cis-acting sequences required for in vivo amplification of genomic RNA3 are organized differently in related bromoviruses

Notes on recombination and reassortment in multipartite/segmented viruses

Besides evolving through nucleotide substitution, viruses frequently also evolve by genetic recombination which can occur when related viral variants co-infect the same cells. Viruses with segmented or multipartite genomes can additionally evolve via the reassortment of genomic components. Various computational techniques are now available for identifying and characterizing recombination and reassortment. While these techniques have revealed both that all well studied segmented and multipartite virus species show some capacity for reassortment, and that recombination is common in many multipartite species, they have indicated that recombination is either rare or does not occur in species with segmented genomes. Reassortment and recombination can make it very difficult to study segmented/multipartite viruses using metagenomics-based approaches. Notable challenges include, both the accurate identification and assignment of genomic components to individual genomes, and the differentiation between natural 'real' recombination events and artifactual 'fake' recombination events arising from the inaccurate de novo assembly of genome component sequences determined using short read sequencing.

Within-host Evolution of Segments Ratio for the Tripartite Genome of Alfalfa Mosaic Virus

The existence of multipartite viruses is an intriguing mystery in evolutionary virology. Several hypotheses suggest benefits that should outweigh the costs of a reduced transmission efficiency and of segregation of coadapted genes associated with encapsidating each segment into a different particle. Advantages range from increasing genome size despite high mutation rates, faster replication, more efficient selection resulting from reassortment during mixed infections, better regulation of gene expression, or enhanced virion stability and cell-to-cell movement. However, support for these hypotheses is scarce. Here we report experiments testing whether an evolutionary stable equilibrium exists for the three genomic RNAs of Alfalfa mosaic virus (AMV). Starting infections with different segment combinations, we found that the relative abundance of each segment evolves towards a constant ratio. Population genetic analyses show that the segment ratio at this equilibrium is determined by frequency-dependent selection. Replication of RNAs 1 and 2 was coupled and collaborative, whereas the replication of RNA 3 interfered with the replication of the other two. We found that the equilibrium solution is slightly different for the total amounts of RNA produced and encapsidated, suggesting that competition exists between all RNAs during encapsidation. Finally, we found that the observed equilibrium appears to be host-species dependent.

Base-paired structure in the 5' untranslated region is required for the efficient amplification of negative-strand RNA3 in the bromovirus melandrium yellow fleck virus

Melandrium yellow fleck virus belongs to the genus Bromovirus, which is a group of tripartite plant RNA viruses. This virus has an approximately 200-nucleotide direct repeat sequence in the 5' untranslated region (UTR) of RNA3 that encodes the 3a movement protein. In the present study, protoplast assays suggested that the duplicated region contains amplification-enhancing elements. Deletion analyses of the 5' UTR of RNA3 showed that mutations in the short base-paired region, which is located dozens of bases upstream of the initiation codon of the 3a gene, greatly reduced the accumulation of RNA3. Disruption and restoration of the base-paired structure caused the accumulation of RNA3 to be decreased and restored, respectively. In vitro translation/replication assays demonstrated that the base-paired structure is important for the efficient amplification of negative-stand RNA3. A similar base-paired structure in RNA3 of another bromovirus, brome mosaic virus (BMV), also facilitated the efficient amplification of BMV RNA3, but only in combination with melandrium yellow fleck virus (MYFV) replicase and not with BMV replicase, thereby suggesting specific interactions between base-paired structures and MYFV replicase.

Melandrium yellow fleck bromovirus infects Arabidopsis thaliana and has genomic RNA sequence characteristics that are unique among bromoviruses

Melandrium yellow fleck bromovirus (MYFV) systemically infected Arabidopsis thaliana, although the susceptibility of several A. thaliana accessions to MYFV differed from their susceptibility to the other two bromoviruses infecting A. thaliana. We constructed full-length cDNA clones of MYFV genomic RNAs 1, 2, and 3 and determined their complete nucleotide sequences. Similar to Broad bean mottle bromovirus, (1) the 5'-terminal nucleotide of the MYFV genomic RNAs was adenine, and (2) the "D-arm" was absent from the tRNA-like structure in the 3' untranslated regions (UTRs) of MYFV RNAs. As unique characteristics, MYFV RNA3 lacked the poly(A) tract in the intercistronic region and contained a directly repeated sequence of about 200 nucleotides and polypyrimidine tracts of heterogeneous lengths in the 5' UTR. Co-infection experiments using RNA3 clones with or without the duplicated sequence demonstrated that the duplication contributed to the competitive fitness of the virus in Nicotiana benthamiana.

Small-Scale Isolation of Viral RNA-Dependent RNA Polymerase from Protoplasts Inoculated with In Vitro Transcripts

Cowpea chlorotic mottle virus (CCMV) replicated in tobacco suspension cell protoplasts inoculated with in vitro transcripts of CCMV RNA1, 2, and 3. CCMV RNA-dependent RNA polymerase (RdRp) isolated from these protoplasts specifically recognized CCMV and Brome mosaic virus (BMV) subgenomic RNA promoters and directed in vitro RNA synthesis in a manner indistinguishable from CCMV RdRp more laboriously isolated from systemically infected cowpea leaves. Omission of CCMV RNA3 from the protoplast inoculum or replacement with in vitro transcripts of BMV RNA3 reduced CCMV (+)-strand RNA1 and 2 accumulation to approximately 1/40 and approximately 1/10, respectively, of the level attained when CCMV RNA3 was present. The absence of CCMV RNA3 did not prevent assembly and isolation of highly active, template-dependent and template-specific CCMV RdRp, which directed synthesis of products identical in size to those of RdRp isolated from protoplasts inoculated with all three CCMV genomic RNAs. These results demonstrate that CCMV RNA1 and 2 are sufficient for CCMV replication and RdRp assembly in tobacco protoplasts. This approach for isolation of functional viral RdRp will be especially useful for viruses for which large quantities of infected tissue are unavailable, such as those with specific tissue tropisms or mutants incapable of systemic movement.

