A replication cycle for viroids and other small infectious RNA's

Synthesis and two-dimensional electrophoretic analysis of mixed populations of circular and linear RNAs

Spontaneous cleavage of the less abundant form of tobacco ringspot virus satellite RNA is readily reversible. Capitalizing on earlier observations by Feldstein and Bruening that small 'mini-monomer' RNAs derived from this molecule and containing little more than covalently attached ribozyme and substrate cleavage products are able to efficiently circularize, we have constructed a series of self-circularizing RNAs of precisely known size. Mixtures of linear and circular RNAs synthesized in vitro and containing 225-1132 nt could be completely resolved using a novel two-dimensional denaturing polyacrylamide gel electrophoresis system. Similar analyses of a complex mixture of coconut cadang-cadang viroid RNAs revealed the presence of relatively large amounts of a previously undescribed 'fast-slow' heterodimeric RNA species in infected palms. Only a single DNA template is required to prepare each pair of circular and linear RNA markers.

Transgenic potato expressing a double-stranded RNA-specific ribonuclease is resistant to potato spindle tuber viroid

We have produced transgenic potato lines expressing the yeast-derived double-stranded RNA-specific ribonuclease pac1. Five lines of pac1 potato (Solanum tuberosum L., cultivar Russet Burbank) challenged with potato spindle tuber viroid (PSTVd) suppressed PSTVd infection and accumulation. All of the progeny potato tubers produced by resistant plants were also free of PSTVd. Because the pac1 gene product digested PSTVd in vitro, double-stranded regions in PSTVd molecule and/or replicative intermediates may be targeted by pac1 gene product in the transgenic potato plant.

Peach latent mosaic viroid is locked by a 2',5'-phosphodiester bond produced by in vitro self-ligation

Although some viroid-like satellite RNAs possess self-cleavage and self-ligation activities, we show that the peach latent mosaic viroid (PLMVd) is unique among all known viroids since it also has such activities. These catalytic activities should have important roles in the rolling circle replication of PLMVd. According to this proposed mechanism, self-cleavage of the multimeric strands occurs via hammerhead structures producing monomers possessing 2',3'-cyclic phosphate and 5'-hydroxyl termini. In the most stable predicted secondary structure for PLMVd these two extremities are juxtaposed, in order for self-ligation to occur. To establish the nature of the phosphodiester bond produced by self-ligation, we followed the classical procedure of complete enzymatic RNA hydrolysis coupled with thin layer chromatography fractionation. Using this procedure, we report that the self-ligation of PLMVd transcripts produces almost exclusively the 2',5' isomer (>96%). Primer extension assays also revealed that reverse transcriptase can read througth this 2', 5' linkage, suggesting that it does not prevent further replication of the viroid. Moreover, we have observed that this 2',5' linkage is resistant to the debranching activity contained in nuclear extracts, as well as being capable of preventing further viroid self-cleavage. Thus, if viroids do indeed self-ligate in vivo, the resulting 2', 5'-phosphodiester bond could contribute to the stability of these RNA species. Finally, an analysis of both the sequence and the structural requirements for hammerhead self-cleavage and self-ligation suggests that these two RNA processes may be interrelated. We hypothesize that the intramolecular self-ligation which produces circular conformers may contribute to the circularization step of the rolling circle replication, while the intermolecular non-enzymatic ligation is a potential mechanism for the sequence reassortment of viroids and viroid-like species.

A 451-nucleotide circular RNA from cherry with hammerhead ribozymes in its strands of both polarities

The sequence of 451 nucleotides of a cherry small circular RNA (csc RNA1) associated with a cherry disease has been determined. Both csc RNA1 and its complementary strand can form hammerhead structures similar to those found previously in other plant and animal small RNAs. In the branched secondary structure of lowest free energy of csc RNA1, the sequences involved in the hammerhead structures, which comprise approximately one-fourth of this RNA, are found opposite each other, forming part of a rod-like segment. Plus- and minus-strand full-length transcripts of csc RNA1 self-cleaved during transcription and after purification, as predicted by the hammerhead structures, which are stable and very probably act as single hammerhead structures. The minus-strand hammerhead structure of csc RNA1 is exceptional in having a central loop with only 11 conserved nucleotides, a situation previously observed in only one other natural hammerhead structure. Both hammerhead structures of csc RNA1 are also peculiar in having an A instead of a C preceding the self-cleavage sites. The in vivo concentration of the plus strand of csc RNA1 is only slightly higher than that of its complementary strand, and significant fractions of both strands are extracted from the tissue in the form of a complex. csc RNA1 has sequence similarities to viroids and especially to some viroid-like satellite RNAs; they also share some characteristics of their corresponding hammerhead structures with these satellite RNAs. These observations, together with the association in symptomatic tissue of csc RNA1 with a set of presumably viral double-stranded RNAs, suggest that csc RNA1 is a new viroid-like satellite RNA.

Antiviral ribozymes. New jobs for ancient molecules

Catalytic RNAs are a genetic property not only of some particular viroids or viruses, but also are more common naturally among eukaryotes and even prokaryotes than earlier expected. However, the major interest in ribozymes results from their potential for development of "tailor-made" cDNA constructions designed to be transcribed into catalytic RNAs that will recognize by hybridization and destroy by specific cleavage their cellular or viral RNA targets. The efficiency of an antiviral ribozyme is determined by both the accessibility and sequence conservation of the target region, as well as the design of the ribozyme: its type, size, and composition of flanking sequences; expression rates; and cellular compartment localization. Until now the most frequently selected viral target is the human immunodeficiency virus, where an up to a 10(4)-fold inhibition in its progeny production has been achieved. Although the first generation ribozymes focused on improvements in basic design and expression rates, more recently the efficiency of antiviral catalytic activity has been increased by employing polyribozymes and/or multitarget ribozymes, as well as special constructions to enhance the cellular co-compartmentation of the ribozyme with its viral RNA target.

