Phosphorylation of tobacco mosaic virus movement protein abolishes its translation repressing ability

Previously we showed that the ribonucleoprotein complexes (RNPs) of the TMV 30-kDa movement protein (MP) with TMV RNA are nontranslatable in vitro and noninfectious to protoplasts, but are infectious to intact plants. It has been suggested that MP-TMV RNA complexes could be converted into the translatable and replicatable form in planta in the course of passage through plasmodesmata (Karpova et al., 1997, Virology 230, 11-21). The role of TMV MP phosphorylation was investigated in terms of its capacity to modulate the translation-repressing ability of the MP. Phosphorylation of the TMV MP, either before or after RNP complex formation, caused a conversion of nontranslatable MP-RNA complexes into a form that was translatable in vitro and infectious to protoplasts and plants.

Mutational analyses of the putative calcium binding site and hinge of the turnip crinkle virus coat protein

The turnip crinkle carmovirus (TCV) coat protein (CP) is folded into R (RNA-binding), S (shell), and P (protruding) domains. The S domain is an eight-stranded beta barrel common to the coat protein subunits of most RNA viruses. A five-amino-acid hinge connects the S and P domains. In assembled particles, each pair of CP subunits is thought to bind a single calcium ion through interactions with three residues of one subunit and two residues of a neighboring subunit. These five residues comprise the putative calcium-binding site (CBS). The putative CBS and hinge are adjacent to one another. Mutations were introduced into the putative CBS or hinge in an effort to further determine the biological functions of TCV CP. One putative CBS mutant, TCV-M32, exhibited wild-type cell-to-cell movement but failed to move systemically in Nicotiana benthamiana, and particles were not detected. Another putative CBS mutant, TCV-M23, exhibited deficient cell-to-cell movement but particles accumulated in isolated protoplasts. Two other putative CBS mutants, TCV-M22 and -M33, showed wild-type cell-to-cell and systemic movement but elicited mild systemic symptoms that were somewhat delayed. All of the hinge mutants exhibited wild-type movement but some elicited non-wild-type symptoms. Point mutations in the putative CBS or hinge appear to alter virus-ion interactions, secondary structure, or particle conformation, thereby affecting interactions between the CP and plant hosts.

Accumulation of helper component/proteinase and coat protein of turnip mosaic virus in intact plants

The helper component/proteinase (HC/Pro) protein of turnip mosaic virus (TuMV) was fused with glutathione S-transferase (GST) and expressed as a fusion protein in Escherichia coli. The quality of antiserum raised against the GST-HC/Pro fusion protein was compared to that of antiserum raised against coat protein (CP) by image analyser. The result showed that these antisera were of similar quality. Then the both antisera were used to follow the time course of accumulation of HC/Pro protein and CP in intact TuMV-infected leaves. CP appeared first at day 3 post inoculation (p.i.) and gradually accumulated in uninoculated upper leaves, whereas HC/Pro protein appeared first at day 4 p.i., accumulated up to day 7 p.i. and then gradually decreased. Potyvirus proteins are encoded by a single translation unit spanning most of the genome and are presumably synthesized in equimolar ratios. Therefore, the reduced accumulation of HC/Pro protein in relation to CP at one month p.i. in infected plants is presumed to be the result of its degradation.

Limitations to tobacco mosaic virus infection of turnip

Turnip vein-clearing virus (TVCV) and tobacco mosaic virus (TMV) represent subgroups of tobamoviruses infecting cruciferous and solanaceous plants, respectively. To identify adaptations that may have been necessary in the evolution of the TVCV subgroup from a TMV-like ancestor, the infection of turnip plants by TMV and by chimeras between TMV and TVCV was explored. TMV accumulated at spatially limited sites on inoculated turnip leaves as determined by leaf skeleton hybridization. A plasmid DNA containing a complete TVCV cDNA, when transcribed in vitro, produced RNA that was infectious to tobacco and turnip plants. TVCV-TMV chimeric genomes with junctions within coding regions were not infectious to tobacco, though the movement protein (MP) chimera was infectious to tobacco with a TMV MP transgene. Reciprocal chimeras with junctions between genes were infectious to tobacco. TVCV with a TMV MP gene infected turnips. The other tested chimeras were not detected in non-inoculated leaves, but were found in the inoculated leaves. Thus, the TMV MP is not responsible for the limitation of TMV spread in turnips.

