Altered balance of the synthesis of plus- and minus-strand RNAs induced by RNAs 1 and 2 of alfalfa mosaic virus in the absence of RNA 3

Citrus tristeza virus co-opts glyceraldehyde 3-phosphate dehydrogenase for its infectious cycle by interacting with the viral-encoded protein p23

KEY MESSAGE

Citrus tristeza virus encodes a unique protein, p23, with multiple functional roles that include co-option of the cytoplasmic glyceraldehyde 3-phosphate dehydrogenase to facilitate the viral infectious cycle. The genome of citrus tristeza virus (CTV), genus Closterovirus family Closteroviridae, is a single-stranded (+) RNA potentially encoding at least 17 proteins. One (p23), an RNA-binding protein of 209 amino acids with a putative Zn-finger and some basic motifs, displays singular features: (i) it has no homologues in other closteroviruses, (ii) it accumulates mainly in the nucleolus and Cajal bodies, and in plasmodesmata, and (iii) it mediates asymmetric accumulation of CTV RNA strands, intracellular suppression of RNA silencing, induction of some CTV syndromes and enhancement of systemic infection when expressed as a transgene ectopically or in phloem-associated cells in several Citrus spp. Here, a yeast two-hybrid screening of an expression library of Nicotiana benthamiana (a symptomatic experimental host for CTV), identified a transducin/WD40 domain protein and the cytosolic glyceraldehyde 3-phosphate dehydrogenase (GAPDH) as potential host interactors with p23. Bimolecular fluorescence complementation corroborated the p23-GAPDH interaction in planta and showed that p23 interacts with itself in the nucleolus, Cajal bodies and plasmodesmata, and with GAPDH in the cytoplasm (forming aggregates) and in plasmodesmata. The latter interaction was preserved in a p23 deletion mutant affecting the C-terminal domain, but not in two others affecting the Zn-finger and one internal basic motif. Virus-induced gene silencing of GAPDH mRNA resulted in a decrease of CTV titer as revealed by real-time RT-quantitative PCR and RNA gel-blot hybridization. Thus, like other viruses, CTV seems to co-opt GAPDH, via interaction with p23, to facilitate its infectious cycle.

Effects of the number of genome segments on primary and systemic infections with a multipartite plant RNA virus

Multipartite plant viruses were discovered because of discrepancies between the observed dose response and predictions of the independent-action hypothesis (IAH) model. Theory suggests that the number of genome segments predicts the shape of the dose-response curve, but a rigorous test of this hypothesis has not been reported. Here, Alfalfa mosaic virus (AMV), a tripartite Alfamovirus, and transgenic Nicotianatabacum plants expressing no (wild type), one (P2), or two (P12) viral genome segments were used to test whether the number of genome segments necessary for infection predicts the dose response. The dose-response curve of wild-type plants was steep and congruent with the predicted kinetics of a multipartite virus, confirming previous results. Moreover, for P12 plants, the data support the IAH model, showing that the expression of virus genome segments by the host plant can modulate the infection kinetics of a tripartite virus to those of a monopartite virus. However, the different types of virus particles occurred at different frequencies, with a ratio of 116:45:1 (RNA1 to RNA2 to RNA3), which will affect infection kinetics and required analysis with a more comprehensive infection model. This analysis showed that each type of virus particle has a different probability of invading the host plant, at both the primary- and systemic-infection levels. While the number of genome segments affects the dose response, taking into consideration differences in the infection kinetics of the three types of AMV particles results in a better understanding of the infection process.

Emergence of distinct brome mosaic virus recombinants is determined by the polarity of the inoculum RNA

Despite overwhelming interest in the impact exerted by recombination during evolution of RNA viruses, the relative contribution of the polarity of inoculum templates remains poorly understood. Here, by agroinfiltrating Nicotiana benthamiana leaves, we show that brome mosaic virus (BMV) replicase is competent to initiate positive-strand [(+)-strand] synthesis on an ectopically expressed RNA3 negative strand [(-) strand] and faithfully complete the replication cycle. Consequently, we sought to examine the role of RNA polarity in BMV recombination by expressing a series of replication-defective mutants of BMV RNA3 in (+) or (-) polarity. Temporal analysis of progeny sequences revealed that the genetic makeup of the primary recombinant pool is determined by the polarity of the inoculum template. When the polarity of the inoculum template was (+), the recombinant pool that accumulated during early phases of replication was a mixture of nonhomologous recombinants. These are longer than the inoculum template length, and a nascent 3' untranslated region (UTR) of wild-type (WT) RNA1 or RNA2 was added to the input mutant RNA3 3' UTR due to end-to-end template switching by BMV replicase during (-)-strand synthesis. In contrast, when the polarity of the inoculum was (-), the progeny contained a pool of native-length homologous recombinants generated by template switching of BMV replicase with a nascent UTR from WT RNA1 or RNA2 during (+)-strand synthesis. Repair of a point mutation caused by polymerase error occurred only when the polarity of the inoculum template was (+). These results contribute to the explanation of the functional role of RNA polarity in recombination mediated by copy choice mechanisms.

