Plant breeding requires genetic diversity of useful traits for crop improvement. EMS-induced mutation is practiced to generate mutations at loci regulating economically important traits and/or to knock out the genes to elucidate their functions. The present study was aimed to induce mutations in a Korean local land race Capsicum annuum ‘Yuwol-cho’. This accession is pungent and also has advantage to mature early. A total of about 1,500 M2 families were screened and three non-pungent mutants were identified and crossed with wild type ‘Yuwol-cho’. After phenotyping of F2 population for pungency, MutMap approach will be used to identify the genes controlling the pungency in mutants. In addition to this, another C. annuum accession “Micro-Pep” was used to develop a mutant population. Micro-Pep is a small, pungent pepper generally used as ornamental purpose. Having compact growth habit, and small size, it has advantage to handle and utilize easily in mutation study and molecular research. On the basis of preliminary experiment 1.3% of mutagen was used for treatment of pepper seeds and 30% less germination percentage was observed in EMS treated seeds in comparison to control seeds. A total of 4,674 M1 plants are grown under greenhouse condition and M2 population will be studied for characterization of phenotypic variation including fruit color and pungency. Newly constructed mutant populations will be valuable assets for identification of functional genes and molecular breeding of pepper.

GWAS (Genome-wide association study) provides a useful to associate phenotypic variation to genetic variation. It has emerged as a powerful approach for identifying genes underlying complex diseases or morphological traits at an unprecedented rate. Despite benefits, there are only a few examples applied in crop plants due to lack of effective genotyping techniques and well prepared resources for developing high density haplotype maps. In this study, 350 core accessions selected from almost 5,000 Capsicum accessions were used for GWAS. We are planning to construct a high-density haplotype map using GBS platform and perform GWAS for various agronomic traits including fruit traits and metabolites related to pungency to identify genes controlling the traits. These results will not only provide a list of candidate loci but also a powerful tools for finding genetic variants that can be directly used for crop improvement and deciphering the genetic architecture of complex traits.

Pepper (Capsicum spp.) germplasm shows diverse phenotypic variations including fruit size, color, pungency, and many other horticultural traits. Traditional markers including SSR, AFLP, and RFLP have been used to construct genetic maps using biparental populations. However to assess the genetic diversity of large number of germplasm, a robust and rapid marker development and genotyping approach is needed. We used six pepper accessions including C. annuum, C. chinense, C. baccatum and C. frutescens and performed genotyping-by-sequencing (GBS). To select the most appropriate condition, eight different 2 bp selective nucleotides were used to make GBS libraries. Selective nucleotide ‘OO’ showed the largest number of reads in all samples, and 11,026 to 47,957 high-quality SNPs were called in six accessions. When C. annuum ‘CM334’ genome sequence was used as a reference, C. annuum showed the smallest number of SNPs, while C. baccatum which was known to be a different Capsicum clade showed the largest number of SNPs. Pepper core collection chosen to represent the genetic diversity of whole germplasm will be genotyped by high-density SNPs developed from GBS. We will perform genome-wide association study (GWAS) using genetic and phenotypic variation to identify the functional genetic loci controlling horticultural traits.

Capsicum annuum ‘Bukang’ is a resistant variety to Cucumber mosaic virus isolate-P0 (CMV-P0), CMV-P1 can overcome the CMV resistance of ‘Bukang’ due to mutations in Helicase (Hel) domain of CMV RNA1. To identify host factors involved in CMV-P1 infection, a yeast two-hybrid system derived from C. annuum ‘Bukang’ cDNA library was used. A total of 156 potential clones interacting with the CMV-P1 RNA helicase domain were isolated. These clones were confirmed by β-galactosidase filter lift assay, PCR screening and sequence analysis. Then, we narrowed the ten candidate host genes which are related to virus infection, replication or virus movement. To elucidate functions of these candidate genes, each gene was silenced by virus induced gene silencing in Nicotiana benthamiana. The silenced plants were then inoculated with green fluorescent protein (GFP) tagged CMV-P1. Virus accumulations in silenced plants were assessed by monitoring GFP fluorescence and enzyme-linked immunosorbent assay (ELISA). Among ten genes, silencing of formate dehydrogenase (FDH) or calreticulin-3 (CRT3) resulted in weak GFP signals of CMV-P1 in the inoculated or upper leaves. These results suggested that FDH and CRT3 are essential for CMV infection in plants. The importance of FDH and CRT3 in CMV-P1 accumulation was also validated by the accumulation level of CMV coat protein confirmed by ELISA. Altogether, these results demonstrate that FDH and CRT3 are required for CMV-P1 infection in plants.