Asymmetric infectivity of pseudorecombinants of cabbage leaf curl virus and squash leaf curl virus: implications for bipartite geminivirus evolution and movement

The bipartite geminiviruses squash leaf curl virus (SqLCV) and cabbage leaf curl virus (CLCV) have distinct host ranges. SqLCV infects a broad range of plants within the Cucurbitaceae, including pumpkin and squash, and CLCV has a broad host range within Brassicaceae that includes cabbage and Arabidopsis thaliana. Despite this, the genomic A components of these viruses share a high degree of sequence identity, particularly in the gene encoding the replication protein AL1, and their common regions are 77% identical. However, there is unexpected sequence diversity in the common regions of the two CLCV genomic A and B components, these being only 80% identical. Based on these sequence similarities, we investigated the host range properties of pseudorecombinants of SqLCV and CLCV. We found that in a pseudorecombinant virus consisting of the A component of CLCV and the B component of SqLCV, both components replicated in tobacco protoplasts, and this pseudorecombinant was infectious and caused systemic disease in Nicotiana benthamiana, a common host to all bipartite geminiviruses. However, this pseudorecombinant did not move systemically in pumpkin or Arabidopsis, despite the demonstrated replication compatibility of the genome components. As a result of the greater sequence differences between the common regions, the pseudorecombinant of SqLCV A and CLCV B components neither replicated the CLCV B component nor systemically infected any of the hosts tested. These findings demonstrate that for different geminiviruses with distinct host ranges, the replication origins and AL1 proteins can be sufficiently similar to permit infectious pseudorecombinants, but replication alone is not sufficient to cause systemic disease, and host range may ultimately be limited at the level of movement. The results of this study further suggest that CLCV is an evolving virus that can provide insights into how new bipartite geminiviruses arise from mixed infections.

Preservation of plant cell ultrastructure during immunolocalization of virus particles

Most immunoelectron microscopy techniques used for ultrastructural analyses of virus-infected plant tissues significantly compromise cellular membranous structures as well as overall contrast and resolution of the image. Here, we describe a protocol which avoids these flaws but retains full antigenicity of the sample. A direct comparison of the conventional and the improved electron immunostaining procedures is presented using tobacco and Arabidopsis thaliana plants infected with turnip vein clearing virus.

Requirement of cauliflower mosaic virus open reading frame VI product for viral gene expression and multiplication in turnip protoplasts

Cauliflower mosaic virus (CaMV) open reading frame (ORF) VI product (P6) has been shown to be the major constituent of viral inclusion body, to function as a post-transcriptional transactivator, and to be essential for infectivity on whole plants. Although these findings suggest that P6 has an important role in viral multiplication, it is unknown whether P6 is required for viral multiplication in a single cell. To address this question, we transfected turnip protoplasts with an ORF VI frame-shift (4 bp deletion) mutant (pCaFS6) of an infectious CaMV DNA clone (pCa122). The mutant was uninfectious. Co-transfection of plasmids expressing P6 complemented the mutant. Overexpression of P6 elevated the infection rate in co-transfection experiments with either pCa122 or pCaFS6. This would have been achieved by elevating the level of pregenomic 35S RNA, a putative polycistronic mRNA for ORFs I, II, III, IV and V, and by enhancing the accumulation of these five viral gene products. When CaMV ORFs I, II, III, IV and V were expressed from monocistronic constructs in which each of the ORFs was placed just downstream of the 35S promoter, the accumulation of ORF III, IV and V products depended on the co-expression of P6. The accumulation of ORF I and II products was not detected, even in the presence of P6. These results suggest that P6 is involved in the stabilization of other viral gene products as well as in the activation of viral gene expression, and thus, is a prerequisite for CaMV multiplication.