Plant pathogenic RNAs and RNA catalysis

The rolling circle replication of small circular plant pathogenic RNAs requires a processing step to convert multimeric intermediates to monomers which are then circularized. Eleven such RNAs are known so far, two are viroids, one is viroid-like and the remainder are satellite RNAs dependent on a helper virus for replication. The processing step is RNA-catalysed in all cases, at least in vitro. All plus forms of these RNAs self-cleave via the hammerhead structure whereas only eight of the minus RNAs self-cleave, five via the hammerhead structure and three via the hairpin structure. There are about 20 other viroids where the processing mechanism has yet to be determined but they are likely candidates for a new type of self-cleavage reaction which is predicted to be conserved in all these viroids. Hepatitis delta RNA is the only circular pathogenic RNA known to self-cleave in the animal kingdom. It is feasible that more single-stranded circular pathogenic RNAs are waiting to be discovered and these could be prospective for new types of self-cleavage reactions.

A cellular homolog of hepatitis delta antigen: implications for viral replication and evolution

Hepatitis delta virus (HDV) is a pathogenic human virus whose RNA genome and replication cycle resemble those of plant viroids. However, viroid genomes contain no open reading frames, whereas HDV RNA encodes a single protein, hepatitis delta antigen (HDAg), which is required for viral replication. A cellular gene whose product interacts with HDAg has now been identified, and this interaction was found to affect viral genomic replication in intact cells. DNA sequence analysis revealed that this protein, termed delta-interacting protein A (DIPA), is a cellular homolog of HDAg. These observations demonstrate that a host gene product can modulate HDV replication and suggest that HDV may have evolved from a primitive viroidlike RNA through capture of a cellular transcript.

RNA structure and the regulation of gene expression

RNA secondary and tertiary structure is involved in post-transcriptional regulation of gene expression either by exposing specific sequences or through the formation of specific structural motifs. An overview of RNA secondary and tertiary structures known from biophysical studies is followed by a review of examples of the elements of RNA processing, mRNA stability and translation of the messenger. These structural elements comprise sense-antisense double-stranded RNA, hairpin and stem-loop structures, and more complex structures such as bifurcations, pseudoknots and triple-helical elements. Metastable structures formed during RNA folding pathway are also discussed. The examples presented are mostly chosen from plant systems, plant viruses, and viroids. Examples from bacteria or fungi are discussed only when unique regulatory properties of RNA structures have been elucidated in these systems.

Mexican papita viroid: putative ancestor of crop viroids

The potato spindle tuber disease was first observed early in the 20th century in the northeastern United States and shown, in 1971, to be incited by a viroid, potato spindle tuber viroid (PSTVd). No wild-plant PSTVd reservoirs have been identified; thus, the initial source of PSTVd infecting potatoes has remained a mystery. Several variants of a novel viroid, designated Mexican papita viroid (MPVd), have now been isolated from Solanum cardiophyllum Lindl. (papita güera, cimantli) plants growing wild in the Mexican state of Aguascalientes. MPVd's nucleotide sequence is most closely related to those of the tomato planta macho viroid (TPMVd) and PSTVd. From TPMVd, MPVd may be distinguished on the basis of biological properties, such as replication and symptom formation in certain differential hosts. Phylogenetic and ecological data indicate that MPVd and certain viroids now affecting crop plants, such as TPMVd, PSTVd, and possibly others, have a common ancestor. We hypothesize that commercial potatoes grown in the United States have become viroid-infected by chance transfer of MPVd or a similar viroid from endemically infected wild solanaceous plants imported from Mexico as germplasm, conceivably from plants known to have been introduced from Mexico to the United States late in the 19th century in efforts to identify genetic resistance to the potato late blight fungus, Phytophthora infestans.

Viroids proper can be distinguished from hammerhead viroids and satellite RNAs through their dinucleotide composition

G + C-rich viroids proper exhibit a unique dinucleotide composition in that AU and UA are much less frequent than expected. Thus, evaluation of the dinucleotide pattern allows a quick discrimination between viroids proper and similar RNAs from plants, such as hammerhead-containing viroids, satellite RNAs, and defective interfering RNAs. In addition to sequence alignment, this method might be useful for the classification of a newly found small RNA replicon.

Casein kinase II and protein kinase C modulate hepatitis delta virus RNA replication but not empty viral particle assembly

Hepatitis delta virus (HDV) contains two virus-specific delta antigens (HDAgs), large and small forms, which are identical in sequence except that the large one contains 19 extra amino acids at the C terminus. HDAgs are nuclear phosphoproteins with distinct biological functions; the small form activates HDV RNA replication, whereas the large form suppresses this process but is required for viral particle assembly. In this study, we have characterized the phosphorylative property of HDAg in a human hepatoma cell line (HuH-7) and examined the role of phosphorylation in HDAg function. As demonstrated by in vivo labeling and kinase inhibitor experiments, the phosphorylation levels of both HDAgs were diminished by the inhibitor of casein kinase II (CKII). Nevertheless, phosphorylation of only the small form could be markedly reduced by the protein kinase C (PKC) inhibitor, suggesting different phosphorylation properties between the two HDAgs. When these two kinase inhibitors were added separately to the transient-expression system, HDV RNA replication was profoundly suppressed. In contrast, the inhibitors did not affect the assembly of empty HDAg particle from HDAgs and hepatitis B virus surface antigen. To further examine the role of phosphorylation in HDAg function, two conservative CKII recognition sites at Ser-2 and Ser-123 of both HDAgs and one potential PKC recognition site at Ser-210 of the large HDAg were altered to alanine by site-directed mutagenesis. Transfection experiments indicated that mutation at Ser-2, but not Ser-123, significantly impaired the activity of the small HDAg in assisting HDV RNA replication. This property is in accordance with our observation that Ser-2, not Ser-123, was the predominant CKII phosphorylation site in the small HDAg. Our studies also excluded the possibility that the phosphorylation of Ser-2, Ser-123, or Ser-210, had roles in the trans-suppression activity of the large HDAg, in the assembly of empty virus-like HDAg particle, and in the nuclear transport of HDAgs. In conclusion, our results indicate that both CKII and PKC positively modulate HDV RNA replication but not the assembly of empty HDAg particle. The role of CKII in HDV replication may at least in part be accounted for by the phosphorylation of Ser-2 in the small HDAg. The effect of PKC on HDV RNA replication is, however, not to mediate the phosphorylation of the conservative Ser-210 in the large HDAg but rather to act on as-yet-unidentified Ser or Thr residues in the small HDAg or cellular factors. These findings provide the first insight into the roles of phosphorylation of the two HDAgs in the HDV replication cycle.

