First report of a resistance-breaking strain of Tomato spotted wilt orthotospovirus infecting Capsicum annuum carrying the Tsw resistance gene in South Korea.

Tomato spotted wilt orthotospovirus (TSWV) was first reported in 2004 from paprika in South Korea (Kim et al., 2004), where it is currently widespread. TSWV infections were reported in chili pepper, tomato, weeds, and ornamental plant species in South Korea (Choi et al., 2014; Choi and Choi, 2015; Yoon et al., 2016; Yoon et al., 2018; Yoon et al., 2019). One of the best strategies for TSWV management is planting resistant cultivars containing the Tsw gene. In 2019 virus-like symptoms were observed in chili pepper (Capsicum annuum) plants bearing the Tsw gene in Anseong-si, South Korea. The infected chili peppers showed mosaic and wilting followed by necrosis on leaves and fruits in the field. To identify the causal virus, symptomatic leaf samples were analyzed using ImmunoStrip kits (Agdia, USA); we detected three pepper-infecting viruses: Pepper mild mottle virus, Cucumber mosaic virus, and TSWV. TSWV was only detected from 40 naturally infected chili pepper plants exhibiting virus-like symptoms. To further confirm the presence of TSWV (named TSWV-P1), we amplified reverse-transcription polymerase chain reaction (RT-PCR) products for L, M, and S RNA segments using tospovirus-specific and TSWV-specific primers (Batuman et al., 2014). Expected fragments of 445, 868, and 777 bp in length were amplified and sequenced. The complete genome sequences of TSWV-P1 from a symptomatic chili pepper plant were also determined using TSWV-specific primers (Choi et al., 2014; Lian et al., 2013). The complete genome sequences of TSWV-P1 were deposited to GenBank (LC549179, LC549180, and LC549181). The sequences of each fragment were identical to a consensus sequence, showing 99.1%, 98.5%, and 98.6% identity with TSWV-L, M, and S RNA (KP008132, AY744492, and KP008134), respectively. These results clearly showed only a single TSWV infection among the naturally infected chili pepper plants, without reassortment between TSWV and another tospovirus. To confirm whether TSWV-P1 is a resistance-breaking (RB) strain, Nicotiana rustica was mechanically inoculated with sap from leaves of the infected pepper samples to propagate TSWV-P1. A non-RB TSWV isolate (TSWV-Kor-lisianthus) from lisianthus was used as a control (Yoon et al., 2017). Two resistant (with Tsw) and two susceptible chili pepper cultivars (20 plants per cultivar) were mechanically inoculated with sap from leaves of the TSWV-infected N. rustica. The incidence rates of disease caused by TSWV-P1 were 90-100% for resistant and 95-100% for susceptible cultivars. In contrast, TSWV-Kor-lisianthus caused symptoms only in the susceptible pepper cultivars (90-100% incidence). TSWV infection in representative plants was confirmed using the TSWV- ImmunoStrip kit and RT-PCR. The NSs gene of TSWV-P1 consists of 1,404 nucleotides (468 amino acids); sequence analysis of the TSWV-P1 NSs gene showed high nucleotide (99.7%) and amino acid identities (99.8%) with the NSs sequences of two TSWV isolates (FR693035, CBX24121). Protein sequence analysis of TSWV-P1 NSs revealed that no amino acid mutation was associated with those of a representative TSWV RB strain, as previously described (Almási et al., 2017), suggesting that TSWV-P1 is a RB strain. Because this TSWV-P1 can overcome resistance conferred by the Tsw gene in commercially grown chili pepper cultivars, it represents a potential threat to pepper production in South Korea.

A quantitative and direct PCR assay for the subspecies-specific detection of Clavibacter michiganensis subsp. michiganensis based on a ferredoxin reductase gene.