Alfalfa mosaic virus temperature-sensitive mutants. II. Early functions encoded by RNAs 1 and 2

Mutants Bts 03 and Mts 04 of alfalfa mosaic virus (AIMV) have temperature-sensitive mutations in genomic RNAs 1 and 2, respectively. These mutants are defective in the production of viral minus-strand RNA, coat protein, and infectious virus when assayed in cowpea protoplasts at the nonpermissive temperature (30 degrees). To determine the temperature-sensitive step in the replication cycle, mutant-infected protoplasts were shifted from an incubation temperature of 25 degrees (permissive temperature) to 30 degrees at different times during a 24-hr incubation period. For both mutants an initial incubation of infected protoplasts for 6 hr at 25 degrees was sufficient to permit a normal minus-strand RNA synthesis, translation of RNA 4 into coat protein, and assembly of infectious virus during the subsequent incubation at the nonpermissive temperature. Probably, AIMV RNAs 1 and 2 encoded proteins are produced early in infection and the mutant proteins are protected from inactivation at 30 degrees once they are incorporated in a functional structure.

Double-stranded RNAs of cucumber mosaic virus and its satellite contain an unpaired terminal guanosine: implications for replication

Terminal sequences of the double-stranded (ds) forms of RNAs 3 and 4 and the satellite RNA (CARNA 5) of cucumber mosaic virus (CMV) have been determined. The ds forms of both CARNA 5 and RNA 3 contain an unpaired guanosine (G) at the 3' end of the minus (-) strand, a feature also present in the replicative forms (RFs) of several animal alphaviruses. The unpaired G present in the CMV-related ds RNAs suggests that these molecules represent RFs and that viral and satellite RNAs share common replicative machinery. The 3' terminus of the (-) strand of ds RNA 4 is heterogeneous, with and without the added G. The existence of these two ds RNA 4 molecules suggests that replication of the subgenomic RNA 4 proceeds through a mechanism different from that of the genomic RNAs. The plus (+) strands of the ds forms of RNAs 3 and 4 and CARNA 5 are uncapped at the 5' termini and all end with a 3'-terminal cytosine (C. The 3'-terminal adenosine (A) present on most single-stranded (ss), encapsidated, CMV RNAs 3 and 4 is therefore added post-transcriptionally, and a possible control function for such a 3' terminus is discussed. The lack of an added 3'-terminal A on ss, encapsidated, CARNA 5 could result in its high replicative efficiency through escape from such a control.

The p23 protein of citrus tristeza virus controls asymmetrical RNA accumulation

Citrus tristeza virus (CTV), a member of the Closteroviridae, has a 19.3-kb positive-stranded RNA genome that is organized into 12 open reading frames (ORFs) with the 10 3' genes expressed via a nested set of nine or ten 3'-coterminal subgenomic mRNAs (sgRNAs). Relatively large amounts of negative-stranded RNAs complementary to both genomic and sgRNAs accumulate in infected cells. As is characteristic of RNA viruses, wild-type CTV produced more positive than negative strands, with the plus-to-minus ratios of genomic and sgRNAs estimated at 10 to 20:1 and 40 to 50:1, respectively. However, a mutant with all of the 3' genes deleted replicated efficiently, but produced plus to minus strands at a markedly decreased ratio of 1 to 2:1. Deletion analysis of 3'-end genes revealed that the p23 ORF was involved in asymmetric RNA accumulation. A mutation which caused a frameshift after the fifth codon resulted in nearly symmetrical RNA accumulation, suggesting that the p23 protein, not a cis-acting element within the p23 ORF, controls asymmetric accumulation of CTV RNAs. Further in-frame deletion mutations in the p23 ORF suggested that amino acid residues 46 to 180, which contained RNA-binding and zinc finger domains, were indispensable for asymmetrical RNA accumulation, while the N-terminal 5 to 45 and C-terminal 181 to 209 amino acid residues were not absolutely required. Mutation of conserved cysteine residues to alanines in the zinc finger domain resulted in loss of activity of the p23 protein, suggesting involvement of the zinc finger in asymmetric RNA accumulation. The absence of p23 gene function was manifested by substantial increases in accumulation of negative-stranded RNAs and only modest decreases in positive-stranded RNAs. Moreover, the substantial decrease in the accumulation of negative-stranded coat protein (CP) sgRNA in the presence of the functional p23 gene resulted in a 12- to 15-fold increase in the expression of the CP gene. Apparently the excess negative-stranded sgRNA reduces the availability of the corresponding positive-stranded sgRNA as a messenger. Thus, the p23 protein controls asymmetric accumulation of CTV RNAs by downregulating negative-stranded RNA accumulation and indirectly increases expression of 3' genes.

