Nonstructural p26 proteins encoded by the 3'-proximal genes of velariviruses and criniviruses are orthologs.

The 3'-most genes in RNA-2 of the Crinivirus genus members (family Closteroviridae) code for non-structural p26 proteins that share amino acid sequence similarity [Stewart LR, Hwang MS, Falk BW (2009) Virus Res 145:293-299]. In this study, sensitive bioinformatic tools have been used to identify the homologous p26 proteins encoded by the 3' genes in monopartite genomes of the members of Velarivirus, another Closteroviridae genus, and mint vein banding-associated virus, an unassigned member of the family. The p26 proteins showed similarity in their predicted secondary structures, but an amino acid sequence alignment showed no strictly conserved positions, thus indicating a high plasticity of these non-structural proteins. The implications of the sequence analysis for possible functions of the crinivirus and velarivirus p26 proteins are discussed.

A conserved region in the Closterovirus 1a polyprotein drives extensive remodeling of endoplasmic reticulum membranes and induces motile globules in Nicotiana benthamiana cells.

In infected plant cells, closterovirus replicative polyproteins 1a and 1ab drive membrane remodeling and formation of multivesicular replication platforms. Polyprotein 1a contains a variable Central Region (CR) between the methyltransferase and helicase domains. In a previous study, we have found that transient expression of the Beet yellows virus CR-2 segment (aa 1305-1494) in Nicotiana benthamiana induces the formation of ~1µm mobile globules originating from the ER membranes. In the present study, sequence analysis has shown that a part of the CR named the "Zemlya region" (overlapping the CR-2), is conserved in all members of the Closterovirus genus and contains a predicted amphipathic helix (aa 1368-1385). By deletion analysis, the CR-2 region responsible for the induction of 1-µm globules has been mapped to aa 1368-1432. We suggest that the conserved membrane-modifying region of the BYV 1a may be involved in the biogenesis of closterovirus replication platforms.

Dual-colour imaging of membrane protein targeting directed by poa semilatent virus movement protein TGBp3 in plant and mammalian cells.

The movement function of poa semilatent hordeivirus (PSLV) is mediated by the triple gene block (TGB) proteins, of which two, TGBp2 and TGBp3, are membrane proteins. TGBp3 is localized to peripheral bodies in the vicinity of the plasma membrane and is able to re-direct TGBp2 from the endoplasmic reticulum (ER) to the peripheral bodies. For imaging of TGBp3-mediated protein targeting, PSLV TGBp3 tagged with a red fluorescent protein (DsRed) was used. Coexpression of DsRed-TGBp3 with GFP targeted to the ER lumen (ER-GFP) demonstrated that ER-GFP was contained in typical ER structures and peripheral bodies formed by TGBp3 protein, suggesting an ER origin for these bodies. In transient coexpression with viral membrane proteins tagged with GFP, DsRed-TGBp3 directed to the peripheral bodies the homologous TGBp2 protein and two unrelated membrane proteins, the 6 kDa movement protein of beet yellows closterovirus and the putative movement protein encoded by the genome component 4 of faba bean necrotic yellows nanovirus. However, coexpression of TGBp3 with GFP derivatives targeted to the ER membranes by artificial hydrophobic tail sequences suggested that targeting to the ER membranes per se was not sufficient for TGBp3-directed protein trafficking to peripheral bodies. TGBp3-induced targeting of TGBp2 also occurred in mammalian cells, indicating the universal nature of the protein trafficking signals and the cotargeting mechanism.

Detection of beet yellows closterovirus methyltransferase-like and helicase-like proteins in vivo using monoclonal antibodies.