Analysis of sequences and predicted structures required for viral satellite RNA accumulation by in vivo genetic selection

In vivo genetic selection was used to study the sequences and structures required for accumulation of subviral sat-RNA C associated with turnip crinkle virus (TCV). This technique is advantageous over site-specific mutagenesis by allowing side-by-side selection from numerous sequence possibilities as well as sequence evolution. A 22 base hairpin and 6 base single-stranded tail located at the 3'-terminus of sat-RNA C were previously identified as the promoter for minus strand synthesis. Approximately 50% of plants co-inoculated with TCV and sat-RNA C containing randomized sequence in place of the 22 base hairpin accumulated sat-RNA in uninoculated leaves. The 22 base region differed in sat-RNA accumulating in all infected plants, but nearly all were predicted to fold into a hairpin structure that maintained the 6 base tail as a single-stranded sequence. Two additional rounds of sat-RNA amplification led to four sequence family 'winners', with three families containing multiple variants, indicating that evolution of these sequences was occurring in plants. Three of the four sequence family winners had the same 3 bp at the base of the stem as wild-type sat-RNA C. Two of the winners shared 15 of 22 identical bases, including the entire stem region and extending two bases into the loop. These results demonstrate the utility of the in vivo selection approach by showing that both sequence and structure contribute to a more active 3'-end region for accumulation of sat-RNA C.

Identification of a 37 kDa plant protein that interacts with the turnip mosaic potyvirus capsid protein using anti-idiotypic-antibodies

Experimental data are provided for the presence of a plant protein that interacts with the capsid protein (CP) of turnip mosaic potyvirus (TuMV). The receptor-like protein was identified by exploiting the molecular mimicry potential of anti-idiotypic antibodies. A single-chain Fv molecule derived from the monoclonal antibody 7A (Mab-7A), which recognizes the CP of TuMV, was produced in Escherichia coli and the recombinant protein was used to raise rabbit antibodies. The immune serum reacted with Mab-7A but not with a monoclonal antibody of the same isotype, indicating that anti-idiotypic antibodies were produced. These anti-idiotypic antibodies recognized a 37 kDa protein from Lactuca sativa. Complex formation between the anti-idiotypic antibodies and the plant protein was inhibited by the CP of TuMV which indicates that the plant protein interacts with the viral protein. The 37 kDa protein was localized in chloroplasts and was detected in other plant species.

Accumulation kinetics of viral gene products in cauliflower mosaic virus-infected turnip protoplasts

The expression of cauliflower mosaic virus (CaMV) genes was studied in a turnip protoplast system. Six CaMV-encoded gene products were detected in infected turnip protoplasts by means of Western blotting. The infected turnip protoplasts showed different patterns of protein accumulation; e.g. an open reading frame (ORF) I-encoded movement protein, an ORF V-encoded reverse transcriptase and an ORF VI-encoded posttranscriptional transactivator representing the early accumulated proteins, an ORF II-encoded aphid transmission factor and an ORF IV-encoded coat protein the late accumulated proteins and an ORF III-encoded DNA binding protein the intermediate protein. The results suggest that the expression of CaMV genes is differentially regulated.

Virion protein sequence variation among Australian isolates of turnip yellow mosaic tymovirus

The virion protein genes, and 3' untranslated regions, of six variants of turnip yellow mosaic tymovirus (TYMV) that produced different symptoms in their native host Cardamine robusta and in Chinese cabbage plants, have been sequenced. The sequences have been compared with each other, and with the same region of the pBL-16 clone of the Blue Lake isolate of TYMV. The sequences of the virion protein genes differed by a mean of 1.89% (range 0-2.82%), and the encoded proteins by a mean of 1.71% (range 0-3.17%). The nucleotide differences were confined to the 5'-most 60% of the gene, whereas there were amino acid differences only among residues 12 to 29 and residue 102 (numbered from the N-terminus) of the virion protein involving only hydrophobic residues at the surface of the protein. The amino acid and nucleotide differences between the seven isolates did not correlate with differences in the symptoms they caused, but confirmed earlier estimates of genetic variability in the wild populations of the virus.

