Complete nucleotide sequence of alfalfa mosaic virus RNA3

Phosphorylation of alfalfa mosaic virus movement protein in vivo

The 32-kDa movement protein, P3, of alfalfa mosaic virus (AMV) is essential for cell-to-cell spread of the virus in plants. P3 shares many properties with other virus movement proteins (MPs); however, it is not known if P3 is posttranslationally modified by phosphorylation, which is important for the function of other MPs. When expressed in Nicotiana tabacum, P3 accumulated primarily in the cell walls of older leaves or in the cytosol of younger leaves. When expressed in Pischia pastoris, P3 accumulated primarily in a soluble form. Metabolic labeling indicated that a portion of P3 was phosphorylated in both tobacco and yeast, suggesting that phosphorylation regulates the function of this protein as it does for other virus MPs.

Biological and Molecular Variability of Alfalfa mosaic virus Affecting Alfalfa Crop in Riyadh Region

In 2011-2012, sixty nine samples were collected from alfalfa plants showing viral infection symptoms in Riyadh region. Mechanical inoculation with sap prepared from two collected samples out of twenty five possitive for Alfalfa mosaic virus (AMV) by ELISA were produced systemic mosaic on Vigna unguiculata and Nicotiana tabacum, local lesion on Chenopodium amaranticolor and C. quinoa. Vicia faba indicator plants that induce mosaic and mottle with AMV-Sagir isolate and no infection with AMV-Wadi aldawasser isolate. Approximately 700-bp was formed by RT-PCR using AMV coat protein specific primer. Samples from infected alfalfa gave positive results, while healthy plant gave negative result using dot blot hybridization assay. The nucleotide sequences of the Saudi isolates were compared with corresponding viral nucleotide sequences reported in GenBank. The obtained results showed that the AMV from Australia, Brazil, Puglia and China had the highest similarity with AMV-Sajer isolate. While, the AMV from Spain and New Zealaland had the lowest similarity with AMV-Sajer and Wadi aldawasser isolates. The data obtained in this study has been deposited in the GenBank under the accession numbers KC434083 and KC434084 for AMV-Sajer and AMV- Wadialdawasser respectively. This is the first report regarding the gnetic make up of AMV in Saudi Arabia.

Variable repeats and poly (A)-stretches in the leader sequence of alfalfa mosaic virus RNA 3

The complete nucleotide sequence of RNA 3 of the L strain of alfalfa mosaic virus (AlMV) was deduced and the 5'-terminal sequence of RNA 3 of the S-strain was revised. A comparison of the RNA sequences of AlMV strains L, S, and M showed that a sequence of 27 to 30 nucleotides is repeated two times in the 5' noncoding regions of all strains. In addition, sequences of 56 and 75 nucleotides are duplicated in the leaders of strain S and L, respectively. An A-rich sequence of 10 nucleotides, present in strain S and M, was found to be extended to 40 nucleotides in strain L. The data provide further information on the fidelity of RNA-dependent RNA polymerases.

High resolution mapping of carnation mottle virus-associated RNAs

The genomic coordinates from which carnation mottle virus (CarMV) subgenomic RNA 5'-ends originate have been determined by high resolution S, nuclease protection and primer-extension mapping techniques. The two, 3'-proximal subgenomic RNAs initiate at nucleotides 2532 and 2315 (counting from the genome 5' terminus). These RNAs contain 1472 and 1689 nucleotides, respectively. There is substantial nucleotide sequence homology surrounding the transcriptional start sites of the two subgenomic RNAs. The 1.5-kb RNA uses the first AUG to initiate translation of viral coat protein. The first AUG on the 1.7-kb RNA begins a short open reading frame of 183 nucleotides. This region encodes a Mr = 6746 polypeptide found by in vitro translation of authentic subgenomic RNA as well as synthetic SP6 transcripts. By SP6 transcription and cell-free translation, we have also mapped coding sequences for a previously identified CarMV gene product, p27, to the 5' terminus of the viral genome.

Artifacts are responsible for the translational activity of polyribosome preparations isolated from alfalfa mosaic virus-infected tobacco leaves

We observed that polyribosome preparations isolated from alfalfa mosaic virus (A1MV)-infected tobacco leaves were contaminated with virion-derived material which could not be removed completely by sucrose gradient centrifugation or by magnesium ion precipitation. Upon incubation of polyribosome preparations with S 100 extracts from reticulocyte lysates, viral-encoded proteins were produced. Aurintricarboxylic acid (ATA), an inhibitor of initiation of translation, was used to inhibit de novo translation of the RNAS contaminating the polyribosome preparations. ATA concentrations, which did not inhibit peptide chain elongation on in vitro-produced polyribosomes, completely inhibited the translational activity of the tobacco polyribosomes. Hence the protein synthetic capacity of the tobacco polyribosome preparations is due to de novo translation of virion-derived material by vacant ribosomes present in the complementing S 100 extract. Efforts to activate the tobacco polyribosomes remain unsuccessful.