RNAs 1 and 2 of Alfalfa mosaic virus, expressed in transgenic plants, start to replicate only after infection of the plants with RNA 3

RNAs 1 and 2 of the tripartite genome of Alfalfa mosaic virus (AMV) encode the two viral replicase subunits. Full-length DNA copies of RNAs 1 and 2 were used to transform tobacco plants (R12 lines). None of the transgenic lines showed resistance to AMV infection. In healthy R12 plants, the transcripts of the viral cDNAs were copied by the transgenic viral replicase into minus-strand RNAs but subsequent steps in replication were blocked. When the R12 plants were inoculated with AMV RNA 3, this block was lifted and the transgenic RNAs 1 and 2 were amplified by the transgenic replicase together with RNA 3. The transgenic expression of RNAs 1 and 2 largely circumvented the role of coat protein (CP) in the inoculum that is required for infection of nontransgenic plants. The results for the first time demonstrate the role of CP in AMV plus-strand RNA synthesis at the whole plant level.

A core promoter hairpin is essential for subgenomic RNA synthesis in alfalfa mosaic alfamovirus and is conserved in other Bromoviridae

The nucleotide sequence immediately in front of the initiation site for subgenomic RNA 4 synthesis on RNA 3 minus strand, which has been proved to function as a core promoter, was inspected for secondary structure in 26 species of the plant virus family Bromoviridae. In 23 cases a stable hairpin could be predicted at a distance of 3 to 8 nucleotides from the initiation site of RNA 4. This hairpin contained several conserved nucleotides that are essential for core promoter activity in brome mosaic virus (R.W. Siegel, S. Adkins and C.C. Kao, Proc. Natl. Acad. Sci. USA 94, 11238-11243, 1997). Phylogenetic evidence and evidence from the effect of artificial mutations reported in the literature (E.A.G. van der Vossen, T. Notenboom and J.F. Bol, Virology 212, 663-672, 1995) indicate that the stem-loop structure is essential for promoter activity in alfalfa mosaic virus and probably in other Bromoviridae. Stability of the hairpin is most pronounced in the genera Alfamovirus and Ilarvirus which display genome activation by coat protein. The hypothesis is put forward that with these viruses the coat protein is needed for the viral RNA polymerase to interact with the core promoter hairpin leading to access for the enzyme to the initiation site of RNA 4.

Subgenomic RNA promoters dictate the mode of recognition by bromoviral RNA-dependent RNA polymerases

Both the brome mosaic virus (BMV) and cowpea chlorotic mottle virus (CCMV) RNA-dependent RNA polymerases (RdRps) were found to recognize the BMV core subgenomic promoter in the same manner, requiring specific functional groups at positions -17, -14, -13, and -11 relative to the subgenomic initiation site (+1). For CCMV subgenomic RNA synthesis, both RdRps required the same nucleotides and four additional nucleotides at positions -20, -16, -15, and -10. The -20 nucleotide is partially responsible for the differential mode of recognition of the two promoters. These data provide evidence that the RNA can induce RdRps to alter the mode of promoter recognition.

Deletion of internal sequences results in tobacco mosaic virus defective RNAs that accumulate to high levels without interfering with replication of the helper virus

Deletion of certain internal sequences of the tobacco mosaic tobamovirus (TMV) genome was required to create replication-defective RNAs (dRNA) that were replicated in trans by TMV. All dRNAs that accumulated to detectable levels were missing nucleotides 3420-4902, which appeared to constitute a core region that inhibited replication in trans. Deletion of additional sequences resulted in dRNAs that varied tremendously in ability to be replicated from none to levels exceeding that of the helper viral RNA. Accumulation of dRNA negative- and positive-stranded RNAs of each dRNA paralleled those of the helper virus. Negative-stranded RNA accumulation of both helper and dRNA ceased at the same early time in the infection while synthesis of both positive-stranded RNAs continued, suggesting that both dRNAs and helper virus RNAs were synthesized from the same pool of replicase complexes. Positive- to negative-stranded RNA ratios for the dRNAs were similar to, or slightly greater than the wild-type helper virus. Full-length dRNAs were not supported in trans by a replication-competent helper virus. Even though some of the artificially constructed dRNAs accumulated to levels exceeding the level of the helper virus, none appreciably affected the replication of the helper virus, suggesting that the dRNAs are produced from "excess" replicase capacity.

Long sequences in the 5' noncoding region of plum pox virus are not necessary for viral infectivity but contribute to viral competitiveness and pathogenesis

The 5'-terminal 31 nucleotides of the 146-nucleotides-long 5' noncoding region of plum pox potyvirus (PPV) are highly conserved in all the members of the Potyvirus genus. To map the sequences of the 5' noncoding region that are necessary in vivo for infectivity, we have constructed a nested set of substitution and deletion mutants. While we were not able to infect Nicotiana clevelandii plants with full-length PPV transcripts bearing mutations in the 5'-terminal 35 nucleotides of the viral genome, the deletion of long sequences located between nucleotides 39 and 145 did not alter either the rate of infection or viral accumulation. Nevertheless, these mutants were not able to compete with the wild-type strain in coinoculation experiments. Plants infected with a PPV mutant that lacked nucleotides 127 to 145 showed a very mild symptomathology; the wild-type symptom severity was recovered after spontaneous second-site mutations.

