The complete nucleotide sequence of apple mosaic virus (ApMV) RNA 1 and RNA 2: ApMV is more closely related to alfalfa mosaic virus than to other ilarviruses

The complete nucleotide sequences of apple mosaic virus RNA 1 and 2 have been characterized. Apple mosaic virus RNA 1 is 3476 nucleotides in length and encodes a single large open reading frame (ORF), whereas apple mosaic virus RNA 2 is 2979 nucleotides in length and also encodes a single ORF. The amino acid sequences encoded by RNA 1 and 2 show similarity to all of the other ilarviruses for which sequence data are available, but both are more closely related to alfalfa mosaic virus (AMV) than to other ilarviruses. Points of similarity include the absence of ORF 2b, present on the RNA 2 of all previously characterized ilarviruses. The close relationship to AMV also occurs in the movement protein, encoded by RNA 3, but not with the coat protein. These data suggest that the present taxonomy should be revised, and that AMV should be considered an aphid-transmissible ilarvirus.

Activation of the alfalfa mosaic virus genome by viral coat protein in non-transgenic plants and protoplasts. The protection model biochemically tested

In non-transgenic host plants and protoplasts alfalfa mosaic virus displays a strong need for coat protein when starting an infection cycle. The "protection model" states that the three viral RNAs must have a few coat protein subunits at their 3' termini in order to protect them in the host cell against degradation by 3'- to- 5' exoribonucleases [Neeleman L, Van der Vossen EAG, Bol JF (1993) Virology 196: 883-887]. We demonstrated that the naked genome RNAs are slightly infectious, if the inoculation is done at very high concentrations, or if it is preceded by an additional inoculation with the RNAs 1 and 2 (encoding subunits for the viral RNA polymerase). This could mean that the necessity for protection by coat protein is lost if the RNAs in large quantities can overcome the activity of the degrading enzymes, or are protected by association with the RNA polymerase, respectively. However, after having tested in protoplasts the survival of separately preinoculated naked RNA 1 during several hours before RNA 2 was inoculated, on the one hand, or of simultaneously inoculated RNAs 1 and 2, with cycloheximide in the medium during the first hours after inoculation, on the other hand, we had to conclude that the viral genome RNAs are quite stable in the cell in the absence of coat protein or RNA polymerase, respectively. This invalidates the protection model. Accommodation of the above findings by our published "messenger release model" for genome activation [Houwing CJ, Jaspars EMJ (1993) Biochimie 75: 617-621] is discussed.

A conformational switch at the 3' end of a plant virus RNA regulates viral replication

3' untranslated regions of alfamo- and ilar-virus RNAs fold into a series of stem-loop structures to which the coat protein binds with high affinity. This binding plays a role in initiation of infection ('genome activation') and has been thought to substitute for a tRNA-like structure that is found at the 3' termini of related plant viruses. We propose the existence of an alternative conformation of the 3' ends of alfamo- and ilar-virus RNAs, including a pseudoknot. Based on (i) phylogenetic comparisons, (ii) in vivo and in vitro functional analyses of mutants in which the pseudoknot has been disrupted or restored by compensatory mutations, (iii) competition experiments between coat protein and viral replicase, and (iv) investigation of the effect of magnesium, we demonstrate that this pseudoknot is required for replication of alfalfa mosaic virus. This conformation resembles the tRNA-like structure of the related bromo- and cucumo-viruses. A low but specific interaction with yeast CCA-adding enzyme was found. The existence of two mutually exclusive conformations for the 3' termini of alfamo- and ilar-virus RNAs could enable the virus to switch from translation to replication and vice versa. The role of coat protein in this modulation and in genome activation is discussed.

Alfalfa mosaic virus RNAs serve as cap donors for tomato spotted wilt virus transcription during coinfection of Nicotiana benthamiana

Tomato spotted wilt virus (TSWV) was shown to use alfalfa mosaic virus (AMV) RNAs as cap donors in vivo during a mixed infection in Nicotiana benthamiana. By use of nested reverse transcription-PCR, TSWV N and NSs mRNAs provided with capped leader sequences derived from all four AMV RNAs could be cloned and sequenced. The sequence specificity of the putative TSWV endonuclease involved is discussed.

Expression of alfalfa mosaic virus coat protein in tobacco mosaic virus (TMV) deficient in the production of its native coat protein supports long-distance movement of a chimeric TMV

Alfalfa mosaic virus (AlMV) coat protein is involved in systemic infection of host plants, and a specific mutation in this gene prevents the virus from moving into the upper uninoculated leaves. The coat protein also is required for different viral functions during early and late infection. To study the role of the coat protein in long-distance movement of AlMV independent of other vital functions during virus infection, we cloned the gene encoding the coat protein of AlMV into a tobacco mosaic virus (TMV)-based vector Av. This vector is deficient in long-distance movement and is limited to locally inoculated leaves because of the lack of native TMV coat protein. Expression of AlMV coat protein, directed by the subgenomic promoter of TMV coat protein in Av, supported systemic infection with the chimeric virus in Nicotiana benthamiana, Nicotiana tabacum MD609, and Spinacia oleracea. The host range of TMV was extended to include spinach as a permissive host. Here we report the alteration of a host range by incorporating genetic determinants from another virus.