Paradoxical interactions between human delta hepatitis agent RNA and the cellular protein kinase PKR

The genome of the human delta hepatitis agent is a circular, highly structured single-stranded RNA lacking regular runs of RNA-RNA duplex longer than 15 bp. We have tested the ability of delta agent RNA to participate in reactions with a protein containing a motif which confers the ability to bind double-stranded RNA (dsRNA). Surprisingly, highly purified delta agent RNA preparations from which all traces of contaminating dsRNA have been removed activate PKR, the dsRNA-dependent protein kinase activity of mammalian cells (also known as DAI, P1-eIF-2, and p68 kinase). This behavior is in marked contrast to the interaction of PKR with a number of other highly structured viral single-stranded RNAs, which inhibit, rather than stimulate, activation of this kinase. PKR activation leads to inhibition of protein synthesis in the rabbit reticulocyte lysate system. Paradoxically, delta RNA failed to elicit the expected PKR-mediated inhibition of cell-free translation. Instead, delta RNA interfered with PKR activation and the translational block induced by dsRNA. We conclude that the interaction of PKR and delta agent RNA may represent a new category of protein-RNA interactions involving the dsRNA binding motif.

Hepatitis delta antigens enhance the ribozyme activities of hepatitis delta virus RNA in vivo

The mechanism of regulation for the ribozyme activity of hepatitis delta virus (HDV) RNA in infected cells is unknown. Previously, we developed a direct assay capable of detecting the ribozyme activity of HDV dimer or trimer RNAs in vivo (K.-S. Jeng, A. Daniel, and M. M. C. Lai, J. Virol, 70:2403-2410, 1996). In this study, we used this method to examine the effects of hepatitis delta antigen (HDAg) on the ribozyme activities of HDV RNA in vivo. The HDV multimer cDNAs were cotransfected with plasmids encoding either HDV small delta antigen (SHDAg) or large delta antigen (LHDAg), and the self-cleavage of the primary transcripts from the HDV cDNA was analyzed at day 2 postransfection. The results were as follows. (i) Both HDAgs, particularly LHDAg, enhanced the self-cleavage activity of HDV RNA; however, HDAgs are not required for HDV RNA cleavage. (ii) HDAg could not restore the ribozyme activity of mutant HDV RNAs which have lost the ribozyme function. (iii) The enhancement of ribozyme activity by HDAg does not require HDV RNA replication. (iv) RNA-binding activity of HDAg is required for the enhancement of RNA cleavage. (v) The self-ligation activities of HDV ribozyme also were enhanced by HDAg. These results suggest that HDAg can regulate the cleavage and ligation of HDV RNA during the HDV life cycle.

Compilation and analysis of viroid and viroid-like RNA sequences

We have created a catalogue comprising all viroid and viroid-like RNA sequences which to our knowledge have been either published or were available from on-line sequence libraries as of October 1, 1995. In the development of this catalogue nomenclature ambiguities were removed, the likely ancestral sequence of most species was determined and the most stable secondary structures of these sequences were predicted using the MulFold package. Only viroids of PSTVd-type possessed a rod-like secondary structure, while most other viroids adopted branched secondary structures. Several viroids have predicted secondary structures that include either a Y or cruciform structure reminiscent of the tRNA-like end of virus genomes at an extremity. However, it remains unknown whether or not these predicted structures are adopted in solution, and if they serve a particular function in vivo. Additional information such as the position of the self-catalytic domains are included in the catalogue. An analysis of the data compilated in the catalogue is included. The catalogue will be available on the world wide web (http://www.callistro.si.usherb.ca/jpperra), on computer disk and in printed form. It should provide an excellent reference point for further studies.

A pseudoknot ribozyme structure is active in vivo and required for hepatitis delta virus RNA replication

The ribozymes of hepatitis delta virus (HDV) have so far been studied primarily in vitro. Several structural models for HDV ribozymes based on truncated HDV RNA fragments, which are different from the hammerhead or the hairpin/paperclip ribozyme model proposed for plant viroid or virusoid RNAs, have been proposed. Whether these structures actually exist in vivo and whether ribozymes actually function in the HDV replication cycle have not been demonstrated. We have now developed an in vivo ribozyme self-cleavage assay capable of detecting self-cleavage of dimer or trimer HDV RNA in vivo. By site-directed mutagenesis and compensatory mutations to disrupt and restore potential base pairing in the ribozyme domain of the full-length HDV RNA according to the various structural models, a close correlation between the detected in vivo and the predicted in vitro ribozyme activities of various mutant RNAs was demonstrated. These results suggest that the proposed in vitro ribozyme structure likely exists and functions during the HDV replication cycle in vivo. Furthermore, the pseudoknot model most likely represents the structure responsible for the ribozyme activity in vivo. All of the mutants that had lost the ribozyme activity could not replicate, indicating that the ribozyme activities are indeed required for HDV RNA replication. However, some of the compensatory mutants which have restored both the cleavage and ligation activities could not replicate, suggesting that the ribozyme domains are also involved in other unidentified functions or in the formation of an alternative structure that is required for HDV RNA replication. This study thus established that the ribozyme has important biological functions in the HDV life cycle.

