Prunus necrotic ringspot virus isolates in stone fruit germplasm accessions and cultivars in Israel

Prunus necrotic ringspot virus (PNRSV) was detected in almonds, plum and apricot germplasm accessions and local almond cultivars in Israel. PNRSV was widespread both in wild and cultivated almond trees and uncommon in wild apricots and plums. The possible variation among the PNRSV isolates was initially evaluated by restriction analysis of PCR products representing the CP gene with the endonuclease RsaI and followed by nucleotide sequence analysis of selected isolates. It was concluded that all 13 isolates belong to group PV96, the largest cluster of PNRSV isolates, described previously. Two PNRSV isolates, one from a plum accession and one from an almond cultivar, were found to be distinct members of group PV96 with unique nucleotide modifications not found in other documented isolates of this virus. However, no PNRSV isolate typical to a specific host and/or to the Middle East region could be identified. This study expands the body of data on variability of PNRSV isolates and highlights the importance of assessing the virus status of germplasm collections by applying reliable diagnostic and differentiating methods.     

Typing Primus necrotic ringspot virus isolates by serology and restriction endonuclease analysis of PCR products

Primus necrotic ringspot virus (PNRSV) isolates were characterised by bioassays, serotyping and restriction fragment length polymorphism (RFLP) analysis of PCR products. Based on symptoms in host trees and bioassays it was concluded that only one of the 16 tested isolates is severe. The serotyping results demonstrated that by using four different MAbs in TAS-ELISA the tested isolates could be divided into four subgroups, however, the severe isolate could not be singled out. RFLP analysis of PCR products supported the serotyping data but did not differentiate between isolates of the two main serological subgroups. A restriction map, derived from sequence analysis of the PCR products obtained from selected isolates, allowed exact location of the restriction sites within the PCR products of each isolate. A mild isolate with a unique genome structure was identified by both serological and RFLP assays. As far as we are aware, this is the first report on sub-grouping of PNRSV isolates by bioassays, serotyping with MAbs and RFLP analysis.     

Molecular Evidence for Recombination in <Emphasis Type="Italic">Prunus</Emphasis> Necrotic Ringspot Virus

Genetic RNA recombination plays an important role in viral evolution. The evolutionary history of Prunus necrotic ringspot virus (PNRSV) has been extensively studied, but knowledge of recombination in its genome is still lacking. To investigate the recombination events in this virus, 67 accessions composed by 62 isolates retrieved from the databanks and five Tunisian isolates described in this study were analyzed. The use of RECCO algorithm which is based on cost minimization allowed us to detect several breakpoints in the coat protein gene (CP) of three out of five isolates from Tunisia and one from Poland. Moreover, a recombination signal was also detected in the putative cell-to-cell movement protein-encoding gene of an isolate from the USA. Tajima Neutrality test implemented in MEGA4 program indicated the occurrence of a high level of deletion/insertion events in the sequences. The evolutionary historical relationships were determined by constructing a dendrogram using neighbor joining, minimum evolution, maximum parsimony, maximum likelihood, and unweighted pair group method with arithmetic mean (UPGMA). The first four analyses gave similar results. Three classical groups (PE 5, PV 32, and PV 96) were delineated. The recombinant isolates from Tunisia clustered in a distinct clade except for one nonrecombinant (Ghernghezel) which revealed to be a member of PV 32 group. In contrast, UPGMA algorithm divided the Tunisian isolates in three distinct subgroups. Apart from recombination, reassortment is still an open question among many others and may also represent another way to explore the genetic diversity of PNRSV.     

Incidence of Prunus necrotic ring spot virus on Malus domestica in India

In surveys of apple (Malus domestica) orchards in various parts of Himachal Pradesh, samples from trees showing necrotic symptoms on the leaves were collected and tested for detection of Prunus necrotic ringspot virus (PNRSV) initially by ELISA followed by RT‐PCR using coat protein gene primers. Positive results were obtained in samples from Kullu and Kalpa regions. The virus gene sequences showed 88–97% similarity to corresponding sequences of other PNRSV isolates deposited in the GenBank database using ncbi.nih.nlm.gov. Although the similarity was high, there were some distinct differences with the Spanish isolate. This is the first report of PNRSV in apple from India.     

