Castaño Ana, Prosenkov Alexander, Baragaño Diego, Otaegui Nerea, Sastre Herminio, Rodríguez-Valdés Eduardo, Gallego José Luis R, Peláez Ana Isabel
Area of Microbiology, Department of Functional Biology and Environmental Biogeochemistry and Raw Materials Group, University of Oviedo, Oviedo, Spain.
INDUROT and Environmental Biogeochemistry and Raw Materials Group, Campus of Mieres, University of Oviedo, Mieres, Spain.
Front Microbiol. 2021 Mar 17;12:643589. doi: 10.3389/fmicb.2021.643589. eCollection 2021.
Nanoscale Zero-Valent Iron (nZVI) is a cost-effective nanomaterial that is widely used to remove a broad range of metal(loid)s and organic contaminants from soil and groundwater. In some cases, this material alters the taxonomic and functional composition of the bacterial communities present in these matrices; however, there is no conclusive data that can be generalized to all scenarios. Here we studied the effect of nZVI application on groundwater from the site of an abandoned fertilizer factory in Asturias, Spain, mainly polluted with arsenic (As). The geochemical characteristics of the water correspond to a microaerophilic and oligotrophic environment. Physico-chemical and microbiological (cultured and total bacterial diversity) parameters were monitored before and after nZVI application over six months. nZVI treatment led to a marked increase in Fe(II) concentration and a notable fall in the oxidation-reduction potential during the first month of treatment. A substantial decrease in the concentration of As during the first days of treatment was observed, although strong fluctuations were subsequently detected in most of the wells throughout the six-month experiment. The possible toxic effects of nZVI on groundwater bacteria could not be clearly determined from direct observation of those bacteria after staining with viability dyes. The number of cultured bacteria increased during the first two weeks of the treatment, although this was followed by a continuous decrease for the following two weeks, reaching levels moderately below the initial number at the end of sampling, and by changes in their taxonomic composition. Most bacteria were tolerant to high As(V) concentrations and showed the presence of diverse As resistance genes. A more complete study of the structure and diversity of the bacterial community in the groundwater using automated ribosomal intergenic spacer analysis (ARISA) and sequencing of the 16S rRNA amplicons by Illumina confirmed significant alterations in its composition, with a reduction in richness and diversity (the latter evidenced by Illumina data) after treatment with nZVI. The anaerobic conditions stimulated by treatment favored the development of sulfate-reducing bacteria, thereby opening up the possibility to achieve more efficient removal of As.
纳米零价铁(nZVI)是一种具有成本效益的纳米材料,被广泛用于从土壤和地下水中去除多种金属(类金属)和有机污染物。在某些情况下,这种材料会改变这些基质中细菌群落的分类和功能组成;然而,尚无可以推广到所有情况的确凿数据。在此,我们研究了在西班牙阿斯图里亚斯一家废弃化肥厂场地的地下水中应用nZVI的效果,该地下水主要受砷(As)污染。该水体的地球化学特征对应于微需氧和贫营养环境。在应用nZVI前后的六个月内监测了物理化学和微生物学(培养的和总的细菌多样性)参数。nZVI处理在处理的第一个月导致Fe(II)浓度显著增加,氧化还原电位显著下降。在处理的头几天观察到As浓度大幅下降,尽管在整个六个月的实验中,随后在大多数井中检测到强烈波动。在用活力染料染色后直接观察这些细菌,无法明确确定nZVI对地下水中细菌的可能毒性作用。在处理的前两周培养细菌的数量增加,尽管在接下来的两周中持续下降,在采样结束时达到略低于初始数量的水平,并且其分类组成也发生了变化。大多数细菌对高浓度的As(V)具有耐受性,并显示出多种抗砷基因的存在。使用自动核糖体基因间隔区分析(ARISA)和Illumina对16S rRNA扩增子进行测序,对地下水中细菌群落的结构和多样性进行了更全面的研究,证实其组成发生了显著变化,在用nZVI处理后丰富度和多样性降低(Illumina数据证明了后者)。处理刺激产生的厌氧条件有利于硫酸盐还原菌的生长,从而为实现更高效的砷去除开辟了可能性。