Effects of coat protein mutations and reduced movement protein expression on infection spread by cowpea chlorotic mottle virus and its hybrid derivatives

Previously we have reported that the essential 3a movement gene of icosahedral cowpea chlorotic mottle virus (CCMV) can be functionally replaced by the 30-kDa movement gene of rod-shaped sunn-hemp mosaic virus (SHMV). Because plant RNA viruses differ in requiring or not requiring coat protein for systemic infection, we have now investigated whether systemic spread by this CCMV/SHMV hybrid is dependent on its CCMV coat protein as well as its SHMV movement protein. We find that either deletion or frameshift mutations in the coat protein gene block systemic spread. Thus, like wild-type CCMV, systemic infection by the hybrid is dependent on both movement protein and coat protein. These results further support the conclusion that the required functions of the coat and movement proteins in CCMV spread do not depend on sequence-specific interaction between these proteins. Additional features of the hybrid also motivated testing the effects of modulating movement protein expression. Creating an extra, out-of-frame translational start codon (AUG) shortly upstream of the 3a movement protein gene in CCMV downregulated its expression 18-fold. Nevertheless, for CCMV derivatives bearing either the CCMV 3a gene or the SHMV 30-kDa gene, the extra AUG resulted in only a minor delay in the onset of viral spread and little or no effect on the subsequent rate of cell-to-cell spread. Thus, under normal circumstances, the rate of CCMV cell-to-cell spread in cowpea plants appears to be limited primarily by factors other than movement protein synthesis.

Analysis of the two subgenomic RNA promoters for turnip crinkle virus in vivo and in vitro

Infection of plants or protoplasts with turnip crinkle virus (TCV), a monopartite RNA virus, results in the synthesis of the genomic RNA and two subgenomic (sg) RNAs. The transcription start site for the 1.45-kb sgRNA was previously mapped to position 2606 (J. C. Carrington, T. J. Morris, P. G. Stockley, and S. C. Harrison, (1987). J. Mol. Biol. 194, 265-276) corresponding to position 2607 in the TCVms isolate and the start site for the 1.7-kb sgRNA has now been mapped to position 2333 in TCVms. A 96-base sequence (90 bases upstream and 6 bases downstream) encompassing the transcription start site for the 1.45-kb sgRNA was sufficient for full promoter activity. Similarly, a 94-base sequence (90 bases upstream and 4 bases downstream) encompassing the start site was required for full activity of the 1.7-kb sgRNA promoter. The 1.45-kb sgRNA promoter, but not the 1.7-kb sgRNA promoter, was able to direct synthesis of a nontemplate RNA in vitro using partially purified TCV RNA-dependent RNA polymerase. Computer generated secondary structures for the two sgRNA promoters revealed an extensive hairpin just upstream from the transcription start site. Comparisons of corresponding sequences from related viruses indicates higher sequence conservation for the 1.45-kb sgRNA promoter compared with the 1.7-kb sgRNA promoter, despite the latter's location within the RNA-dependent RNA polymerase open reading frame.

Invasion of minor veins of tobacco leaves inoculated with tobacco mosaic virus mutants defective in phloem-dependent movement

To fully understand vascular transport of plant viruses, the viral and host proteins, their structures and functions, and the specific vascular cells in which these factors function must be determined. We report here on the ability of various cDNA-derived coat protein (CP) mutants of tobacco mosaic virus (TMV) to invade vascular cells in minor veins of Nicotiana tabacum L. cv. Xanthi nn. The mutant viruses we studied, TMV CP-O, U1mCP15-17, and SNC015, respectively, encode a CP from a different tobamovirus (i.e., from odontoglossum ringspot virus) resulting in the formation of non-native capsids, a mutant CP that accumulates in aggregates but does not encapsidate the viral RNA, or no CP. TMV CP-O is impaired in phloem-dependent movement, whereas U1mCP15-17 and SNC015 do not accumulate by phloem-dependent movement. In developmentally-defined studies using immunocytochemical analyses we determined that all of these mutants invaded vascular parenchyma cells within minor veins in inoculated leaves. In addition, we determined that the CPs of TMV CP-O and U1mCP15-17 were present in companion (C) cells of minor veins in inoculated leaves, although more rarely than CP of wild-type virus. These results indicate that the movement of TMV into minor veins does not require the CP, and an encapsidation-competent CP is not required for, but may increase the efficiency of, movement into the conducting complex of the phloem (i.e., the C cell/sieve element complex). Also, a host factor(s) functions at or beyond the C cell/sieve element interface with other cells to allow efficient phloem-dependent accumulation of TMV CP-O.

