Effect of 5' and 3' terminal sequences, overall length, and coding capacity on the accumulation of defective RNAs associated with broad bean mottle bromovirus in planta.

Broad bean mottle bromovirus (BBMV) was shown to accumulate RNA2-derived defective interfering (DI) RNAs [Romero et al., Virology 194, 576-584 (1993); Pogany et al., Virology 212, 574-586 (1995)]. In this work, we utilize three sets of BBMV RNA2-derived artificial DI RNA constructs to determine factors that affect the accumulation of defective RNAs in planta. One set of deletion constructs was used to localize sequences required for efficient accumulation within the 5' 883 nt and the 3' 387 nt of the DI RNAs. The second set had a gradually increasing size of 3' nested deletions to determine the minimal length required for efficient DI RNA accumulation. The smallest DI RNA still accumulating in plants was found to be 1712 nt long. The third set consisted of frameshift mutants which showed that at least 64.4% of BBMV DI RNA sequences must have the 5' portion of the 2a open reading frame to ensure efficient accumulation. The importance of these factors in the selection of DI RNAs is discussed.

De novo generation of defective interfering-like RNAs in broad bean mottle bromovirus.

Broad been mottle virus (BBMV) is the only member of the bromoviruses that is known to accumulate defective-interfering (DI) RNAs (Romero et al., Virology 194, 576-584, 1993). De novo generation of DI-like RNAs was demonstrated during serial passages of BBMV in broad bean using either DI RNA-free virion RNA preparations or transcribed genomic RNA inocula. As for previously described DI RNAs, all but one of the characterized de novo generated DI-like RNAs were derived by a single in-frame deletion from the RNA2 component. The sole exception was derived by two shorter in-frame deletions from RNA2. The maintenance of an open reading frame by all DI-like RNAs suggests the importance of coding capacity and/or the shortened 2a protein in the accumulation of these RNAs during infection. The deletion junction sites were between nucleotides 1152 and 2366, suggesting that the retained regions are essential for the efficient accumulation of BBMV DI-like RNAs in planta. Short regions of sequence similarity and/or complementarity were revealed at the 5' and 3' junction borders. We speculate that these regions can facilitate DI (DI-like) RNA formation. In addition to DI-like RNAs, the full-length nucleotide sequences of RNA2 components of the Type and Morocco strains of BBMV are presented.

Infectious transcripts from PCR-amplified broad bean mottle bromovirus cDNA clones and variable nature of leader regions in RNA 3 segment.

The genome of broad bean mottle bromovirus (BBMV) contains three positive-sense ssRNA segments, each capped with m7GpppA. Full-length transcribable cDNA clones for four strains of BBMV were constructed by employing reverse transcriptase-PCR (RT-PCR) and a high fidelity Vent DNA polymerase. The transcribed BBMV RNAs contained a 5' non-viral G residue and, although delayed, produced symptoms similar to those observed in plants infected with authentic virion RNAs. The transcripts replicated inefficiently in protoplasts. In contrast, transcript-derived progeny BBMV RNAs had the repaired termini, were as infectious as the authentic BBMV RNAs and replicated to high levels in protoplasts. In vitro translation of synthetic RNAs confirmed the previously proposed gene expression strategy for BBMV. Sequencing of virion RNAs from the Bawden strain revealed two forms of BBMV RNA3 components, the longer form containing 21 5' extra nucleotides derived by the duplication of two short 5' leader regions. The relative concentration of the two RNA 3 forms was found to be host-dependent, with the longer form prevailing in broad bean and Nictiana clevelandii infections and the shorter form in bean infections.

Interstrain pseudorecombinants of cowpea chlorotic mottle virus: effects on systemic spread and symptom formation in soybean and cowpea.

