http://chineseinput.net/에서 pinyin(병음)방식으로 중국어를 변환할 수 있습니다.
변환된 중국어를 복사하여 사용하시면 됩니다.
Ik-Soon Jang,Eunbi Jo,Soo Jung Park,Su Jeong Baek,In-Hu Hwang,Hyun Mi Kang,Je-Ho Lee,권요셉,Junik Son,HO JEONG KWON,최종순 고려인삼학회 2020 Journal of Ginseng Research Vol.44 No.1
Background: The cellular senescence of primary cultured cells is an irreversible process characterized bygrowth arrest. Restoration of senescence by ginsenosides has not been explored so far. Rg3(S) treatmentmarkedly decreased senescence-associated b-galactosidase activity and intracellular reactive oxygenspecies levels in senescent human dermal fibroblasts (HDFs). However, the underlying mechanism of thiseffect of Rg3(S) on the senescent HDFs remains unknown. Methods: We performed a label-free quantitative proteomics to identify the altered proteins in Rg3(S)-treated senescent HDFs. Upregulated proteins induced by Rg3(S) were validated by real-time polymerasechain reaction and immunoblot analyses. Results: Finally, 157 human proteins were identified, and variable peroxiredoxin (PRDX) isotypes werehighly implicated by network analyses. Among them, the mitochondrial PRDX3 was transcriptionally andtranslationally increased in response to Rg3(S) treatment in senescent HDFs in a time-dependent manner. Conclusion: Our proteomic approach provides insights into the partial reversing effect of Rg3 on senescentHDFs through induction of antioxidant enzymes, particularly PRDX3.
충북에서 사과 주요 토양병에 의한 고사율과 재배환경과의 상관관계
이성희,권의석,신현만,김익제,남상영,홍의연,김대일,차재순,Lee, Sung-Hee,Kwon, Yeuseok,Shin, Hyunman,Kim, Ik-Jei,Nam, Sang-Young,Hong, Eui Yon,Kim, Daeil,Cha, Jae-Soon 한국식물병리학회 2017 식물병연구 Vol.23 No.1
이전 연구에서 충북지방의 사과과수원에서 토양병에 의한 사과나무 고사율이 매우 높게 나타났다. 본 연구에서는 토양병에 의한 사과나무 고사율과 재배환경과의 상관관계를 조사하였다. 자주날개무늬병에 의한 사과나무 고사율은 토양 내 칼슘 함량과 유의하게 정의 상관관계를 보였고, 흰날개무늬병에 의한 사과나무 고사율은 토양 내 유효 인산 함량과 유의하게 정의 상관관계를 보였다. 반면에 역병 피해 사과원 14개소에서는 사과나무 고사율과 재배환경과는 유의성 있는 상관관계가 없었다. 세분화한 재배환경과의 상관관계 분석결과는 토양 내 칼슘함량 외에 과원 경사도와 착과수가 자주날개무늬병에 의한 고사율에 영향을 미쳤고, 토양 내 유효인산 함량 외에 칼슘 함량이 흰날개무늬병에 의한 고사율에 영향을 미쳤다. 과원경사도, 토성, 마그네슘과 칼슘 함량이 사과역병에 의한 고사율에 영향을 주었다. 이 결과는 사과과원의 재배법 변경에 의해 토양병에 의한 사과나무 고사율을 감소시키는 데 적용 가능할 것이다. The previous study showed that die-back of apple trees caused by soil-borne diseases was significantly high in the apple orchards in Chungbuk province. The correlation between dieback ratio and cultivation environment in apple orchards infected by soil-borne diseases was investigated in this study. The dieback ratio of five orchards diseased by violet root rot and five places infected by white root rot showed significantly positive correlation with Ca content and available $P_2O_5$ content in soil, respectively. Whereas, the dieback ratio of fourteen orchards diseased by Phytophthora root rot was not significant. Subgrouping of cultivation environment analysis showed that the slope degree of orchard and the number of fruit setting also affected the dieback ratio caused by violet root rot and Ca content in soil also affected the dieback ratio caused by white root rot. It showed that the slope degree, soil texture, Mg and Ca content affected the dieback ratio caused by Phytophthora root rot. These results can be applied to reduce die-back ratio by the modification cultivation environment for each soil-borne disease.
송인자(In-Ja Song),선현진(Hyeon-Jin Sun),정옥철(Ok-Cheol Jeong),양대화(Dae-Hwa Yang),진일두(Il-Doo Jin),강홍규(Hong-Gyu Kang),고석민(Suk-Min Ko),권용익(Yong-Ik Kwon),배태웅(Tae-Woong Bae),송필순(Pill-Soon Song),이효연(Hyo-Yeon Lee) 한국육종학회 2017 한국육종학회지 Vol.49 No.1
This study was carried out to develop new zoysiagrass (Zoysia japonica Steud.) cultivar ‘Halla Green 2’ (Grant number: No. 118). To develop a zoysiagrass cultivar with dwarfism by using the mutation breeding method, the wild type control Gosan plants were irradiated using a 30 Gy gamma ray source in 2010. Dwarf mutants were selected from the mutated grasses in successive generations. Dwarf mutant lines were identified and a new zoysiagrass variety Halla Green 2 was developed. The plant height of Halla Green 2 was 3.4 and 1.8 times lower than that of Gosan and Zenith, respectively. This cultivar has dwarf characteristics such as shorter sheath, shorter leaf blade, shorter flag leaf, and shorter third internode of stolon compared to those of Gosan and Zenith. Additionally, the sheaths and leaf blades color of Gosan, Zenith and Halla Green 2 were all light green, whereas their stolons were purple, yellow-green and yellow green, respectively. Trichomes(hairs) were visible on both adaxial and abaxial surfaces of the Gosan leaves, whereas only on the adaxial side of the Zenith and Halla Green 2 leaves. The Halla Green 2 grass showed distinguishable morphological traits compared to those of wild type Gosan and Zenith.
