Viroids

Molecular interactions of plant viral satellites

Plant viral satellites fall under the category of subviral agents. Their genomes are composed of small RNA or DNA molecules a few hundred nucleotides in length and contain an assortment of highly complex and overlapping functions. Each lacks the ability to either replicate or undergo encapsidation or both in the absence of a helper virus (HV). As the number of known satellites increases steadily, our knowledge regarding their sequence conservation strategies, means of replication and specific interactions with host and helper viruses is improving. This review demonstrates that the molecular interactions of these satellites are unique and highly complex, largely influenced by the highly specific host plants and helper viruses that they associate with. Circularized forms of single-stranded RNA are of particular interest, as they have recently been found to play a variety of novel cellular functions. Linear forms of satRNA are also of great significance as they may complement the helper virus genome in exacerbating symptoms, or in certain instances, actively compete against it, thus reducing symptom severity. This review serves to describe the current literature with respect to these molecular mechanisms in detail as well as to discuss recent insights into this emerging field in terms of evolution, classification and symptom development. The review concludes with a discussion of future steps in plant viral satellite research and development.

Impact of Nucleic Acid Sequencing on Viroid Biology

The early 1970s marked two breakthroughs in the field of biology: (i) The development of nucleotide sequencing technology; and, (ii) the discovery of the viroids. The first DNA sequences were obtained by two-dimensional chromatography which was later replaced by sequencing using electrophoresis technique. The subsequent development of fluorescence-based sequencing method which made DNA sequencing not only easier, but many orders of magnitude faster. The knowledge of DNA sequences has become an indispensable tool for both basic and applied research. It has shed light biology of viroids, the highly structured, circular, single-stranded non-coding RNA molecules that infect numerous economically important plants. Our understanding of viroid molecular biology and biochemistry has been intimately associated with the evolution of nucleic acid sequencing technologies. With the development of the next-generation sequence method, viroid research exponentially progressed, notably in the areas of the molecular mechanisms of viroids and viroid diseases, viroid pathogenesis, viroid quasi-species, viroid adaptability, and viroid–host interactions, to name a few examples. In this review, the progress in the understanding of viroid biology in conjunction with the improvements in nucleotide sequencing technology is summarized. The future of viroid research with respect to the use of third-generation sequencing technology is also briefly envisaged.

Novel coding, translation, and gene expression of a replicating covalently closed circular RNA of 220 nt

The highly structured (64% GC) covalently closed circular (CCC) RNA (220 nt) of the virusoid associated with rice yellow mottle virus codes for a 16-kDa highly basic protein using novel modalities for coding, translation, and gene expression. This CCC RNA is the smallest among all known viroids and virusoids and the only one that codes proteins. Its sequence possesses an internal ribosome entry site and is directly translated through two (or three) completely overlapping ORFs (shifting to a new reading frame at the end of each round). The initiation and termination codons overlap UGAUGA (underline highlights the initiation codon AUG within the combined initiation-termination sequence). Termination codons can be ignored to obtain larger read-through proteins. This circular RNA with no noncoding sequences is a unique natural supercompact "nanogenome."

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

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

Circular single-stranded RNA replicon in Saccharomyces cerevisiae

Circular RNA replicons have been reported in plants and, in one case, in animal cells. We describe such an element in yeast. In certain yeast strains, a 20S RNA species appears on transfer of cells to acetate medium. This phenotype shows cytoplasmic (non-Mendelian) inheritance and the 20S RNA is associated with 23-kDa protein subunits as a 32S particle. We demonstrate that yeast 20S RNA is an independent replicon with no homology to host genomic, mitochondrial, or 2-microns plasmid DNA or to the L-A, L-BC, or M1 double-stranded RNA viruses of yeast. The circularity of the 20S RNA is shown by the apparent absence of 3' and 5' ends, by two-dimensional gel electrophoresis, and by electron microscopy. Replication of yeast 20S RNA proceeds through an RNA-RNA pathway, and a 10,000-fold amplification occurs on shift to acetate medium. The copy number of 20S RNA is also reduced severalfold by the SKI gene products, a host antiviral system that also lowers the copy numbers of yeast double-stranded RNA viruses. Yeast 20S RNA and the hepatitis delta virus show some similarities.

