RESUMO
Brugmansia suaveolens, known as angel's trumpet, is a perennial ornamental shrub in the Solanaceae with large fragrant flowers. In June 2018, a leaf sample of B. suaveolens that showed virus-like symptoms including chlorotic spots, yellowing and mottle on leaves was collected from a greenhouse in Seongnam, South Korea for disease diagnosis (Supplementary Figure S1a, b). Disease incidence in the greenhouse was greater than 80% for about 2,000 B. suaveolens plants. To identify a causal virus, transmission electron microscopy (TEM) was used to analyze symptomatic leaf samples using leaf dips and thin section methods. Filamentous virus particles and pinwheel structures were observed, indicating the presence of a potyvirus (Supplementary Figure S1c, d). To confirm the TEM results, a symptomatic leaf sample was further analyzed by reverse-transcription polymerase chain reaction (RT-PCR) using species-specific detection primers for three potyviruses that infect Brugmansia spp.: Colombian datura virus (CDV), Brugmansia mosaic virus (BruMV), and Brugmansia suaveolens mottle virus (BsMoV) (Lucinda et al, 2008; Park et al., 2014; Verma et al., 2014). The sample was positive only for CDV. CDV is transmitted by aphids in a nonpersistent manner and mechanical inoculation and can infect plants in the Solanaceae family including tomato and tobacco (Kahn and Bartels 1968; Schubert et al. 2006; Verhoeven et al. 1996) and has been designated a quarantine virus in Korea. Additional analysis of 13 symptomatic B. suaveolens plants from the infected greenhouse found that all samples except one were infected with CDV. To isolate CDV from B. suaveolens, leaf extracts from symptomatic samples were mechanically inoculated on an assay host, Nicotiana tabacum cv. BY via three single-lesion passages followed by propagation in N. benthamiana. For the bioassay of the CDV isolate (CDV-AT-Kr), sap from infected N. benthamiana was mechanically inoculated on 31 indicator plants, including B. suaveolens (Supplementary Table S2). CDV-AT-Kr induced chlorotic local lesions, necrotic local lesions, mottle, and/or mosaic systemically in 10 Nicotiana spp., and mottle and yellowing in tomato. On inoculated B. suaveolens, te mild mottle symptom was reproduced. No symptoms were observed in pepper or Datura stramonium. These results were confirmed by RT-PCR. To characterize CDV-AT-Kr genetically, the complete genome sequence of CDV-AT-Kr was obtained by RT-PCR using specific primers (Supplementary Table S3) and deposited in GenBank (accession no. MW075268). The CDV-AT-Kr RNA consists of 9,620 nt, encoding a polyprotein of 3,076 aa. BLASTn analysis showed that CDV-AT had maximum nucleotide identities of 98.9% at the complete genome level with a CDV isolate (accession no. JQ801448) from N. tabacum in the UK. To our knowledge, this is the first report of CDV infection in B. suaveolens in Korea and the second report in the world of the complete genome sequence. As B. suaveolens is cultivated by vegetative propagation, production and maintenance of virus-free, healthy B. suaveolens is needed. In addition, as new CDV hosts have been repeatedly reported (Pacifico et al., 2016; Salamon et al., 2015; Tomitaka et al., 2014; Verma et al., 2014), we are monitoring nationwide occurrence to prevent the spread of the virus to other crops.