Mapping regions of the cauliflower mosaic virus ORF III product required for infectivity

The open reading frame (ORF) III product (PIII) of the pararetrovirus cauliflower mosaic virus (CaMV) has nucleic acid-binding properties in vitro, but its biological role is not yet determined. ORF III is closely linked to ORF II and overlaps ORF IV out of frame in the CaMV genome. A new CaMV-derived vector (Ca delta) devoid of ORF III and containing unique restriction sites between ORFs II and IV was designed. Introduction of the wild-type CaMV ORF III into Ca delta results in a clone (Ca3) infectious in turnip plants. Truncated or point-mutated versions of ORF III were then inserted into Ca delta and tested in vivo. Inoculation of the different mutants into turnip revealed that the four C-terminal amino acid residues of PIII are dispensable for infectivity as well as an internal domain (amino acids 61 to 80). Taken together the results show that PIII possesses a functional two-domain organization. Moreover, the CaMV PIII function(s) cannot be replaced either by the PIII protein of another caulimovirus, the figwort mosaic virus, or by the P2 protein of the cacao swollen shoot badnavirus, a member of the second plant pararetrovirus group.

Turnip yellow mosaic virus isolates with experimentally produced recombinant virion proteins

The consensus secondary structure of the virion proteins (VPs) of tymoviruses was predicted from their amino acid sequences using a combination of computer methods: profile alignment, hydrophobicity moment and 'PredictProtein'. All methods predicted that they were eight-stranded anti-parallel beta-barrels with two alpha-helical regions. The predicted structure was used to design recombinants of turnip yellow mosaic virus (TYMV) in which selected parts of its VP were replaced with homologous regions of belladonna mottle virus (BeMV) in a cDNA clone encoding the genome of TYMV. Six of ten such recombinants were fully viable and most gave symptoms in Chinese cabbage indistinguishable from those of TYMV, although they did not always infect plants systemically and none infected hosts of BeMV or of other tymoviruses. A TYMV recombinant with the N-terminal part of its VP replaced with the E71 epitope of Plasmodium falciparum was also viable, but others with the same region replaced with the V3 region of the lentivirus human immunodeficiency virus type 1 were not. Epitope analysis of antisera prepared against the virions of parental TYMV and some of the recombinants showed that, although the N terminus of the VP is immunogenically dominant, it is not exposed at the surface of the virion, a finding confirmed by comparing the electrophoretic mobilities of the virions. The recently published structure of the TYMV VP determined by X-ray crystallography confirms the accuracy of the predicted secondary structure of the VP, and hence the utility of the methods used.

A functional role for the conserved protonatable hairpins in the 5' untranslated region of turnip yellow mosaic virus RNA

The 5' untranslated region (UTR) of the RNA of several tymoviruses contains conserved hairpins with protonatable internal loops, consisting of C-C and C-A mismatches (K. Hellendoorn, P. J. A. Michiels, R. Buitenhuis, and C. W. A. Pleij, Nucleic Acids Res. 24, 4910-4917, 1996). Here, we present a functional analysis of the 5' UTR of turnip yellow mosaic virus (TYMV) RNA, which contains two protonatable hairpins with nearly identical internal loops. Mutations were introduced in an infectious cDNA clone, and T7 RNA transcripts were used to infect Chinese cabbage plants. Different symptoms were observed for the various mutants, pointing to a functional role of the C-C and C-A mismatches in the hairpins of the 5' UTR. The replication of the virus is influenced by the mutations made, while in vitro translation studies showed that the expression of the two overlapping reading frames of TYMV is not influenced by the secondary structure of the leader. Various mutants were propagated for up to five serial passages of infection, and the sequence of the 5' UTR was determined. This resulted in virus RNA with new non-wild-type sequences that produced the wild-type phenotype in infected plants. Remarkably, in all cases C-C or C-A mismatches were introduced. The internal loop of the 5'-proximal hairpin seems to be more important for the viral life cycle than that of the second hairpin. A deletion of 75% of the leader, including the two hairpins, resulted in a virus that was deficient in viral spread. Since the ratio between filled and empty capsids was changed drastically by this mutation, a role of the 5' UTR in viral packaging is proposed.

