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Burdock (Arctium lappa L., belongs to the family Asteraceae), is an edible plant and an oriental medicinal herb in Korea (Han and Koo, 1993). In July 2023, burdocks showing chlorotic ringspots and yellowing on the leaves were observed in nine of approximately 4,000 plants in a greenhouse in Daegu, South Korea. To determine the causal virus species, nine symptomatic leaves from each individual plant were collected and tested using commercially available immunostrips (Agdia, Elkhart, USA) for cucumber mosaic virus (CMV) and tomato spotted wilt virus (TSWV). Seven out of nine samples tested positive for TSWV only. TSWV in South Korea was first reported on sweet pepper from Yesan in 2004 (Kim et al., 2004) and has since spread to various crops. The first report of TSWV infecting burdock plants in the world was from Hawaii in 1995 (Bautista et al., 1995), but TSWV-infected burdock has not been reported in Korea. To further confirm the presence of TSWV, total RNA was extracted from TSWV-positive burdock leaves using the RNeasy Plant Mini Kit (Qiagen, Hilden, Germany) and used in reverse transcription-polymerase chain reaction (RT-PCR) assays with a specific primer set that amplifies 777 bp of nucleocapsid gene (N gene) of TSWV (Yoon et al., 2014). To obtain the complete genome sequence of this TSWV in the burdock plant, named TSWV-DG, fragments of L, M, and S segments were amplified and sequenced. The complete genome sequences of the L (8914 nt), M (4773 nt), and S (2946 nt) segments were obtained by overlapping RT-PCR amplicons. RT-PCR products were cloned into the pGEM-T Easy vector, and selected DNA clones were sequenced using Sanger method (Bioneer, Korea). The complete genome sequences were deposited to GenBank (LC790665, LC790666, and LC790667, respectively). BLASTn analysis showed that sequences of each TSWV-DG segment had maximum nucleotide identities of 99.5%, 99.5%, and 99.5% with TSWV-L, TSWV-M, and TSWV-S (OM154971, OM154970, and OM154969, respectively), which were isolated from water dropwort (Oenanthe crocata) in China (Qiu et al., 2023). To assess the biological activity of TSWV-DG, A. lappa and Nicotiana benthamiana were inoculated mechanically with sap from infected burdock leaves and maintained for visual inspection of virus symptoms at 25 ℃ at 3 weeks. TSWV-DG produced symptoms on the systemic leaves of A. lappa, that included chlorotic spots and yellowing, and on the leaves of N. benthamiana, that included chlorotic spots and mosaic patterns from 14 days-post-inoculation. Meanwhile, mock-inoculated A.lappa and N.benthamiana remained symptomless. The presence of TSWV on the inoculated leaves was subsequently confirmed through Immunostrip and RT-PCR analyses. TSWV may pose a significant threat to the production of A. lappa, which is cultivated as both leafy greens and root vegetables in Korea. Furthermore, A. lappa may not only be at risk of damage from TSWV infection but also act as a potential source of TSWV infection, thereby posing a risk of transmission to other key crops in Korea, such as pepper or potato (Yoon et al., 2014). This is the first report TSWV infecting burdock in South Korea.

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Several studies have showed that the nucleotide and dinucleotide composition of viruses possibly follows their host species or protein coding region. Nevertheless, the influence of viral segment on viral nucleotide and dinucleotide composition is still unknown. Here, we explored through tomato spotted wilt virus (TSWV), a segmented virus that seriously threatens the production of tomatoes all over the world. Through nucleotide composition analysis, we found the same over-representation of A across all viral segments at the first and second codon position, but it exhibited distinct in segments at the third codon position. Interestingly, the protein coding regions which encoded by the same or different segments exhibit obvious distinct nucleotide preference. Then, we found that the dinucleotides UpG and CpU were overrepresented and the dinucleotides UpA, CpG and GpU were underrepresented, not only in the complete genomic sequences, but also in different segments, protein coding regions and host species. Notably, 100% of the data investigated here were predicted to the correct viral segment and protein coding region, despite the fact that only 67% of the data analyzed here were predicted to the correct viral host species. In conclusion, in case study of TSWV, nucleotide composition and dinucleotide preference of segment viruses are more strongly dependent on segment and protein coding region than on host species. This research provides a novel perspective on the molecular evolutionary mechanisms of TSWV and provides reference for future research on genetic diversity of segmented viruses.

