Expression of the cauliflower mosaic virus capsid gene in vivo

Characterization of Cestrum yellow leaf curling virus: a new member of the family Caulimoviridae

Cestrum yellow leaf curling virus (CmYLCV) has been characterized as the aetiological agent of the Cestrum parqui mosaic disease. The virus genome was cloned and the clone was proven to be infectious to C. parqui. The presence of typical viroplasms in virus-infected plant tissue and the information obtained from the complete genomic sequence confirmed CmYLCV as a member of the Caulimoviridae family. All characteristic domains conserved in plant pararetroviruses were found in CmYLCV. Its genome is 8253 bp long and contains seven open reading frames (ORFs). Phylogenetic analysis of the relationships with other members of the Caulimoviridae revealed that CmYLCV is closely related to the Soybean chlorotic mottle virus (SbCMV)-like genus and particularly to SbCMV. However, in contrast to the other members of this genus, the primer-binding site is located in the intercistronic region following ORF Ib rather than within this ORF, and an ORF corresponding to ORF VII is missing.

Interaction of the cauliflower mosaic virus coat protein with the pregenomic RNA leader

Using the yeast three-hybrid system, the interaction of the Cauliflower mosaic virus (CaMV) pregenomic 35S RNA (pgRNA) leader with the viral coat protein, its precursor, and a series of derivatives was studied. The purine-rich domain in the center of the pgRNA leader was found to specifically interact with the coat protein. The zinc finger motif of the coat protein and the preceding basic domain were essential for this interaction. Removal of the N-terminal portion of the basic domain led to loss of specificity but did not affect the strength of the interaction. Mutations of the zinc finger motif abolished not only the interaction with the RNA but also viral infectivity. In the presence of the very acidic C-terminal domain, which is part of the preprotein but is not present in the mature CP, the interaction with the RNA was undetectable.

Cauliflower mosaic virus ORF III product forms a tetramer in planta: its implication in viral DNA folding during encapsidation

Cauliflower mosaic virus (CaMV) open reading frame (ORF) III encodes a 15 kDa protein; the function of which is as yet unknown. This protein has non-sequence-specific DNA binding activity and is associated with viral particles, suggesting that the ORF III product (P3) is involved in the folding of CaMV DNA during encapsidation. In this study, we demonstrated that P3 forms a tetramer in CaMV-infected plants. A P3-related protein with an apparent molecular weight of 60 kDa was detected by Western blotting analysis using anti-P3 antiserum under non-reducing conditions, while only 15 kDa P3 was detected under reducing conditions. Analysis of P3 using viable mutants with a 27-bp insertion in either ORF III or IV revealed that the 60 kDa protein was a tetramer of P3. The P3 tetramer co-sedimented with viral coat protein in multiple fractions on sucrose gradient centrifugation, suggesting that P3 tetramer binds to mature and immature virions. These results strongly suggested that CaMV P3 forms a tetramer in planta and that disulfide bonds are involved in its formation and/or stabilization. The finding of P3 tetramer in planta suggested that viral DNA would be folded compactly by the interaction with multiple P3 molecules, which would form tetramers, while being packaged into the capsid shell.

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.

Evidence for a dual strategy in the expression of cauliflower mosaic virus open reading frames I and IV

Studies have indicated that cauliflower mosaic virus (CaMV) gene expression is mediated by the translation of polycistronic 35S pregenomic RNA, but the involvement of some minor subgenomic RNA species is also suspected. We examined the involvement of the 35S promoter in the expression of CaMV open reading frames (ORFs) I and IV using both 35S RNA-driven and promoter-less ORF I- and ORF IV-beta-glucuronidase (GUS) fusion constructs. In addition to the 35S promoter-dependent expression of both ORF I- and IV-GUS fusions, we detected the 35S promoter-independent expression of both fusion genes via subgenomic mRNAs, which were detected by Northern blotting in the protoplasts transfected with the 35S promoter-driven constructs as well as in those transfected with the promoter-less constructs. These results suggest the involvement of subgenomic RNAs in the expression of CaMV ORFs I and IV, and the operation of a dual strategy in the expression of two viral genes.

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.

