Cap-independent translational enhancement of turnip crinkle virus genomic and subgenomic RNAs

The presence of translational control elements and cap structures has not been carefully investigated for members of the Carmovirus genus, a group of small icosahedral plant viruses with positive-sense RNA genomes. In this study, we examined both the 5' and 3' untranslated regions (UTRs) of the turnip crinkle carmovirus (TCV) genomic RNA (4 kb) as well as the 5' UTR of the coat protein subgenomic RNA (1.45 kb) for their roles in translational regulation. All three UTRs enhanced translation of the firefly luciferase reporter gene to different extents. Optimal translational efficiency was achieved when mRNAs contained both 5' and 3' UTRs. The synergistic effect due to the 5'-3' cooperation was at least fourfold greater than the sum of the contributions of the individual UTRs. The observed translational enhancement of TCV mRNAs occurred in a cap-independent manner, a result consistent with the demonstration, using a cap-specific antibody, that the 5' end of the TCV genomic RNA was uncapped. Finally, the translational enhancement activity within the 5' UTR of 1.45-kb subgenomic RNA was shown to be important for the translation of coat protein in protoplasts and for virulent infection in Arabidopsis plants.     

Identification of regions affecting virulence, RNA processing and infectivity in the virulent satellite of turnip crinkle virus.

Turnip crinkle virus (TCV) supports a small family of satellite RNAs (RNAs C, D and F). RNA C is a virulent satellite, producing severe symptoms in host plants, while RNAs D and F are avirulent satellites. The virulent satellite (RNA C) has two major domains--a 5'-domain similar to the avirulent satellites and a 3'-domain similar to the 3'-end of the TCV genome. To demonstrate that the 3'-domain of RNA C determines virulence, a chimeric satellite was constructed composed mostly of the 5'-domain of the avirulent satellite (RNA F) and the 3'-domain of the virulent satellite (RNA C). To locate other functional regions, small DNA fragments were inserted or deleted at various sites in the cDNA of virulent satellite (RNA C). Most small internal deletions and insertions in the midsection of the molecule had no detectable effects while those near the 3'-end of RNA C destroyed infectivity. Modifications in a small region centering on an AGCAGC repeat in the domain of satellite homology blocked the accumulation of monomers and presumably the processing of RNA C. Other modifications in this region produced more intense symptoms. Hence, these experiments reveal regions of the satellite which determine virulence, are essential for infectivity, affect monomer accumulation (RNA processing) and modulate symptom expression.     

Satellite RNA-mediated resistance to turnip crinkle virus in Arabidopsis involves a reduction in virus movement.

Satellite RNAs (sat-RNAs) are parasites of viruses that can mediate resistance to the helper virus. We previously showed that a sat-RNA (sat-RNA C) of turnip crinkle virus (TCV), which normally intensifies symptoms of TCV, is able to attenuate symptoms when TCV contains the coat protein (CP) of cardamine chlorotic fleck virus (TCV-CPCCFV). We have now determined that sat-RNA C also attenuates symptoms of TCV containing an alteration in the initiating AUG of the CP open reading frame (TCV-CPm). TCV-CPm, which is able to move systemically in both the TCV-susceptible ecotype Columbia (Col-0) and the TCV-resistant ecotype Dijon (Di-0), produced a reduced level of CP and no detectable virions in infected plants. Sat-RNA C reduced the accumulation of TCV-CPm by < 25% in protoplasts while reducing the level of TCV-CPm by 90 to 100% in uninoculated leaves of Col-0 and Di-0. Our results suggest that in the presence of a reduced level of a possibly altered CP, sat-RNA C reduces virus long-distance movement in a manner that is independent of the salicylic acid-dependent defense pathway.     