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The tomato spotted wilt virus (TSWV) is a member of the Tospoviridae family and has an negative/ambisense single-stranded RNA genome. Frankliniella occidentalis and F. intonsa are known to be dominant pests in Capsicum annuum (hot pepper) and can cause damage to the plant either directly by feeding, or indirectly by transmitting TSWV in a persistent and propagative manner, resulting in serious economic damage. This study compared the immune responses of two different thrips species against TSWV infection by transcriptome analysis, which then allowed the assessment of antiviral responses using RNA interference (RNAi). Both adult thrips shared about 90 % of the transcripts in non-viruliferous conditions. Most signal components of the immune pathways were shared by these two thrips species, and their expression levels fluctuated differentially in response to TSWV infection at early immature stages. The functional assays using RNAi treatments indicated that the Toll and JAK/STAT pathways were associated with the antiviral responses, but the IMD pathway was not. The upregulation of dorsal switch protein one supported its physiological role in recognizing TSWV infection and triggering the eicosanoid biosynthetic pathway, which mediates melanization and apoptosis in thrips. In addition, the signal components of the RNAi pathways fluctuated highly after TSWV infection. Individual RNAi treatments specific to the antiviral signalling and response components led to significant increases in the TSWV amount in the thrips, causing virus-induced mortality. These findings suggest that immune signalling pathways leading to antiviral responses are operating in the thrips to regulate TSWV litres to prevent a fatal viral overload. This study also indicates the differential antiviral responses between the TSWV-transmitting F. occidentalis and F. intonsa.

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An in-house tomato inbred line, YNAU335, was planted in a greenhouse in spring from 2014 to 2017, and showed immunity to tomato spotted wilt virus (TSWV). YNAU335 was infected with TSWV in the spring from 2018 to 2020, and disease was observed on the leaves, sepals, and fruits. In 2021 and 2022, YNAU335 was planted in spring in the same greenhouse, which was suspected of being infected with TSWV, and visible disease symptoms were observed on the fruits. Transmission electron microscopy, deep sequencing of small RNAs, and molecular mutation diagnosis were used to analyze the pathological features and genetic polymorphism of TSWV infecting tomato fruit. Typical TSWV virions were observed in the infected fruits, but not leaves from YNAU335 grown between 2021 and 2022, and cross-infection was very rarely observed. The number of mitochondria and chloroplasts increased, but the damage to the mitochondria was greater than that seen in the chloroplasts. Small RNA deep sequencing revealed the presence of multiple viral species in TSWV-infected and non-infected tomato samples grown between 2014-2022. Many virus species, including TSWV, which accounted for the largest proportion, were detected in the TSWV-infected tomato leaves and fruit. However, a variety of viruses other than TSWV were also detected in the non-infected tissues. The amino acids of TSWV nucleocapsid proteins (NPs) and movement proteins (MPs) from diseased fruits of YNAU335 picked in 2021-2022 were found to be very diverse. Compared with previously identified NPs and MPs from TSWV isolates, those found in this study could be divided into three types: non-resistance-breaking, resistance-breaking, and other isolates. The number of positive clones and a comparison with previously identified amino acid mutations suggested that mutation F at AA118 of the MP (GenBank OL310707) is likely the key to breaking the resistance to TSWV, and this mutation developed only in the infected fruit of YNAU335 grown in 2021 and 2022.