Phylogenetic analysis of some large double-stranded RNA replicons from plants suggests they evolved from a defective single-stranded RNA virus

Sequences were recently obtained from four double-stranded (ds) RNAs from different plant species. These dsRNAs are not associated with particles and as they appeared not to be horizontally transmitted, they were thought to be a kind of RNA plasmid. Here we report that the RNA-dependent RNA polymerase (RdRp) and helicase domains encoded by these dsRNAs are related to those of viruses of the alpha-like virus supergroup. Recent work on the RdRp sequences of alpha-like viruses raised doubts about their relatedness, but our analyses confirm that almost all the viruses previously assigned to the supergroup are related. Alpha-like viruses have single-stranded (ss) RNA genomes and produce particles, and they are much more diverse than the dsRNAs. This difference in diversity suggests the ssRNA alpha-like virus form is older, and we speculate that the transformation to a dsRNA form began when an ancestral ssRNA virus lost its virion protein gene. The phylogeny of the dsRNAs indicates this transformation was not recent and features of the dsRNA genome structure and translation strategy suggest it is now irreversible. Our analyses also show some dsRNAs from distantly related plants are closely related, indicating they have not strictly co-speciated with their hosts. In view of the affinities of the dsRNAs, we believe they should be classified as viruses and we suggest they be recognized as members of a new virus genus (Endornavirus) and family (Endoviridae).

Accumulation of alfalfa mosaic virus RNAs 1 and 2 requires the encoded proteins in cis

RNAs 1 and 2 of the tripartite genome of alfalfa mosaic virus (A1MV) encode the replicase proteins P1 and P2, respectively. P1 expressed in transgenic plants (P1 plants) can be used in trans to support replication of A1MV RNAs 2 and 3, and P2 expressed in transgenic plants (P2 plants) can be used in trans to support replication of A1MV RNAs 1 and 3. Wild-type RNA 1 was able to coreplicate with RNAs 2 and 3 in P1 plants, but this ability was abolished by frameshifts or deletions in the P1 gene of RNA 1. Similarly, wild-type RNA 2 coreplicated with RNAs 1 and 3 in P2 plants, but frameshifts or deletions in the P2 gene of RNA 2 interfered with this replication. Apparently, the P1 and P2 genes are required in cis for the accumulation of RNAs 1 and 2, respectively. Point mutations in the GDD motif of the P2 gene in RNA 2 interfered with accumulation of RNA 2 in P2 plants, indicating that replication of RNA 2 is linked to its translation into a functional protein. Plants transformed with both the P1 and P2 genes (P12 plants) accumulate replicase activity that is able to replicate RNA 3 in trans. An analysis of the time course of the accumulation of RNAs 1, 2, and 3 in protoplasts of P12 plants supported the conclusion that translation and replication are tightly coupled for A1MV RNAs 1 and 2 but not for RNA 3.

Structural elements of the 3'-terminal coat protein binding site in alfalfa mosaic virus RNAs

The 3'-terminal of the three genomic RNAs of alfalfa mosaic virus (AIMV) and ilarviruses contain a number of AUGC-motifs separated by hairpin structures. Binding of coat protein (CP) to such elements in the RNAs is required to initiate infection of these viruses. Determinants for CP binding in the 3'-terminal 39 nucleotides (nt) of AIMV RNA 3 were analyzed by band-shift assays. From the 5'- to 3'-end this 39 nt sequence contains AUGC-motif 3, stem-loop structure 2 (STLP2), AUGC-motif 2, stem-loop structure 1 (STLP1) and AUGC-motif 1. A mutational analysis showed that all three AUGC-motifs were involved in CP binding. Mutation of the A- and U-residues of motifs 1 or 3 had no effect on CP binding but similar mutations in motif 2 abolished CP binding. A mutational analysis of the stem of STLP1 and STLP2 confirmed the importance of these hairpins for CP binding. Randomization of the sequence of the stems and loops of STLP1 and STLP2 had no effect on CP binding as long as the secondary structure was maintained. This indicates that the two hairpins are not involved in sequence-specific interactions with CP. They may function in a secondary structure-specific interaction with CP and/or in the assembly of the AUGC-motifs in a configuration required for CP binding.

