Soybean cultivar ‘Seonpung’ was developed for soy-paste and tofu. Suwon 224 and YS1325-3S-2 were crossed in 2003 and selected from F3 to F5 by pedigree method. The preliminary yield trial (PYT) and advanced yield trial (AYT) were conducted from 2009 to 2010, and regional yield trial (RYT) in twelve regions was conducted from 2011 to 2013. In RYT, ‘Seonpung’ was stable in variable environments and a high yield cultivar. ‘Seonpung’ is determinate, white flower, yellow spherical seed and yellow hilum. Flowering date and maturity date were Aug. 5 and Oct. 19, respectively. Plant height was similar to ‘Daewonkong (standard cultivar)’. However ‘Seonpung’ has higher node number (16) and seed weight (25.9g/100-seed weight) than ‘Daewonkong’ (14 and 24.2g/100-seed weight). ‘Seonpung’ is resistant to root rot, and it also has high level of resistance to bacterial pustule and soybean mosaic virus. The yield of tofu of ‘Seonpung’ was 241%, and noticeably lighter, and solidity was higher than ‘Daewonkong’. Soybean malt scent, fermented soybean yield and γ-polyglutamic acid (γ-PGA) of ‘Seonpung’ were 4, 181% and 31.7㎎/g. The yield in adaptable regions was 340kg/10a (21% increase compared to ‘Daewonkong’). ‘Seonpung’ is expected to be cultivated and used widely for soy-paste and tofu. (Registration number: 5931)

A soybean cultivar for soy-paste, ‘Uram’, was developed from the cross between ‘Suwon190’ and ‘SS99244’ (Shinpaldal-2 X T243) by soybean breeding team at the National Institute of Crop Science (NICS) in 2010. A promising line, SS00232-B-B-3SSD-9-4-1-1, was selected and designated as the name of ‘Milyang188’. It was prominent and had good result from regional adaptation yield trials (RYT) in southern area of Korea for three years from 2008 to 2010 and released as the name of ‘Uram’. It has a determinate growth habit, white flower, gray pubescence, yellow seed coat, yellow hilum, spherical seed shape and large seed (25.8 grams per 100 seeds). ‘Uram’ was found to be resistant to bacterial pustule and soybean mosaic virus, the major soybean diseases in Korea. The lowest pod height of ‘Uram’ was 19cm and it will be able to reduce seed loss during mechanical harvesting. The average yield of ‘Uram’ is 3.27 ton per hectare in southern double cropping area. Through these results, ‘Uram’ is soybean cultivar that is favorable for mechanization harvesting, resistant to diseases and highly yield.

본 연구는 우리나라 기상여건을 고려하여 콩 생육초기에 습해 저항성 자원을 선발하여 내습성 콩 품종의 조기육성 및 유전적 요인을 구명하기 위한 기초자료를 제공하고자 수행하였던 바, 그 결과를 요약하면 다음과 같다.1.국내 콩 주요 품종 및 보존 유전자원 등 192점에 대한 담수처리에 의한 생존율에 따라 습해 저항성과 감수성으로 분류하였다. 그 결과, 장백콩, 단백콩, 소원콩, 소청2호, 수원269는 습해 저항성 자원으로 선발되었다. 신록, T181, T201, NTS1116, HP-963은 습해 감수성 자원으로 선발되었다. 2.습해처리에 의해 발현이 증가된다고 보고된 유전자들 APX1, APX2, Adh의 발현을 분석한 결과 유전자들의 발현이 증가하였으며, 이로 미루어 습해처리가 정상적으로 처리되었음을 알 수 있다.3.1차 선발된 습해 저항성 및 감수성 자원에 습해를 처리하였을 때, 저항성 자원은 생존율이 71% 이상, 감수성 자원은 25% 이하의 생존율을 나타내었다. 1차 선발된 습해 저항성 및 감수성 자원에 대한 재현성을 확인하였다.4.부정근은 습해 저항성 자원에서 17.3~41.3개, 감수성 자원에서 0~9개를 나타내었다. 습해 감수성 자원에 비해 습해 저항성 자원에서 부정근이 상대적으로 많이 발달함을 확인할 수 있었다.5.주근의 길이는 저항성 자원에서는 0~25% 정도 감소한 반면 감수성 자원에서는 44~60% 감소한 것으로 조사되었다. 측근의 수는 감수성 자원에서는 37~65%로 감소하였지만 저항성 자원에서는 8~67% 증가하였다.