Structure and assembly of turnip crinkle virus. II. Mechanism of reassembly in vitro

Dissociation of turnip crinkle virus (TCV) at elevated pH and ionic strength produces free dimers of the coat protein and a ribonucleoprotein complex that contains the viral RNA, six coat-protein subunits, and the minor protein species, p80 (a covalently linked coat-protein dimer). This "rp-complex" is stable for several days in high salt at pH 8.5. Reassembly of TCV can be accomplished under physiological conditions, using isolated coat protein and either rp-complex or protein-free RNA. If rp-complex is used in reassembly, the same subunits remain bound to RNA on subsequent dissociation; if free RNA is used, rp-complex is regenerated. In both cases, the assembly is selective for viral RNA in competition experiments with heterologous RNA. Electron microscopy shows that assembly proceeds by continuous growth of a shell from an initiating structure, rather than by formation of distinct intermediates. We suggest that rp-complex is the initiating structure, suggest a model based on the organization of the TCV particle, and propose a mechanism for TCV assembly.     

Structure of turnip crinkle virus. III. Identification of a unique coat protein dimer

The minor structural protein (p80), found in about one copy per virion in turnip crinkle virus (TCV), is shown by amino acid analysis and peptide mapping to be a covalent dimer of the major coat protein (p40). The covalent linkage occurs near the N termini of the crosslinked chains. These data suggest that TGV and related viruses contain 178 copies of p40 (89 non-covalent dimers) and one copy of p80 (covalent dimer of two additional p40 chains). The presence of p80 in the salt-stable RNA-protein complex formed when TCV dissociates, as described in an accompanying paper, indicates that the covalent modification affects binding to RNA. We suggest that p80 might be the final dimer to be incorporated into the shell and that it might also be the site for initiation of uncoating.     

Identification of an Arabidopsis locus required for resistance to turnip crinkle virus

Inoculation of turnip crinkle virus (TCV) into a (TCV)-resistant line of Arabidopsis thaliana , Di-17, results in the development of a hypersensitive response (HR) on the inoculated leaves. In contrast, an HR does not occur when leaves of the TCV-susceptible Di-3 line or the susceptible ecotypes Columbia (Col-0), or Landsberg erecta ( Ler ) are inoculated. Genetic analysis of progeny from crosses between Di-17 and either Di-3, Col-0 or Ler demonstrates that the development of an HR is regulated by a single dominant nuclear locus, herein designated HRT . Using progeny from a Di-17 X Col-0 cross, HRT was mapped to chromosome 5, where it is tightly linked to the DFR locus. We also demonstrate that a variety of resistance-associated phenomena, including the TCV-induced accumulation of salicylic acid, camalexin and autofluorescent cell-wall material, correlate with the HR, suggesting the possibility that HRT is required for their activation.     

Symptom attenuation by a normally virulent satellite RNA of turnip crinkle virus is associated with the coat protein open reading frame.

Many satellite RNAs (sat-RNAs) can attenuate or intensify the symptoms produced by their helper virus. Sat-RNA C, associated with turnip crinkle virus (TCV), was previously found to intensify the symptoms of TCV on all plants in which TCV produced visible symptoms. However, when the coat protein open reading frame (ORF) of TCV was precisely exchanged with that of cardamine chlorotic fleck virus, sat-RNA C attenuated the moderate symptoms of the chimeric virus when Arabidopsis plants were coinoculated with the chimeric virus. Symptom attenuation was correlated with a reduction in viral RNA levels in inoculated and uninoculated leaves. In protoplasts, the presence of sat-RNA C resulted in a reduction of approximately 70% in the chimeric viral genomic RNA at 44 hr postinoculation, whereas the sat-RNA wa consistently amplified to higher levels by the chimeric virus than by wild-type TCV. TCV with a deletion of the coat protein ORF also resulted in a similar increase in sat-RNA C levels in protoplasts, indicating that the TVC coat protein, or its ORF, downregulates the synthesis of sat-RNA C. These results suggest that the coat protein or its ORF is a viral determinant for symptom modulation by sat-RNA C, and symptom attenuation is at least partly due to inhibition of virus accumulation.     

