications. Additionally, infectivity was detected in the monomeric RNA transcripts, in which transcription was initiated at guanine nucleotides distinct from the predicted processing/ligation site. Moreover, monomeric viroid RNAs bearing 5′-monophosphate, 5′-hydroxyl, or 5′-capped termini were found to be infectious. Northern blot analysis of the pooled total RNA of the plants inoculated with the 5′-terminal modified RNA of potato spindle tuber viroid (PSTVd) indicated that maximum PSTVd accumulation occurred in plants with 5′-monophosphate RNA inoculation, followed by the plants with 5′-triphosphate RNA inoculation. Our system for synthesizing an infectious monomeric linear viroid RNA from a cDNA clone will facilitate mutational analyses by in vitro mutagenesis in viroid research.

Symptom Severity, Infection Progression and Plant Responses in Solanum Plants Caused by Three Pospiviroids Vary with the Inoculation Procedure

Infectious viroid clones consist of dimeric cDNAs used to generate transcripts which mimic the longer-than-unit replication intermediates. These transcripts can be either generated in vitro or produced in vivo by agro-inoculation. We have designed a new plasmid, which allows both inoculation methods, and we have compared them by infecting Solanum lycopersicum and Solanum melongena with clones of Citrus exocortis virod (CEVd), Tomato chlorotic dwarf viroid (TCDVd), and Potato spindle tuber viroid (PSTVd). Our results showed more uniform and severe symptoms in agro-inoculated plants. Viroid accumulation and the proportion of circular and linear forms were different depending on the host and the inoculation method and did not correlate with the symptoms, which correlated with an increase in PR1 induction, accumulation of the defensive signal molecules salicylic (SA) and gentisic (GA) acids, and ribosomal stress in tomato plants. The alteration in ribosome biogenesis was evidenced by both the upregulation of the tomato ribosomal stress marker SlNAC082 and the impairment in 18S rRNA processing, pointing out ribosomal stress as a novel signature of the pathogenesis of nuclear-replicating viroids. In conclusion, this updated binary vector has turned out to be an efficient and reproducible method that will facilitate the studies of viroid–host interactions.

An Inside Look into Biological Miniatures: Molecular Mechanisms of Viroids

Viroids are tiny single-stranded circular RNA pathogens that infect plants. Viroids do not encode any proteins, yet cause an assortment of symptoms. The following review describes viroid classification, molecular biology and spread. The review also discusses viroid pathogenesis, host interactions and detection. The review concludes with a description of future prospects in viroid research.

Plant Virus-Derived Vectors: Applications in Agricultural and Medical Biotechnology

Major advances in our understanding of plant viral genome expression strategies and the interaction of a virus with its host for replication and movement, induction of disease, and resistance responses have been made through the generation of infectious molecules from cloned viral sequences. Autonomously replicating viral vectors derived from infectious clones have been exploited to express foreign genes in plants. Applications of virus-based vectors include the production of human/animal therapeutic proteins in plant cells and the specific study of plant biochemical processes, including those that confer resistance to pathogens. Additionally, virus-induced gene silencing, which is RNA mediated and triggered through homology-dependent RNA degradation mechanisms, has been exploited as an efficient method to study the functions of host genes in plants and to deliver small RNAs to insects. New and exciting strategies for vector engineering, delivery, and applications of plant virus-based vectors are the subject of this review.

Harnessed viruses in the age of metagenomics and synthetic biology: an update on infectious clone assembly and biotechnologies of plant viruses

Recent metagenomic studies have provided an unprecedented wealth of data, which are revolutionizing our understanding of virus diversity. A redrawn landscape highlights viruses as active players in the phytobiome, and surveys have uncovered their positive roles in environmental stress tolerance of plants. Viral infectious clones are key tools for functional characterization of known and newly identified viruses. Knowledge of viruses and their components has been instrumental for the development of modern plant molecular biology and biotechnology. In this review, we provide extensive guidelines built on current synthetic biology advances that streamline infectious clone assembly, thus lessening a major technical constraint of plant virology. The focus is on generation of infectious clones in binary T-DNA vectors, which are delivered efficiently to plants by Agrobacterium. We then summarize recent applications of plant viruses and explore emerging trends in microbiology, bacterial and human virology that, once translated to plant virology, could lead to the development of virus-based gene therapies for ad hoc engineering of plant traits. The systematic characterization of plant virus roles in the phytobiome and next-generation virus-based tools will be indispensable landmarks in the synthetic biology roadmap to better crops.

Highly efficient construction of infectious viroid-derived clones

BACKGROUND

Viroid research generally relies on infectious cDNA clones that consist of dimers of the entire viroid sequence. At present, those dimers are generated by self-ligation of monomeric cDNA, a strategy that presents several disadvantages: (i) low efficiency, (ii) it is a non-oriented reaction requiring tedious screenings and (iii) additional steps are required for cloning into a binary vector for agroinfiltration or for in vitro RNA production.

RESULTS

We have developed a novel strategy for simultaneous construction of a viroid dimeric cDNA and cloning into a multipurpose binary vector ready for agroinfiltration or in vitro transcription. The assembly is based on IIs restriction enzymes and positive selection and supposes a universal procedure for obtaining infectious clones of a viroid independently of its sequence, with a high efficiency. Thus, infectious clones of one viroid of each family were obtained and its infectivity was analyzed by molecular hybridization.