In the positive-stranded RNA genome of beet yellows closterovirus (BYV), the 5'-terminal ORF 1a encodes a 295 kDa polyprotein with the domains of papain-like cysteine proteinase, methyltransferase (MT) and helicase (HEL), whereas ORF 1b encodes an RNA-dependent RNA polymerase. Eleven and five hybridoma cell lines secreting monoclonal antibodies (MAbs) were derived from mice injected with the bacterially expressed fragments of the BYV 1a product encompassing the MT and HEL domains, respectively. On immunoblots of protein from BYV-infected Tetragonia expansa plants, four MAbs against the MT recognized a approximately 63 kDa protein, and two MAbs against the HEL recognized a approximately 100 kDa protein. Both the methyltransferase-like protein and the helicase-like protein were found mainly in the fractions of large organelles (P1) and membranes (P30) of the infected plants. These data clearly indicate that (i) the BYV methyltransferase-like and helicase-like proteins, like other related viral enzymes, are associated with membrane compartments in cells, and (ii) the 1a protein, apart from the cleavage by the leader papain-like proteinase that is expected to produce the 66 kDa and 229 kDa fragments, undergoes additional processing by a virus-encoded or cellular proteinase.

Identification and study of tobacco mosaic virus movement function by complementation tests.

The phenomenon of trans-complementation of cell-to-cell movement between plant positive-strand RNA viruses is discussed with an emphasis on tobamoviruses. Attention is focused on complementation between tobamoviruses (coding for a single movement protein, MP) and two groups of viruses that contain the triple block of MP genes and require four (potato virus X) or three (barley stripe mosaic virus) proteins for cell-to-cell movement. The highlights of complementation data obtained by different experimental approaches are given, including (i) double infections with movement-deficient (dependent) and helper viruses; (ii) infections with recombinant viral genomes bearing a heterologous MP gene; (iii) complementation of a movement-deficient virus in transgenic plants expressing the MP of a helper virus; and (iv) co-bombardment of plant tissues with the cDNAs of a movement-dependent virus genome and the MP gene of a helper virus.

The minor coat protein of beet yellows closterovirus encapsidates the 5' terminus of RNA in virions.

Filamentous particles of beet yellows closterovirus (BYV) are built of two related capsid proteins, of which the minor species, p24, forms a 75 nm tail at one end of the virion. In the present work, we used polyclonal antibodies against p24 for isolating the 'tailed' virion segments from sonicated BYV particle preparations. The [gamma-32P]ATP-labelled RNA obtained from the antibody-selected particle segments consistently showed stronger hybridization with the 5'-terminal BYV cDNA clones than with the 3'-terminal cDNA clones. These data clearly indicate that it is the 5'-terminal portion of the closterovirus RNA genome that is encapsidated by p24.

Beet yellows closterovirus HSP70-like protein mediates the cell-to-cell movement of a potexvirus transport-deficient mutant and a hordeivirus-based chimeric virus.

It has been suggested that the beet yellows closterovirus (BYV)-encoded p65 protein, a homologue of HSP70 cell chaperones, plays a role as a virus movement protein (MP). To test this hypothesis, we used two types of complementation experiments with plant viruses containing the triple gene block (TGB) of MP genes. In one, the BYV p65 gene was cloned into a 35S promoter plasmid and introduced into Nicotiana benthamiana plants by microprojectile bombardment along with the 35S promoter-driven GUS gene-tagged cDNA of a transport-deficient potexvirus mutant. Transient expression of p65 complemented the mutant as visualized by the significant increase in the number of cells expressing the GUS reporter gene in the infection foci. In the other test, the p65 gene was inserted into the infectious cDNA of the hordeivirus RNA beta component to replace either the 58 kDa MP gene or the whole TGB. Inoculation of Chenopodium quinoa and Chenopodium amaranticolor plants with the T7 transcripts of the chimeric RNA beta, together with the hordeivirus RNA alpha and RNA gamma, caused symptomless infection in inoculated leaves detected by hybridization of the total leaf RNA with a specific cDNA probe. The ability of BYV p65 to substitute for the potexvirus or hordeivirus MPs provides direct evidence for its involvement in the cell-to-cell movement of closterovirus infection.

Complete genome structure and phylogenetic analysis of little cherry virus, a mealybug-transmissible closterovirus.

