Comparison of three techniques for detection of grapevine leafroll-associated virus 1

Thirty seven plants of grapevine from the Research Station of Viticulture, Karlstejn was examined for the presence of leafroll viruses. Grapevine leafroll-associated virus 1 (GLRaV-1) was detected in the grapevines plants tested using double-antibody sandwich ELISA (DAS-ELISA), RT-PCR and molecular hybridization with non-radioactive RNA probes. Both molecular methods were based on a detection of the GLRaV-1 heat-shock protein 70 (HSP70) gene and showed a higher sensitivity in the detection of GLRaV-1 compared to DAS-ELISA. RNA probes are considered more suitable for the GLRaV-1 detection, as their application can overcome potential minor sequence variability, which may cause the detection by RT-PCR less reliable, especially when the variability occurs in the genome region targeted by RT-PCR primers. Based on additional DAS-ELISA, a mixed infection of GLRaV-1 and Grapevine leafroll-associated virus 3 (GLRaV-3) occurred frequently, while a mixed infection of GLRaV-1 and Grapevine virus A (GVA) or Grapevine fleck virus (GFkV) or a multiple infection of GLRaV-1, GLRaV-3 and GFkV occurred rarely in the tested plants. A mixed infection of all the four viruses mentioned above was not observed.     

Molecular characterization and taxonomy of grapevine leafroll-associated virus 7

The complete nucleotide sequence of an Albanian isolate of grapevine leafroll-associated virus 7 (GLRaV-7-Alb) was determined. The viral genome consists of 16,404 nucleotides and has nine open reading frames (ORFs) that potentially encode proteins, most of which are typical for members of the family Closteroviridae. Only the 25-kDa (ORF8) and 27-kDa (ORF9) proteins had no apparent similarity to other viral proteins in the sequence databases. The genome structure of GLRaV-7-Alb closely resembles that of little cherry virus 1 and cordyline virus 1. In phylogenetic trees constructed with HSP70h sequences, these three viruses cluster together in a clade next to that comprising members of the genus Crinivirus, to which they are more closely related than to the clostero- and ampeloviruses. The molecular properties of these three viruses differ sufficiently from those of members of the three extant genera of the family Closteroviridae to warrant their classification in a novel genus.     

Macroarray detection of grapevine leafroll-associated viruses

Grapevine leafroll-associated viruses (GLRaVs) are an emerging group of viruses that represent a significant threat to the global productivity and sustainability of the grapevine industry. Their control is achieved through the identification and elimination of infected vines, and the use of planting material derived from virus-tested, certified stocks. As such, much effort has been invested in developing reliable molecular diagnostic techniques. In this work, we report the development of a macroarray assay for the detection of the principal GLRaVs. In total 314 70-mer oligonucleotides specific to GLRaV-1, -2, -3, -4, -7, and GLRaV-4 strains 5, 6, 9 and Pr were spotted onto a 11×7cm nylon membrane. Thirty-four grapevine samples from various origins were tested by the macroarray, RT-PCR and ELISA. Thirty were positive for virus infection using RT-PCR, 28 by ELISA and 25 by the macroarray. Mixed infections were identified by macroarray in two samples and confirmed by RT-PCR or ELISA. There were a few discrepancies between methods that were most likely due to differences in the sensitivity of detection, and in the case of the macroarray, limitations in the sequence data available for certain virus species in the design of the oligonucleotides. This work demonstrates the successful application of macroarray methodology using randomly primed and sequence-nonspecific amplified cDNAs derived from grapevine total RNA extracts, and provides a proof-of-principal for unbiased multiplex detection using a single robust platform.     

