Transgenically expressed T-Rep of tomato yellow leaf curl Sardinia virus acts as a trans-dominant-negative mutant, inhibiting viral transcription and replication.

We have previously shown that transgenic expression of a truncated C1 gene of Tomato yellow leaf curl Sardinia virus (TYLCSV), expressing the first 210 amino acids of the replication-associated protein (T-Rep) and potentially coexpressing the C4 protein, confers resistance to the homologous virus in Nicotiana benthamiana plants. In the present study we have investigated the role of T-Rep and C4 proteins in the resistance mechanism, analyzing changes in virus transcription and replication. Transgenic plants and protoplasts were challenged with TYLCSV and the related TYLCSV Murcia strain (TYLCSV-ES[1]). TYLCSV-resistant plants were susceptible to TYLCSV-ES[1]; moreover, TYLCSV but not TYLCSV-ES[1] replication was strongly inhibited in transgenic protoplasts as well as in wild-type (wt) protoplasts transiently expressing T-Rep but not the C4 protein. Viral circular single-stranded DNA (cssDNA) was usually undetectable in transgenically and transiently T-Rep-expressing protoplasts, while viral DNAs migrating more slowly than the cssDNA were observed. Biochemical studies showed that these DNAs were partial duplexes with the minus strand incomplete. Interestingly, similar viral DNA forms were also found at early stages of TYLCSV replication in wt N. benthamiana protoplasts. Transgenically expressed T-Rep repressed the transcription of the GUS reporter gene up to 300-fold when fused to the homologous (TYLCSV) but not to the heterologous (TYLCSV-ES[1]) C1 promoter. Similarly, transiently expressed T-Rep but not C4 protein strongly repressed GUS transcription when fused to the C1 promoter of TYLCSV. A model of T-Rep interference with TYLCSV transcription-replication is proposed.

Identification of artichoke mottled crinkle virus (AMCV) proteins required for virus replication: complementation of AMCV p33 and p92 replication-defective mutants.

Mutagenesis of the artichoke mottled crinkle virus (AMCV) genome and complementation studies between replication-defective mutants were undertaken to identify viral protein(s) essential for AMCV replication. Inoculation of Nicotiana benthamiana protoplasts with mutant transcripts revealed that null mutations in ORFs 1 [tA33(-)], 2 [tA92(-)] and 6 [tA7(-)], as well as an ORF 2 mutation [tA92GED] in the GDD motif of the 92 kDa protein, the putative replicase, prevented accumulation of detectable levels of progeny RNA. Conversely, mutations of ORFs 3 [tA41(-)], 4 [tA21(-)] and 5 [tA19(-)] did not substantially affect the accumulation of AMCV genomic and subgenomic RNAs of both positive and negative polarity. Inoculation of N. benthamiana plants with transcripts impaired in replication revealed that tA92(-) and tA7(-) mutants lead to replicating pseudorevertants. Functional analysis of these pseudorevertants showed that: (i) the double stop codon introduced at the end of ORF 1 to prevent the translational readthrough of the 92 kDa protein reverted to a single amber, ochre or opal codon, giving rise to viable genomes; (ii) the putative 7 kDa protein is not essential for genome viability, although the RNA region spanning ORF 6 plays a role in cis in replication. Finally, the two replication-defective mutants tA33(-) and tA92(-) complemented when co-inoculated to N. benthamiana protoplasts, definitively proving that the 33 kDa protein is essential for tombusvirus genome replication. Analysis of viral RNAs from the coinfection experiments showed that tA92(-) was preferentially amplified over tA33(-).

Nucleotide sequence, genomic organization and synthesis of infectious transcripts from a full-length clone of artichoke mottle crinkle virus.

The complete nucleotide sequence of the genome of artichoke mottle crinkle virus (AMCV), a member of the tombusvirus group, has been determined. The genome is 4790 nucleotides (nt) in length. A full-length cDNA of the AMCV genome has been cloned in pUC9 downstream of the T7 RNA polymerase promoter. Transcripts were infective when inoculated onto Nicotiana clevelandii and N. benthamiana plants. The AMCV genome contains five open reading frames (ORFs). The first ORF from the 5' terminus (ORF1) encodes a protein with a predicted M(r) of 33K. ORF2 extends through the amber termination codon of ORF1 to yield a polypeptide of predicted M(r) 92K and which is the putative RNA-dependent RNA polymerase. ORF3 codes for the coat protein (41K). Two nested ORFs in different reading frames (ORFs 4 and 5) code for a 22K and a 19K polypeptide respectively. Sequence homologies suggest that the 22K protein could be involved in cell-to-cell movement of virus. ORFs 3, 4 and 5 are translated from two 3' coterminal subgenomic (sg) RNAs, the 5' termini of which have been mapped. The two sg RNAs are 2155 (sg1) and 934 (sg2) nt in length. ORF3 is expressed from sg1 RNA whereas ORFs 4 and 5 are potentially expressed from sg2 RNA. Time course experiments with Cynara scolymus protoplasts indicate that during AMCV infection both positive and negative strands of genomic and sg RNAs are produced and that sg2 RNA is produced before and at a higher level than sg1 RNA.

