Department of Civil and Environmental Engineering, Michigan State University, East Lansing, MI, USA.
Michigan State University, A135, 1449 Engineering Research Court, East Lansing, MI, 48824, USA.
Appl Microbiol Biotechnol. 2020 May;104(9):4155-4170. doi: 10.1007/s00253-020-10512-3. Epub 2020 Mar 13.
1,4-Dioxane, a probable human carcinogen, is a co-contaminant at many chlorinated solvent-contaminated sites. Although numerous 1,4-dioxane-degrading aerobic bacteria have been isolated, almost no information exists on the microorganisms able to degrade this chemical under anaerobic conditions. Here, the potential for 1,4-dioxane biodegradation was examined using multiple inocula and electron acceptor amendments. The inocula included uncontaminated agricultural soils and river sediments as well as sediments from two 1,4-dioxane contaminated sites. Five separate experiments involved the examination of triplicate live microcosms and abiotic controls for approximately 1 year. Compound-specific isotope analysis (CSIA) was used to further investigate biodegradation in a subset of the microcosms. Also, DNA was extracted from microcosms exhibiting 1,4-dioxane biodegradation for microbial community analysis using 16S rRNA gene amplicon high-throughput sequencing. Given the long incubation periods, it is likely that electron acceptor depletion occurred and methanogenic conditions eventually dominated. The iron/EDTA/humic acid or sulfate amendments did not result in 1,4-dioxane biodegradation in the majority of cases. 1,4-dioxane biodegradation was most commonly observed in the nitrate amended and no electron acceptor treatments. Notably, both contaminated site sediments illustrated removal in the samples compared to the abiotic controls in the no electron acceptor treatment. However, it is important to note that the degradation was slow (with concentration reductions occurring over approximately 1 year). In two of the three cases examined, CSIA provided additional evidence for 1,4-dioxane biodegradation. In one case, the reduction in 1,4-dioxane in the samples comparing the controls was likely too low for the method to detect a significant C/C enrichment. Further research is required to determine the value of measuring H/H for generating evidence for the biodegradation of this chemical. The microbial community analysis indicated that the phylotypes unclassified Comamonadaceae and 3 genus incertae sedis were more abundant in 1,4-dioxane-degrading microcosms compared to the live controls (no 1,4-dioxane) in microcosms inoculated with contaminated and uncontaminated sediment, respectively. The relative abundance of known 1,4-dioxane degraders was also investigated at the genus level. The soil microcosms were dominated primarily by Rhodanobacter with lower relative abundance values for Pseudomonas, Mycobacterium, and Acinetobacter. The sediment communities were dominated by Pseudomonas and Rhodanobacter. Overall, the current study indicates 1,4-dioxane biodegradation under anaerobic and, likely methanogenic conditions, is feasible. Therefore, natural attenuation may be an appropriate cleanup technology at sites where time is not a limitation.
1,4-二恶烷是一种可能的人类致癌物,是许多氯化溶剂污染场地的共污染物。尽管已经分离出许多 1,4-二恶烷降解好氧细菌,但几乎没有关于在厌氧条件下能够降解这种化学物质的微生物的信息。在这里,使用多种接种物和电子受体添加剂研究了 1,4-二恶烷生物降解的潜力。接种物包括未受污染的农业土壤和河流沉积物以及两个 1,4-二恶烷污染场地的沉积物。五个单独的实验涉及大约一年的时间对三个重复的活微宇宙和非生物对照进行检查。使用特定于化合物的同位素分析 (CSIA) 进一步研究了微宇宙中的一部分生物降解情况。此外,还从表现出 1,4-二恶烷生物降解的微宇宙中提取 DNA,用于使用 16S rRNA 基因扩增子高通量测序进行微生物群落分析。鉴于孵育时间较长,很可能电子受体耗尽,并且最终出现产甲烷条件。在大多数情况下,铁/EDTA/腐殖酸或硫酸盐添加剂并未导致 1,4-二恶烷生物降解。在硝酸盐添加和没有电子受体处理的情况下,1,4-二恶烷生物降解最常见。值得注意的是,与没有电子受体处理的非生物对照相比,在没有电子受体处理的情况下,两个污染场地的沉积物都表明去除了 1,4-二恶烷。然而,需要注意的是,降解速度较慢(浓度减少发生在大约一年的时间内)。在检查的三个案例中的两个中,CSIA 提供了 1,4-二恶烷生物降解的额外证据。在一种情况下,与对照相比,样品中 1,4-二恶烷的减少量太低,以至于该方法无法检测到明显的 C/C 富集。需要进一步研究来确定测量 H/H 的价值,以生成这种化学物质生物降解的证据。微生物群落分析表明,与未接种 1,4-二恶烷的活对照相比,未分类的 Comamonadaceae 和 3 个属未定种的拟杆菌在 1,4-二恶烷降解微宇宙中更为丰富,分别接种污染和未污染的沉积物。在属水平上还研究了已知 1,4-二恶烷降解菌的相对丰度。土壤微宇宙主要由 Rhodanobacter 主导,而 Pseudomonas、Mycobacterium 和 Acinetobacter 的相对丰度值较低。沉积物群落由 Pseudomonas 和 Rhodanobacter 主导。总体而言,目前的研究表明,在厌氧条件下,可能是产甲烷条件下,1,4-二恶烷的生物降解是可行的。因此,在时间不是限制因素的情况下,自然衰减可能是一种合适的清理技术。
