Background: Panax ginseng C. A. Meyer is wood-cultivated ginseng (WCG) in Korea which depends on an artificial forest growth method. To produce this type of ginseng, various P. ginseng cultivars can be used. To obtain a WCG similar to wild ginseng (WG), this method is usually performed in a mountain using seeds or seedlings of cultivated ginseng (CG) and WG. Recently, the WCG industry is suffering a problem in that Panax notoginseng (Burk.) F. H. Chen or Panax quinquefolium L. are being sold as WCG Korean market; These morphological similarities have created confusion among customers. Methods and Results: WCG samples were collected from five areas in Korea. After polymerase chain reaction (PCR) amplification using the primer pair labeled with fluorescence dye (FAM, NED, PET, or VIC), fragment analysis were performed. PCR products were separated by capillary electrophoresis with an ABI 3730 DNA analyzer. From the results, WCG cultivated in Korea showed very diverse genetic background. Conclusions: In this study, we tried to develop a method to discriminate between WCG, P. notoginseng or P. quinquefolium using simple sequence repeat (SSR) markers. Furthermore, we analyzed the genetic diversity of WCG collected from five cultivation areas in Korea.

Background: In the herbal medicinal industry, Angelica gigas Nakai, Angelica sinensis (Oliv.) Diels. and Angelica acutiloba (Siebold & Zucc.) Kitag. are often confused, because the roots of the three species can not be distinguished by their appearance. This confusion can cause serious side effects. In this study, we determined the origins of Angelica roots distributed in the Korean market using the simple sequence repeat (SSR) markers developed based on the A. gigas chloroplast DNA sequence. Methods and Results: We collected twenty seven A. gigas and three A. acutiloba samples from the Seoul, Daegu, and Cheongju herbal medicinal markets. Fifty sections of one collection were mixed and ground to make a powder, which was used for DNA extraction using the cetyl trimethylammonium bromide (CTAB) method. Chloroplast based SSR markers were applied to the DNA for the determination of the species. In addition, polymorphism was found in eight samples. The phylogenetic analysis showed that the A. gigas roots collected from herbal medicinal markets were clearly discriminated from A. sinensis and A. acutiloba even though they were grouped into four clusters. Conclusions: This study showed that chloroplast based SSR markers would help the discrimination of Angelica roots in the Korean herbal medicinal industry and the markers are useful to prevent confusion between Angelica roots.

We collected 32 maize inbred lines from eastern cereal and oilseed research center in Canada to develop new maize varieties. We also evaluated genetic diversity, genetic relationships, and population structure using 35 SSR markers. A total of 269 alleles were revealed in 35 loci with an average of 7.69 and a range between 3 and 15 alleles per locus. The genetic diversity values varied from 0.176 to 0.889 with an average of 0.691. The polymorphic information content varied from 0.171 to 0.879 with an average of 0.659. Population structure analysis indicated that 32 Canadian maize inbred lines comprised four major groups and one admixed group based on a membership probability threshold of 0.80. The four major groups contained 13, 2, 5 and 2 maize inbred lines, respectively. From genetic relationships analysis, the all inbred lines were divided into three main groups at 26% genetic similarity. Group I included 22 inbred lines, and Group II included 9 inbred lines. Group III consist of only one inbred line. The results in this study would be useful for the improvement and development of new cultivars, planning crosses for hybrids or development of inbred line in maize breeding program

Background : Panax ginseng C.A. Meyer is a perennial herb belongs to the family Araliaceae. Wild-cultivated ginseng (WCG) is a specific type of ginseng in Korea which cultivated on artificial forest cultivation method. To obtain a WCG which is similar to wild ginseng (WG), this method usually performed in a mountain using seeds or seedlings of cultivated ginseng (CG) and WG. WCG is very expensive because it is difficult to cultivate. However, systematic cultivation method have not yet been developed compared to high added value. Furthermore, very high price of WCG caused the problem that Panax notoginseng or Panax quinquefolium are sold as WCG in Korean market. In this study, we analyzed the genetic diversity of WCG collected from five areas in Korea using SSR markers. Methods and Results : WCG samples were collected from five areas in Korea (Bucheon, Cheongju, Hoengseong, Judeok and Ulsan). DNA extraction was performed using CTAB method. SSR markers were collected from the published papers. After test PCR using the markers, one of the primer pair was labeled with fluorescence dye (FAM, NED, PET, or VIC) and GeneScan analysis were performed. DNA amplification was conducted using T-100 Thermal Cycler (Bio-Rad). PCR products were separated by capillary electrophoresis on the ABI 3730 DNA analyzer (Applied Biosystems). Conclusion : Eight SSR markers were collected from the published literature and used for the analysis. From the 8 tested SSR markers, 7 SSR markers showed polymorphism between varieties. GenScan analysis were performed using the selected SSR markers to analyze the phylogenetic relationship of WCG. From the results, WCG cultivated in Korea showed that they have a very diverse genetic background.