Nonstructural alfalfa mosaic virus RNA-coded proteins present in tobacco leaf tissue

The proteins synthesized under the direction of alfalfa mosaic virus RNAS in tobacco leaves have been examined under conditions of suppressed host protein synthesis. Besides the coat protein we could detect a 22K (K = apparent molecular weight in thousands), a 35K, and a set of 54K proteins. The 22K protein is serologically related to the coat protein. The 35K protein comigrated with the 35K protein whose synthesis is directed by RNA 3 in vitro The 54K proteins are serologically related to the 35K protein produced in vitro. Readthrough products of the 35K protein cistron into the coat protein cistron have been found previously in wheat germ extracts programmed with RNA 3. Two of these proteins comigrate with the 54K proteins synthesized in vivo. Since the 35K and the coat protein cistrons are read in different reading frames the formation of readthrough products is puzzling. In viruses with a tripartite genome the subgenomic mRNA for coat protein, RNA 4, is not known to be replicated as a separate genome entity. This might indicate that proteins synthesized by readthrough into the coat protein cistron play an essential role during replication, especially in the earliest phases.

Virus protein synthesis in alfalfa mosaic virus infected alfalfa protoplasts

Four proteins unique to virus infection were synthesized in alfalfa mosaic virus-infected alfalfa mesophyll protoplasts. These proteins, P1, P2, P3, and coat protein comigrated on electrophoresis with the major in vitro translation products of RNA 1, RNA 2, RNA 3, and RNA 4, respectively. P1, P3, and coat protein were observed at 5 hr post inoculation; P2 was detected at 9 hr post inoculation. The three nonstructural proteins accumulated most rapidly early in infection until about 15 hr post inoculation; stable protein levels were maintained thereafter. Coat protein accumulated rapidly until about 20 hr after inoculation. All four virus RNA species were detected in infected protoplasts by labelling with [3H]uridine. Ultraviolet irradiation of protoplasts prior to inoculation was necessary for virus protein detection, but it severely depressed the synthesis of RNA 1 and RNA 2 relative to RNA 3 and RNA 4.

Identification, Characterization, and Molecular Detection of Alfalfa mosaic virus in Potato

ABSTRACT Alfalfa mosaic virus (AMV) was detected in potato fields in several provinces in Canada and characterized by bioassay, enzyme-linked immunosorbent assay, and reverse-transcription polymerase chain reaction (RT-PCR). The identity of eight Canadian potato AMV isolates was confirmed by sequence analysis of their coat protein (CP) gene. Sequence and phylogenetic analysis indicated that these eight AMV potato isolates fell into one strain group, whereas a slight difference between Ca175 and the other Canadian AMV isolates was revealed. The Canadian AMV isolates, except Ca175, clustered together among other strains based on alignment of the CP gene sequence. To detect the virus, a pair of primers, AMV-F and AMV-R, specific to the AMV CP gene, was designed based on the nucleotide sequence alignment of known AMV strains. Evaluations showed that RT-PCR using this primer set was specific and sensitive for detecting AMV in potato leaf and tuber samples. AMV RNAs were easily detected in composite samples of 400 to 800 potato leaves or 200 to 400 tubers. Restriction analysis of PCR amplicons with SacI was a simple method for the confirmation of PCR tests. Thus, RT-PCR followed by restriction fragment length polymorphism analysis may be a useful approach for screening potato samples on a large scale for the presence of AMV.

Arabidopsis thaliana is an asymptomatic host of Alfalfa mosaic virus

The susceptibility of Arabidopsis thaliana ecotypes to infection by Alfalfa mosaic virus (AMV) was evaluated. Thirty-nine ecotypes supported both local and systemic infection, 26 ecotypes supported only local infection, and three ecotypes could not be infected. No obvious symptoms characteristic of virus infection developed on the susceptible ecotypes under standard conditions of culture. Parameters of AMV infection were characterized in ecotype Col-0, which supported systemic infection and accumulated higher levels of AMV than the symptomatic host Nicotiana tabacum. The formation of infectious AMV particles in infected Col-0 was confirmed by infectivity assays on a hypersensitive host and by electron microscopy of purified virions. Replication and transcription of AMV was confirmed by de novo synthesis of AMV subgenomic RNA in Col-0 protoplasts transfected with AMV RNA or plasmids harboring AMV cDNAs.

A conserved hairpin structure in Alfamovirus and Bromovirus subgenomic promoters is required for efficient RNA synthesis in vitro

The coat protein gene in RNA 3 of alfalfa mosaic virus (AMV; genus Alfamovirus, family Bromoviridae) is translated from the subgenomic RNA 4. Analysis of the subgenomic promoter (sgp) in minus-strand RNA 3 showed that a sequence of 37 nt upstream of the RNA 4 start site (nt +1) was sufficient for full sgp activity in an in vitro assay with the purified viral RNA-dependent RNA-polymerase (RdRp). The sequence of nt -6 to -29 could be folded into a potential hairpin structure with a loop represented by nt -16, -17, and -18, and a bulge involving nt -23. By introducing mutations that disrupted base pairing and compensatory mutations that restored base pairing, it was shown that base pairing in the top half of the putative stem (between the loop and bulge) was essential for sgp activity, whereas base pairing in the bottom half of the stem was less stringently required. Deletion of the bulged residue A-23 or mutation of this residue into a C strongly reduced sgp activity, but mutation of A-23 into U or G had little effect on sgp activity. Mutation of loop residues A-16 and A-17 affected sgp activity, whereas mutation of U-18 did not. Using RNA templates corresponding to the sgp of brome mosaic virus (BMV; genus Bromovirus, family Bromoviridae) and purified BMV RdRp, evidence was obtained indicating that also in BMV RNA a triloop hairpin structure is required for sgp activity.