The 5' nontranslated region of potato virus X RNA affects both genomic and subgenomic RNA synthesis

A tobacco protoplast system was developed to analyze cis-acting sequences required for potato virus X (PVX) replication. Protoplasts inoculated with transcripts derived from a PVX cDNA clone or from clones containing mutations in their 5' nontranslated regions (NTRs) were assayed for RNA production by S1 nuclease protection assays. A time course of plus- and minus-strand-RNA accumulation indicated that both minus- and plus-strand PVX RNAs were detectable at 0.5 h postinoculation. Although minus-strand RNAs accumulated more rapidly than plus-strand RNAs, maximum levels of plus-strand RNAs were 40- to 80-fold higher. On the basis of these data, time points were chosen for determination of RNA levels in protoplasts inoculated with PVX clones containing deletions or an insertion in their 5' NTRs. Deletions of more than 12 nucleotides from the 5' end, internal deletions, and one insertion in the 5' NTR resulted in substantially decreased levels of plus-strand-RNA production. In contrast, all modified transcripts were functional for minus-strand-RNA synthesis, suggesting that elements in the 5' NTR were not essential for minus-strand-RNA synthesis. Further analysis of the 5' NTR deletion mutants indicated that all mutations that decreased genomic plus-strand-RNA synthesis also decreased synthesis of the two major subgenomic RNAs. These data indicate that cis-acting elements from different regions of the 5' NTR are required for plus-strand-RNA synthesis and that this process may be linked to synthesis of subgenomic RNAs.

Comparison of the replication of positive-stranded RNA viruses of plants and animals

It is clear from the experimental data that there are some similarities in RNA replication for all eukaryotic positive-stranded RNA viruses—that is, the mechanism of polymerization of the nucleotides is probably similar for all. It is noteworthy that all mechanisms appear to utilize host membranes as a site of replication. Membranes appear to function not only as a way of compartmentalizing virus RNA replication but also appear to have a central role in the organization and functioning of the replication complex, and further studies in this area are needed. Within virus supergroups, similarities are evident between animal and plant viruses—for example, in the nature and arrangements of replication genes and in sequence similarities of functional domains. However, it is also clear that there has been considerable divergence, even within supergroups. For example, the animal alpha-viruses have evolved to encode proteinases which play a central controlling function in the replication cycle, whereas this is not common in the plant alpha-like viruses and even when it occurs, as in the tymoviruses, the strategies that have evolved appear to be significantly different. Some of the divergence could be host-dependent and the increasing interest in the role of host proteins in replication should be fruitful in revealing how different systems have evolved. Finally, there are virus supergroups that appear to have no close relatives between animals and plants, such as the animal coronavirus-like supergroup and the plant carmo-like supergroup.

In vivo restoration of biologically active 3' ends of virus-associated RNAs by nonhomologous RNA recombination and replacement of a terminal motif

Sequences at the 3' ends of plus-strand RNA viruses and their associated subviral RNAs are important cis elements for the synthesis of minus strands in vivo and in vitro. All RNAs associated with turnip crinkle virus (TCV), including the genomic RNA (4,054 bases) and satellite RNAs (sat-RNAs) such as sat-RNA D (194 bases), terminate with the motif CCUGCCC. While investigating the ability of in vivo-generated recombinants between sat-RNA D and TCV to be amplified in plants, we discovered that sat-RNA D, although truncated by as many as 15 bases in the chimeric molecules, was released from the chimeric transcripts and amplified to high levels. The "new" sat-RNA D molecules nearly all terminated with the motif (C1-2)UG(C1-3) (which may begin with 1 or 2 cytosines and end with 1, 2, or 3 cytosines), which was similar or identical to the natural sat-RNA D 3' end. The new sat-RNA D also contained between 1 and 22 bases of heterogeneous sequence upstream from the terminal motif, which, in some cases, was apparently derived from internal regions of either the plus or minus strand of the TCV genomic RNA. Since most of these internal genomic RNA sequences within TCV were not adjacent to (C1-2)UG(C1-3), at least two steps were required to produce new sat-RNA D 3' ends: nonhomologous recombination with the TCV genomic RNA followed by the addition or modification of the terminus to generate the (C1-2)UG(C1-3) motif.

Bromovirus RNA replication and transcription require compatibility between the polymerase- and helicase-like viral RNA synthesis proteins

The positive-strand RNA bromoviruses encode two nonstructural proteins, 1a and 2a, involved in RNA-dependent RNA replication. These proteins have extensive sequence similarities with methyltransferase, helicase, and polymerase proteins of other plant and animal viruses. 1a and 2a can also form a complex in vitro. To explore whether 1a-2a interaction is required for RNA replication in vivo, we reassorted the 1a and 2a genes from two different bromoviruses, brome mosaic virus (BMV) and cowpea chlorotic mottle virus (CCMV). 1a and 2a were expressed independently of viral replication by using RNA- or DNA-based transient expression, and their in vivo RNA replication activities were tested in protoplasts with BMV and CCMV RNA3 templates. RNA-based transient expression confirmed prior indications that bromovirus RNA replication is more sensitive to reductions in 1a expression than to reductions in 2a expression. DNA-based expression of the homologous combinations of 1a and 2a supported high levels of RNA synthesis, but both 1a-2a heterologous combinations exhibited RNA synthesis defects. The combination of CCMV 1a and BMV 2a did not support detectable synthesis of negative-strand, positive-strand, or subgenomic RNA. The converse combination of BMV 1a and CCMV 2a was preferentially defective in positive-strand and subgenomic RNA accumulation, showing that 1a-2a interaction is involved in these processes in ways distinct from negative-strand RNA synthesis, which was only slightly affected. These results indicate that at least some functions of 1a and 2a operate in a mutually dependent manner in vivo and that the mechanisms of positive- and negative-strand RNA synthesis are differentiated in part by features of such interactions.