Background : Codonopsis lanceolata is a flowering perennial climber. The roots are used as medicinal materials or vegetables. C. lanceolata is distributed in India and East Asia such as China, Japan as well as Korea. Recently, demand for C. lanceolata is increasing as a healthy food. In South Korea, this plant is widely cultivated in Gangwon-do province. Although, C. lanceolata is one of the most important medicinal plants in Korea, it is easy to be confused with other species of the same genus. Simple sequence repeat (SSR) marker is a powerful tool for distinguish specific species. In addition, there are many studies that show species-specific polymorphisms in chloroplasts SSR. In this study, we developed chloroplast SSR markers that can distinguish C. lanceolata from 6 Codonopsis species. Methods and Results : We collected 6 Codonopsis species include C. lanceolata. and extrated DNA using CTAB method. The DNA was diluted to 10 ng/㎕ and kept at –20℃. We designed the primer sets using CLC Main Workbench based on chloroplast DNA SSR region of C. lanceolata. PCR was performed using three independent plants for each species. Conclusion : We designed six primer sets from six SSR regions of C. lanceolata cpDNA. All of the primer sets amplified the amplicon effectively. Two of the 6 primer sets had polymorphism. We could distinguish C. lanceolata from 6 Codonopsis species using two primer sets.

Background : Codonopsis lanceolata is a perennial plant of Campanulaceae and mainly distributed in East Asia such as Korea, China, and Japan. C. lanceolata has a unique taste and aroma, and it is rich in minerals such as phosphorus and calcium, and vitamin B1 and B2, so our ancestors used the plant as medicinal herb and edible vegetable. However, systematic cultivation and development of varieties have not been achieved compared to demand or high added value. The genetic diversity and relationship analysis of the plants help to increase the efficiency of breeding through genetic variation. Methods and Results : Ten species of Codonopsis plants were used as materials and DNA was extracted from each 4 individuals per species and quantified at a concentration of 10 ng /㎕. The extracted DNA was pooled by species and PCR was performed using the EST-SSR marker developed based on C. lanceolata in the previous study. PCR amplification was carried out using a denaturation at 94℃ for 30 sec, annealing at 58℃ for 30 sec and extension at 72℃ for 30 sec, repeated for 35 total cycles. The PCR products were separated in a 4% agarose gell at 100 V for 40 min. Conclusion : In this study, C. lanceolata collections was determined among several Codonopsis species using these molecular marker. It is expected that the data of this study can be used as reference for genetic polymorphism analysis and related gene studies of Codonopsis species.

Background : Codonopsis lanceolata is a perennial plant of Campanulaceae with characteristic flavor and aroma and this plant has saponin, flavonoid, and inulin, which are reported to have physiological activity and antioxidant activity. In contrast, breeding or study of C. lanceolata varieties had not been done for a long time. Genetic polymorphism and phylogenetic relationship analysis of the plants by region of the crops can help the collection of genetic backgroud data for variety development. Methods and Results : In this study, we collected 26 C. lanceolata lines (95 individual plants) from 26 regions in Korea. We genotyped the collected lines using SSR markers developed in the previous study and analyzed the population structure based on the results. Population structures were analyzed using model-based STRUCTURE software (version 2.3.4) using the following parameters: Number of clusters (K) set = 1 to 12; Number of Iterations = 5; Length of Burning Period = 100,000; Number of MCMC (Markov Chain Monte Carlo) Reps after Burnin = 100,000. As a result, Of the 26 collections, were genetically grouped into 6 or 7 groups. Conclusion : The 26 C. lanceolata collections (95 individual plants) were genetically grouped but not grouped by collected regions. These results suggest that C. lanceolata has diverse genetic backgrounds and this data could be used as a basis for genetic polymorphism analysis of Codonopsis species.