CONCLUSION

This is a zero-background strategy for direct cloning into a binary vector, optimized for the generation of infectious viroids. As a result, this methodology constitutes a powerful tool for viroid research and exemplifies the applicability of type IIs restriction enzymes and the lethal gene ccdB to design efficient and affordable direct cloning approaches of PCR products into binary vectors.

Pathogenesis by subviral agents: viroids and hepatitis delta virus

The viroids of plants are the simplest known infectious genetic elements. They have RNA genomes of up to 400 nucleotides in length and no protein encoding capacity. Hepatitis delta virus (HDV), an infectious agent found only in humans co-infected with hepatitis B virus (HBV), is just slightly more complex, with an RNA genome of about 1700 nucleotides, and the ability to express just one small protein. Viroid and HDV RNAs share several features that include circular structure, compact folding, and replication via a rolling-circle mechanism. Both agents were detected because of their obvious pathogenic effects. Their simplicity demands a greater need than conventional RNA or DNA viruses to redirect host components for facilitating their infectious cycle, a need that directly and indirectly incites pathogenic effects. The mechanisms by which these pathogenic effects are produced are the topic of this review. In this context, RNA silencing mediates certain aspects of viroid pathogenesis.

Construction of an infectious clone of a plant RNA virus in a binary vector using one-step Gibson Assembly

The construction of full-length infectious clones of RNA viruses is often laborious due to the many cloning steps required and the DNA exclusion within the plasmid during Escherichia coli transformation. We demonstrate single-step cloning procedure of an infectious cDNA of the tomato blistering mosaic virus (ToBMV) using Gibson Assembly (GA), which drastically reduces the number of cloning steps. By agro-inoculation with the construct obtained by this procedure, ToBMV was recovered six days post-inoculation in Nicotiana benthamiana plants. The symptoms induced by the recovered virus were indistinguishable from those caused by the wild-type virus. We conclude that the GA is very useful method particularly to construct a full-length cDNA clone of a plant RNA virus in a binary vector.

Analysis and application of viroid-specific small RNAs generated by viroid-inducing RNA silencing

Viroids are noncoding RNA pathogens inducing severe to mild disease symptoms on agriculturally important crop plants. Viroid replication is entirely dependent on host transcription machinery, and their replication/accumulation in the infected cells can activate RNA silencing-a host defense mechanism that targets the viroid itself. RNA silencing produces in the cell large amounts of viroid-specific small RNAs of 21-24-nucleotides by cleaving (or "dicing") entire molecules of viroid RNA. However, viroid replication is resistant to the effects of RNA silencing and disrupts the normal regulation of host gene expression, finally resulting in the development of disease symptoms on infected plant. The molecular mechanisms of biological processes involving RNA silencing and underlying various aspects of viroid-host interaction, such as symptom expression, are of special interests to both basic and applied areas of viroid research. Here we present a method to create infectious viroid cDNA clones and RNA transcripts, the starting material for such analyses, using Hop stunt viroid as an example. Next we describe methods for the preparation and analysis of viroid-specific small RNAs by deep sequencing using tomato plants infected with Potato spindle tuber viroid as an example. Finally we introduce bioinformatics tools and methods necessary to process, analyze, and characterize these viroid-specific small RNAs. These bioinformatic methods provide a powerful new tool for the detection and discovery of both known and new viroid species.

Construction of Infectious cDNA Clone of a Chrysanthemum stunt viroid Korean Isolate

Chrysanthemum stunt viroid (CSVd), a noncoding infectious RNA molecule, causes seriously economic losses of chrysanthemum for 3 or 4 years after its first infection. Monomeric cDNA clones of CSVd isolate SK1 (CSVd-SK1) were constructed in the plasmids pGEM-T easy vector and pUC19 vector. Linear positive-sense transcripts synthesized in vitro from the full-length monomeric cDNA clones of CSVd-SK1 could infect systemically tomato seedlings and chrysanthemum plants, suggesting that the linear CSVd RNA transcribed from the cDNA clones could be replicated as efficiently as circular CSVd in host species. However, direct inoculation of plasmid cDNA clones containing full-length monomeric cDNA of CSVd-SK1 failed to infect tomato and chrysanthemum and linear negative-sense transcripts from the plasmid DNAs were not infectious in the two plant species. The cDNA sequences of progeny viroid in systemically infected tomato and chrysanthemum showed a few substitutions at a specific nucleotide position, but there were no deletions and insertions in the sequences of the CSVd progeny from tomato and chrysanthemum plants.

Transfer of Agrobacterium DNA to Plants Requires a T-DNA Border But Not the virE Locus

Agrobacterium tumefaciens induces tumors in plants by transferring and integrating oncogenes (T-DNA) into the chromosomes of host plant cells. Agrobacterium strains were used to transfer complementary DNA copies of a potato spindle tuber viroid (PSTV) to plant cells at a wound site on tomato plant stems. Subsequently, infectious viroid RNA was found in the leaves of these plants, indicating systemic PSTV infection. This process utilized the T-DNA transfer mechanisms of Agrobacterium since PSTV infection required most virulence genes (vir) as well as one of the DNA sequences that flank either side of the Agrobacterium T-DNA. However, transfer still occurred from virE mutants of Agrobacterium, strains that fail to induce tumors even though a completely functional T-DNA is present. The virE gene seems to be directly involved in the integration of foreign DNA into plant chromosomes.

