Genomic Structure of Three Phenotypically Different Isolates of Peach Latent Mosaic Viroid: Implications of the Existence of Constraints Limiting the Heterogeneity of Viroid Quasispecies

The peach latent mosaic viroid (PLMVd) is used to study the interactions between a viroid containing hammerhead ribozymes and its natural host, peach. To gain insight into the molecular basis of the phenotypic effects observed upon viroid infection, sequence variants from three PLMVd isolates that differ in symptom expression on the peach indicator GF-305 have been characterized. Analysis of the primary structures of a total of 29 different sequence variants derived from a severe and two latent isolates has revealed a large number of polymorphic positions in the viroid molecule. The variability pattern indicates that preservation of the stability of both hammerhead structures and conservation of a branched secondary structure of the viroid molecule may be factors limiting sequence heterogeneity in PLMVd. Moreover, compensatory mutations in two hairpin loops of the proposed secondary structure, suggesting that a pseudoknot-like interaction may exist between them, have also been observed. Phylogenetic analysis has allowed the allocation of PLMVd molecules into three major groups. This clustering does not strictly correlate with the source isolate from which the variants were obtained, providing insights into the complex mixture of molecules which make up each isolate. Bioassays of individual PLMVd sequence variants on GF-305 peach seedlings have shown that the biological properties of the PLMVd isolates may be correlated with both the complexity of their viroid populations and the presence of specific sequence variants.     

Chrysanthemum stunt viroid: primary sequence and secondary structure.

The sequence of the 356 nucleotide residues of chrysanthemum stunt viroid (CSV) has been determined. Overlapping linear viroid fragments were obtained by partial ribonuclease digestion, radiolabelled in vitro at their 5'-ends, and sequenced using partial enzymic cleavage methods. Of the CSV sequence, 69% is contained in the published sequence of potato spindle tuber viroid (PSTV). Differences in the primary sequence of CSV and PSTV suggest that neither the positive nor putative negative strands of these two viroids code for functional polypeptide products. However, the two viroids can form similar secondary structures, implicating a role for viroid structure in replication.     

Mutational analysis of viroid pathogenicity: tomato apical stunt viroid

A series of nucleotide substitutions within the pathogenicity domain of tomato apical stunt viroid have been evaluated for their effects upon infectivity and symptom expression. None of the 12 A----G substitutions and one C----U substitution that were examined abolished infectivity in a whole plant bioassay, and the resulting progeny were characterized by nucleotide sequence analysis of cDNAs amplified by the polymerase chain reaction. Four of the 13 substitutions gave rise to altered progeny, but the patterns of sequence changes observed were unexpectedly complex. Mutations that did not rapidly revert to the wild-type sequence are located near the right border of the pathogenicity domain, a region which shows considerable natural sequence variability. None had a detectable effect upon symptom expression. The ability to observe viroid sequence evolution in vivo may provide insight into the molecular interactions responsible for viroid host range and symptom formation.     

Grapevine yellow speckle viroid: structural features of a new viroid group.

A single stranded circular RNA was isolated from grapevines infected with yellow speckle disease. The RNA which we have called grapevine yellow speckle viroid (GYSV), contains 367 nucleotide residues and has the potential to form the rod-like secondary structure characteristic of viroids. GYSV has 37% sequence homology with the recently described apple scar skin viroid (ASSV; 330 residues) and has some sequence homology with the viroids in the potato spindle tuber viroid (PSTV) group. The sequence of GYSV has characteristics which fit the structural domains described for the PSTV group. However, GYSV lacks the PSTV central conserved sequence. Instead, there is a conserved sequence in the central region of GYSV and ASSV which has the potential to form a stem loop configuration and a stable palindromic structure as does the central conserved region of the PSTV group. These structural features suggest there is a different central conserved region for GYSV and ASSV. The results support the viroid nature of GYSV and its inclusion into a separate viroid group which we suggest should be represented by ASSV.     

Australian grapevine viroid--evidence for extensive recombination between viroids.

Australian grapevine viroid (AGV, 369 residues) is a novel viroid with less than 50% sequence similarity with any known viroid. Nevertheless its entire sequence can be divided into regions, each with a high sequence similarity with segments from one of citrus exocortis, potato spindle tuber, apple scar skin, and grapevine yellow speckle viroids. AGV contains the entire central conserved region of the apple scar skin viroid group and is proposed as a member of this group. AGV appears to have originated from extensive RNA recombination involving other viroids. The vegetatively propagated grapevines which have been exposed to multiple viroid infections during their long history of cultivation may have allowed such recombination.     