Carotenoids are vital pigments responsible for yellow, orange and red color in plants. In Capsicum, capsanthin-capsorubin synthase (CCS), phytoene synthase (PSY), β-Carotene hydroxylase (CRTZ-2) and lycopene β-cyclase (LCYB) were identified to be involved in the carotenoids synthesis pathway. Previously molecular markers based on the CCS and PSY genes have been developed to distinguish fruit colors in pepper. However these markers can distinguish fruit colors of limited pepper genotypes. Therefore, there is need of developing additional markers for accurate prediction of fruit colors using molecular markers. In this study carotenoids contents of 16 pepper accessions were analyzed and the CCS, PSY, CRTZ-2, LCYB genes were sequenced to identify the genes affecting the fruit color. Among all the analyzed carotenoids, capsanthin was accumulated in much higher amount in red and orange fruits (1100-2500 mAU·min and 30-500 mAU·min respectively) while violaxanthin (20-1200 mAU·min) was accumulated more in yellow fruits. Sequence analysis revealed that deletions and two frame shift mutations in CCS gene for yellow accessions. Frame shift mutations of the PSY gene were detected in two orange accessions. These results show that mutations in CCS and PSY genes affect the fruit colors of pepper, and markers can be developed using mutations of these genes.

Powdery mildew disease caused by Leveillula taurica is a serious fungal threat to greenhouse pepper production. In contrast to most epiphytic powdery mildew species, L. taurica is an endophytic fungus which colonizes in the mesophyll tissues of the leaf. In the genus Capsicum, several studies have been conducted to identify resistance sources to L. taurica. In previous studies, five quantitative trait loci (QTLs) for powdery mildew resistance have been identified. An F2 population derived from self-pollination of the commercial cultivar Capsicum annuum ‘PM Singang’ was used for genetic analysis of powdery mildew resistance. Resistance of the F2 plants was tested under the natural environmental conditions. Sporulation intensity on infected leaves was used as a disease scale to assign resistance levels to plants, where 0-5% is Resistant, 6-15% Moderate resistant and 16-100% Susceptible. A total of 83 F2 plants were evaluated for resistance. The results showed that 59 plants were resistant, 10 susceptible and 14 moderately resistant. If we consider MR as S, segregation ratio fitted to a single dominant resistance gene model. In the future study, closely linked molecular marker will be developed and tested to locate this gene. The developed marker will be used to identify the powdery mildew resistance gene.

Capsinoids, low-pungent compounds, have the same biological effects as capsaicinoids such as anticancer and anti-obesity. A precursor of capsinoids, vanillyl alcohol, is known to be produced by mutations in the putative-aminotransferase (pAMT) gene. In the previous study, ‘SNU11-001’ (Capsicum chinense) containing high levels of capsinoids was identified in germplasm collections of Capsicum. This collection has a unique mutation in the pAMT gene that can cause dysfunction of this gene. In order to develop pepper varieties containing high capsinoids contents, marker-assisted foreground and background selections were performed during backcross breeding. Compared to the conventional backcrossing, marker-assisted backcrossing (MABC) is extremely useful for recovery of a recurrent parent’s genetic background. For foreground selection, plants carrying the pAMT/pamt genotype were selected from a BC1F1 and BC2F1 populations using SCAR markers derived from the unique pAMT mutation of ‘SNU11-001’. To obtain background selection markers, a total of 412 single nucleotide polymorphism (SNP) markers was screened on ‘Shinghong’ parental lines and ‘SNU11-001’ to obtain polymorphic SNP markers. Of the 412 SNP markers, 144 and 204 polymorphic SNP markers evenly distributed in pepper genome were finally selected. BC1F1 and BC2F1 plants carrying the pAMT/pamt genotype were subjected to background selection using the selected marker sets. Multiple genotype analysis was done using a high-throughput genotyping system (EP1TM, Fluidigm®, USA). As a result, one BC1F1 plant 84% similar to the recurrent parent and several BC2F1 plants more than 96% recovery rate of the recurrent parent were selected. Genetic backgrounds of the selected BC2F1 plants were evaluated by the genotype-by-sequencing (GBS) method in order to confirm the background selection results using the SNP marker set. GBS results showed that recovery rate and positions of introgressed segments were well matched between two methods demonstrating MABC can be successfully done with a couple hundred SNP markers.