RESUMO
Rhodococcus fascians is a bacterium that causes growth abnormalities such as leafy galls, fasciation, and shoot proliferation in many plants, including ornamental plants. In February 2020, the Animal and Plant Quarantine Agency of South Korea detected 492,000 contaminated lily bulbs using an in-house PCR test based on the R. fascians fasD gene, and subsequently 1.3 million imported bulbs were destroyed. Because no pathogen isolation was associated with this diagnosis, there has been great cultivator demanded for bacterial isolation evidence of lily bulb infection with pathogenic R. fascians. To isolate the causal bacterium of the PCR tests, we sampled leaf, stem, and bulb tissues from 130 lilies with growth abnormality symptoms, collected from 24 South Korean mass production lily farms from June to August 2020. Supernatants of the homogenized samples were spread on mD2 medium (Kado and Heskett 1970) and incubated at 28°C for 10 days. Yellow to orange colonies were isolated into pure culture on mD2. Total DNA was extracted from cultures grown in yeast extract broth (YEB) at 28°C for 24 hours with Wizard DNA prep kit (Promega, Madison, WI, USA). PCR was performed to test for pathogenicity genes fas (A,D, and R) and att (A and R) (Putnam and Miller 2007). Colonies that produced at least one amplicon from these pathogenicity genes were analyzed by partial 16s rRNA gene sequencing to determine the corresponding species. Three strains that were isolated from the bulbs of fasciated lilies from Wanju (35°56´22.1ËN; 127°08´52.0ËE), Gwacheon (37°26´51.6ËN; 127°00´11.8ËE), and Yeongwol (37°18´45.8ËN; 128°11´05.6ËE), or W1, G3, and Y5 strains, yielded PCR products of the expected size for fas and att genes with the primer sets published in Serdani et al. (2013) and developed in this study (attAF: 5'-CCCGGCTACACGCATTCGC-3', attAR: 5'-CGAACGCGGTGTGCAGGT-3' and attRF: 5'-AGTGTCCCGTCGGCGAG-3', attRR: 5'-CGCGGCAGATCGAAGTCCT-3'). Sequences of the three strains were deposited in Genbank for fasA (accession MW122940-942), fasD (G3:MW122935 and 936), and fasR (MW122937-939); all shared 98.3 - 100% nucleotide identity to corresponding sequences from phytopathogenic R. fascians A25f (CP049745.1 Protein_ID fasA:QII09280.1, fasD:QII09282.1, and fasR:QII09277.1). The attA and attR products were only present in G3 (attA: MW122943 and attR: MW122944) and resulted in 100% identity to those of A25f (CP049745.1 Protein_ID attA:QII09269.1, attR:QII09267.1). Partial 16s rRNA gene sequences were obtained (MW064131-133) and clustered with phytopathogenic R. fascians strains D188, A21d2, and A25f. Thus we concluded that strains (W1, G3, and Y5) corresponded to R. fascians. To test the pathogenicity of these three strains, 10 seeds of garden peas for each strain were inoculated at 108 CFU/ml according to Nikolaeva et al. (2009), and the length of the main stem of each seedling was calculated 22 days post-inoculation. Seedlings inoculated with G3 and Y5 resulted in a stunted phenotype with up to 40% height reduction (p ≤ 0.001) compared to non-inoculated seedlings. As for the seedlings inoculated with W1, they exhibited as much as 15% height reduction (p ≤ 0.001). Colonies were recovered from the inoculated seedlings, identity was confirmed through colony PCR for fas and att genes. To our knowledge, this is the first report of phytopathogenic R. fascians in lilies cultivated in South Korea.
RESUMO
We report the complete genome sequence of a novel nucleorhabdovirus, apple rootstock virus A (ApRVA), isolated from Malus spp. in South Korea. ApRVA has a 14,043-nt single-stranded negative-sense RNA genome. In the antigenome sense, it contains seven open reading frames, encoding the putative nucleocapsid protein, phosphoprotein, cell-to-cell movement protein, matrix protein, glycoprotein, RNA-dependent RNA polymerase, and an additional hypothetical protein, the gene for which is located between the genes for the matrix protein and glycoprotein. The complete genome sequence of ApRVA showed 47.45% nucleotide sequence identity to that of black currant-associated rhabdovirus 1. The genome organization, phylogenetic relationships, and sequence similarities to other nucleorhabdoviruses suggest that ApRVA is a new member of the genus Nucleorhabdovirus.
Assuntos
Genoma Viral , Malus/virologia , Raízes de Plantas/virologia , Rhabdoviridae/classificação , Rhabdoviridae/genética , Análise de Sequência de DNA , Ordem dos Genes , Fases de Leitura Aberta , Filogenia , RNA Viral/genética , República da Coreia , Rhabdoviridae/isolamento & purificação , Homologia de Sequência do Ácido Nucleico , Proteínas Virais/genéticaRESUMO
An assay for detecting Apple scar skin viroid (ASSVd) was developed based on nucleic acid sequence based amplification (NASBA) in combination with real-time detection during the amplification process using molecular beacon. The ASSVd specific primers for amplification of the viroid RNA and molecular beacon for detecting the viroid were designed based on highly conserved regions of several ASSVd sequences including Korean isolate. The assay had a detection range of 1 × 104 to 1 × 1012 ASSVd RNA copies/µl with reproducibility and precision. Following the construction of standard curves based on time to positive (TTP) value for the serial dilutions ranging from 1 × 107 to 1 × 1012 copies of the recombinant plasmid, a standard regression line was constructed by plotting the TTP values versus the logarithm of the starting ASSVd RNA copy number of 10-fold dilutions each. Compared to the established RT-PCR methods, our method was more sensitive for detecting ASSVd. The real-time quantitative NASBA method will be fast, sensitive, and reliable for routine diagnosis and selection of viroid-free stock materials. Furthermore, real-time quantitative NASBA may be especially useful for detecting low levels in apple trees with early viroid-infection stage and for monitoring the influence on tree growth.