The sequencing of the complete genome of a Tomato black ring virus (TBRV) and of the RNA2 of three Grapevine chrome mosaic virus (GCMV) isolates from grapevine reveals the possible recombinant origin of GCMV.

The complete genome of a Tomato black ring virus isolate (TBRV-Mirs) (RNA1, 7,366 nt and RNA2, 4,640 nt) and the RNA2 sequences (4,437; 4,445; and 4,442 nts) of three Grapevine chrome mosaic virus isolates (GCMV-H6, -H15, and -H27) were determined. All RNAs contained a single open reading frame encoding polyproteins of 254 kDa (p1) and 149 kDa (p2) for TBRV-Mirs RNA1 and RNA2, respectively, and 146 kDa for GCMV RNA2. p1 of TBRV-Mirs showed the highest identity with TBRV-MJ (94 %), Beet ringspot virus (BRSV, 82 %), and Grapevine Anatolian ringspot virus (GARSV, 66 %), while p2 showed the highest identity with TBRV isolates MJ (89 %) and ED (85 %), followed by BRSV (65 %), GCMV (58 %), and GARSV (57 %). The amino acid identity of RNA2 sequences of four GCMV isolates (three from this study and one from GenBank) ranged from 91 to 98 %, the homing protein being the most variable. The RDP3 program predicted putative intra-species recombination events for GCMV-H6 and recognized GCMV as a putative inter-species recombinant between GARSV and TBRV. In both cases, the recombination events were at the movement protein level.

Production of antibodies to Little cherry virus 1 coat protein by DNA prime and protein boost immunization.

Little cherry, an economically important disease of cherry is caused by at least two different viruses. One of these is Little cherry virus 1 (LChV-1) for the detection of which no efficient serological tools are available, so that diagnosis is based on molecular methods. In this study, different immunization strategies for producing antibodies against the viral coat protein of LChV-1 were tried, using either purified virus preparations, or bacterially expressed protein, or a DNA vector that expressed the cloned coat protein (CP) gene in vivo. Effective induction of specific antibodies to LChV-1 CP was obtained using DNA intramuscular immunization followed by a single boost with the recombinant protein. The entire coat protein sequence was cloned in a mammalian expression vector and, after being coated by an amphiphilic non-toxic reagent was delivered into rabbit. A protein boost increased the specific immune response against the virus protein. The sensitivity of this antiserum is lower if compared with that of antisera raised conventionally against other viruses, thus it requires improvements for use for diagnostic purposes.

Isolation and pathogenicity of Xylella fastidiosa associated to the olive quick decline syndrome in southern Italy.

In autumn 2013, the presence of Xylella fastidiosa, a xylem-limited Gram-negative bacterium, was detected in olive stands of an area of the Ionian coast of the Salento peninsula (Apulia, southern Italy), that were severely affected by a disease denoted olive quick decline syndrome (OQDS). Studies were carried out for determining the involvement of this bacterium in the genesis of OQDS and of the leaf scorching shown by a number of naturally infected plants other than olive. Isolation in axenic culture was attempted and assays were carried out for determining its pathogenicity to olive, oleander and myrtle-leaf milkwort. The bacterium was readily detected by quantitative polymerase chain reaction (qPCR) in all diseased olive trees sampled in different and geographically separated infection foci, and culturing of 51 isolates, each from a distinct OQDS focus, was accomplished. Needle-inoculation experiments under different environmental conditions proved that the Salentinian isolate De Donno belonging to the subspecies pauca is able to multiply and systemically invade artificially inoculated hosts, reproducing symptoms observed in the field. Bacterial colonization occurred in prick-inoculated olives of all tested cultivars. However, the severity of and timing of symptoms appearance differed with the cultivar, confirming their differential reaction.

The role of the C-terminal region of olive latent virus 1 coat protein in host systemic infection.

A full-length cDNA clone of olive latent virus 1 (OLV-1), a member of the genus Necrovirus, family Tombusviridae, was subjected to site-directed mutagenesis, and coat protein gene mutants were constructed. A mutant clone, denoted Delta3297, was obtained by deleting the nucleotide in position 3297, thus inducing a frameshift and replacing the last 49 amino acids of the viral coat protein (CP) by a shorter sequence of 39 amino acids. This mutant was viable, stable, able to synthesize a smaller CP, and able to give rise to the formation of apparently intact virus particles. Cell-to-cell movement of Delta3297 in Nicotiana benthamiana leaves was not affected, but, contrary to wild type OLV-1, it failed to spread systemically. These results indicate that virion formation is necessary but not sufficient for long-distance movement for OLV-1 and highlights the role of the CP carboxy-terminal domain in systemic infection.

Identification of an RNA-silencing suppressor in the genome of Grapevine virus A.