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Capsicum annuum (CA) is grown outdoors across fields in Jeollabuk-do, South Korea. The weeds surrounding these fields were investigated regarding the infection of 11 viruses infecting CA during the year 2014-2018. In the reverse transcription polymerase chain reaction diagnosis, 546 out of 821 CA samples (66.5%) were infected by nine viruses, and 190 out of 918 weed samples (20.7%) were infected by eight viruses. Correlation analysis of the mutual influence of the viruses infecting CA and weeds during these 5 years showed that five viruses had significant positive correlations with the infection in both CA and weeds. Over the study period, the weeds infected by cucumber mosaic virus (CMV) in the previous year were positively correlated with the incidence of CMV infection in CA in the current year, although the correlation was lower for tomato spotted wilt virus (TSWV) compared to CMV. The CMV infection percent was 14.0% in summer annuals, 11.4% in perennials, and 7.8% in winter annuals. However, considering the overwintering period without CA, the infection percent was 5.2% higher in winter annuals and perennials than that in summer annuals, indicating that winter annual and perennial weeds served as the main habitats for insect vectors. The TSWV infection percent in weeds was 10.4% in summer annuals, 6.4% in winter annuals, and 6.2% in perennials. The weeds surrounding CA fields, acting as the intermediate hosts, were found to be the potent sources of infection, influencing the spread and diversity of CA-infecting viruses. The results of this study can contribute to prevent viral infection in agricultural fields.

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Tomato spotted wilt virus (TSWV, family Tospoviridae, genus Orthotospovirus) is a thrips-vectored pathogen that infects lettuce (Lactuca sativa) and many vegetable crops (Kuo et al. 2014, Hasegawa et al. 2022). Another thrips-borne pathogen of lettuce, impatiens necrotic spot virus (INSV, Tospoviridae, Orthotospovirus), was first reported in 2021 in Yuma, Arizona (Hasegawa et al. 2022). Symptoms of both viruses in lettuce are similar and include necrotic spotting, leaf chlorosis and plant stunting (Kuo et al. 2014). Beginning February through April of 2022, lettuce displaying symptoms of orthotospovirus infection was collected from romaine lettuce (var. longifolia) fields in three regions of Yuma County. A total of 96 plants were collected (5 from Tacna on 2/21, 5 from Wellton on 2/21, 15 from Wellton on 3/23, 30 from Tacna on 4/4, 20 from Wellton on 4/4, and 21 from Yuma Valley on 4/4). The area of the fields ranged from 10 to 18 acres, and the percent disease incidence ranged from 0.8% (Tacna on 4/4) to 2.75% (Tacna on 2/21). Thrips vector were present in all fields were symptomatic plants were observed. One leaf disk per plant (8 mm in diameter) was sampled with a cork borer and grounded individually with a micro pestle in a 1.7 ml microcentrifuge tube with 150 ul of Tri-reagent (Molecular Research Center). Total RNA was extracted from each sample using the Zymo Direct-zol-96 kit (Zymo Research). Samples were diluted with water to a ratio of 1:10 after RNA extraction. RT-qPCR was performed in 20 ul reactions with 5 ul of input RNA using the PCR Biosystems qPCRBIO Probe 1-Step Go No-ROX for the cDNA/qPCR master mix. RT-qPCR assays were carried out in multiplex reactions using primers specific for TSWV and INSV, in addition to a lettuce internal control gene (LOC111918243), along with negative controls. Primer and probe sequence details are reported in supplemental Table 1. We used a cycle threshold (ct) < 40 to indicate a positive result for both INSV and TSWV (Chen et al. 2013; Boonham et al. 2002). RT-qPCR successfully amplified INSV in 90 out of 96 samples and TSWV in 8 out of 96 samples. These 8 samples tested positive for both TSWV and INSV, showing that INSV and TSWV co-infected lettuce plants. Thus overall, ∼ 95% of symptomatic plants were infected with INSV alone, and ∼ 8% were co-infected with TSWV and INSV. Amplicons of 4 samples testing positive for TSWV were sent for Sanger sequencing (Eurofins Genomics, Louisville, KY). All were identified as TSWV. One amplicon with TSWV was sequenced for INSV and double infection was confirmed. BLAST results from the NCBI nt database show 100% (138 bp) identity to TWSV (MW519211) for the 4 TWSV amplicons and 99.22% (137 bp) identity to INSV (KX790323) for the INSV amplicon. Sanger sequence data are in the GenBank (accession: OQ685940-OQ685944). Based on RT-qPCR results, all TSWV infected plants were also infected with INSV. INSV may have been introduced to Yuma by infected plants or thrips from lettuce transplants produced in California (Hasegawa et al. 2022). TSWV could have been introduced similarly. To our knowledge, this is the first report of TSWV infecting lettuce in Yuma and the first report of INSV and TSWV co-infecting lettuce. TSWV and INSV infections have remained low since their discovery in Yuma, in part due to effective cultural and chemical management by lettuce growers (Palumbo, 2022). However, an increase in disease incidence and severity in the future could have a significant negative impact on production of romaine lettuce in the region.