Molecular adaptation within the coat protein-encoding gene of Tunisian almond isolates of Prunus necrotic ringspot virus

The sequence alignments of five Tunisian isolates of Prunus necrotic ringspot virus (PNRSV) were searched for evidence of recombination and diversifying selection. Since failing to account for recombination can elevate the false positive error rate in positive selection inference, a genetic algorithm (GARD) was used first and led to the detection of potential recombination events in the coat protein-encoding gene of that virus. The Recco algorithm confirmed these results by identifying, additionally, the potential recombinants. For neutrality testing and evaluation of nucleotide polymorphism in PNRSV CP gene, Tajima’s D, and Fu and Li’s D and F statistical tests were used. About selection inference, eight algorithms (SLAC, FEL, IFEL, REL, FUBAR, MEME, PARRIS, and GA branch) incorporated in HyPhy package were utilized to assess the selection pressure exerted on the expression of PNRSV capsid. Inferred phylogenies pointed out, in addition to the three classical groups (PE-5, PV-32, and PV-96), the delineation of a fourth cluster having the new proposed designation SW6, and a fifth clade comprising four Tunisian PNRSV isolates which underwent recombination and selective pressure and to which the name Tunisian outgroup was allocated.     

Preparation and Characterization of a Monoclonal Antibody to Prunus necrotic ringspot virus

A cell line named PVRSV1D11 secreting monoclonal antibody (McAb) against the prokaryotically expressed coat protein (CP) of Prunus necrotic ringspot virus (PNRSV) was developed using hybridoma technology including animal immunization, cell fusion, cell line culture and enzyme‐linked immunosorbent assay (ELISA)‐based for screening. The specificity, titre and detection sensitivity of the McAb were determined by indirect ELISA to establish optimal conditions. The antibody reacted strongly with PNRSV and showed no cross‐reactions with the proteins of Plum pox virus, Prunus dwarf virus, Apple stem pitting virus, Apple stem grooving virus, Apple mosaic virus or Apple chlorotic leafspot virus. The ascites developed with PNRSV1D11 cell line showed high absorbance until it was diluted to over 6.6 × 10⁷ fold. The McAb belonged to IgG_2a isotype and was diluted by 1.28 × 10⁵ folds as an optimal detection concentration. The detection sensitivity of the monoclonal antibody was 11.7 ng/ml protein of PNRSV. The results indicated that the McAb against the CP of PNRSV is suitable for PNRSV detection in the plants and for monitoring the dynamics of the virus by using indirect ELISA.     

Biological and molecular characterization of <Emphasis Type="Italic">Prunus necrotic ringspot virus</Emphasis> isolates from three rose cultivars

Prunus necrotic ringspot virus (PNRSV) is a rose and stone fruit tree pathogen. Three different PNRSV isolates, originating from three rose cultivars were studied. These PNRSV isolates were characterized using molecular techniques. Nearly the complete nucleotide sequence (1,630 nucleotides) of RNA3 of the isolate PNRSV-R1 has been determined (GenBank Acc. No. DQ003584). The sequence of the MP gene of the PNRSV-R1 isolate was determined, the first such results for a rose-derived PNRSV isolate. The reaction of PNRSV infection on test plants was also investigated. Cucumis sativus cv. Wisconsin, Cucurbita maxima cv. Buttercup and Cucurbita pepo cv. Melonowa Żółta appeared to be the most useful test plants for the differentiation of isolate-specific pathogenicity.     

Adaptive covariation between the coat and movement proteins of prunus necrotic ringspot virus

The relative functional and/or structural importance of different amino acid sites in a protein can be assessed by evaluating the selective constraints to which they have been subjected during the course of evolution. Here we explore such constraints at the linear and three-dimensional levels for the movement protein (MP) and coat protein (CP) encoded by RNA 3 of prunus necrotic ringspot ilarvirus (PNRSV). By a maximum-parsimony approach, the nucleotide sequences from 46 isolates of PNRSV varying in symptomatology, host tree, and geographic origin have been analyzed and sites under different selective pressures have been identified in both proteins. We have also performed covariation analyses to explore whether changes in certain amino acid sites condition subsequent variation in other sites of the same protein or the other protein. These covariation analyses shed light on which particular amino acids should be involved in the physical and functional interaction between MP and CP. Finally, we discuss these findings in the light of what is already known about the implication of certain sites and domains in structure and protein-protein and RNA-protein interactions.     