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.

The coat protein of white clover mosaic potexvirus has a role in facilitating cell-to-cell transport in plants

Functions of the coat protein of white clover mosaic potexvirus (WCIMV) were investigated using C-terminal deletion mutants. Whereas plants inoculated with RNA transcripts of a full-length wild-type clone of WCIMV produced typical infections, plants inoculated with transcripts of each mutant did not produce symptoms, and viral RNA species were not detected by Northern analysis. The mutants were able to replicate in protoplasts, although, relative to the wild-type RNA profile, the level of genomic RNA, but not subgenomic RNA, was reduced. These results indicate a role for the coat protein in efficient cell-to-cell transport in plants. Virus-like particles were detected in protoplast extracts inoculated with transcripts of a mutant in which the coat protein was truncated by 31 amino acids. This result suggests that the lack of detectable transport in plants was not due solely to a failure of the mutants to form virus particles. Possible roles for the coat protein in transport and replication are discussed. A 6-kDa open reading frame, internal to the coat protein gene, was shown by mutational analysis not to be essential for replication or transport.

Role of alfalfa mosaic virus coat protein in regulation of the balance between viral plus and minus strand RNA synthesis

Replication of wild type RNA 3 of alfalfa mosaic virus (AIMV) and mutants with frameshifts in the P3 or coat protein (CP) genes was studied in protoplasts from tobacco plants transformed with DNA copies of AIMV RNAs 1 and 2. Accumulation of viral plus and minus strand RNAs was monitored with strand-specific probes. A frameshift in the P3 gene did not change the asymmetry in plus/minus strand accumulation observed for the wild type. A frameshift early in the CP gene resulted in a 100-fold reduction in plus strand accumulation and a 3- to 10-fold increase in minus strand accumulation. A frameshift late in the CP gene caused a similar reduction in plus strand accumulation but had no effect on minus strand accumulation. This latter mutant accumulated nearly wild type levels of a truncated CP molecule. Apparently, wild type AIMV CP up-regulates plus strand accumulation and down-regulates minus strand accumulation and these two functions can be mutated separately.

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.

Replication of potato virus X RNA is altered in coinfections with potato virus Y

Potato virus X (PVX) and potato virus Y (PVY) may coinfect tobacco to cause a classic synergistic disease. In the acute stage the disease is characterized by a dramatic increase in the accumulation of infectious PVX particles, with no corresponding increase or decrease in the accumulation of PVY. The accumulation of PVX genomic RNA and coat protein has been examined in doubly versus singly infected tobacco leaves. These experiments indicate that the levels of both viral components increase in doubly infected plants to about the same extent as the level of infectious PVX particles. The level of PVX subgenomic coat protein mRNA found associated with polyribosomes of synergistically infected plants is also increased to a similar extent. Pulse labelling experiments suggest that the increase in PVX coat protein is due to an increased rate of synthesis. The level of PVX (-) strand RNA template increases disproportionately in doubly infected tissue, to a level three times higher than that of the virion or its component parts. This result suggests that PVX/PVY synergism involves an alteration in the normal regulation of the relative levels of PVX (+) and (-) strand RNAs during viral replication.

Regulation of (+):(-)-strand asymmetry in replication of brome mosaic virus RNA

Transfection of barley protoplasts with brome mosaic virus (BMV) RNAs 1 + 2 in the absence of RNA-3 yielded a molar ratio for (+):(-)-strand progeny at 24 hr postinoculation near unity, whereas over 100-fold more (+)- than (-)-strand progeny accumulated in its presence. The presence of RNA-3 enhanced total (+)-strand RNA production 205-fold and that of RNAs 1 + 2 by 29-fold. In contrast, total (-)-strand RNA accumulation decreased by 68% and that for (-)RNAs 1 + 2 by 79% in the presence of RNA-3. Transfections containing an RNA-3 mutant (Gsgi----U RNA-3) that is incapable of yielding RNA-4 as a result of a single nucleotide substitution at the subgenomic RNA initiation site yielded only 66% of the (+):(-) asymmetry seen in the presence of wild-type RNA-3. Only 1.8-fold excess of (+)-over (-)-strand production was obtained for transfections that included delta SGP RNA-3, a deletion that includes the subgenomic promoter core and extends 43 nt into the RNA-4 sequence. Transfections containing RNA-3 mutants bearing frameshifts or deletions in the coat protein cistron yielded levels of asymmetry similar to those seen for Gsgi----U RNA-3. These findings implicate the subgenomic promoter and other sequences in the intercistronic region of RNA-3 as the primary determinants of asymmetric replication, although the coat protein may be an additional factor enhancing the accumulation of (+)-strand RNA.