Complementation of a potato virus X mutant mediated by bombardment of plant tissues with cloned viral movement protein genes

Microprojectile bombardment was used to examine the transport function of the 25 kDa movement protein (MP) encoded in the triple gene block of potato virus X (PVX). A 25 kDa MP-defective full-length cloned PVX genome carrying a beta-glucuronidase (GUS) reporter gene was co-bombarded with 35S promoter constructs containing either the 25 kDa MP gene of wild-type PVX, the MP gene of either of two tobamoviruses (tomato mosaic virus or crucifer tobamovirus), red clover necrotic mosaic dianthovirus (RCNMV) or brome mosaic bromovirus (BMV). When inoculated alone, the MP-defective PVX was unable to move out of the inoculated cell, as visualized by in situ staining for GUS activity. However, cell-to-cell movement of the mutant PVX genome was restored by co-inoculation with 35S constructs containing the MP cDNA of PVX, either tobamovirus or RCNMV. The BMV MP construct did not complement movement of the defective PVX. These results show that co-bombardment of cDNA of an MP-defective virus with plasmids designed to express MP of other viruses could be used as a fast and simple method for transcomplementation experiments.

Characterization of chimeric turnip yellow mosaic virus genomes that are infectious in the absence of aminoacylation

Previous experiments have characterized the chimeric genome TYMC-TMVPSK, in which the 3'-tRNA-like structure of turnip yellow mosaic virus (TYMV) was replaced by 3' sequences from tobacco mosaic virus. This genome accumulated in turnip protoplasts to a level about 3% of wild type, but was not infectious on plants. In the present study, TYMV sequences introduced into the anticodon loop and amino acid acceptor arm of the 3' region of this chimera led to three- to fourfold increases in viral accumulation. Two such modified chimeric genomes gave rise to stable infections in plants. After further passaging in plants and the accumulation of minor sequence changes in the 3' terminal region, the resultant viruses, TYMC-XX and TYMC-YY, were highly infectious. Viral accumulations in protoplasts were about 40% of wild type on the basis of coat protein levels, and virion yields in plants were about 0.1 mg/g leaf. Extensive assays failed to detect aminoacylation of these genomic RNAs in vitro, but they were active substrates for wheat germ. CCA nucleotidyltransferase. In separate experiments, the 3'-tRNA-like structure of TYMV RNA was replaced by the 3' terminal 96 nucleotides from erysimum latent tymovirus RNA, resulting in a genome that was infectious to plants (isolate TYMC-H). This chimeric virus produced similar symptoms and virion yield in plants as TYMC-XX and -YY, although accumulations of coat protein in protoplasts were 13% of wild type. The viral RNA was a poor substrate for CCA nucleotidyltransferase and could not be aminoacylated. TYMC-XX, -YY, and -H are the first TYMV replicons known to amplify efficiently and infect plants in the absence of aminoacylation. Their viability suggests that other properties can compensate for the absence of aminoacylation.

Expression of functional elements inserted into the 35S promoter region of infectious cauliflower mosaic virus replicons