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

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

RNA determinants of a specific RNA-coat protein peptide interaction in alfalfa mosaic virus: conservation of homologous features in ilarvirus RNAs

Alfalfa mosaic virus (AMV) coat protein and tobacco streak virus (TSV) coat protein bind specifically to the 3' untranslated regions of the viral RNAs and are required with the genomic RNAs to initiate virus replication. A combination of nucleotide substitutions, hydroxyl radical footprinting, and ethylation and chemical modification interference analysis has been used to define the RNA determinants important for the specific binding of the 3'-terminal 39 nucleotides of AMV RNA 3/4 (AMV843-881) to an amino-terminal coat protein peptide (CP26). The results demonstrate that potential phosphate and base-specific contacts as well as ribose moieties protected upon peptide binding cluster in lower hairpin stems and flanking AUGC sequences of the viral RNA, without direct involvement of loop nucleotides. Nucleotides identified in the modification-interference analyses as important for RNA-protein interactions are highly conserved among AMV and the ilarvirus RNAs. This RNA sequence homology, coupled with the recent identification of an RNA binding consensus sequence for AMV and ilarvirus coat proteins, provides a framework for understanding the functional equivalence of AMV and TSV coat proteins in binding RNA and activating virus replication and may explain why heterologous AMV and ilarvirus coat protein-RNA mixtures are infectious.

Gene expression from viral RNA genomes

This review is centered on the major strategies used by plant RNA viruses to produce the proteins required for virus multiplication. The strategies at the level of transcription presented here are synthesis of mRNA or subgenomic RNAs from viral RNA templates, and 'cap-snatching'. At the level of translation, several strategies have been evolved by viruses at the steps of initiation, elongation and termination. At the initiation step, the classical scanning mode is the most frequent strategy employed by viruses; however in a vast number of cases, leaky scanning of the initiation complex allows expression of more than one protein from the same RNA sequence. During elongation, frameshift allows the formation of two proteins differing in their carboxy terminus. At the termination step, suppression of termination produces a protein with an elongated carboxy terminus. The last strategy that will be described is co- and/or post-translational cleavage of a polyprotein precursor by virally encoded proteinases. Most (+)-stranded RNA viruses utilize a combination of various strategies.

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.

The complete nucleotide sequence of apple mosaic virus RNA-3

The complete nucleotide sequence of apple mosaic ilarvirus (ApMV) RNA-3 has been determined from cloned viral cDNAs. The 5' terminus of RNA-3 was determined by direct RNA sequencing, while the 3' end was determined by polyadenylation of genomic RNA and sub-cloning using oligo dT. ApMV RNA-3 is 2056 bases in length and encodes at least two open reading frames. It is similar in size and genome organization to the RNA-3 of other members of the Bromoviridae, which includes ilarviruses. The CP gene is in the 3' half of the molecule, and another large open reading frame is upstream of the CP gene and can potentially encode a protein of 32,400 daltons. This peptide is the same size and shows limited sequence homology to an open reading frame located at the 5' end of RNA 3 in tobacco streak and prune dwarf ilarviruses and alfalfa mosaic virus, which is postulated to be the viral movement protein. The nucleic acid sequence was not homologous to tobacco streak virus, prune dwarf virus, alfalfa mosaic virus or other members of the Bromoviridae. The 5'-non-coding region of ApMV RNA-3 contains a 15 base palindromic sequence which encloses a sequence resembling the ICR-2 regions of eukaryotic tRNA gene promoters.

Proposed classification of the bipartite-genomed raspberry bushy dwarf idaeovirus, with tripartite-genomed viruses in the family Bromoviridae

Raspberry bushy dwarf virus (RBDV) has an unusual combination of properties and has been classified as the sole member of a new plant virus genus, for which the name idaeovirus has been proposed. Particles of RBDV resemble those of ilarviruses (family Bromoviridae) in appearance and in being transmitted in association with pollen. RBDV has two genomic RNA species, RNA-1 (5,449 nt) and RNA-2 (2,231 nt). The particles also contain RNA-3 (946 nt), a subgenomic monocistronic coat protein mRNA which is derived from the 3' end of the bicistronic RNA-2. The single 190 K protein encoded by RNA-1 contains methyltransferase, helicase and polymerase domains. Evolutionary distance data obtained from multiple alignments of the amino acid sequence of the RBDV 190 K protein and corresponding proteins with replicative function from other plant viruses suggest that the closest affinities of RBDV are with the tripartite genomed viruses in the family Bromoviridae. We propose that the genus idaeovirus be included in the family Bromoviridae.