The 5'-terminal genomic region (8597 nt) of little cherry virus (LChV), a mealybug-borne closterovirus, was cloned from double-stranded RNA, and its sequence determined to complete the 16934 nt sequence of the monopartite LChV RNA genome. In the 5' to 3' direction, the sequence encompasses ORF 1a, encoding the conserved replicative domains of methyltransferase and helicase, and ORF 1b, encoding RNA polymerase. ORFs 1a and 1b partially overlap (in O/+1 configuration), and the LChV replicase is probably expressed by ribosomal frameshifting as a fusion product with a molecular mass of 318 kDa. The N-terminal part of the ORF 1a product contains a papain-like cysteine proteinase (PCP) domain with a predicted cleavage site between Gly-619 and Ser-620. The PCP and the upstream protein domains can be aligned with the equivalent parts of the leader proteins encoded by the whitefly-transmitted lettuce infectious yellows and sweet potato sunken vein closteroviruses. Phylogenetic reconstruction based on the aligned RNA polymerase sequences clearly suggests that the aphid-transmissible and whitefly-transmissible closteroviruses represent two distinct evolutionary lineages, with the mealybug-transmissible LChV being the most remote member of the 'whitefly' lineage.

The beet yellows closterovirus p65 homologue of HSP70 chaperones has ATPase activity associated with its conserved N-terminal domain but does not interact with unfolded protein chains.

The positive-strand RNA genome of beet yellows closterovirus (BYV) encodes a 65 kDa protein (p65) related to the HSP70 family of cell chaperones. The full-sized BYV p65, and N- and C-terminal fragments, with (His)6 tails, were overexpressed in bacteria and purified by metal-chelate chromatography. Using a polyclonal antiserum raised against the C-terminal fragment of p65, evidence was obtained for expression of the viral protein in planta. Purified recombinant p65 and its N-terminal 40 kDa fragment exhibited Mg2+-dependent ATPase activity in vitro. However, unlike its cellular HSP70 homologues, p65 was unable to bind to denatured protein and its ATPase activity was not stimulated by synthetic peptides which are known to stimulate HSP70 ATPases. Hence, the BYV p65, although being a chaperone-type ATPase, may have a distinct substrate specificity and function in BYV-infected cells.

Comparisons of the genomic cis-elements and coding regions in RNA beta components of the hordeiviruses barley stripe mosaic virus, lychnis ringspot virus, and poa semilatent virus.

Nucleotide sequences of the genomic RNA beta components of hordeiviruses poa semilatent virus (PSLV) and lychnis ringspot virus (LRSV) were determined. PSLV and LRSV closely resemble barley stripe mosaic virus (BSMV), type hordeivirus, in the gene arrangement of their RNAs beta, comprising 5'-proximal beta a (coat protein) gene and downstream triple gene block (TGB) coding for the beta b, beta c, and beta d putative transport proteins. The beta a, beta b, beta c, and beta d proteins of the three hordeiviruses showed significant sequence similarity, with the respective proteins of PSLV and BSMV being closer to each other than to their counterparts of LSRV. Comparisons of the TGB-encoded proteins of hordeiviruses, potexviruses, carlaviruses, and furoviruses indicate that the first and second TGB genes belong to the monophyletic groups, whereas the third gene may have multiple ancestry. LRSV, PSLV, and BSMV showed remarkable variation in the 3'-untranslated regions of their genomic RNAs. Among the three hordeiviruses, LRSV has the shortest 3'-noncoding region that lacks tentative pseudoknot-forming elements conserved upstream of the 3'-tRNA-like structure in the BSMV and PSLV genomes. On the other hand, LRSV RNA beta, like that of BSMV, contained the internal poly(A) sequence that is absent from PSLV RNA.

"Rattlesnake" structure of a filamentous plant RNA virus built of two capsid proteins.

Elongated particles of simple RNA viruses of plants are composed of an RNA molecule coated with numerous identical capsid protein subunits to form a regular helical structure, of which tobacco mosaic virus is the archetype. Filamentous particles of the closterovirus beet yellow virus (BYV) reportedly contain approximately 4000 identical 22-kDa (p22) capsid protein subunits. The BYV genome encodes a 24-kDa protein (p24) that is structurally related to the p22. We searched for the p24 in BYV particles by using immunoelectron microscopy with specific antibodies against the recombinant p24 protein and its N-terminal peptide. A 75-nm segment at one end of the 1370-nm filamentous viral particle was found to be consistently labeled with both types of antibodies, thus indicating that p24 is indeed the second capsid protein and that the closterovirus particle, unlike those of other plant viruses with helical symmetry, has a "rattlesnake" rather than uniform structure.