Analysis of the protein composition of alfalfa mosaic virus RNA-dependent RNA polymerase

RNA-dependent RNA polymerase (RdRp) was solubilized and purified from cellular membranes isolated from alfalfa mosaic virus (AIMV)-infected tobacco by employing a procedure recently described for brome mosaic virus RdRp [R. Quadt and E.M.J. Jaspars, 1990, Virology 178, 189-194]. The purified AIMV RdRp is completely dependent on added template RNAs and exhibits a high degree of template specificity. Analysis of the protein composition of AIMV RdRp showed that AIMV-encoded proteins P1 and P2 and the coat protein (CP) are present in the active enzyme complex. Minus-strand synthesis by the AIMV RdRp is inhibited by AIMV CP. Native double-stranded AIMV RNAs are utilized as template for viral RNA synthesis by AIMV RdRp indicating that a helicase activity is present in the purified AIMV RdRp preparation.

Replication of an incomplete alfalfa mosaic virus genome in plants transformed with viral replicase genes

RNAs 1 and 2 of alfalfa mosaic virus (AIMV) encode proteins P1 and P2, respectively, both of which have a putative role in viral RNA replication. Tobacco plants were transformed with DNA copies of RNA1 (P1-plants), RNA2 (P2-plants) or a combination of these two cDNAs (P12-plants). All transgenic plants were susceptible to infection with the complete AIMV genome (RNAs 1, 2, and 3). Inoculation with incomplete mixtures of AIMV RNAs showed that the P1-plants were able to replicate RNAs 2 and 3, that the P2-plants were able to replicate RNAs 1 and 3, and that the P12-plants were able to replicate RNA3. Initiation of infection of nontransgenic plants, P1-plants, or P2-plants requires the presence of AIMV coat protein in the inoculum, but no coat protein was required to initiate infection of P12-plants with RNA3. Results obtained with P12-protoplasts supported the conclusion that coat protein plays an essential role in the replication cycle of AIMV RNAs 1 and 2.

Role of alfalfa mosaic virus coat protein gene in symptom formation

On Samsun NN tobacco plants strains 425 and YSMV of alfalfa mosaic virus (AIMV) cause mild chlorosis and local necrotic lesions, respectively. DNA copies of RNA3 of both strains were transcribed in vitro into infectious RNA molecules. When the 425 and YSMV transcripts were inoculated to tobacco plants transformed with DNA copies of AIMV RNAs 1 and 2, they induced symptoms indistinguishable from those of the corresponding parent strains. Exchange of restriction fragments between the infectious clones showed that symptom expression was determined by the coat protein gene in RNA3. The sequence of YSMV RNA3 was determined and compared with the known sequence of 425 RNA3. When the codon for Gln-29 in the coat protein of strain 425 was mutated into the Arg codon present at this position in strain YSMV, the symptoms induced by the transcript on inoculated leaves changed from chlorosis to necrosis. Genetic determinants for the systemic response were more complex.

Construction of full-length cDNA clones of cucumber mosaic virus RNAs 1, 2 and 3: generation of infectious RNA transcripts

Full-length cDNA copies of cucumber mosaic virus (CMV) RNAs 1 and 2 of the Fny strain were constructed from partial cDNA clones and were cloned downstream of bacteriophage T7 promoters. In one pair of clones, transcription proceeded from an unaltered T7 promoter such that in vitro transcripts representing RNAs 1 and 2 contained an additional 17 nucleotides at their 5' termini. In a second pair of clones, the T7 promoter/cDNA junction was altered by oligonucleotide-directed mutagenesis such that the in vitro transcripts contained only an additional G residue at their 5' ends. In addition, a full-length cDNA copy of Fny-CMV RNA 3 was constructed from two overlapping cDNA clones and was cloned downstream of an altered T7 promoter such that the resultant in vitro transcripts also contained only an additional G residue at their 5' ends. In vitro transcripts derived from all clones contained an additional C residue at their 3' ends. In vitro transcripts representing RNAs 1, 2 and 3 which contained an additional residue at each terminus were shown to be infectious together in several hosts of CMV.

cis-acting elements involved in replication of alfalfa mosaic virus RNAs in vitro

A DNA copy of alfalfa mosaic virus (AIMV) RNA3 was transcribed in vitro in two different orientations with T7 RNA polymerase and the transcripts were used as templates for a virus-specific RNA-dependent RNA polymerase (RdRp) purified from AIMV-infected bean plants. Minus-stranded templates were transcribed by the RdRp into subgenomic plus-stranded RNA4. A deletion analysis showed that a sequence in minus-strand RNA3, located between nucleotides -8 and -55 upstream of the initiation site for RNA4 synthesis, was sufficient for subgenomic promoter activity in vitro. Plus-stranded templates were transcribed by the RdRp into full-length minus-stranded copies. A deletion analysis indicated that a sequence located between nucleotides 133 and 163 from the 3'-end of AIMV RNA3 was sufficient to direct the synthesis of minus-stranded products by the RdRp. Thus, the 3'-terminal region of the AIMV RNAs, which contains the binding sites with a high affinity for coat protein, appears not to be involved in recognition of the RNAs by the RdRp in vitro.

