Role of the Pepino mosaic virus 3'-untranslated region elements in negative-strand RNA synthesis in vitro.

Pepino mosaic virus (PepMV) is a mechanically-transmitted positive-strand RNA potexvirus, with a 6410 nt long single-stranded (ss) RNA genome flanked by a 5'-methylguanosine cap and a 3' poly-A tail. Computer-assisted folding of the 64 nt long PepMV 3'-untranslated region (UTR) resulted in the prediction of three stem-loop structures (hp1, hp2, and hp3 in the 3'-5' direction). The importance of these structures and/or sequences for promotion of negative-strand RNA synthesis and binding to the RNA dependent RNA polymerase (RdRp) was tested in vitro using a specific RdRp assay. Hp1, which is highly variable among different PepMV isolates, appeared dispensable for negative-strand synthesis. Hp2, which is characterized by a large U-rich loop, tolerated base-pair changes in its stem as long as they maintained the stem integrity but was very sensitive to changes in the U-rich loop. Hp3, which harbours the conserved potexvirus ACUUAA hexamer motif, was essential for template activity. Template-RNA polymerase binding competition experiments showed that the ACUUAA sequence represents a high-affinity RdRp binding element.

In vitro template-dependent synthesis of Pepino mosaic virus positive- and negative-strand RNA by its RNA-dependent RNA polymerase.

Pepino mosaic virus (PepMV)-infected tomato plants were used to develop an in vitro template-dependent system for the study of viral RNA synthesis. Differential sedimentation and sucrose-gradient purification of PepMV-infected tomato extracts resulted in fractions containing a transcriptionally active membrane-bound RNA-dependent RNA polymerase (RdRp). In the presence of Mg(2+) ions, (32)P-labelled UTP and unlabelled ATP, CTP, GTP, the PepMV RdRp catalysed the conversion of endogenous RNA templates into single- and double-stranded (ds) genomic RNAs and three 3'-co-terminal subgenomic dsRNAs. Hybridisation experiments showed that the genomic ssRNA was labelled only in the plus strand, the genomic dsRNA mainly in the plus strand and the three subgenomic dsRNAs equally in both strands. Following removal of the endogenous templates from the membrane-bound complex, the purified template-dependent RdRp could specifically catalyse transcription of PepMV virion RNA, in vitro-synthesized full-length plus-strand RNA and the 3'-termini of both the plus- and minus-strand RNAs. Rabbit polyclonal antibodies against an immunogenic epitope of the PepMV RdRp (anti-RdRp) detected a protein of approximately 164kDa in the membrane-bound and template-dependent RdRp preparations and exclusively inhibited PepMV RNA synthesis when added to the template-dependent in vitro transcription system. The 300 nucleotides long 3'-terminal region of the PepMV genome, containing a stretch of at least 20 adenosine (A) residues, was an adequate exogenous RNA template for RdRp initiation of the minus-strand synthesis but higher transcription efficiency was observed as the number of A residues increased. This observation might indicate a role for the poly(A)-tail in the formation and stabilisation of secondary structure(s) essential for initiation of transcription. The template-dependent specific RdRp system described in this article will facilitate identification of RNA elements and host components required for PepMV RNA synthesis.

In vitro synthesis of minus-strand RNA by an isolated cereal yellow dwarf virus RNA-dependent RNA polymerase requires VPg and a stem-loop structure at the 3' end of the virus RNA.

Cereal yellow dwarf virus (CYDV) RNA has a 5'-terminal genome-linked protein (VPg). We have expressed the VPg region of the CYDV genome in bacteria and used the purified protein (bVPg) to raise an antiserum which was able to detect free VPg in extracts of CYDV-infected oat plants. A template-dependent RNA-dependent RNA polymerase (RdRp) has been produced from a CYDV membrane-bound RNA polymerase by treatment with BAL 31 nuclease. The RdRp was template specific, being able to utilize templates from CYDV plus- and minus-strand RNAs but not those of three unrelated viruses, Red clover necrotic mosaic virus, Cucumber mosaic virus, and Tobacco mosaic virus. RNA synthesis catalyzed by the RdRp required a 3'-terminal GU sequence and the presence of bVPg. Additionally, synthesis of minus-strand RNA on a plus-strand RNA template required the presence of a putative stem-loop structure near the 3' terminus of CYDV RNA. The base-paired stem, a single-nucleotide (A) bulge in the stem, and the sequence of a tetraloop were all required for the template activity. Evidence was produced showing that minus-strand synthesis in vitro was initiated by priming by bVPg at the 3' end of the template. The data are consistent with a model in which the RdRp binds to the stem-loop structure which positions the active site to recognize the 3'-terminal GU sequence for initiation of RNA synthesis by the addition of an A residue to VPg.

Molecular characterization of a partitivirus from Ophiostoma himal-ulmi.

The complete nucleotide sequences of two double-stranded (ds) RNA molecules, S1 (1,744 bp) and S2 (1,567 bp), isolated from an isolate HP62 of the Himalayan Dutch elm disease fungus, Ophiostoma himal-ulmi, were determined. RNA S1 had the potential to encode a protein, P1, of 539 amino acids (62.7 kDa), which contained sequence motifs characteristic of RNA-dependent RNA polymerases (RdRps). A database search showed that P1 was closely related to RdRps of members of the genus Partitivirus in the family Partitiviridae. RNA S2 had the potential to encode a protein, P2, of 430 amino acids (46.3 kDa), which was related to capsid proteins of members of the genus Partitivirus. Virus particles isolated from isolate HP62 were shown to be isometric with a diameter of 30 nm, and to contain dsRNAs S1 and S2 and a single capsid protein of 46 kDa. N-terminal sequencing of tryptic peptides derived from the capsid protein proved unequivocally that it is encoded by RNA S2 and corresponds to protein P2. It is concluded that O. himal-ulmi isolate HP62 contains a new member of the genus Partitivirus, which is designated Ophiostoma partitivirus 1. A phylogenetic tree of RdRps of members of the family Partitiviridae showed that there are least two RdRp lineages of viruses currently classified in the genus Partitivirus. One of these lineages contained viruses with fungal hosts and viruses with plant hosts, raising the possibility of horizontal transmission of partitiviruses between plants and fungi. The partitivirus RdRp and capsid proteins appear to have evolved in parallel with the capsid proteins evolving much faster than the RdRps.