Only one of four possible secondary structures of the central conserved region of potato spindle tuber viroid is a substrate for processing in a potato nuclear extract

The influence of RNA secondary structure on the substrate activity of a longer-than-unit length transcript for processing to circular viroids was studied in a nuclear extract from potato suspension cells. The nuclear extract was prepared according to a modified procedure for a plant transcription extract. The transcript of the potato spindle tuber viroid (PSTVd) consists of a monomeric molecule with 17 additional nucleotides, thus doubling most of the central conserved region of viroids of the PSTVd-class. The transcript can assume four different secondary structures, which either co-exist as conformers in solution or can be kept as metastable structures after different treatments by temperature and/or ionic strength. The structures were analysed by thermodynamic calculations and temperature-gradient gel electrophoresis and were confirmed by oligonucleotide mapping. Only the so-called extended middle structure was processed to exact viroid circles. In this structure the 5'- and 3'-ends are branching out from the rod-like viroid structure at the loop starting with nucleotide 87. The other structures were processed only if they could be rearranged into the active structure.

Tm studies of a tertiary structure from the human hepatitis delta agent which functions in vitro as a ribozyme control element

Viroids and other circular subviral RNA pathogens, such as the hepatitis delta agent, use a rolling circle replication cycle requiring an intact circular RNA. However, many infectious RNAs have the potential to form self-cleavage structures, whose formation must be controlled in order to preserve the circular replication template. The native structure of delta RNA contains a highly conserved element of local tertiary structure which is composed of sequences partially overlapping those needed to form the self-cleavage motif. A bimolecular complex containing the tertiary structure can be made. We show that when it is part of this bimolecular complex the potential cleavage site is protected and is not cleaved by the delta ribozyme, demonstrating that the element of local tertiary structure can function as a ribozyme control element in vitro. Physical studies of the complex containing this element were carried out. The complex binds magnesium ions and is not readily dissociated by EDTA under the conditions tested; > 50% of the complexes remain following incubation in 1 mM EDTA at 60 degrees C for 81 min. The thermal stability of the complex is reduced in the presence of sodium ions. A DNA complex and a perfect RNA duplex studied in parallel showed a similar effect, but of lesser magnitude. The RNA complex melts at temperatures approximately 10 degrees C lower in buffers containing 0.5 mM MgCl2 and 100 mM NaCl than in buffers containing 0.5 mM MgCl2 with no NaCl (78.1 compared with 87.7 degrees C). The element of local tertiary structure in delta genomic RNA appears to be a molecular clamp whose stability is highly sensitive to ion concentration in the physiological range.

3-D models of the antigenomic ribozyme of the hepatitis delta agent with eight new contacts suggested by sequence analysis of 188 cDNA clones

We mapped 359 mutations at 25 positions in synthetic variants of the antigenomic ribozyme of the hepatitis delta agent by analyzing the sequences of 188 cDNA clones. These data were used to identify three features of the ribozyme: highly conserved nucleotides, positions with restricted nucleotide substitutions and three-dimensional relationships between nucleotides. The distribution of mutations at the 25 positions was as follows: G-11 (the eleventh nucleotide from the cleavage site) was mutated in 56 clones; G-12 in 36; U-15 in 33; C-13 in 26; G-28 in 23; C-27 in 21; C-29 in 19; U-26 in 17; C-18 in 14; A-14 in 13; C-16 in 13; C-19 in 12; U-17 in 11; A-20 in 10; G-42 in 9; G-40 in 7; G-41 in 7; C-24 in 6; U-32 in 6; U-23 in 5; C-25 in 4; C-21 in 3; G-30 in 3; G-31 in 3; C-22 in 1. All clones containing a mutation at C-25 had an A at this position, suggesting that the extra cyclic amino group present in adenine and cytosine may function during the cleavage event. Mutations at certain positions were common in simple clones (containing only one or two mutations), while mutations at other positions were over-represented in more complex clones. Both compensatory base changes and co-mutational frequencies were used to identify eight pairs of nucleotides which may interact with each other: G-11 and C-18, G-12 and C-27, C-13 and G-28, C-21 and U-23/C-24, C-21 and G-30, U-23 and G-31/U-32, C24 and G-30, C-27 and G-42. These pairs, which involve some of the most conserved positions in the molecule, suggest interactions among nucleotides previously depicted in open-loop structures. The newly proposed points of contact between pairs of nucleotides are compatible with both the axehead and pseudoknot secondary structural models and were combined with previously proposed Watson-Crick base paired helices to produce two three dimensional models. In both of these, C-25 and C-76 are placed near the cleavage site.

The roles of the conserved pyrimidine bases in hammerhead ribozyme catalysis: evidence for a magnesium ion-binding site

We report details of the synthesis and characterization of oligoribonucleotides containing 4-thiouridine or 2-pyrimidinone ribonucleoside (4HC). We have used these probes to examine the roles of the conserved pyrimidines in the central core of the hammerhead ribozyme. The effects on catalysis of singly-substituted hammerhead ribozyme and substrate strands were quantified in multiple-turnover reactions. Various effects were observed on kcat. and Km, with up to a 7-fold decrease and a 3-fold increase respectively. For substitutions with 4HC at positions 3 or 17, catalytic activity in single turnover reactions can be increased up to 8-fold equivalent to 40% of wild-type activity, by increasing the concentration of the Mg2+ cofactor, implying that these substitutions had a deleterious effect on Mg2+ binding. Calculations of the change in the apparent free energy of binding for variants at positions 3, 4 or 17 are each consistent with deletion of a single hydrogen-bond to an uncharged group in the ribozyme. The cytidine 5' to the scissile phosphate had not previously been thought to play a direct role in catalysis, however, removal of the exocyclic amino group decreased kcat. 4-fold. Recently, the crystal structures of a hammerhead ribozyme bound to either a non-cleavable 2'-deoxy substrate strand or a ribo-substrate strand have been reported. The kinetic properties of the variants described here are consistent with several key interactions seen in the crystals, in particular they provide experimental support for the assignment of the proposed catalytically active magnesium ion-binding site.