Cloning and sequencing of RNA-1 cDNA from cucumber mosaic virus strain O

The complete nucleotide (nt) sequence (3369 nt) of RNA 1 of cucumber mosaic virus strain O (CMV-O) was determined. One open reading frame (ORF; 993 aa) could be deduced from the nt sequence. The homologies of the ORF between CMV-O and CMV-Q or CMV-Fny were calculated to be 85% or 97%, respectively. For CMV-O and CMV-Q, the first one-third of the ORF showed a higher degree of homology (89%), as compared with the other portions (82-85%); the first 224 aa showed more than 93% homology. A comparative study of the three viruses revealed that CMV-O is more homologous to CMV-Fny (subgroup I) [corrected]) than to CMV-Q (subgroup II) [corrected].

Defined mutations in a small region of the brome mosaic virus 2 gene cause diverse temperature-sensitive RNA replication phenotypes

The central portion of the brome mosaic virus (BMV) 2a protein represents the most conserved element among the related RNA replication components of a large group of positive-strand RNA viruses of humans, animals, and plants. To characterize the functions of the 2a protein, mutations were targeted to a conserved portion of the 2a gene, resulting in substitutions between amino acids 451 and 484. After the temperature profile of wild-type BMV RNA replication was defined, RNA replication by nine selected mutants was tested in barley protoplasts at permissive (24 degrees C) and nonpermissive (34 degrees C) temperatures. Four mutants did not direct RNA synthesis at either temperature. Various levels of temperature-sensitive (ts) replication occurred in the remaining five mutants. For two ts mutants, no viral RNA synthesis was detected at 34 degrees C, while for two others, an equivalent reduction in positive- and negative-strand RNA accumulation was observed. For one mutant, positive-strand accumulation was preferentially reduced over negative-strand accumulation at 34 degrees C. Moreover, this mutant and another displayed preferential suppression of genomic over subgenomic RNA accumulation at both 24 and 34 degrees C. The combination of phenotypes observed suggests that the 2a protein may play a role in the differential initiation of specific classes of viral RNA in addition to a previously suggested role in RNA elongation.

Mechanism of synthesis of turnip yellow mosaic virus coat protein subgenomic RNA in vivo

Turnip yellow mosaic virus (TYMV) possesses a monopartite single-stranded (+) sense RNA genome in which the coat protein (cp) gene is 3' proximal and is expressed in vivo via a subgenomic RNA. Evidence is presented here that this subgenomic RNA is synthesized in vivo by internal initiation of replication on (-) RNA strands of genomic length. The double-stranded RNAs (dsRNAs) from TYMV-infected plants have been isolated, purified, and characterized. Under native conditions, no dsRNAs (replicative intermediates and/or replicative forms) of subgenomic length corresponding to subgenomic cp RNA can be detected by ethidium bromide staining of RNA-sizing gels or by Northern blot hybridization using RNA probes. The presence of nascent subgenomic cp (+) RNA strands on the dsRNA of genomic length has been demonstrated using two different approaches: (1) Northern blot hybridization using (-) RNA probes under denaturing conditions and (2) characterization of the 5' ends of nascent (+) RNA strands upon labeling by vaccinia virus nucleoside-2'-methyltransferase.

Characterization of cucumber mosaic virus. I. Molecular heterogeneity mapping of RNA 3 in eight CMV strains

RNAs from 13 strains of cucumber mosaic virus (CMV) were divided into two groups on the basis of their ability to hybridize to cDNA of either Fny-CMV RNA or WL-CMV RNA. The extent of the cross-hybridization within one of these groups was analyzed by an RNA protection assay. A cDNA clone of RNA 3 of the Fny strain of CMV was placed in a transcription vector between bacterial promoters T3 and T7. Labeled, minus-sense RNA transcripts prepared from all or part of the cDNA to RNA 3 of Fny-CMV were annealed to the genomic RNA of each of a number of cucumoviruses and digested with RNases. The patterns of RNA fragments protected from digestion were specific for each CMV strain and revealed the extent and location of heterogeneity among the viruses as well as within the Fny-CMV natural population. This approach will allow the differences in host range and disease processes to be correlated with variations in genomic RNAs.

