Elucidating Key Microbial Drivers for Methane Production during Cold Adaptation and Psychrophilic Anaerobic Digestion of Cattle Manure and Food Waste

Haripriya Rama, B. Ndaba, M. Dhlamini, Nicolene M. Cochrane, Malik Maaza, A. Roopnarain
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Abstract

At psychrophilic temperatures (<20 °C), anaerobic digestion produces less methane (CH4). For psychrophilic anaerobic digestion (PAD) to be successful, investigation of cold-adapted microbial consortia involved in methane production is critical. This study aimed to investigate the microbial community driving enhanced methane production from the cold-adaptation process and bioaugmentation of PAD with cold-adapted inoculum (BI). Microbial consortia in cattle manure (CM) and food waste (FW) were adapted and applied during batch PAD of CM and FW to bioaugment methane production at 15 °C. Cold adaptation and PAD with BI resulted in cumulative specific methane yields of 0.874 ± 0.231 and 0.552 ± 0.089 L CH4 g−1 volatile solids, respectively, after 14 weeks, while the absence of BI (control) led to acidification and no methane production during PAD. Following 16S rRNA V4–V5 amplicon sequencing and metagenomic analyses, Methanosarcina was revealed as a key driver of methanogenesis during cold adaptation and PAD bioaugmentation. Furthermore, based on the predictive functional and metabolic analysis of the communities, possible synergies were proposed in terms of substrate production and utilization by the dominant microbial groups. For instance, during methane production, Bacteroides and Methanobrevibacter were possibly involved in a syntrophic relationship, which promoted methanogenesis by Methanosarcina. These findings provide insight into the prospective microbial synergies that can be harnessed and/or regulated in cold-adapted inoculum for the improvement of methane production during PAD.
阐明牛粪和厨余在适应寒冷和心理亲水厌氧消化过程中产生甲烷的关键微生物驱动因素
在心理亲水温度(<20 °C)下,厌氧消化产生的甲烷(CH4)较少。要使心理亲水厌氧消化(PAD)取得成功,对参与甲烷生产的低温适应性微生物群落进行调查至关重要。本研究的目的是调查微生物群落在冷适应过程中提高甲烷产量的驱动力,以及利用冷适应接种物(BI)对 PAD 进行生物增殖。在对牛粪(CM)和厨余(FW)进行批量 PAD 的过程中,对牛粪(CM)和厨余(FW)中的微生物群落进行了改造和应用,以便在 15 °C 下对甲烷产量进行生物增产。冷适应和使用 BI 的 PAD 在 14 周后分别产生了 0.874 ± 0.231 和 0.552 ± 0.089 L CH4 g-1 挥发性固体,而不使用 BI(对照组)则导致酸化和 PAD 期间无甲烷产生。通过 16S rRNA V4-V5 扩增子测序和元基因组分析,发现 Methanosarcina 是冷适应和 PAD 生物增殖过程中甲烷生成的关键驱动因素。此外,根据对群落的预测性功能和代谢分析,提出了优势微生物群在底物生产和利用方面可能存在的协同作用。例如,在甲烷生产过程中,Bacteroides 和 Methanobrevibacter 可能参与了合成营养关系,从而促进了 Methanosarcina 的甲烷生成。这些发现使人们深入了解了可在适应低温的接种物中利用和/或调节的微生物协同作用,以提高 PAD 期间的甲烷产量。
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