Evolution and taxonomy of positive-strand RNA viruses: implications of comparative analysis of amino acid sequences

Despite the rapid mutational change that is typical of positive-strand RNA viruses, enzymes mediating the replication and expression of virus genomes contain arrays of conserved sequence motifs. Proteins with such motifs include RNA-dependent RNA polymerase, putative RNA helicase, chymotrypsin-like and papain-like proteases, and methyltransferases. The genes for these proteins form partially conserved modules in large subsets of viruses. A concept of the virus genome as a relatively evolutionarily stable "core" of housekeeping genes accompanied by a much more flexible "shell" consisting mostly of genes coding for virion components and various accessory proteins is discussed. Shuffling of the "shell" genes including genome reorganization and recombination between remote groups of viruses is considered to be one of the major factors of virus evolution. Multiple alignments for the conserved viral proteins were constructed and used to generate the respective phylogenetic trees. Based primarily on the tentative phylogeny for the RNA-dependent RNA polymerase, which is the only universally conserved protein of positive-strand RNA viruses, three large classes of viruses, each consisting of distinct smaller divisions, were delineated. A strong correlation was observed between this grouping and the tentative phylogenies for the other conserved proteins as well as the arrangement of genes encoding these proteins in the virus genome. A comparable correlation with the polymerase phylogeny was not found for genes encoding virion components or for genome expression strategies. It is surmised that several types of arrangement of the "shell" genes as well as basic mechanisms of expression could have evolved independently in different evolutionary lineages. The grouping revealed by phylogenetic analysis may provide the basis for revision of virus classification, and phylogenetic taxonomy of positive-strand RNA viruses is outlined. Some of the phylogenetically derived divisions of positive-strand RNA viruses also include double-stranded RNA viruses, indicating that in certain cases the type of genome nucleic acid may not be a reliable taxonomic criterion for viruses. Hypothetical evolutionary scenarios for positive-strand RNA viruses are proposed. It is hypothesized that all positive-strand RNA viruses and some related double-stranded RNA viruses could have evolved from a common ancestor virus that contained genes for RNA-dependent RNA polymerase, a chymotrypsin-related protease that also functioned as the capsid protein, and possibly an RNA helicase.

The nucleotide sequence and genome organization of the RNA-1 segment in two bromoviruses: broad bean mottle virus and cowpea chlorotic mottle virus

The complete nucleotide sequences of the RNA-1 segments in broad bean mottle virus (BBMV) and cowpea chlorotic mottle virus (CCMV) were determined. BBMV RNA-1 consists of 3158 nucleotides and CCMV RNA-1 has 3171 nucleotides. Both BBMV and CCMV RNA-1 are capped at the 5' end but, unlike in other tricornaviruses, BBMV RNA-1 initiates with an A residue. Both BBMV and CCMV RNA-1 are monocistronic encoding for highly homologous 1a proteins of 966 and 958 amino acids, respectively. The highest homologies are clustered within two domains: the N-domain that aligns with the nsP1 Sindbis virus protein, a putative methyl transferase, and the C-domain which has a conserved nucleotide binding motif. Previous sequence comparisons suggest that the C-terminal domain may function as an NTP-dependent RNA helicase. In addition, we find that the C-domain has patterns similar to those of the reovirus and vaccinia virus guanylyl transferases. All this implies that 1a protein is a multifunctional polypeptide involved in both RNA capping and RNA polymerization processes.

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.

Biologically active transcripts of alfalfa mosaic virus RNA3

Transcripts of the bicistronic RNA3 of alfalfa mosaic virus were synthesized using the in vitro T7 run-off transcription system. Synthetic RNA3 containing one additional G nucleotide at the 5' end were found to be infectious when coinoculated with RNA1 and RNA2 and coat protein.

Nucleotide sequence of the ononis yellow mosaic tymovirus genome

The nucleotide sequence of the genome of ononis yellow mosaic tymovirus (OYMV) has been determined. The genome is single-stranded RNA, 6211 nucleotides long, and has three main open reading frames (ORFs), two of them overlapping. The largest ORF (nucleotides 179-5509) encodes a polyprotein of 1776 amino acid residues that has sequence similarities with polymerases of other viruses with RNA genomes. The smaller overlapping ORF (nucleotides 172-1965) encodes a protein of 597 amino acids of unknown function. The third ORF located at the 3' end of the genome (nucleotides 5487-6065) is the virion protein gene, and it overlaps by 20 nucleotides the 3' terminus of the largest ORF. The organization of the OYMV genome, its sequence, and the sequences of the protein it encodes are clearly similar to those of two other tymoviruses, turnip yellow mosaic virus and eggplant mosaic virus. The 5' terminal noncoding region of the OYMV genome is much longer than the same region of other tymoviral genomes and includes a direct duplication of a sequence of 21-23 nucleotides.

