An ultraviolet-sensitive RNA structural element in a viroid-like domain of the hepatitis delta virus.

The RNA genome of the hepatitis delta virus (HDV) appears to be made up of two parts: a small domain with a high degree of sequence conservation and structural features likely to promote replication; plus a second, larger domain that is less conserved and encodes the delta antigen. This report focuses on one of the several sets of data that have led to the proposal of this model: the existence of a novel structural element in HDV genomic RNA. This structural element lies within the highly conserved domain of HDV RNA and may be related to the local tertiary structure previously mapped to the central conserved region of the plant viroid genome. Both elements occur in regions with no apparent coding capacity and are distinctively responsive to ultraviolet (UV) light. Transcripts containing partial and full-length genomic sequences of HDV readily undergo a UV-induced crosslinking reaction, which establishes a covalent bond between two noncontiguous segments. By locking two segments of the overall structure into place, this crosslink has permitted the unbranched, rodlike model of HDV RNA to be examined and confirmed in the portion of the RNA analyzed. The clustering of the novel tertiary structure and the recently discovered self-cleavage sites into a highly conserved, but apparently noncoding, portion of the genome defines a viroid-like domain in HDV RNA and raises questions about the possible events leading up to the association of free-living RNAs with messenger RNAs and other RNA molecules.

Ultraviolet light-induced crosslinking reveals a unique region of local tertiary structure in potato spindle tuber viroid and HeLa 5S RNA.

The positions of intramolecular crosslinks induced by irradiation with ultraviolet light were mapped into potato spindle tuber viroid RNA and HeLa 5S rRNA. Crosslinking in each of these molecules occurred at a single major site, which was located by RNA fingerprinting and secondary analysis (and additional primer extension studies in the case of the viroid). Various lines of evidence suggest that these crosslinks identify a previously undescribed element of local tertiary structure common to these two widely divergent RNA molecules: (i) both crosslinks occur in an identical eight-base context, with the sequence 5' GGGAA 3' on one side and the sequence 5' UAC 3' on the other; (ii) both crosslinks connect bases that are not thought to be involved in conventional hydrogen bonding, within regions usually depicted as single-stranded loops flanked by short helical segments; and (iii) both crosslinks connect a purine and a pyrimidine residue, and both may generate the same G-U dimer. Furthermore, it is likely that the crosslinking site is of functional significance because it is located within the most highly conserved region of the viroid sequence and involves bases that are essentially invariant among eukaryotic 5S rRNA molecules.

Unusual properties of two branched RNA's with circular and linear components.

Irradiation with ultraviolet light was used to create two nonlinear RNA molecules. Circular potato spindle tuber viroid (PSTV) RNA was crosslinked at a single site to generate a figure eight-shaped molecule; 5S rRNA from HeLa cells was transformed into an alpha-shaped molecule with a small circular element and two arms (1). Crosslinked RNA's could be separated from their untreated counterparts by electrophoresis in polyacrylamide gels containing urea. The gel mobility of crosslinked PSTV was not altered by boiling, treatment with E. coli RNase III or glyoxalation. However, mild nuclease digestion ("nicking") produced derivatives which migrated more slowly than the starting material in gels of certain polyacrylamide concentrations, but not in others. Limited nuclease digestion of crosslinked 5S rRNA did not generate any detectable products with reduced mobility in the gels tested. Thus, the ability of the "nicking assay" to reveal circular elements within nonlinear RNA's can vary depending upon the composition of the gel chosen for analysis and on the size of the circular element relative to the rest of the molecule.

Evidence for a single rolling circle in the replication of potato spindle tuber viroid.

We analyzed in vivo-labeled RNA to determine which of the two proposed rolling-circle models is more likely to depict the replication cycle of potato spindle tuber viroid. A key feature distinguishing the two models is the presence of a circular monomeric minus strand in one and not the other. Chromatography on cellulose CF11 was used to purify a fraction containing the replication intermediates free from single-stranded progeny. Heat denaturation followed by gel electrophoresis was used to seek possible circular templates-species required for rolling-circle replication to take place. Upon heating, a (32)P-labeled RNA was released. Limited nuclease digestion ("nicking") revealed that this was a unitlength circular RNA. Fingerprinting identified it as a plus strand. No circular minus strands were detected in this population or in nuclease-treated samples containing RNase T1-resistant cores of the replication complex. Thus, potato spindle tuber viroid appears to use an asymmetric pathway in which minus strands are synthesized by rolling-circle copying, but plus strands are not. More details of the replication pathways used by various viroid-like RNAs are needed and will help to establish the evolutionary relationships among these infectious agents.

Interference between coinoculated viroids.

Experiments were carried out to seek evidence of an interaction between two viroid RNAs introduced to tomato plants in the same inoculum. At the level of symptom expression, the severe isolate of potato spindle tuber viroid (PSTV) dominated the mild isolate. Seventy-five percent of the plants inoculated with a 100-fold excess of the mild isolate developed unattenuated symptoms of severe disease. Other experiments revealed that infectious RNA molecules transcribed from cloned DNA templates containing PSTV sequences reduced the level of hop stunt viroid (HSV) RNA present in nucleic acid extracts of plants which had been inoculated with a mixture of dimeric plus-strand transcripts of these two viroids. Plants inoculated with dual transcripts--containing two copies of PSTV linked to two copies of HSV--developed characteristic symptoms of severe PSTV. Dot hybridization demonstrated that only PSTV replicated to detectable levels in these plants. A likely interpretation of these results is that the HSV portion of the dual transcripts failed to replicate because of interference from PSTV. These results raise questions about how the process of viroid replication is related to symptom expression, and lead to suggested models for the effect of viroid-like RNAs in cells under both normal and pathogenic circumstances.