Higher plants use post-transcriptional gene silencing (PTGS), an RNA-degradation system, as a defence mechanism against viral infections. To counteract this, plant viruses encode and express PTGS suppressor proteins. Four of the five proteins encoded by the Grapevine virus A (GVA) genome were screened using a green fluorescent protein (GFP)-based transient expression assay, and the expression product of ORF5 (protein p10) was identified as a suppressor of silencing. ORF5 p10 suppressed local and systemic silencing induced by a transiently expressed single-stranded sense RNA. This protein was active towards both a transgene and exogenous GFP mRNAs. Ectopic expression of GVA-ORF5 by a Potato virus X vector enhanced symptom severity. The findings that p10 markedly reduces the levels of small interfering RNAs (siRNAs) and that the recombinant protein is able to bind single-stranded and double-stranded forms of siRNAs and microRNAs, suggest the existence of a potential mechanism of suppression based on RNA sequestering.

Subcellular localization and immunodetection of movement proteins of olive latent virus 1.

Polyclonal sera raised to Escherichia coli-expressed movement proteins encoded by ORF 3 (p8K) and ORF 4 (p6K) of olive latent virus 1, were used for their immunodetection in infected Nicotiana benthamiana plants. In subfractionated locally infected tissues 4 days post inoculation (d.p.i.) that were analysed by Western blot, p8K was found in the fast-sedimenting fractions P1 and P30 containing membranous material and/or cell organelles and, likely, the fibrous structures mentioned below, but not in the soluble protein-containing supernatant. No p6K could be detected in these extracts. In locally inoculated leaves p8K began to accumulate from 2 d.p.i onwards reaching its peak at 4 d.p.i. Intracellular immunogold labelling of cells from locally and systemically infected tissues localized p8K primarily in fibrous inclusions made up of thin filaments with a helical structure present in the cytoplasm of locally and systemically infected cells. In systemic infections a light and scattered labelling was observed in the cytoplasm and near the cell wall. The specific serum to p6K did not label the fibrous structures and failed to recognize its antigen in systemically and locally infected tissues except at 4 d.p.i., when scattered labelling was observed in the cytoplasm and near plasmodesmata.

Genetic variability and population structure of Grapevine leafroll-associated virus 3 isolates.

The genetic variability and population structure of a collection of 45 Grapevine leafroll-associated virus 3 (GLRaV-3) isolates were studied by single-stranded conformation polymorphism (SSCP) and sequence analysis of the RNA-dependent RNA polymerase (RdRp), heat-shock protein 70 homologue (HSP-70) and coat protein (CP) genes. The distribution of SSCP profiles was not correlated with the geographical origin of the isolates, indicating that GLRaV-3 is a single, undifferentiated population. The majority of the isolates showed an SSCP profile and a population structure that were composed of a single predominant variant. However, 10% of the isolates for the RdRp and HSP-70 genes and 15% for the CP gene were composed of a combination of two or more variants. Estimation of genetic diversity and phylogenetic analysis disclosed the possible existence of vines with mixed infections by diverging sequence variants, showing, in some cases, possible recombination events. Furthermore, differences in the genetic diversity and constraints existing in the three regions analysed indicated a higher variability in the CP gene. The epidemiological and biological implications of this finding are discussed.

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.

Foveavirus, a new plant virus genus.

Foveavirus is a novel genus of plant viruses with helically constructed filamentous particles ca. 800 nm long, typified by apple stem pitting virus (ASPV). Virions do not contain lipids or carbohydrates, have a positive sense, single-stranded, polyadenylated RNA genome 8.4 to 9.3 kb in size, and a single type of coat protein with a size of 28 to 44 kDa. The genome of definitive viral species is made up of five ORFs encoding respectively, the replication-related proteins (ORF 1), the putative movement proteins (ORF 2 to 4, constituting the triple block gene), and the coat protein (ORF 5). Virions accumulate in the cytoplasm, where replication is likely to occur with a strategy comparable to that of potexviruses, based on direct expression of the 5'-proximal ORF, and expression of downstream ORFs through subgenomic RNAs. No vector is known. Virus transmission is by grafting, and dispersal is through infected propagating material. The genome structure and organization (i.e., number and order of genes) closely resembles that of the genera Potexvirus, Carlavirus and Allexvirus, but ORF 1 and the coat protein cistron (ASPV only) are significantly larger.

Ultrastructure of turnip crinkle- and saguaro cactus virus-infected tissues.

An electron microscope study of different hosts infected with turnip crinkle (TCV) and saguaro cactus (SCV) viruses, two tentative members of the tombusvirus group, was carried out. Particles of both viruses were readily detected in cells of different tissues, in the cytoplasm of which they occurred in great numbers, though not in crystalline arrays. Cytological modifications of various types were also observed. The most striking of these was an extensive peripheral vesiculation of mitochondria in TCV-infected cells, which was accompanied by plastic activity of the organelles that often engulfed portions of ground cytoplasm and virus particles. Cytoplasmic inclusion bodies were not present. Likewise, none of the cytopathological features characterizing tombusvirus infections was observed. No indications were obtained to support the idea that TCV and SCV may continue to be considered members, even though tentative, of the tombusvirus group.