Amino acids of alfalfa mosaic virus coat protein that direct formation of unusually long virus particles

In contrast to most alfalfa mosaic virus (AMV) strains (YSMV, S, M and 425), AMV strains VRU and 1 5/64 can form abnormally long virus particles, an ability which has been linked to the coat protein (CP). In order to study this phenomenon, the CP-encoding RNAs 3 of AMV strains VRU and 1 5/64 were cloned and fully sequenced. Comparative sequence analyses of AMV RNA 3 sequences derived from different strains revealed two non-conservative amino acid substitutions, Ser65 and Leu175, which occur exclusively in the closely related VRU- and 15/64-CPs. When these amino acid alterations were introduced into the CP of AMV strain 425 unusually long virus particles were assembled. This confirms that amino acids Ser66 and Leu175 of the CPs of AMV strains VRU and 15/64 are involved in the formation of tubular virus particles.

The sequence of RNA 1 and RNA 2 of tobacco streak virus: additional evidence for the inclusion of alfalfa mosaic virus in the genus Ilarvirus

Here we describe the complete sequence of RNA 1 and 2 of the WC isolate of tobacco streak virus (TSV). These two sequences complete the information on the genome of TSV, the type member of the genus Ilarvirus, and are the first sequences described for the RNA 1 and RNA 2 of a member of subgroup 1 of this genus. The sequences have a similar organization to those reported for the corresponding RNAs of other ilarviruses. However, the putative translation products of these two molecules differ sufficiently from previously sequenced ilarviruses so that TSV should remain in a subgroup on its own. Phylogenetic comparison of sequence data for RNA 1 with that of other ilarviruses and alfalfa mosaic virus (AMV) reveals two distinct clusters (TSV, CiLRV, and SpLV) and (AMV, PDV, and ApMV). These data support the suggestion [16] based on data for RNA 3 of ilarviruses that AMV should be included as a true ilarvirus.

The complete nucleotide sequence of prune dwarf ilarvirus RNA-1

The sequence of prune dwarf ilarvirus (PDV) RNA-1 has been determined; it consists of 3,374 nucleotides and contains a single open reading frame of 3,168 nucleotides. The putative translation product is 1,055 amino acids in length with a calculated molecular mass of 118.9 kDa. Both the nucleic acid and the translated amino acid sequences show stronger homology to the corresponding RNA-1 and ORF-1 of apple mosaic ilarvirus and alfalfa mosaic alfamovirus than to spinach latent mosaic ilarvirus or citrus leaf rugose ilarvirus. These findings are consistent with the inclusion of alfalfa mosaic virus in the ilarvirus genus. The reported sequence of PDV RNA-1 and its single ORF conform to the genomic organization typical of the Bromoviridae family.

Regulation of single-strand RNA synthesis of alfalfa mosaic virus in non-transgenic cowpea protoplasts by the viral coat protein

We have compared the RNA synthesis of alfalfa mosaic virus in complete (by RNAs 1, 2 and 3) and incomplete infections (by RNAs 1 and 2) of cowpea protoplasts. Both viral RNA polymerase activity and accumulation of viral RNA were measured. By annealing RNA in solution with 32P-labelled probes of plus and minus polarity followed by treatment with ribonucleases, we determined viral RNAs quantitatively in both single- and double-stranded RNA fractions. The accumulation of single-stranded RNA of positive polarity differed considerably between the two types of infection (250 ng vs. less than 1 ng per 10(5) protoplasts), although viral RNA polymerase activities as measured in vitro and the concentrations of minus RNA were similar. Since the method also measured fragmented RNA, this difference is probably not due to lack of protection of viral RNA by coat protein during incomplete infection. Synthesis of single-stranded plus RNA requires either RNA 3 itself or one of its gene products. We postulate that coat protein is the stringent regulator of alfalfa mosaic virus genomic expression.

Expression of the catalytic subunit (UL54) and the accessory protein (UL44) of human cytomegalovirus DNA polymerase in a coupled in vitro transcription/translation system

The catalytic subunit (UL54) and accessory protein (UL44) of human cytomegalovirus (HCMV) DNA polymerase have been cloned and expressed in an in vitro-coupled transcription/translation reticulocyte lysate system. The influence of the 5'-untranslated region (5'-UTR) on the efficiency of expression from the circular plasmids has been investigated. For expression of both UL54 and UL44, a truncated form of the alfalfa mosaic virus (AMV) RNA4 5'-UTR was found to be superior to the full-length AMV 5'-UTR or the original HCMV 5'-UTRs of different lengths. Protein products with Mr approximately 140 and 55 kDa were detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis in the UL54 and UL44 in vitro expression reactions, respectively. The properties of the expressed enzyme were compared with those of native HCMV DNA polymerase purified from HCMV-infected cells. DNA polymerase and 3'-5' exonuclease activities of the expressed UL54/UL44 complex were found to be dependent on salt concentration in the same manner as the activities of the native enzyme. The in vitro-expressed enzyme resembles the purified HCMV DNA polymerase in its affinity for deoxynucleoside triphosphates as well as in its sensitivity to known inhibitors (cidofovir diphosphate, ganciclovir triphosphate, and foscarnet). This straightforward method for protein expression may also be applicable to other enzymes where reproducible generation of fully functional products is desirable.