Characterization of different electrophoretic forms of cauliflower mosaic virus virions (strain Cabb-S)

The electrophoretic forms of purified cauliflower mosaic virus (CaMV), strain Cabb-S, were examined by electrophoresis on agarose gels. Three populations of viral particles were identified: a faster migrating component (the form F) and two slower migrating components (the forms S and S'). When the different forms of virions, after excision from gels, were subjected to analysis in SDS-polyacrylamide gel, the fast component consisted of the 37 and 42 kDa coat proteins whereas the slow components contained mainly the 39 kDa coat protein. However, there was no difference among the nucleic acids associated within the three forms. The biological significance of the different components is discussed.

Processing of the minor capsid protein of the cauliflower mosaic virus requires a cysteine proteinase

The major capsid protein of the cauliflower mosaic virus (CaMV) is processed in vivo. The viral aspartic proteinase that catalyses this maturation has been characterized previously and is coded by the CaMV gene V. This virus has a second capsid protein, a minor component, encoded by gene III. This protein, P3, is also processed at its C-terminus in vivo. To determine whether P3 is matured by the CaMV proteinase P5, we expressed, in Saccharomyces cerevisiae, P3, P5 and a fusion protein P7-P4, containing potential sites of cleavage. P5 was found to be involved in maturation of P7-P4 but did not cleave P3. The latter result was confirmed by experiments carried out with an in vitro translation system (the reticulocyte lysate) and with preparations of replication complexes purified from infected plants. Moreover, [N-(L-3-trans-carboxyoxiran-2-carbonyl)-L-leu cyl]-amido(4-guanido)butane, a specific inhibitor of cysteine proteinases, inhibited the maturation of P3, suggesting that the two CaMV capsid proteins are not processed by the same proteolytic event.

How do viral reverse transcriptases recognize their RNA genome?

Reverse transcription is not solely a retroviral mechanism. Hepadnaviruses and caulimoviruses have RNA intermediates that are reverse transcribed into DNA. Moreover non-viral retroelements, retrotransposons, use reverse transcription in their transposition. All these retroelements encode reverse transcriptase but each group developed their own expression modes capable of assuring a specific and efficient replication of their genomes.

The cauliflower mosaic virus reverse transcriptase is not produced by the mechanism of ribosomal frameshifting in Saccharomyces cerevisiae

The capsid protein and the reverse transcriptase of cauliflower mosaic virus (CaMV) are encoded by two genes (ORF IV and ORF V) that lie in different translation reading frames. A comparison can be drawn between the synthesis of both CaMV proteins and the fusion protein in a yeast retrotransposon, Ty, resulting from a +1 frameshifting event which fuses two out-of-phase ORFs encoding the structural protein and the reverse transcriptase of Ty. For this reason, we constructed a yeast expression vector containing CaMV ORF VII fused to CaMV ORF III by a fragment of 452 bp including the overlapping region of ORF IV and ORF V, ORF VII and ORF III being used as reporter genes. We characterized two proteins (22 and 50 kDa) synthesized from this plasmid in the yeast expression system. We demonstrated that the 50-kDa polypeptide is not synthesized from a +1 frameshifting event but is probably a dimeric form of the 22-kDa protein. From this result we conclude that the CaMV reverse transcriptase is not produced by a mechanism of ribosomal frameshifting.

Crystallization of cauliflower mosaic virus

Cauliflower mosaic virus has been crystallized in hanging and sitting drops. The hexagonal and octahedrally shaped crystals are up to 0.5 mm in mean diameter. The octahedrally shaped crystals diffract to about 27 A resolution. The results are discussed in relation to the lability and aggregation of the virions.

The cauliflower mosaic virus open reading frame VII product can be expressed in Saccharomyces cerevisiae but is not detected in infected plants

Antiserum was prepared against a synthetic peptide corresponding to the N-terminal 20 amino acids of the protein encoded by cauliflower mosaic virus (CaMV) open reading frame VII (ORF VII). This antiserum was used to detect the expression of CaMV ORF VII either in Saccharomyces cerevisiae transformed by an expression vector containing CaMV ORF VII or in CaMV-infected plants. Only in S. cerevisiae has a 14-kilodalton protein been detected.

The cauliflower mosaic virus gene III product is a non-sequence-specific DNA binding protein

The interaction of the gene III product, P15, of cauliflower mosaic virus with different double-stranded DNA fragments of the viral genome was investigated. The results suggest that gene III product which showed DNA binding activity is a structural protein of the viral particle.