通过RNA的比较稳定同位素探测法鉴定缺氧稻田土壤中产甲烷条件下的乙酸同化微生物。
Identification of acetate-assimilating microorganisms under methanogenic conditions in anoxic rice field soil by comparative stable isotope probing of RNA.
作者信息
Hori Tomoyuki, Noll Matthias, Igarashi Yasuo, Friedrich Michael W, Conrad Ralf
机构信息
Max Planck Institute for Terrestrial Microbiology, Karl-von-Frisch-Strasse, D-35043 Marburg, Germany.
出版信息
Appl Environ Microbiol. 2007 Jan;73(1):101-9. doi: 10.1128/AEM.01676-06. Epub 2006 Oct 27.
Acetate is the most abundant intermediate of organic matter degradation in anoxic rice field soil and is converted to CH(4) and/or CO(2). Aceticlastic methanogens are the primary microorganisms dissimilating acetate in the absence of sulfate and reducible ferric iron. In contrast, very little is known about bacteria capable of assimilating acetate under methanogenic conditions. Here, we identified active acetate-assimilating microorganisms by using a combined approach of frequent label application at a low concentration and comparative RNA-stable isotope probing with (13)C-labeled and unlabeled acetate. Rice field soil was incubated anaerobically at 25 degrees C for 12 days, during which (13)C-labeled acetate was added at a concentration of 500 muM every 3 days. (13)C-labeled CH(4) and CO(2) were produced from the beginning of the incubation and accounted for about 60% of the supplied acetate (13)C. RNA was extracted from the cells in each sample taken and separated by isopycnic centrifugation according to molecular weight. Bacterial and archaeal populations in each density fraction were screened by reverse transcription-PCR-mediated terminal restriction fragment polymorphism analysis. No differences in the bacterial populations were observed throughout the density fractions of the unlabeled treatment. However, in the heavy fractions of the (13)C treatment, terminal restriction fragments (T-RFs) of 161 bp and 129 bp in length predominated. These T-RFs were identified by cloning and sequencing of 16S rRNA as from a Geobacter sp. and an Anaeromyxobacter sp., respectively. Apparently these bacteria, which are known as dissimilatory iron reducers, were able to assimilate acetate under methanogenic conditions, i.e., when CO(2) was the predominant electron acceptor. We hypothesize that ferric iron minerals with low bioavailability might have served as electron acceptors for Geobacter spp. and Anaeromyxobacter spp. under these conditions.
乙酸盐是缺氧稻田土壤中有机质降解最丰富的中间产物,可转化为CH₄和/或CO₂。乙酸裂解产甲烷菌是在没有硫酸盐和可还原铁离子的情况下异化乙酸盐的主要微生物。相比之下,对于在产甲烷条件下能够同化乙酸盐的细菌了解甚少。在此,我们通过采用低浓度频繁标记应用以及用¹³C标记和未标记乙酸盐进行比较RNA稳定同位素探测的联合方法,鉴定了活跃的乙酸盐同化微生物。稻田土壤在25℃下厌氧培养12天,在此期间每3天添加浓度为500μM的¹³C标记乙酸盐。从培养开始就产生了¹³C标记的CH₄和CO₂,约占供应乙酸盐¹³C的60%。从每个采集的样品中提取细胞RNA,并根据分子量通过等密度离心进行分离。通过逆转录-PCR介导的末端限制性片段长度多态性分析筛选每个密度级分中的细菌和古菌群体。在未标记处理的整个密度级分中未观察到细菌群体的差异。然而,在¹³C处理的重级分中,长度为161bp和129bp的末端限制性片段(T-RFs)占主导。通过对16S rRNA进行克隆和测序,分别将这些T-RFs鉴定为来自地杆菌属和厌氧粘细菌属。显然,这些已知为异化铁还原菌的细菌能够在产甲烷条件下,即当CO₂是主要电子受体时同化乙酸盐。我们推测,在这些条件下,生物可利用性低的铁矿物可能作为地杆菌属和厌氧粘细菌属的电子受体。
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