Full-length complementary DNA (cDNA) copies of genomic RNA1, RNA2, and RNA3 segments of cowpea chlorotic mottle virus (CCMV) strains D, N, and S were synthesized using polymerase chain reaction and were cloned downstream of a T7 RNA polymerase promoter. Mixtures of the homologous in vitro-transcribed RNAs produced typical CCMV symptoms when inoculated on soybean (cv. Bragg) and cowpea (cv. California Blackeye) plants. Using either gel-purified or in vitro-transcribed CCMV RNA components, the pseudorecombinants SSD, SSN, DDS, and NNS were constructed. The properties of these pseudorecombinants were tested by comparing the induced symptoms, virus concentration, and systemic spread. These studies revealed a direct involvement of RNA3 genetic information in necrotic lesion formation and in breakage of CCMV resistance in soybean. Exchanges between RNA1 or RNA2 components further affected the biological features of reassorted CCMV variants. The true nature of the pseudorecombinants was confirmed by reconstitution of the parental strains from the corresponding pseudorecombinant RNA components.

Characterization of defective interfering RNA components that increase symptom severity of broad bean mottle virus infections.

Several strains of the broad bean mottle virus (BBMV), an icosahedral tripartite plant RNA virus, which show distinct reactions on certain plant hosts have been described (K. M. Makkouk et al., Neth. J. Plant Pathol. 94, 195-212, 1988). Here we report defective interfering (DI) RNAs encapsidated in two BBMV strains from Morocco and Tunisia. While not effective in some plants, these DI RNAs exacerbated the severity of symptoms in others. The most dramatic, lethal effect of DI RNAs has been found on pea (Pisum sativum, cv. Rondo) seedlings. Sequence analysis has revealed that the DI RNAs were derived by single in-frame central deletions of 448 to 537 nt in the corresponding genomic RNA2 components. A comparison of the intensities of full-length RNA2 bands from DI molecule-containing and DI molecule-deficient virion RNA preparations revealed that the DI RNAs decreased the level of RNA2 components in total RNA preparations. The differences between corresponding virion RNAs were much smaller. This suggests an interference with RNA replication. In vitro assays and an analysis of the polyribosomal RNA fractions confirmed the translational activity of DI RNAs. This paper reports the first description of natural DI RNAs in tripartite isometric plant RNA viruses.

The nucleotide sequence and genome organization of the RNA2 and RNA3 segments in broad bean mottle virus.

Complete nucleotide sequences of broad bean mottle virus (BBMV) genomic RNAs 2 and 3 were determined. They consist of 2811 and 2293 nucleotides, respectively. Both RNAs are caped and, unlike in other tricornaviruses, both initiate with an A residue. BBMV RNA2 is monocistronic and encodes an 815 amino acid 2a protein, whereas RNA3 is dicistronic, encoding for a 295 amino acid 3a protein and for the 190 amino acid coat protein. A central, 423 amino acid 2a protein core region is highly homologous among the three bromoviruses, whereas both N- and C-termini are more heterologous. Most of the homologies among 3a proteins are concentrated within the N-termini two-thirds of the molecule that is predominantly hydrophobic, whereas the C-terminal one-third contains a large number of charged amino acids. The homologies among coat proteins are clustered within several mostly hydrophobic, or neutral, domains. The 5' noncoding region of the RNA2 has 110 nucleotides, whereas that of RNA3 contains 330 nucleotides. As in cowpea chlorotic mottle virus, but unlike in Brome mosaic virus, the 5' noncoding region includes subgenomic promoter-like sequences. The BBMV RNA3 intercistronic region also has subgenomic promoter sequences and contains a long poly(A) stretch. At the 3' end, BBMV RNAs 2 and 3 have 257 and 236 noncoding nucleotides, respectively.

Immunochromatographic purification of Bean Yellow Mosaic Virus.

The method of immunoadsorptional purification of Bean Yellow Mosaic Virus has been worked out. Immunosorbents were obtained by coupling the antibody (IgG) fraction isolated from anti-BYMV and anti-pea leaf protein antisera with CNBr-activated 1% agarose beads. Conditions for preparation of immunosorbents, for BYMV adsorption and elution as well as the method of plant protein separation from BYMV were pointed out. The purity of BYMV was checked by double immunodiffusion as well as by SDS-acrylamide gel electrophoresis. Also biological activity was determined. TMV was used as the model virus for further BYMV studies.