Multicomponent RNA plant virus infection derived from cloned viral cDNA

In vitro transcripts from mixtures of appropriate brome mosaic virus (BMV) cDNA clones are infectious when inoculated onto barley plants. Infectivity depends on in vitro transcription and on the presence of transcripts from clones of all three BMV genetic components. Infectivity is destroyed by RNase after transcription, but it is insensitive to RNase before or to DNase after transcription. Virion RNAs from plants infected with cDNA transcripts hybridize to BMV-specific probes and coelectrophorese with virion RNAs propagated from conventional inoculum. Direct RNA sequencing shows that a deletion in the noncoding region of one infectious BMV clone is preserved in viral RNA from plants systemically infected with transcript mixtures representing that clone.

cDNA cloning of the complete genome of tobacco mosaic virus and production of infectious transcripts

The entire genome of tobacco mosaic virus (TMV) was copied into a series of subgenomic cDNA clones. cDNA sequences of the 5' and 3' ends of TMV were cloned separately. A synthetic oligonucleotide primer was used to generate a Pst I site at the 5' terminus, whereas a different primer was used to generate an Nde I site at the 3' terminus. This strategy permitted removal of non-TMV sequences from cloned cDNA inserts by treatment with exonuclease VII following restriction endonuclease cleavage. Pst I linkers were added to TMV 3' terminal cDNAs. Subgenomic cDNA fragments were ligated together into several independent full-genomic constructions from which TMV cDNA sequences could be cleanly excised as a single fragment by Pst I digestion. Full-genomic TMV cDNA was ligated immediately downstream from the lambda phage promoter from pPM1 and transcribed in vitro with Escherichia coli RNA polymerase. RNA transcripts from three of four full-genomic cDNA constructions were infectious, even though they contained 6 non-TMV nucleotides at the 3' end. Transcripts from a construction with 6 extra nucleotides at the 5' end also were infectious. Progeny virus from plants infected with cDNA transcripts appeared identical to the parental virus. Restriction maps of independent cDNA clones of the same regions of the genome were identical to each other and as predicted from the reported nucleotide sequence of TMV. Also, sequences of the 200 nucleotides proximal to the 5' termini of four independent cDNA clones were identical to each other and to published sequences, suggesting that independent isolates of TMV may have remarkably similar sequences.

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.

In vitro-transcribed Chrysanthemum stunt viroid RNA is infectious to chrysanthemum and other plants

Chrysanthemum stunt viroid (CSVd), a noncoding RNA, is known to cause chrysanthemum stunt disease, which affects the yield of flowers. To gain insights into CSVd replication, infection, and the reasons for the spreading of CSVd disease in chrysanthemum plants, we prepared linear CSVd RNA and analyzed its ability to cause disease in chrysanthemum plants. We found that linear CSVd replicated as efficiently as CSVd RNA isolated from the infected chrysanthemum plants. Additionally, the linear CSVd RNA was evaluated for its ability to infect other plants as well, which revealed that CSVd has a wide host range for its replication. Importantly, the CSVd isolated from these hosts is infectious to chrysanthemum plants, and thus potentially contributes to the spreading of the disease to chrysanthemum plants.

Analysis of viroid replication

Viroids, as a consequence of not encoding any protein, are extremely dependent on their hosts. Replication of these minimal genomes, composed exclusively by a circular RNA of 246-401 nt, occurs in the nucleus (family Pospiviroidae) or in the chloroplast (family Avsunviroidae) by an RNA-based rolling-circle mechanism with three steps: (1) synthesis of longer-than-unit strands catalyzed by host DNA-dependent RNA polymerases recruited and redirected to transcribe RNA templates, (2) cleavage to unit-length, which in family Avsunviroidae is mediated by hammerhead ribozymes, and (3) circularization through an RNA ligase or autocatalytically. This consistent but still fragmentary picture has emerged from a combination of studies with in vitro systems (analysis of RNA preparations from infected plants, transcription assays with nuclear and chloroplastic fractions, characterization of enzymes and ribozymes mediating cleavage and ligation of viroid strands, dissection of 5' terminal groups of viroid strands, and in situ hybridization and microscopy of subcellular fractions and tissues), and in vivo systems (tissue infiltration studies, protoplasts, studies in planta and use of transgenic plants expressing viroid RNAs).

One-step site-directed mutagenesis of viroid dimeric cDNA

The study of viroids (plant pathogens constituted by small non-coding RNA) has greatly benefited from the use of site-directed mutagenesis tools. However, compared to viral systems, this technique is complicated by the fact that, usually, infectious cDNAs carry two copies of the viroid genome. A simple method for a one-step site-directed mutagenesis of viroids is described and tested by estimating the rate of mutation incorporation of three random nucleotide substitutions in each Chrysanthemum stunt viroid (CSVd) and Chrysanthemum chlorotic mottle viroid (CChMVd). The protocol is essentially based on the original QuickChange Stratagene methodology; dimeric cDNA templates are amplified directly using Pfu DNA polymerase and self-complementary mutagenic primers. The reaction typically yields dimeric, but also monomeric clones which can be easily distinguished by electrophoretic analysis. The data show that approximately 50% of the dimeric clones carry the desired mutation in both viroid copies. Since the proposed protocol is simple technically and rapid compared to previous methods, it could be applied routinely for site-directed mutagenesis studies in viroids.