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The nonstructural protein NSm of tomato spotted wilt virus (TSWV) has been identified as the avirulence determinant of the tomato single dominant Sw-5 resistance gene. Although Sw-5 effectiveness has been shown for most TSWV isolates, the emergence of resistance-breaking (RB) isolates has been observed. It is strongly associated with two point mutations (C118Y or T120N) in the NSm viral protein. TSWV-like symptoms were observed in tomato crop cultivars (+Sw-5) in the Baja California peninsula, Mexico, and molecular methods confirmed the presence of TSWV. Sequence analysis of the NSm 118-120 motif and three-dimensional protein modelling exhibited a noncanonical C118F substitution in seven isolates, suggesting that this substitution could emulate the C118Y-related RB phenotype. Furthermore, phylogenetic and molecular analysis of the full-length genome (TSWV-MX) revealed its reassortment-related evolution and confirmed that putative RB-related features are restricted to the NSm protein. Biological and mutational NSm 118 residue assays in tomato (+Sw-5) confirmed the RB nature of TSWV-MX isolate, and the F118 residue plays a critical role in the RB phenotype. The discovery of a novel TSWV-RB Mexican isolate with the presence of C118F substitution highlights a not previously described viral adaptation in the genus Orthotospovirus, and hence, the necessity of further crop monitoring to alert the establishment of novel RB isolates in cultivated tomatoes.

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Strawflower (Helichrysum bracteatum, Asteraceae) , an annual or biennial herb, is one of the most popular flowers in the world because of the colorful flowers and the long flowering period. However, the ornamental plants belonging to Asteraceae are susceptible to numerous viruses such as cucumber mosaic virus (CMV) (Cucumovirus, Bromoviridae) , potato virus Y (Potyvirus, Potyviridae), tomato mosaic virus (ToMV) (Tobamovirus, Virgaviridae), tobacco mosaic virus (TMV) (Tobamovirus, Virgaviridae), chrysanthemum virus B (CVB) (Carlavirus, Betaflexiviridae), tomato aspermy virus (TAV) (Cucumovirus, Bromoviridae), tomato spotted wilt virus (TSWV) (Orthotospovirus tomatomaculae, Tospoviridae), and impatiens necrotic spot virus (INSV) (Orthotospovirus impatiensnecromaculae, Orthotospovirus) resulting in severe yield loss (Verma et al. 2003; Raj et al. 2007; Kondo et al. 2011; Liu et al. 2014; Marys et al. 2014; Min et al. 2020; Gautam et al. 2021; Read et al. 2022; Supakitthanakorn et al. 2022). Among these viruses, the TSWV, a thrips-transmitted negative-stranded RNA virus, is well known to cause viral disease in several plant species while is less reported in Helichrysum, especially in China. In April 2021, viral attack symptoms were detected on the leaves of H. bracteatum during our routine checks in the greenhouse located at Shunyi District, Beijing, China, such as wilting, shrinking, chlorotic blotches, chlorotic ring spots. To investigate the virus infecting H. bracteatum, in total of 25 symptomatic and 5 asymptomatic leaves were sampled and tested by the effective double antibody sandwich enzyme-linked immunosorbent assay (DAS-ELISA) using antisera against CMV, PVY/PVX, ToMV, TMV, CVB, TAV, TSWV, INSV, separately (Agdia, USA). Only the TSWV showed positive in symptomatic samples, and asymptomatic samples were all negative, which implied TSWV infection. To further confirm the virus type of TSWV isolated from H. bracteatum samples, the genomic RNA of the virus was isolated using reverse transcription and polymerase chain reaction (RT-PCR), and then was cloned, sequenced and analyzed. Total RNA of five symptomatic leaves (ELISA-positive) were extracted using the FastPure Plant Total RNA Isolation Kit (Vazyme, China), and then were reverse transcribed by HiScript II Reverse Transcriptase (Vazyme, China). Each genome segments were amplified using Phanta Max Super-Fidelity DNA Polymerase (Vazyme, China) with TSWV-specific primers newly designed and listed in Table S1. The PCR setup was as follow: 95°C for 30 s, followed by 35 cycles at 95°C for 30 s, 55°C for 30 s, and 72°C for 1.5 min, with a final extension at 72°C for 10 min. All PCR products were cloned into the TA/Blunt-Zero vector (Vazyme, China) and sequenced (GENEWIZ, Inc.). We assembled and then analyzed the evolutionary relationship of three genomic fragments, that is, TSWV-BJFC-Hb S (2923 bp), M (4785 bp) and L (8971 bp) using the BLAST tools. The results showed high similarity with TSWV-henan isolated from pepper in China (99.6% to TSWV-S (MT799179.1), 99.8 % to TSWV-M (MT799178.1) and 99.8 % TSWV-L (MT799177.1)). These sequences have been submitted to the GenBank (OM982910, OM982911 and OM937131). Taking all of these evidences together, the viral disease observed in H. bracteatum was closely associated with TSWV. TSWV is currently widespread in China, infecting Nasturtium, Chrysanthemum and cowpea (Xiao et al. 2015; Hu et al. 2018; Yu et al. 2021). Epidemics of TSWV have also been reported in several other countries such as Korea, North Carolina, Turkey and India (Renukadevi et al. 2015; Koehler et al. 2016; Kwak et al. 2021; Erilmez, S. 2022). This is the first report of TSWV infection on H. bracteatum in China. Due to the fast spread and serious economic losses of TSWV, the rapid detection may be the essential way to prevent this viral disease among crops (Macharia et al. 2014).

