본 시험은 기상여건상 상습적인 과습장해에 대비하여 내습성 콩 품종의 조기육성 및 습해 경감기술 개발을 위한 기초자료를 제공하고자 수행하였던 바, 그 결과를 요약하면 다음과 같다. 1. 뿌리건물중은 풍산나물콩이 과습구가 대조구의 59~67%로 과습에 의한 감소정도가 가장 적었고, 장엽콩이 과습구가 대조구의 47~49%로 감소정도가 가장 컸다. 본엽4엽기(V5 stage) 과습처리후 21일간 뿌리건물중 일당증가량은 풍산나물콩이 과습구가 대조구의 47~56%로 회복력이 가장 컸고, 장엽콩이 과습구가 대조구의 26~27%로 회복력이 가장 적었다. 2. 근류건물중은 풍산나물콩이 과습구가 대조구의 83~91%로 과습에 의한 감소가 가장 적었으나, 명주나물콩은 과습구가 대조구의 48~66%로 감소정도가 가장 컸다. 3. 지상부 건물중에 대한 지하부 건물중의 비율(R/S)은 기간이 경과할수록 감소하였는데, 장엽콩은 과습처리 직후부터 과습처리 종료 11일 후 까지 대조구가 과습구에 비해 R/S가 0.04~0.06 정도 더 높았으며, 풍산나물콩은 과습처리 종료 4일 후 까지는 대조구가 과습구에 비해 R/S가 0.04 정도 더 높았으나, 과습처리 종료 11일 후에는 대조구는 R/S가 0.37였으나 과습구는 R/S가 0.39으로서, 대조구에 비해 과습구의 R/S가 더 높았다. 이는 과습처리 종료 후 뿌리의 회복속도가 빠르고, 부정근(adventitious root)의 발생이 많았기 때문인 것으로 나타났다. 4. 과습처리 종료 11일 후 전체 뿌리 생체중에 대한 부정근의 생체중 비율은 명주나물콩이 14%로 가장 낮았고, 풍산나물콩이 38%로 가장 높아 생육후기 양 수분 흡수능력증대에 유리한 것으로 나타났다.

자연발생포장 및 톱다리개미허리노린재 접종구에서 협 피해 및 수량 감소가 적었던 품종은 풍산나물콩, 소백나물콩, 두유콩, 신팔달콩 2호로 다른 품종에 비해 노린재 선호도가 낮은 품종으로 생각되었고, 명주나물콩, 만리콩, 황금콩은 피해가 심한 품종으로 분류되었다. 콩 품종간 톱다리개미허리노린재 선호성으로 모용색이 회백색인 품종군의 피해율이 13.0%인데 비해 갈색모용의 품종군은 8.2%로 피해율이 낮았으며, 제색도 황색에 비해 담갈색>갈색>회갈색 순으로 제

콩 재래종과 야생종 자원의 엽 형질간의 관계를 분석하여 콩의 엽형 조사를 계량화할 수 있는 기준을 제시함으로써 콩의 초형개량과 재배법 개선을 위하여 필요한 기초자료를 제공하고자 충북대학교 농업생명환경대학 두류유전자원관리실에서 분양받은 콩 재배종 94개와 야생종 91개의 엽형질을 조사한 결과는 다음과 같다. 1. 재배종과 야생종의 엽장은 각각 12.3pm1.25 cm(8.7~15.3 cm)과 평균 6.6pm1.35 cm(3.7~11.3 cm), 엽폭은 각

Anthocyanins of black soybean may play an important role in physiological functions related to human health such as antioxidant, anti-inflammatory, and anticancer. The objective of this study was to investigate the profiles of anthocyanin in fourteen black soybean varieties using high-performance liquid chromatography (HPLC) with photodiode array detector (PAD). In all of the cultivars analyzed totally nine anthocyanins including, CatCy3glc, Dp3gal, Dp3glc, Cy3gal, Cy3glc, Pt3glc, Pg3glc, Pn3glc, and Cy were found. Cy3glc was the major anthocyanin content, represention 69.5% of anthocyanin, followed by Dp3glc (23.0%), Pt3glc (4.9%), Pn3glc (1.2%), and Pg3glc(1.1%), respectively. In contrast, the other five anthocyanins were in very low amounts, below 0.3 % in all varieties. Comparing cultivars and anthocyanin compositions, Geomjeong 2, Cheongja 2, and Cheongja 3 were found to content 9 anthocyanins. Geomjeong 1 and Seonheuk contented CatCy3glc, Cy3gal, Cy3glc, and Pn3glc. The variation of total anthocyanin concentration were significant for soybean cultivars. Geomjeong 2 showed highest average total anthocyanin content (17,937.8 ㎍/g seed coat), and Tawonkong and Heugcheong had the lowest total anthocyanin values (2,835.7 and 2,853.1 ㎍/g seed coat, respectively).