Root-knot nematode, Meloidogyne incognita is a virulent pest of solanaceaous crops worldwide. The M. incognita resistance gene Me7 derived from Capsicum annuum CM334, is located on chromosome 9. In the present study, an F2 population derived from a cross between ECW03R and CM334 was used to locate the Me7 gene. An F2 population was inoculated using approximately 1,000 second-stage juveniles per individual plant. Phenotype screening was done 45 days after inoculation by using gall index system. The phenotype study of 503 F2 individual showed 391 resistant and 112 susceptible plants. The 3:1 phenotypic ratio confirmed that resistance phenotype is controlled by a single dominant gene. Previously reported two markers were tested to reveal the linkage of markers to phenotype. Two markers, CAPS_F4R4 and SCAR_PM6a were located at 4.3 and 2.7 cM from the resistance gene, respectively. Additional SNP markers were developed using CM334 reference genome information to narrow down the position of the gene, but no closer markers could be developed due to errors of DNA sequence assembly. The closest marker was positioned on telomere of the chromosome 9 long arm, where tens of other NB-LRR genes are clustered. NB-LRR genes are being used as candidates to identify the Me7 gene.

Phytophthora capsici an Oomycete pathogen is a major challenge to the pepper (Capsicum spp.) production around the world. Control measures are proved ineffective, so breeding resistant cultivars are the most promising strategy against the pathogen. Resistance against P. capsici is governed by quantitative trait loci (QTL). According to previous studies on QTL detection, the QTL on pepper chromosome 5 is a major contributor to resistance. In this study, to exploit the involvement of this QTL and identify its contributing genes, the F2 population derived from a cross between ECW30R and CM334 was inoculated with a medium virulence P. capsici strain JHAI1-7 zoospores at the 6-8 leaf stage. Composite interval mapping revealed two major QTLs; QTL5-1 from 7 days post inoculation (dpi) and QTL5-2 from 16 dpi on chromosome 5. To characterize and detect interactions of the two QTLs, near isogenic lines (NIL) were constructed by crossing Tean and recombinant inbred line (RIL) derived from a cross between YCM334 and Tean. RILs were screened with P. capsici strain MY-1 and resistant lines were selected. Among the resistance RILs most closely related to Tean were selected using AFLP and SSR genotyping data. These RILs were named as YT39-2 and YT143-2. To develop more advanced NILs, two rounds of marker-assisted backcrossing were done using a high-throughput SNP genotyping system (EPI Fluidigm, USA). Among the NILs derived from YT39-2, YT39-2-64 contains only QTL5-1 whereas YT39-2-61 and YT39-2-69 were identified to have both QTLs. On the other hand, YT143-2-55-7 with the highest Tean genetic background contains QTL5-1 only. In the next step, the 3 different NILs having QTL5-1, QTL5-2 individually and both QTLs will be identified. Furthermore, phenotyping and fine mapping will be done for the analysis of individual and interaction effects of QTLs.

sy-2 (Seychelles-2) is a temperature sensitive natural mutant of Capsicum chinense and native to Seychelles Island in Africa. Previously we showed that sy-2 leaves were irregularly shaped and defective in chlorophyll development at temperatures below 24℃. A segregation test revealed that the sy-2 gene is controlled by a single recessive gene. To identify the sy-2 gene, we performed a map-based cloning approach using a total 600 individual F2 plants derived from crossing sy-2 and the wild type C. chinense ‘No.3341’. Fine-mapping of the locus allowed us to position sy-2 to an approximately 170-kb region flanked by markers IN2-1-1 and SNP-3-7 on chromosome 1. Among the approximately 36 hypothetical genes in this region several candidate genes including: HSP90-like ATPase family proteins, lipid-transfer proteins, calmodulin-domain protein kinases, and zinc finger proteins (ZFPs) were identified. RT-PCR and sequencing of the hypothetical genes are under way to identify sy-2.