Deep sequencing of small RNAs in tomato for virus and viroid identification and strain differentiation

Small RNAs (sRNA), including microRNAs (miRNA) and small interfering RNAs (siRNA), are produced abundantly in plants and animals and function in regulating gene expression or in defense against virus or viroid infection. Analysis of siRNA profiles upon virus infection in plant may allow for virus identification, strain differentiation, and de novo assembly of virus genomes. In the present study, four suspected virus-infected tomato samples collected in the U.S. and Mexico were used for sRNA library construction and deep sequencing. Each library generated between 5-7 million sRNA reads, of which more than 90% were from the tomato genome. Upon in-silico subtraction of the tomato sRNAs, the remaining highly enriched, virus-like siRNA pools were assembled with or without reference virus or viroid genomes. A complete genome was assembled for Potato spindle tuber viroid (PSTVd) using siRNA alone. In addition, a near complete virus genome (98%) also was assembled for Pepino mosaic virus (PepMV). A common mixed infection of two strains of PepMV (EU and US1), which shared 82% of genome nucleotide sequence identity, also could be differentially assembled into their respective genomes. Using de novo assembly, a novel potyvirus with less than 60% overall genome nucleotide sequence identity to other known viruses was discovered and its full genome sequence obtained. Taken together, these data suggest that the sRNA deep sequencing technology will likely become an efficient and powerful generic tool for virus identification in plants and animals.     

Some properties of the viroid inducing peach latent mosaic disease

Analysis by polyacrylamide gel electrophoresis of nucleic acid extracts from different peach samples, healthy or infected with the peach latent mosaic (PLM) disease, demonstrated the association of this disease with an RNA exhibiting the electrophoretic properties typical of circular viroid molecules. This RNA was called peach latent mosaic viroid (PLMV), since a purified preparation of it, when inoculated into GF 305 peach seedlings induced characteristic symptoms of PLM disease. PLMV was estimated to have a molecular size in the range of 330–340 bases, by comparison of its electrophoretic mobility under denaturing conditions with those of several viroid RNA. Dot-blot analysis showed that PLMV has a sequence clearly different from other viroids, including citrus exocortis viroid, apple scar skin viroid (ASSV), hop stunt viroid (HSV) and avocado sunblotch viroid. The possible significance of the limited sequence homology shared by PLMV with HSV, and especially with ASSV, is discussed.     

The molecular structure of hop latent viroid (HLV), a new viroid occurring worldwide in hops.

A new viroid which does not seem to produce any symptoms of disease, and is therefore tentatively named hop latent viroid (HLV) was found to occur worldwide in hops. HLV proved to be infectious when mechanically inoculated onto viroid- and virus-free hops. The viroid nature of HLV was also substantiated by sequence analysis which revealed that HLV is a circular RNA consisting of 256 nucleotides, that can be arranged into the viroid-specific, rod-like secondary structure. HLV also contains the central conserved region typical for most of the presently known viroids. However HLV does not contain the viroid-specific oligo(A) stretch in the upper left part of its rod-like molecule. Because of this feature and a sequence similarity with the prototypes of the other viroid groups below 55%, HLV can be regarded as the first member of a new viroid group.     

Variations in the "cross protection" effect between two strains of citrus exocortis viroid

In a survey conducted to evaluate the biological properties of several field sources that induced a severe exocortis reaction on citron (Citrus medica L.), a viroid isolate which induced mild symptoms on Gynura aurantiaca was detected. This isolate was characterised as a strain of the citrus exocortis viroid (CEV) by size and homology, and was designated as CEV-129. Cross protection assays using CEV-129 as a “protecting” strain against the severe type strain of CEV demonstrated that a mild strain of CEV could provide apparent ‘protection’ against challenge inoculations with the severe strain. The protection effect, however, displayed a variability which ranged from only a brief delay to almost total impairment of symptom expression. The level of protection was dependent upon the length of the interval between the inoculations with the mild and the severe strains. In all cases the effect was temporary since the symptoms and viroid concentration which ultimately prevailed reflected the predominance of the severe strain in the mixed infection. The interpretation of these results and their relationship with previous reports of ‘cross protection’ reactions are discussed along with the consideration of the efficacy and limitations of this term with viroid infection.     