Five phylogenetic groups identified in the coat protein gene of grapevine leafroll-associated virus 3 obtained from Portuguese grapevine varieties

The genetic variability and population structure of grapevine leafroll-associated virus 3 (GLRaV-3) variants were updated by examining the diversity within the viral coat protein (CP) gene among 174 isolates belonging to a collection of Vitis vinifera representing most of the Portuguese varieties. Phylogenetic analysis revealed the existence of five well-defined clusters. Three of these correspond to previously defined groups, another corresponds to variants from Chile for which only one sequence has been previously identified, and an additional new group includes only Portuguese variants. A typing tool based on asymmetric PCR-ELISA (APET) was developed within the frame of this population structure. This tool was used to assess the prevalence of each phylogenetic group among the infected grapevine varieties. Although most of the isolates harbour variants from groups 1 and 2, variants from the remaining three groups exist in a number of varieties, reinforcing the notion that they are genuine genomic variants and are not isolated, atypical cases.     

Genetic diversity and recombination analysis in the coat protein gene of Banana bract mosaic virus

Banana bract mosaic virus (BBrMV), a member of the genus Potyvirus, family Potyviridae, is the causal agent of the bract mosaic disease (BBrMD) that causes serious yield losses in banana and plantain in India and the Philippines. In this study, global genetic diversity and molecular evolution of BBrMV based on the capsid protein (CP) gene were investigated. Multiple alignments of CP gene of 49 BBrMV isolates showed nucleotide (nt) and amino acid (aa) identity of 79–100 and 80–100 %, respectively. Phylogenetic analysis revealed that except two Indians isolates (TN14 and TN16), all isolates clustered together. Eleven recombination events were detected using Recombination Detection Program. Codon-based maximum-likelihood methods revealed that most of the codons in the CP gene were under negative or neutral selection except for codons 28, 43, and 92 which were under positive selection. Gene flow between BBrMV populations of banana and cardamom was relatively frequent but not between two different populations of banana infecting isolates identified in this study. This is the first report on genetic diversity, and evolution of BBrMV isolates based on recombination and phylogenetic analysis in India.     

Molecular characterisation of two divergent variants of grapevine leafroll-associated virus 3 in New Zealand

Partial genomic sequences of two divergent grapevine leafroll-associated virus 3 (GLRaV-3) variants, NZ1-B and NZ2, from New Zealand were determined and analysed (11,827 nt and 7,612 nt, respectively). At the nucleotide level, both variants are more than 20 % different from the previously published GLRaV-3 sequences, from phylogenetic groups 1 to 5. Phylogenetic analysis indicated that NZ1-B is a variant of the previously identified divergent NZ-1, while NZ2 is a novel sequence with only 76 % nucleotide sequence identity to GLRaV-3 variants NZ-1, GH11, and GH30. Therefore, NZ2 is a new variant of GLRaV-3. Amino acid sequence analysis of the NZ1-B and NZ2 coat proteins indicated significant substitutions that are predicted to alter the coat protein structure, which potentially leads to the observed reduced immunological reactivity of both variants to the Bioreba anti-GLRaV-3 conjugated monoclonal antibody.     

Biological,molecular, and serological studies of a novel strain of grapevine leafroll-associated virus 2

In California, a novel closterovirus was detected in “Redglobe” grapevine, associated with graft incompatibility and given a trivial name “Grapevine rootstock stem lesion associated virus (GRSLaV).” The biological properties of the putative virus were ascertained when asymptomatic yet infected Redglobe scion buds were graft-inoculated onto test plants of Cabernet Sauvignon propagated on 18 different rootstocks. It proved lethal on test plants growing on rootstocks 1616C, 5BB, 5C, 3309C, and 1103 P, whereas latent infections occurred on the remaining scion-rootstock combinations. In contrast, GLRaV-2 type (type strain) produced only typical leafroll symptoms. In a different experiment, GLRaV-2 type was successfully sap-transmitted to N. benthamiana, whereas sap transmission of GRSLaV was unsuccessful. Double-stranded RNA was extracted from infected Redglobe grapevines, cloned, sequenced, and determined a genome length of 16,527 nucleotides. Computer-assisted analysis of open-reading frames (ORFs) revealed a genome organization typical of monopartite viruses in the genus Closterovirus with nine ORFs (range 71–79% identity) with GLRaV-2 type, the closest similar virus species within the family Closteroviridae. Also the 3′-UTR of GRSLaV consisted of 223 nucleotides with an extended oligo(A) tract similar to that of GLRaV-2 type, Beet yellow stunt virus, and Beet yellows virus. Recombinant GRSLaV coat protein was expressed in E. coli, purified, and immunized a rabbit to produce polyclonal antiserum. Serological data matched the molecular data, whereby exposed plant tissue extracts of grapevines infected by both viruses (GRSLaV and GLRaV-2) reacted positively with homologous and heterologous viral antisera but not with healthy grapevine extracts in ELISA and Western blot tests. Based on the comparative sequence data and shared antigens, GRSLaV is now considered a strain of GLRaV-2 and redesignated as Grapevine leafroll associated virus-2 Redglobe (GLRaV-2RG). Primers specific for GLRaV-2RG were developed, which did not amplify GLRaV-2 type strain. When both sets of specific primers were used in assays of different grapevine collections, the incidence of the respective viruses varied considerably, e.g., 1.7 and 13.5%, respectively, for GLRaV-2RG and GLRaV-2 type.     