Mutations in coat protein binding sites of alfalfa mosaic virus RNA 3 affect subgenomic RNA 4 accumulation and encapsidation of viral RNAs

The 3'-untranslated regions (3'-UTRs) of the three RNAs of alfalfa mosaic virus (AMV) contain a specific binding site for coat protein (CP) and act as a promoter for minus-strand RNA synthesis by the purified AMV RNA-dependent RNA polymerase (RdRp) in an in vitro assay. Binding of CP to the viral RNAs is required to initiate infection. The sequence of the 3'-terminal 39 nucleotides of AMV RNA 3 can be folded into two stem-loop structures flanked by three single-stranded AUGC sequences and represents a CP binding site. Mutations in this sequence that are known to interfere with CP binding in vitro were introduced into an infectious clone of RNA 3, and mutant RNA transcripts were used as templates in the in vitro RdRp assay and to infect protoplasts and plants. Mutation of AUGC motif 2 or disruption of the stem of the 3'-proximal hairpin 1 interfered with CP binding in vitro but not with minus-strand promoter activity in vitro or replication of RNA 3 in vivo. However, hairpin 1 appeared to be essential for encapsidation of RNA 3. Reversion of three G-C base pairs in hairpin 1 had no effect on CP binding but interfered with minus-strand promoter activity in vitro and with RNA 3 replication in vivo. It is concluded that the viral RdRp and CP recognize different elements in the 3'-UTRs of AMV RNAs. Moreover, several mutations that interfered with CP binding in vitro interfered with the accumulation in vivo of RNA 4, the subgenomic messenger for CP, but not with the accumulation of RNA 3.

The 3' untranslated region of alfalfa mosaic virus RNA3 contains a core promoter for minus-strand RNA synthesis and an enhancer element

The 3' untranslated regions (UTRs) of the three genomic RNAs of alfalfa mosaic virus consist of a 3' homologous sequence of 145 nt and upstream unique sequences 18-34 nt in length. Mutations were made in the 3' UTR of a cDNA clone of RNA3. Point mutations in five AUGC motifs which interfere with specific binding of coat protein to the 3' UTR had no effect on template activity of RNA3 for minus-strand RNA synthesis in vitro by purified viral RNA-dependent RNA polymerase (RdRp). Deletion analysis showed that the 3' homologous sequence of 145 nt was sufficient for a low level of template activity in the in vitro RdRp assay and a similarly low level of RNA3 accumulation in plants. The presence of an additional sequence of nucleotides 145-165 from the 3' end of RNA3 enhanced template recognition by RdRp in vitro and accumulation of RNA3 in vivo to wild-type levels.

Comparison of the role of 5' terminal sequences of alfalfa mosaic virus RNAs 1, 2, and 3 in viral RNA replication

The 5' untranslated regions (UTRs) of the genomic RNAs 1, 2, and 3 of alfalfa mosaic virus (AMV) are 100, 54, and 345 nucleotides (nt) long, respectively, and lack extensive sequence similarity to each other. RNA 3 encodes the movement protein P3 and the coat protein and can be replicated in transgenic tobacco plants expressing the replicase proteins P1 and P2 (P12 plants). 5' Cis-acting sequences involved in RNA 3 replication have been shown to be confined to the 5' UTR. When the 5' UTR of RNA 3 was replaced by the 5' UTRs of RNAs 1 or 2, the recombinant RNA was not infectious to P12 plants. Also, when the P3 gene in RNA 3 was put under the control of a subgenomic promoter and the 5' UTR of this RNA was replaced by 5' terminal RNA 1 sequences of 103 to 860 nt long or RNA 2 sequences of 57 to 612 nt long, no accumulation of the hybrid RNAs was observed. Deletion of the 5' 22 nucleotides of RNA 3 resulted in the accumulation of a major progeny that lacked the 5' 79 nt. However, when the 5' 22 nucleotides of RNA 3 were replaced by the complete 5' UTR of RNA 1 or 5' sequences of RNAs 1, 2, or 3 with a length of 5 to 15 nt, accumulation of the full-length mutant RNAs was observed. The effect of mutations in the 5' viral sequences of 5 to 15 nt was analyzed. It is concluded that although elements within nucleotides 80-345 of the 5' UTR of RNA 3 are sufficient for replication, a specific sequence of 3 to 5 nt is required to target the replicase to an initiation site corresponding to the 5' end of the RNA.

Functional equivalence of common and unique sequences in the 3' untranslated regions of alfalfa mosaic virus RNAs 1, 2, and 3

The 3' untranslated regions (UTRs) of alfalfa mosaic virus (AMV) RNAs 1, 2, and 3 consist of a common 3'-terminal sequence of 145 nucleotides (nt) and upstream sequences of 18 to 34 nt that are unique for each RNA. The common sequence can be folded into five stem-loop structures, A to E, despite the occurrence of 22 nt differences between the three RNAs in this region. Exchange of the common sequences or full-length UTRs between the three genomic RNAs did not affect the replication of these RNAs in vivo, indicating that the UTRs are functionally equivalent. Mutations that disturbed base pairing in the stem of hairpin E reduced or abolished RNA replication, whereas compensating mutations restored RNA replication. In vitro, the 3' UTRs of the three RNAs were recognized with similar efficiencies by the AMV RNA-dependent RNA polymerase (RdRp). A deletion analysis of template RNAs indicated that a 3'-terminal sequence of 127 nt in each of the three AMV RNAs was not sufficient for recognition by the RdRp. Previously, it has been shown that this 127-nt sequence is sufficient for coat protein binding. Apparently, sequences required for recognition of AMV RNAs by the RdRp are longer than sequences required for CP binding.