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A total of 35 piperazine derivatives were designed and synthesized, and their activities against tomato spotted wilt virus (TSWV) were evaluated systematically. Compounds 34 and 35 with significant anti-TSWV activity were obtained. Their EC50 values were 62.4 and 59.9 µg/mL, prominently better than the control agents ningnanmycin (113.7 µg/mL) and ribavirin (591.1 µg/mL). To explore the mechanism of the interaction between these compounds and the virus, we demonstrated by agrobacterium-mediated, molecular docking, and microscale thermophoresis (MST) experimental methods that compounds 34 and 35 could inhibit the infection of TSWV by binding with the N protein to prevent the assembly of the virus core structure ribonucleoprotein (RNP), and it also meant that the arginine at 94 of the N protein was the key site of interaction between the compounds and the TSWV N target. Therefore, this study demonstrated the potential for forming antiviral agents from piperazine derivatives containing α-ketoamide moieties.

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Phytohormones play important roles in plant immunity. Recently, Chen et al. discovered that the tomato spotted wilt virus attacks the plant hormone receptor to promote infection. Plants evolved an immune receptor to mimic the attacked hormone receptors to recognize the virus, thereby activating a robust immune response.

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CRISPR/Cas genome-editing tools provide unprecedented opportunities for basic plant biology research and crop breeding. However, the lack of robust delivery methods has limited the widespread adoption of these revolutionary technologies in plant science. Here, we report an efficient, non-transgenic CRISPR/Cas delivery platform based on the engineered tomato spotted wilt virus (TSWV), an RNA virus with a host range of over 1000 plant species. We eliminated viral elements essential for insect transmission to liberate genome space for accommodating large genetic cargoes without sacrificing the ability to infect plant hosts. The resulting non-insect-transmissible viral vectors enabled effective and stable in planta delivery of Cas12a and Cas9 nucleases as well as adenine and cytosine base editors. In systemically infected plant tissues, the deconstructed TSWV-derived vectors induced efficient somatic gene mutations and base conversions in multiple crop species with little genotype dependency. Plants with heritable, bi-allelic mutations could be readily regenerated by culturing the virus-infected tissues in vitro without antibiotic selection. Moreover, we showed that antiviral treatment with ribavirin during tissue culture cleared the viral vectors in 100% of regenerated plants and further augmented the recovery of heritable mutations. Because many plants are recalcitrant to stable transformation, the viral delivery system developed in this work provides a promising tool to overcome gene delivery bottlenecks for genome editing in various crop species and elite varieties.

