ICTV Virus Taxonomy Profile: Bromoviridae.

Bromoviridae is a family of plant viruses with tri-segmented, positive-sense, single-stranded RNA genomes of about 8 kb in total. Genomic RNAs are packaged in separate virions that may also contain subgenomic, defective or satellite RNAs. Virions are variable in morphology (spherical or bacilliform) and are transmitted between hosts mechanically, in/on the pollen and non-persistently by insect vectors. Members of the family are responsible for major disease epidemics in fruit, vegetable and fodder crops such as tomato, cucurbits, bananas, fruit trees and alfalfa. This is a summary of the International Committee on Taxonomy of Viruses (ICTV) Report on the family Bromoviridae, which is available at www.ictv.global/report/bromoviridae.

Cassava Ivorian bacilliform virus is a member of the genus Anulavirus.

The complete genomic sequence of Cassava Ivorian bacilliform virus (CIBV) is described. The virus has a genomic organization similar to that of pelargonium zonate spot virus (PZSV), the type member of the genus Anulavirus, but it is most closely related to a second, recently described, anulavirus, Amazon lily mild mottle virus (ALiMMV).

Characterization of a new Anulavirus isolated from Amazon lily plants.

A quasi-spherical virus was isolated from a cultivated Amazon lily plant (Eucharis grandiflora) that could be mechanically transmitted to healthy E. grandiflora plants, subsequently producing mild mosaic or mottle symptoms on the leaves. The purified virus consisted of three quasi-spherical particles about 20 nm wide and 70, 40 and 30 nm in length, containing three segmented genomes of 3,169, 2,507 and 2,530 nucleotides, respectively. Sequence analysis showed that the newly isolated virus is related to pelargonium zonate spot virus, a member of the genus Anulavirus. We propose that the virus should be designated as Amazon lily mild mottle virus (ALiMMV).

Molecular characterisation of Raspberry bushy dwarf virus isolates from Sweden and Belarus.

The complete coding sequences were determined for RNA-1 and RNA-2 of five raspberry isolates of Raspberry bushy dwarf virus (RBDV) from Belarus (BY1, BY3, BY8, BY22) and Sweden (SE3). The analysed sequences for both RNA-1 and RNA-2 were highly conserved among these isolates. Phylogenetic analyses including available sequences for the CP gene and the MP gene showed that all analysed RBDV isolates from raspberry were closely related. However, there was no strong correlation between the grouping of raspberry isolates in the phylogenetic analyses and their geographical location. In contrast, RBDV isolates showed a host-dependent relationship with isolates from raspberry and grapevine, forming two distinct clades.

PCR assays for the detection of members of the genus Ilarvirus and family Bromoviridae.

A PCR assay was developed for the universal detection of ilarviruses using primers designed to the RNA-dependent RNA polymerase gene in RNA2. The assay detected 32 isolates of 15 definite and 2 tentative ilarvirus species using a one-step RT-PCR. The assay was more specific, and at least as sensitive as a commercial assay, and allowed direct sequencing of amplicons. No cross-reaction was observed with neither healthy plants of 15 host species nor from isolates in other genera of the Bromoviridae. A further PCR assay targeting the helicase motif of RNA1 was able to detect all species tested within the family Bromoviridae, including members of the Alfamovirus, Anulavirus, Bromovirus, Cucumovirus and Ilarvirus. The assays provide a sensitive and cost-effective way for detecting and characterising members of the Bromoviridae and can be used for quarantine and certification programmes.

Recombination structure and genetic relatedness among members of the family Bromoviridae based on their RNAs 1 and 2 sequence analyses.

In determining putative recombination events and their evolution rates in the RNAs 1 and 2 of currently the known members of the family Bromoviridae, a detailed study comprising 107 accessions retrieved from the international databases, has been carried out by using RECCO and RDP v3.31beta algorithms. These programs allowed the detection of potential recombination sites in all the five virus genera composing the family Bromoviridae with various degrees of consistency. The RNAs 1 and 2 showed inferred phylogenies fully congruent and clearly delineated five clusters representing the five studied virus genera. In this respect, we proposed to classify the Ilarviruses in three distinct subgroups instead of 10 as mentioned in several reports of the International Committee on Taxonomy of Viruses where its suggestions were based on antigenic differences. Moreover, we confirmed that Alfalfa mosaic virus should be considered as a component of the Ilarvirus genus instead of being the unique representative of Alfamovirus genus. In addition, Pelargonium zonate spot and Olive latent 2 viruses fully deserve their affiliation to the family Bromoviridae.