The last decade has witnessed tremendous progress in genome sequencing and explosion of genome sequence information. This remarkable advancement in genomics provides unprecedented opportunities for crop improvement. Pepper (Capsicum spp.) is an important vegetable crop worldwide. Pepper production is constantly challenged by various pathogens and developing cultivars harnessing multiple disease resistance genes are ever increasing. Molecular markers linked to disease resistance genes will expedite the gene pyramiding. Here, I introduce genome-assisted development of molecular markers linked to resistance genes, in pepper. Phytophthora capsici L. is one of the most destructive pathogens of pepper (Capsicum spp.). Resistance of Capsicum annuum against P. capsici is controlled by quantitative trait loci (QTL), including a major QTL on chromosome 5 that is the predominant contributor to resistance. Here, to maximize the effect of this QTL and study its underlying genes, an F2 population and recombinant inbred lines were inoculated with P. capsici strain JHAI1-7 zoospores at a low concentration (3 x 103 /mL). Resistance phenotype segregation ratios for the populations were close to 3:1 and 1:1 (resistant:susceptible), respectively, consistent with a single dominant gene model. Bulked segregant analysis (BSA) using Affymetrix GeneChips revealed a single position polymorphism (SPP) marker mapping to the major QTL. When this SPP marker (Phyto5SAR) together with other SNP markers located on chromosome 5 were used to confirm the position of the major QTL, Phyto5SAR showed the highest LOD value at the QTL. A scaffold sequence (scaffold194) containing Phyto5SAR was identified from the C. annuum genome database. The scaffold contained two putative NBS-LRR genes and one SAR 8.2A gene as candidates for contributing to Phytophthora resistance. Markers linked to these genes were developed and validated by testing 100 F1 commercial cultivars. Among the markers, Phyto5NBS1 showed about 90% accuracy in predicting resistance phenotypes to a low-virulence Phytophthora isolate. These results suggest that Phyto5NBS1 is a reliable marker for Phytophthora resistance and can be used for identification of a gene(s) underlying the major QTL on chromosome 5

Genotyping-by-sequencing (GBS) is a robust and rapid tool to develop SNP markers. Reduced sequencing complexity and multiplex sequencing of GBS has reduced genotyping cost for complex genome. However multiplex sequencing brings low sequencing depth which can lead to reduced number of markers. Therefore to find the appropriate condition for GBS is needed. In this research we demonstrated the use of ApeKI and selective primers for GBS of pepper (Capsicum spp.). Selective primers which amplify the GBS library with one or two flanking sequences to ApeKI site were used to increase sequencing depth. By in silico digestion, we developed six different selective primers amplify 4,000-400,000 regions. We made the GBS library with eight pepper accessions in four species using six selective primers and sequenced. Proper selective primers and pooling rate for each species will be determined. This approach will be useful for genotyping Capsicum breeding lines or populations by developing high quality SNP markers.

Capsicum diversity is getting lower in modern crops because of the genetic erosion. In Capsicum, breeders have been mainly focused on agriculturally important traits such as disease resistances, high yield and pungency. This narrow breeding pool hampered to develop improved cultivars. It has become a hot issue to conservation of genetic diversity and exploitation of wild germplasm in Capsicum. However, although a large number of accessions are maintained in Capsicum germplasm collections, their use for crop improvement is limited by the scarcity of information on genetic diversity, population structure and proper phenotypic assessment. The identification of representative and manageable subset of accessions would facilitate access to the diversity available in large collections. A genome wide germplasm characterization using molecular markers can offer reliable tools for adjusting the quality and representativeness of core samples. We investigated patterns of molecular diversity at 48 single nucleotide polymorphisms (SNPs) in 4056 accessions from 11 Capsicum species from 89 different countries. Using these genetic variations and 32 different morphological traits, 250 core set was selected in whole Capsicum germplasm. The core collection could be a primary source for distributing germplasm to pepper breeders and other national programs as well as for evaluation

