Joyce Aoife, Ijaz Umer Z, Nzeteu Corine, Vaughan Aoife, Shirran Sally L, Botting Catherine H, Quince Christopher, O'Flaherty Vincent, Abram Florence
Functional Environmental Microbiology, School of Natural Sciences, National University of Ireland Galway, Galway, Ireland.
Environmental Omics Laboratory, School of Engineering, University of Glasgow, Glasgow, United Kingdom.
Front Microbiol. 2018 Mar 21;9:540. doi: 10.3389/fmicb.2018.00540. eCollection 2018.
Harvesting valuable bioproducts from various renewable feedstocks is necessary for the critical development of a sustainable bioeconomy. Anaerobic digestion is a well-established technology for the conversion of wastewater and solid feedstocks to energy with the additional potential for production of process intermediates of high market values (e.g., carboxylates). In recent years, first-generation biofuels typically derived from food crops have been widely utilized as a renewable source of energy. The environmental and socioeconomic limitations of such strategy, however, have led to the development of second-generation biofuels utilizing, amongst other feedstocks, lignocellulosic biomass. In this context, the anaerobic digestion of perennial grass holds great promise for the conversion of sustainable renewable feedstock to energy and other process intermediates. The advancement of this technology however, and its implementation for industrial applications, relies on a greater understanding of the microbiome underpinning the process. To this end, microbial communities recovered from replicated anaerobic bioreactors digesting grass were analyzed. The bioreactors leachates were not buffered and acidic pH (between 5.5 and 6.3) prevailed at the time of sampling as a result of microbial activities. Community composition and transcriptionally active taxa were examined using 16S rRNA sequencing and microbial functions were investigated using metaproteomics. Bioreactor fraction, i.e., grass or leachate, was found to be the main discriminator of community analysis across the three molecular level of investigation (DNA, RNA, and proteins). Six taxa, namely Bacteroidia, Betaproteobacteria, Clostridia, Gammaproteobacteria, Methanomicrobia, and Negativicutes accounted for the large majority of the three datasets. The initial stages of grass hydrolysis were carried out by Bacteroidia, Gammaproteobacteria, and Negativicutes in the grass biofilms, in addition to Clostridia in the bioreactor leachates. Numerous glycolytic enzymes and carbohydrate transporters were detected throughout the bioreactors in addition to proteins involved in butanol and lactate production. Finally, evidence of the prevalence of stressful conditions within the bioreactors and particularly impacting Clostridia was observed in the metaproteomes. Taken together, this study highlights the functional importance of Clostridia during the anaerobic digestion of grass and thus research avenues allowing members of this taxon to thrive should be explored.
从各种可再生原料中获取有价值的生物产品对于可持续生物经济的关键发展至关重要。厌氧消化是一种成熟的技术,可将废水和固体原料转化为能源,还具有生产高市场价值的工艺中间体(如羧酸盐)的额外潜力。近年来,通常源自粮食作物的第一代生物燃料已被广泛用作可再生能源。然而,这种策略在环境和社会经济方面的局限性导致了第二代生物燃料的发展,其中包括利用木质纤维素生物质等原料。在这种背景下,多年生草的厌氧消化对于将可持续可再生原料转化为能源和其他工艺中间体具有巨大潜力。然而,这项技术的进步及其在工业应用中的实施依赖于对支撑该过程的微生物群落有更深入的了解。为此,对从消化草的重复厌氧生物反应器中回收的微生物群落进行了分析。生物反应器渗滤液未进行缓冲,由于微生物活动,采样时呈现酸性pH值(介于5.5和6.3之间)。使用16S rRNA测序检查群落组成和转录活性分类群,并使用元蛋白质组学研究微生物功能。在三个分子水平(DNA、RNA和蛋白质)的研究中,生物反应器部分(即草或渗滤液)被发现是群落分析的主要区分因素。六个分类群,即拟杆菌纲、β-变形菌纲、梭菌纲、γ-变形菌纲、甲烷微菌纲和厌氧球菌纲占了这三个数据集的绝大部分。草水解的初始阶段由草生物膜中的拟杆菌纲、γ-变形菌纲和厌氧球菌纲进行,生物反应器渗滤液中的梭菌纲也参与其中。除了参与丁醇和乳酸生产的蛋白质外,在整个生物反应器中还检测到许多糖酵解酶和碳水化合物转运蛋白。最后,在元蛋白质组中观察到生物反应器内存在应激条件的证据,特别是对梭菌纲有影响。综上所述,本研究强调了梭菌纲在草厌氧消化过程中的功能重要性,因此应探索使该分类群成员茁壮成长的研究途径。