Background : Adenophora triphylla var. japonica (Regel) H. Hara shows vegetative growth by radical leaf until 1 year after sowing and shows reproductive growth during the second year and there is a characteristic of bolting by turning into cauline leaf. In addition, the phenotypes of plants varies even though they are belonging to the same species. For this reason, there is a limit for the classification of the species by the method of visual examination. Methods and Results : Simple sequence repeat (SSR) markers were developed based on the genomic sequence of A. triphylla using next generation sequencing to prepare the basis of molecular breeding and analyze the genetic diversity. Ninety-five primer sets including tri-, tetra- and penta-nucleotide motif types were randomly selected and they were applied to mixed genomic DNA and finally 39 primer sets showing from two to four bands were selected and used for genetic relationship analysis. Conclusions : Using the next generation sequencing, 39 polymorphic SSR markers were developed.

Background : In the herbal medicine market, Angelica gigas, Angelica sinensis, and Angelica acutiloba are all called "Danggui" and used confusingly. We aimed to assess the genetic diversity and relationships among 14 Angelica species collected from different global seed companies. Toward this aim we developed DNA markers to differentiate the Angelica species. Methods and Results : A total of 14 Angelica species, A. gigas, A. acutiloba, A. sinensis, A. pachycarpa, A. hendersonii, A. arguta, A. keiskei, A. atropurpurea, A. dahurica, A. genuflexa, A. tenuissima, A. archangelica, A. taiwaniana, and A. hispanica were collected. The genetic diversity of all 14 species was analyzed by using five chloroplast DNA-based simple sequence repeat (SSR) markers and employing the DNA fragment analysis method. Each primer amplified 3 - 12 bands, with an average of 6.6 bands. Based on the genetic diversity analysis, these species were classified into specific species groups. The cluster dendrogram showed that the similarity coefficients ranged from 0.77 to 1.00. Conclusions : These findings could be used for further research on cultivar development by using molecular breeding techniques and for conservation of the genetic diversity of Angelica species. The analysis of polymorphic SSRs could provide an important experimental tool for examining a range of issues in plant genetics.

Background: In the herbal medicine market, Angelica gigas, Angelica sinensis, and Angelica acutiloba are all called "Danggui" and used confusingly. We aimed to assess the genetic diversity and relationships among 14 Angelica species collected from different global seed companies. Toward this aim we developed DNA markers to differentiate the Angelica species. Methods and Results: A total of 14 Angelica species, A. gigas, A. acutiloba, A. sinensis, A. pachycarpa, A. hendersonii, A. arguta, A. keiskei, A. atropurpurea, A. dahurica, A. genuflexa, A. tenuissima, A. archangelica, A. taiwaniana, and A. hispanica were collected. The genetic diversity of all 14 species was analyzed by using five chloroplast DNA-based simple sequence repeat (SSR) markers and employing the DNA fragment analysis method. Each primer amplified 3 - 12 bands, with an average of 6.6 bands. Based on the genetic diversity analysis, these species were classified into specific species groups. The cluster dendrogram showed that the similarity coefficients ranged from 0.77 to 1.00. Conclusions: These findings could be used for further research on cultivar development by using molecular breeding techniques and for conservation of the genetic diversity of Angelica species. The analysis of polymorphic SSRs could provide an important experimental tool for examining a range of issues in plant genetics.

Understanding the genetic variation among landrace collections is important for crop improvement and utilization of valuable genetic resources. The present study was carried out to analyse the genetic diversity and associated population structure of 621 foxtail millet accessions of Korean landraces using 22 EST-SSR markers. A total of 121 alleles were detected from all accessions with an average of 5.5 alleles per microsatellite locus. The average values of gene diversity, polymorphism information content, and expected heterozygosity were 0.518, 0.594, and 0.034, respectively. Following the unweighted neighbor-joining method with arithmetic mean based clustering using binary data of polymorphic markers, the genotypes were grouped into 3 clusters, and population structure analysis also separated into 3 populations. Principal coordinate analysis (PCoA) explained a variation of 13.88% and 10.99% by first and second coordinates, respectively. However, in PCoA analysis, clear population-level clusters could not be found. This pattern of distribution might be the result of gene flow via germplasm exchanges in nearby regions. The results indicate that these Korean landraces of foxtail millet exhibit a moderate level of diversity. This study demonstrated that molecular marker strategies could contribute to a better understanding of the genetic structure in foxtail millet germplasm, and provides potentially useful information for developing conservation and breeding strategies.

