Lettuce mosaic virus pathogenicity determinants in susceptible and tolerant lettuce cultivars map to different regions of the viral genome.

Full-length infectious cDNA clones were constructed for two isolates (LMV-0 and LMV-E) of Lettuce mosaic virus (LMV), a member of the genus Potyvirus. These two isolates differ in pathogenicity in susceptible and tolerant-resistant lettuce cultivars. In susceptible plants, LMV-0 induces mild mosaic symptoms, whereas LMV-E induces severe stunting, leaf deformation, and a necrotic mosaic. In plants carrying either of the two probably allelic recessive resistance genes mol1 or mol2, LMV-0 is restricted partially to the inoculated leaves. When a systemic invasion does occur, however, symptoms fail to develop. LMV-E overcomes the protection afforded by the resistance genes, resulting in systemic mosaic symptoms. Analysis of the behavior of recombinants constructed between the two virus isolates determined that the HC-Pro protein of LMV-E causes the severe stunting and necrotic mosaic induced by this isolate in susceptible cultivars. In contrast, the ability to overcome mol resistance and induce symptoms in the resistant-tolerant cultivars was mapped to the 3' half of the LMV-E genome. These results indicate that the ability to induce severe symptoms and to overcome the protection afforded by the recessive genes mol1 or mol2 are independent phenomena.

Comparison of the complete nucleotide sequences of two isolates of lettuce mosaic virus differing in their biological properties.

The complete nucleotide sequences of the genomic RNAs of the 0 and E isolates of lettuce mosaic potyvirus (LMV) have been determined. These two isolates differ by their behavior towards two lettuce resistance genes and by their seed transmission properties. LMV-0 is unable to induce disease in lettuce carrying either one of the mol1 and mol2 recessive resistance genes, whereas LMV-E is able to induce disease in the same plants. The genomes of these two isolates are 10080 nucleotides (nt) in length, excluding the poly(A) tract, and encode polyproteins of 3255 amino acids (aa). The open reading frame is flanked by a 5' non-coding region of 103 nt and a 3' non-coding region of 212 nucleotides. Ten proteins were predicted. The P3 protein, with 377 aa, is the longest potyviral P3 protein characterized to date while the P1 protein, with 437 aa, is among the longest P1 proteins reported. Sequence comparisons between the two isolates demonstrated only limited sequence difference. The overall nucleotide and amino acid sequence identities between LMV-0 and LMV-E are 94 and 97% respectively. The greatest variability occurs in the P1 and in the variable N-terminal region of the coat protein, while the NIa protease domain, the NIb protein, the C-terminus of the helper component protease and the 3' non-coding region are extensively conserved. While this sequence analysis does not allow direct identification of determinants involved in the resistance breaking or in the seed transmissibility properties, these data are a first step towards the characterization of these determinants.

Biological and molecular variability of lettuce mosaic virus isolates.

ABSTRACT Lettuce mosaic potyvirus (LMV) causes severe disease of commercial lettuce crops. LMV isolates show wide biological variability, particularly in their ability to overcome the resistance genes described in Lactuca sativa. For a better understanding of the molecular interaction between lettuce and LMV, biological and molecular characterization of a collection of 10 LMV isolates known to differ in virulence or aggressiveness was performed. The ability of these isolates to overcome the resistance genes was reevaluated under standardized conditions. To study the molecular variability of LMV, an immunocapture-reverse transcription-poly-merase chain reaction technique, coupled with direct sequencing, was used to obtain nucleotide sequence data from three short regions of the LMV genome. Clustering analysis was performed and compared to the biological properties of the 10 isolates. Three groups of LMV isolates were discriminated based on the molecular data. These groups appear to correlate with the geographic origin of the isolates rather than with their pathogenicity. Sequence comparison with California isolates clearly showed that the California isolates are related to the western European isolates, raising the possibility of past exchanges of LMV between western Europe and California.

Complete nucleotide sequence of a putative new cytorhabdovirus infecting lettuce.

The full-length nucleotide sequence of the genomic RNA of a new cytorhabdovirus infecting lettuce was determined. Six open reading frames were found in the antigenomic sequence of the 12,926-nt negative-sense viral RNA genome. The genomic organisation was similar to that of lettuce necrotic yellows virus (LNYV), the type member of the genus Cytorhabdovirus: 3'-N-P-3-M-G-L-5', where N is the capsid protein gene, P the putative phosphoprotein gene, 3 a gene coding for a putative protein of unknown function, M the putative matrix protein gene, G the glycoprotein gene, and L the putative polymerase gene. Amino acid sequence comparison with the corresponding sequences of other rhabdoviruses revealed the closest relationship to LNYV, with identities ranging from 41% for the matrix proteins and 65% for the L polymerase proteins. These results indicate that this virus may be a member of a new cytorhabdovirus species, for which the name Lettuce yellow mottle virus (LYMoV) is proposed.

Characterization of the genome of cacao swollen shoot virus.