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 and replication of the genome of the hepatitis delta virus

The hepatitis delta virus can be found in the serum and liver of some hepatitis B virus patients. We now report that the RNA genome of serum-derived delta virus is single-stranded and circular. Livers of infected chimpanzees or woodchucks contained as many as 300,000 copies of genomic strand RNA per average cell, and at least some of this RNA had a circular conformation. Also present in the livers were RNA species complementary to the virion RNA. The genomic RNA was 5-22 times more abundant than this antigenomic strand. Some of the antigenomic RNA was complexed with genomic RNA, as evidenced by the fact that at least 34% of the antigenomic RNA was resistant to digestion with either RNase A in 0.3 M NaCl or S1 nuclease. Some of the antigenomic RNA was in a circular conformation. These and other findings showed that the structure and replication of hepatitis delta virus are in many ways similar to those of the previously described plant viroids, virusoids, and satellite RNAs.

Structure, sequence and expression of the hepatitis delta (delta) viral genome

Biochemical and electron microscopic data indicate that the human hepatitis delta viral agent contains a covalently closed circular and single-stranded RNA genome that has certain similarities with viroid-like agents from plants. The sequence of the viral genome (1,678 nucleotides) has been determined and an open reading frame within the complementary strand has been shown to encode an antigen that binds specifically to antisera from patients with chronic hepatitis delta viral infections.

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.

Relationship of viroids and certain other plant pathogenic nucleic acids to group I and II introns

The nucleotide sequences of viroids contain features believed to be essential for the splicing of group I introns. Common sequence elements include a 16-nucleotide consensus sequence and three pairs of short sequences arranged in the same sequential order in both types of RNAs. The calculated probability of finding sequences resembling the 16-nucleotide consensus sequence in random nucleotide chains showed that at low fidelity (up to 5 mismatched nucleotides), the number of such sequences in viroids, plant viral satellite RNAs, plant viral RNAs and one plant viral DNA, group I introns and flanking exons does not significantly differ from the number expected at random. As the degree of fidelity is increased, the number in both introns and viroids, but not in exons or the other plant pathogens examined, greatly exceeds that expected in random chains. These findings suggest that viroids may have evolved from group I introns and/or that processing of viroid oligomers to monomers may have structural requirements similar to those of group I introns. The nucleotide sequences of viroids do not show close homology with two conserved regions of group II introns, the 14-base pair consensus region and the 5' terminal segment. However, close homology does exist between the conserved sequence of the 3' terminal segment of group II introns and viroids thus suggesting a possible evolutionary or functional relationship.

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.

Infectivity and in vitro mutagenesis of monomeric cDNA clones of citrus exocortis viroid indicates the site of processing of viroid precursors

Monomeric cDNA clones of citrus exocortis viroid (CEV) were constructed in the plasmid vector pSP6-4 and the infectivity of the clones plus in vitro-synthesized RNA transcripts determined by inoculation onto tomato seedlings. Infectivity was dependent on the site of the viroid molecule used for cloning and the orientation of the cDNA insert. Only the plus BamHI cDNA clone was infectious and produced progeny viroid with wild-type sequence at the region corresponding to the BamHI cloning site. Infectivity correlated with the terminal repetition of 11 nucleotides of viroid sequence, 5'GGATCCCCGGG 3', in the vector adjacent to the insert. The 11-nucleotide sequence lies within the highly conserved central region of viroids. Site-directed mutagenesis of a single nucleotide in the repeat at the 5'-end of the CEV insert to 5' GGATCCCC(T,A)GG 3' gave two point mutants. The two mutant CEV inserts, when excised from the vector, were not infectious. However, plasmid DNA and RNA transcripts from non-excised mutant CEV inserts were infectious. The progeny of one of these clones was examined and contained wild-type sequence. It was concluded that in vivo processing of longer-than-unit-length CEV occurs at one of three adjacent sites in the 11 nucleotide sequence and that the G nucleotide at position 97 is important for viroid replication.