The Gram-positive bacterium Clavibacter michiganensis subsp. michiganensis is the causal agent of canker disease in tomato. Because it is very important to control newly introduced inoculum sources from commercial materials, the specific detection of this pathogen in seeds and seedlings is essential for effective disease control. In this study, a novel and efficient assay for the detection and quantitation of C. michiganensis subsp. michiganensis in symptomless tomato and red pepper seeds was developed. A pair of polymerase chain reaction (PCR) primers (Cmm141F/R) was designed to amplify a specific 141 bp fragment on the basis of a ferredoxin reductase gene of C. michiganensis subsp. michiganensis NCPPB 382. The specificity of the primer set was evaluated using purified DNA from 16 isolates of five C. michiganensis subspecies, one other Clavibacter species, and 17 other reference bacteria. The primer set amplified a single band of expected size from the genomic DNA obtained from the C. michiganensis subsp. michiganensis strains but not from the other C. michiganensis subspecies or from other Clavibacter species. The detection limit was a single cloned copy of the ferredoxin reductase gene of C. michiganensis subsp. michiganensis. In conclusion, this quantitative direct PCR assay can be applied as a practical diagnostic method for epidemiological research and the sanitary management of seeds and seedlings with a low level or latent infection of C. michiganensis subsp. michiganensis.

Double mutations in eIF4E and eIFiso4E confer recessive resistance to Chilli veinal mottle virus in pepper.

To evaluate the involvement of translation initiation factors eIF4E and eIFiso4E in Chilli veinai mottle virus (ChiVMV) infection in pepper, we conducted a genetic analysis using a segregating population derived from a cross between Capsicum annuum 'Dempsey' containing an eIF4E mutation (pvr1(2)) and C. annuum 'Perennial' containing an eIFiso4E mutation (pvr6). C. annuum 'Dempsey' was susceptible and C. annuum 'Perennial' was resistant to ChiVMV. All F(1) plants showed resistance, and F(2) individuals segregated in a resistant-susceptible ratio of 166:21, indicating that many resistance loci were involved. Seventy-five F(2) and 329 F(3) plants of 17 families were genotyped with pvr1(2) and pvr6 allele-specific markers, and the genotype data were compared with observed resistance to viral infection. All plants containing homozygous genotypes of both pvr1(2) and pvr6 were resistant to ChiVMV, demonstrating that simultaneous mutations in eIF4E and eIFiso4E confer resistance to ChiVMV in pepper. Genotype analysis of F2 plants revealed that all plants containing homozygous genotypes of both pvr1(2) and pvr6 showed resistance to ChiVMV. In protein-protein interaction experiments, ChiVMV viral genome-linked protein (VPg) interacted with both eIF4E and eIFiso4E. Silencing of eIF4E and eIFiso4E in the VIGS experiment showed reduction in ChiVMV accumulation. These results demonstrated that ChiVMV can use both eIF4E and eIFiso4E for replication, making simultaneous mutations in eIF4E and eIFiso4E necessary to prevent ChiVMV infection in pepper.

Transgenic peppers that are highly tolerant to a new CMV pathotype.

The CMV (cucumber mosaic virus) is the most frequently occurring virus in chili pepper farms. A variety of peppers that are resistant to CMVP0 were developed in the middle of 1990s through a breeding program, and commercial cultivars have since been able to control the spread of CMVP0. However, a new pathotype (CMVP1) that breaks the resistance of CMVP0-resistant peppers has recently appeared and caused a heavy loss in productivity. Since no genetic source of this new pathotype was available, a traditional breeding method cannot be used to generate a CMVP1-resistant pepper variety. Therefore, we set up a transformation system of pepper using Agrobacterium that had been transfected with the coat protein gene, CMVP0-CP, with the aim of developing a new CMVP1-resistant pepper line. A large number of transgenic peppers (T(1), T(2) and T(3)) were screened for CMVP1 tolerance using CMVP1 inoculation. Transgenic peppers tolerant to CMVP1 were selected in a plastic house as well as in the field. Three independent T(3) pepper lines highly tolerant to the CMVP1 pathogen were found to also be tolerant to the CMVP0 pathogen. These selected T(3) pepper lines were phenotypically identical or close to the non-transformed lines. However, after CMVP1 infection, the height and fruit size of the non-transformed lines became shorter and smaller, respectively, while the T(3) pepper lines maintained a normal phenotype.