Transgenic mice support replication of hepatitis delta virus RNA in multiple tissues, particularly in skeletal muscle

Hepatitis delta virus (HDV) is hepatotropic and frequently causes fulminant hepatitis in both human and nonhuman primate hosts. To understand the molecular basis of HDV tissue tropism and the mechanism of pathogenesis, transgenic mice in which replication-competent HDV dimeric RNA is expressed under the control of either liver-specific or universal transcriptional promoters were developed. The expressed RNA replicated efficiently in the liver and several tissues of nonhepatic origin. Surprisingly, maximal replication of HDV RNA occurred in skeletal muscle and was almost 100-fold greater than in the liver. These findings suggest that the hepatotropism of HDV is most likely a receptor-mediated restriction and that muscle-specific factors may facilitate HDV RNA replication. No evidence of cytopathology was apparent in most of the tissues examined, including the liver, supporting the contention that hepatocellular disease is not mediated by direct cytopathological effects associated with HDV RNA replication and gene expression. However, mild muscle atrophy in some of the transgenic mice was noted. Delta antigen was detected in the nuclei of myocytes. Only the small form, not the large form, of delta antigen was detected, suggesting that the RNA editing event which causes the conversion of delta antigen did not occur in transgenic mice. Furthermore, the 0.8-kb antigenomic RNA species, which is postulated to be the mRNA for delta antigen, was not detected in mice. The preferential replication of HDV RNA in skeletal muscle suggests that HDV RNA replication can be facilitated by certain muscle-specific factors.

Identification of a retroviroid-like element from plants

The biological nature of carnation small viroid-like RNA (CarSV RNA), a 275-nt circular molecule with self-cleaving hammerhead structures in its strands of both polarities, was investigated. The lack of infectivity observed in a series of transmission assays in carnation indicates that CarSV RNA, in spite of sharing structural similarities with viroid and viroid-like satellite RNAs from plants, does not belong to either of these two groups. Additional evidence in this direction comes from the observation that CarSV RNA also exists in carnation plants as DNA tandem repeats. In this respect, CarSV RNA is similar to a small transcript of a tandemly repeated DNA sequence of the newt genome. Moreover, CarSV and newt RNAs have similarities in their sequences as well as in some characteristics of their corresponding hammerhead structures. Further analyses have revealed that CarSV DNA is found directly fused to DNA sequences of carnation etched ring caulimovirus, a pararetrovirus, most likely in the form of an extrachromosomal element. The properties of the CarSV RNA/DNA system are those of a retroviroid-like element having some features in common with viroid and viroid-like satellite RNAs from plants and others with the newt transcript.

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.

The RNA of both polarities of the peach latent mosaic viroid self-cleaves in vitro solely by single hammerhead structures

Hammerhead self-cleavage of dimeric, monomeric, truncated and mutated transcripts derived from both polarities of the peach latent mosaic viroid (PLMVd) were characterized. In contrast to some results previously published for a very close sequence variant (see ref. 1), these RNAs exhibit a virtually identical self-cleavage during transcription and after purification. By self-cleavage of dimeric transcripts with normal and mutated hammerhead domains and by complementation experiments, we show that the cleavage reactions involve only single hammerhead structures. This observation contrasts with the case of avocado sunblotch viroid (ASBVd), the other self-cleaving viroid, whose mechanism involves mostly double hammerhead structures, whereas single hammerhead cleavage is associated with viroid-like plant satellite RNAs. The difference in stability between the native secondary structures adopted by viroids and the autocatalytic structures, including the hammerhead motif, governs the efficiency of the self-cleavage reaction. The transition between these conformers is the limiting step in catalysis and is related exclusively to the left arm region of PLMVd secondary structure, which includes the hammerhead sequences. Most of the mutations between the variant we used and the sequence variant previously published are located in this left arm region, which may explain to a great extent the differences in their cleavage efficiency. No interactions with long-range sequences contributing to the autocatalytic tertiary structure were revealed in these experiments.

An RNA tertiary structure of the hepatitis delta agent contains UV-sensitive bases U-712 and U-865 and can form in a bimolecular complex

Genomic RNA of the hepatitis delta agent has a highly conserved element of local tertiary structure. This element contains two nucleotides which become covalently crosslinked to each other upon irradiation with UV light. Using direct RNA analysis, we now identify the two nucleotides as U-712 and U-865 and show that the UV-induced crosslink can be broken by re-exposure to a 254 nm peak UV light source. In the rod-like secondary structural model of delta RNA, nucleotides U-712 and U-865 are off-set from each other by 5-6 bases, a distance too great to permit crosslinking. This model needs to be modified. Our data indicate that bases U-712 and U-865 closely approximate each other and suggest that the smooth helical contour proposed for delta RNA is interrupted by the UV-sensitive element. The nucleotide sequence shows that the UV-sensitive site does not have a particularly high density of conventional Watson-Crick base pairs compared to the rest of the genome. However, this element may have a number of non-Watson-Crick bonds which confer stability. Following UV-crosslinking and digestion with 1 mg/ml of RNase T1 at 37 degrees C for 45 min in 10 mM Tris-HCl, 1 mM EDTA (conditions expected to give complete digestion), this element can be isolated as part of a 54 nucleotide long partial digestion product containing at least 16 internal G residues. UV-crosslinking analysis shows that this unusual tertiary structural element can form in a bimolecular complex.