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BACKGROUND: Tomato spot wilt virus (TSWV) and tomato yellow leaf curl virus (TYLCV) are highly harmful viruses in agricultural production, which can cause serious economic losses to crops and even devastating consequences for vegetable yield in some countries and regions. Although the two viruses belong to different families and have different transmission vectors, they share most hosts. OBJECTIVE: This study aimed to examine the transcriptomic expression of single and mixed inoculations of TSWV and TYLCV, leading to antagonism using high-throughput RNA sequencing. METHODS: We confirmed the single and mixed infections of these viruses in Nicotiana benthamiana (N. benthamiana) by artificial inoculation. And the expression changes of related genes and their biological functions and pathways during the mixed infection of TSWV and TYLCV were analyzed by comparative transcriptome. RESULTS: Basically, similar symptoms were observed in the plants singly infected with TSWV and co-infected with TYLCV; the symptoms of TYLCV in the co-infected plants were not obvious compared with single TYLCV infections. When inoculated with TYLCV, the accumulation of the virus significantly reduced in single and mixed infections with TSWV; the TSWV accumulated slightly less in co-infection with TYLCV, whereas this reduction was much smaller than that of TYLCV. The results suggested that TSWV had an antagonistic effect on the accumulation of TYLCV in N. benthamiana. It mainly focused on the changes in unique differentially expressed genes (DEGs) caused by the co-infection of TSWV and TYLCV. The eight pathways enriched by upregulated DEGs mainly included amino acid biosynthesis, citrate cycle (or tricarboxylic acid cycle, TCA cycle), and so on. However, only pentose phosphate pathway (PPP) and peptidoglycan biosynthesis could be downregulated in the Kyoto Encyclopedia of Genes and Genomes pathway in which peptidoglycan biosynthesis was involved in upregulated and downregulated pathways. CONCLUSIONS: The antagonistic effect of TSWV on TYLCV in N.benthamiana and the change trends and specific pathways of DEGs in this process were found. Our study provided new insights into the host regulation and competition between viruses in response to TSWV and TYLCV mixed infection.

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Tomato spotted wilt virus (TSWV) causes severe viral diseases on many economically important plants of Solanaceae. During the infection process of TSWV, a series of 3'-truncated subgenomic RNAs (sgRNAs) relative to corresponding genomic RNAs were synthesized, which were responsible for the expression of some viral proteins. However, corresponding genomic RNAs (gRNAs) seem to possess the basic elements for expression of these viral proteins. In this study, molecular characteristics of sgRNAs superior to genomic RNAs in viral protein expression were identified. The 3' ends of sgRNAs do not cover the entire intergenic region (IGR) of TSWV genomic RNAs and contain the remarkable A-rich characteristics. In addition, the 3' terminal nucleotides of sgRNAs are conserved among different TSWV isolates. Based on the eIF4E recruitment assay and subsequent northern blot, it is suggested that the TSWV sgRNA, but not gRNA, is capped in vivo; this is why sgRNA is competent for protein expression relative to gRNA. In addition, the 5' and 3' untranslated region (UTR) of sgRNA-Ns can synergistically enhance cap-dependent translation. This study further enriched the understanding of sgRNAs of ambisense RNA viruses.

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Tospoviruses infect numerous crop species worldwide, causing significant losses throughout the supply chain. As a defence mechanism, plants use RNA interference (RNAi) to generate virus-derived small-interfering RNAs (vsiRNAs), which target viral transcripts for degradation. Small RNA sequencing and in silico analysis of capsicum and N. benthamiana infected by tomato spotted wilt virus (TSWV) or capsicum chlorosis virus (CaCV) demonstrated the presence of abundant vsiRNAs, with host-specific differences evident for each pathosystem. Despite the biogenesis of vsiRNAs in capsicum and N. benthamiana, TSWV and CaCV viral loads were readily detectable. In response to tospovirus infection, the solanaceous host species also generated highly abundant virus-activated small interfering RNAs (vasiRNAs) against many endogenous transcripts, except for an N. benthamiana accession lacking a functional RDR1 gene. Strong enrichment for ribosomal protein-encoding genes and for many genes involved in protein processing in the endoplasmic reticulum suggested co-localisation of viral and endogenous transcripts as a basis for initiating vasiRNA biogenesis. RNA-seq and RT-qPCR-based analyses of target transcript expression revealed an inconsistent role for vasiRNAs in modulating gene expression in N. benthamiana, which may be characteristic of this tospovirus-host pathosystem.

