Hee-Bum Yang

Molecular mapping and characterization of a single dominant gene controlling CMV resistance in peppers (Capsicum annuum L.)

Cucumber mosaic virus (CMV) is one of the most destructive viruses in the Solanaceae family. Simple inheritance of CMV resistance in peppers has not previously been documented; all previous studies have reported that resistance to this virus is mediated by several partially dominant and recessive genes. In this study, we showed that the Capsicum annuum cultivar ‘Bukang’ contains a single dominant resistance gene against CMVKorean and CMVFNY strains. We named this resistance gene Cmr1 (Cucumber mosaic resistance 1). Analysis of the cellular localization of CMV using a CMV green fluorescent protein construct showed that in ‘Bukang,’ systemic movement of the virus from the epidermal cell layer to mesophyll cells is inhibited. Genetic mapping and FISH analysis revealed that the Cmr1 gene is located at the centromeric region of LG2, a position syntenic to the ToMV resistance locus (Tm-1) in tomatoes. Three SNP markers were developed by comparative genetic mapping: one intron-based marker using a pepper homolog of Tm-1, and two SNP markers using tomato and pepper BAC sequences mapped near Cmr1. We expect that the SNP markers developed in this study will be useful for developing CMV-resistant cultivars and for fine mapping the Cmr1 gene.

Transgenic Brassica rapa plants over-expressing eIF(iso)4E variants show broad-spectrum Turnip mosaic virus (TuMV) resistance.

The protein-protein interaction between VPg (viral protein genome-linked) of potyviruses and eIF4E (eukaryotic initiation factor 4E) or eIF(iso)4E of their host plants is a critical step in determining viral virulence. In this study, we evaluated the approach of engineering broad-spectrum resistance in Chinese cabbage (Brassica rapa) to Turnip mosaic virus (TuMV), which is one of the most important potyviruses, by a systematic knowledge-based approach to interrupt the interaction between TuMV VPg and B. rapa eIF(iso)4E. The seven amino acids in the cap-binding pocket of eIF(iso)4E were selected on the basis of other previous results and comparison of protein models of cap-binding pockets, and mutated. Yeast two-hybrid assay and co-immunoprecipitation analysis demonstrated that W95L, K150L and W95L/K150E amino acid mutations of B. rapa eIF(iso)4E interrupted its interaction with TuMV VPg. All eIF(iso)4E mutants were able to complement an eIF4E-knockout yeast strain, indicating that the mutated eIF(iso)4E proteins retained their function as a translational initiation factor. To determine whether these mutations could confer resistance, eIF(iso)4E W95L, W95L/K150E and eIF(iso)4E wild-type were over-expressed in a susceptible Chinese cabbage cultivar. Evaluation of the TuMV resistance of T1 and T2 transformants demonstrated that the over-expression of the eIF(iso)4E mutant forms can confer resistance to multiple TuMV strains. These data demonstrate the utility of knowledge-based approaches for the engineering of broad-spectrum resistance in Chinese cabbage.

An ultra-high-density bin map facilitates high-throughput QTL mapping of horticultural traits in pepper (Capsicum annuum)

Most agricultural traits are controlled by quantitative trait loci (QTLs); however, there are few studies on QTL mapping of horticultural traits in pepper (Capsicum spp.) due to the lack of high-density molecular maps and the sequence information. In this study, an ultra-high-density map and 120 recombinant inbred lines (RILs) derived from a cross between C. annuum ‘Perennial’ and C. annuum ‘Dempsey’ were used for QTL mapping of horticultural traits. Parental lines and RILs were resequenced at 18× and 1× coverage, respectively. Using a sliding window approach, an ultra-high-density bin map containing 2,578 bins was constructed. The total map length of the map was 1,372 cM, and the average interval between bins was 0.53 cM. A total of 86 significant QTLs controlling 17 horticultural traits were detected. Among these, 32 QTLs controlling 13 traits were major QTLs. Our research shows that the construction of bin maps using low-coverage sequence is a powerful method for QTL mapping, and that the short intervals between bins are helpful for fine-mapping of QTLs. Furthermore, bin maps can be used to improve the quality of reference genomes by elucidating the genetic order of unordered regions and anchoring unassigned scaffolds to linkage groups.