Background : Wild-cultivated P. ginseng (WCG) is a specific ginseng in Korea which depends on artificial forest growth method. To obtain a WCG which is similar to wild ginseng (WG), this method usually performed in a mountain using seeds or seedlings of cultivated ginseng (CG) and WG. Recently, very high price of WCG caused the problem that Panax notoginseng or Panax quinquefolium are sold as WCG in Korean market. This is concerned as a serious problem to consumers. In this study, we tried to develop a method to discriminate WCG, CG or WG using simple sequence repeat (SSR) markers and phylogenetic analysis. Methods and Results : WCG samples (3, 5, or 6-years old) were collected in Hoengseong, Gangwondo. DNA extraction was performed using CTAB method. SSR markers were collected from the published papers. After test PCR using the markers, one of the primer pair was labeled with fluorescence dye (FAM, NED, PET, or VIC) and Gene Scan analysis were performed. NTsys-PC program was used for the phylogenetic analysis of the data. Eight SSR markers were collected from the published literature and used for the analysis. From the 8 tested SSR markers, 7 SSR markers showed polymorphism between varieties. GenScan analysis were performed using the selected SSR markers to analyze the phylogenetic relationship of WCG. Conclusion : Phylogenetic analysis showed the relationship between WCG and P. ginseng cultivars and the seven SSR markers used in this study are able to distinguish Wild-cultivated P. ginseng.

Background : Codonopsis is a flowering plants belong to the family Campanulaceae, and has many kinds of medicinal properties. As currently recognized, two other groups, Campanumoea and Leptocodon, are included in the Codonopsis. The enlarged genus Codonopsis is distributed in Eastern, Southern, Central, and Southeastern Asia. C. lanceolata, C. clematidea and C. pilosula has many kinds of medicinal properties and this plants are used as medicinal and edible plants. C. ovata and C. mollis are distributed in Pakistan Kashmir and Himalaya mountains at an altitude of about 3,000 m, and flowers bloom in July to August. Methods and Results : In this study, we analyzed the genetic diversity of 5 Codonopsis species using 8 SSR markers base on C. lancelolata genomic sequences. Samples were obtained from fresh leaves of 5 plants from each species and genomic DNA was extracted using CTAB method. PCR was performed in total 20μl reaction volume containing 20 ng of DNA template and 5 pmole of primers. PCR conditions composed pre-denaturation at 95℃ for 5 min, then 35 cycles of 95°C for 30 sec, 60°C for 30 sec and 72°C for 30 sec, and a final extension at 72℃ for 30 min. The amplified band sizes ranged from 74 to 301 bp and clearly showed single or doble bands in eletrophoresis. From the phylogenetic analysis, C. lanceolata was grouped together, but the others were not grouped together according to the species. Conclusion : We concluded that C. lanceolata cultivated in Korea is different from the other species, and the eight SSR markers used in this study are able to distinguish C. lanceolata from the other species.

Background : ‘baek-chul’(White atractylodes rhizome) widely used in traditional herbal remedies in Asia. A. Japonica and A. Macrocephala are used as ‘baek-chul’ in Japanese Pharmacopoeia but only A. Macrocephala is used as ‘baek-chul’ in Chinese Pharmacopoeia. Based on morphologic observation A. japonica has small infloresence diameter, white flowers and gynodioecism, whereas A. macrocephala has large inflorescence diameter, red flowers ,monoecism and developed rhizomes. but The distinction of these isn't easy. SSRs are very useful molecular markers for species identification. In this study, genetic diversity and identification between A. Japonica and A. Macrocephala were confirmed by SSR marker. Methods and Results : DNAs were extracted from leaf tissue of A. Japonica, A. Macrocephala and A. Japonica × A. Macrocephala (Breeding varieties, ‘Dachul’) using DNeasy plant Mini Kit (Qiagen, Hilen, Germany). these plants cultivated from RDA(Eumseong) and used for PCR amplification. The relative concentration of the extracted DNA was estimated Nano Drop ND-1000 (NanoDrop Technologies, Wilmington, De, USA) And final DNA concentration was adjusted to 5.5ng/μL. In this study 8 primer pairs were tested on 4 A. Japonica, 4 A. Macrocephala, 2 ‘Dachul’. These primers showed high polymorphism among and within four populations of A. macrocephala.(Zheng et al.). We detected interspecific and intraspecific SSR polymorphism by 3 primer pairs. Conclusion : The results showed that these markers were found to be useful for diversity analysis as they distinguished among Atractylodes spp. and also A.Macrocephala. This work is intended to serve as the basis for the breeding of new varieties in white atractylodes rhizome.

