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.     

Determination of potato spindle tumor viroid and chrysanthenum stund viroid using biotinylated olideoxyribonucleotides]

A 26 base long oligodeoxyribonucleotide complementary to a common RNA sequence of potato spindle tuber viroid (PSTV) and chrysantemum stunt viroid (CSV) was synthesized. The 3'-end biotinylated one was used for the detection of PSTV and CSV RNA immobilized on nitrocellulose filters by nucleic acid hybridization. Visualization of hybridization results was performed by two ways, either by streptavidin-alkaline phosphatase conjugate or streptavidine and biotinylated alkaline phosphatase. It was possible to detect 0.65 ng of purified CSV and PSTV RNA. The suggested system of viroid diseases detection can be used by agricultural and horticultural enterprises.     

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.     

Site-specific mutagenesis of potato spindle tuber viroid cDNA:

Summary The infectivity of cloned viroid cDNAs permits investigation of structure/function relationships in these unusual pathogenic RNAs by systematic site-specific mutagenesis of the cDNAs and subsequent bioassay. We have used three different strategies to create nucleotide substitutions within premelting region 2, a region of potato spindle tuber viroid (PSTV) believed to be important in viroid replication: sodium bisulfitecatalyzed deamination of deoxycytosine residues, oligonucleotide-directed mutagenesis, and construction of chimeric viroid cDNAs from fragments of infectious PSTV and tomato apical stunt viroid cDNAs. Although their effects upon the rod-like native structure of PSTV should be minimal, C U transitions at positions 92 or 284 appeared to be lethal. When inoculation with PSTV cDNA containing a single nucleotide substitution was mediated by the Ti plasmid of Agrobacterium tumefaciens, PSTV progeny with an unaltered wild type sequence was obtained. Two factors, the high error frequency characteristic of RNA synthesis and the use of a systemic bioassay for PSTV replication, may explain such sequence reversion and emphasize the importance of an appropriate bioassay system for screening mutant viroid cDNAs.     

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

A suspension culture from potato spindle tuber viroid (PSTV)-infected cells of the wild type potato (Solanum demissum) has been established, which is a suitable model system for studying PSTV replicationin vivo. The conditions for rapid growth of these cells and for permanent extensive viroid biosynthesis within them are described. Biosynthesis of PSTV in the potato cells was demonstrated by³²P-incorporation into nucleic acids and their subsequent electrophoretic analysis on polyacrylamide gels. Under optimum culture conditions the amount of³²P-orthophosphate incorporation into PSTV reached 10% of that incorporated into the 2 M LiCl-soluble cellular RNA. (+)PSTV and its complementary form, i.e. (?)PSTV were identified after their electrophoretic separation on polyacrylamide and agarose gels by molecular hybridization. This analysis revealed the presence of six high molecular weight(?)PSTV species, which are possibly multimers of the unit length(+)PSTV molecule consisting of 359 nucleotides.     

Cloning of Chrysanthium stund virion cDNA in pUC19 plasmid and the use of cloned cDNA for detecting the virion]

26 base long deoxyribonucleotide complementary to the lower part of the Central Conserved Region of chrysanthemum stund viroid (CSV) was used for synthesis of the first strand cDNA. The cDNA was cloned into plasmid vector pUC19 and the primary structure was determined. Cloned, full length cDNA was used as hybridisation probe for detection of CSV. It was possible to detect about 26 pg of purified CSV RNA immobilized on nitrocellulose filters using 32P-labeled probe. In the case of biotinylated probe it was possible to detect about 26 pg of purified CSV RNA visualizing results by streptavidin-alkaline phosphatase conjugates. It has been shown that such a cloned cDNA can be used for wide scale detection of CSV.     

Detection of avocado sunblotch viroid (ASBV) by dot-spot self-hybridization with a [32P]-labelled ASBV-RNA

RNA was extracted from plants infected with avocado sunblotch viroid (ASBV) and was analyzed by electrophoresis in polyacrylamide gel. The ASBV related fraction was eluted from the gel, labelled with [³²P] using polynucleotide kinase and used as a probe for hybridization with a purified ASBV-RNA preparation dot spotted on nitrocellulose paper. Positive self-hybridization indicated a high degree of internal complementarity. Dot spots of whole cell RNA and of leaf sap from ASBV infected plants were shown to hybridize with the labelled probe. This hybridization procedure proved to be 16–64 times more sensitive in diagnosing ASBV when compared with polyacrylamide gel analysis.     

Nucleotide sequence and proposed secondary structure of Columnea latent viroid: a natural mosaic of viroid sequences.

The Columnea latent viroid (CLV) occurs latently in certain Columnea erythrophae plants grown commercially. In potato and tomato, CLV causes potato spindle tuber viroid (PSTV)-like symptoms. Its nucleotide sequence and proposed secondary structure reveal that CLV consists of a single-stranded circular RNA of 370 nucleotides which can assume a rod-like structure with extensive base-pairing characteristic of all known viroids. The electrophoretic mobility of circular CLV under nondenaturing conditions suggests a potential tertiary structure. CLV contains extensive sequence homologies to the PSTV group of viroids but contains a central conserved region identical to that of hop stunt viroid (HSV). CLV also shares some biological properties with each of the two types of viroids. Most probably, CLV is the result of intracellular RNA recombination between an HSV-type and one or more PSTV-type viroids replicating in the same plant.     