Sequence of cowpea chlorotic mottle virus RNAs 2 and 3 and evidence of a recombination event during bromovirus evolution

The genomic sequence of cowpea chlorotic mottle virus (CCMV) was completed by sequencing biologically active cDNA clones of CCMV RNA2 (2774 bases) and RNA3 (2173 bases). While only the central core of the encoded 94-kDa CCMV 2a protein contains features conserved among known and putative RNA replication proteins from many viruses, both flanking regions of CCMV 2a show substantial similarity to the corresponding protein of the related brome mosaic virus (BMV). The 3a proteins of CCMV and BMV, implicated as contributors to the distinct host specificities of the two viruses, show lower levels of conservation but are still discernibly related throughout. Major differences occur in the organization of noncoding sequences in CCMV and BMV RNA3. With respect to an otherwise similar region preceding the BMV 3a gene, the CCMV RNA3 5' noncoding sequence contains a clearly bounded 111-base insertion that must reflect a sequence rearrangement in evolution of at least one of the two viruses. The presence of a subgenomic promoter-like sequence near the end of the novel CCMV sequence makes the organization of genes in CCMV RNA3 reminiscent of the 3' end of tobacco mosaic virus RNA, suggesting that CCMV or its 3a gene might have been derived from an ancestor with fewer genomic RNAs. Sequence similarities between the CCMV and BMV RNA3 intercistronic regions include the subgenomic mRNA promoter and an oligo(A), but not an intercistronic segment required for BMV RNA3 amplification, implying that replication signals on the two RNA3s may be organized quite differently.

Alfalfa mosaic virus temperature-sensitive mutants. V. The nucleotide sequence of TBTS 7 RNA 3 shows limited nucleotide changes and evidence for heterologous recombination

Nucleotide sequence determination of the coat protein cistron of the alfalfa mosaic virus (AIMV) temperature-sensitive mutant, Tbts 7 (uv) revealed a small number of point mutations of which only one results in the replacement of an amino acid: the asparagine residue at position 126 is replaced by an aspartate residue. RNA transcribed in vitro from a Tbts 7 cDNA 4 clone directed the production in vitro of a polypeptide which shows the same altered electrophoretic mobility in SDS-polyacrylamide gels as the Tbts 7 coat protein. Nucleotide sequence analysis of the 32-kDa open reading frame revealed some base changes, but none of these lead to changes in the primary structure of the protein. The 5'-terminal sequence of Tbts 7 RNA 3 was analyzed by cDNA cloning. At least three different types of nontranslated leader sequences were found, indicating considerable heterogeneity at the 5' end of the mutant RNA 3. The results indicated that the low abundance of RNA 3-containing particles in Tbts 7 virus preparations might be due to malfunctioning of the 5' terminus of Tbts 7 RNA 3 during replication.

Preparation of soluble, biologically active alfalfa mosaic virus coat protein and its CaCl2-induced degradation

A method for the preparation of soluble protein from five biologically distinct alfalfa mosaic virus (AMV) isolates is described. Highly purified AMV was dissociated with 1 M CaCl2 in 10 mM sodium acetate, pH 6.0, and the precipitated RNA was removed by centrifugation. The protein was dialysed against 10 mM sodium acetate, pH 6.0, containing 0.1 M CaCl2. If the salt concentration was reduced further, proteins from some AMV isolates precipitated. Proteins prepared by this method were shown to be immunoreactive and to activate the infectivity of the AMV genome. However, during prolonged exposure of the protein to buffers containing 0.1 M CaCl2, it undergoes slow proteolysis thereby losing its ability to activate the AMV genome but not its immunoreactivity.

Nucleotide sequence analysis of cDNA encoding the coat protein of cucumber mosaic virus: genome organization and molecular features of the protein

The cDNA sequence coding for the coat protein of cucumber mosaic virus (Japanese Y strain) was cloned, and its nucleotide sequence was determined. The sequence contains an open reading frame that encodes the coat protein composed of 218 amino acids. The nucleotide and deduced amino acid sequences of the coat protein of this strain were compared with those of the Q strain; the homologies of the sequences were 78% and 81%, respectively. Further study of the sequences gave an insight into the genome organization and the molecular features of the coat protein. The coding region can be divided into three characteristic regions. The N-terminal region has conserved features in the positively charged structure, the hydropathy pattern and the predicted secondary structure, although the amino acid sequence is varied mainly due to frameshift mutations. It is noteworthy that the positions of arginine residues in this region are highly conserved. Both the nucleotide and amino acid sequences of the central region are well conserved. The amino acid sequence of the C-terminal region is not conserved, because of frameshift mutations, however, the total number of amino acids is conserved. The nucleotide sequence of the 3'-noncoding region is divergent, but it could form a tRNA-like structure similar to those reported for other viruses. Detailed investigation suggests that the Y and Q strains are evolutionarily distant.

A centrifugation method for separation of plant viral genomic and subgenomic RNAs

Using alfalfa mosaic virus (AMV) as a model, a simple method for separating plant viral genomic RNAs from their subgenomic counterparts was established. The method relies on sucrose gradient fractionation under carefully selected conditions of centrifugation and fraction collection. The RNA components are recovered in nearly quantitative yield and have full biological activity as measured by infectivity of the reconstituted RNAs in suitable protoplasts and plant hosts. The individual RNAs, on the other hand, show no such infectivity, indicating that the separation is indeed complete.