Identification of a competitive translation determinant in the 3' untranslated region of alfalfa mosaic virus coat protein mRNA

We report that the competitive translational activity of alfalfa mosaic virus coat protein mRNA (CP RNA), a nonadenylated mRNA, is determined in part by the 3' untranslated region (UTR). Competitive translation was characterized both in vitro, with cotranslation assays, and in vivo, with microinjected Xenopus laevis oocytes. In wheat germ extracts, coat protein synthesis was constant when a fixed amount of full-length CP RNA was cotranslated with increasing concentrations of competitor globin mRNA. However, translation of CP RNA lacking the 3' UTR decreased significantly under competitive conditions. RNA stabilities were equivalent. In X. laevis oocytes, which are translationally saturated and are an inherently competitive translational environment, full-length CP RNA assembled into large polysomes and coat protein synthesis was readily detectable. Alternatively, CP RNA lacking the 3' UTR sedimented as small polysomes, and little coat protein was detected. Again, RNA stabilities were equivalent. Site-directed mutagenesis was used to localize RNA sequences or structures required for competitive translation. Since the CP RNA 3' UTR has an unusually large number of AUG nucleotide triplets, two AUG-containing sites were altered in full-length RNA prior to oocyte injections. Nucleotide substitutions at the sequence GAUG, 20 nucleotides downstream of the coat protein termination codon, specifically reduced full-length CP RNA translation, while similar substitutions at the next AUG triplet had little effect on translation. The competitive influence of the 3' UTR could be explained by RNA-protein interactions that affect translation initiation or by ribosome reinitiation at downstream AUG codons, which would increase the number of ribosomes committed to coat protein synthesis.

In vitro genetic selection analysis of alfalfa mosaic virus coat protein binding to 3'-terminal AUGC repeats in the viral RNAs

The coat proteins of alfalfa mosaic virus (AMV) and the related ilarviruses bind specifically to the 3' untranslated regions of the viral RNAs, which contain conserved repeats of the tetranucleotide sequence AUGC. The purpose of this study was to develop a more detailed understanding of RNA sequence and/or structural determinants required for coat protein binding by characterizing the role of the AUGC repeats. Starting with a complex pool of 39-nucleotide RNA molecules containing random substitutions in the AUGC repeats, in vitro genetic selection was used to identify RNAs that bound coat protein. After six iterative rounds of selection, amplification, and reselection, 25% of the RNAs selected from the randomized pool were wild type; that is, they contained all four AUGC sequences. Among the 31 clones analyzed, AUGC was clearly the preferred selected sequence at the four repeats, but some nucleotide sequence variability was observed at AUGC(865-868) if the other three AUGC repeats were present. Variant RNAs that bound coat protein with affinities equal to or greater than that of the wild-type molecule were not selected. To extend the in vitro selection results, RNAs containing specific nucleotide substitutions were transcribed in vitro and tested in coat protein and peptide binding assays. The data strongly suggest that the AUGC repeats provide sequence-specific determinants and contribute to a structural platform for specific coat protein binding. Coat protein may function in maintaining the 3' ends of the genomic RNAs during replication by stabilizing an RNA structure that defines the 3' terminus as the initiation site for minus-strand synthesis.

A plant viral coat protein RNA binding consensus sequence contains a crucial arginine

A defining feature of alfalfa mosaic virus (AMV) and ilarviruses [type virus: tobacco streak virus (TSV)] is that, in addition to genomic RNAs, viral coat protein is required to establish infection in plants. AMV and TSV coat proteins, which share little primary amino acid sequence identity, are functionally interchangeable in RNA binding and initiation of infection. The lysine-rich amino-terminal RNA binding domain of the AMV coat protein lacks previously identified RNA binding motifs. Here, the AMV coat protein RNA binding domain is shown to contain a single arginine whose specific side chain and position are crucial for RNA binding. In addition, the putative RNA binding domain of two ilarvirus coat proteins, TSV and citrus variegation virus, is identified and also shown to contain a crucial arginine. AMV and ilarvirus coat protein sequence alignment centering on the key arginine revealed a new RNA binding consensus sequence. This consensus may explain in part why heterologous viral RNA-coat protein mixtures are infectious.

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.

The 5' terminal sequence of alfalfa mosaic virus RNA 3 is dispensable for replication and contains a determinant for symptom formation

Transgenic P12 tobacco plants, transformed with the replicase genes P1 and P2 of alfalfa mosaic virus (AIMV), can be infected with RNA 3 of the tripartitite AIMV genome or with a DNA copy of RNA 3 fused to the CaMV 35S promoter and nos terminator. The effect of various modifications on the infectivity of the 35S/cDNA 3 construct to P12 plants was studied. When nonviral sequences ranging from 11 to 200 bp were inserted between the 35S promoter and cDNA 3, the infection became dependent on addition of coat protein (CP) to the inoculum. About 80% of the progeny RNAs resulting from these infections were full-length and had lost the nonviral sequence, whereas 20% were truncated by a deletion of the 5' terminal 79 nucleotides (nt). When the sequence corresponding to the 5' terminal 22 nt of RNA 3 was deleted from the 35S/cDNA 3 construct, the clone was as infectious as the wild type (wt), provided that CP was added to the inoculum, but only progeny RNA with a 5' terminal deletion of 79 nt was produced. The 5' truncated RNA 3 molecules induced necrotic ringspot-like symptoms on P12 tobacco plants, whereas wt RNA 3 did not induce detectable symptoms on these plants. It is proposed that in the infections with the modified 35S/cDNA 3 clones, CP is required in the inoculum to permit internal initiation of plus-strand RNA 3 synthesis on 3'-extended or 3'-truncated minus-strand RNA templates. Evidence was obtained that minus-strand RNA 3 synthesized under the control of the 35S promoter was not infectious to P12 plants.