Complete nucleotide sequence and genome organization of a tobamovirus infecting cruciferae plants.

Genomic RNA sequence of a tobamovirus infecting cruciferae plants (cr-TMV) was determined. The RNA is composed of 6312 nucleotides and contains four ORFs encoding the proteins of 122K (ORF1), 178K (ORF2), 29K (ORF3) and 18K (capsid protein, ORF4). ORF4 overlaps ORF3 by 74 nucleotides and the overlapping region can be folded into a stable hairpin structure. The 3'-terminal region of the cr-TMV RNA preceding the tRNA-like structure was shown to form six potentially stable pseudoknots.

Expression of the beet yellows closterovirus capsid protein and p24, a capsid protein homologue, in vitro and in vivo.

The positive-sense RNA genome of beet yellows closterovirus (BYV) encompasses open reading frames (ORFs) for the viral capsid protein (CP, ORF 6) and for a CP homologue (p24, ORF 5). The sequences of the ORFs 5 and 6 were inserted into an Escherichia coli expression vector, pQE-9, under the control of the bacteriophage T5 promoter. The proteins were expressed in bacteria, purified, and used for antiserum production in rabbits. The recombinant BYV CP and p24 showed serological cross-reactions when probed with each antiserum on Western blots. The cross-reactions of the anti-p24 serum with the CP, and of the anti-CP serum with the p24, were abolished by preadsorption with the heterologous antigens, suggesting that CP and p24 share a common epitope(s) resistant to SDS denaturation. Cross-reactivity of the soluble CP and p24 was also observed in indirect plate-trapped antigen ELISA, whereas virtually none was encountered in double-antibody sandwich ELISA. Using a polyclonal anti-p24 serum preadsorbed with the recombinant CP, the p24 was detected in BYV-infected plants. Analysis of subcellular fractions of BYV-infected Tetragonia expansa indicated that both proteins are predominantly located in the soluble fraction of the host cells. Primer extension analysis of the individual double-stranded forms of the subgenomic RNAs bearing the CP and p24 genes allowed them to be mapped and their 5' start sites to be located at nucleotide positions 13,588 and 12,815, respectively, in the complete genome sequence. This corresponds to the 5' untranslated regions of 52 and 105 nucleotides in the subgenomic RNAs for CP and p24, respectively. The data obtained indicate that the synthesis of both subgenomic RNAs is initiated on a negative RNA strand at an adenosine residue found within the conserved sequence 5' CCAUUUPyA (shown as positive-sense), which may thus represent a core element of the subgenomic promoter. This conserved sequence also resembles the sequences at the 5' ends of the CP subgenomic RNAs of tobamoviruses and the Bromoviridae family members, the viruses evolutionarily most closely related to BYV.

Beet yellows closterovirus: complete genome structure and identification of a leader papain-like thiol protease.

The sequence of 8734 nucleotides (nt) from the 5'-end of the beet yellows closterovirus (BYV) RNA was determined to complete the 15,480-nt sequence of the virus genome. The 5'-terminal two-thirds of the sequence are occupied by two overlapping open reading frames (ORFs) 1a and 1b, encoding products with calculated M(r) of 295K and 48K, respectively. The RNA sequence surrounding the stop codon in ORF 1a shows structural elements typical of ribosomal frameshifting signals in a number of animal and plant viruses. It is predicted that the ORF 1b product is expressed via a +1 ribosomal frameshifting as the 348K ORF 1a/1b fusion protein. This putative protein contains the array of methyltransferase, RNA helicase, and RNA-dependent RNA polymerase domains that is conserved in the Sindbis-like supergroup of positive-strand RNA viruses. The 348K protein of BYV is longer than the putative replicases of the most closely related viruses (tobra- and tobamoviruses) by about 1300 amino acids distributed between two unique regions, one at the N-terminus, and the other in the central portion. The N-terminal domain showed sequence similarity to the helper component papain-like protease of potyviruses. By using in vitro translation of the T7 transcripts encoding the N-terminal 92K peptide of the BYV ORF 1a product, we found that the N-terminal fragment of 588 amino acids is released from the translation product by cleavage at the Gly-Gly dipeptide. Site-directed mutagenesis of either of the predicted catalytic residues Cys-509 and His-569 or of the Gly-588 at the cleavage site completely abolished the cleavage. The central unique region of the 348K protein contains a domain distantly resembling the aspartic protease of HIV and other lentiviruses. As shown previously, the 3'-terminal portion of the BYV genome encompasses seven more ORFs, one of which codes for a protein related to the HSP70 cell heat shock proteins, whereas two others encode the capsid protein and its diverged copy. Thus, despite the apparent evolutionary relationship with Sindbis-like viruses, BYV comprises a collection of genomic modules absorbed from different sources and has a unique expression strategy.