We describe experiments directed towards development of cauliflower mosaic virus (CaMV) replicons for propagation of functional elements during infection of plants. Modifications and inserts were introduced into replaceable domains associated with the 35S promoter. The 35S enhancer (-208 to -56) was found to potentiate promoter activity when in reverse orientation sufficient to establish systemic infection. However, replacement of the 35S enhancer with that from the nos promoter caused loss of infectivity. A 31 bp oligonucleotide containing a polypurine tract specifying initiation of CaMV plus strand DNA synthesis was inserted into a 35S enhancer deletion mutant and propagated in plants. Analysis of progeny DNA showed the presence of an additional discontinuity at its new location in the 35S enhancer, indicating that the artificial primer had functioned correctly in an ectopic site. An intron and flanking sequences from the RNA leader of the Arabidopsis phytoene desaturase (pds) gene, when inserted into the 35S enhancer in forward orientation was very efficiently spliced during infection. The CaMV replicon carrying the pds gene fragment produced unusual infection characteristics, with plants showing early symptoms and then recovering. We conclude that infectious CaMV replicons can be used to carry a variety of elements that target both viral and host functions.

The complete nucleotide sequence of turnip mosaic virus RNA Japanese strain

The complete nucleotide sequence of the RNA genome of turnip mosaic virus Japanese strain (TuMV-J) has been determined from five overlapping cDNA clones and by direct sequencing of viral RNA. The RNA sequence was 9833 nucleotides in length, excluding a 3' terminal poly(A) tail. An AUG triplet at position 130-132 was assigned as the initiation codon for the translation of the genome size viral polyprotein which would consist of 3164 amino acid residues. Interestingly, a different amino acid sequence (continuous twenty amino acids) within the cytoplasmic inclusion protein between TuMV-J and Canadian strain of TuMV was observed, caused by an insertion and a deletion of nucleotides.

Changes in locations of crossover sites over time in de novo generated RNA recombinants

Recombinant RNAs generated in plants 3 weeks postinoculation with turnip crinkle virus (TCV) genomic RNA and an associated satellite RNA, sat-RNA D, have a majority of TCV crossover sites in a 24-nucleotide repeat (motif IIIA/IIIB) that forms part of a stable hairpin (Carpenter et al., 1995, J. Mol.Biol. 245, 608-622). To determine if parameters other than nucleotide sequence in the crossover region affect junction site selection, recombinants were assayed at various times postinoculation of plants and protoplasts. Populations of recombinants became progressively shorter in plants and larger in protoplasts. Levels of inoculated transcript and age of the plant were not substantial factors in the shifts in crossover site locations. The two most commonly cloned recombinant species were not amplified to detectable levels in protoplasts, suggesting that these molecules are not viable templates for replication. These results suggest that recombination between sat-RNA D and TCV is a very frequent event, and populations of recombinants are likely generated de novo in each infected cell and represent the original recombinant molecules rather than progeny of such molecules. Therefore, factors other than simple selection for recombinants that are more fit to replicate are probably responsible for the differences in junction sites in populations of sat-RNA D/TCV recombinants.

Classification of turnip mosaic virus isolates according to the 3'-untranslated region

The 3'-untranslated region (3'UTR) of five isolates of turnip mosaic virus (TuMV) from United Kingdom, Canada, Greece, the Czech Republic and from Uzbekistan were sequenced and compared with another nine previously sequenced TuMV isolates. All the isolates had 209 nucleotides long 3'UTR, with the exception of the Uzbekistan isolate, which had one-base deletion at nucleotide (nt) position 162. Phylogenetic analysis identified three clusters of related isolates. The clusters correlated with secondary folding of the 3'UTRs, partially with the source host plant of the isolates but not with their geographical origin.

The turnip yellow mosaic virus tRNA-like structure cannot be replaced by generic tRNA-like elements or by heterologous 3' untranslated regions known to enhance mRNA expression and stability

The tRNA-like structure (TLS) at the 3' end of the turnip yellow mosaic virus genome was replaced with heterologous tRNA-like elements, and with a poly(A) tail, in order to assess its role. Replacement with the valylatable TLSs from two closely related tymoviruses resulted in infectious viruses. In contrast, no systemic symptoms on plants, and only low viral accumulations in protoplasts, were observed for three chimeric genomes with 3' sequences known to enhance mRNA stability and translatability. One of these chimeras had a poly(A) tail, and the others had the TLS with associated upstream pseudoknot tracts from the 3' ends of brome mosaic and tobacco mosaic viruses. The latter two chimeric RNAs were shown to be appropriately folded by demonstrating their aminoacylation in vitro with tyrosine and histidine, respectively. The results show that enhancement of genome stability or gene expression is not the major role of the turnip yellow mosaic virus TLS. The major role is likely to be replicational, dependent on features present in tymoviral TLSs but not in generic tRNA-like structures.