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To explore the novel compounds with high antiviral activity, three series ferulic acid derivatives containing amide moiety were gradually designed and synthesized based on antiviral activity tracking. The bioassay results exhibited that some target compounds had notable antiviral activities against tomato spotted wilt virus (TSWV) and cucumber mosaic virus (CMV). Compounds Y1, Y2, Y8, Z1 and Z2 presented splendid curative, protective, and inactivating activities to TSWV and CMV at 500 µg/mL. Especially, these compounds displayed outstanding inactivating effects on TSWV with the EC50 values of 225.9, 126.1, 224.6, 216.1, and 147.3 µg/mL, which were superior to ningnanmycin (249.1 µg/mL) and ribavirin (315.7 µg/mL). Furthermore, the antiviral mechanisms of compound Y2 were investigated by conducting microscale thermophoresis experiment and molecular docking experiment. The results suggested that compound Y2 performed excellent binding affinity to TSWV coat protein (TSWV CP) with the binding constant of 2.14 µM, which due to two strong hydrogen bonds of compound Y2 to the key amino acids ARG94 of TSWV CP. Therefore, compound Y2 can be regarded as a leading structure for development of the potential antiviral agent.

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Water dropwort (Oenanthe javanica) is an aquatic perennial plant that has been cultivated in many regions in Asia for thousands of years. In China, it is an economically important vegetable that has been consumed as food, while also being used as a folk remedy to alleviate diseases (Liu et al., 2021). In 2021, during a disease survey of a greenhouse in Beijing, China, chlorotic spots were detected on many water dropwort plants (Fig. S1A). Twenty-seven water dropwort samples were collected for the extraction of total RNA using the TRIzol reagent (Invitrogen, USA). High-quality RNA samples from three water dropwort plants were combined and used as the template for constructing a single small RNA library (BGI-Shenzhen Company, China). The Velvet 1.0.5 software was used to assemble the clean reads (18 to 28 nt) into larger contigs, which were then compared with the nucleotide sequences in the National Center database using the BLASTn algorithm. Thirty-eight contigs matched sequences in the tomato spotted wilt virus (TSWV) genome. No other viruses were detected. Twenty-seven leaf samples were analyzed in an enzyme-linked immunosorbent assay (ELISA) with anti-TSWV antibody (Agdia, USA), which revealed 17 positive reaction. Two sets of primer pairs targeting different parts of the S RNA (Table S1) was used to verify the TSWV infection on water dropwort by reverse transcription (RT)-PCR followed by Sanger sequencing (BGI-Shenzhen, China). The TSWV target sequences were amplified from 17 samples, which was consistent with the ELISA results. The sequenced 861-bp PCR product shared 99.8% nucleotide sequence identity with TSWV isolate MR-01 (MG593199), while the 441-bp amplicon shared a 99.2% nucleotide sequence identity with MR-01 (MG593199). To obtain the whole genome sequence of TSWV (S, M, and L RNA sequences), specific RT-PCR primers were designed (Table S1) and used to amplify their respective fragments from one representative sample (TSWV-water dropwort). The amplified products were inserted into PCE2TA/Blunt-Zero vector (Vazyme Biotech Co., Ltd, China) and then sequenced (BGI-Shenzhen, China). The S, M, and L RNA sequences were determined to be 2,952 nt (accession no. OM154969), 4,776 nt (accession no. OM154970), and 8,914 nt (accession no. OM154971), respectively. BLASTn analysis demonstrated that the whole genome sequence was highly conserved. The nucleotide identities between this isolate and other TSWV isolates ranged from 98.6% to 99.6% (S RNA), 98.9% to 99.2% (M RNA), and 97.3% to 98.7% (L RNA). Using MEGA 7.0, the phylogenetic relationships of TSWV were determined on the basis of the S, M, and L RNA full-length sequences (Kumar et al., 2016). In the S RNA derived phylogenetic tree, the water dropwort isolate was closely related to the MR-01 isolate from the USA (MG593199). In the M RNA and L RNA derived phylogenetic trees, the water dropwort isolate formed a branch with only a TSWV isolate from eggplant. Additionally, the M and L RNA sequences were most similar to sequences in TSWV isolates from China and Korea, respectively (Fig. S1B). To the best of our knowledge, this is the first report of water dropwort as a natural host for TSWV in China and the second report worldwide since the first finding in the Korea (Kil et al. 2020). TSWV has caused serious problems on many crops in the world, and the infection of TSWV on water dropwort in a greenhouse should not be looked lightly. Firstly, the virus can be passed on from generation to generation in infected water dropwort due to the vegetative propagation mode of the plant in production, thus threaten the production of this vegetable crop. In addition, infected water dropwort may serve as a reservoir for the virus, thus potentially posing a threat for causing TSWV spread in the affected greenhouses. The author(s) declare no conflict of interest. Funding: This research was supported by the Beijing Academy of Agriculture and Forestry Foundation, China (QNJJ202131, KJCX20200212, and KJCX20200113). References: Kil et al. 2020. Plant Pathol. J. 36: 67-75 Kumar et al. 2016. Mol Biol Evol, 33: 1870-1874 Liu et al. 2021. Horticulture Research. 8:1-17.