Genetic diversity and recombination of porcine sapoviruses

Sapoviruses (SaVs) are emerging enteric pathogens that cause diarrhea in humans and animals. Human SaVs are genetically variable and have been classified into four genogroups (GI, -II, -IV, and -V). To date, only two genetically similar porcine SaV strains have been reported that belong to GIII. To investigate the genetic diversity of porcine SaVs and their genetic relatedness to human strains, we sequenced 286 nucleotides (nt) of the RNA-dependent RNA polymerase (RdRp) region of nine porcine SaVs detected from field pig fecal samples collected in U.S. swine farms during the period from 1999 to 2003. One strain (Po/SaV/MI-QW19/2002/US) was most closely related to human GII SaVs. We also sequenced 3 kb of the viral genome, including the partial RdRp (766 to 790 nt), the complete capsid, the ORF2 and the 3'-untranslated region of four strains representative for the positive farms or for the distinct genetic clusters. From the sequence analysis of the complete capsid, we identified a potential new genogroup of porcine SaVs, with Po/SaV/OH-JJ681/00/US as the representative strain. Furthermore, two potential porcine SaV recombinants were identified. To our knowledge this is the first report of a porcine SaV strain more closely related genetically to human SaVs and the occurrence of porcine SaV recombinants. The presence of porcine SaVs more similar to human SaVs is a significant finding because of the potential for zoonotic infections or generation of porcine/human recombinants if intragenogroup human strains exist.     

Improved detection of grapevine leafroll-associated virus 1 by magnetic capture hybridisation RT-PCR on a conserved region of viral RNA

Summary. We report the development of a sensitive diagnostic method for the detection of the grapevine leafroll-associated virus 1 (GLRaV-1). We have considered the current shortcoming in detection of GLRaV-1 to be linked to two factors, sequence variation in the viral RNA and low template concentration. Sequence information available allowed the selection of optimal target sequences for detection by RT-PCR, having high copy number and low levels of sequence variation. This was combined with the use of magnetic capture hybridisation to allow the removal of RT-PCR inhibitors and the addition of 100-fold excess template RNA to a single RT-PCR. The reproducibility of the technique was confirmed using field samples.     

Complete nucleotide sequence of a new strain of grapevine leafroll-associated virus 3 in South Africa

The complete genome sequences of two newly identified genetic variants of grapevine leafroll-associated virus 3 (GLRaV-3) are described. Two isolates, GH11 (18671 nt) and GH30 (18576 nt) were sequenced and found to be less than 70?% similar to other South African GLRaV-3 variants. The genome organization of GH11 and GH30 is similar to that of previously described GLRaV-3 isolates. However, no corresponding open reading frame 2 (ORF2) could be identified. Phylogenetic analysis indicates that GH11 and GH30 cluster in a subgroup (group VI) that is separate from the previously described GLRaV-3 isolates and should be regarded as a different strain of GLRaV-3.     