Potato spindle tuber viroid: the simplicity paradox resolved?

TAXONOMY

Potato spindle tuber viroid (PSTVd) is the type species of the genus Posipiviroid, family Pospiviroidae. An absence of hammerhead ribozymes and the presence of a 'central conserved region' distinguish PSTVd and related viroids from members of a second viroid family, the Avsunviroidae.

PHYSICAL PROPERTIES

Viroids are small, unencapsidated, circular, single-stranded RNA molecules which replicate autonomously when inoculated into host plants. Because viroids are non-protein-coding RNAs, designation of the more abundant, highly infectious polarity strand as the positive strand is arbitrary. PSTVd assumes a rod-like, highly structured conformation that is resistant to nuclease degradation in vitro. Naturally occurring sequence variants of PSTVd range in size from 356 to 361 nt. HOSTS AND SYMPTOMS: The natural host range of PSTVd-cultivated potato, certain other Solanum spp., and avocado-appears to be quite limited. Foliar symptoms in potato are often obscure, and the severity of tuber symptoms (elongation with the appearance of prominent bud scales/eyebrows and growth cracks) depends on both temperature and length of infection. PSTVd has a broad experimental host range, especially among solanaceous species, and strains are classified as mild, intermediate or severe based upon the symptoms observed in sensitive tomato cultivars. These symptoms include shortening of internodes, petioles and mid-ribs, severe epinasty and wrinkling of the leaves, and necrosis of mid-ribs, petioles and stems.

Processing of RNAs of the family Avsunviroidae in Chlamydomonas reinhardtii chloroplasts

The family Avsunviroidae comprises four viroid species with the ability to form hammerhead ribozymes that mediate self-cleavage of the multimeric plus and minus strands resulting from replication in the chloroplast through a symmetric rolling-circle mechanism. Research on these RNAs is restricted by their host range, which is limited to the plants wherein they were initially identified and some closely related species. Here we report cleavage and ligation in transplastomic Chlamydomonas reinhardtii expressing plus- and minus-strand dimeric transcripts of representative members of the family Avsunviroidae. Despite the absence of viroid RNA-RNA transcription, the C. reinhardtii-based system can be used to address intriguing questions about viroid RNA processing and, in particular, about the cellular factors involved in cleavage and ligation.

Biolistic inoculation of plants with viroid nucleic acids

Parameters for biolistic transfer of viroid nucleic acids using a Helios Gene Gun device were assayed. The main achievement of this method is high efficiency of inoculation with linear monomeric viroid cDNAs and RNAs. This greatly facilitates the study of mutated sequence variants, viroid libraries and mixed populations. The lower limits for efficient inoculation of monomeric cDNA fragments with the sequence of potato spindle tuber viroid (PSTVd) and native PSTVd RNA as detected 21 days p.i. are in the range of 50 ng and 200 pg per tomato plant, respectively. At a higher dose, i.e. 2 ng of native RNA per plant, biolistic transfer causes drastic stunting compared to conventional mechanical inoculation, which points to higher PSTVd titers after the biolistic transfer. Infection is readily achieved with exact length monomeric RNA transcripts having 5'-triphosphate and 3'-OH termini in amounts ranging from 2 to 20 ng per plant, suggesting no need for any supplementary modifications of ends or RNA circularization. The biolistic transfer is efficient for viroid "thermomutants", which exhibit low or no infectivity with conventional mechanical inoculation with Carborundum. The biolistic inoculation is also efficient for two other members of the Pospiviroidae family, hop stunt and hop latent viroid.

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.

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).

Use of intramolecular chimeras to map molecular determinants of symptom severity of potato spindle tuber viroid (PSTVd)

Nucleotide sequence comparison shows that sequence variations are mostly clustered in the P (pathogenicity) and V (variable) domains of the potato spindle tuber viroid (PSTVd) molecule. Although these comparisons suggest the P domain as the primary determinant of PSTVd symptom severity, the potential contribution of the V domain has never been analysed in detail. To investigate the relationship between the structure of these domains and pathogenicity, six intraspecific chimeric PSTVd variants were constructed by exchanging P and V domains between a mild and two different severe PSTVd isolates. Infectivity studies showed that the P domain is directly responsible for the severity of symptoms induced in tomato. The four recombinants containing a P domain from a severe isolate caused severe symptoms including severe epinasty, stunting and veinal necrosis, while the two chimeras containing the mild isolate P domain induced only mild symptoms. Quantitation of viroid accumulation in plants infected with the various recombinants suggests that, with the constructions used, symptom severity did not correlate with viroid accumulation, indicating that the P domain did not influence symptom production through this simple mechanism.

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.