Cacao swollen shoot disease has been known to be caused by a small non-enveloped bacilliform virus for more than 25 years. Purification using a combination of celite filtration, polyethylene glycol concentration and sucrose density gradient centrifugation has yielded concentrated preparations of purified cacao swollen shoot virus (CSSV). Results of nuclease sensitivity tests indicated that the CSSV genome consists of dsDNA which has two single-stranded regions. The approximate size of CSSV DNA calculated from restriction enzyme digests is 7.4 kbp. It is very likely that CSSV is a member of the commelina yellow mottle virus group.

Nucleotide sequence of cucumber mosaic virus-associated RNA 5.

The complete nucleotide sequence of cucumber mosaic virus-associated (satellite) RNA 5 (CARNA 5) strain D has been determined. The molecule is 335 residues long and is capped at its 5' extremity. There were minor variations in the sequence of different preparations of the satellite RNA. Otherwise, no unusual features of secondary structure or sequence are present. CARNA 5 (D) contains a number of possible initiation and termination codons for protein synthesis. Study of CARNA 5 isolated from other strains of cucumber mosaic virus suggests that sequence variation of the molecule from one strain to another is very limited.

Characterization, nucleotide sequence and genome organization of leek white stripe virus, a putative new species of the genus Necrovirus.

White stripe is a disease affecting leek in France with which an isometric virus c. 30 nm in diameter is associated. The most evident symptom is the presence of white stripes on the leaves extending to the stem. Attempts to demonstrate transmission through the soil by sowing or transplanting leek in contaminated soil were unsuccessful. The virus was transmitted by sap inoculation to a narrow range of herbaceous hosts, all of which were infected only locally. Virus purification was from infected leek tissues, where it accumulated in large amounts, as demonstrated by ultrastructural observations. RNA was extracted from purified virus preparations and cDNA clones were prepared. The complete nucleotide sequence of the viral RNA was determined: The genome is 3,662 nucleotides long and contains five open reading frames (ORFs). The first (ORF 1) encodes a putative translation product of M(r) 23,803 (p24) and read through of its amber stop codon results in a protein of M(r) 82,625 (p83) (ORF 2). ORF 3 and ORF 4 encode two small polypeptides of M(r) 11,280 (p11) and M(r) 6,261 (p6), respectively. ORF 5 encodes the capsid protein of M(r) 27,460 (p27). The genome organization and sequence alignments with the corresponding products of necroviruses suggest that the virus isolated from leek is a new species in the genus Necrovirus, for which the name of leek white stripe virus (LWSV) is proposed.

Nucleotide sequence of the 3' terminal region of lettuce mosaic potyvirus RNA shows a Gln/Val dipeptide at the cleavage site between the polymerase and the coat protein.

DNA complementary to the 3' terminal 1651 nucleotides of the genome of the common strain of lettuce mosaic virus (LMV-O) has been cloned and sequenced. Microsequencing of the N-terminus enabled localization of the coat protein gene in this sequence. It showed also that the LMV coat protein coding region is at the 3' end of the genome, and that the coat protein is processed from a larger protein by cleavage at an unusual Q/V dipeptide between the polymerase and the coat protein. This is the first report of such a site for cleavage of a potyvirus polyprotein, where only Q/A, Q/S, and Q/G cleavage sites have been reported. The LMV coat protein gene encodes a 278 amino acid polypeptide with a calculated Mr of 31,171 and is flanked by a region which has a high degree of homology with the putative polymerase and a 3' untranslated region of 211 nucleotides in length. Percentage of homology with the coat protein of other potyviruses confirms that LMV is a distinct member of this group. Moreover, amino acid homologies noticed with the coat protein of potexvirus, bymovirus, and carlavirus elongated plant viruses suggest a functional significance for the conserved domains.

Nucleotide sequence of beet western yellows virus RNA.

The nucleotide sequence of the genomic RNA (5641 nt) of beet western yellow virus (BWYV) isolated from lettuce has been determined and its genetic organization deduced. The sequence of the 3'terminal 2208 nt of RNA of a second BWYV isolate, obtained from sugarbeet, was also determined and was found to be very similar but not identical to that of the lettuce isolate. The complete sequence of BWYV RNA contains six long open reading frames (ORFs). A cluster of three of these ORFs, including the coat protein cistron, display extensive amino acid sequence homology with corresponding ORFs of a second luteovirus, the PAV isolate of barley yellow dwarf virus (BYDV) (1,2). The ORF corresponding to the putative viral RNA-dependant RNA polymerase, on the other hand, resembles that of southern bean mosaic virus. There is circumstantial evidence that expression of the BWYV RNA polymerase ORF may involve a translational frameshift mechanism. The ORF immediately following the coat protein cistron may be translated by in-frame readthrough of the coat protein cistron amber termination codon. Similar mechanisms have been proposed for expression of the corresponding ORFs of BYDV(PAV) (1).

Nucleotide sequence and genomic organization of cacao swollen shoot virus.