Amino acid sequence of the ;pathogenesis-related' leaf protein p14 from viroid-infected tomato reveals a new type of structurally unfamiliar proteins

We have established the complete sequence of the 130 amino acid residues of the pathogenesis-related (PR) protein p14 accumulating in tomato leaves infected with the viroid of the spindle tuber disease of potato (PSTV) and partial sequences of the PR protein 1a which accumulates in tobacco mosaic virus-infected tobacco leaves. Both PR proteins are closely related to each other. However, no homology could be found between the sequence of p14 and any of the 3061 published protein sequences compiled in the protein sequence database at present. Thus, p14 represents not only the first completely sequenced PR plant protein but also a new type of structurally unfamiliar proteins whose biological function in the diseased plant remains to be elucidated.     

Continous replication of potato spindle tuber viroid (PSTV) in permanent cell cultures of potato and tomato

The continuous replication of potato spindle tuber viroid (PSTV) in callus cultures from PSTV-infected wild-type potato (Solanum dem/ssum L.) and tomato (Lycopersicon peruvianum L. Mill) plants and in cell suspensions derived from potato protoplasts (Solanum tuberosum L.) inoculatedin vitro is described. The persistence of PSTV replication in these cell lines through at least 14 subculture passages, which corresponds to a continous replication over a period of more than one year, was demonstrated by infectivity assay and by polyacrylamide-gel electrophoresis of isolated nucleic acids. This continuous synthesis denovo of PSTV was substantiated by the incorporation of [³H]uridine and of [³²P]orthophosphate into viroid RNA.     

Studies on the primary and secondary structure of potato spindle tuber viroid: products of digestion with ribonuclease A and ribonuclease T1, and modification with bisulfite.

Potato spindle tuber viroid (PSTV), a small infectios RNA, has been completely digested with RNase T1 and RNase A, and the resulting oligonucleotides have been sequenced using 5'-terminal 32p-labelling with gamma-32p ATP and T4 polynucleotide kinase, fingerprinting and controlled nuclease P1 digestion. Modified nucleotides have not been detected in 5'-positions of these oligonucleotides. PSTV consists of about 359 nucleotides and contains a remarkable stretch of 18 purines, mainly adenosines; there is no AUG initiation triplet present. The established oligonucleotide sequences preclude a perfect intramolecular base complementarity within the covalently closed viroid circle. Therefore, the rigid, rod-like native secondary structure of PSTV, as seen in the electron microscope, must be based on a defective rather than on a homogeneous RNA helix. The detailed analysis of the bisulfite-catalized modification of cytidine to uridine in PSTV revealed a higher reactivity for the majority of the cytidines than would be expected for a perfect helix. Since only cytidines in single-stranded regions are knonw to be fully reactive, this finding provides additional evidence for defects in the helical secondary structure of PSTV.     

Correlation between structure and pathogenicity of potato spindle tuber viroid (PSTV)

Sequence analysis by primer-extension at the level of their cDNA showed that the RNA genomes of various field isolates of potato spindle tuber viroid (PSTV) of different virulence differ from each other only in a few nucleotides in two distinct regions of the rod-shaped molecule. Despite insertions and deletions the chain length of 359 nucleotides is strictly conserved in all the isolates studied. Thermodynamic calculations revealed that due to the observed sequence differences the region located at the left hand part of the rod-like secondary structure of the PSTV molecule, denoted 'virulence modulating (VM) region', becomes increasingly unstable with the increasing virulence of the corresponding isolate. Based on these data we propose in molecular terms a model for the mechanism of viroid pathogenicity. It implies that the nucleotides of the VM region specify and modulate the binding- and hence the competition-potential of the PSTV RNA molecule for a still unknown host factor(s) and thus determine the virulence of PSTV.     

The sequence of a viroid from grapevine closely related to severe isolates of citrus exocortis viroid.

The primary structure of a grapevine viroid (GVs) isolated in Spain was determined. The sequence consisted of 369 nucleotide residues forming a circular molecule. GVs presented extensive homology with viroids of the potato spindle tuber viroid (PSTV) group, that was specially high in the case of citrus exocortis viroid (CEV) both with variants found in isolates inducing severe (92% with CEV-A) and mild (89% with CEV-DE26) symptoms on tomato. The secondary structure proposed for GVs showed that the changes in the sequence in relation to CEV-A generated modifications of the secondary structure particularly important in the left terminal (Tl), variable (V) and pathogenesis (P) viroid domains that have been postulated. Nevertheless it was noted in GVs a central core in the P domain that is conserved in the class A sequence variants characteristic of severe isolates, but not in the class B ones found in mild isolates of CEV. These observations indicate that GVs should be considered as a severe isolate of CEV from grapevine (CEV-g), a suggestion that correlates with the biological properties of CEV-g both in tomato and in Gynura aurantiaca. The presence of this central core in the P domain seems to characterize all the variants of CEV inducing severe symptoms in tomato.     

应用聚合酶链式反应扩增和光敏生物素标记的cDNA探针检测马铃薯纺锤块茎类病毒

以含马铃薯纺锤块茎类病毒(potato spindle tuber viroid,PSTV)RNA的总核酸为模板,加入人工合成的互补DNA引物,用反转录酶合成PSTV cDNA;在聚合酶链式反应系统中,用两个PSTV特异性引物进行cDNA扩增,用以制备光敏生物素标记的PSTV cDNA探针。用此探针进行斑点杂交检测含PSTV的马铃薯核酸提取液和汁液均出现阳性杂交信号,而健康马铃薯的核酸提取液和汁液的结果均为阴性。光敏生物素标记探针检测纯化PSTV的灵敏度可达5pg;检测感染PSTV的马铃薯块茎汁液的可测出最高稀释度为1:400。     

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

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