Analysis of the population structure of three phenotypically different PSTVd isolates

Phenotypically dissimilar greenhouse isolates from a Polish collection of potato spindle tuber viroid (PSTVd) were analysed. Partially purified PSTVd genomic RNAs from severe, intermediate and mild isolates was reverse transcribed and the resulting cDNAs enzymatically amplified. Abutting-primer PCR (Ab-P PCR) technology was used to obtain, in a single step, infectious full-length PSTVd cDNA monomers and these were sequenced. The mild isolate was found to be composed of a unique molecular variant (M), closely related to previously described PSTVd mild isolates. In the intermediate isolate, three variants, i2, i3 and i4, were detected. The severe isolate was found to be a mixture containing at least four molecular variants: s23, s27, i4 and i2. Infection of test plants with plasmids carrying monomeric cDNAs corresponding to each of the cloned variants confirmed that they are infectious. In addition, variant M produced mild symptoms, variants i2, i3, i4 intermediate symptoms and variants s23 and s27 severe symptoms. Therefore, the disease symptoms produced by a mixture are determined by the severe variants, masking the presence of milder ones. All the variants detected (except i2 which is identical to previously described PSTVd-DI) represent novel PSTVd sequences with point mutations located in the V and/or P domains. In particular, variants s23 and i4 represent shorter (358 nucleotides) versions of the PSTVd genome.

Identification of multiple structural domains regulating viroid pathogenicity

To investigate the role of individual structural domains in viroid pathogenicity and replication, a series of interspecific chimeras was constructed by exchanging the terminal left (TL) and/or pathogenicity (P) domains between tomato apical stunt (TASVd) and citrus exocortis (CEVd) viroids. All six chimeras tested were replicated stably in tomato, and the symptoms exhibited by infected plants were intermediate between those induced by the parental viroids. Quantitative comparisons of symptom development and progeny accumulation revealed that: (i) the TL domain of TASVd contains a determinant required for appearance of severe veinal necrosis in tomato, (ii) the severe epinasty and stunting characteristic of TASVd requires the presence of its TL and P domains, and (iii) the variable (V) and terminal right (TR) domains comprising the right side of the native structure also play an important role in viroid pathogenicity. Chimeras containing the right side of TASVd accumulated to higher levels early in infection, and infected plants developed more severe symptoms than those whose right halves were derived from CEVd. Although the individual contributions of the TL and P domains to symptom induction could not be completely separated from that of viroid titer, the TL domain appears to exert a greater effect upon symptom severity than does the P domain. The TL, P, V, and TR domains of TASVd and CEVd contain three discrete regions of sequence and/or structural variability that may correspond to the pathogenicity determinants uncovered by our genetic analysis.

Processing of linear longer-than-unit-length potato spindle tuber viroid RNAs into infectious monomeric circular molecules by a G-specific endoribonuclease

Different cDNA constructs were used for the in vitro synthesis of RNA transcripts that contain a complete monomeric unit of the potato spindle tuber viroid (PSTVd) plus an additional repeat of a part of the circular RNA genome. These permutated linear longer-than-unit-length PSTVd RNAs were incubated with the G-specific endoribonuclease RNase T1 which generated monomeric circular PSTVd RNA molecules that were infectious when mechanically inoculated to tomato plants. Besides the correct monomeric PSTVd RNA, smaller and larger circular RNAs were also formed during the reaction. The comparison of different transcripts revealed that correct in vitro processing of PSTVd RNA can proceed at alternative sites indicating that circularization is driven by RNA structure and not governed by a particular sequence. Based on these data, we propose a novel model for the processing of multimeric replicative viroid RNA intermediates through RNA cleavage and ligation catalyzed by a host endoribonuclease.

A rapid and versatile method for cloning viroids or other circular plant pathogenic RNAs

We surveyed the occurrence of unique restriction sites on the cDNAs of viroids, virusoids, and plant viral satellite RNAs that have a circular RNA as an intermediate of replication and found that four such sites would linearize their circular cDNAs. A rapid and simple method was then developed for cloning a naturally occurring viroid from Nematanthus wettsteinii plants. First-strand cDNA was synthesized using random hexanucleotide DNA primers and M-MuLV reverse transcriptase (Superscript RT). Second-strand DNA was synthesized by employing the replacement synthesis method using Escherichia coli RNase H, E. coli DNA polymerase I, E. coli DNA ligase, and beta-NAD+. The circular double-stranded DNA was analyzed for the presence of commonly available, unique restriction sites and subsequently linearized with a selected restriction enzyme. The linear cDNA was ligated to dephosphorylated plasmid vector pGEM 3Z f(+) and cloned in E. coli strain DH5 alpha. This cDNA cloning procedure is suitable for cloning sequence variants of well-characterized viroids, virusoids, certain plant viral satellite RNAs, and new such pathogens of unknown sequence.

RNA progeny of an infectious two-base deletion cDNA mutant of potato spindle tuber viroid (PSTV) acquire two nucleotides in Planta

Deletion mutations were generated in four structural domains of a potato spindle tuber viroid (PSTV) complementary DNA (cDNA) clone. Deletions of 3 to 5 nucleotides at the central conserved domain (CCGGG, positions 94 to 98), variable domain (GCCG, positions 146 to 149) and pathogenicity domain (CGA, positions 286 to 288) abolished infectivity of dimeric or trimeric cDNA constructs, or their in vitro transcripts. By contrast, a clone (St4) with a deletion of two nucleotides (UU, positions 339 and 340), located at the left terminal domain, retained infectivity when DNA or in vitro transcribed (+)RNA was used as inoculum. Sequencing of four cDNA clones of such viroid progeny demonstrated that two nucleotides were added at the deletion site. Two of the viroid progeny contained a CG addition. A third clone possessed a GU addition, whereas the fourth clone had a UU addition which represents a true reversion to full-length wild-type PSTV RNA. Ribonuclease protection assay of viroid progeny from St4-infected tomato plants suggested that only a negligible proportion of the St4 progeny were true revertants.

