• Title/Summary/Keyword: Stable isotope probing (SIP)

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Use of Stable Isotope Probing in Selectively Isolating Target Microbial Community Genomes from Environmental Samples for Enhancing Resolution in Ecotoxicological Assessment

  • Park, Joonhong;Congeevaram, Shankar;Ki, Dong-Won;Tiedje, James M.
    • Molecular & Cellular Toxicology
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    • v.2 no.1
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    • pp.11-14
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    • 2006
  • In this study we attempted to develop a novel genomic method to selectively isolate target functional microbial genomes from environmental samples. For this purpose, stable isotope probing (SIP) was applied in selectively isolating organic pollutant-assimilating populations. When soil microbes were fed with $^{13}C-labeled $ biphenyl, biphenyl-utilizing cells were incorporated with the heavy carbon isotope. The heavy DNA portion was successfully separated by CsCl equilibrium density gradient. And the diversity in the heavy DNA was sufficiently reduced, being suitable for the current DNA microarray techniques to detect biphenyl-utilizing populations in the soil. In addition, we proposed a new way to get more genetic information by combining this SIP method with selective metagenomic approach. The increased selective power of these new DNA isolation methods will be expected to provide a good quality of new genetic information, which, in turn, will result in development of a variety of biomarkers that may be used in assessing ecotoxicology issues including the impacts of organic hazards, and antibiotic-resistant pathogens on human and ecological systems.

Deciphering Functions of Uncultured Microorganisms (난배양성 미생물의 기능 분석 방법)

  • Kim, Jeong-Myeong;Song, Sae-Mi;Jeon, Che-Ok
    • Korean Journal of Microbiology
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    • v.45 no.1
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    • pp.1-9
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    • 2009
  • Microbes within complex communities show quite different physiology from pure cultured microbes. However, historically the study of microbes has focused on single species in pure culture and most of microbes are unculturable in our labs, so understanding of complex communities lags behind understanding of pure cultured cells. Methodologies including stable isotope probing (SIP), a combination of fluorescence in situ hybridization (FISH) and microautoradiography (MAR), isotope micrarray, and metagenomics have given insights into the uncultivated majority to link phylogenetic and functional information. Here, we review some of the most recent literatures, with an emphasis on methodological improvements to the sensitivity and utilities of these methods to link phylogeny and function in complex microbial communities.

Functional Metagenomics using Stable Isotope Probing: a Review

  • Vo, Nguyen Xuan Que;Kang, Ho-Jeong;Park, Joon-Hong
    • Environmental Engineering Research
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    • v.12 no.5
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    • pp.231-237
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    • 2007
  • The microbial eco-physiology has been the vital key of microbial ecological research. Unfortunately, available methods for direct identity of microorganisms and for the investigation of their activity in complicated community dynamics are limited. In this study, metagenomics was considered as a promising functional genomics tool for improving our understanding of microbial eco-physiology. Its potential applications and challenges were also reviewed. Because of tremendous diversity in microbial populations in environment, sequence analysis for whole metagenomic libraries from environmental samples seems to be unrealistic to most of environmental engineering researchers. When a target function is of interest, however, sequence analysis for whole metagenomic libraries would not be necessary. For this case, nucleic acids of active populations of interest can be selectively gained using another cutting-edge functional genomic tool, SIP (stable isotope probing) technique. If functional genomes isolated by SIP can be transferred into metagenomic library, sequence analysis for such selected functional genomes would be feasible because the reduced size of clone library may become adequate for sequencing analysis. Herein, integration of metagenomics with SIP was suggested as a novel functional genomics approach to study microbial eco-physiology in environment.

Polychlorobiphenyl (PCB) 토양오염복원: PCB 제거 토양미생물들의 군집과 기능을 효과적으로 분석하는 신 genomics 방법개발에 관한 연구

  • Park Jun-Hong
    • Proceedings of the Korean Society of Soil and Groundwater Environment Conference
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    • 2005.04a
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    • pp.28-30
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    • 2005
  • Because of high population diversity in soil microbial communities, it is difficult to accurately assess the capability of biodegradation of toxicant by microbes in soil and sediment. Identifying biodegradative microorganisms is an important step in designing and analyzing soil bioremediation. To remove non-important noise information, it is necessary to selectively enrich genomes of biodegradative microorganisms fromnon-biodegradative populations. For this purpose, a stable isotope probing (SIP) technique was applied in selectively harvesting the genomes of biphenyl-utilizing bacteria from soil microbial communities. Since many biphenyl-using microorganisms are responsible for aerobic PCB degradation In soil and sediments, biphenyl-utilizing bacteria were chosen as the target organisms. In soil microcosms, 13C-biphenyl was added as a selective carbon source for biphenyl users, According to $13C-CO_2$ analysis by GC-MS, 13C-biphenyl mineralization was detected after a 7-day of incubation. The heavy portion of DNA(13C-DNA) was separated from the light portion of DNA (12C-DNA) using equilibrium density gradient ultracentrifuge. Bacterial community structure in the 13C-DNAsample was analyzed by t-RFLP (terminal restriction fragment length polymorphism) method. The t-RFLP result demonstates that the use of SIP efficiently and selectively enriched the genomes of biphenyl degrading bacteria from non-degradative microbes. Furthermore, the bacterial diversity of biphenyl degrading populations was small enough for environmental genomes tools (metagenomics and DNA microarrays) to be used to detect functional (biphenyl degradation) genes from soil microbial communities, which may provide a significant progress in assessing microbial capability of PCB bioremediation in soil and groundwater.

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