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.

Nucleotide sequence of the satellite of peanut stunt virus reveals structural homologies with viroids and certain nuclear and mitochondrial introns

Peanut stunt virus-associated RNA 5 (PARNA 5), the satellite of a plant cucumovirus, is a linear RNA of 393 nucleotides with a 5' cap and a 3' hydroxyl group. Determination of its nucleotide sequence has revealed two consecutive open reading frames that together extend most of its length. Sequences at the 5' and 3' ends are homologous with those of the satellite of the related cucumber mosaic virus, and the double-stranded forms of both satellites contain an unpaired guanosine at the 3' end of the minus strand. However, little other homology exists between the two satellites. In contrast, PARNA 5 has several regions of 90% sequence homology with various plant viroids, including sequences of the conserved central region of most viroids. Such homologies suggest a common origin with viroids coupled with specific adaptation as a linear RNA. The presence within PARNA 5 of conserved intron sequences essential to proper RNA processing suggests a possible origin from plant introns and/or involvement of such sequences in the processing of PARNA 5 multimers to monomers at some stage of replication.

Eleven new sequence variants of citrus exocortis viroid and the correlation of sequence with pathogenicity

Full-length double-stranded cDNA was prepared from purified circular RNA of two new Australian field isolates of citrus exocortis viroid (CEV) using two synthetic oligodeoxynucleotide primers. The cDNA was then cloned into the phage vector M13mp9 for sequence analysis. Sequencing of nine cDNA clones of isolate CEV-DE30 and eleven cDNA clones of isolate CEV-J indicated that both isolates consisted of a mixture of viroid species and led to the discovery of eleven new sequence variants of CEV. These new variants, together with the six reported previously, form two classes of sequence which differ by a minimum of 26 nucleotides in a total of 370 to 375 residues. These two classes correlate with two biologically distinct groups when propagated on tomato plants where one produces severe symptoms and the other gives rise to mild symptoms. Two regions of the native structure of CEV, comprising 18% of the total residues, differ between the sequence variants of mild and severe isolates. Whether or not both of these regions are essential for the variation in pathogenicity has yet to be determined.

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.

Molecular cloning of potato spindle tuber viroid (PSTV) cDNA synthesized by enzymatic elongation of PSTV-specific DNA primers: a general strategy for viroid cloning

Different cDNAs were synthesized by primer extension from the RNA of the severe strain KF 440 of potato spindle tuber viroid (PSTV) with the aid of reverse transcriptase using three PSTV-specific DNA molecules as primers. The cDNAs were made double-stranded and cloned into plasmid pBR 322. Various overlapping subgenomic DNA fragments were prepared from these clones and recombined in two different ways. In both cases a PSTV DNA copy was obtained which represented the entire PSTV RNA genome. The sequence of the DNA of one of the resulting full-length clones was identical with the original PSTV isolate, whereas the other clone showed one nucleotide change. On the basis of these results the advantages and problems of different strategies for the molecular cloning of the circular viroid RNA genome are discussed.

Detection of avocado sunblotch viroid by hybridization with synthetic oligonucleotide probes

Two short (20 and 17 nucleotides) DNA hybridization probes, complementary to avocado sunblotch viroid (ASBV) RNA nucleotides 68-87 and 88-104 respectively (Symons, R.H., Nucleic Acid Res. 9, 6527, 1981) were synthesized. The sensitivity and specificity of these radioactively labelled probes for hybridization with RNA of several ASBV isolates are demonstrated.