RESUMO
Impatiens necrotic spot virus (INSV) (Orthotospovirus impatiensnecromaculae) is a virus in the Order Bunyavirales and Family Tospoviridae. The virus is vectored by several species of thrips and is a serious pathogen of ornamentals and lettuce in the United States (Hasegawa & Del Pozo-Valdivia 2023; Daughtrey, M. L., et al. 1997; Webster, C. G., et al. 2015). In January 2023, tomato plants (Solanum lycopersicum,'Big Dena') with viral symptoms of reduced vigor, wilting, necrotic spots on leaves, and sunken lesions on the stem were observed in one greenhouse in Guilford County, North Carolina (NC) (Figure 1A-C). Disease incidence was low (2%), with only three symptomatic plants in the single greenhouse. Affected plants also had signs of thrips feeding (dead thrips, frass, and feeding scars) present across the whole plant (Figure 1D). Samples were submitted to the NC State Plant Disease and Insect Clinic and tested positive for INSV, but negative for TSWV, using Agdia ImmunoStrips®. RNA was extracted from symptomatic leaf tissue using the IBI Total RNA Mini kit (Plant), and complementary DNA (cDNA) was generated using the ThermoFisher Verso cDNA synthesis kit. A reverse transcriptase (RT)-PCR with INSV nucleocapsid (N) primers (F:5'-ATGAACAAAGCAAAGATTACC-3' and R:5'- TTAAATAGAATCATTTTTCCC-3') was used to confirm INSV presence (Hassani-Mehraban et al. 2016). Full length N cDNA amplicon sequencing [GenBank No. PP658213] revealed 99.62% nucleotide identity to NCBI GenBank accessions KF926828 (orchid in California), MH453554.1 (hosta from NY), and MH453552.1 (foxglove from NY), all of which are INSV N sequences. The infected leaf samples were used to mechanically inoculate Emilia sonchifolia and tomato (cv.'Moneymaker') using standard virological methods. We successfully infected E. sonchifolia with INSV (confirmed with visual mosaic symptoms and positive INSV ImmunoStrip). However, mechanical inoculation of the tomato plants proved unsuccessful. Using the INSV infected E. sonchifolia leaves as an inoculum source, we generated a viruliferous Frankliniella occidentalis (Western flower thrips) cohort and challenged three week old tomatoes using thrips mediated inoculation (adapted from Aramburu et al. 2009 and Rotenberg et al., 2009). Twenty days post-inoculation, tomatoes with thrips feeding scars were symptomatic for INSV infection with chlorotic and necrotic spots, stunting, and reduced vigor. INSV infection of these tomato plants was verified with a positive INSV ImmunoStrip® result, two-step RT-PCR amplification of N, and Sanger sequencing of N. Samples from thrips-inoculated tomato plants did not test positive for TSWV. Sequence alignment showed that the recovered virus sequence was 99.85% identical to the original INSV sequence from the diagnostic sample (a single nucleotide difference). To the best of our knowledge, this is the first instance of INSV infecting tomato in NC production systems. Although TSWV is more common in vegetable production in NC (253 cases of TSWV compared to 1 case of INSV in vegetable crops based on NC State Plant Disease and Insect Clinic records since 2008), INSV incursion into tomato producing areas is concerning and should be closely monitored, especially at the transplant stage. This report also underscores the importance of using thrips vectors to transmit virus in screening for susceptibility to orthotospoviruses.
RESUMO
Widespread use of tomato cultivars with the Sw-5 resistance gene has led to the emergence of resistance-breaking (RB) strains of tomato spotted wilt virus across the globe. In June of 2022, tomato spotted wilt (TSW) symptoms were observed at two farms (A and B, within 15 miles of each other) in Rowan County, NC on several commercial TSW resistant tomato cultivars (all heterozygous for the Sw-5 gene). At farm A, ~10% of plants had symptomatic foliage with ~30% of fruit with symptoms, while at farm B, up to 50% of plants had symptomatic foliage with ~80% of fruit with symptoms. Visual symptoms included stunting, severe leaf curling and bronzing, necrotic lesions on leaves, petioles and stems, and concentric ring spots on fruit (Supplementary Fig. 1). TSWV ImmunoStrips (AgDia, Elkhart, IN) and reverse-transcription (RT)-PCR with NSm primers (di Rienzo et al 2018) confirmed the presence of TSWV in 12 symptomatic plants sampled across the two farms. Primers designed to detect Impatiens necrotic spot virus, groundnut ringspot virus, tomato chlorotic spot virus, tomato chlorosis virus, alfalfa mosaic virus, and tomato necrotic streak virus (ilarvirus, Badillo et al., 2016) failed to generate amplicons of the expected size from cDNA generated from these field samples. The amplicons from full-length NSm cDNA were sequenced from independent, single-leaflet isolates from the TSWV-positive plants (three from farm A, nine from farm B) with the expectation of finding an amino acid (aa) substitution associated with the Sw-5 RB phenotype identified previously in CA (C118Y, Batuman et al. 2017) or Spain (C118Y and T120N, Lopez et al. 2011). All three nucleotide sequences from farm A contained the NSm C118Y substitution reported in CA. All three sequences were 99% identical (including the C118Y mutation) to NCBI GenBank accession KU179600.1, a TSWV isolate collected from GA in 2014 with no cultivar information reported. The nine nucleotide sequences from farm B contained neither of the two previously reported aa substitutions associated with the RB phenotype. Instead, all contained a D122G substitution within a conserved region of the TSWV NSm protein reported to be involved in direct interaction with the Sw-5 protein (Zhu et al 2017). Likewise, Huang et al (2021) generated a D122A mutation in TSWV-NSm, resulting in failure to elicit a Sw-5 mediated hypersensitive response. Three NSm sequences retrieved from GenBank contained the D122G substitution (AY848921.1, HM015516.1, KU179582.1), however, this mutation was not implicated directly with RB phenotypes (Ciuffo et al., 2005; Lopez et al., 2011; Marshall, 2016). The RB phenotype was confirmed with the NC variants on 'Mountain Merit' (Sw-5) by two means of virus inoculation: mechanical, rub-inoculation with extracted sap from infected plants, and thrips transmission assays with lab colony-maintained, Frankliniella occidentalis, the western flower thrips. Symptomatic leaf tissue obtained from these inoculation assays tested positive for TSWV by DAS-ELISA (AgDia, Elkhart, IN) and RT-PCR with NSm primers, providing definitive evidence of the occurrence of RB-TSWV at both farms, and subsequent sequencing confirmed the C118Y and D122G substitutions. This report warrants further investigation of the putative origins, prevalence and epidemiological implications of RB-TSWV variants in NC tomato production, and the development of new sources of resistance to TSWV.