Evolutionary relationships among members of the Bromoviridae deduced from whole proteome analysis.

Many molecular phylogenies of viruses build upon the analysis of single genes. The study of whole-genomes, however, might yield more reliable information to infer tree topologies and a better approach for drawing the evolutionary history of virus families. In this study, we apply a novel comparative proteomic approach to seek whether incorporating information from the entire proteome would support the actual taxonomy of the family Bromoviridae. Our results suggest that the current taxonomic classification should be modified in several aspects to account for the genomic properties of the Bromoviridae. These differences are: i) Alfalfa mosaic virus (AMV) is a true Ilarvirus instead of constituting an independent genus; ii) Pelargonium zonate spot virus (PZSV) should be considered as a member of the Bromoviridae; and iii) the genus Ilarvirus should be divided into fewer phylogenetic subgroups than suggested by antigenic differences.

A comprehensive open reading frame phylogenetic analysis of isometric positive strand ssRNA plant viruses.

Rigorous large-scale whole genome comparisons are capable of providing more comprehensive and potentially more accurate descriptions of viral relationships, allowing for the effective validation and modification of current taxonomy. Using a set of 5 togaviruses as an outgroup, a comprehensive phylogeny for 115 isometric positive ssRNA plant viruses was generated based on the simultaneous comparison of over 480 ORFs found within completely sequenced genomes. With the exception of a diverse group of viruses representing the family Comoviridae, the single tree generated contained well supported branches corresponding to well established groups of viruses, including Bromoviridae, Umbravirus, Sobemovirus, and Tymoviridae. In addition, evidence for specific relationships between groups were also observed, specifically Tombusviridae + Umbravirus, and Luteoviridae + Sobemovirus. Various well established subgroups of viruses were also well resolved within the tree. In addition, some recent proposals involving the creation of new genera or the inclusion of newly described viruses into established genera were supported, while others were not. The evidence for frequent gene sharing and the potential consequences to viral taxonomy are discussed.

Molecular evolution of the plant virus family Bromoviridae based on RNA3-encoded proteins.

We have carried out an evolutionary study of the two proteins encoded by the RNA 3 from members of the plant virus family Bromoviridae. Using maximum likelihood methods, we have inferred the patterns of amino acid substitution that better explain the diversification of this viral family. The results indicate that the molecular evolution of this family was rather complex, with each protein evolving at different rates and according to different patterns of amino acid substitution. These differences include different amino acid equilibrium frequencies, heterogeneity in substitution rates among sites, and covariation among sites. Despite these differences, the model of protein evolution that better fits both proteins is one specifically proposed for the evolution of globular proteins. We also found evidence for coevolution between domains of these two proteins. Finally, our analyses suggest that the molecular clock hypothesis does not hold, since different lineages evolved at different rates. The implications of these results for the taxonomy of this important family of plant viruses are discussed.

Complete nucleotide sequence of Pelargonium zonate spot virus and its relationship with the family Bromoviridae.

The complete sequence of the Pelargonium zonate spot virus (PZSV) genome was determined. It comprises 8477 nt, distributed in three positive-strand RNA species encoding four proteins. RNA-1 is 3383 nt long, with an ORF that encodes a polypeptide with a molecular mass of 108 419 Da (denoted protein 1a). This protein contains the conserved sequence motifs I-III of type I methyltransferases and the seven consensus motifs of the helicases of superfamily 1. RNA-2 is 2435 nt long and encodes a major polypeptide with a molecular mass of 78 944 Da (denoted protein 2a), which shows identity to the RNA-dependent RNA polymerases of positive-strand RNA viruses. RNA-3 is 2659 nt long and contains two major ORFs. The first ORF is located in the 5' portion of the genome and sequence comparison of the putative translation product revealed similarities with the 30K superfamily of virus movement proteins. The second ORF is located in the 3' half and encodes the viral coat protein, which is expressed via a subgenomic RNA, RNA-4. The transcription initiation site of RNA-4 maps to the intergenic region of RNA-3. The organization of the PZSV genome, including the primary structure of terminal non-coding regions, strongly suggests that this virus belongs to the family Bromoviridae. The overall biological and genomic characteristics of PZSV indicate affinities in diverging directions with one or other of the virus species in this family, thus enabling it to be considered as a possible representative of a new genus within the family Bromoviridae.

Multiplex RT-PCR-ELISA compared with bioassay for the detection of four apple viruses.