3'-End stem-loops of the subviral RNAs associated with turnip crinkle virus are involved in symptom modulation and coat protein binding

Many plant RNA viruses are associated with one or more subviral RNAs. Two subviral RNAs, satellite RNA C (satC) and defective interfering RNA G (diG) intensify the symptoms of their helper, turnip crinkle virus (TCV). However, when the coat protein (CP) of TCV was replaced with that of the related Cardamine chlorotic fleck virus (CCFV), both subviral RNAs attenuated symptoms of the hybrid virus TCV-CP(CCFV). In contrast, when the translation initiation codon of the TCV CP was altered to ACG and reduced levels of CP were synthesized, satC attenuated symptoms while diG neither intensified nor attenuated symptoms. The determinants for this differential symptom modulation were previously localized to the 3'-terminal 100 bases of the subviral RNAs, which contain six positional differences (Q. Kong, J.-W. Oh, C. D. Carpenter, and A. E. Simon, Virology 238:478-485, 1997). In the current study, we have determined that certain sequences within the 3'-terminal stem-loop structures of satC and diG, which also serve as promoters for complementary strand synthesis, are critical for symptom modulation. Furthermore, the ability to attenuate symptoms was correlated with weakened binding of TCV CP to the hairpin structure.     

New insights into resistance protein-mediated signaling against turnip crinkle virus in Arabidopsis

The Arabidopsis-turnip crinkle virus (TCV) system is one of the few tractable plant-virus systems that allow simultaneous characterization of host components required for basal- and/or resistance (R) protein-mediated defenses. Another unique feature is that hypersensitive response (HR) and resistance can be studied as two distinct phenotypes in this pathosytem. The R protein HRT confers HR to TCV but requires a recessive locus rrt to confer resistance. The pathways leading to HR and resistance are mutually exclusive. HRT interacts with EDS1, which potentiates HR to TCV and is also required for resistance signaling. HRT-mediated signaling is also dependent on the EDS1-interacting proteins PAD4 and SAG101, which form binary and ternary complexes with EDS1. HRT-mediated resistance is also dependent on light and more specifically on the blue-light photoreceptors, cryptochromes (CRY) and phototropins (PHOT). Of these, CRY2 and PHOT2 are required for the stability of HRT. HRT is degraded in a proteasome-dependent manner, which correlates with its interaction with the E3 ubiquitin ligase, COP1. Together, these results suggest that components of light signaling modulate plant defense against TCV by regulating the stability of, and signaling mediated by, the R protein HRT.     

The virulent satellite RNA of turnip crinkle virus has a major domain homologous to the 3' end of the helper virus genome

RNA C (355 bases), RNA D (194 bases) and RNA F (230 bases) are small, linear satellite RNAs of turnip crinkle virus (TCV) which have been cloned as cDNAs and sequenced in this study. These RNAs produce dramatically different disease symptoms in infected plants. RNA C is a virulent satellite that intensifies virus symptoms when co-inoculated with its helper virus in turnip plants, while RNA D and RNA F are avirulent. RNA D and RNA F, the avirulent satellites, are closely related to each other except that RNA F has a 36-base insert near its 3' end, not found in RNA D. The 189 bases at the 5' end of RNA C, the virulent satellite, are homologous to the entire sequence of RNA D. However, the 3' half of RNA C, is composed of 166 bases which are nearly identical to two regions at the 3' end of the TCV helper virus genome. Hence, the virulent satellite is a composite molecule with one domain at its 5' end homologous to the other avirulent satellites and another domain at its 3' end homologous to the helper virus genome. All four TCV RNAs, RNAs C, D and F and the helper virus genome have identical 7 bases at their 3' ends. The secondary structure of RNA C deduced from the sequence can be folded into two separate domains — the domain of helper virus genome homology and the domain homologous to other TCV satellite RNAs. Comparative sequences of several different RNA C clones reveal that this satellite is a population of molecules with sequence and length heterogeneity.     

Encapsidation of turnip crinkle virus is defined by a specific packaging signal and RNA size.

A protoplast infection assay has been used to reliably examine the viral RNA encapsidation of turnip crinkle virus (TCV). Analysis of the encapsidation of various mutant viral RNAs revealed that a 186-nucleotide (nt) region at the 3' end of the coat protein (CP) gene, with a bulged hairpin loop of 28 nt as its most essential element, was indispensable for TCV RNA encapsidation. When RNA fragments containing the 186-nt region were used to replace the CP gene of a different virus, tomato bushy stunt virus, the resulting chimeric viral RNAs were encapsidated into TCV virions. Furthermore, analysis of the encapsidated chimeric RNA species established that the RNA size was an important determinant of the TCV assembly process.     