본 연구는 고 전분 함유 유용 유전자원 선발 및 콩 우량품종 육성의 기초자료로 활용하고자 국내 콩 주요 품종 및 보존 유전자원의 전분함량과 변이 양상을 분석하였으며 그 결과는 다음과 같다. 1.총 2354점 국내 콩 주요 품종 및 보존 유전자원에 대한 요오드-전분 반응에 의한 착색 정도에 따라 1에서 4등급으로 분류를 하였으며, 대부분의 콩 유전자원이 2∼3등급으로 분류되었고, 가장 강한 착색 반응을 보인 4등급으로 126점의 유전자원이 선발되었다2.전분함량의 정량적 분석을 수행한 결과, 1, 2등급으로 분류된 유전자원 Daewang, Soheonje, Jyuiku #109는 각각 0.57, 0.45, 0.54%의 낮은 전분함량을 나타내었다. 반면, 4등급으로 분류된 유전자원은 2.81∼4.55%의 상대적으로 높은 전분함량을 보여 요오드-전분 반응법은 유전자원의 대량검정에 유용하게 이용할 수 있을 것으로 판단되었다.3.각 유전자원에서 전분함량의 차이가 다른 구성 성분의 함량에 영향을 미치는지를 알아보기 위해, 조단백질함량, 조지방함량, 수분함량을 각각 측정하였다. 전분함량의 변화는 조단백질 함량 변화에 영향을 미치며, 조지방과 수분함량의 변화에 영향이 없음을 확인하였다.

Although much effort has been made to find agronomically important loci in the soybean plant, extensive linkage disequilibrium and genome duplication have limited efficient genome-wide linkage analyses that can identify important regulatory genes. In this respect, recombination block-based analysis of cultivated plant genomes is a potential critical step for molecular breeding and target locus screening. We propose a new three-step method of detecting recombination blocks and comparative genomics of bred cultivars. It utilizes typical reshuffling features of their genomes, which have been generated by the recombination processes of breeding ancestral genomes. To begin with, mutations were detected by comparing genomes to a reference genome. Next, sequence blocks were examined for likenesses and difference with respect to the reference genome. The boundaries between the blocks were taken as recombination sites. All recombination sites found in the cultivar set were used to split the genomes, and the resulting sequence fragments were named as core recombination blocks (CRBs). Finally, the genomes were compared at the CRB level, instead of at the sequence level. In the genomes of the five Korean soybean cultivars used, the CRB-based comparative genomics method produced long and distinct CRBs that are as large as 22.9 Mb. We also demonstrated efficiency in detecting functionally useful target loci by using indel markers, each of which represents a CRB. We further showed that the CRB method is generally applicable to both monocot and dicot crops, by analyzing publicly available genomes of 31 soybeans and 23 rice accessions.

Resequencing data is actively used for searching QTL or analyzing genetic diversity in the crops. However, the complexity of genome, caused by genome duplication, limits the utility of genome-wide association studies and linkage analyses to identify genes that regulate agronomically valuable traits. Here, we propose a comparative genomics approach based on core or common variation-based recombination blocks (CRB) using single nucleotide variation (SNV) density information. We found that the soybean genomes are assembled with long and distinct CRBs as large as 10Mb. CRB-based comparative genomics enabled us to accurately identify recombination blocks at the whole-chromosome level. We identified the Ih locus that determines the yellow hilum color in soybeans using CRB-based mapping with representative indel markers. These results suggest that the CRB-based comparison method is a promising platform for molecular breeding and map-based cloning.

