Genetic Diversities of Cymbidium mosaic virus and Odontoglossum ringspot virus Isolates Based on the Coat Protein Genes from Orchids in Guangdong Province,China

Orchids are some of the most important ornamental flowers. Cymbidium mosaic virus (CymMV) and Odontoglossum ringspot virus (ORSV) are the most prevalent and economically important viruses affecting orchids in China. In this study, 20 CymMV and 28 ORSV isolates were selected for genetic diversity analysis. The CymMV isolates shared 84.6–100% and 89.5–100% identities of coat protein (CP) at the nucleotide (nt) and amino acid (aa) levels, respectively. The identities of ORSV isolates were 96.4–100% (nt) and 92.5–99.4% (aa). The CP genes of CymMV were found to have genetic diversity, and the CP genes of ORSV were genetically conservative. These results can aid in designing effective disease‐control strategies.     

Specific and Rapid Detection of Lily symptomless virus and Arabis mosaic virus in Lily by Dual IC‐RT‐PCR

Lily symptomless virus (LSV) and Arabis mosaic virus (ArMV) cause severe losses of quantity and quality of lily flower and bulb production. Specificity, sensitivity and speed of detection methods for viruses need to be improved greatly to prevent LSV and ArMV from spreading from infected lilies. A dual IC‐RT‐PCR procedure for detection was developed in which the antibodies of LSV and ArMV were mixed and the mixture used to coat the PCR tubes. The particles of the two viruses were captured by the respective antibodies. Interference by other RNA viruses in infected lily was eliminated in the RT‐PCR. Also, an RNA extraction step was omitted. The dual IC‐RT‐PCR products of LSV and ArMV were 521 bp and 691 bp, respectively. The specificity of the method was validated; only LSV and ArMV of four viruses were detected by dual IC‐RT‐PCR. The sensitivity of the detection method is 1 mg leaf tissue and higher than DAS‐ELISA due to enrichment by dual immunocapture.     

Low Genetic Diversity Suggests a Single Introduction and Recent Spread of Tomato chlorosis virus in Brazil

By comparing the partial nucleotide sequences of the heat shock protein HSP70 homologue gene, we assessed the genetic diversity of Brazilian tomato isolates of Tomato chlorosis virus (ToCV), as well as their relationship with other ToCV isolates found worldwide. The Brazilian ToCV isolates shared 99.9–100% nucleotide identity, which indicates low genetic diversity. Brazilian ToCV isolates showed a closer evolutionary relationship to those from Mediterranean countries. Based on these results, the origin of Brazilian ToCV isolates and the possible number of introductions of the virus into Brazil are discussed.     

A Comovirus Infecting Rocket (Eruca sativa) in Brazil

A virus related to Radish mosaic virus and Turnip ringspot virus (TuRSV) was found infecting rocket plants in Brazil. Predicted amino acids from partial viral RNA sequences placed it closer to TuRSV. We describe here the identification and partial characterization of the first comovirus found infecting a crucifer species in Brazil.     

A Distinct Strain of Cowpea mild mottle virus Infecting Soybean in India

Soybean crops showing systemic mottling, mosaic and leaf deformation were observed at high disease incidences (25.1–71.0%) in the kharif season of 2011 and 2012 in the experimental farm of the Indian Agricultural Research Institute (IARI), New Delhi. Symptomatic soybean leaves contained flexuous particles (650 × 12 nm), suggesting an infection by a Carlavirus. The causal virus was characterized as a strain of Cowpea mild mottle virus (CPMMV) on the basis of mechanical inoculation, whitefly transmission, seed transmission and sequencing of the viral genome. This is the first report of natural infection by a distinct strain of CPMMV in soybean in India.     

Molecular Analysis of ORF6, ORF7 and ORF8 of Beet yellows virus Iranian Isolate

Beet yellows virus (BYV), a member of the Closteroviridae family, is one of the most important sugar beet yellowing viruses. The nine ORFs of BYV genome encode different proteins required for BYV life cycle. We sequenced a part of the genome of BYV Iranian isolate consisting of ORF6, ORF7 and ORF8. The primer pair BYVA/Z was used for amplification of this region in RT‐PCR. The amplicon (1615 bp) was cloned and sequenced. Comparisons showed the amplified segment is corresponding to ORF6, ORF7 and ORF8 of BYV genome encoding coat protein, p20 and p21 proteins, respectively. The ORF7 of BYV Iranian isolate overlaps with ORF6 and ORF8 in four and 26 nucleotides at 5′ and 3′ ends, respectively. The ORF7 of Iranian isolate of BYV was sequenced completely. However, approximately 24 nt. from the beginning of ORF6 and 23 nt. from end of ORF8, including the stop codon, were not determined. ORF6, ORF7 and ORF8 showed the highest similarity at nucleotide (98.3, 99.4 and 99.2%) and amino acid (97.4, 98.9 and 100%) sequence levels, with BYV Ukrainian isolate. Phylogenetic analysis of the deduced amino acid sequences of ORF6, ORF7 and ORF8 revealed closer relationship of Iranian isolate of BYV with BYV Ukrainian isolate than other BYV isolates available at GenBank.     