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.

Analysis of cis-acting elements in the 5' leader sequence of alfalfa mosaic virus RNA 3

The leader sequence of RNA 3 of the Leiden isolate of alfalfa mosaic virus strain 425 consists of 345 nucleotides (nt) and contains four putative stem-loop structures each with a motif in the loop that resembles the internal control region 2 (ICR2) of tRNA genes. The sequence of the 5' terminal 112 nt of this leader contains one of these stem-loop structures and is sufficient for a reduced accumulation of RNA 3 in protoplasts and a delayed accumulation in plants (E. A. G. van der Vossen et al., Nucleic Acids Res. 21, 1361-1367 (1993). A number of mutations were made in this 112-nt leader sequence to investigate its role in RNA 3 accumulation. Deletion of nucleotides 23-43, 44-90, or 55-112 and inversion or duplication of nucleotides 44-90 all abolished RNA 3 accumulation. Similarly, two base substitutions in the ICR2 motif (nucleotides 60-77) abolished RNA'3 accumulation. Mutations in the stem sections of the putative stem-loop structure had various effects on RNA 3 accumulation and supported the notion that this structure is important for plus-strand promoter activity.

cis-preferential stimulation of alfalfa mosaic virus RNA 3 accumulation by the viral coat protein

RNA 3 of alfalfa mosaic virus (AIMV) encodes the movement protein P3 and the viral coat protein (CP) which is translated from the subgenomic RNA 4. RNA 3 is able to replicate in tobacco plants transformed with the AIMV replicase genes P1 and P2 (P12 plants). Frameshifts or deletions in the P3 gene have little effect on RNA 3 accumulation in P12 protoplasts whereas such mutations in the CP gene result in a 100-fold reduction of plus-strand RNA 3 accumulation. When P12 protoplasts were inoculated with a mixture of a RNA 3 mutant with a deletion in the P3 gene and a mutant with a deletion in the CP gene, CP expressed by the P3 mutant was unable to upregulate plus-strand RNA accumulation of the CP mutant. However, when a wild-type CP gene and subgenomic promoter were inserted in a RNA 3 mutant with a defective CP gene, the mutant accumulated at wild-type levels. It is concluded that the function of CP in plus-strand RNA 3 accumulation acts in cis and cannot be complemented in trans. In P12 plants, P3 and CP mutants were able to complement each other at low and variable levels. This complementation in plants appeared to be correlated with the occurrence of recombination to wild-type RNA 3.

Purification, characterization, assembly and crystallization of assembled alfalfa mosaic virus coat protein expressed in Escherichia coli

The coast protein of alfalfa mosaic virus (AMV) was cloned and expressed in Escherichia coli as a fusion protein containing a 37 amino acid extension with a (His)6 region for affinity purification. About half of the expressed recombinant coat protein (rCP) was soluble upon extraction and half was insoluble in inclusion bodies. Western blot analysis confirmed the identity of the rCP and protoplast infectivity assays indicated that the rCP was biologically active in an early event of AMV infection, called genome activation. The rCP assembled into T = 1 empty icosahedral particles, as described previously for native coat protein. Empty particles formed hexagonal crystals that diffracted X-rays to 5.5 A resolution. The crystals of trypsin-treated particles of rCP appear to be isomorphous with crystals of trypsin-treated particles of native coat protein, Spherical particles containing RNA assembled when the rCP was combined with in vitro transcripts of AMV RNA4, the smallest naturally encapsidated AMV RNA. Bacilliform particles that resembled native virions assembled when the rCP was combined with transcripts of RNA1, the largest genomic RNA.

Interaction between RNA-dependent RNA polymerase of alfalfa mosaic virus and its template: oxidation of vicinal hydroxyl groups blocks in vitro RNA synthesis

In the life cycle of a (+)-strand RNA plant virus the processes of template RNA recognition and initiation of the synthesis of a complementary strand by the viral RNA-dependent RNA polymerase (RdRp) are crucial early steps. Using a template-dependent in vitro RNA synthesizing system of alfalfa mosaic virus (AIMV) we were able to study the effect of small chemical modifications of the 3' end of the template RNAs on product formation. After oxidation of the 3'-terminal nucleoside of the template no products could be detected. Presumably, RNA synthesis was blocked at the stage of initiation, since the promoter of the RdRp is internal (A. C. Van der Kuyl et al., Virology 176, 346-354, 1990). Blocking was probably due to an irreversible binding of the enzyme to the 3' end of the modified RNA. Using this system it was shown that in template competition experiments the RdRp of AIMV displays a high specificity for its cognate template, either before or after the oxidation of the 3'-terminal nucleoside. From this it was concluded that periodate modification of the 3'-terminal nucleoside has little or no effect on template recognition. Furthermore, we showed that the viral coat protein, which forms a part of the viral polymerase (R. Quadt et al., Virology 182, 309-315, 1991), was not the main target involved in the inhibition of RNA synthesis.