Bromovirus movement protein genes play a crucial role in host specificity

Monocot-adapted brome mosaic virus (BMV) and dicot-adapted cowpea chlorotic mottle virus (CCMV) are closely related bromoviruses with tripartite RNA genomes. Although RNAs 1 and 2 together are sufficient for RNA replication in protoplasts, systemic infection also requires RNA3, which encodes the coat protein and the nonstructural 3a movement protein. We have previously shown with bromoviral reassortants that host specificity determinants in both viruses are encoded by RNA3 as well as by RNA1 and/or RNA2. Here, to test their possible role in host specificity, the 3a movement protein genes were precisely exchanged between BMV and CCMV. The hybrid viruses, but not 3a deletion mutants, systemically infected Nicotiana benthamiana, a permissive host for both parental viruses. The hybrids thus retain basic competence for replication, packaging, cell-to-cell spread, and long-distance (vascular) spread. However, the hybrids failed to systemically infect either barley or cowpea, selective hosts for parental viruses. Thus, the 3a gene and/or its encoded 3a protein contributes to host specificity of both monocot- and dicot-adapted bromoviruses. Tests of inoculated cowpea leaves showed that the spread of the CCMV hybrid containing the BMV 3a gene was blocked at a very early stage of infection. Moreover, the BMV hybrid containing the CCMV 3a gene appeared to spread farther than wt BMV in inoculated cowpea leaves. Several pseudorevertants directing systemic infection in cowpea leaves were obtained from plants inoculated with the CCMV(BMV 3a) hybrid, suggesting that the number of mutations required to adapt the hybrid to dicots is small.

Role of the 5' leader sequence of alfalfa mosaic virus RNA 3 in replication and translation of the viral RNA

RNA 3 of alfalfa mosaic virus (AIMV) encodes the movement protein P3 and the viral coat protein which is translated from the subgenomic RNA 4. The 5'-leader sequences of RNA 3 of AIMV strains S, A, and Y differ in length from 314 to 392 nucleotides and contain a variable number of internal control regions of type 2 (ICR2 motifs) each located in a 27 nt repeat. Infectious cDNA clones were used to exchange the leader sequences of the three strains. This revealed that the leader sequence controls the specific ratio in which RNAs 3 and 4 are synthesized for each strain. In addition, it specifies strain specific differences in the kinetics of P3 accumulation in plants. Subsequent deletion analysis revealed that a 5'-sequence of 112 nt containing one ICR2 motif was sufficient for a 10 to 20% level of RNA 3 accumulation in protoplasts and a delayed accumulation in plants. An additional leader sequence of maximally 114 nt, containing two ICR2 motifs, was required to permit wildtype levels of RNA 3 accumulation. The effect of deletions in the leader sequence on P3 synthesis in vitro and in vivo was investigated.

Location of the replication determinants of the satellite RNA associated with grapevine fanleaf nepovirus (strain F13)

A large satellite RNA of 1114 nucleotides, named RNA3, is always found associated with the genomic RNAs of grapevine fanleaf virus, isolate F13 (GFLV-F13). RNA3 encodes a non-structural protein (P3) of M(r) 37K to which no function has previously been assigned. Full-length cDNA clones of RNA3 were mutated in the 5' and 3' non-coding regions and in the 37K open reading frame. The ability of transcripts obtained from these clones to be replicated was investigated by protoplast infection in the presence of a helper virus. We demonstrate that the 5' and 3' non-coding regions as well as the satellite-encoded P3 protein are essential for replication of the GFLV-F13 satellite RNA. Our results suggest that two hydrophobic regions located at the N- and C-extremity of P3 and a zinc-finger motif near the C-terminal extremity of P3 are probably involved in the replication of this satellite. Analysis of the in vitro translation products from transcripts of RNA3 clones of different lengths indicates that the double band formed by P3 could result from phosphorylation of a part of this protein.

cis-acting elements for in trans complementation of replication-defective mutant of tobacco mosaic virus

We have shown that virus-encoded replicase components of tobacco mosaic virus (TMV)(130K/180K proteins) could complement a replication-defective mutant (LDR28) for viral replication in trans [Ogawa et al. Virology 185, 580-584 (1991)]. Using this trans-complementation system, we investigated the dispensability of regions of the 130K/180K protein genes as cis-acting elements for viral replication. A series of replication-defective mutants (LDRs) which had various deletions in the 130K/180K coding region were constructed. These were co-inoculated with a replication-competent mutant (LDCS29) into tobacco protoplasts. Accumulation of LDR-genomic RNA, CP mRNA, and CP was much increased by the removal of the 3' terminal one-third of the readthrough part of 180K protein gene (residues 4529-4937 of TMV-RNA) from LDR, suggesting that this region interferes with the viral replication in this trans-complementation system. In addition, accumulation of CP mRNA and CP was much decreased by the removal of the 5'terminal half of the 30K protein gene (residues 4938-5263 of TMV-RNA), suggesting the presence of an element to enhance the synthesis of CP mRNA in this region.

cis-active sequences near the 5'-termini of beet necrotic yellow vein virus RNAs 3 and 4

RNAs 3 and 4 of the multicomponent genome of beet necrotic yellow vein virus are dispensable for infection of Chenopodium quinoa leaves. We have used mutagenesis of biologically active RNA 3 transcripts to identify 5'-proximal sequences essential in cis for RNA 3 amplification. One such element, Box I, (nucleotides 283-292) was complementary to the first 10 residues (Box I') following the 5'-terminal cap. A second cis-active element (Box II) was identified between nucleotides 237-244 and was complementary to nucleotides 16-23 (Box II'). Other cis-active sequences exist between Box II' and II but have not been mapped to fine scale. Most sequence substitutions in Boxes I and II or in the 5'-proximal complementary sequences were lethal but compensatory mutations designed to restore Box I/I' or Box II/II' base pairing restored viability, suggesting that secondary structure involving these elements rather than their exact sequence is the critical feature. Transcripts bearing short deletions near residue 200 were replicated but did not assemble into virions, indicating that this region contains or contributes to a cis-active encapsidation signal. Similar experiments with RNA 4 transcript have shown that 5'-proximal cis-essential elements are limited to the first 400 residues of this RNA. Essential subdomains within this region have not been mapped but there are no structures obviously homologous to Boxes I/I' and II/II' of RNA 3.

