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佛罗里达州西南部富营养化和贫营养化淡水环境中外源 DNA 的周转率。

Turnover of extracellular DNA in eutrophic and oligotrophic freshwater environments of southwest Florida.

机构信息

Department of Marine Science, University of South Florida, St. Petersburg, Florida 33701-5016.

出版信息

Appl Environ Microbiol. 1989 Jul;55(7):1823-8. doi: 10.1128/aem.55.7.1823-1828.1989.

DOI:10.1128/aem.55.7.1823-1828.1989
PMID:16347976
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC202957/
Abstract

The turnover of extracellular DNA was investigated in oligotrophic springs of the Crystal River and the eutrophic Medard Reservoir of southwest Florida. The Medard Reservoir possessed large populations of bacterioplankton and phytoplankton (6.8 x 10 cells per liter and 28.6 mug of chlorophyll a per liter, respectively), while the Crystal River springs only contained a fraction of the microbial biomass found in the Medard Reservoir. Although dissolved DNA values were greater in the Medard Reservoir, higher rates of DNA removal resulted in similar extracellular DNA turnover times in both environments (9.62 +/- 3.6 h in the Crystal River and 10.5 +/- 2.1 h in the Medard Reservoir). These results indicate that regardless of trophic status or microbial standing stock, extracellular DNA turns over rapidly in subtropical planktonic freshwater environments. Therefore, recombinant DNA sequences from released genetically engineered microorganisms might not be expected to survive for long periods of time in freshwater planktonic environments.

摘要

研究了佛罗里达州西南部贫营养性水晶河泉和富营养性梅达德水库的细胞外 DNA 周转率。梅达德水库拥有大量的细菌浮游生物和浮游植物(分别为每升 6.8×10 个细胞和每升 28.6 微克叶绿素 a),而水晶河泉中的微生物生物量仅为梅达德水库的一小部分。尽管梅达德水库中的溶解 DNA 值较高,但较高的 DNA 去除率导致两种环境中的细胞外 DNA 周转率相似(水晶河泉为 9.62±3.6 小时,梅达德水库为 10.5±2.1 小时)。这些结果表明,无论营养状态或微生物现存量如何,亚热带浮游淡水环境中的细胞外 DNA 都会迅速周转。因此,释放的基因工程微生物中的重组 DNA 序列预计不会在淡水浮游环境中存活很长时间。

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