BAC-derived markers converted from RFLP linked to Phytophthora capsici resistance in pepper (Capsicum annuum L.).

Phytophthora capsici Leonian, an oomycete pathogen, is a serious problem in pepper worldwide. Its resistance in pepper is controlled by quantitative trait loci (QTL). To detect QTL associated with P. capsici resistance, a molecular linkage map was constructed using 100 F(2) individuals from a cross between Capsicum annuum 'CM334' and C. annuum 'Chilsungcho'. This linkage map consisted of 202 restriction fragment length polymorphisms (RFLPs), 6 WRKYs and 1 simple sequence repeat (SSR) covering 1482.3 cM, with an average interval marker distance of 7.09 cM. QTL mapping of Phytophthora root rot and damping-off resistance was performed in F(2:3) originated from a cross between resistant Mexican landrace C. annuum 'CM334' and susceptible Korean landrace C. annuum 'Chilsungcho' using composite interval mapping (CIM) analysis. Four QTL explained 66.3% of the total phenotypic variations for root rot resistance and three 44.9% for damping-off resistance. Of these QTL loci, two were located close to RFLP markers CDI25 on chromosome 5 (P5) and CT211A on P9. A bacterial artificial chromosome (BAC) library from C. annuum 'CM334' was screened with these two RFLP probes to obtain sequence information around the RFLP marker loci for development of PCR-based markers. CDI25 and CT211 probes identified seven and eight BAC clones, respectively. Nine positive BAC clones containing probe regions were sequenced and used for cytogenetic analysis. One single-nucleotide amplified polymorphism (SNAP) for the CDI25 locus, and two SSRs and cleaved amplified polymorphic sequence (CAPS) for CT211 were developed using sequences of the positive BAC clones. These markers will be valuable for rapid selection of genotypes and map-based cloning for resistance genes against P. capsici.

Transgenic watermelon rootstock resistant to CGMMV (cucumber green mottle mosaic virus) infection.

In watermelon, grafting of seedlings to rootstocks is necessary because watermelon roots are less viable than the rootstock. Moreover, commercially important watermelon varieties require disease-resistant rootstocks to reduce total watermelon yield losses due to infection with viruses such as cucumber green mottle mosaic virus (CGMMV). Therefore, we undertook to develop a CGMMV-resistant watermelon rootstock using a cDNA encoding the CGMMV coat protein gene (CGMMV-CP), and successfully transformed a watermelon rootstock named 'gongdae'. The transformation rate was as low as 0.1-0.3%, depending on the transformation method used (ordinary co-culture vs injection, respectively). However, watermelon transformation was reproducibly and reliably achieved using these two methods. Southern blot analysis confirmed that the CGMMV-CP gene was inserted into different locations in the genome either singly or multiple copies. Resistance testing against CGMMV showed that 10 plants among 140 T1 plants were resistant to CGMMV infection. This is the first report of the development by genetic engineering of watermelons resistant to CGMMV infection.

PPI1: a novel pathogen-induced basic region-leucine zipper (bZIP) transcription factor from pepper.

We have isolated a full-length cDNA, PPI1 (pepper-PMMV interaction 1), encoding a novel basic region-leucine zipper (bZIP) DNA-binding protein, from expressed sequence tags differentially expressed in Capsicum chinense P1257284 infected with Pepper mild mottle virus (PMMV). PPI1 encodes a predicted protein of 170 amino acids and contains a putative DNA-binding domain that shares significant amino acid identity with ACGT-binding domains of members of the bZIP DNA-binding protein family. PPI1 was localized in the nucleus and had transcriptional activation activity in yeast. Transcripts of the PPI1 gene were preferentially induced during an incompatible interaction by inoculation with PMMV, Pseudomonas syringae pv. syringae 61, and Xanthomonas campestris pv. vesicatoria race 3. However, the PPII gene was not induced by abiotic stressors that activate the plant defense-signaling pathway. Our data provide the first evidence that a bZIP transcription factor is preferentially induced by pathogen attack, suggesting that PPI1 may play a specific functional role in the regulation of expression of plant defense-related genes.