Nucleotide sequence and secondary structure of apple scar skin viroid.

The complete nucleotide sequence of apple scar skin viroid(ASSV) has been established, and a probable secondary structure is proposed. A single-stranded circular ASSV RNA consists of 330 nucleotides and can assume the rodlike conformation with extensive base-pairing characteristic of all the known viroids. ASSV shows low sequence homologies with other viroids and lacks the central conserved region. These indicate that ASSV should be allocated to a separate viroid group. However, homologous sequences with potato spindle tuber viroid(PSTV) in ASSV occur in limited and scattered regions of both viroids. These homologous regions fall within the particular domains in the viroid domain model which has been previously proposed by Keese and Symons(Proc. Natl. Acad. Sci. USA. 82, 4582-4586, 1985).     

Deep-Sequencing of the Peach Latent Mosaic Viroid Reveals New Aspects of Population Heterogeneity

Viroids are small circular single-stranded infectious RNAs characterized by a relatively high mutation level. Knowledge of their sequence heterogeneity remains largely elusive and previous studies, using Sanger sequencing, were based on a limited number of sequences. In an attempt to address sequence heterogeneity from a population dynamics perspective, a GF305-indicator peach tree was infected with a single variant of the Avsunviroidae family member Peach latent mosaic viroid (PLMVd). Six months post-inoculation, full-length circular conformers of PLMVd were isolated and deep-sequenced. We devised an original approach to the bioinformatics refinement of our sequence libraries involving important phenotypic data, based on the systematic analysis of hammerhead self-cleavage activity. Two distinct libraries yielded a total of 3,939 different PLMVd variants. Sequence variants exhibiting up to ∼17% of mutations relative to the inoculated viroid were retrieved, clearly illustrating the high level of divergence dynamics within a unique population. While we initially assumed that most positions of the viroid sequence would mutate, we were surprised to discover that ∼50% of positions remained perfectly conserved, including several small stretches as well as a small motif reminiscent of a GNRA tetraloop which are the result of various selective pressures. Using a hierarchical clustering algorithm, the different variants harvested were subdivided into 7 clusters. We found that most sequences contained an average of 4.6 to 6.4 mutations compared to the variant used to initially inoculate the plant. Interestingly, it was possible to reconstitute and compare the sequence evolution of each of these clusters. In doing so, we identified several key mutations. This study provides a reliable pipeline for the treatment of viroid deep-sequencing. It also sheds new light on the extent of sequence variation that a viroid population can sustain, and which may give rise to a quasispecies.     

Transmission of Three Viroids Through Seed and Pollen of Tomato Plants

The severe strain of potato spindle tuber viroid (s-PSTV) as well as chrysanthemum stunt (CSV) and cucumber pale fruit (CPFV) viroids were found to be transmitted through seed and pollen of the tomato cvs. Rutgers and Najwcze?niejszy. Plants pollinated with a pollen infected with any of these three viroids became systematically infected. Plant, fruit and seed symptoms of viroid infection were noted on sap- and pollen-inoculated plants and the yield of these plants was reduced. Tomato cv. Rutgers plants grown from infected seeds were symptomless although all three viroids were detected in these plants by bioassay and by electrophoresis on 5% polyacrylamide gel. When DNA complementary to s-PSTV RNA was used for a direct viroid detection in seed samples by spot hybridization technique it hybridized not only with s-PSTV RNA but also with CSV RNA as well as with CPFV RNA.     

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

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

Avocado sunblotch viroid: primary sequence and proposed secondary structure.

The sequence of the 247 nucleotide residues of the single strand circular RNA of avocado sunblotch viroid (ASBV) was determined using partial enzymic cleavage methods on overlapping viroid fragments obtained by partial ribonuclease digestion followed by 32p-labelling in vitro at their 5'-ends. ASBV is much smaller than potato spindle tuber viroid (PSTV; 359 residues) and chrysanthemum stunt viroid (CSV; 356 residues). A secondary structure model for ASBV is proposed and contains 67% of its residues base paired. In contrast to the extensive (69%) sequence homology of CSV with PSTV, only 18% of the ASBV sequence is homologous to PSTV and CSV. There are eight potential polypeptide translation products with chain lengths from 4 to 63 amino acid residues coded for by the plus (infectious) strand and four potential translation products (2 to 60 residues) coded for by the minus strand. An improved method is described for the synthesis of gamma-32p-ATP of high specific activity.