Coat protein gene duplication in a filamentous RNA virus of plants.

Computer-assisted analysis revealed a striking sequence similarity between the putative 24-kDa protein (p24) encoded by open reading frame (ORF) 5 of beet yellows closterovirus and the coat protein of this virus encoded by the adjacent ORF6. Both of these proteins are closely related to the homologous proteins of another closterovirus, citrus tristeza virus. It is hypothesized that the genes for coat protein and its diverged tandem copy have evolved by duplication. Phylogenetic analysis using various methods for tree generation suggested that the duplication was already present in the genome of the common ancestor of the two closteroviruses. The genes for p24 and coat protein of beet yellows closterovirus were cloned, transcribed, and translated in vitro yielding products of the expected size. It was shown that p24 is translated starting from the first of the two alternative AUG codons located near the 5' terminus of ORF5. The presence of a single protein species in beet yellows closterovirus virions and the near identity of the amino acid composition of this protein with the composition of the ORF6 but not the ORF5 product indicated that p24 is not a major virion component. Most of the amino acids that are conserved in the coat proteins of filamentous viruses of plants are retained also in p24. These observations suggest that p24 may share some structural and functional features with the coat protein but probably fulfills a distinct function in virus reproduction.

Poa semilatent virus, a hordeivirus having no internal polydisperse poly(A) in the 3' non-coding region of the RNA genome.

RNA from the Hungarian isolate of poa semilatent virus (PSLV) directed in vitro synthesis of 120K, 75K, 25K (coat protein) and 20K polypeptides. In vitro translation of PSLV RNA was blocked by the cap analogue, m7Gpp, thus suggesting that the virus RNA was capped. PSLV RNA could be aminoacylated with [14C]tyrosine in vitro. The sequence of 1.5 kb from the 3' end of the PSLV RNA gamma component revealed two open reading frames (ORFs) separated by a uridine-rich intergenic region. The putative product of the incomplete 5'-proximal ORF showed a close amino acid sequence similarity with the C-terminal segment of the gamma a protein (putative RNA replicase) encoded in the barley stripe mosaic virus (BSMV) RNA gamma, and the 20K product of the 3'-proximal ORF was found to be related to the 17K gamma b product of BSMV. The sequence of 0.8 kb from the 3' end of PSLV RNA beta encompassed two (incomplete) overlapping ORFs whose putative products are related to the beta c and beta d proteins encoded in the similarly arranged ORFs of BSMV RNA beta. Nucleotide sequence homology between the respective parts of the two hordeivirus genomes was restricted to the ORF for gamma a, the spacer between the ORFs for gamma a and gamma b, and the 3' non-coding region, particularly the 95 nucleotide segment at the 3' end representing a tRNA-like structure. Despite limited sequence conservation beyond this segment, the entire 3' non-coding region of PSLV RNA could be folded in a tight pseudoknotted structure closely resembling that of BSMV RNA. Surprisingly, the 'signature' sequence typical for BSMV RNA, internal polydisperse poly(A) intercalated between the coding part of the 3' tRNA-like structure, was not detected in the PSLV genome. Instead, the virus RNA contained several oligoadenylate stretches spaced by other residues, close to the junction of its coding and 3' non-coding portions.