Identification of a broad-spectrum recessive gene in Brassica rapa and molecular analysis of the eIF4E gene family to develop molecular markers

Two Chinese cabbage (Brassica rapa L. ssp. pekinensis) lines resistant to Turnip mosaic virus (TuMV) CHN5 were identified and found to have broad-spectrum resistance against three other TuMV strains (CHN2, 3, and 4). Genetic analysis indicated that this TuMV resistance is recessive, and a candidate gene approach was used to identify the resistance gene, which we named trs (TuMV resistance discovered at Seoul National University). Based on previous research in Arabidopsis showing that mutations in eIF(iso)4E determine TuMV resistance, the eIF(iso)4E gene was selected as a candidate for the trs gene in Brassica rapa. Three copies of eIF(iso)4E, Braiso4Ea, Braiso4Eb, and Braiso4Ec, were amplified, and polymorphisms between resistant and susceptible lines were analyzed. Sequence polymorphisms were found in Braiso4Ea and Braiso4Eb; in contrast, no sequence differences were found in Braiso4Ec between resistant and susceptible lines. A CAPS marker developed to test the linkage between Braiso4Eb and TuMV resistance displayed no linkage. A SCAR marker, trsSCAR, developed using allele-specific deletions and SNPs in Braiso4Ea, did co-segregate perfectly with trs in three F2 populations. However, the presence or absence of the Braiso4Ea sequence deletion was not consistent between resistant lines and susceptible lines, indicating that Braiso4Ea is not the actual resistance gene. Results from mapping analysis indicated that the trs is located at chromosome A04, between scaffold 000104 and scaffold 040552. This location demonstrated that trs may be another recessive resistance gene tightly linked to retr02 or another allele. The molecular markers developed in this study will be useful for breeding durable resistance.

Development of a high-throughput SNP marker set by transcriptome sequencing to accelerate genetic background selection in Brassica rapa

Among the molecular markers used today, single nucleotide polymorphisms (SNP) are the most common type used in genetic diversity analysis due to their abundance. To develop a high-throughput SNP marker set to accelerate genetic background selection in Brassica rapa breeding, we sequenced the transcriptomes of 20 Chinese cabbage accessions representing diversity in traits such as head type, maturity, inner leaf color, and disease resistance. We identified 13,976 SSRs and 380,198 SNPs by aligning their contigs. We chose 189 SNPs that covered the entire B. rapa genome through a filtering process based on criteria such as depth, level of polymorphism, segregation ratio, lack of adjacent SNPs, copy number, and PIC value. To validate the SNP marker set, we genotyped 23 Chinese cabbage accessions and constructed a phylogenetic tree. The results showed that the SNP genotyping data could distinguish the Chinese cabbage accessions according to their phenotypic variations. The 23 accessions were classified into two groups that were characterized by phenotypic traits, especially head type and maturity. In conclusion, the selected SNP marker set is a reliable breeding tool for distribution analysis or selection of different Chinese cabbage accessions and may be applicable for rapid genetic background selection of Chinese cabbages for breeding.

Methods for Developing Molecular Markers

Molecular markers are essential for breeding major crops today and many molecular marker techniques have been developed. DNA markers are now the most commonly used. This chapter describes the principles of DNA marker techniques and methods to map major genes. DNA markers can be classified into two categories: (1) DNA hybridization-based techniques, including restriction fragment polymorphism and DNA chips, and (2) polymerase chain reaction techniques, including simple sequence repeats, random amplified polymorphic DNA, amplified fragment length polymorphism, and single nucleotide polymorphism. To develop trait-linked markers, segregating populations for the target traits and reliable phenotyping methods are indispensable. With these tools, two approaches can be used to develop trait-linked markers: (1) when there is no biological information for the trait, and (2) when biological information is available. Finally, we describe several case studies for trait-linked marker development.

Rapid and practical molecular marker development for rind traits in watermelon

A three-locus model for rind phenotypes in watermelon (Citrullus lanatus) was previously proposed based on genetic analysis. These three loci, S (foreground stripe pattern), D (depth of rind color), and Dgo (background rind color), segregate in a Mendelian manner. Whole genome sequencing of watermelon offers a new strategy for marker development in these rind phenotype-related loci. A genotype analysis using subsets of 188, 273, 287 and 113 probes was performed for the ‘0901’, ‘10909’, ‘109905’ and ‘90509’ rind trait-segregating F2 populations, respectively. A total of 26, 34, 30 and 15 linkage groups with 175, 254, 269 and 79 probes were constructed for the ‘0901’, ‘10909’, ‘109905’ and ‘90509’ populations, respectively. The genetic order of the probes was mostly collinear with the physical order on the reference genome, except for some probes on chromosomes 1, 3 and 11. The three rind-related loci, S, D, and Dgo were anchored near chr6_25767 on chromosome 6, chr8_26061 on chromosome 8 and chr4_150/chr4_249 on chromosome 4, respectively. The three loci are located on different chromosomes, and the three-locus model was therefore verified through molecular genetic analysis. We suggest a rapid and practical marker development strategy that can be used not only for rind traits but also for other agriculturally important traits in watermelon and applied for conventional breeding.