Prunus necrotic ringspot virus: incidence on stone and pome fruits and diversity analysis

Stone fruits and pome fruits are cultivated commercially worldwide. In India, they are grown in temperate regions, which mainly includes Jammu and Kashmir, Uttarakhand, Himachal Pradesh and some North-Eastern states. In this study, an attempt has been made to identify the Prunus necrotic ringspot virus (PNRSV) infecting stone and pome fruits in India and to characterise them on the molecular level. Surveys were conducted in the temperate fruit-growing areas and incidence of PNRSV was detected by serological and molecular means in almond, apple, cherry, nectarine, peach, plum and wild cherry. Further diversity analysis of PNRSV was performed using bioinformatics tools such as clustalW, DNA Data Bank of Japan, MultAlin and Recombination Detection Programme. PNRSV was detected in plum, peach, cherry, almond, nectarine, wild cherry and apple. In the diversity analysis study on the basis of coat protein gene, it was found that the isolates showed identity levels from 82 to 100%. In a plum isolate, a stretch of amino acids from 207 to 221 was found variable from Indian and other isolates. In one of the Indian apple isolates, “NR” repeats at 41–44 position (characteristic of PV-32 group, Group I) were identified. Phylogenetic analysis revealed that Indian isolates are falling in Group-I. Movement protein was also amplified from peach and multiple alignment studies showed that N-terminus was mostly conserved, whereas the C-terminal was highly variable.     

Detection and Molecular Variability of Turnip mosaic virus (TuMV) in Shaanxi,China

Turnip mosaic virus (TuMV) is one of the most devastating threats to oilseed rape by causing serious crop losses. A total of 86 leaf samples of oilseed rape from eight different locations in Shaanxi, China, were tested by RT‐PCR for TuMV; the results revealed an infection level of 43% by TuMV. The complete coat protein (CP) gene of 32 TuMV isolates was cloned and sequenced. Analysis of the CP gene with sequences from the database allowed the genetic classification of 170 TuMV isolates or sequences. Four genetic clusters were obtained: MB (mostly Brassica isolates), MR (mostly Radish isolates), IBR (mostly Intermediate between Brassica and Radish clusters) and OBR (mostly outside Brassica and Radish clusters). All subgroups were slightly related to the hosts, but unrelated to geographical origins. Most of Shaanxi TuMV isolates were on separate branches, compared with the 138 known isolates originating from other parts of the world. Our results help provide a better understanding of the genetic diversity of TuMV isolates infecting oilseed rape in Shaanxi, China.     

Analysis of Coat Protein of Peanut stunt virus Subgroup II Isolates from Alfalfa Fields in West Iran

Alfalfa fields in three western provinces of Iran were surveyed for Peanut stunt virus (PSV) during 2011 and 2012. Forty‐seven of 115 samples tested (41%) were infected with PSV. Phylogenetic analysis using coat protein (CP) gene sequences showed that the Iranian isolates belong to the subgroup II of PSV. Pairwise identity analysis revealed four groups representing four phylogenetic subgroups. PSV strains in subgroups III and IV are closely related to each other, as supported by the lowest nucleotide diversity, high pairwise nucleotide identity and high haplotype diversity as evidence of a recent population expansion after a genetic bottleneck. Using the maximum likelihood method, amino acid 86S in the CP gene of the Iranian PSV isolates was found to be under positive selection, although the likelihood ratio test statistics is not significant. This is the first report of the occurrence and phylogenetic relationships of Iranian PSV isolates in west Iran.     

