Tamra' was selected in Jeju in 1997 and its open-pollinated progenies were proliferated at the Korea Forest Research Institute in Suwon, Kyungkido. Stability of genetic characteristics was evaluated from 2001 to 2004. The progenies were annually managed with transplanting and 5 to 6 times in weeding. Leaves, flowers, branches and growth characteristics on selected trees were investigated. Results of morphological characteristics showed that 'Tamra' has simple flower in open type of flower and funnel shape in flower type. It has flower diameter of 100.0 mm that is relatively very large as compared with contrastive cultivar, 'Chilbo'. The petal is slightly folded as compared with contrastive cultivar and its eye zone is not spread. Leaf type is in oval shape, and leaf length and width are short (47.1 mm) and narrow (23.8 mm), respectively. Leaf width to width of leaf shoulder ratio having 1.5 is much wider as compared with contrastive cultivar having 1.4. Thickness of leaf, gloss of leaf and density of branch are all medium. Quantity of bloom is in normal condition and changes in the number of flowers by seasons are small, also, its blossom comes into summer. 'Tamra' having large flowers and red color could be useful for a good ornamental and garden tree.

“Daeshin” (Perilla frutescens (L.) Britton), a new cultivar for leaf vegetable, was developed from a cross between YPL5 (Ipdeulkkae1/YCPL187) and Milyang2 at the National Yeongnam Agricultural Experiment Station (NYAES), RDA, in 2002. For the cultivation of leaf vegetable perilla, seeds are sown in narrow spacing of 10 × 5 cm and all branches are removed to harvest uniform leaves from main stem. Because of the narrow planting distance, it is difficult to distinguish seeds from soil in dark brown seed cultivar. Therefore the gray-white size color of “Daeshin” is very useful characteristic for easier sawing in perilla cultivation. “Daeshin” grow vigorously and yield high quality leaf. The fresh leaf yield of “Daeshin” is 9% higher than that of “Ipdeulkkae 1” (4,823 vs. 4,459 kg/10a). For the leaf production, “Daeshin” is adaptable to whole arable land in South Korea. However, the southern parts of Korea such as South Gyeongsang and South Jeolla provinces are appropriate for the seed production.

Soybean seeds contain high amounts of isoflavones that display biological effects and isoflavone content of soybean seed can vary by year, environment, and genotype. Objective of this study was to identify quantitative trait loci that underlie isoflavone content in soybean seeds. The study involved 85 F2 populations derived from Korean soybean cultivar 'Kwangkyo' and wild type soybean 'IT182305' for QTL analysis associated with isoflavone content. Isoflavone content of seeds was determined by HPLC. The genetic map of 33 linkage groups with 207 markers was constructed. The linkage map spanned 2,607.5 cM across all 33 linkage groups. The average linkage distance between pair of markers among all linkage groups was 12.6 cM in Kosambi map units. Isoflavone content in F2 generations varied in a fashion that suggested a continuous, polygenic inheritance. Eleven markers (4 RAPD, 3 SSR, 4 AFLP) were significantly associated with isoflavone content. Only two markers, Satt419 and CTCGAG3 had F-tests that were significant at P<0.01 in F2 generation for isoflavone content. Interval mapping using the F2 data revealed only two putative QTLs for isoflavone content. The peak QTL region on linkage group 3, which was near OPAG03c, explained 14~% variation for isoflavone content. The peak QTL region on linkage group 5, which was located near OPN14 accounted for 35.3~% variation for isoflavone content. Using both Map-Maker-QTL (LOD~geq2.0) and single-factor analysis (P~leq0.05) , one marker, CTCGAG3 in linkage group 3 was associated with QTLs for isoflavone content. This information would then be used in identification of QTLs for isoflavone content with precision

Soybean is a major source of protein meal in the world. Kunitz trypsin inhibitor (KTI) protein is responsible for the inferior nutritional quality of unheated or incompletely heated soybean meal. The objective of this research was to identify RAPD markers linked to KTI protein allele using bulked segregant analysis. Cultivar Jinpumkong2 (TiTi) was crossed with C242 (titi, absence of KTI protein) and F. seeds were planted. The F1 . plants were grown in the greenhouse to produce F2 seeds. Each F2 seed from F1 . plants was analysed electrophoretically to determine the presence of the KTI protein band. The present and absent bulks contained twenty individuals each, which were selected on the basis of the KTI protein electrophoresis, respectively. Total 94 F2 individuals were constructed and 1,000 Operon random primers were used to identify RAPD primers linked to the Ti locus. The presence of KTI protein is dominant to the lack of a KTI protein and Kunitz trypsin inhibit protein band is controlled by a single locus. Four RAPD primers (OPAC12, OPAR15, OPO12, and OPC08) were linked to the Ti locus. RAPD primer OPO12 was linked to Ti locus, controlling kunitz trypsin inhibitor protein at a distance of 16.0 cM. This results may assist in study of developing fine map including Ti locus in soybean.