Nucleotide sequence of the 3' terminal region of the RNA of two filamentous grapevine viruses.

The 3' terminal region of grapevine virus A (GVA) and grapevine virus B (GVB), encompassing 1883 and 2136 nucleotides, respectively, was sequenced by the deoxynucleotide chain termination method. Three putative open reading frames (ORF) were identified in both genomic viral RNAs, denoted 1 to 3 in the 5' to 3' direction. ORF 1 encoded a polypeptide with estimated M(r) of 31 kDa (GVA) and 36.5 kDa (GVB), possessing the G/D motif of the "30 K superfamily" movement proteins, and showing good alignments with putative movement proteins of trichoviruses and capilloviruses. ORF 2 was identified as the coat protein (CP) cistron, coding for polypeptides with an estimated M(r) of 21.5 kDa (GVA) and 21.6 kDa (GVB). These CPs showed substantial sequence homology with one another and with CPs of tricho- and capilloviruses, but not of closteroviruses. ORF 3 potentially coded for two small polypeptides with estimated M(r) of 10 kDa (GVA) and 14 kDa (GVB). The ORF 3 product of GVB (14 K), but not that of GVA, shared some homology with the 3' terminal polypeptides of different plant viruses that exhibit the "zinc finger domain" of proteins with nucleic acid-binding properties. GVA and GVB have many properties in common with trichoviruses but possess an extra open reading frame (ORF 3). Whether this finding may have a bearing on the classification of these viruses is unclear. However, until the taxonomic significance of this difference in genome structure is established, it seems plausible to include GVA and GVB as tentative species in the Trichovirus genus.

Cytopathology in the identification and classification of tombusviruses.

Ten recognized members of the tombusvirus group, including two strains of tomato bushy stunt virus, were compared for their ultrastructural effects in Nicotiana clevelandii, Gomphrena globosa, and Chenopodium quinoa. The cytopathic inclusions known as multivesicular bodies and tonoplast evaginations containing virus particles were induced by all the viruses in all three hosts. Some of the viruses could be differentiated from each other (especially in C. quinoa) by other characters, such as the accumulation of membranes in cell nuclei, or the type of organelle (chloroplasts, mitochondria or peroxisomes) from which multivesicular bodies developed. The usefulness of these characters for virus identification and grouping is discussed.

Complete nucleotide sequence of RNA-2 of Olive latent ringspot virus.

The complete nucleotide sequence of Olive latent ringspot virus (OLRSV) RNA-2 was determined. This RNA is 3969 nucleotides in length and contains a single open reading frame of 3448 nt, that encodes a polypeptide of 1146 amino acids, with a calculated Mr of 126,044. OLRSV RNA-2 has a structural organization typical of nepoviruses, with the coat protein (CP) cistron located in the C-terminal and the putative movement protein (MP) in the N-terminal regions of the polyprotein. Computer-assisted comparison of coat proteins of OLRSV and other nepoviruses disclosed relationships that tally with subgrouping based on physicochemical properties.

Grapevine virus A: nucleotide sequence, genome organization, and relationship in the Trichovirus genus.

The 5' terminal region of the genomic RNA of grapevine virus A (GVA), a tentative member of the Trichovirus genus, encompassing 5466 nucleotides, was sequenced. Evidence was obtained that the RNA is capped. Two putative open reading frames (ORF) were identified: ORF 1 that codes for a 194 kDa polypeptide with conserved motifs of replication-related proteins of positive-strand RNA viruses, and ORF 2 that encodes a 19 kDa polypeptide with no significant homology with protein sequences from databases. This polypeptide, however, showed 44% similarity with the product expressed by a comparable ORF present in grapevine virus B (GVB). GVA genome had the same size and structural organization as that of GVB. It also had the same size of the genome of apple chlorotic leaf spot virus (ACLSV), the type species of the Trichovirus genus, but differed substantially in the number (5 versus 3), size, and order of genes. Differences existed also in the degree of sequence homology between polymerases, which did not cluster together in phylogenetic trees. Definitive (ACLSV, PVT) and tentative (GVA, GVB) trichovirus species differ molecularly, biologically and epidemiologically to an extent that warrants the taxonomic revision of the genus.

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.

The nucleotide sequence and genomic organization of grapevine virus B.