A hybrid plant RNA virus made by transferring the noncapsid movement protein from a rod-shaped to an icosahedral virus is competent for systemic infection

For many plant RNA viruses, multiple viral gene products, including noncapsid movement proteins and capsid proteins, contribute to the spread of infection within plants. The extent to which these factors interact to support infection spread is not known, but, for movement protein mutants of certain viruses, the inability of coinoculated "helper" viruses to complement defective movement has suggested a possible requirement for coadaptation between noncapsid movement proteins and other virus factors. To test directly for required coadaptation, the 3a movement protein gene of cowpea chlorotic mottle virus, an icosahedral bromovirus, was replaced with the nonhomologous 30-kDa movement protein gene of sunn-hemp mosaic virus, a rod-shaped, cowpea-adapted tobamovirus. The resulting hybrid virus is competent for systemic infection of cowpea, with systemic infection dependent upon expression of the 30-kDa gene. In view of the dramatic differences between cowpea chlorotic mottle virus and sunn-hemp mosaic virus in genetic organization and particle morphology, the ability of the hybrid to systemically infect cowpea implies that the tobamovirus 30-kDa movement protein functions independently of sequence-specific interactions with other viral components or sequences. Similarly, the required contribution of bromovirus capsid protein to infection movement appears to be independent of specific interaction with the natural 3a movement protein. In addition to other implications concerning movement protein and coat protein function, the results are consistent with the possibility that two or more distinguishable transfer processes may be involved in crossing different tissue barriers to achieve full systemic spread of infection.

The nucleotide sequence and genome organization of the RNA2 and RNA3 segments in broad bean mottle virus

Complete nucleotide sequences of broad bean mottle virus (BBMV) genomic RNAs 2 and 3 were determined. They consist of 2811 and 2293 nucleotides, respectively. Both RNAs are caped and, unlike in other tricornaviruses, both initiate with an A residue. BBMV RNA2 is monocistronic and encodes an 815 amino acid 2a protein, whereas RNA3 is dicistronic, encoding for a 295 amino acid 3a protein and for the 190 amino acid coat protein. A central, 423 amino acid 2a protein core region is highly homologous among the three bromoviruses, whereas both N- and C-termini are more heterologous. Most of the homologies among 3a proteins are concentrated within the N-termini two-thirds of the molecule that is predominantly hydrophobic, whereas the C-terminal one-third contains a large number of charged amino acids. The homologies among coat proteins are clustered within several mostly hydrophobic, or neutral, domains. The 5' noncoding region of the RNA2 has 110 nucleotides, whereas that of RNA3 contains 330 nucleotides. As in cowpea chlorotic mottle virus, but unlike in Brome mosaic virus, the 5' noncoding region includes subgenomic promoter-like sequences. The BBMV RNA3 intercistronic region also has subgenomic promoter sequences and contains a long poly(A) stretch. At the 3' end, BBMV RNAs 2 and 3 have 257 and 236 noncoding nucleotides, respectively.

Substantial portions of the 5' and intercistronic noncoding regions of cowpea chlorotic mottle virus RNA3 are dispensable for systemic infection but influence viral competitiveness and infection pathology

Cowpea chlorotic mottle virus (CCMV) has a tripartite, positive strand RNA genome. Genomic RNA3 (2.2 kb) encodes the 3a nonstructural protein and the coat protein, which are dispensable for viral RNA synthesis in protoplasts, but required for systemic infection of whole plants. In protoplasts, portions of the 5' and intercistronic noncoding regions of CCMV RNA3 are also dispensable for RNA3 replication and for transcription of the subgenomic coat protein mRNA. To determine whether these noncoding sequences are required for systemic infection, a series of 5' and intercistronic deletions in RNA3 were tested for their effects on the infection of cowpea plants, a natural host of CCMV. The results refine the mapping of the subgenomic mRNA promoter and show that at least 144 bases in the 5' noncoding region and at least 125 bases in the intercistronic noncoding region of CCMV RNA3 are dispensable for systemic infection. For mutants with deletions within these regions, no differences were noted in the rate of infection spread, and the level of virus accumulation in systemically infected tissue 10-14 days postinoculation was 60-100% of wild type (wt). However, the largest viable intercistronic deletion transformed the nearly symptomless appearance of wt CCMV infections to an extensive, bright yellow chlorosis, showing that infection pathology can be altered by mutations with a regulatory rather than a protein-coding character. In addition, neither 5' nor intercistronic deletion mutants competed effectively with wt CCMV in whole plant co-infection experiments; i.e., such mutants were not detectable in systemically infected tissue after co-inoculation with wt CCMV. Thus, although substantial portions of both the 5' and the intercistronic noncoding regions of CCMV RNA3 are dispensable for individual systemic infection, these segments contribute to the competitive fitness of the virus and influence interaction with the host, as evidenced by symptom response.

Bromovirus RNA replication and transcription

Ongoing characterization of cis-acting sequences in bromovirus RNA-dependent RNA replication and transcription has been complemented in the past year by progress in elucidating the roles of virus-encoded replication factors 1a and 2a. Recent studies suggest that the helicase-like 1a and polymerase-like 2a proteins may participate in a well organized replication complex in which polymerase, helicase, and possibly capping functions operate in a highly coordinated manner.