Characterization of sequences controlling the synthesis of alfalfa mosaic virus subgenomic RNA in vivo

RNA 3 of alfalfa mosaic virus encodes the movement protein P3 and the viral coat protein (CP). CP is translated from a subgenomic (sg) messenger, RNA 4. To characterize the sg promoter that is responsible for RNA 4 synthesis in vivo, putative sg promoter sequences were inserted in a unique Xhol site located between the initiation codon of the P3 gene and a second in-frame ATG codon in an infectious cDNA clone of RNA 3. Mutants with an active sg promoter insert expressed an N-terminally truncated P3 protein and were able to accumulate in plants. In addition, sg promoter activity was analyzed in protoplasts. When the transcription start site is taken as +1, the sequence of nucleotides -26/+1 was found to have a basal level of sg promoter activity. This activity was increased to near maximum levels when the sg promoter sequence was extended to -136/+12. The upstream positive regulatory element was mapped to nucleotides -136/-94. Engineering of point mutations and small deletions in RNA 3 around the transcription start site for RNA 4 synthesis revealed elements important for sg promoter activity with similarity to sequences conserved in sg promoters of alpha-like viruses. Some of these elements appeared to be required in cis for RNA 3 accumulation. A deletion of the C-terminal three amino acids of the P3 protein rendered this protein nonfunctional in cell-to-cell movement.

High-affinity RNA-binding domains of alfalfa mosaic virus coat protein are not required for coat protein-mediated resistance

A virus-based vector was used for the transient expression of the alfalfa mosaic virus coat protein (CP) gene in protoplasts and plants. The accumulation of wild-type CP conferred strong protection against subsequent alfalfa mosaic virus infection, enabling the efficacy of CP mutants to be determined without developing transgenic plants. Expression of the CP mRNA alone without CP accumulation conferred weaker protection against infection. The activity of the N-terminal mutant CPs in protection did not correlate with their activities in genome activation. The activity of a C-terminal mutant suggested that encapsidation did not have a role in protection. Our results indicate that interaction of the CP with alfalfa mosaic virus RNA is not important in protection, thereby leaving open the possibility that interactions with host factors lead to protection.

mRNAs containing the unstructured 5' leader sequence of alfalfa mosaic virus RNA 4 translate inefficiently in lysates from poliovirus-infected HeLa cells

Poliovirus infection is accompanied by translational control that precludes translation of 5'-capped mRNAs and facilitates translation of the uncapped poliovirus RNA by an internal initiation mechanism. Previous reports have suggested that the capped alfalfa mosaic virus coat protein mRNA (AIMV CP RNA), which contains an unstructured 5' leader sequence, is unusual in being functionally active in extracts prepared from poliovirus-infected HeLa cells (PI-extracts). To identify the cis-acting nucleotide elements permitting selective AIMV CP expression, we tested capped mRNAs containing structured or unstructured 5' leader sequences in addition to an mRNA containing the poliovirus internal ribosome entry site (IRES). Translations were performed with PI-extracts and extracts prepared from mock-infected HeLa cells (MI-extracts). A number of control criteria demonstrated that the HeLa cells were infected by poliovirus and that the extracts were translationally active. The data strongly indicate that translation of RNAs lacking an internal ribosome entry site, including AIMV CP RNA, was severely compromised in PI-extracts, and we find no evidence that the unstructured AIMV CP RNA 5' leader sequence acts in cis to bypass the poliovirus translational control. Nevertheless, cotranslation assays in the MI-extracts demonstrate that mRNAs containing the unstructured AIMV CP RNA 5' untranslated region have a competitive advantage over those containing the rabbit alpha-globin 5' leader. Previous reports of AIMV CP RNA translation in PI-extracts likely describe inefficient expression that can be explained by residual cap-dependent initiation events, where AIMV CP RNA translation is competitive because of a diminished quantitative requirement for initiation factors.

Ability of tobacco streak virus coat protein to substitute for late functions of alfalfa mosaic virus coat protein

The coat protein (CP) of tobacco streak virus (TSV) can substitute for the early function of alfalfa mosaic virus (AIMV) CP in genome activation. Replacement of the CP gene in AIMV RNA 3 with the TSV CP gene and analysis of the replication of the chimeric RNA indicated that the TSV CP could not substitute for the function of AIMV CP in asymmetric plus-strand RNA accumulation but could encapsidate the chimeric RNA and permitted a low level of cell-to-cell transport.

Characterization of the alfalfa mosaic virus strain T6

A strain T6 of alfalfa mosaic virus (AlMV) was characterized. It was isolated from field grown lucerne. Purified virus preparations contained four types of particles, B, M, Tb and Ta, containing separately encapsidated ssRNAs 1 to 4. The strain T6 was able to infect 40 different plant species of 9 families, and to develop a systemic infection in most of them. The symptomatology on bean and the RNA mobility of the AlMV strains T6 and 425 were compared. The classical cross-protection experiments on bean have shown that plants inoculated with strain 425 did not develop symptoms of the challenge strain T6.