Arabidopsis thaliana expressing the cauliflower mosaic virus ORF VI transgene has a late flowering phenotype

Expression of open reading frame (ORF) VI of cauliflower mosaic virus (CaMV) in transgenic Arabidopsis thaliana caused a typical syndrome characterised by leaf chlorosis, vein clearing, plant stunting and reduced fertility. In addition and in comparison to untransformed controls we observed the formation of much larger rosettes of leaves combined with much later flowering and more extensive tillering. In these aspects, the ORF VI transgenic plants resembled late flowering mutants. All these phenotypes correlated with expression of ORF VI in three lines of transgenic plants which were produced independently, with different Ti-plasmid derived vectors and with different selective markers. The late flowering phenotype cosegregated with the transgene.

Sequence comparison and classification of beet luteovirus isolates

Three distinct sequence groups were found among partial nucleotide sequences of 38 isolates of beet western yellows virus (BWYV) and beet mild yellowing virus (BMYV) from Europe, Iran and the USA. The first group contains both sugar beet and oilseed rape specific isolates, and the differentiating characteristic linked to this host range specificity are 2 single base pair changes in a 1,200 nucleotide region of the genome. It is proposed that the European BWYV strains that can be transferred at low frequency between rape and sugar beet belong to this group. Also belonging to this group are the published BWYV sequences of Veidt et al. and of the California BWYV-ST9 isolate. The second group contains mostly rape-derived isolates which have an intergenic region highly distinct from that of group-1 isolates but similar polymerase and coat protein regions. It is proposed that the rape-specific BWYV isolates which cannot be transmitted to sugar beet belong to this group. The third group contains mostly beet-specific isolates from Southern Europe and Iran, and may be adapted to the Mediterranean climate and flora. It is distinct from groups 1 and 2 in all three genome regions investigated and its polymerase and intergenic regions are as much related to those of potato leafroll virus (PLRV) and curcurbit aphid borne yellows virus (CABYV) as they are to those of group-1 and group-2. On the basis of sequence similarities and established nomenclature it is proposed to use BWYV for groups 1 and 2 (BWYV-1 and BWYV-2 respectively) and to use BMYV for group-3 isolates, which are distinct enough from the other two groups to merit a separate nomenclature.

Immunodetection, expression strategy and complementation of turnip crinkle virus p28 and p88 replication components

The plus-sense RNA genome of turnip crinkle virus (TCV) encodes at its 5' end a 28-kDa protein of unspecified function. Readthrough suppression of the p28 stop codon allows for the production of an 88-kDa product which is required for genome replication. Immunological analysis of the expression of p28 and p88 demonstrated that: (i) the genome directs the synthesis of polypeptides of approximately 28 and 88 kDa, (ii) the 88-kDa protein is immunologically related to p28, consistent with p88 being a readthrough product, and (iii) p28, but not p88, is detectable in vivo. An in vivo assay, in which readthrough is linked to the expression of a beta-glucuronidase reporter gene, showed that readthrough of the p28 amber stop codon occurs with an efficiency of approximately 1%. A similar efficiency of readthrough was observed when an altered context from the nonviable TCV mutant, mA2, containing a disrupted secondary structure (FfFa) spanning the p28 termination codon, was tested. This result suggests that the defective phenotype of mA2 is likely not linked to an alteration in readthrough efficiency. Additional studies demonstrated that complementation occurs in coinoculations with two nonviable TCV mutants, RT and APA, which are unable to express either p28 or p88, respectively. This result verifies that p28 is essential for TCV genome replication and provides the first definitive evidence for the role of a 5'-proximal open reading frame for any member of the family Tombusviridae.