Construction of tobacco mosaic virus subgenomic replicons that are replicated and spread systemically in tobacco plants

Two tobacco mosaic virus (TMV)-derived replicons, created by deletion of most of the 126/183-kDa open reading frame (ORF), replicated and systemically invaded tobacco plants when supported by wild type TMV. One RNA replicon contained an internal direct repeat of 476 nucleotides from the 3' end of the 30-kDa ORF. Although this RNA was replicated, most of the progeny were heterogeneous in size and smaller than the original transcript. A second TMV-derived RNA replicon, without any internally repeated sequences and containing a deletion of the 5' portion of the 30-kDa ORF as well as most of the 126/183-kDa ORF, was created and coinoculated with wild type TMV as helper. This RNA also was replicated efficiently and systemically invaded tobacco plants. An examination of the sequences of cDNA clones obtained after PCR amplification of the progeny population of this RNA replicon demonstrated that the observed size heterogeneity was due to deletions and insertions adjacent to the artificially created deletion junction. These data demonstrate that a TMV infection is capable of supporting an artificially created RNA replicon, similar to defective interfering RNAs or satellites. However, these dependent RNAs were replicated without noticeably interfering with wild type TMV symptoms or replication.

Deletion analysis of cis- and trans-acting elements involved in replication of alfalfa mosaic virus RNA 3 in vivo

DNA copies of alfalfa mosaic virus (AIMV) RNA 3 were transcribed in vitro into RNA molecules with deletions in coding and noncoding sequences. The replication of these transcripts was studied in protoplasts from transgenic tobacco plants expressing DNA copies of AIMV RNAs 1 and 2. Deletions in the 5'-proximal P3 gene, encoding the putative viral transport function, did not affect replication whereas deletions in the 3'-proximal coat protein gene reduced replication of RNA 3 by about 100-fold. Sequences required for the synthesis in protoplasts of RNA 4, the coat protein messenger, were more extensive than the subgenomic promoter characterized previously in an in vitro replicase assay. At the 5'-end of RNA 3 a sequence of 169 nucleotides was sufficient for replication whereas a sequence of 112 nucleotides was not. 3'-Terminal deletions up to 133 nucleotides reduced replication to a low but significant level. Further 3'-deletions abolished replication.

Complementation and recombination between alfalfa mosaic virus RNA3 mutants in tobacco plants

Deletions were made in an infectious cDNA clone of alfalfa mosaic virus (AIMV) RNA3 and the replication of RNA transcripts of these cDNAs was studied in tobacco plants transformed with AIMV replicase genes (P12 plants). Previously, we found that deletions in the P3 gene did not affect accumulation of RNA3 in P12 protoplasts whereas deletions in the coat protein (CP) gene reduced accumulation 100-fold (A. C. van der Kuyl, L. Neeleman, and J. F. Bol, 1991, Virology 183, 687-694). In P12 plants deletions in the P3 gene reduced accumulation by about 200-fold and accumulation of CP deletion mutants was not detectable. When P12 plants were inoculated with a mixture of P3- and CP-deletion mutants, both mutants replicated efficiently and various amounts of full-length RNA3 molecules were formed by recombination. The observation that some P3 and CP mutants did not recombine at a detectable level after several passages in P12 plants demonstrated that mutations in the AIMV P3 and CP genes can be complemented in trans.

Use of bromovirus RNA3 hybrids to study template specificity in viral RNA amplification

Brome mosaic virus (BMV) and cowpea chlorotic mottle virus (CCMV) are related positive-strand RNA viruses with genomes divided among RNAs 1, 2, and 3. RNAs 1 and 2 encode the viral RNA replication factors, which share extensive conservation with proteins encoded by the animal alphaviruses and diverse plant viruses. In barley protoplasts, CCMV RNAs 1 and 2 support high but distinguishable amplification of either BMV RNA3 (B3) or CCMV RNA3 (C3), while BMV RNAs 1 and 2 show even greater discrimination, amplifying C3 poorly relative to B3. To identify the cis-acting determinants of these template-specific and virus-specific differences in RNA3 accumulation, we constructed and tested a series of B3/C3 hybrids that exchange in turn the 5',3', and intercistronic noncoding regions, which contain all sequences required in cis for efficient B3 and C3 amplification. Despite suggestive prior in vitro results, the 3' noncoding regions were not the major determinant of the differences in amplification of B3 and C3 in vivo. Rather, 3' exchanges had relatively modest effects and did not transfer the distinctive asymmetry of amplification between B3 and C3. Intercistronic exchanges produced larger effects on RNA3 accumulation and transferred some of the polarized characteristics of the wild-type B3 and C3 behaviors. 5' exchanges revealed context-specific effects showing that the contribution of the B3 5' region to RNA3 amplification is dependent on some other B3 segment or segments. Together with previous results implicating the BMV and CCMV 1a genes in trans-acting discrimination between B3 and C3 (P. Traynor and P. Ahlquist, J. Virol. 64:69-77, 1990), these observations should help to guide studies of protein-RNA interactions governing template specificity in bromovirus RNA replication.

