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음식물 쓰레기를 이용한 3단계 메탄생산 공정의 미생물 다양성
남지현,김시욱,이동훈,Nam, Ji-Hyun,Kim, Si-Wouk,Lee, Dong-Hun 한국미생물학회 2012 미생물학회지 Vol.48 No.2
혐기성 소화는 음식물 쓰레기와 같은 폐기물로부터 재생 가능한 에너지원으로 메탄을 생성하는 공정이다. 본 연구에서는 음식물 쓰레기와 폐수를 동시에 처리하는 3단계 메탄생산 공정을 이용한 혐기성 소화공정의 bacteria와 archaea 군집 변화를 조사하였다. 3단계 메탄생산 공정은 음식물 쓰레기 및 폐수를 메탄과 이산화탄소로 전환하는 반혐기성 가수분해/산생성, 혐기성 산생성과 혐기성 메탄생성조로 구성되어있으며, 16 rRNA 유전자 라이브러리의 염기서열 분석과 정량 PCR 등의 분자생물학적 방법으로 주요 미생물 군집을 조사하였다. 메탄생산 공정의 주요 미생물 군집은 VFA-산화 박테리아와 Methanoculleus 속에 속하는 hydrogenotrophic methanogen의 두 종(species)이었다. 또한, 소수의 Picrophilaceae 과(Thermoplasmatales 목)의 archaea도 확인하였다. 음식물을 이용한 3단계 메탄생산 공정은 acetogenesis를 기반으로 하는 고전적 메탄생성 공정과 달리 주로 hydrogenotrophic methanogen의 분해 경로에 의해 이루어 짐을 알 수 있다. 이들 균주의 우점은 중온 소화공정, 중성 pH, 높은 암모니아 농도, 짧은 HRT, Tepidanaerobacter 속 등과 같은 VFA 산화세균과의 상호작용 등에서 기인한 것으로 생각된다. Anaerobic digestion is an alternative method to digest food wastes and to produce methane that can be used as a renewable energy source. We investigated bacterial and archaeal community structures in a three-stage methane production process using food wastes with concomitant wastewater treatment. The three-stage methane process is composed of semianaerobic hydrolysis/acidogenic, anaerobic acidogenic, and strictly anaerobic methane production steps in which food wastes are converted methane and carbon dioxide. The microbial diversity was determined by the nucleotide sequences of 16S rRNA gene library and quantitative real-time PCR. The major eubacterial population of the three-stage methane process was belonging to VFA-oxidizing bacteria. The archaeal community consisted mainly of two species of hydrogenotrophic methanogen (Methanoculleus). Family Picrophilaceae (Order Thermoplasmatales) was also observed as a minor population. The predominance of hydrogenotrophic methanogen suggests that the main degradation pathway of this process is different from the classical methane production systems that have the pathway based on acetogenesis. The domination of hydrogenotrophic methanogen (Methanoculleus) may be caused by mesophilic digestion, neutral pH, high concentration of ammonia, short HRT, and interaction with VFA-oxidizing bacteria (Tepidanaerobacter etc.).
금속펩타이드를 이용한 Pseudomonas alcaligenes의 5S rRNA의 구조 연구
김희정,김시욱,고문주,Kim, Hee-Joung,Kim, Si-Wouk,Koh, Moon-Joo 대한화학회 2002 대한화학회지 Vol.46 No.1
$Ni(II){\cdot}Gly$-Gly-His(Arg)COOH와 $Cu(II){\cdot}Gly$-Gly-His(Arg)COOH 형태의 금속펩타이드를 이용하여 P. alcaligenes에서 얻은 5S rRNA의 구조를 조사하였다. 그 결과 금속 펩타이드들은 5S rRNA의 줄기-고리 구조에서 염기쌍을 이루지 않거나 불안정하게 이루는 부분을 선택적으로 변형시켰다. 금속펩타이드의 선택성은 중심 금속이 Ni(II)인 경우와 Cu(II)인 경우에 차이가 거의 없었다. 금속펩타이드를 이용한 절단 결과를 금속 착물 M(II)CR을 이용한 결과와 비교하면 금속펩타이드에 의한 선택성이 더 크게 나타났다. 금속펩타이드와 금속착물을 이용한 절단 결과로부터 P. alcaligenes에서 얻은 5S rRNA의 이차구조를 살펴보았다. The recognition and cleavage of 5S rRNA from P. alcaligenes by metallopeptides to the form $Ni(II){\cdot}Gly$-Gly-His(Arg)COOH and $Cu(II){\cdot}Gly$-Gly-His(Arg)COOH were investigated. The results of RNA cleavage analyses suggest that metallopeptides selectively target the unpaired or unstably paired bases of stem-loop structure of 5S rRNA. The selectivity of metallopeptides was little affected by the species of metal ion, Ni(II) or Cu(II). When the result of cleavage by metallopeptides was compared with that of by metal complexes M(II)CR, the recognition by metallopeptides was more selective and structure specific. The cleavage data by metallopeptides and other metal complexes were used to probe the secondary structure of 5S rRNA from P. alcaligenes.
김옥봉,임채광,김시욱,박종근,윤성명,이정섭,Kim, Ok-Bong,Lim, Chae-Kwang,Kim, Si-Wouk,Park, Jong-Kun,Yoon, Seong-Myeong,Lee, Jung-Sup The Korean Society for Integrative Biology 1998 Korean journal of biological sciences Vol.2 No.3
A RecA-like protein (RecAps) was identified from fluorescent Pseudomonas sp. and the inducible nature of the protein was characterized in detail. It was shown by dose-response and time-course experiments using two DNA damaging agents, nalidixic acid and mitomycin-C, that the cellular level of RecAps protein was increased 3-8 fold compared to that of the control. The most effective doses of nalidixic acid and mitomycin-C for the protein induction were $30{\mu}g/ml$ and $0.3{\mu}g/ml$ at the treatment time point of 150 min, respectively. The enhanced level of RecAps protein was gradually decreased to the control level after 10 hr in normal medium. Interestingly, the cellular level of RecAps protein was increased by the same DNA damaging agents even when cell growth was completely inhibited by treatment with $170{\mu}g/ml$ of chloramphenicol, an inhibitor of protein synthesis, suggesting that new protein synthesis is not required for the induction of RecAps. All these results suggest that a typical S0S repair function driven by RecA-like protein is conserved in Pseudomonas sp. cells as in E, coli.