Structure and assembly of turnip crinkle virus. I. X-ray crystallographic structure analysis at 3.2 A resolution

The structure of turnip crinkle virus has been determined at 3.2 A resolution, using the electron density of tomato bushy stunt virus as a starting point for phase refinement by non-crystallographic symmetry. The structures are very closely related, especially in the subunit arm and S domain, where only small insertions and deletions and small co-ordinate shifts relate one chain to another. The P domains, although quite similar in fold, are oriented somewhat differently with respect to the S domains. Understanding of the structure of turnip crinkle virus has been important for analyzing its assembly, as described in an accompanying paper.     

A multifunctional turnip crinkle virus replication enhancer revealed by in vivo functional SELEX

The motif1-hairpin (M1H), located on (-)-strands of Turnip Crinkle Virus (TCV)-associated satellite RNA C (satC), is a replication enhancer and recombination hotspot. Results of in vivo genetic selection (SELEX: systematic evolution of ligands by exponential enrichment), where 28 bases of the M1H were randomized and then subjected to selection in plants, revealed that most winners contained one to three short motifs, many of which in their (-)-sense orientation are found in TCV and satC (-)-strand promoter elements. Ability to replicate in protoplasts correlated with fitness to accumulate in plants with one significant exception. Winner UC, containing only a seven-base replacement sequence, was the second most fit winner, yet replicated no better than a 28-base random replacement sequence. Fitness of satC containing different M1H replacement sequences could be due to enhanced satC replication or enhanced ability to affect TCV movement, since satC interferes with TCV virion accumulation, which is correlated with enhanced movement to younger tissue. Cells inoculated with TCV and UC accumulated fewer virions when compared to other winners that replicated better in protoplasts but were less fit in plants. UC, and other first and second round winners, contained structures that were on average 33% more stable in their (+)-strand orientation, and most formed hairpins with a A-rich sequence at the base. These results suggest that M1H replacement sequences contribute to the fitness of satC by either containing (-)-strand elements that enhance satRNA replication and/or a (+)-strand hairpin flanked with single-stranded sequence that enhances TCV movement.     

Structure and assembly of turnip crinkle virus. VI. Identification of coat protein binding sites on the RNA

Structural studies of turnip crinkle virus have been extended to include the identification of high-affinity coat protein binding sites on the RNA genome. Virus was dissociated at elevated pH and ionic strength, and a ribonucleoprotein complex (rp-complex) was isolated by chromatography on Sephacryl S-200. Genomic RNA fragments in the rp-complex, resistant to RNase A and RNase T1 digestion and associated with tightly bound coat protein subunits, were isolated using coat-protein-specific antibodies. The identity of the protected fragments was determined by direct RNA sequencing. These approaches allowed us to study the specific RNA-protein interactions in the rp-complex obtained from dissociated virus particles. The location of one protected fragment downstream from the amber terminator codon in the first and largest of the three viral open reading frames suggests that the coat protein may play a role in the regulation of the expression of the polymerase gene. We have also identified an additional cluster of T1-protected fragments in the region of the coat protein gene that may represent further high-affinity sites involved in assembly recognition.     

Defective interfering RNAs of a satellite virus

Panicum mosaic virus (PMV) is a recently molecularly characterized RNA virus with the unique feature of supporting the replication of two subviral RNAs in a few species of the family Gramineae. The subviral agents include a satellite RNA (satRNA) that is devoid of a coding region and the unrelated satellite panicum mosaic virus (SPMV) that encodes its own capsid protein. Here we report the association of this complex with a new entity in the RNA world, a defective-interfering RNA (DI) of a satellite virus. The specificity of interactions governing this four-component viral system is illustrated by the ability of the SPMV DIs to strongly interfere with the accumulation of the parental SPMV. The SPMV DIs do not interfere with PMV satRNA, but they do slightly enhance the rate of spread and titer of PMV. The SPMV-derived DIs provide an additional avenue by which to investigate fundamental biological questions, including the evolution and interactions of infectious RNAs.