Replication of avocado sunblotch viroid: evidence for a symmetric pathway with two rolling circles and hammerhead ribozyme processing

The structure of a series of RNAs extracted from avocado infected by the 247-nt avocado sunblotch viroid (ASBVd) was investigated. The identification of multistranded complexes containing circular ASBVd RNAs of (+) and (-) polarity suggests that replication of ASBVd proceeds through a symmetric pathway with two rolling circles where these two circular RNAs are the templates. This is in contrast to the replication of potato spindle tuber viroid and probably of most of its related viroids, which proceeds via an asymmetric pathway where circular (+)-strand and linear multimeric (-)-strand RNAs are the two templates. Linear (+) and (-) ASBVd RNAs of subgenomic length (137 nt and about 148 nt, respectively) and one linear (+)-strand ASBVd RNA of supragenomic length (383-384 nt) were also found in viroid-infected tissue. The two linear (+)-strand RNAs have the same 5'- and 3'-terminal sequences, with the supragenomic species being a fusion product of the monomeric and subgenomic (+)-strand ASBVd RNAs. The 3' termini of these two (+)-strand molecules, which at least in the subgenomic RNA has an extra nontemplate cytidylate residue, could represent sites of either premature termination of the (+)-strands or specific initiation of the (-)-strands. The 5' termini of sub- and supragenomic (+)-strand and the 5' terminus of the subgenomic (-)-strand ASBVd RNA are identical to those produced in the in vitro self-cleavage reactions of (+) and (-) dimeric ASBVd RNAs, respectively. These observations strongly suggest that the hammerhead structures which mediate the in vitro self-cleavage reactions are also operative in vivo.

The nature of multimeric forms of cymbidium ringspot tombusvirus satellite RNA

The multimeric forms of cymbidium ringspot tombusvirus (CyRSV) satellite (sat) RNA were analysed. Attempts to amplify the putative junction region of oligomers using the polymerase chain reaction (PCR) failed, indicating the absence of such structures. SatRNA-related species having the size double than the unit length were shown to be double-stranded monomers and not single-stranded dimers. Similarly, satRNA species of a size four times the unit length were shown to be constituted by aggregates of double-stranded monomers. The absence of single-stranded CyRSV satRNA oligomers indicates that the formation of multimers is not a step in the replication of this RNA molecule.

The viroid: big punch in a small package

Although viroids consist solely of short lengths of unencapsidated single-stranded circular RNA, they replicate autonomously in plants and cause diseases that are as varied and often as severe as those caused by plant viruses. All this, without ever serving as mRNAs. However, aside from some fascinating glimpses, the mechanisms of viroid pathogenesis remain largely enigmatic.

Prominent polypurine and polypyrimidine tracts in plant viroids and in RNA of the human hepatitis delta agent

To seek patterns of nucleotide usage in the three types of circular subviral RNA pathogens, trimer frequencies and nearest-neighbor biases were studied in 12 plant viroid sequences; five sequences of circular plant viral satellite RNAs; and the sequence of RNA from the human hepatitis delta agent. The viroids and RNA of the delta agent contain tracts of polypurines and polypyrimidines which make up substantial portions of their genomes. Such tracts are not common in the virusoids or in the satellite RNA of tobacco ringspot virus. Viroids, the delta hepatitis agent, and the circular satellite RNAs of certain plant viruses have several features in common: all have circular genomic RNA and replicate through an RNA to RNA rolling circle replication cycle. However, virusoids and related satellite RNAs are directly or indirectly dependent on their helper viruses for replication, while the delta agent and viroids are not. The difference in the pattern of nucleotide usage between the plant viral satellite RNAs on the one hand, and viroids and delta RNA on the other, may relate to this difference in replication strategy.

Delta hepatitis: molecular biology and clinical and epidemiological features

Hepatitis delta virus, discovered in 1977, requires the help of hepatitis B virus to replicate in hepatocytes and is an important cause of acute, fulminant, and chronic liver disease in many regions of the world. Because of the helper function of hepatitis delta virus, infection with it occurs either as a coinfection with hepatitis B or as a superinfection of a carrier of hepatitis B surface antigen. Although the mechanisms of transmission are similar to those of hepatitis B virus, the patterns of transmission of delta virus vary widely around the world. In regions of the world in which hepatitis delta virus infection is not endemic, the disease is confined to groups at high risk of acquiring hepatitis B infection and high-risk hepatitis B carriers. Because of the propensity of this viral infection to cause fulminant as well as chronic liver disease, continued incursion of hepatitis delta virus into areas of the world where persistent hepatitis B infection is endemic will have serious implications. Prevention depends on the widespread use of hepatitis B vaccine. This review focuses on the molecular biology and the clinical and epidemiologic features of this important viral infection.

Functional motifs of delta antigen essential for RNA binding and replication of hepatitis delta virus

The functions of delta antigens (HDAgs) in the replication of hepatitis delta virus (HDV) have been identified previously. The small HDAg acts as a transactivator, whereas the large HDAg has a negative effect on replication. To understand the molecular mechanisms involved in the control of HDV replication, we have established a replication system in Huh-7 cells by cotransfecting a monomeric cDNA genome of HDV and a plasmid encoding the small HDAg. We demonstrate that a leucine repeat in the middle domain of the small HDAg is involved in binding to the HDV genome and transactivation of HDV replication. When the leucine repeat was disrupted by a substitution of valine for leucine at position 115, both RNA-binding and transactivation activity of the small HDAg were abolished. In contrast, the binding and transactivation activities were not affected when Leu-37 and Leu-44 of the small HDAg were replaced by valines. In addition, small and large HDAgs can interact with each other to form protein complexes in vitro. The complex formation that may lead to the trans-dominant negative regulation of large HDAg in HDV replication is mediated by a cryptic signal located between amino acid residues 35 and 65 other than the putative N-terminal leucine zipper motif. Furthermore, an extra 21-amino-acid extension near the N terminus converts the small HDAg into a pseudo-large HDAg with negative regulation activity of HDV replication even though the extreme C-terminal residue is unchanged.