Efficient inoculation with CaMV 35 S promoter-driven DNA clones of the tobravirus PEBV

Clones have been constructed containing full-length cDNA copies of PEBV RNA1 and RNA2, flanked by the CaMV 35 S RNA promoter and the nopaline synthase terminator. The clones are infectious when inoculated onto Nicotiana benthamiana plants. Both the viral RNAs and the virus particles were identified in infected plants.

In vitro synthesis of an infectious viroid: analysis of the infectivity of monomeric linear CEV

Infectious monomers of citrus exocortis viroid (CEV) were synthesized in vitro precisely to predetermined sequences in microgram quantities without resorting to cloning procedures. Amplification of CEV double-stranded cDNAs fused with a T7 RNA polymerase promoter was followed by transcription of the DNA resulting in the production of an infectious linear CEV monomer. This is the first demonstration of an infectious unit length viroid synthesized in vitro. Transcripts containing 3'-OH terminal groups were infectious, demonstrating that a 2',3'-cyclic phosphate terminus is not a prerequisite for viroid infectivity as previously suggested. Conversion of the 5'-triphosphate terminus to either 5'-monophosphate or 5'-OH had little effect on infectivity. The linear RNA could be circularized using T4 RNA ligase to produce an authentic CEV molecule. This procedure, which results in the production of biologically active RNA, would allow routine application of oligonucleotide-directed mutagenesis to the study of viroids and other circular RNAs. It would also enable the in vitro synthesis and mutagenesis of infectious viral RNAs containing a 5'-G residue.

cDNAs of beet necrotic yellow vein virus RNAs 3 and 4 are rendered biologically active in a plasmid containing the cauliflower mosaic virus 35S promoter

cDNAs of beet necrotic yellow vein virus RNAs 3 and 4 could be rendered biologically active when they were placed under the control of the cauliflower mosaic virus 35S promoter and polyadenylation signal. Although the 35S in vivo transcripts should have contained up to forty 5' and several hundred 3' nonviral nucleotides, the progeny viral RNAs had the same sizes as in naturally infected sugarbeets. The progeny RNAs did not hybridize with the nonviral sequences indicating that they were apparently not replicated. Deletion and insertion mutants of RNA 3 cDNA clones were also biologically active in plants but a plasmid which contained the cDNA of RNA 3 in antisense orientation was not. The biological activity of plasmid DNAs compared with the corresponding synthetic transcripts is discussed.

Effects of random mutagenesis upon potato spindle tuber viroid replication and symptom expression

A combination of random chemical mutagenesis plus temperature gradient gel electrophoresis was used to isolate a collection of 57 potato spindle tuber viroid (PSTV) cDNAs containing mutations distributed throughout the entire 359 nucleotide genome. Although the presence of multiple mutations was often associated with a loss of cDNA infectivity, infectious PSTV cDNAs containing as many as four unlinked alterations could be isolated. Several mutations in the pathogenicity domain and left terminal loop were stably maintained in the resulting progeny, but those which affect base pairing in secondary hairpins I and II were either lethal or rapidly reverted to wild-type. One stable C----U substitution which may promote significant structural rearrangement within the right side of the pathogenicity domain had no detectable effect upon symptom expression. The variable domains of several noninfectious mutants contained an A----G substitution which is likely to inhibit the in vitro formation of secondary hairpin II via stabilization of the native structure, and the lethal nature of this mutation was confirmed by oligonucleotide-directed mutagenesis. Several lines of evidence now point toward an essential role for secondary hairpin II in the replication of PSTV and related viroids.

Formation of a thermodynamically metastable structure containing hairpin II is critical for infectivity of potato spindle tuber viroid RNA

The functional relevance of a hairpin II-containing structure of viroid RNA was studied by site-directed mutagenesis, thermodynamic calculations, experimental denaturation curves and infectivity tests. Hairpin II is formed during thermal denaturation of circular viroids or as part of a metastable structure during synthesis of viroid replication intermediates. In potato spindle tuber viroid (PSTVd), eight single-site mutations were generated in the segments which form hairpin II. From the mutated viroid cDNA clones, linear RNA transcripts of PSTVd unit length were synthesized. The relevance of hairpin II for the mechanism of denaturation was confirmed quantitatively by optical denaturation curves and temperature-gradient gel electrophoresis. Infectivity tests showed that the mutations in the core region of hairpin II reverted to the wild type sequence whereas the mutations in the peripheral regions of hairpin II remained genetically stable. These data are in accordance with the natural variance of hairpin II in other viroids of the PSTVd class. Thus, the integrity of the core of hairpin II is critical for infectivity. Hairpin II exhibits a strong similarity in sequence as well as in three-dimensional structure to certain DNA GC-clusters found in the 5'-upstream regions of some genes in man, animals, viruses and plants. A hypothesis about a function of hairpin II as a binding site for host cell transcription factors is proposed.