Characterization and engineering of sequences controlling in vivo synthesis of brome mosaic virus subgenomic RNA

Expression of brome mosaic virus (BMV) coat protein and internal genes of many other positive-strand RNA viruses requires initiation of subgenomic mRNA synthesis from specific internal sites on minus-strand genomic RNA templates. Biologically active viral cDNA clones were used to investigate the sequences controlling production of BMV subgenomic RNA in vivo. Suitable duplications directed production of specifically initiated, capped subgenomic RNAs from new sites in the BMV genome. Previously implicated promoter sequences extending 20 bases upstream (-20) and 16 bases downstream (+16) of the subgenomic RNA initiation site directed only low-level synthesis. Subgenomic RNA production at normal levels required sequences extending to at least -74 but not beyond -95. Loss of an (rA)18 tract immediately upstream of the -20 to +16 "core promoter" particularly inhibited subgenomic RNA synthesis. The -38 to -95 region required for normal initiation levels contains repeats of sequence elements in the core promoter, and duplications creating additional upstream copies of these repeats stimulated subgenomic RNA synthesis above wild-type levels. At least four different subgenomic RNAs can be produced from a single BMV RNA3 derivative. For all derivatives producing more than one subgenomic RNA, a gradient of accumulation progressively favoring smaller subgenomic RNAs was seen.

Mutational analysis of the core and modulator sequences of the BMV RNA3 subgenomic promoter

The subgenomic promoter of a (+)-stranded RNA virus, brome mosaic virus (BMV) controlling synthesis of subgenomic RNA4 has been defined in vitro. Truncated and mutant (-)-strand RNA templates were produced by in vitro transcription of cloned RNA3 cDNA. Subgenomic (+)-sense RNA was synthesized in vitro from these templates by a replicase (RNA-dependent RNA polymerase) preparation extracted from infected barley leaves. The activities of templates with truncations and deletions surrounding the RNA4 initiation site revealed a promoter of approximately 62 bases grouped into four functional domains. The core sequence consists of about twenty bases immediately upstream of, and including, the initiation nucleotide. In addition to the core sequence, a domain overlapping the 5' untranslated end of RNA4 apparently determines correct initiation. Two domains immediately upstream of the promoter core consist of the internal poly(A) tract of RNA3, which probably serves as an non base-paired spacer facilitating access of the replicase to the promoter, and a sequence, UUAUUAUU, that is required for high levels of promoter activity. Homologies to sequences surrounding the initiation sites of subgenomic RNAs from several plant RNA viruses, and from alphaviruses, have been detected.

The dynamical structure of the RNA in alfalfa mosaic virus studied by 31P-nuclear magnetic resonance

The structure of the viral RNA in alfalfa mosaic virus (AlMV) was investigated by means of 31P-nuclear magnetic resonance (NMR). It was found that the 31P-NMR line width of AlMV Top a particles is significantly smaller than that of the larger Bottom particles. At low temperatures, the totational correlation time of the 31P nuclei essentially equals the tumbling rate of the virus particle, indicating that the RNA is contained rigidly inside the virion. At more elevated temperatures, the NMR line width sharpens more than expected on the basis of viscosity changes and the RNA exhibits internal mobility. The occurrence of internal mobility is paralleled by an increased internal mobility of the N-terminal part of the coat protein, as could be observed by 1H-NMR spectroscopy. The influence of EDTA on the 31P-NMR line width appeared to be negligible, which is in agreement with the idea that AlMV does not 'swell' like several other RNA-containing plant viruses.

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.

The complete nucleotide sequence of RNA beta from the type strain of barley stripe mosaic virus

The complete nucleotide sequence of RNA beta from the type strain of barley stripe mosaic virus (BSMV) has been determined. The sequence is 3289 nucleotides in length and contains four open reading frames (ORFs) which code for proteins of Mr 22,147 (ORF1), Mr 58,098 (ORF2), Mr 17,378 (ORF3), and Mr 14,119 (ORF4). The predicted N-terminal amino acid sequence of the polypeptide encoded by the ORF nearest the 5'-end of the RNA (ORF1) is identical (after the initiator methionine) to the published N-terminal amino acid sequence of BSMV coat protein for 29 of the first 30 amino acids. ORF2 occupies the central portion of the coding region of RNA beta and ORF3 is located at the 3'-end. The ORF4 sequence overlaps the 3'-region of ORF2 and the 5'-region of ORF3 and differs in codon usage from the other three RNA beta ORFs. The coding region of RNA beta is followed by a poly(A) tract and a 238 nucleotide tRNA-like structure which are common to all three BSMV genomic RNAs.