Genetic diversity plays a great role in the survival and adaptability of a species under changable environment. Korea is known as original region of cultivated soybean species with high genetic diversity of wild and cultivated soybean lines. We have collected many semi-wild soybean lines, however, the information about the genetic diversity of these lines is limited. And also the phylogenetic relationship and genetic distance among the semi-wild, typical wild types (Glycine soja Sied. & Zucc.), and cultivated soybean(Glycine max (L.) Merr.) have been controversial. This study was carried out to analyze the diversity of the three groups, and to verify their genetic variation and relationships among them. The diversity indexes of typical wild, semi-wild, and cultivated soybean accessions were 0.854, 0.677, and 0.528, respectively. According to the cluster analysis for the genetic relationships, 58 accessions were defined into three genetic groups. Cluster I consisted of 20 cultivated soybean accessions and three semi-wild soybean lines. Cluster II contained 13 semi-wild soybean lines and one typical wild soybean line. Cluster II included 21 typical wild soybean lines and one semi-wild soybean line. Genetic distance between cultivated and semi-wild soybean, typical wild and semi-wild, and cultivated and typical wild were 0.525 0.761 and 0.810, respectively. The relationship between semi-wild soybean was much closer to the cultivated soybean the to the wild soybean

Acid rain due to air pollution has been believed to be harmful to vegetation and crops, either by direct deposition on the foliage or by indirect leaching of nutrients from the soil. This study was conducted to investigate physiological response and damage of soybean caused by acid rain in the glasshouse at the experimental station of Seoul National University. Soybean (Glycine max L.) cv. Sinpaldal was subjected to simulated acid rain (SAR) two times a week from R2 stage until its maturity. The pH values of SAR treatments were ranged from 2 to 5 together with tap water treatment (pH 7±0.2) as a control. The SAR was composed of H2SO4 and HNO3 at the ratio of 2:1 (v/v). SAR treatment at pH 2 caused clear visual damage on leaves and pods with severe chlorosis and necrosis even after the first SAR was applied, while those at pH greater than 3 showed no clear visual damage. Chlorophyll content (expressed as SPAD value) tended to decrease with decreasing pH with significant reduction at pH 2 as compared with pH values greater than 3. Photosynthesis also showed decrease with decreasing pH with significant reduction at pH 3 and 2. Soybean yield and its components were also affected by SAR treatment, particularly significant at pH 2.

Lectin protein and Kunitz trypsin inhibitor (KTI) protein of mature 　soybean seed are a main antinutritional factor in soybean seed. The Le gene controls a lectin protein and Ti gene controls the KTI protein in soybean. Ti locus has been located on linkage group 9 in the classical linkage map of soybean. Position of Le locus on linkage map was not identified. Genetic relationship between Ti locus and Le locus could be useful in soybean breeding program for the genetic elimination of these factors. The objective of this study was to determine the independent inheritance or linkage between Ti locus and Le locus in soybean seed. Two F2 populations were developed from three parents (Gaechuck#1, T102, and PI548415). The F1 seeds from Gaechuck#1 (titiLeLe) x T102 (TiTilele) and Gaechuck#1 (titiLeLe) x PI548415 (TiTilele) were obtained. The lectin and KTI protein were analysed from F2 seeds harvested from the F1 plants to find independent assortment or linkage between Ti locus and Le locus. The segregation ratios of 3 : 1 for Le locus (129 Le_ : 44 lele) and Ti locus (132 Ti_ : 41 titi) and were observed. The segregation ratios of 9 : 3 : 3 : 1 (95 Le_Li_ : 34 Le_titi: 37 leleTi_ : 7 leletiti) between Le gene and Ti gene in F2 seeds were observed. This data showed that Ti gene was inherited independently with the Le gene in soybean. These results will be helpful in breeding program for selecting the line with lacking both KTI and lectin protein in soybean.

