James Watt School of Engineering, Advanced Research Centre (ARC), University of Glasgow, Chapel Lane, Glasgow G11 6EW, UK.
The Lyell Centre, Heriot-Watt University, Research Avenue South, Edinburgh EH14 4AS, UK.
Water Res. 2024 Sep 15;262:122053. doi: 10.1016/j.watres.2024.122053. Epub 2024 Jul 5.
Biofiltration is a low-cost, low-energy technology that employs a biologically activated bed of porous medium to reduce the biodegradable fraction of the dissolved organic matter (DOM) pool in source water, resulting in the production of drinking water. Microbial communities at different bed depths within the biofilter play crucial roles in the degradation and removal of dissolved organic carbon (DOC), ultimately impacting its performance. However, the relationships between the composition of microbial communities inhabiting different biofilter depths and their utilisation of various DOC fractions remain poorly understood. To address this knowledge gap, we conducted an experimental study where microbial communities from the upper (i.e., top 10 cm) and lower (i.e., bottom 10 cm) sections of a 30-cm long laboratory-scale biofilter were recovered. These communities were then individually incubated for 10 days using the same source water as the biofilter influent. Our study revealed that the bottom microbial community exhibited lower diversity yet had a co-occurrence network with a higher degree of interconnections among its members compared to the top microbial community. Moreover, we established a direct correlation between the composition and network structure of the microbial communities and their ability to utilise various DOM compounds within a DOM pool. Interestingly, although the bottom microbial community had only 20 % of the total cell abundance compared to the top community at the beginning of the incubation, it utilised and hence removed approximately 60 % more total DOC from the DOM pool than the top community. While both communities rapidly utilised labile carbon fractions, such as low-molecular-weight neutrals, the utilisation of more refractory carbon fractions, like high-molecular-weight humic substances with an average molecular weight of more than ca. 1451 g/mol, was exclusive to the bottom microbial community. By employing techniques that capture microbial diversity (i.e., flow cytometry and 16S rRNA amplicon sequencing) and considering the complexities of DOM (i.e., LCOCD), our study provides novel insights into how microbial community structure could influence the microbial-mediated processes of engineering significance in drinking water production. Finally, our findings could offer the opportunity to improve biofilter performances via engineering interventions that shape the compositions of biofilter microbial communities and enhance their utilisation and removal of DOM, most notably the more classically humified and refractory DOM compound groups.
生物过滤是一种低成本、低能耗的技术,它采用多孔介质生物活性床来降低水源中可生物降解的溶解有机物 (DOM) 池的比例,从而生产饮用水。生物滤床内不同深度的微生物群落对溶解有机碳 (DOC) 的降解和去除起着至关重要的作用,最终影响其性能。然而,栖息在不同生物滤床深度的微生物群落的组成与其对各种 DOC 分数的利用之间的关系仍知之甚少。为了解决这一知识空白,我们进行了一项实验研究,从 30 厘米长的实验室规模生物滤床的上部(即顶部 10 厘米)和下部(即底部 10 厘米)回收微生物群落。然后,将这些群落分别在与生物滤床进水相同的条件下单独培养 10 天。我们的研究表明,与上部微生物群落相比,下部微生物群落的多样性较低,但成员之间的共生网络具有更高的连接度。此外,我们建立了微生物群落的组成和网络结构与其在 DOM 池内利用各种 DOM 化合物的能力之间的直接相关性。有趣的是,尽管下部微生物群落的总细胞丰度仅为上部群落的 20%,但它从 DOM 池中利用和去除的总 DOC 比上部群落多约 60%。虽然两个群落都迅速利用了易生物降解的碳分数,如低分子量中性物,但对更难生物降解的碳分数的利用,如平均分子量超过约 1451 克/摩尔的高分子量腐殖质物质,仅限于下部微生物群落。通过采用捕捉微生物多样性的技术(即流式细胞术和 16S rRNA 扩增子测序)并考虑 DOM 的复杂性(即 LCOCD),我们的研究提供了新的见解,即微生物群落结构如何影响工程意义上的微生物介导的饮用水生产过程。最后,我们的发现为通过工程干预来改善生物滤床性能提供了机会,这些干预措施可以改变生物滤床微生物群落的组成,并增强它们对 DOM 的利用和去除,尤其是更经典的类腐殖质和难生物降解的 DOM 化合物。