Fluorescence studies on the coat protein of alfalfa mosaic virus

The intrinsic luminescence of different forms of the alfalfa mosaic virus (AMV) strain 425 coat protein has been studied, both statically and time resolved. It was found that the emission of the protein (Mr 24,250), which contains two tryptophans at positions 54 and 190 and four tyrosines, is completely dominated by tryptophan fluorescence. The high fluorescence quantum yield indicates that both tryptophans are emitting. Surprisingly, the fluorescence decay is found to be strictly exponential, with a lifetime of 5.1 nsec. Similar results were obtained for various other forms of the protein, i.e. the 30-S polymer, the mildly trypsinized forms of the protein lacking the N-terminal part and the protein assembled into viral particles. Virus particles and proteins of stains S and VRU gave similar results, as well as the VRU protein polymerised into tubular structures. The fluorescence decay is also monoexponential in the presence of various concentrations of the quenching molecules acrylamide and potassium iodide. Stern-Volmer plots were linear and yield for the coat protein dimer with acrylamide a quenching constant of 4.5* 10(8) M-1 sec-1. This indicates that the tryptophans are moderately accessible for acrylamide. For the 30-S polymer a somewhat smaller value was found, whereas in the viral Top a particles the accessibility of the tryptophans is still further reduced. From the decay of the polarisation anisotropy of the fluorescence of the coat protein dimer the rotational correlation time was obtained as 35 nsec. Since this roughly equals the expected rotational correlation time of the dimer as a whole, it suggests that the tryptophans are contained rigidly in the dimer. The results show that in the excited state of the protein the two tryptophans are strongly coupled and suggest that the trp-trp distance is smaller than 10 A. Because the coat protein occurs as a dimer, the coupling can be inter- or intramolecular. The implications for the viral structure are discussed.

Regulation of protein synthesis in virus-infected animal cells

This chapter summarizes the structural features that govern the translation of viral mRNAs: where the synthesis of a protein starts and ends, how many proteins can be produced from one mRNA, and how efficiently. It focuses on the interplay between viral and cellular mRNAs and the translational machinery. That interplay, together with the intrinsic structure of viral mRNAs, determines the patterns of translation in infected cells. It also points out some possibilities for translational regulation that can only be glimpsed at present, but are likely to come into focus in the future. The mechanism of selecting the initiation site for protein synthesis appears to follow a single formula. The translational machinery displays a certain flexibility that is exploited more frequently by viral than by cellular mRNAs. Although some of the parameters that determine efficiency have been identified, how efficiently a given mRNA will be translated cannot be predicted by summing the known parameters.

Nucleotide sequences from phaseolin cDNA clones: the major storage proteins from Phaseolus vulgaris are encoded by two unique gene families

The nucleotide sequences of eight partial and five full-length phaseolin cDNA clones show that phaseolin polypeptides are encoded by two distinct gene families which differ in their coding regions by the presence or absence of two different size direct repeats. The alpha-type phaseolin polypeptides are encoded by genes containing direct repeats which encode 14 additional amino acids. Aside from these differences, the alpha-and beta-type phaseolin genes show a high degree of homology (98%) which is consistent with these genes being derived from a common ancestral gene. Much of the heterogeneity found in the phaseolin polypeptides appears to be due to post-translational processing. Nucleotide sequence analysis demonstrates that the alpha-type genes contain only a few amino acid replacement substitutions and that the beta-type genes appear to contain no amino acid replacement substitutions. S1 nuclease mapping shows a complex pattern for transcriptional initiation of phaseolin mRNA. Hydropathy analysis shows that phaseolin polypeptides are predominately hydrophilic, and that the two N-glycosyl recognition sites are located in different hydropathic environments.

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.

Translational discrimination between the four RNAs of alfalfa mosaic virus. A quantitative evaluation

In an attempt to relate the translational characteristics of alfalfa mosaic virus (A1MV) RNAs to their structure [Ravelonandro et al. (1983) Nucleic Acids Res. 11, 2815-2826; Gehrke et al. (1983) Biochemistry 22, 5157-5164] we measured the relative affinities (discrimination ratios) of these RNAs for the initiation complex, in the wheat germ extract and in the nuclease-treated reticulocyte lysate, using a competition method designed by Brendler et al. [(1981) J. Biol. Chem. 256, 11747-11754]. As a prerequisite of this study we ascertained that the molecular mass distribution of the translation products was independent of RNA concentration in both translation systems. In the wheat germ extract the discrimination ratios are very similar for two strains of A1MV (S and B) which differ mainly by the presence (strain S) or absence (strain B) of a stable 5'-proximal hairpin. Hence this structure has no bearing on discrimination. Taking the affinity of RNA 3 as reference, the following orders of magnitude are found for the affinities of the different RNAs in the wheat germ: RNA 3, 1.0; RNA 1, 10; RNA 2, 60; RNA 4, 150. In the reticulocyte lysate the discrimination ratios are not significantly different from the wheat germ. Thus it seems that the mechanism of discrimination is essentially the same in the two translation systems, despite a difference in rate-limitation.