Consequences of gene transfer between distantly related tombusviruses.

Hybrid cDNA clones were constructed by fusing the coat protein-encoding gene and/or the 3'-terminal region (including the 22- and 19-kDa protein-encoding genes) derived from a clone of artichoke mottled crinkle tombusvirus to the 5'-terminal region of a full-length clone of cymbidium ringspot tombusvirus. In vitro transcripts from recombinant clones were infectious when inoculated into Nicotiana clevelandii plants. Inoculated plants showed symptoms different from those induced by parent viruses. In particular, systemic invasion depended very much, although not exclusively, on the type of protein that coated progeny viral RNA, suggesting a role of the capsid protein in the long-distance movement of tombusvirus infections.

cDNA cloning of artichoke mottled crinkle virus RNA and localization and sequencing of the coat protein gene.

We report the cDNA cloning of the genomic RNA of artichoke mottled crinkle virus (AMCV), which is a member of Tombusvirus group. AMCV has a monopartite positive sense RNA genome, which is not polyadenylated at the 3' end. The genome size is 4.8 kb. We have localized and sequenced the open reading frame (ORF) encoding the coat protein. Unlike most monopartite positive-strand RNA plant viruses, the ORF is not located near the 3' end, but like other members of the Tombusvirus group, CyRSV (cymbidium ringspot virus), TBSV-cherry (tomato bushy stunt virus cherry strain) and CNV (cucumber necrosis virus) it starts ca. 2.7 kb downstream of the 5' end and stops ca. 1 kb upstream of the 3' end. This ORF predicts a polypeptide chain of 387 amino acids. Comparison of the coat proteins of AMCV, TBSV-BS3, TBSV-cherry and CNV confirms that, within the Tombusvirus group, there exists a high degree of similarity among coat proteins but that this similarity is not uniformly distributed among domains. In particular, the N-terminal region, thought to make contact with the phosphate groups of the viral RNA, and the C-terminal region, considered the most immunogenic portion of the capsid, are found to be the least homologous.

Gene dosage alteration of L2 ribosomal protein genes in Saccharomyces cerevisiae: effects on ribosome synthesis.

In Saccharomyces cerevisiae, the genes coding for the ribosomal protein L2 are present in two copies per haploid genome. The two copies, which encode proteins differing in only a few amino acids, contribute unequally to the L2 mRNA pool: the L2A copy makes 72% of the mRNA, while the L2B copy makes only 28%. Disruption of the L2B gene (delta B strain) did not lead to any phenotypic alteration, whereas the inactivation of the L2A copy (delta A strain) produced a slow-growth phenotype associated with decreased accumulation of 60S subunits and ribosomes. No intergenic compensation occurred at the transcriptional level in the disrupted strains; in fact, delta A strains contained reduced levels of L2 mRNA, whereas delta B strains had almost normal levels. The wild-type phenotype was restored in the delta A strains by transformation with extra copies of the intact L2A or L2B gene. As already shown for other duplicated genes (Kim and Warner, J. Mol. Biol. 165:79-89, 1983; Leeret al., Curr. Genet. 9:273-277, 1985), the difference in expression of the two gene copies could be accounted for via differential transcription activity. Sequence comparison of the rpL2 promoter regions has shown the presence of canonical HOMOL1 boxes which are slightly different in the two genes.

Ribosomal protein L2 in Saccharomyces cerevisiae is homologous to ribosomal protein L1 in Xenopus laevis. Isolation and characterization of the genes.

By cross-hybridization with a cDNA probe for the Xenopus laevis ribosomal protein L1 we have been able to isolate the homologous genes from a Saccharomyces cerevisiae genomic library. We have shown that these genes code for a ribosomal protein which was previously named L2. In yeast, like in X. laevis, these genes are present in two copies per haploid genome and, unlike the vertebrate counterpart, they do not contain introns. Amino acid comparison of the X. laevis L1 and S. cerevisiae L2 proteins has shown the presence of a highly conserved protein domain embedded in very divergent sequences. Although these sequences are very poorly homologous, they confer an overall secondary structure and folding highly conserved in the two species.