본 연구에서는 RNAi 기작을 이용하여 식미에 중요한 영향을 미치는 아밀로스 함량을 다양화하기 위해 GBSSI 유전자의 3’-UTR 부위를 targeting하여 dsRNA를 생성시킬 수 있는 운반체를 제작하고, 벼에 형질전환 하였다. 작성된 형질전환체들을 대상으로 I2-KI 용액 반응과 아밀로스 함량을 분석한 결과, I2-KI 용액에 대한 반응은 waxy 타입으로 나타났으나 아밀로스 함량은 찰벼와 저아밀로스 벼 사이에 해당되는 범위를 보였다. 원품종과

The cultivated radish (Raphanus sativus L.) is a major vegetable crop in the world wide and fast-growing species that grows inhabitats of six continents. It is very important to determine hybrid seed purity in the production of hybrid Brassica vegetable seeds to avoid unacceptable contamination with self-inbred (sib) seeds. The use of random amplified polymorphic DNA (RAPD) markers for evaluating seed purity in F2 -hybrid radish cultivars demonstrated. One hundred eighty seeds from the F1 male and female harvest were subsequently screened for seed purity using 13 primers. The 13 primers result in 17 cultivar-specific bands and 23 variable RAPD bands scored for cultivar. RAPD analysis of hybrid seeds from the harvest revealed 128 seeds tested except underdevelopment and decayed seeds were sibs. Especially, F2 hybrids of radish, OPC13, OPD20 were presented clear hybrid bands. It maintains higher than average level of genetic diversity compared with their correspondent parents. RAPD amplification of DNA extracted from germinated individuals from the female harvest reveal that 10 of 208 seeds tested were self-inbred (4.8%). RAPD analysis of hybrid seeds from the male harvest revealed 7 of the 208 seeds tested were sibs (3.4%). The RAPD may lead to a better insight in to the hybrid seed purity.

1. 본 연구에서는 완두유래의 세포질성 PsAPX1 유전자를 대상으로 산화스트레스 유도성 프로모터를 연결하여 엽록체에 targeting 되는 과발현 운반체를 제작하고 벼에 도입한 결과 형질전환체에서 도입유전자 수가 1~3 copy인 것으로 나타나, 적은 수의 유전자가 안정적으로 도입되었음을 확인하였다. 2. 염, 오존, 자외선, 한발과 같은 다양한 환경스트레스 조건에서 내성이 증진된 우수 계통을 선발하기 위하여 작성된 형질전환 벼 계통들을 대상으로 생물

1. 본 연구에서는 공동배양 배지에 Agrobacterium 성장 억제물질인 silver nitrate를 첨가하고 변온과 여과지처리를 추가하여 공동배양 기간을 7일로 늘였으며, 또한 항산화 물질 3종을 공동배양 배지에 첨가하여 세포의 oxidative burst를 최소화함으로써 벼 형질전환효율을 높일 수 있었다. 또한 이 방법을 적용하여 형질전환이 어려운 품종을 대상으로도 형질전환 식물체를 작성할 수 있었다. 2. 벼 형질전환체의 70%에서 도입유전자

Agronomic characteristics of transgenic herbicide-resistant rice lines were evaluated under field condition. Differences in agronomic traits and rice quality were observed between transgenic plants and the corresponding untransformed controls. Transgenic Ilpumbyeo lines flowered earlier than untransformed controls, whereas transgenic Nagdongbyeo flowered at the same time as untransformed control. With regard to the yield and rice quality, most of the transgenic lines showed lower yield than control except some selected transgenic lines. Selected Nagdongbyeo transgenic line also showed good eating quality comparable to the control although most selected Ilpumbyeo transgenic lines showed slightly lower eating quality and increased white center/belly in the rice grain. In order to find the main factor leading to somaclonal variation among transgenic lines, Tos17, a rice retrotransposon activated by prolonged tissue culture period was investigated. Although the transgenic lines carried only one or two of transformed bar gene, the copy number of Tos17 increased in most transgenic lines compared with control. The activation of Tos17 was not detected in selected promising transgenic lines such as ND115-15-1-B and IP23-3-3, suggesting that the increased copy number of Tos17 may have negatively affected agronomic characteristics of transgenic rice.