Sindbis virus proteins nsP1 and nsP2 contain homology to nonstructural proteins from several RNA plant viruses

Although the genetic organization of tobacco mosaic virus (TMV) differs considerably from that of the tripartite viruses (alfalfa mosaic virus [AlMV] and brome mosaic virus [BMV]), all of these RNA plant viruses share three domains of homology among their nonstructural proteins. One such domain, common to the AlMV and BMV 2a proteins and the readthrough portion of TMV p183, is also homologous to the readthrough protein nsP4 of Sindbis virus (Haseloff et al., Proc. Natl. Acad. Sci. U.S.A. 81:4358-4362, 1984). Two more domains are conserved among the AlMV and BMV 1a proteins and TMV p126. We show here that these domains have homology with portions of the Sindbis proteins nsP1 and nsP2, respectively. These results strengthen the view that the four viruses share mechanistic similarities in their replication strategies and may be evolutionarily related. These results also suggest that either the AlMV 1a, BMV 1a, and TMV p126 proteins are multifunctional or Sindbis proteins nsP1 and nsP2 function together as subunits in a single complex.

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.

Nucleotide sequence of cucumber-mosaic-virus RNA 2 reveals a translation product significantly homologous to corresponding proteins of other viruses

The nucleotide sequence of the 3035 residues of RNA 2 (Mr 1.03 X 10(6) ) of the Q strain of cucumber mosaic virus (CMV) was determined by sequencing M13 clones of the RNA 2 cDNA and by dideoxy sequencing using primers prepared either from M13 clones or by chemical synthesis. A single long open reading frame starts at the second AUG from the 5' end of RNA 2 and encodes 839 amino acids (Mr 94333). This frame has flanking regions of 92 nucleotides at the 5' terminus and 423 nucleotides at the 3' terminus. Computer analysis of the nucleotide sequence showed that CMV RNA 2 has a significant homology with RNA 2 of brome mosaic virus (BMV) and alfalfa mosaic virus (AMV) and also with a region for tobacco mosaic virus (TMV) RNA encoding the read-through part of the 183-kDa protein. About 400 amino acids in the central region of the CMV RNA 2 translation product have a striking homology with the corresponding proteins encoded by BMV and AMV and with the read-through part of the TMV 183-kDa protein. Hydrophobicity plots of CMV and BMV RNA translation products also had apparent similarities. It is concluded that CMV is related to BMV, AMV and TMV in order of increasing evolutionary divergence.

Primary structural comparison of RNA-dependent polymerases from plant, animal and bacterial viruses

Possible alignments for portions of the genomic codons in eight different plant and animal viruses are presented: tobacco mosaic, brome mosaic, alfalfa mosaic, sindbis, foot-and-mouth disease, polio, encephalomyocarditis, and cowpea mosaic viruses. Since in one of the viruses (polio) the aligned sequence has been identified as an RNA-dependent polymerase, this would imply the identification of the polymerases in the other viruses. A conserved fourteen-residue segment consisting of an Asp-Asp sequence flanked by hydrophobic residues has also been found in retroviral reverse transcriptases, a bacteriophage, influenza virus, cauliflower mosaic virus and hepatitis B virus, suggesting this span as a possible active site or nucleic acid recognition region for the polymerases. Evolutionary implications are discussed.

Striking similarities in amino acid sequence among nonstructural proteins encoded by RNA viruses that have dissimilar genomic organization

The plant viruses alfalfa mosaic virus (AMV) and brome mosaic virus (BMV) each divide their genetic information among three RNAs while tobacco mosaic virus (TMV) contains a single genomic RNA. Amino acid sequence comparisons suggest that the single proteins encoded by AMV RNA 1 and BMV RNA 1 and by AMV RNA 2 and BMV RNA 2 are related to the NH2-terminal two-thirds and the COOH-terminal one-third, respectively, of the largest protein encoded by TMV. Separating these two domains in the TMV RNA sequence is an amber termination codon, whose partial suppression allows translation of the downstream domain. Many of the residues that the TMV read-through domain and the segmented plant viruses have in common are also conserved in a read-through domain found in the nonstructural polyprotein of the animal alphaviruses Sindbis and Middelburg. We suggest that, despite substantial differences in gene organization and expression, all of these viruses use related proteins for common functions in RNA replication. Reassortment of functional modules of coding and regulatory sequence from preexisting viral or cellular sources, perhaps via RNA recombination, may be an important mechanism in RNA virus evolution.

Selection of initiation sites by eucaryotic ribosomes: effect of inserting AUG triplets upstream from the coding sequence for preproinsulin

Recombinant plasmids that direct synthesis of rat preproinsulin under the direction of the SV40 early promoter have been used to probe the mechanism of initiation of translation. Insertion of an upstream AUG triplet that was out-of-frame with respect to the coding sequence for preproinsulin reduced the yield of proinsulin, in keeping with the predictions of the scanning model. The extent to which an upstream AUG codon interfered depended on sequences surrounding the AUG triplet; with two constructs ( p255 /20 and C2) the 5'-proximal AUG codon constituted an absolute barrier: there was no initiation at the downstream start site for preproinsulin. With two other constructs ( p255 /9, p255 /21), however, proinsulin was made despite the presence of an upstream, out-of-frame AUG codon in a favorable context for initiation. In those cases the reading frame set by the first AUG triplet was short, terminating before the start of the preproinsulin coding sequence. The interpretation that ribosomes initiate at the first AUG, terminate, and then reinitiate at the AUG that directly precedes the preproinsulin coding sequence was tested by introducing a point mutation that eliminated the terminator codon: the resulting mutant made no proinsulin.