Eggplant (Solanum melongena L.) is an economically important vegetable crop in Brazil, especially in family-based farming. Eggplant hybrids ‘Ciça’ and ‘Napoli’ (≈ 400 plants) were detected exhibiting virus-like symptoms (5-20% incidence) in field surveys (2015–2018) in Brasília–DF (Figure 1). Symptoms included chlorosis, mosaic and apical leaf deformation. Six symptomatic leaf samples were collected from fruit-bearing plants (around 100 days after planting) aiming at verifying the potential orthotospovirus infection. Double antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA) was carried out with polyclonal antibodies (produced at Centro Nacional de Pesquisa de Hortaliças – CNPH) against the N gene coat protein of the three major orthotospoviruses: tomato spotted wilt orthotospovirus (TSWV), groundnut ringspot orthotospovirus (GRSV) and, tomato chlorotic spot orthotospovirus (TCSV). Strong serological reactions were observed only against GRSV antibodies in the extracts from symptomatic samples, but not in the controls. To confirm the causal agent of those symptoms, total RNA was extracted from infected leaf samples via the standard Trizol® (Sigma) protocol and subsequently used in a two-step reverse transcriptase polymerase chain reaction (RT–PCR) approach. Synthesis of the cDNA was carried out with the J13 primer (5’–CCC GGA TCC AGA GCA AT–3’) (Cortez et al., 2001) followed by PCR assays with the primer pair BR60 (5’–AGA GCA ATC GTG TCA–3`) and BR65 (5`–ATC AAG CCT TCT GAA AGT CAT–3’) (Eiras et al., 2002). This primer set amplifies a fragment of 453 bp including the 3’ untranslated region at the 3’ terminus of the S RNA and the protein N-coding gene of at least five species: TSWV, GRSV, TCSV, chrysanthemum stem necrosis orthotospovirus (CSNV) and zucchini lethal chlorosis orthotospovirus (ZLCV). In addition, GRSV-specific primers (LNA Reis, unpublished) were used for amplification of all three segments: L segment: LF/LR (5’–AAC AGG ATT CAG CAA TAT GG–3’/ 5’–AAT TCC TTG AAG ACA ATT GTG T –3’); M segment: MF/MR (5’–TTT GTC CAA CCA TAC CAG ACC C– 3’ / 5’–GGC TTC AAT AAA GGC TTG GG–3’) and, S segment: SF/SR (5’–TTC AAA CTC AGT TGT ACT CTG A–3’/5’–TTA CTT TCG ATC TGG TTG AA– 3’). Amplicons with 509 bp (MT043204), 289 bp (MT043205), and 901 bp (MT043203) were obtained for L, M and S segments of the eggplant isolate DF-687. PCR amplicons corresponding to a segment of the N-coding gene (396 bp) of a second eggplant isolate (BJL02; MK176337) were obtained with the primer pair BR60/BR65 and subjected to Sanger dideoxy sequencing at CNPH. Alignments of nucleotide sequences of both isolates revealed identity levels varying around 99% to the corresponding genomic regions of a large set of GRSV isolates from GenBank database. PCR assays using total RNA as template yielded 494 bp amplicons solely with GRSV-specific primers (Webster et al., 2011), but no products were obtained with TSWV-specific primers (Adkins and Rosskopf, 2002), confirming the former as the sole causal agent of the field symptoms. Leaves of eggplant cv. ‘Ciça’ and indicator hosts, including Nicotiana rustica, Capsicum chinense ‘PI 159236’ (with the Tsw gene), and S. lycopersicum cv. Santa Clara were rub inoculated with extracts prepared from eggplant samples naturally infected with GRSV. Mosaic, necrotic ringspots and systemic leaf deformation symptoms were observed around ten days after inoculation on newly emerged leaves of all inoculated plants. GRSV infection was confirmed by DAS-ELISA and RT-PCR ten days after inoculation. Eggplant was erroneously listed as a host of GRSV in Brazil (Kitajima, 2020). Hence, this is the first report of eggplant infection by this virus in South America. No significant yield losses have been observed in eggplant due to GRSV infection since the overall symptoms are often mild. However, this natural host of GRSV might impact disease management strategies since eggplant is quite often cultivated under family-based farming conditions as a companion crop of highly susceptible tomato, sweet-pepper, and lettuce cultivars. References: Adkins, S., and Rosskopf, E. N. 2002. Plant Dis. 86: 1310. Cortez, I., et al. 2001. Arch. Virol. 146:265. Eiras, M. et al., 2002. Fitopatol. Bras. 27:285. Kitajima, E.W. 2020. Biota Neotrop. 20: e2019932. Webster, C. G., et al. 2011. Virology 413: 216.