In vitro evidence that the coat protein of alfalfa mosaic virus plays a direct role in the regulation of plus and minus RNA synthesis: implications for the life cycle of alfalfa mosaic virus

The coat protein of alfalfa mosaic virus has both structural and regulating functions. The latter is evident from the fact that the genomic RNAs of the virus, although they are of messenger polarity, cannot start an infection cycle in the absence of cost protein. The reason could be that the coat protein is needed for viral RNA synthesis. Indeed, the coat protein has been found in tight association with the viral RNA polymerase (R. Quadt et al., 1991, Virology 182, 309-315). To investigate the role of the coat protein, if any, in viral RNA synthesis, we have isolated that viral RNA polymerase (RNA-dependent RNA polymerase, RdRp) from mock-inoculated tobacco plants transformed with cDNAs 1 and 2, known as P12 plants (P. E. M. Taschner et al., 1991, Virology 181, 687-693), which express the nonstructural proteins P1 and P2. Such an enzyme (called M-RdRp) will contain the viral subunits P1 and P2 but not the coat protein. As a comparison we also isolated the RdRp from virion-inoculated P12 plants (C-RdRp). This enzyme will contain the coat protein. We found that both M-RdRp and C-RdRp could synthesize minus RNA, showing that coat protein is not needed for minus-strand synthesis. In contrast, minus-strand synthesis by both enzymes was inhibited by coat protein. Plus-strand synthesis was unaffected by coat protein in the case of C-RdRp, but strongly stimulated by coat protein in the case of M-RdRp. These data might explain why infected cells, which do not produce coat protein, display a very low accumulation of viral plus-strand RNA. They also give a possible explanation for the noninfectious character of the genomes of alfalfa mosaic virus and ilarviruses in the absence of coat protein. The fact that an active enzyme could be isolated from the same membrane fraction in infected and noninfected P12 plants shows that coat protein is not needed for assembly and targeting of the viral RNA polymerase.

Replicase-mediated resistance to alfalfa mosaic virus

Tobacco plants transformed with the P1 and P2 replicase genes of alfalfa mosaic virus (AIMV) have been shown to produce functional replicase proteins, permitting their infection with AIMV inocula lacking the genome segments encoding P1 and P2, respectively. To see whether expression of a mutant P2 protein would interfere with the assembly of a functional replicase complex, tobacco plants were transformed with modified P2 genes. When plants were transformed with a P2 gene encoding an N-terminally truncated protein which mimicked the tobacco mosaic virus 54K protein, no resistance was observed with 10 independent lines of transformants. Similarly, when the GDD motif in the full-length P2 protein was changed into VDD, no resistance was observed in 14 transgenic lines. However, when the GDD motif was changed into GGD (5 lines), GVD (15 lines), or DDD (13 lines), 20 to 30% of the transgenic lines showed a high level of resistance to AIMV infection. This resistance was effective to inoculum concentrations of 10 to 25 micrograms/ml of virus and 100 micrograms/ml of viral RNA, causing severe necrosis of control plants. For all transgenic lines, the expression of the transgenes was analyzed at the RNA level. With the GGD, GVD, and DDD mutants, resistance was generally observed in plants with a relatively high expression level. This indicates that the resistance is due to the mutant replicase rather than to an RNA-mediated cosuppression phenomenon.

Mapping of the RNA-binding domain of the alfalfa mosaic virus movement protein

In-frame contiguous deletions were created in the movement protein gene of alfalfa mosaic virus by site-directed mutagenesis. The mutated movement proteins were expressed in Escherichia coli, extracted and then purified by denaturing gel electrophoresis and then renatured. Their binding ability with RNA was assayed by electrophoretic retardation and u.v.-crosslinking. Results indicated that a domain included within amino acids 36 to 81 was necessary for RNA binding.

Plants transformed with a mutant alfalfa mosaic virus coat protein gene are resistant to the mutant but not to wild-type virus

Transgenic tobacco plants expressing the wild-type (wt) coat protein (CP) gene of alfalfa mosaic virus (AIMV) have been shown to be resistant to infection with viral particles and RNAs or to infection with viral particles only. The difference in resistance of these plants to RNA inocula was found to correlate with a difference in the expression level of the transgene. Plants expressing a mutant AIMV CP with the N-terminal serine residue changed to glycine have been shown to be susceptible to infection with wt viral particles or RNAs. By site-directed mutagenesis of AIMV cDNA a viable mutant virus encoding CP with the same N-terminal mutation was obtained. Plants expressing wt or mutant CP were resistant to the mutant virus, demonstrating that a single amino acid substitution in CP did not permit the virus to overcome CP-mediated resistance. Although the mutant CP did not confer resistance to wt virus when expressed in transgenic plants, it was still effective in classical cross-protection: plants infected with the mutant virus were resistant to severe strain of AIMV. A model to explain the data is discussed.

