Department of Microbiology, North Carolina State University, Raleigh, NC 27695, USA.
Biodegradation. 2011 Sep;22(5):961-72. doi: 10.1007/s10532-011-9455-3. Epub 2011 Feb 1.
Biodegradation of the gasoline oxygenates methyl tertiary-butyl ether (MTBE) and ethyl tertiary-butyl ether (ETBE) can cause tertiary butyl alcohol (TBA) to accumulate in gasoline-impacted environments. One remediation option for TBA-contaminated groundwater involves oxygenated granulated activated carbon (GAC) reactors that have been self-inoculated by indigenous TBA-degrading microorganisms in ground water extracted from contaminated aquifers. Identification of these organisms is important for understanding the range of TBA-metabolizing organisms in nature and for determining whether self-inoculation of similar reactors is likely to occur at other sites. In this study (13)C-DNA-stable isotope probing (SIP) was used to identify TBA-utilizing organisms in samples of self-inoculated BioGAC reactors operated at sites in New York and California. Based on 16S rRNA nucleotide sequences, all TBA-utilizing organisms identified were members of the Burkholderiales order of the β-proteobacteria. Organisms similar to Cupriavidus and Methylibium were observed in both reactor samples while organisms similar to Polaromonas and Rhodoferax were unique to the reactor sample from New York. Organisms similar to Hydrogenophaga and Paucibacter strains were only detected in the reactor sample from California. We also analyzed our samples for the presence of several genes previously implicated in TBA oxidation by pure cultures of bacteria. Genes Mpe_B0532, B0541, B0555, and B0561 were all detected in (13)C-metagenomic DNA from both reactors and deduced amino acid sequences suggested these genes all encode highly conserved enzymes. One gene (Mpe_B0555) encodes a putative phthalate dioxygenase-like enzyme that may be particularly appropriate for determining the potential for TBA oxidation in contaminated environmental samples.
汽油中含氧化合物甲基叔丁基醚 (MTBE) 和乙基叔丁基醚 (ETBE) 的生物降解会导致叔丁醇 (TBA) 在受汽油影响的环境中积累。受 TBA 污染地下水的一种修复选择是采用含氧颗粒活性炭 (GAC) 反应器,该反应器由从受污染含水层中提取的地下水中的土著 TBA 降解微生物自行接种。这些生物体的鉴定对于了解自然界中 TBA 代谢生物体的范围以及确定是否可能在其他地点发生类似反应器的自我接种非常重要。在这项研究中,(13)C-DNA 稳定同位素探测 (SIP) 用于鉴定在纽约和加利福尼亚的自接种 BioGAC 反应器样品中利用 TBA 的生物体。根据 16S rRNA 核苷酸序列,鉴定出的所有利用 TBA 的生物体均为β-变形菌目伯克霍尔德氏菌的成员。在两个反应器样品中都观察到类似于 Cupriavidus 和 Methylibium 的生物体,而类似于 Polaromonas 和 Rhodoferax 的生物体则仅存在于来自纽约的反应器样品中。类似于 Hydrogenophaga 和 Paucibacter 菌株的生物体仅在来自加利福尼亚的反应器样品中检测到。我们还分析了我们的样品,以确定以前在细菌纯培养物中氧化 TBA 时涉及的几个基因的存在。基因 Mpe_B0532、B0541、B0555 和 B0561 均在两个反应器的(13)C 宏基因组 DNA 中检测到,推导的氨基酸序列表明这些基因均编码高度保守的酶。一个基因(Mpe_B0555)编码一种推测的邻苯二甲酸双加氧酶样酶,该酶可能特别适合于确定受污染环境样品中 TBA 氧化的潜力。