Identification and Characterization of Pothos latent virus Causing Necrotic Ringspots and Line Patterns on Lisianthus (Eustoma grandiflorum) in Taiwan

Lisianthus (Eustoma grandiflorum) grown in screenhouses in Taiwan showed ringspots and concentric line patterns on leaves. A virus having isometric particles approximately 30–32 nm in diameter was isolated from affected lisianthus. Combined results of biological, cytological, serological, molecular and phylogenetic analyses show that the virus can be identified as Pothos latent virus (PoLV), genus Aureusvirus, family Tombusviridae. Inoculating the virus on non‐infected lisianthus plants reproduced the symptoms previously observed in the field. So, this is the first report of PoLV causing disease in lisianthus and the first report of the virus in Taiwan.     

A Cocktail ELISA Semi‐nested RT‐PCR Assay to Detect Bean pod mottle virus in Soya bean Seeds

Bean pod mottle virus (BPMV) has been identified as an important pathogen for plant quarantine in China because large quantities of soya bean seeds (approximately 7 × 10⁷ tons) are imported annually. To develop a practical detection programme for BPMV, a cocktail enzyme‐linked immunosorbent assay (ELISA) nested RT‐PCR using a combination of serological and molecular methods was designed for soya bean seeds. The single‐vessel detection assay was performed in a 96‐well ELISA plate, which served as a carrier for the subsequent nested RT‐PCR assay. Assay specificity was demonstrated by the production of the expected 330‐ and 296‐bp bands using the external and internal primers, respectively. This method was 10⁴‐fold more sensitive than immunocapture‐RT‐PCR (IC‐RT‐PCR). In particular, it is important to note that this assay resulted in successful micro‐extraction from soya bean seeds and combined the advantages of each individual technique. The cocktail ELISA nested RT‐PCR is a specific, sensitive, rapid and economical procedure to rapidly identify and characterize BPMV and could be suitable for both primary‐level platforms and laboratories.     

Improved Detection of Citrus psorosis virus and Coat Protein‐Derived Transgenes in Citrus Plants: Comparison Between RT‐qPCR and TAS‐ELISA

Citrus is one of the most economically important fruit crops in the world. Citrus psorosis is a serious disease affecting mainly oranges and mandarins in Argentina and Uruguay. The causal agent is Citrus psorosis virus (CPsV), an ophiovirus with a tripartite ssRNA genome of negative polarity. The coat protein (CP), the most abundant viral protein in infected plants, has been used to detect CPsV by TAS‐ELISA, but only biological indexing, requiring 1 year, is the current and validated technique for diagnosis of citrus psorosis. In this study, a SYBR Green RT‐qPCR protocol was developed, with primers designed to the most conserved region of the cp gene. We tested their specificity and sensitivity in comparison with TAS‐ELISA. This RT‐qPCR was applied successfully to field samples from Argentina, to a variety of isolates from different countries maintained in the greenhouse, to young seedlings and old trees from a psorosis natural transmission plot, and to transgenic citrus expressing the cp gene of CPsV or a fragment thereof. This method allowed accurate quantification of viral titer and cp gene expression in transgenic plants, which could not be detected previously. The sensitivity and reliability of quantitative CPsV detection were improved with greater speed using commercial reagents, and the sensitivity was three orders of magnitude higher than that of TAS‐ELISA. All these data encourage its validation.     

Brief Report of a New Highly Divergent Variant of Grapevine leafroll‐associated virus 3 (GLRaV‐3)

The alignment of the complete genomes of genetic variants of Grapevine leafroll‐associated virus 3 (GLRaV‐3) representing phylogenetic groups I, II, III and VI revealed numerous regions with exceptionally high divergence between group I to III and group VI variants. Oligonucleotide primers universal for all the above groups of the virus were designed in conserved short stretches of sequences flanking the divergent regions in the helicase (Hel) and RNA‐dependent RNA polymerase (RdRP) domains of the replicase gene and the divergent copy of the capsid protein (dCP) gene. Cloning and sequencing of the 549‐bp RT‐PCR amplicon of the helicase domain from grapevine cv. Shiraz lead to the detection of a variant of GLRaV‐3, which shared only 69.6–74.1% nt similarity with other variants, including the recently reported, new, highly divergent variant, isolate 139. This was confirmed by the results of the analysis of 517‐bp amplicon of the HSP70 gene of GLRaV‐3 generated in RT‐nested PCR based on degenerate primers for the simultaneous amplification of members of the Closteroviridae family designed by Dovas and Katis (J Virol Methods, 109, 2003, 217). In this genomic region, the variant shares 72.3–78.7% nt similarity with other variants of GLRaV‐3. This previously unreported, new, highly divergent variant was provisionally named GTG10. From the alignment of the HSP70 sequences primers for the specific RT‐nested PCR amplification of the variant GTG10 and members of group VI, and specific simultaneous amplification of variants of groups I, II and III, were designed. The results obtained from brief testing of various grapevines using all these primers suggest a relatively limited presence of GTG10 variant in vineyards.