Characterization of infectious transcripts from a potato virus X cDNA clone

A full-length cDNA clone of potato virus X (PVX) has been constructed and fused to the bacteriophage T7 promoter in an in vitro transcription vector. Transcripts derived from this template (pMON 8660) were infectious when inoculated onto the local lesion host, Chenopodium amaranticolor. The infectivity of these transcripts was approximately 0.2% that of authentic PVX RNA. Lesions sampled from plants inoculated with these transcripts contained virus particles and virus aggregates typically observed in lesions from plants inoculated with authentic PVX RNA, as evidenced by electron microscopy. In addition, progeny virus isolated from these lesions was as infectious as progeny virus from an authentic PVX RNA infection when inoculated onto new local lesions plants. Infectious transcripts derived from PVX cDNA clones will facilitate analysis of the molecular aspects of PVX infection.

The role of the viroid central conserved region in cDNA infectivity

The effect of sequence duplication upon the infectivity of plasmid DNAs containing monomeric tomato apical stunt viroid cDNAs has been determined. Two factors appear to control the specific infectivity of the different plasmid constructions tested: the presence of a subset of a palindromic sequence located within the central conserved region and the orientation of the viroid cDNA within the recombinant plasmid. Deletions which disrupt the integrity of the putative processing site abolished cDNA infectivity, a result that is consistent with the involvement of this site in the cleavage/ligation of viroid RNAs during replication.

Construction of novel viroid chimeras containing portions of tomato apical stunt and citrus exocortis viroids

Several novel tomato apical stunt viroid (TASV) recombinants were isolated after inoculation of tomato seedlings with monomeric viroid cDNAs. Two intraspecific recombinants were constructed by exchanging the left and right sides of the closely related Ivory Coast and Indonesian strains of TASV, and a third, interspecific, recombinant was constructed by similar manipulations involving TASV and citrus exocortis viroid (CEV) cDNAs. Characterization of these TASV recombinants by RNA protection assays and nucleotide sequence analysis of polymerase chain reaction-amplified cDNAs revealed no evidence for sequence instability. The symptoms induced by replication of the CEV-TASV chimera in tomato were milder than those induced by either TASV or the TASV chimeras and resembled those induced by the CEV isolate which provided its pathogenicity domain.

Conditional poliovirus mutants made by random deletion mutagenesis of infectious cDNA

Small deletions were introduced into DNA plasmids bearing cDNA copies of Mahoney type 1 poliovirus RNA. The procedure used was similar to that of P. Hearing and T. Shenk (J. Mol. Biol. 167:809-822, 1983), with modifications designed to introduce only one lesion randomly into each DNA molecule. Methods to map small deletions in either large DNA or RNA molecules were employed. Two poliovirus mutants, VP1-101 and VP1-102, were selected from mutagenized populations on the basis of their host range phenotype, showing a large reduction in the relative numbers of plaques on CV1 and HeLa cells compared with wild-type virus. The deletions borne by the mutant genomes were mapped to the region encoding the amino terminus of VP1. That these lesions were responsible for the mutant phenotypes was substantiated by reintroduction of the sequenced lesions into a wild-type poliovirus cDNA by deoxyoligonucleotide-directed mutagenesis. The deletion of nucleotides encoding amino acids 8 and 9 of VP1 was responsible for the VP1-101 phenotype; the VP1-102 defect was caused by the deletion of the sequences encoding the first four amino acids of VP1. The peptide sequence at the VP1-VP3 proteolytic cleavage site was altered from glutamine-glycine to glutamine-methionine in VP1-102; this apparently did not alter the proteolytic cleavage pattern. The biochemical defects resulting from these mutations are discussed in the accompanying report.

Cloned hepatitis delta virus cDNA is infectious in the chimpanzee

A head-to-tail trimer of a full-length cDNA clone of the hepatitis delta virus (HDV) genome was examined for infectivity by direct inoculation into the liver of a chimpanzee that was already infected with hepatitis B virus. Five weeks after inoculation, a marked elevation of serum alanine aminotransferase activity was observed, followed by the appearance of high levels of HDV RNA and antigen in both liver and serum and a high level of viral particles in the serum. A transient suppression of hepatitis B virus replication was evident during the acute phase of HDV infection. Seroconversion for antibodies to delta antigen occurred 3 weeks after the onset of the disease. These results demonstrate that a typical HDV infection can be initiated by inoculation of a susceptible animal with recombinant HDV cDNA.

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.

A microscale procedure for isolating and sequencing the viroid RNA present in one gram of infected leaf tissue

A microscale procedure for the isolation and purification of viroid RNA from one gram of viroid-infected leaf tissue and for its subsequent sequencing at the cDNA level is described using potato spindle tuber viroid (PSTV) as model system. Total nucleic acids are phenol-extracted and salt-fractionated with 2 M LiCl. The viroid-containing fraction is then subjected to bidirectional polyacrylamide gel electrophoresis. This removes all co-fractionated cellular RNAs from the circular viroid RNA which is finally recovered from the gel in pure form by isotachophoresis. Thus, from one gram of PSTV-infected tomato leaf tissue, about 100-250 ng of circular PSTV RNA can be obtained and used as template for several DNA primer-directed reverse transcription reactions. From the primer-extended overlapping cDNAs the entire sequence of the viroid progeny synthesized in an individual plant or plant leaf can thus be established by Maxam-Gilbert sequencing. This renders the procedure especially suited for the routine analysis of the in vivo fate of viroid mutants constructed in vitro.