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Biochar is a rich carbon product obtained by pyrolysis of biomass under a limited supply of oxygen. It is composed mainly of aromatic molecules, but its agronomic value is hard to evaluate and difficult to predict due to its great variable characteristics depending on the type of starting biomass and the conditions of pyrolysis. Anyway, it could be used as soil amendment because it increases the soil fertility of acidic soils, increases the agricultural productivity, and seems to provide protection against some foliar and soilborne diseases. In this study, the effects of biochar, obtained from olive pruning, have been evaluated on tomato seedlings growth and on their response to systemic agents' infection alone or added with beneficial microorganisms (Bacillus spp. and Trichoderma spp.). First, experimental data showed that biochar seems to promote the development of the tomato seedlings, especially at concentrations ranging from 1 to 20% (w/w with peat) without showing any antimicrobial effects on the beneficial soil bacteria at the tomato rhizosphere level and even improving their growth. Thus, those concentrations were used in growing tomato plants experimentally infected with tomato spotted wilt virus (TSWV) and potato spindle tuber viroid (PSTVd). The biochar effect was estimated by evaluating three parameters, namely, symptom expression, number of infected plants, and pathogen quantification, using RT-qPCR technique and -ΔΔCt analysis. Biochar at 10-15% and when added with Trichoderma spp. showed that it reduces the replication of PSTVd and the expression of symptoms even if it was not able to block the start of infection. The results obtained on TSWV-infected plants suggested that biochar could contribute to reducing both infection rate and virus replication. For systemic viral agents, such as PSTVd and TSWV, there are no curative control methods, and therefore, the use of prevention means, as can be assumed the use biochar, for example, in the nursery specialized in horticultural crops, can be of great help. These results can be an encouraging starting point to introduce complex biochar formulates among the sustainable managing strategies of plant systemic diseases.

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The Sw5 gene cluster furnishes robust resistance to Tomato spotted wilt virus in tomato, which has led to its widespread applicability in agriculture. Among the five orthologs, Sw5b functions as a resistance gene against a broad-spectrum tospovirus and is linked with tospovirus resistance. However, its paralog Sw5a has been recently implicated in providing resistance against Tomato leaf curl New Delhi virus, broadening the relevance of the Sw5 gene cluster in promoting defense against plant viruses. We propose that plants have established modifications within the homologs of R genes that permit identification of different effector proteins and provide broad and robust resistance against different pathogens through activation of the hypersensitive response and cell death.

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Tomato spotted wilt virus (TSWV) is a highly destructive virus for pepper. Introgression of the resistance gene Tsw in pepper is used to manage TSWV worldwide; however, the occurrence of Tsw resistance-breaking (RB) variants threatens the pepper industry. Here, we developed a multiplex reverse-transcription PCR assay for detection of recently emerged Tsw RB variants in South Korea with high specificity and sensitivity.

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