Replication of hepatitis delta virus RNA: effect of mutations of the autocatalytic cleavage sites

Hepatitis delta virus (HDV) contains a circular RNA genome of 1.7 kb. HDV RNA replication is thought to proceed via a rolling-circle mechanism that is dependent on autocatalytic cleavage and ligation reactions. However, it has never been established that these ribozyme activities are indeed involved in HDV RNA replication. To investigate the possible biological significance of HDV RNA self-cleavage, we constructed several HDV dimer cDNAs containing single-base substitutions of the 3' nucleotide of the genomic and the antigenomic self-cleavage sites. These mutations were known to affect self-cleavage in vitro to various extents. The effects of these mutations on HDV RNA replication were examined in hepatic and nonhepatic cell lines. The results showed that all of the mutants which had lost the in vitro self-cleavage activity could not replicate. The only mutant which retained full cleavage activity replicated as efficiently as the wild-type RNA. Thus, this study established that self-cleavage activity is required for HDV RNA replication in cells. Interestingly, the level of HDV RNA detected in cells transfected with this replication-competent mutant and that detected in cells transfected with the wild-type construct were similar in COS-7 cells but vastly different in HepG2 and Huh-7 cells, suggesting that HDV RNA self-cleavage activity may be modulated by cell-specific factors. We also compared the effects of mutations when the primary transcripts of these constructs were of either genomic or antigenomic sense. In constructs which synthesize primary transcripts of genomic sense, all of the antigenomic self-cleavage mutants produced as much hepatitis delta antigen (HDAg) as did the wild-type construct, even in the absence of detectable HDV RNA replication, whereas the genomic self-cleavage mutants produced very little HDAg. These and other data suggest that (i) the primary HDV RNA transcripts of both genomic and antigenomic polarities must first be processed to serve as a template for HDV RNA transcription, (ii) efficient cleavage at the antigenomic self-cleavage site is not required for HDAg expression, and (iii) HDV RNA replication most likely occurs by a double-rolling-circle mechanism.

Mechanism of viroid pathogenesis: differential activation of the interferon-induced, double-stranded RNA-activated, M(r) 68,000 protein kinase by viroid strains of varying pathogenicity

Purified potato spindle tuber viroid (PSTVd) was added to an in vitro assay system containing purified interferon-induced, dsRNA-activated protein kinase (P68). Viroid RNA activated (phosphorylated) the enzyme, although with less efficiency than did the synthetic, perfectly matched poly I-poly C. In binding experiments, RNA transcripts of the intermediate strain of PSTVd were shown to specifically bind to a P68-antibody complex. Activation of the enzyme by a strain of PSTVd that results in severe symptoms in infected tomato plants was at least ten-fold that by the mild strain. Activation by a strain that results in intermediate symptoms was quantitatively similar to activation by the severe strain. To our knowledge, this is the first demonstration of a differential effect of viroid strains inducing different levels of pathology on any biochemical or metabolic system investigated. This differential effect suggests that activation of a plant enzyme homologous to mammalian P68 protein kinase may represent the triggering event in viroid pathogenesis. Differential activation of P68 is surprising, because the primary structures of the mild and severe PSTVd strains analyzed differ by only a two-nucleotide inversion (UUC-->CUU) in the lower portion of the 'pathogenicity' region of the molecules. This change, according to thermodynamic calculations, should have only a minor effect on the secondary structure of the viroid molecule. Binding assays indicated that PSTVd specifically binds to P68.

Generation of viroid conformational isomers that are stable to incubation with magnesium ions and in a nuclear extract from tomato plants

We identified conditions for heating and quick cooling viroid RNAs in the presence of salt which lead to the production of conformational isomers stable to incubation for at least 45 minutes at 30 degrees in the presence of magnesium ions. Elution in 0.3 M NaCl allowed the purification of an electrophoretically slow form of an in vitro transcript carrying a complete copy of the potato spindle tuber viroid RNA sequence. Slow forms of this transcript and of kinase-labeled linear viroid RNA persisted for longer than 20 minutes when incubated with a protein-rich extract prepared from the nuclei of uninfected tomato plants, although both were slowly cleaved by a nuclease present in this extract. The fast form of the transcript was highly resistant to this tomato ribonuclease. The slow form of the transcript was much more susceptible to cleavage by RNase T1 than the fast form of this RNA, suggesting that the reduced gel mobility of the slow forms results from their relatively open structure. The ability to purify viroid conformational isomers from polyacrylamide gels will facilitate biochemical studies aimed at identifying host components interacting with RNAs of the viroid replication complex, which may not all be present in the most thermodynamically favored rodlike structure of mature viroids.