Early and late functions of alfalfa mosaic virus coat protein can be mutated separately

To investigate the role of alfalfa mosaic virus coat protein (CP) in genome activation, asymmetric plus-strand RNA accumulation, and cell-to-cell spread of the virus, mutations were made in the CP gene and putative CP binding sites in the 3'-untranslated region (UTR) of RNA 3. Mutants that produced no CP-related peptide or CP with an N-terminal deletion of 20 amino acids were defective in all three functions. Insertion of several nonviral amino acids at position 85 of CP had little effect on genome activation and plus-strand RNA accumulation but abolished cell-to-cell spread. A mutant encoding CP with a C-terminal deletion of 21 amino acids was defective in plus-strand RNA accumulation but showed substantial levels of genome activation and cell-to-cell spread. Mutations in the 3'-UTR that interfered with CP binding affected plus-strand RNA accumulation and cell-to-cell spread. Neither CP nor CP binding sites at the 3'-end of RNA 3 were required for minus-strand RNA accumulation. The results demonstrate that early and late functions of CP can be mutated separately, indicating that different domains of CP are involved in the three functions investigated.

The 3'-untranslated region of alfalfa mosaic virus RNA 3 contains at least two independent binding sites for viral coat protein

The 3'-termini of the three genomic RNAs of alfalfa mosaic virus contain a common sequence of 145 nucleotides (nt) with a specific binding site for coat protein (CP). This sequence consists of several stem/loop structures interspersed with single-stranded AUGC-motifs; in RNA 3 this folding pattern is extended to a region upstream of the homologous sequence. By band-shift assays a minimum of two specific binding sites for CP were identified near the 3'-end of RNA 3. Site 1 consists of the region between nt 11 and 127 from the 3'-end and contains two AUGC-motifs. Site 2 is located between nt 133 and 208 from the 3'-end in a sequence that is largely unique to RNA 3 and contains also two AUGC-motifs. Deletion studies revealed that the two sites could bind CP independently of each other and permitted the identification of sequence elements that are essential for the activity of each site. By site-directed mutagenesis it was shown that the AUGC-motifs are important for binding of CP to both sites. These binding sites may play a role in the phenomenon that each genomic RNA has to be complexed with a few CP molecules to initiate infection. Later in the replication cycle they may act as origins for the assembly of virus particles.

Nucleotide sequence and structural determinants of specific binding of coat protein or coat protein peptides to the 3' untranslated region of alfalfa mosaic virus RNA 4

The specific binding of alfalfa mosaic virus coat protein to viral RNA requires determinants in the 3' untranslated region (UTR). Coat protein and peptide binding sites in the 3' UTR of alfalfa mosaic virus RNA 4 have been analyzed by hydroxyl radical footprinting, deletion mapping, and site-directed mutagenesis experiments. The 3' UTR has several stable hairpins that are flanked by single-stranded (A/U)UGC sequences. Hydroxyl radical footprinting data show that five sites in the 3' UTR of alfalfa mosaic virus RNA 4 are protected by coat protein, and four of the five protected regions contain AUGC or UUGC. Electrophoretic mobility band shift results suggest four coat protein binding sites in the 3' UTR. A 3'-terminal 39-nucleotide RNA fragment containing four AUGC repeats bound coat protein and coat protein peptides with high affinity; however, coat protein bound poorly to antisense 3' UTR transcripts and poly(AUGC)10. Site-directed mutagenesis of AUGC865-868 resulted in a loss of coat protein binding and peptide binding by the RNA fragment. Alignment of alfalfa mosaic RNA sequences with those from several closely related ilarviruses demonstrates that AUGC865-868 is perfectly conserved; moreover, the RNAs are predicted to form similar 3'-terminal secondary structures. The data strongly suggest that alfalfa mosaic virus coat protein and ilavirus coat proteins recognize invariant AUGC sequences in the context of conserved structural elements.

Specific RNA binding by amino-terminal peptides of alfalfa mosaic virus coat protein

Specific RNA-protein interactions and ribonucleoprotein complexes are essential for many biological processes, but our understanding of how ribonucleoprotein particles form and accomplish their biological functions is rudimentary. This paper describes the interaction of alfalfa mosaic virus (A1MV) coat protein or peptides with viral RNA. A1MV coat protein is necessary both for virus particle formation and for the initiation of replication of the three genomic RNAs. We have examined protein determinants required for specific RNA binding and analyzed potential structural changes elicited by complex formation. The results indicate that the amino-terminus of the viral coat protein, which lacks primary sequence homology with recognized RNA binding motifs, is both necessary and sufficient for binding to RNA. Circular dichroism spectra and electrophoretic mobility shift experiments suggest that the RNA conformation is altered when amino-terminal coat protein peptides bind to the viral RNA. The peptide--RNA interaction is functionally significant because the peptides will substitute for A1MV coat protein in initiating RNA replication. The apparent conformational change that accompanies RNA--peptide complex formation may generate a structure which, unlike the viral RNA alone, can be recognized by the viral replicase.

Ribosome-messenger recognition in the absence of the Shine-Dalgarno interactions

In an attempt to understand how Escherichia coli ribosomes recognize the initiator codon on mRNAs lacking the Shine-Dalgarno (SD) sequence, we have studied 30S initiation complex formation in extension inhibition (toeprinting) experiments using (-SD)mRNAs which are known to be reliably translated in E. coli: the plant viral messenger A1MV RNA 4 and two chimaeric mRNAs coding for beta-glucuronidase (GUS) and bearing the 5'-untranslated sequence of TMV RNA (omega) or the omega-derived sequence (CAA)n as 5'-leaders. Ribosomal protein S1 and IF3 have been found to be indispensable for translational initiation. Protein S1 appears to be a key recognition element. S1 binds to sequences within the leaders of (-SD)mRNAs thus providing their affinity to E. coli ribosomes.