Incidence and genetic diversity of raspberry bushy dwarf virus (RBDV) in Rubus spp. in Turkey

Raspberry bushy dwarf virus (RBDV), recently renamed to Idaeovirus rubi, is one of the most common viruses infecting Rubus species worldwide but there is still a limited number of genome sequences available in the GenBank database and the majority of the sequences include partial sequences of RNA-1 and RNA-2. The distribution and incidence of RBDV in main raspberry and blackberry growing provinces in Turkey were monitored during 2015–2019 and 537 Rubus spp. samples were tested by both DAS-ELISA and RT-PCR. Among the tested samples, 36 samples tested positive for RBDV by DAS-ELISA and 67 samples by RT-PCR. There was relatively low nucleotide diversity among the Turkish isolates. Turkish isolates shared 93%–97.7%, 84.3%–98.9%, and 85%–99.2% nucleotide sequence identities with available sequences in the GenBank, in partial RNA-1, movement protein (MP) and coat protein (CP) genes, respectively. In the phylogenetic tree constructed for RNA-1, MP, and CP sequences, all Turkish raspberry isolates were clustered in a distinct clade. However, the blackberry isolates showed considerable variation in nucleotide sequences and were placed in three distinct groups. The divergent blackberry isolates showed high variability in MP (84.5%–89.3%) and CP (85.5%–89.7%) regions and were placed in a distinct group. The rest of blackberry isolates clustered together with sweet cherry RBDV isolates adjacent to the grapevine clade or together with raspberry isolates. The comparative analysis conducted on three RNA segments of RBDV highlighted the high sequence diversity of Turkish RBDV isolates. This study also emphasizes the importance of regular monitoring of RBDV infections in Turkey, with special regard to those Rubus spp. and grapevine accessions employed in conservation and selection programmes. In particular, the presence of new RBDV genetic variants and infection of Rubus species must be taken into account to choose a correct detection protocol and management strategy.     

Occurrence and Genome Analysis of Cucurbit chlorotic yellows virus in Iran

In 2011 and 2012, several cucurbit‐growing regions of Iran were surveyed and samples with symptoms similar to those induced by Cucurbit chlorotic yellows virus (CCYV) were collected. The pathogen was transmitted to cucumber and melon under greenhouse conditions by whiteflies (Bemisia tabaci). RT‐PCR using designed CCYV‐specific primer pair (CCYV‐F/CCYV‐R) resulted in amplification of the predicted size DNA fragment (870 bp) for the coat protein (CP) gene in samples collected from Boushehr, Eyvanakay and Varamin. Nucleotide sequences of the CP of the three Iranian CCYV isolates were compared with five CCYV isolates obtained from GenBank and analysed. Phylogenetically, all CCYV isolates clustered in two groups; Group I is composed of five non‐Iranian isolates from China, Lebanon, Japan, Sudan and Taiwan, and the three Iranian isolates formed Group 2. Among Iranian isolates, the Eyvanakay isolate clustered in a distinct clade with the Boushehr and Varamin isolates. A phylogenetic tree based on amino acid identity of CP showed that CCYV was closely related to Lettuce chlorosis virus (LCV), Bean yellow disorder virus (BnYDV) and Cucurbit yellow stunting disorder virus (CYSDV). This is the first report of CCYV in Iran.     

Studies on rose mosaic disease in field-grown roses produced in the United Kingdom

Arabis mosaic virus (AMV) and prunus necrotic ringspot virus (PNRSV), separately or together, caused in field-grown roses the range of symptoms recognised as rose mosaic disease. PNRSV infection alone generally induced chlorotic line patterns, ring-spots or mottles in the leaves at some time during the growing season; AMV plus PNRSV normally caused chlorotic vein-banding. However, during prolonged periods of high temperatures (c. 21 °C or more) vein banding occurred in some roses infected only with PNRSV. Isolates of PNRSV from rose had particles which were similar in shape, protein mol. wt, density and sedimentation coefficients to previously described isolates of PNRSV from cherry, plum and rose; all were cherry serotypes. In graft-inoculated roses, apple serotypes of PNRSV induced stunting and chlorosis, puckering and distortion of leaves, which closely resembled symptoms associated with rose mosaic in the USA and chlorotic mottle rose mosaic in New Zealand. To avoid possible confusion in using the name rose mosaic it is suggested that the virus(es) present in roses should be named.     

