한국의 시화호와 중국의 Aha호 저질토에서 서식하는 황산염 환원세균(sulfate reducing bacteria, SRB)의 깊이에 따른 군집구조를 비교하기 위하여, 이화성 아황산염 환원효소(EC 1.8.99.1; dissimilatory sulfite reductase, dsr) 유전자를 대상으로, polymerase chain reaction (PCR), denaturing gradient gel electrophoresis (DGGE) 및 클론 라이브러리를 이용하여 미생물의 군집구조를 분석하였다. DGGE band 양상을 분석한 결과, Aha호 보다는 시화호에서 더 맡은 밴드를 보여 다양성이 높았고, 깊이별 차이는 나타나지 않았다. 두 서식지에서 얻은총68개 클론의 염기서열을 가지고 계통학적 분석을 한 결과 시화호에서는 Deltaproteobacteria 그룹, Firmicutes 그룹에 속해있는 Desulfotomaculum 종과 archaeal thermophilic SRB 그룹에 속해있는 Archaeoglobus 종이, Aha호에서는 Desulfotomaculum 그룹과 유사성이 높았다. 분리된 대부분의 클론들(59%)은 배양된 황산염 환원세균과는 매우 낮은 유사도를 보였고, 환경에서 분리된 클론들과도90% 이하의 유사도를 나타냈다. 총 클론을 88% 유사도를 기준으로 9그룹으로 나뉘었을 때 시하호와 Aha호의 각 클론은 서로 다른 그룹으로 존재하였다. 이러한 결과는 두 서식지의 이화성 아황산염 환원효소를 가지고 있는 미생물의 군집구조는 확연히 다르고 각 서식지에 특이적인 황산염 환원 미생물이 존재함을 시사한다.

The diversity of sulfate reducing bacteria was investigated in different depths of sediments in Lake Sihwa, Korea and Lake Aha, China by PCR amplification, denaturing gradient gel electrophoresis (DGGE) and clone libraries targeting dissimilatory sulfite redectase (dsr) gene. In the analysis of DGGE band patterns, the community compositions of dsr gene in the sediments of both lakes were significantly different whereas bands in all depths of each environment revealed similar patterns. Bands from Lake Sihwa were produced much more than those from Lake Aha, demonstrating a higher diversity of dsr gene in Lake Sihwa. Total 68 clones containing dsr gene were obtained to analyze their sequences. Sequences from the sediment of Lake Sihwa were affiliated to Deltaproteobacteria, the Gram-positive thermophilic sulfate reducers belonging to the genus Desulforomaculum and archaeal thermophilic SRB belonging to the genus Archaeoglobus, whereas sequences from the sediments of Lake Aha were related to genus Desulfotomaculum. Clones retrieved from sediment of Lake Sihwa revealed a higher numbers than those of Lake Aha, demonstrating a higher diversity of dsr gene in Lake Sihwa. Most of clones (59%) were distantly related to the known cultivated SRB with $60\sim65%$ of similarity, which were clustered only the sequences from the environments showed less than 90% similarity. These habitat specific sequences suggested that the clustered dsr sequences represent species or groups of species that were indigenous to these environments. This study showed that these lakes have a specific bacterial communities having dsr gene distinct from those in other environments such as soil and marine ecosystems around the world.

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