Biological activities of hybrid RNAs generated by 3'-end exchanges between tobacco mosaic and brome mosaic viruses

Sequences within the conserved, aminoacylatable 3' noncoding regions of brome mosaic virus (BMV) genomic RNAs 1, 2, and 3 direct initiation of negative-strand synthesis by BMV polymerase extracts and, like sequences at the structurally divergent but aminoacylatable 3' end of tobacco mosaic virus (TMV) RNA, are required in cis for RNA replication in vivo. A series of chimeric RNAs in which selected 3' segments were exchanged between the tyrosine-accepting BMV and histidine-accepting TMV RNAs were constructed and their amplification was examined in protoplasts inoculated with or without other BMV and TMV RNAs. TMV derivatives whose 3' noncoding region was replaced by sequences from BMV RNA3 were independently replication competent when the genes for the TMV 130,000-M(r) and 180,000-M(r) replication factors remained intact. TMV replicase can thus utilize the BMV-derived 3' end, though at lower efficiency than the wild-type (wt) TMV 3' end. Providing functional BMV RNA replicase by coinoculation with BMV genomic RNAs 1 and 2 did not improve the amplification of these hybrid genomic RNAs. By contrast, BMV RNA3 derivatives carrying the 3' noncoding region of TMV were not amplified when coinoculated with wt BMV RNA1 and RNA2, wt TMV RNA, or all three. Thus, BMV replicase appeared to be unable to utilize the TMV 3' end, and there was no evidence of intervirus complementation in the replication of any of the hybrid RNAs. In protoplasts coinoculated with BMV RNA1 and RNA2, the nonamplifiable RNA3 derivatives bearing TMV 3' sequences gave rise to diverse new rearranged or recombined RNA species that were amplifiable.

Functional analysis of deletion mutants of cucumber mosaic virus RNA3 using an in vitro transcription system

Full-length DNA copies of RNAs 1, 2, and 3 of CMV Y strain (CMV-Y) were cloned downstream of modified phage T7 promoter sequences to obtain infectious RNA transcripts. The small number of extra nonviral nucleotides at the 5' ends considerably decreased the specific infectivity of the transcripts of RNAs 1 and 2 but did not affect that of the RNA3 transcripts. Using the most infective transcripts, up to 45% of tobacco protoplasts could be infected. Various cDNA mutants were constructed from the full-length RNA3 cDNA to give RNA transcripts having deletions in the coding region of the 3a protein or the coat protein. These mutants replicated in tobacco protoplasts but did not produce systemic symptoms on tobacco when inoculated together with transcripts of RNAs 1 and 2. One of the mutants having a small in-frame deletion near the N-terminal region of the coat protein produced local lesions on cowpea and local chlorotic spots on the inoculated leaves of tobacco. These results suggest that both the 3a protein and the coat protein are involved in virus transport, and that viral assembly is associated with long-distance movement of CMV.

Deletion analysis of brome mosaic virus 2a protein: effects on RNA replication and systemic spread

Brome mosaic virus (BMV) genomic RNA2 encodes the 94-kDa 2a protein, which is one of two BMV nonstructural proteins required for RNA replication and subgenomic mRNA transcription. 2a contains a central polymeraselike region, which has extensive sequence similarity with the Sindbis virus nsP4 and tobacco mosaic virus (TMV) 183-kDa replication proteins, and also contains N- and C-terminal flanking segments without counterparts in the Sindbis virus and TMV nonstructural proteins. To further investigate the roles of the central and flanking segments in 2a, we have constructed a series of deletion and frameshift mutants in a biologically active BMV RNA2 cDNA clone and tested their ability to support viral RNA replication in barley protoplasts and systemic infection in whole barley plants. The entire 125-amino-acid C-terminal segment following the polymeraselike region was dispensable for RNA replication and transcription. Within the 200-amino-acid N-terminal flanking segment, deletion of the first 50 residues dramatically reduced genomic and subgenomic RNA accumulation, and deletion of 100 or more residues abolished detectable RNA synthesis. All mutations removing residues from the central polymeraselike domain also blocked RNA replication in trans. Sequences required in cis for RNA2 replication or stability were found to occur within the first 300 nucleotides of the 2a coding region. In whole barley plants, systemic infection was inhibited even by 2a deletions that supported strong RNA replication in protoplasts. Some replication-competent 2a variants failed to spread to uninoculated leaves, while other showed 10- to 500-fold-reduced virus yield in both inoculated and uninoculated leaves. These reductions were not due to any defects in RNA2 encapsidation.

Regeneration of a functional RNA virus genome by recombination between deletion mutants and requirement for cowpea chlorotic mottle virus 3a and coat genes for systemic infection

RNAs 1 and 2 of the tripartite cowpea chlorotic mottle virus (CCMV) genome are sufficient for RNA replication in protoplasts, whereas systemic infection of cowpea plants additionally requires RNA3, which encodes the 3a noncapsid protein and coat protein. By using biologically active CCMV cDNA clones, we find that deletions in either RNA3 gene block systemic infection. Thus, though some plant RNA viruses are able to spread systemically without encapsidation, both the coat and 3a genes are required for systemic infection of cowpeas by CCMV. When plants were coinoculated with CCMV RNAs 1 and 2 and both the 3a and coat deletion mutants of RNA3, 30-60% rapidly developed systemic infection. Progeny RNA recovered from systemically infected leaves in such infections contained neither of the starting deletion mutants but rather a single full-length RNA3 component with both genes intact. Nucleotide substitutions introduced into the coat protein deletion mutant as an artificial marker were recovered in the full-length progeny RNA, confirming its recombinant nature. Intermolecular RNA recombination in planta can, therefore, rescue a complete infectious genome from coinoculated mutants independently disabled for systemic spread. These results have implications for the repair of defective genomes produced by frequent natural replication errors, the possible emergence of newly adapted RNA viruses upon coinfection of new hosts, and further studies of RNA virus recombination.