Genome organization and variation in the 3′-partial sequence of garlic latent virus in China

Ten different isolates of a carlavirus were detected by degenerate PCR from 12 garlic samples collected from 6 provinces in China, and the complete genome sequence of the Zhejiang isolate ZJ1 and 3’-terminal sequences of 9 other isolates were determined. The RNA genome of isolate ZJ1 consisted of 8363nts excluding the 3’-poly (A) tail, and the genome organization was similar to other carlaviruses with 6 open reading frames encoding a replicase, TGB1, TGB2, TGB3, CP and NABP respectively. Sequence comparisons showed that all 10 isolates were Garlic latent virus (GarLV). The variations in the TGB2, TGB3 and NABP were more significant than those in the CP. High homology was also detected between those isolates and Shallot latent virus (ShLV). Phylogenetic analysis suggested that GarLV isolates from garlic can be divided into 4 main groups and Chinese isolates belonged to each group. This is the first reported molecular analysis of members of the genus Carlavirus in China.     

Molecular variability analyses of <Emphasis Type="Italic">Apple chlorotic leaf spot virus</Emphasis> capsid protein

The complete sequences of the coat protein (CP) gene of 26 isolates of Apple chlorotic leaf spot virus (ACLSV) from India were determined. The isolates were obtained from various pome (apple, pear and quince) and stone (plum, peach, apricot, almond and wild Himalayan cherry) fruit trees. Other previously characterized ACLSV isolates and Trichoviruses were used for comparative analysis. Indian ACLSV isolates among themselves and with isolates from elsewhere in the world shared 91–100% and 70–98% sequence identities at the amino acid and nucleotide levels, respectively. The highest degree of variability was observed in the middle portion with 9 amino acid substitutions in contrast to the N-terminal and C-terminal ends, which were maximally conserved with only 4 amino acid substitutions. In phylogenetic analysis no reasonable correlation between host species and/or geographic origin of the isolates was observed. Alignment with capsid protein genes of other Trichoviruses revealed the TaTao ACLSV peach isolate to be phylogenetically closest to Peach mosaic virus, Apricot pseudo chlorotic leaf spot virus and Cherry mottle leaf virus. Recombination analysis (RDP3 ver.2.6) done for all the available ACLSV complete CP sequences of the world and Indian isolates indicate no significant evidence of recombination. However, one recombination event among Indian ACLSV-CP isolates was detected. To the best of our knowledge, this is the first report of complete CP sequence variability study from India and also the first evidence of homologous recombination in ACLSV.     

Rapid Detection and Identification of Six Tomato yellow leaf curl virus Isolates from Different Regions Using Polymerase Chain Reaction and Restriction Enzyme Analysis

The combinational analysis of polymerase chain reaction and restriction enzyme analysis (PCR‐RE) to distinguish six Tomato yellow leaf curl virus (TYLCV) isolates from five countries was developed. Tomato yellow leaf curl virus has spread from the Middle East to Western Europe, Central America and Eastern Asia, and occurs on infected crops such as tomatoes, peppers, cucurbits and beans. Tomato yellow leaf curl virus isolates from Jordan (TYLCV‐Mld[Jo:Cuc] and TYLCV‐IL[Jo:Cuc]), Israel (TYLCV‐IL[IL:Reo:86]), Spain (TYLCV‐Mld[ES72/97]), USA (TYLCV‐IL[US:F10:04]) and Korea (TYLCV‐KR) were collected, and the sequences of the six isolates were analysed to distinguish them by PCR‐RE combination analysis. Oligonucleotide primers for the six TYLCV isolates were designed to amplify approximately 740 base pairs including the intergenic region (IR) and parts of V1 and V2 ORF. Unique restriction enzyme sites were analysed to identify isolate‐specific restriction enzyme sites on the PCR products of each isolate. Three enzymes (DdeI, FauI and BssSI) were selected by in silico analysis, and then, the PCR products following the serial digestion of each restriction enzyme were separated by agarose gel electrophoresis to distinguish the TYLCV isolates. Taken together, the PCR‐RE combination analysis by serial digestion with three restriction enzymes could be a useful method for distinguishing the six isolates.