Transgenic tobacco expressing tobacco streak virus or mutated alfalfa mosaic virus coat protein does not cross-protect against alfalfa mosaic virus infection

Transgenic tobacco plants expressing the coat protein (CP) genes of tobacco streak virus (TSV) and alfalfa mosaic virus (AIMV) were used in studies on cross-protection and genome activation. Plants expressing the TSV CP gene were highly resistant to infection with TSV nucleoproteins but were susceptible to infection with AIMV nucleoproteins. Moreover, these plants could be infected with a mixture of AIMV RNAs 1, 2, and 3 in contrast to the nontransformed control plants. This demonstrates that the endogenously produced TSV CP is able to activate the AIMV genome but does not cross-protect against this virus. Conversely, it was shown that plants expressing the AIMV CP gene did not resist TSV infection. Transgenic tobacco plants transformed with an AIMV CP gene with a frame-shift mutation in the reading frame were found to accumulate viral transcripts to a level similar to that obtained in plants expressing a wild-type AIMV CP gene. However, these plants did not produce detectable amounts of viral protein and showed no resistance to infection with AIMV nucleoproteins in contrast to transgenic plants accumulating wild-type AIMV CP. This demonstrates that it is the CP that is responsible for cross-protection in transgenic plants and not the chimeric CP mRNA.

Nucleotide sequence and genetic organization of barley stripe mosaic virus RNA gamma

The complete nucleotide sequences of RNA gamma from the Type and ND18 strains of barley stripe mosaic virus (BSMV) have been determined. The sequences are 3164 (Type) and 2791 (ND18) nucleotides in length. Both sequences contain a 5'-noncoding region (87 or 88 nucleotides) which is followed by a long open reading frame (ORF1). A 42-nucleotide intercistronic region separates ORF1 from a second, shorter open reading frame (ORF2) located near the 3'-end of the RNA. There is a high degree of homology between the Type and ND18 strains in the nucleotide sequence of ORF1. However, the Type strain contains a 366 nucleotide direct tandem repeat within ORF1 which is absent in the ND18 strain. Consequently, the predicted translation product of Type RNA gamma ORF1 (mol wt 87,312) is significantly larger than that of ND18 RNA gamma ORF1 (mol wt 74,011). The amino acid sequence of the ORF1 polypeptide contains homologies with putative RNA polymerases from other RNA viruses, suggesting that this protein may function in replication of the BSMV genome. The nucleotide sequence of RNA gamma ORF2 is nearly identical in the Type and ND18 strains. ORF2 codes for a polypeptide with a predicted molecular weight of 17,209 (Type) or 17,074 (ND18) which is known to be translated from a subgenomic (sg) RNA. The initiation point of this sgRNA has been mapped to a location 27 nucleotides upstream of the ORF2 initiation codon in the intercistronic region between ORF1 and ORF2. The sgRNA is not coterminal with the 3'-end of the genomic RNA, but instead contains heterogeneous poly(A) termini up to 150 nucleotides long (J. Stanley, R. Hanau, and A. O. Jackson, 1984, Virology 139, 375-383). In the genomic RNA gamma, ORF2 is followed by a short poly(A) tract and a 238-nucleotide tRNA-like structure.

Biologically active transcripts of cloned DNA of the coat protein messenger of two plant viruses

To initiate infection, a mixture of the three genomic RNAs of alfalfa mosaic virus (AIMV) has to be supplemented with a small amount of coat protein or RNA 4, the subgenomic messenger for coat protein. The possibility to replace RNA 4 in the inoculum by in vitro synthesized transcripts of a cloned DNA copy of the coat protein cistron was investigated using the SP6 transcription system. Transcripts with or without the cap structure m(7)G(5')ppp(5')G were both translated in vitro in viral coat protein, but only capped transcripts yielded an infectious mixture when added to the AIMV genomic RNAs. This indicates that the cap structure is essential to the in vivo translatin of RNA 4. Similar results were obtained with RNAs transcribed in vitro from a DNA copy of the putative coat protein cistron of tobacco streak virus (TSV). re]19850822 rv]19851203 ac]19860114.

Plant-virus-based vectors for gene transfer will be of limited use because of the high error frequency during viral RNA synthesis

The error frequency during the RNA replication of alfalfa mosaic virus (AMV) was calculated to be significantly higher than 10(-5). It may be expected that RNA synthesis in general will have low fidelity compared to DNA synthesis. The low fidelity of RNA replication will severely restrict the usefulness of vectors for genetic engineering which are based on RNA viruses, viroids or DNA viruses which are replicated via an RNA intermediate (e.g. caulimoviruses). Spontaneous mutants selected by host shift were found to be much less stable than UV-induced mutants. This difference points to variations in fidelity during RNA synthesis, probably due to the local sequence of the template.