Capsinoids, low-pungent compounds, have the same biological effects as capsaicinoids such as anticancer and anti-obesity. A precursor of capsinoids, vanillyl alcohol, is known to be produced by mutations in the p-aminotransferase (p-AMT) gene. In the previous study, SNU11-001 (C. chinense) containing high levels of capsinoids was found in germplasm collections of Seoul National University. We found that this collection has a unique mutation in the p-AMT gene. In order to develop a cultivar containing high capsinoids contents, marker-assisted foreground and background selection were performed in this study. Backcrossing is an effective breeding method for introducing useful traits to an elite cultivar. Compared to conventional backcrossing, marker-assisted backcrossing (MABC) is extremely useful for recovery of a recurrent parent’s genetic background. To obtain background selection markers, a total of 412 single nucleotide polymorphism (SNP) markers was screened to obtain polymorphic SNP markers between ‘Takanotsume (C. annuum)’ and ‘SNU11-001’. Of the 412 SNP markers, 96 polymorphic SNP markers evenly distributed in pepper genome were finally selected. Plants carrying the pAmt/pamt genotype were selected from a BC1F1 population using SCAR markers derived from the unique p-AMT mutation of SNU11-001. BC1F1 plants carrying the pAmt/pamt genotype were subjected to background selection. Multiple genotype analysis was done using Fluidigm platform (BioMark). Once we obtain plants carrying most similar genetic background to recurrent parent, capsinoids contents will be measured and another round of MABC be done to obtain plants containing high levels of capsinoids.

In plants, eukaryotic translation elongation factor 1B (eEF1B) is composed of three subunits, eEF1Bα, eEF1Bβ and eEF1B γ. Two subunits are nucleotide exchange subunits (eEF1Bα and eEF1Bβ) and one is a structural protein (eEF1Bγ). In the previous study, eEF1B was identified as a common host factor for several RNA viruses. To test which subunit of eEF1B is essential for Potato virus X (PVX) replication, the virus-induced gene silencing (VIGS) for eEF1Bα, β or γ was performed in Nicotiana benthamiana and green fluorescent protein (GFP)-tagged PVX was inoculated. PVX-GFP accumulation was decreased when eEF1Bβ or γ subunit was silenced, whereas eEF1Bα had no effect on PVX-GFP accumulation in inoculated leaves. Targeting induced local lesions in genome (TILLING) was performed using a Capsicum annuum EMS population to test whether mutations in eEF1Bβ subunit affect virus infection in pepper. We obtained 81 eEF1Bβ mutant lines consisted of 16,759 individuals. These mutant lines are being tested to validate the function of eEF1B β in PVX replication.

Next-generation sequencing (NGS) technology and fast improvement in plant genetics have elevated to massive development of molecular genetic markers through fast analysis of huge molecular biological data. Furthermore, in domestic commercial breeding of horticultural crops, the application of marker assisted breeding (MAB) has been introduced recently. For effective improvement of cultivar breeding, in this research, transcriptome analysis and single nucleotide polymorphism (SNP) comparison with high density pepper map in UC-DAVIS were performed using four lines of Capsicum annuum and C. chinense. For rapid analysis of MAB of tolerant pepper lines, 412 Fluidigm probes were newly designed in this study. These designed probes and SSR and COSII markers were applied for background selection through the MAB program. In addition, powdery mildew (PM), tomato spot wilt virus (TSWV) resistance related markers were subjected to foreground selection of BC1, BC2, and BC3 progenies. The MAB system using Fluidigm probes, and trait-related and common markers was introduced into domestic pepper breeding, which will rapidly approach to a new elite line and a commercial tolerant cultivar.

sy-2 (Seychelles-2) is a temperature sensitive mutant of Capsicum chinense and native to Seychelles Island in Africa. Previously we showed that sy-2 leaves were irregularly shaped and defective in chlorophyll development at temperatures lower than 24℃. A segregation test revealed that the sy-2 gene is controlled by a single recessive gene. To identify the sy-2 gene, we performed a map-based cloning approach using a total of 1,010 F2 plants derived from crossing sy-2 and the wild type C. chinense ‘No.3341’. sy-2 gene is located on chromosome 1, 0.3 cM and 0.1cM away from cosII markers C2_At4g29120 and C2_At1g09070, respectively. The tomato genome sequence between those two markers was compared with pepper genome sequence. We found three of pepper scaffold sequences in this region. We developed seven ingle nucleotide polymorphism (SNP) markers on the pepper scaffold sequences, among which five SNP markers were co-segregated with sy-2. To fill the gap between the scaffolds which contains co-segregating markers, we screened a bacterial artificial chromosome (BAC) library, and end-sequences of total of 22 AC clones were i. We found that five clones were overlapped to cover the gap. We fully sequenced four AC clones and found that the physical distance between C2_At4g29120 and C2_At1g09070 is 343kb. This region contains 70 putative genes such as HSP90-like ATPase family proteins, lipid-transfer proteins, calmodulin-domain protein kinases, and zinc finger proteins (ZFPs). To identify the sy-2 gene, we performed RT-PCR and found that a ZFP-like gene is differentially expressed between WT and sy-2 leaves. This result suggests that the ZFP-like gene is a strong candidate for the sy-2 gene. We are currently characterizing this candidate gene.

