Since its first occurrence in Israel and Jordan in 2014 and 2015, the tomato brown rugose fruit virus (ToBRFV) has become one of the most concerning pathogens affecting tomatoes and other crops worldwide. Its rapid sp...
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Since its first occurrence in Israel and Jordan in 2014 and 2015, the tomato brown rugose fruit virus (ToBRFV) has become one of the most concerning pathogens affecting tomatoes and other crops worldwide. Its rapid spread is believed to result from the international trade of contaminated seeds and its seed transmissibility, underscoring the critical importance of seed health testing for ToBRFV to prevent further dissemination of the virus. To this end, reverse transcription-quantitative polymerase chain reaction (RT-qPCR) protocols employing TaqMan probe chemistry have been widely adopted. However, the development of RT-qPCR protocols for ToBRFV seed testing using SYBR Green chemistry remains limited. The SYBR Green method offers the advantage of distinguishing ToBRFV from other tobamoviruses through melt curve analysis. In this study, we developed a SYBR Green-based RT-qPCR detection method using newly designed primer sets, which demonstrated high specificity for ToBRFV and sufficient sensitivity. While this protocol requires further optimization and validation for application in routine seed testing, it establishes a foundational approach for SYBR Green-based RT-qPCR seed testing. Additionally, this study raises an important question regarding the relationship between RT-qPCR results in seed tests and the likelihood of virus contamination or transmission via seeds.
The tobamovirus, tomato brown rugose fruit virus (ToBRFV), is a significant concern in global tomato production due to the ineffectiveness of the widely used Tm-2(2) resistance gene. Our previous study showed that the...
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The tobamovirus, tomato brown rugose fruit virus (ToBRFV), is a significant concern in global tomato production due to the ineffectiveness of the widely used Tm-2(2) resistance gene. Our previous study showed that the tomato variety GCR237, a Tm-1 homozygote, resisted an Israeli isolate of ToBRFV (DSMZ PV-1241) for up to 35 days post inoculation (dpi), suggesting Tm-1-homozygous cultivars could control ToBRFV. In the present study, we inoculated GCR237 plants with ToBRFV and cultivated them for a longer period of time. The plants resisted systemic infection up to 50 dpi, but mosaic symptoms appeared on the upper leaves by 100 dpi. We retrieved the virus from symptomatic leaves and established four single local lesion isolates. These isolates had several amino acid (AA) substitutions in the helicase domain of 126-kDa/183-kDa replication proteins, where the Tm-1 protein likely binds to inhibit viral RNA replication. Back-inoculating these isolates onto GCR237 plants confirmed they had acquired the ability to overcome GCR237's resistance and induced mosaic symptoms as early as 14 dpi. About 90% of 229 ToBRFV isolates in the NCBI database had identical AA sequences in the corresponding region to DSMZ PV-1241, while similar to 10% inherently had AA substitutions that would confer complete breaking ability to the Tm-1 resistance. These results suggest that while Tm-1 can inhibit ToBRFV RNA replication, ToBRFV can easily overcome Tm-1 homozygotes.
Since the first report of the tobamovirus tomato brown rugose fruit virus (ToBRFV) in 2014, it has become globally distributed. Its rapid spread has been primarily attributed to seed-borne transmission. Here, the seed...
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Since the first report of the tobamovirus tomato brown rugose fruit virus (ToBRFV) in 2014, it has become globally distributed. Its rapid spread has been primarily attributed to seed-borne transmission. Here, the seed-borne nature of ToBRFV transmission was investigated in different cultivars of tomato, bell pepper, and eggplant. In situ hybridization to localize the virus in reproductive organs of ToBRFV-infected tomato plants revealed that the virus was not present in shoot apices, flower buds, or in ovules during flower opening, indicating the virus may be restricted to the outer integument and transported in the vascular bundles during seed development. However, during early fruit development, the virus was present in the integuments in the ovule. Seeds of tomato cultivars with or without tobamovirus resistance gene Tm-22 transmitted the virus to the progeny seedlings at rates that reflected the ineffectiveness of the gene against ToBRFV. Seeds of bell peppers transmitted ToBRFV at higher rates than tomato seeds, but a bell pepper cultivar that has resistance gene L3 was not systemically infected, and its seeds did not harbor the virus. Three eggplant cultivars were systemically infected with ToBRFV but without showing any obvious symptoms, and even though ToBRFV was present in their seeds, the seedlings were not infected. ToBRFV was detected in the seed coats of contaminated tomato and bell pepper seeds, but not in eggplant seed coats. These results indicate mechanistic differences in seed-borne transmission among the three Solanaceae crops.
Japanese star anise (Illicium anisatum L., JSA) is seriously damaged by a ringspot disease in Japan. Herein, to determine the causal agent using high-throughput sequencing, we discovered viral RNAs associated with JSA...
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Japanese star anise (Illicium anisatum L., JSA) is seriously damaged by a ringspot disease in Japan. Herein, to determine the causal agent using high-throughput sequencing, we discovered viral RNAs associated with JSA ringspot disease. We then determined the complete or near-complete nucleotide sequences of these RNAs using Sanger sequencing and RACE. The complementary strand of viral RNAs 1, 2, 3, 4, and 5 encoded a single protein, which shared sequence identity with P1 (RNA-dependent RNA polymerase), P2 (glycoprotein precursor), P3 (nucleocapsid protein), P4 (movement protein), and a protein with unknown function of emaraviruses (genus Emaravirus), respectively;however, the highest amino acid sequence identity for the P1-P5 proteins between JSARaV and known emaraviruses was 41.9%, 30.0%, 30.1%, 52.2%, and 38.0%, respectively, all of which were lower than the species demarcation criterion. Furthermore, RNA segments harbored conserved 12-nt terminal sequences at the 5 '- and 3 '-termini, and a high complementarity of approximately 20 nt in 5 '- and 3 '-terminal sequences. Transmission electron microscopy confirmed the presence of virus-like particles. JSA ringspot disease was found to be transmitted by an eriophyid mite (subclass Acari, superfamily Eriophyoidea) that belongs to the family Diptilomiopidae. Taken together, these results identified the virus responsible for the ringspot disease of JSA as a new member of the genus, Emaravirus, which we named as the Japanese star anise ringspot-associated virus (JSARaV). Moreover, this is the first report noting that eriophyid mites of the family Diptilomiopidae are capable of transmitting emaravirus.
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