A sensitive and reliable multiplex RT-PCR-ELISA technique for the detection of Apple chlorotic leaf spot virus, Apple stem pitting virus, Apple mosaic virus and Apple stem grooving virus was developed. This technique is compared with the method used commonly for indexing by woody indicators, which is time consuming and expensive. For the RT-PCR-ELISA technique, the amplified products were labeled with digoxigenin during the RT-PCR by incorporation of a digoxigenin labeled primer. After hybridization of the PCR products to specific capture oligonucleotides, which were bound covalently to the surface of NucleoLink strips, anti-digoxigenin antibodies were used for detection. More than 100 samples were tested in parallel by indexing and multiplex-RT-PCR-ELISA. All infections detected by woody indicators were also detected by multiplex RT-PCR-ELISA. Furthermore, additional infections were only found by multiplex RT-PCR-ELISA. The colourimetric detection of multiplex-RT-PCR products was at least as sensitive and sometimes slightly more sensitive than detection by gel electrophoresis. The results show that this molecular technique is more reliable for the detection of the above mentioned apple viruses than indexing by woody indicators, thereby helping to reduce cost and time during the certification of plant material.

The complete nucleotide sequence of prune dwarf ilarvirus RNA-1.

The sequence of prune dwarf ilarvirus (PDV) RNA-1 has been determined; it consists of 3,374 nucleotides and contains a single open reading frame of 3,168 nucleotides. The putative translation product is 1,055 amino acids in length with a calculated molecular mass of 118.9 kDa. Both the nucleic acid and the translated amino acid sequences show stronger homology to the corresponding RNA-1 and ORF-1 of apple mosaic ilarvirus and alfalfa mosaic alfamovirus than to spinach latent mosaic ilarvirus or citrus leaf rugose ilarvirus. These findings are consistent with the inclusion of alfalfa mosaic virus in the ilarvirus genus. The reported sequence of PDV RNA-1 and its single ORF conform to the genomic organization typical of the Bromoviridae family.

Oleavirus, a new genus in the family Bromoviridae.

Oleavirus is a monotypic genus having olive latent virus 2 (OLV-2) as the type species. OLV-2 is transmitted by inoculation of sap but not by aphids. Virus particles have different shape and size, ranging from quasi spherical to bacilliform with length of 37, 43, 48, and 55 nm, respectively, and a diameter of ca. 18 nm. Virions do not contain lipids or carbohydrates and possess a single coat protein species with molecular mass of ca. 24 kDa, which is not required for infectivity. Individual particles contain a single molecule of linear, positive sense ssRNA, constituting ca. 19% of their weight. The genome consists of three functional non polyadenylated, capped, positive sense, single-stranded RNA molecules occurring as three functional species of 3126 nt (RNA1, monocistronic), 2734 nt (RNA2, monocistronic), and 2438 nt (RNA3, bicistronic). Virions encapsidate a fourth RNA species 2078 nt in size (RNA4) with no apparent messenger activity. Virus replication is thought to occur in the cytoplasm possibly in connection with vesicular structures. The strategy of replication encompasses proteolytic processing and subgenomic RNA production. Oleavirus does not have a complete straightforward relationship with any of the current genera in the Bromoviridae, but shows homologies in diverging directions with one genus of the family or another.

The nucleotide sequence of RNA1 and RNA2 of olive latent virus 2 and its relationships in the family Bromoviridae.

The complete nucleotide sequence of RNA1 and RNA2 of olive latent virus 2 (OLV-2), a virus with quasi-spherical to bacilliform particles and a non-polyadenylated tripartite ssRNA genome, was determined. RNA1 consists of 3126 nucleotides and contains a single open reading frame (ORF) coding for a polypeptide with a molecular mass of 102689 Da (p1a). RNA2 is also a monocistronic molecule, 2734 nt in length, coding for a polypeptide with a molecular mass of 90631 Da (p2a). The translation products of RNA1 and RNA2 possess the motifs proper to helicase, methyltransferase (RNA1) and RNA polymerase (RNA2), suggesting that both are involved in the replication of the viral RNA. The similarities found between OLV-2 and members of the Bromoviridae in some properties and in the sequences of all genomic products (including p1a and p2a) are strongly indicative that it belongs in this family. OLV-2, however, did not show a direct relationship with any of the current genera in the family. Rather, it revealed homologies in diverging directions with one or other of the Bromoviridae genus, thus qualifying as the possible representative of a new taxon in this family.