dlm mutants controlling disease lesion mimic leaf trait may be useful in basic research of disease hypersensitive response and programmed cell death in soybean. The study on genetic relationship between dlm trait and other morphological C trait, position of dlm allele on classical linkage group, and a molecular marker linked to dlm allele was little reported. Two populations [T173 (ffDlmDlm) x T363 (FFdlmdlm), T363 (dlmdlmY9Y9) x T135 (DlmDlmy9y9)] were made to find independent assortment or linkage between dlm locus and f locus or between dlm locus and y9 locus. The segregation ratios of 3 : 1 were observed in the F2 population and the Chi-square values suggested that the disease lesion mimic leaf, fasciation stem, and chlorophyll-deficient leaf traits were controlled by a single recessive gene. Segregation ratios of 78 Dlm_F_: 19 Dlm_ff: 17 dlmdlmF_ : 3 dlmdlmff based on F2 phenotype showed that dlm allele was inherited independently with the f allele controlling fasciation stem trait in soybean. Also, segregation ratios of from 149 Dlm_Y9_: 41 Dlm_y9y9: 38 dlmdlmY9_ : 5 dlmdlmy9y9 based on F2 phenotype confirmed that dlm allele was inherited independently with the y9 allele controlling chlorophyll- deficient leaf trait in soybean. From these results, dlm allele would not be located on linkage group 11 (molecular linkage group: D1b+W) and linkage group 14 (molecular linkage group: E) in soybean. This results will helpful to attempt to position the Dlm locus on the soybean molecular linkage map.

GE interaction is the expression of differential genotypic adaptation across environments. GE interactions through different stability parameters and performance of the traits of genotypes were studied. The traits were days to maturity, pod length, number of pods/ plant, 100-seed weight and seed yield/plant in ten soybean genotypes across five environments. Significant differences were observed for genotypes, environments and GE interactions. Stability analysis after Eberhart and Russell's model suggested that the genotypes used in this study were all more or less responsive to environmental changes. Most of the genotypes perform better in Env.3. Based on phenotypic indices(Pi), regression (S2di) genotype Garurab was found fairly stable for days to maturity. BS-23 and G-2120 may be considered as stable genotype for pod length. All the genotypes except G-2120 showed that the genotypes were relatively unstable under environmental fluctuation for the number of pod/plant. Genotype BS-23 was found most stable among all the genotypes for 100-seed weight. BS-3 and Gaurab was the most stable and desirable genotypes for seed yield in soybean.

dlm allele controlling disease lesion mimic trait is useful in basic research aimed at better understanding disease hypersensitive response and programmed cell death in soybean. Inheritance between dlm trait and any morphological trait, position of dlm allele on classical linkage group, molecular marker linked to dlm allele were not reported. Two populations [T255 (lf2lf2DlmDlm) x T363 (Lf2Lf2dlmdlm), T363 (dlmdlmp1p1) x T43 (DlmDlmP1P1)] were made to find independent assortment or linkage between dlm locus and lf2 or between dlm locus and P1 locus. The segregation ratios of 3 : 1 were observed in the F2 population and the Chi-square values strongly suggested that the disease lesion mimic and seven-leaflet trait was controlled by a single recessive gene. Glabrousness trait was controlled by a single dominant gene. Segregation ratios of 48 Lf2_Dlm_: 30 Lf2_dlmdlm: 21 lf2f2Dlm_ : 8 lf2lf2dlmdlm based on F2 phenotype showed that dlm allele was inherited independently with the lf2 allele controlling seven-leaflet trait in soybean. However, more F2 plants will be needed to confirm this result. Also, segregation ratios of 137 P1_Dlm_: 46 P1_dlmdlm: 49 p1p1Dlm_ : 16 p1p1dlmdlm from F2 phenotype confirmed strongly that dlm allele was inherited independently with the P1 allele controlling glabrous trait in soybean. This results indicate that dlm allele will not located in soybean classical linkage group 2 (molecular linkage group K) and soybean classical linkage group 16. This observation will helpful to attempt to position the Dlm locus on the soybean molecular linkage map.