Tomato yellow leaf curl disease is a devastating disease of tomato (Solanum lycopersicum), which is caused by begomoviruses generally referred to as tomato yellow leaf curl virus (TYLCV). The breeding for TYLCV resistance has been based on the introgression of the Ty-3 resistance locus. Knowledge about the exact location of the Ty-3 on tomato chromosome 6 is needed to understand the genomic organization of the Ty-3 locus. In this study, we conducted a genetic analysis using a segregating population derived from a cross between resistant accession S. lycopersicum “A45” and susceptible accession S. lycopersicum “A39”. The F1 plants showed resistance to TYLCV and F1 was self-pollinated to produce F2 progeny. To screen the TYLCV resistance in 145 F2 plants, a leaf agroinfiltration method was used. F2 plants showed a classical Mendelian seregation (106 resistance : 39 susceptibility) for resistance to TYLCV respectively. SCAR and CAPS markers linked to the Ty-3 were tested for genotyping F2 plants and .genotyping and agroinfiltration results were cosegregated in the newly developed F2 population.

Capsinoids, low-pungent compounds, have the same biological effects as capsaicinoids such as anticancer and anti-obesity. A precursor of capsinoids, vanillyl alcohol, is known to be produced by mutations in the p-aminotransferase (p-AMT) gene. In the previous study, SNU11-001 (C. chinense) containing high levels of capsinoids was found in germplasm collections of Seoul National University. We found that this collection has a unique mutation in the p-AMT gene. In order to develop a cultivar containing high capsinoids contents, marker-assisted foreground and background selection were performed in this study. Backcrossing is an effective breeding method for introducing useful traits to an elite cultivar. Compared to conventional backcrossing, marker-assisted backcrossing (MABC) is extremely useful for recovery of a recurrent parent’s genetic background. To obtain background selection markers, a total of 412 single nucleotide polymorphism (SNP) markers was screened to obtain polymorphic SNP markers between ‘Takanotsume (C. annuum)’ and ‘SNU11-001’. Of the 412 SNP markers, 96 polymorphic SNP markers evenly distributed in pepper genome were finally selected. Plants carrying the pAmt/pamt genotype were selected from a BC1F1 population using SCAR markers derived from the unique p-AMT mutation of SNU11-001. BC1F1 plants carrying the pAmt/pamt genotype were subjected to background selection. Multiple genotype analysis was done using Fluidigm platform (BioMark). Once we obtain plants carrying most similar genetic background to recurrent parent, capsinoids contents will be measured and another round of MABC be done to obtain plants containing high levels of capsinoids

Pepper mottle virus (PepMoV) is frequently occurring virus in pepper field. PepMoV infected plants show symptoms including mosaic leaf, distortion of foliage and fruit deformation. The dominant gene Pvr7 from Capsicum annuum ‘9093’ confers resistance to PepMoV. Previous research reveals that Pvr7 is located in 10 chromosome and linked to the dominant potyvirus resistance gene Pvr4 and Tomato spotted wilt virus (TSWV) resistance gene Tsw. To identify the Pvr7 gene, we constructed an intraspecific F2 mapping population from a cross between C. annuum ‘9093’ (PepMov resistant) and C. annuum ‘Jejujaerae’ (PepMoV susceptible). Resistance of F2 plants were screened with green flouorescent protein (GFP) tagged PepMoV. Genomic DNA was extracted from F2 individuals and markers were developed using C.annuum ‘CM334’ whole genome sequence (WGS). Several single nucleotide polymorphism (SNP) markers that were co-segregated with Pvr7 were developed. We are expecting that this Pvr7 SNP marker can be used to breeding PepMoV resistant cultivars and fine mapping of Pvr7.