Analysis of RNA structures by temperature-gradient gel electrophoresis: viroid replication and processing

The structure and structural transitions of single-stranded RNA were investigated by energy calculations and temperature-gradient gel electrophoresis. Most experiments have been carried out on RNA of mature viroids and their replication intermediates, which are RNA (-) strand oligomers and RNA (+) strand oligomers. The technique of temperature-gradient gel electrophoresis proved to be particularly useful for analysing co-existing structures. The secondary structure of lowest free energy for unit length and oligomeric replication intermediates is an extended rod-like structure similar to that of the mature circular viroid. When this structure is used as a model for calculations, there is a large degree of agreement between theoretical and experimental curves. Under particular solution conditions, however, (+) strand oligomers undergo a rearrangement from the extended structure to a branched structure, in which every two units form a region of three helices, together 28 bp long. This structure is called the tri-helical structure. The process of structure formation during the synthesis of oligomers could be followed: at first, a transient multi-branched structure is formed which is then transformed into the extended and the tri-helical structures. The region of the three stable helices serves to divide up the oligomeric (+) strand into structural units which may be recognized by cleavage and ligation enzymes, and be processed into circular mature viroids. Co-transcription of complementary (+) and (-) strands shows that energetically favored double-strand formation may at least partially be prohibited by stable secondary structures of the single strands. Natural replication intermediates have been analysed in respect to their subcellular location and their size distribution. They are associated with the nucleoli as was found earlier for mature viroids. Natural (-) strand oligomers are larger than (+) strand oligomers; both types show a periodicity in the size distribution of two units. The models of the structures, which are involved in viroid processing, are in accordance with recent infectivity data and with the results on natural replication intermediates.

In vitro assembly of a functional nucleocapsid from the negative-stranded genome RNA of a defective interfering particle of vesicular stomatitis virus

The template for transcription and replication of negative-stranded RNA viruses is a ribonucleoprotein structure, the nucleocapsid. We have developed a system that supports assembly of the negative-stranded RNA genome of a defective interfering (DI) particle of vesicular stomatitis virus (VSV) into a nucleocapsid in vitro. This system uses extracts from wild-type VSV-infected cells as a source of proteins to encapsidate the RNA. In vitro assembled nucleocapsids were compared to in vivo-derived nucleocapsids by the following characteristics: nuclease resistance of the encapsidated RNA, CsCl density banding of labeled RNA in a position coincident with nucleocapsids, correct sedimentation rate in sucrose gradients, the presence of the nucleocapsid protein on the nucleocapsids, and the infectivity of the in vitro assembled nucleocapsids. We conclude that the system we present is capable of assembling the isolated genome of a rhabdovirus DI particle into nucleocapsids indistinguishable from those produced during the course of intracellular DI replication.

Molecular analysis of Sindbis virus pathogenesis in neonatal mice by using virus recombinants constructed in vitro

Genetic loci affecting Sindbis virus pathogenesis in neonatal mice have been examined by using a full-length cDNA clone of the virus (Toto1101). The full-length cDNA is linked to a bacteriophage SP6 promoter to facilitate the synthesis of infectious RNA transcripts in vitro. Virus derived from Toto1101 showed reduced virulence (attenuation) in neonatal mice. Replacement of the E1 glycoprotein and 6K genes of Toto1101 with cloned E1 and 6K genes derived from a virulent Sindbis virus strain, AR339 (SB), resulted in a new construct, TR2000, that gave rise to virulent virus. Sequence determinations for the entire substituted regions of TR2000, Toto1101, and related virulent and attenuated strains identified three coding differences in E1 between Toto1101 and TR2000. These differences, individually or in combination, may be responsible for the attenuated phenotype. Previous studies in this laboratory identified another attenuating mutation at amino acid position 114 of the E2 glycoprotein (N.L. Davis, F.J. Fuller, W.G. Dougherty, R.A. Olmsted, and R.E. Johnston, Proc. Natl. Acad. Sci. USA 83:6771-6775, 1986). Substitution of Arg-114 in the mutant SB-RL for Ser-114 of SB appears to confer three distinguishing phenotypes: attenuation in neonatal mice, increased sensitivity to specific E2 monoclonal antibodies, and accelerated penetration of BHK cells. Replacement of TR2000 sequences containing the codon for amino acid 114 of E2 with corresponding fragments from cDNA clones of SB or SB-RL produced two strains of Sindbis virus (TR2100 and TR2200) which were isogenic except for the E2 114 codon (Ser and Arg, respectively). The three diagnostic phenotypes cosegregated according to the origin of the codon for amino acid 114 of E2, confirming the dramatic effect of this single amino acid substitution on these three phenotypes.

Infectious positive- and negative-strand transcript RNAs from bacteriophage Q beta cDNA clones

Plasmids containing full-length cDNA copies of the Q beta RNA phage genome and flanking T7 promoters were constructed. Positive-strand Q beta RNA, generated by in vitro transcription of these plasmids with T7 RNA polymerase, was infectious to Escherichia coli spheroplasts. The Q beta replicase gene from the cloned DNA was subcloned and expressed in E. coli cells by means of a thermoinducible plasmid. Full-length, negative-strand Q beta transcripts were infectious when transfected into spheroplasts containing the induced replicase gene.

An improved procedure for the rapid one-step-cloning of full-length viroid cDNA

The efficiency of viroid cloning can be increased by three to four orders of magnitude when the synthesis of viroid cDNA is primed in such a way that it carries identical sticky ends on both termini and when the multi-ion transformation is applied.