Synthesis of brome mosaic virus subgenomic RNA in vitro by internal initiation on (-)-sense genomic RNA

The genomes of many (+)-stranded RNA viruses, including plant viruses and alphaviruses, consist of polycistronic RNAs whose internal genes are expressed via subgenomic messenger RNAs. The mechanism(s) by which these subgenomic mRNAs arise are poorly understood. Based on indirect evidence, three models have been proposed: (1) internal initiation by the replicase on the (-)-strand of genomic RNA, (2) premature termination during (-)-strand synthesis, followed by independent replication of the subgenomic RNA and (3) processing by nuclease cleavage of genome-length RNA. Using an RNA-dependent RNA polymerase (replicase) preparation from barley leaves infected with brome mosaic virus (BMV) to synthesize the viral subgenomic RNA in vitro, we now provide evidence that subgenomic RNA arises by internal initiation on the (-)-strand of genomic RNA. We believe that this also represents the first in vitro demonstration of a replicase from a eukaryotic (+)-stranded RNA virus capable of initiating synthesis of (+)-sense RNA.

Homology between the proteins encoded by tobacco mosaic virus and two tricornaviruses

A comparison was made of the amino acid sequences of the proteins encoded by RNAs 1 and 2 of alfalfa mosaic virus (A1MV) and brome mosaic virus (BMV), and the 126K and 183K proteins encoded by tobacco mosaic virus (TMV). Three blocks of extensive homology of about 200 to 350 amino acids each were observed. Two of these blocks are located in the A1MV and BMV RNA 1 encoded proteins and the TMV encoded 126K protein; they are situated at the N-terminus and C-terminus, respectively. The third block is located in the A1MV and BMV RNA 2 encoded proteins and the C-terminal part of the TMV encoded 183K protein. These homologies are discussed with respect to the functional equivalence of these putative replicase proteins and a possible evolutionary connection between A1MV, BMV and TMV.

Complete nucleotide sequence of RNA 3 from alfalfa mosaic virus, strain S

We report the sequence of RNA 3 from strain S of Alfalfa mosaic virus (2,055 nucleotides). This RNA codes for a 32.4 kd protein (P3) and for the 24 kd coat protein (P4). The largest part of the sequence was established using RNA sequencing methods. The completion of the sequence in the region coding for P3 was achieved with cloned cDNA synthesized after priming at internal sites of RNA 3. Comparison of the RNA sequences coding P3 and P4 proteins in strain S with those reported in the literature for strain 425 revealed a higher amino acid substitution rate (3%) for P3 than for P4 (congruent to 1%) despite a similar average base substitution of 3-4% in these regions. In P3, two out of nine amino acid changes occur in hydrophilic regions. The amino acid changes in P4 do not modify the local hydrophilicity distribution. The intercistronic region displays a low degree of base substitution (2%) when compared with the untranslated 3'-end region (3.6%) or the 5'-end leader region (8%), the average substitution rate being 3.2%.

Competition between the RNA 3 molecules of wildtype alfalfa mosaic virus and the temperature-sensitive mutant Tbts 7(uv)

In mixed infections of wildtype (wt) alfalfa mosaic virus (AMV) and a temperature-sensitive mutant Tbts 7(uv), which carries a thermosensitive defect in the early function of the coat protein, the mutant symptoms were not found at 30°C. In the progeny from these mixed infections almost no mutant coat protein and no mutant RNA 3 could be detected. Even at 23°C there was some loss of mutant RNA 3 and coat protein from the progeny of the mixed infections. Analysis and comparison of mutant and wt ds RNA preparations revealed a lower ds RNA 3 content for the mutant preparation at 23°C. Also the amount of RNA 3 in virion preparations was lower for the mutant than for wt. These results point to a mutation in the RNA 3 of Tbts 7(uv) which diminishes its affinity for the viral replicase.

Inhibition of alfalfa mosaic virus RNA and protein synthesis by actinomycin D and cycloheximide

Actinomycin D, added early after inoculation, reduces the production of infectious alfalfa mosaic virus in cowpea protoplasts by 90%. This reduction was associated with an inhibition of viral minus-strand and plus-strand RNA synthesis, suggesting the involvement of host factors in these processes. Coat protein production was less affected by the drug. Addition of cycloheximide throughout the growth cycle resulted in an immediate cessation of coat protein production and an enhanced degradation of viral RNA. This degradation obscured possible effects of the drug on viral RNA synthesis.