Grapevine virus B (GVB) is a tentative member of the genus Trichovirus. The 5'-terminal region of the RNA genome of GVB comprises 5437 nucleotides and has been sequenced by the dideoxynucleotide chain termination method. Evidence was obtained that the RNA is capped. Two putative open reading frames (ORFs) were identified. ORF 1 coded for a 194.7 kDa polypeptide with conserved motifs of replication-related proteins of positive-strand RNA viruses (i.e. methyltransferase, helicase and RNA-dependent RNA polymerase, in that order from the N to the C terminus). ORF 2 encoded a 20 kDa polypeptide that did not show any significant sequence homology with protein sequences from the databases. The biological function of this polypeptide was not determined. Although the 20 kDa product was expressed as a fusion protein with glutathione S-transferase in Escherichia coli and an antiserum produced, it could not be identified in GVB-infected plant tissue extracts. The GVB genome had the same size as that of apple chlorotic leaf spot virus (ACLSV), the type species of the genus Trichovirus, but differed substantially in the number (five compared to three), size and order of genes. Differences existed also in the extent of sequence homology between polymerases, which did not cluster together in tentative phylogenetic trees. The results of this study show that definitive and tentative trichovirus species differ molecularly to an extent that may warrant a taxonomic revision of the genus.

The nucleotide sequence of RNA3 and RNA4 of olive latent virus 2.

Olive latent virus 2 (OLV2), a virus with particle shapes resembling those of alfalfa mosaic alfamovirus (AMV), has four major RNA species, two of which (RNA3 and RNA4) were completely sequenced. RNA3 was a bicistronic molecule containing two clear-cut ORFs, one of which (ORF1) coded for a 36.5 kDa polypeptide with conserved motifs of the '30K superfamily' movement proteins and the other (ORF2) encoded a 20 kDa polypeptide identified as the viral coat protein. RNA4, which was a little smaller than RNA3 (2078 nt versus 2438 nt), also differed from RNA3 in a few positions, but its in vitro translation did not produce any protein. By contrast, an additional RNA, 1042 nt in size with strong sequence homology with RNA3 and RNA4, was identified in RNA extracts from infected plants. This RNA, which may be a subgenomic form of RNA3 carrying the coat protein cistron, is apparently encapsidated to a very small extent, or not at all. Comparative computer-assisted analysis of virus-coded protein sequences disclosed homologies suggesting that OLV2 may belong to the family Bromoviridae, but as an entity separated from the currently known genera.

Nucleotide sequence of the genome of a citrus isolate of olive latent virus 1.

The 3699 nt genome of olive latent virus 1 (OLV-1), described years ago from Southern Italy as a putative sobemovirus, was completely sequenced. OLV-1 genomic RNA was not polyadenylated and had a structure virtually identical to that of species of the Necrovirus rather than the Sobemovirus genus. Five open reading frames (ORFs) were identified, of which the 5'-proximal encoded a 23K protein and ended with an amber codon whose readthrough could yield a putative 82K product. This polypeptide had extensive sequence similarity with polymerases of serotypes A and D of tobacco necrosis necrovirus (TNV-A and TNV-D) and species of the family Tombusviridae and related genera (Dianthovirus and Machlomovirus). Two small ORFs followed, which encoded polypeptides of 8K and 6K, respectively. The 6K product had extensive homology with the comparable 6K protein of TNV-A and was also related to the 11K protein of shallot latent carlavirus, one of the "triple block" polypeptides involved in cell-to-cell virus movement. The 3'-proximal ORF was in the same position as the coat protein (CP) cistron of necroviruses and encoded a 30K product related to CP of both TNV-A and -D. Computer-assisted comparative analysis of structural and non-structural proteins of OLV-1, TNV-A and TNV-D disclosed on overall distant relationship between OLV-1 and TNV-D. OLV-1 genome appeared homologous to that of TNV-A, but differences from TNV-A were the absence of the small ORF downstream of the CP cistron and in the low degree of sequence identity in CP (39% aa identity). OLV-1 is serologically distantly related to TNV-A and even more distantly related to TNV-D. We propose that OLV-1 is a necrovirus species in its own right.

Sequence analysis of pothos latent virus genomic RNA.

The complete genomic sequence of pothos latent virus (PoLV) has been determined. The genome organization is very similar to that of tombusviruses. The genome is 4415 nucleotides long and contains five ORFs. The 5' ORF (ORF 1) encodes a protein with a predicted molecular mass of 25 kDa and readthrough of its amber stop codon results in an 84 kDa protein (ORF 2). ORF 3 encodes the 40 kDa capsid protein. Two nested ORFs (ORFs 4 and 5) in different reading frames encode 27 and 14 kDa proteins, respectively. Amino acid sequence alignments revealed significant similarities between the readthrough portion of ORF 2 and the coat protein (ORF 3) of PoLV and the corresponding proteins of several tombusviruses. Conversely, the predicted products of ORFs 1, 4 and 5 showed only limited similarity to the equivalent tombusvirus proteins. These results support the conclusion that PoLV is a new but atypical member of the family Tombusviridae.