Cacao swollen shoot virus is classified as a badnavirus based on its nonenveloped, bacilliform particle morphology and double-stranded DNA genome. A complete copy of the genome was cloned into a plasmid vector and the sequence was determined from 75 overlapping subclones covering both strands. The genome contains 7161 base pairs and possesses an intergenic region and five putative open reading frames (ORF) capable of coding for proteins > 10 kDa. All of the ORFs are present on the plus-strand. ORF 1 (17 kDa) and ORF 2 (14 kDa) encode proteins of unknown function. The large ORF 3 (211 kDa) encodes a polyprotein that can be divided into three regions. Based on distant homologies with viral movement proteins, region 1 may encode a protein involved in cell-to-cell spread, while region 2 encodes the viral capsid protein. Region 3 contains consensus sequences for viral aspartyl proteinase, reverse transcriptase, and ribonuclease H characteristic of pararetroviruses. The last two ORFs (13 and 14 kDa) overlap ORF 3 and are not present in the other badnaviruses described.

Coat protein gene sequences of garlic and onion isolates of the onion yellow dwarf potyvirus (OYDV).

Partial genomic sequences from an unknown garlic potyvirus and from an onion isolate of the onion yellow dwarf potyvirus (OYDV) were obtained. Comparison of the deduced amino acid sequences showed a similarity of 88% between the respective viral coat proteins. The garlic potyvirus coat protein was expressed in E. coli cells, purified, and subjected to Western blot analysis using antibodies raised against different garlic-infecting viruses. The expression protein was consistently recognised by anti-OYDV antibodies and did not react with antibodies specific for leek yellow stripe potyvirus (LYSV), garlic common latent carlavirus (GCLV) and shallot latent carlavirus (SLV). Besides, the garlic potyvirus coat protein was obtained as a fusion protein and used as antigen to produce polyclonal antibodies. These antibodies reacted with purified OYDV virions, but failed to recognise LYSV particles. In the light of this evidence the garlic potyvirus was identified as the garlic strain of OYDV.

Construction of full-length cDNA clones of lettuce mosaic virus (LMV) and the effects of intron-insertion on their viability in Escherichia coli and on their infectivity to plants.

A full length cDNA copy of the genomic RNA of lettuce mosaic virus (LMV) was constructed under the control of an enhanced CaMV 35S promoter and of the NOS terminator. This construct was found infectious when inoculated to lettuce plants. The intron II of the bean nitrite reductase gene was engineered into the LMV FL cDNA in order to relieve possible deleterious effects of viral sequences to Escherichia coli cells and to evaluate the effects of the presence of the intron on the FL cDNA infectivity. The intron-less FL cDNA was found to be as stable as its intron-containing counterpart in E. coli. Sequence analysis of progeny RNA derived from plants inoculated with the intron-containing FL cDNA demonstrated that the inserted intron was perfectly spliced out. The symptoms induced in lettuce by either the intron-less or the intro-containing constructs were identical to those caused by the wild-type virus. However a slight delay in the establishment of infection in lettuce and a more obvious lag in Nicotiana benthamiana were observed with the intron-containing FL cDNA.

Identification of beet western yellows luteovirus genes implicated in viral replication and particle morphogenesis.

The roles in replication and viral assembly of different beet western yellows luteovirus gene products were investigated in Chenopodium quinoa protoplasts using mutated transcripts. Of the six long open reading frames (ORFs) present on the viral RNA, only ORFs 2 and 3, which encode proteins containing conserved putative replicase domains, were essential for replication. Various deletions in the 3' part of the genome within ORFs 4, 5, and 6 did not affect viral replication. Analysis of the progeny of those mutants capable of replication showed that virus particles were produced in protoplasts infected with transcripts modified in ORFs 1, 5, or 6 but not with transcripts unable to produce coat protein, encoded by ORF 4.

Nucleotide sequence of the 3' terminal region of the genome of four lettuce mosaic virus isolates from Greece and Yemen.

Lettuce mosaic virus (LMV) is an economically important Potyvirus causing a severe disease of commercial lettuce crops. Based on molecular data, three phylogenetic groups of isolates have previously been discriminated, reflecting their geographical origin (Western Europe-California, Greece, or Yemen). Sequence information for the entire coat protein domain was only available for one of the Western Europe-California phylogenetic group. We have now sequenced the 3' terminal region of the genome LMV-Gr4, -Gr5 and -GrB, isolates which belong to the Greek phylogenetic group and of LMV-Yar, the sole known representative of the third LMV phylogenetic group. The region sequenced encodes the last 62 amino-acids of the polymerase and the entire coat protein of the four isolates, plus the 3' non-translated region of LMV-Gr5 and -Yar. The Greek and Yemenite isolates studied are all very aggressive on lettuce, are able to overcome the resistance genes mo1(1) and mo1(2) and belong to the two phylogenetic groups which have so far been only partially characterised. As for other Potyviruses, the core and the C-terminal regions of the coat protein are highly conserved among all isolates whereas the N-terminus is more variable. No amino acid change in the coat protein or carboxy-terminal part of the polymerase could be related to the resistance-breaking properties of the isolates analysed. The sequences obtained provide the basis for the rapid typing of LMV isolates using the restriction pattern of segments of cDNA amplified by PCR.