Background : Astragalus membranaceus is one of the most widely used traditional medicinal herbs in Korea. Studies on the genomic of A. membranaceus resources have not been carried out so far. The present study was carried out to discriminate A. membranaceus based on genetic diversity using genomic simple sequence repeat (SSR) markers. Methods and Results : We collected 5 A. membranaceus lines: Asung, Poongsung, Am-Jecheon, Am-Sancheong, and Am-China. One hundred mg of fresh leaves were used for genomic DNA extraction using the DNeasy plant DNA isolation kit (Qiagen GmbH, Hilden, Germany). 450,449 contigs were searched for 147,766 SSR candidate loci in this study using the MicroSAtellite identification tool (MISA). We selected 949 A. membranaceus genomic SSR markers that were showed variation for the five collections in silico screening with CLC genomics workbench program. The genetic diversity of all A. membranaceus resources was analyzed using 17 SSR markers employing the DNA fragment analysis method. Based on the genetic diversity analysis, these lines were classified into four distinct groups. Conclusion : These findings could be used for further research on cultivar development using molecular breeding techniques and for conservation of the genetic diversity of A. membranaceus. Furthermore, the markers could be used for marker-assisted selection for crop breeding.

Background : Angelica gigas is a monocarpic biennial or short lived perennial plant. A. gigas, also called Dang Gui or Korean Angelica, is a major medicinal herb used in Asian countries such as Korea, Japan and China. In Korea, we are using the roots of A. gigas, but, they are using Angelica sinensis in China and Angelica acutiloba in Japan to obtain many active constituents. The biggest problem in the using of A. gigas would be the confusion with A. acutiloba or A. sinensis. These three plants can't be distinguished by appearance. And the constituent ratios of the three plants are different. This confusion can cause an accident or the pharmaceutical effects do not meet the expectations. In this study, we developed chloroplast SSR markers that can distinguish A. gigas, A. acutiloba and A. sinensis. Methods and Results : We collected A. gigas, A. acutiloba and A. sinensis. and extrated DNA using CTAB method. The DNA was diluted to 10 ng/㎕ and kept -20℃. We designed the primer sets using CLC Main Workbench based on chloroplast DNA SSR region of A. gigas. PCR were performed on the three angelica plant samples (in 5 repeat). Conclusion : We made five primer sets from five SSR regions of A. gigas cpDNA. All of the primer sets amplified the amplicon effectively. Two of the 5 primer sets had polymorphism. We can distinguish A. gigas, A. acutiloba, and A. sinensis using the 2 primer sets

Plant breeding requires the collection of genetically diverse genetic resources. Studies on the characteristics of Platycodon grandiflorum resources have not been carried out so far. The present study was carried out to discriminate P. grandiflorum based on morphological characteristics and genetic diversity using simple sequence repeat (SSR) markers. Methods and Results :We collected 11 P. grandiflorum cultivars: Maries II, Hakone double white, Hakone double blue, Fuji white, Fuji pink, Fuji blue, Astra white, Astra pink, Astra blue, Astra semi-double blue and Jangbaek. Analyses of the morphological characteristics of the collection were conducted for aerial parts (flower, stem and leaf) and underground parts (root). Next, the genetic diversity of all P. grandiflorum resources was analyzed using SSR markers employing the DNA fragment analysis method. We determined that the 11 P. grandiflorum cultivars analyzed could be classified by plant length, leaf number and root characteristic. Based on the genetic diversity analysis, these cultivars were classified into four distinct groups. Conclusions : These findings could be used for further research on cultivar development using molecular breeding techniques and for conservation of the genetic diversity of P. grandiflorum. Moreover, the markers could be used for genetic mapping of the plant and marker-assisted selection for crop breeding.