A sensitive one-step real-time RT-PCR method for detecting Grapevine leafroll-associated virus 2 variants in grapevine

Grapevine leafroll syndrome is caused by a complex of up to nine different Grapevine leafroll-associated viruses (GLRaV-1-9) with GLRaV-2 being reported as one of the most variable species of this group. Many methods, including indexing, serological and molecular procedures, have been developed for the detection of GLRaV-2. However, due to the low concentration of the virus in plants and the high variability of GLRaV-2, a method with improved sensitivity and with the capacity to detect of all known variants is required. Such improvement is essential for grapevine rootstocks, as these are suspected to harbour frequent GLRaV-2 infections difficult to detect, thus contributing to the spread of the leafroll disease. The development of new universal primers is described using a target sequence located in the 3' end of the virus genome. These primers were combined with a one-step SYBR Green real-time RT-PCR assay to achieve quantitative detection. All 43 GLRaV-2 isolates tested in this study were identified readily and reproducibly, regardless of their geographical origin or variety of grapevine. Using the procedure developed in this study, the sensitivity was increased 125 times compared to a conventional single-tube RT-PCR. This real-time method opens new perspectives for the sanitary selection of grapevine and in leafroll 2 disease monitoring.     

Occurrence of grapevine leafroll-associated virus 5 in Portugal: genetic variability and population structure in field-grown grapevines

A comparison of 15 field isolates of grapevine leafroll-associated virus 5 (GLRaV-5) was conducted, based on the analysis of nucleotide sequences of two viral ORFs: the coat protein (CP) and the heat shock protein 90 homolog (HSP90h). After amplification and cloning, the population of viral sequences was analyzed for each isolate, revealing the within-isolate presence of sequence variants for both genes, with one or more major CP variants. Phylogenetic analysis showed the gene sequence variants detected to be exclusive for each isolate. These data, together with estimates of genetic diversity and positive selection, did not reveal evidence of vector-mediated transfer of GLRaV-5. Conversely, a strong effect of host vegetative propagation on divergence dynamics of GLRaV-5 variants was suggested by the isolates from this work The phylogeny of the CP gene further revealed clustering of GLRaV-5 isolates into eight lineages, four of which were detected in our study, revealing a higher diversity than previously described. The information gathered also contributes to firmly establishing GLRaV-5 as a cohesive taxonomic group within the ampeloviruses.     

An assay for the detection of grapevine leafroll-associated virus 3 using a single-chain fragment variable antibody

Grapevine leafroll-associated virus 3 (GLRaV-3) is a major pathogen of grapevine. A previously described single-chain fragment variable (scFv) antibody (scFvLR3), directed against the coat protein (CP) of GLRaV-3, was expressed in Escherichia coli and used to develop a diagnostic ELISA kit. The antibody was fused to the light chain constant domain of human immunoglobulin to create the bivalent reagent C_L-LR3, which was purified from the periplasmic fraction, giving a yield of ~5 mg/l. The sensitivity of the reagent against recombinant GLRaV-3 CP was 0.1 ng. The sensitivity, specificity and durability of the reagent was similar to a commercial kit. The C_L-LR3 showed a weak cross-reaction in immune electron microscopy assays to GLRaV-1 and -7, but not with the phylogenetically more distant GLRaV-2. A fully recombinant kit was developed with the inclusion of a recombinant GLRaV-3 CP expressed in bacteria, thus avoiding problems associated with virus propagation and purification. This system represents a rapid, simple, sensitive and standardized diagnostic protocol for GLRaV-3 detection.     

Genetic diversity and positive selection analysis of classical swine fever virus isolates in south China