ITS 염기서열 분석 및 CAPS를 이용한 조이시아 속(Zoysia) 들잔디와 갯잔디의 구별
홍민지(Min-Ji Hong),양대화(Dae-Hwa Yang),정옥철(Ok-Cheol Jeong),김양지(Yang-Ji Kim),박미영(Mi-Young Park),강홍규(Hong-Gyu Kang),선현진(Hyeon-Jin Sun),권용익(Yong-Ik Kwon),박신영(Shin-Young Park),양바오로(Paul Yang),송필순(Pill-Soon So 한국원예학회 2017 원예과학기술지 Vol.35 No.3
Zoysia 속 잔디는 학교운동장 및 공원, 골프장, 스포츠경기장과 같이 다양한 장소에 식재되고 있는 중요한 잔디이다. 해안가에서 자생하는 Zoysia 속 들잔디와 갯잔디는 외부 형태적 특성이 유사하여 외부 형태적 분류 뿐 만 아니라 분자생물학적 분류도 필요하다. 본 연구에서는 nrDNA ̵ ITS(Internal Transcribed Spacer)의 DNA 바코드 분석을 통해서 자생하는 들잔디와 갯잔디의 분자생물학적 신속한 분류체계를 확립하고자 하였다. 이를 위해 난지형 잔디인 Zoysia 속 들잔디(Z. japonica) 및 갯잔디(Z. sinica)와 한지형 대표 잔디인 크리핑 벤트그라스(A. stolonifera) 및 켄터키 블루그라스(P. pratensis)의 nrDNA - ITS 염기서열을 확보하였다. 확보된 들잔디및 갯잔디, 크리핑 벤트그라스, 켄터키 블루그라스의 ITS 염기서열 전체 구간은 각 686bp와 687bp, 683bp, 681bp으로 확인되었으며, nrDNA - ITS 내부 염기서열구간 분석 결과, ITS1의 크기는 248 ̵ 249bp, ITS2는 270 - 274bp, 5.8S rDNA는 163 - 164bp의 차이로, 각 4종의 잔디가 ITS 염기서열을 이용하여 식별되었다. 특히, 들잔디와 갯잔디 nrDNA-ITS 염기서열은 19 염기(2.8%) 차이를 나타냈으며, ITS1과 ITS2의 G + C 함량은 55.4 ̵ 63.3% 임을 확인하였다. 이러한 들잔디와 갯잔디의 ITS 염기서열 차이를 바탕으로 CAPS 마커로 전환하여 대조구 및 수집된 자생 Zoysia 속 잔디 영양체 62개체를 분석한 결과, 외부형태학적 분류법으로 들잔디 개체, 갯잔디 개체로 동정되었지만, ITS CAPS 마커를 이용한 분자생물학적 분류법으로 들잔디 36개체와 갯잔디 22개체 뿐만 아니라 들잔디와 갯잔디간의 자연교배종 4개체도 식별하였다. 이상의 결과에서 들잔디와 갯잔디는 ITS 염기서열 및 ITS 기반 CAPS를 통하여 식별할 수 있을 것으로 판단된다. Zoysiagrasses are important turf plants used for school playgrounds, parks, golf courses, and sports fields. The two most popular zoysiagrass species are Zoysia japonica and Zoysia sinica. These are widely distributed across different growing zones and are morphologically distinguishable from each other; however, it is phenotypically difficult to differentiate those that grow along the coastal line from those in beach area habitats. A combination of morphological and molecular approaches is desirable to efficiently identify these two plant cultivars. In this study, we used a rapid identification system based on DNA barcoding of the nrDNA-internal transcribed spacer (ITS) regions. The nrDNA-ITS regions of ITS1, 5.8S nrDNA, and ITS2 from Z. japonica , Z. sinica , Agrostis stolonifera , and Poa pratensis were DNA barcoded to classify these grasses according to their molecular identities. The nrDNA-ITS sequences of these species were found at 686 bp, 687 bp, 683 bp, and 681 bp, respectively. The size of ITS1 ranged from 248 to 249 bp, while ITS2 ranged from 270 to 274 bp. The 5.8S coding region ranged from 163 - 164bp. Between Z. japonica and Z. sinica , nineteen (2.8%) nucleotide sites were variable, and the G+C content of the ITS region ranged from 55.4 to 63.3%. Substitutions and insert/deletion (indel) sites in the nrDNA-ITS sequence of Z. japonica and Z. sinica were converted to cleaved amplified polymorphic sequence (CAPS) markers, and applied to the Zoysia grasses sampled to verify the presence of these markers. Among the 62 control and collected grass samples, we classified three groups: 36 Z. japonica , 22 Z. sinica , and 4 Z. japonica /Z. sinica hybrids. Morphological classification revealed only two groups; Z. japonica and Z. sinica . Our results suggest that used of the nrDNA-ITS barcode region and CAPS markers can be used to distinguish between Z. japonica and Z. sinica at the species level.