Expression and localization of the small and large delta antigens during the replication cycle of hepatitis D virus

To study the expression and localization of delta antigen during the replication cycle of hepatitis D virus, we cotransfected HuH-7 hepatoma cells with a hepatitis B virus expression plasmid and plasmids expressing the small or large delta antigen or the entire HDV genome. The transfected cells and culture medium were analyzed on double immunofluorescence staining for delta antigen and HBsAg, on Western blotting and on Northern-blot hybridization from 4 hr to 9 days after transfection. In cells transfected with the expression plasmid carrying the small delta antigen open reading frame, only the small delta antigen was expressed; it was localized in the nucleolus and was not released into the medium during the culture period. In cells transfected with the large delta antigen expression plasmid, the large delta antigen expressed was localized in the nucleolus at the initial stage; this was followed by relocalization in nucleoplasm. Finally, large delta antigen was released in HBsAg-enveloped particles within 1 day of transfection. In cells cotransfected with hepatitis B virus and hepatitis D virus expression plasmids, the small delta antigen was expressed 4 hr after transfection, whereas the large form was expressed 3 days after transfection. Expression of the large delta antigen coincided with the localization changes from nucleolar to mixed stage and, finally, to nucleoplasm and release of the hepatitis D virus particles. The large delta antigen appears to play a key role in relocalization of the delta antigen and packaging of the hepatitis D virus virions.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural requirements for viroid processing by RNase T1

Viroids are replicated via a rolling circle-like mechanism in which (+) strand oligomeric intermediates have to be cleaved enzymatically to unit-length molecules followed by ligation to mature circles. A transcript of potato spindle tuber viroid, which is still infectious, consists of a monomeric molecule with only 22 additional nucleotides, thus doubling part of the central conserved region of viroids. It was shown that this transcript can be cleaved and ligated in vitro to circles by RNase T1. To elucidate the site and mechanism of processing, 16 different site-specific mutants of this longer-than-unit-length transcript were constructed and analyzed by in vitro processing with RNase T1, infectivity studies, temperature-gradient gel electrophoresis, and structure calculations. The wild-type sequence and several mutated transcripts are able to adopt a particular secondary structure which is the prerequisite for enzymatic cleavage and ligation by RNase T1. This "processing structure" exposes both potential cleavage sites in the nearest spatial neighborhood, thus favoring the subsequent ligation to circles. Those mutated sequences for which the formation of the processing structure is impossible or thermodynamically highly unfavored are not processed. The results demonstrate that the particular structural features of viroids enable them to be cleaved and ligated by one and the same enzyme, RNase T1. The in vitro mechanism may serve as a mechanistic model for cellular processing of viroids.

Satellite RNAs of plant viruses: structures and biological effects

Plant viruses often contain parasites of their own, referred to as satellites. Satellite RNAs are dependent on their associated (helper) virus for both replication and encapsidation. Satellite RNAs vary from 194 to approximately 1,500 nucleotides (nt). The larger satellites (900 to 1,500 nt) contain open reading frames and express proteins in vitro and in vivo, whereas the smaller satellites (194 to 700 nt) do not appear to produce functional proteins. The smaller satellites contain a high degree of secondary structure involving 49 to 73% of their sequences, with the circular satellites containing more base pairing than the linear satellites. Many of the smaller satellites produce multimeric forms during replication. There are various models to account for their formation and role in satellite replication. Some of these smaller satellites encode ribozymes and are able to undergo autocatalytic cleavage. The enzymology of satellite replication is poorly understood, as is the replication of their helper viruses. In many cases the coreplication of satellites suppresses the replication of the helper virus genome. This is usually paralleled by a reduction in the disease induced by the helper virus; however, there are notable exceptions in which the satellite exacerbates the pathogenicity of the helper virus, albeit on only a limited number of hosts. The ameliorative satellites are being assessed as biocontrol agents of virus-induced disease. In greenhouse studies, satellites have been known to "spontaneously" appear in virus cultures. The possible origin of satellites will be briefly considered.

Characterization of RNAs specific to avocado sunblotch viroid synthesized in vitro by a cell-free system from infected avocado leaves

Analysis by molecular hybridization of the RNAs transcribed by a cell-free fraction from avocado infected with avocado sunblotch viroid (ASBV) demonstrated the presence of newly synthesized viroid-specific sequences, most of which were of the same polarity as the mature infectious viroid RNA. Treatment of the cell-free fraction with DNase reduced the total synthesis of RNA considerably, but it did not influence that of the ASBV-specific RNAs, indicating that the latter were transcribed on an RNA template. Inhibition studies with alpha-amanitin showed that the synthesis of ASBV-specific RNAs was not affected by concentrations of 1 and 200 micrograms/ml of the drug, which typically inhibit RNA polymerase II and III, respectively, from most animal and plant systems. These results suggest that either RNA polymerase I or an unidentified RNA polymerase activity resistant to alpha-amanitin, acting on an RNA template, plays a role in the replication of ASBV, whereas for the rest of the viroids studied so far it appears that RNA polymerase II is involved. Analysis by polycrylamide gel electrophoresis under partially and fully denaturing conditions of the ASBV-specific RNAs synthesized in vitro showed that they contain unit and longer than unit length viroid strands, probably associated in complexes with single- and double-stranded regions. The structural properties of these complexes are similar to those of the RNAs accumulating in vivo in viroid-infected tissues, which are the postulated replicative intermediates of the rolling-circle mechanism proposed for viroid synthesis.

Production of infectious hepatitis delta virus in vitro and neutralization with antibodies directed against hepatitis B virus pre-S antigens

Hepatitis delta virus (HDV) particles were produced in Huh7 human hepatoma cells by transfection with cloned hepatitis B virus (HBV) DNA and HDV cDNA. The particles were characterized by their buoyant density, the presence of encapsidated viral RNA, and their ability to infect primary cultures of chimpanzee hepatocytes. Successful infection was evidenced by the appearance of increasing amounts of intracellular HDV RNA after exposure to particles. Infection was prevented when particles were incubated with antibodies directed against synthetic peptides specific for epitopes of the pre-S1 or pre-S2 domains of the HBV envelope proteins before exposure to hepatocytes. These data demonstrate that HDV particles produced in vitro are infectious and indicate (i) that infectious particles are coated with HBV envelope proteins that contain the pre-S1 and pre-S2 regions, (ii) that epitopes of the pre-S1 and pre-S2 domains of HBV envelope proteins are exposed at the surface of HDV particles, and (iii) that antibodies directed against those epitopes have neutralizing activity against HDV.