Classical swine fever virus (CSFV) causes a highly contagious disease that leads to significant economic losses in the pig industry worldwide. However, there is a paucity of knowledge on the accurate genotyping of CSFV isolates in south China. This study genotyped the E2 gene of 14 CSFV strains isolated during 2008-2010 from domestic pigs in different districts of south China. Phylogenetic analyses revealed that all of the 14 CSFV isolates were clustered into genetic subgroup 1.1. This contrasts with most parts of China, where group 2 isolates are predominant. Furthermore, the positive selection pressures acting on the E(rns) and E2 envelope protein genes of CSFV were assessed and a site-by-site analysis of the dN/dS ratio was performed to identify specific codons that undergo diversification under positive selection. While no significant evidence for positive selection was observed in E(rns), two positively selected sites at amino acid residues 49 and 72 in the E2 encoding region were identified. Our results revealed that a predominance of subgroup 1.1 CSFV isolates is currently circulating in some districts of south China, which appear to be unrelated to the Chinese C-strain vaccine. Moreover, the envelope protein gene, E2, has undergone positive selection in 14 CSFV strains and two positively selected sites have been identified in this study. Understanding the molecular epidemiology and functional importance of these positively selected amino acid positions could help to predict possible changes in virulence, the development of vaccines and disease control.     

Distribution, genetic diversity and recombination analysis of Citrus tristeza virus of India

Citrus tristeza virus (CTV) isolates representing all the citrus-growing geographical zones of India were analyzed for nucleotide sequence of the 5'ORF1a fragments of the partial LProI domain and for the coat protein (CP) gene. The nucleotide sequences were compared with previously reported Indian and CTV genotypes from GenBank. The Indian isolates had 80-99 % sequence identity for the 5'ORF1a and 89-99 % identity for the CP genes. In phylogenetic tree analysis, all the Indian and previously reported isolates segregated into eight clades or groups for the 5'ORF1a region. Indian CTV isolates were clustered in all the clades, four of which, D13, K5, BAN-1, and B165, consisted of only Indian isolates. Phylogenetic tree analysis of the CP genes resulted in seven clades. Indian CTV isolates clustered in six of them, and clades I and VI consisted of only Indian isolates. In the phylogenetic tree the Indian CTV isolates clustered in different groups regardless their geographical origin. Diversities in CTV isolates within individual citrus farms were highlighted. Because incongruent phylogenetic relationships were observed for both of the genomic regions, 5'ORF1a and CP gene, recombination analysis was performed using program RDP3. This analysis detected potential recombination events among the CTV isolates which involved exchange of sequences between divergent CTV variants. The SplitsTree analysis showed evidence of phylogenetic conflicts in evolutionary relationships among CTV isolates.     

Phylogenetic analysis of partial S1 and N gene sequences of infectious bronchitis virus isolates from Italy revealed genetic diversity and recombination

A total of ten infectious bronchitis virus (IBV) isolates collected from commercial chickens in Italy in 1999 were characterized by RT-PCR and sequencing of the S1 and N genes. Phylogenetic analysis based on partial S1 gene sequences showed that five field viruses clustered together with 793/B-type strains, having 91.3–98.5% nucleotide identity within the group, and one isolate had very close sequence relationship (94.6% identity) with 624/I strain. These two IBV types have been identified in Italy previously. The other three variant isolates formed novel genotype detected recently in many countries of Western Europe. For one of these variant viruses, Italy-02, which afterwards became the prototype strain, the entire S1 gene was sequenced to confirm its originality. In contrast, phylogenetic analysis of more conserved partial N gene sequences, comprising 1–300 nucleotides, revealed different clustering. Thus, three variant IBVs of novel Italy-02 genotype, which had 96.7–99.2% S1 gene nucleotide identity with each other, belonged to three separate subgroups based on N gene sequences. 624/I-type isolate Italy-06 together with Italy-03, which was undetectable using S1 gene primers, shared 97.7% and 99.3% identity, respectively, in N gene region with vaccine strain H120. Only one of the 793/B-type isolates, Italy-10, clustered with the 793/B strain sharing 99.3% partial N gene identity, whereas the other four isolates were genetically distant from them (only 87.7–89.7% identity) and formed separate homogenous subgroup. The results demonstrated that both mutations and recombination events could contribute to the genetic diversity of the Italian isolates. The nucleotide sequences reported in this paper have been submitted to the EMBL/GenBank database and have been assigned the accession numbers AJ458958, AJ457137, AJ458959, AJ491327, AJ458960–AJ458964 for the S1 gene and AM260961–AM260970 for the N gene.