Chemical, Biological and Environmental Engineering, Oregon State University , Corvallis, Oregon 97331, United States.
Environ Sci Technol. 2017 Feb 7;51(3):1635-1642. doi: 10.1021/acs.est.6b05050. Epub 2017 Jan 17.
In anoxic groundwater aquifers, the long-term survival of Dehalococcoides mccartyi populations expressing the gene vcrA (or bvcA) encoding reductive vinyl chloride dehalogenases are important to achieve complete dechlorination of tetrachloroethene (PCE) and trichloroethene (TCE) to nonchlorinated ethene. The absence or inactivity of vcrA-containing Dehalococcoides results in the accumulation of the harmful chlorinated intermediates dichloroethene (DCE) and vinyl chloride (VC). Although vcrA-containing Dehalococcoides subpopulations depend on synergistic interaction with other organohalide-respiring populations generating their metabolic electron acceptors (DCE and VC), their survival requires successful competition for electron donor within the entire organohalide-respiring microbial community. To understand this dualism of synergy and competition under growth conditions relevant in contaminated aquifers, we investigated Dehalococcoides-level population structure when subjected to a change in the ratio of electron donor to chlorinated electron acceptor in continuously stirred tank reactors (CSTRs) operated over 7 years. When the electron donor formate was supplied in stoichiometric excess to TCE, both tceA-containing and vcrA-containing Dehalococcoides populations persisted, and near-complete dechlorination to ethene was stably maintained. When the electron donor formate was supplied at substoichiometric concentrations, the interactions between tceA-containing and vcrA-containing populations shifted toward direct competition for the same limiting catabolic electron donor substrate with subsequent niche exclusion of the vcrA-containing population. After more than 2000 days of operation under electron donor limitation, increasing the electron donor to TCE ratio facilitated a recovery of the vcrA-containing Dehalococoides population to its original frequency. We demonstrate that electron donor scarcity alone, in the absence of competing metabolic processes or inhibitory dechlorination intermediate products, is sufficient to alter the Dehalococcoides population structure. These results underscore the importance of electron donor and chloroethene stoichiometry in maintaining balanced functional performance within consortia composed of multiple D. mccartyi subpopulations, even when other competing electron acceptor processes are absent.
在缺氧地下水含水层中,表达编码还原型氯乙烯脱卤酶基因 vcrA(或 bvcA)的 Dehalococcoides mccartyi 种群的长期存活对于完全脱氯四氯乙烯 (PCE) 和三氯乙烯 (TCE) 至关重要,以生成非氯化的乙烯。缺乏或无活性的 vcrA 含量 Dehalococcoides 会导致有害的氯代中间体二氯乙烯 (DCE) 和氯乙烯 (VC) 的积累。尽管含有 vcrA 的 Dehalococcoides 亚群依赖于与产生代谢电子受体 (DCE 和 VC) 的其他有机卤化物呼吸种群的协同相互作用,但它们的生存需要在整个有机卤化物呼吸微生物群落中成功竞争电子供体。为了在受污染含水层中相关的生长条件下理解这种协同作用和竞争的双重性,我们研究了当连续搅拌罐反应器 (CSTR) 中电子供体与氯化电子受体的比例发生变化时,Dehalococcoides 水平的种群结构在 7 年的时间里。当电子供体甲酸钠以化学计量过量供应给 TCE 时,含 tceA 和 vcrA 的 Dehalococcoides 种群都得以维持,并且接近完全脱氯至乙烯稳定维持。当电子供体甲酸钠以亚化学计量浓度供应时,含 tceA 和 vcrA 的种群之间的相互作用转向直接竞争相同的限制代谢电子供体底物,随后含 vcrA 的种群被排斥。在电子供体受限条件下运行超过 2000 天后,增加电子供体与 TCE 的比例有助于 vcrA 含量 Dehalococoides 种群恢复到原始频率。我们证明,仅电子供体缺乏,而没有竞争代谢过程或抑制脱氯中间产物,足以改变 Dehalococcoides 种群结构。这些结果强调了电子供体和氯代乙稀的化学计量在维持由多个 D. mccartyi 亚群组成的群落的平衡功能性能中的重要性,即使其他竞争的电子受体过程不存在也是如此。
