Methanogenesis Recovery Mechanism Under Extreme Acidic Stress in Failed Solid-State Anaerobic Digestion System of Maize Straw

IF 3 3区工程技术 Q3 ENERGY & FUELS

BioEnergy Research Pub Date : 2025-06-26 DOI:10.1007/s12155-025-10862-8

Mengyi Wang, Hongyi Lyu, Wenjin Zhao, Hui Wang, Fei Li, Jing Chen, Caiyun Yang, Yiqing Yao

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Abstract

Volatile fatty acid accumulation may cause inhibition, or complete cessation of methanogenesis, which was undesirable for large-scale anaerobic digestion (AD) engineering. In this study, it was unexpectedly observed that methanogenesis gradually resumed after a long period of time when gas production had stopped due to acid inhibition in maize straw solid-state (SS)-AD. The results showed SS-AD achieved the cumulative methane production of 9.32 mL/gVS and maintained the acetic acid degradation rate at 70.8%–88.8% within 8 days of methanogenesis recovery. 16S rRNA amplicon sequencing and metagenomic analysis revealed that Thermoclostridium, Defluviitalea, and Hydrogenispora were the key bacteria resisting extreme acidic stress, while Methanosarcina mazei, Methanoculleus thermophilus, and Methanosarcina thermophila were the key archaea promoting methanogenesis recovery. Microorganisms survived under extreme acidic stress mainly by lysine decarboxylation and biosynthesis of cell membranes/walls and flagella. Meanwhile, enhanced tryptophan synthesis and metabolism accelerated carbon supply to TCA cycle, promoting the growth and reproduction of microorganisms under extreme acidic stress. Moreover, the genetic information processing ability and CRISPR-Cas system were enhanced in M. mazei and M. thermophila, which favored their survival and growth in SS-AD. M. thermophilus mainly contributed to the methanogenesis by CO₂ reduction. This study helps in developing SS-AD methodology for overcoming extreme acidic stress.

Graphical Abstract

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玉米秸秆固态厌氧消化系统在极端酸性胁迫下的产甲烷恢复机制

挥发性脂肪酸积累可能导致甲烷生成的抑制或完全停止，这是大规模厌氧消化（AD）工程所不希望的。在本研究中，出乎意料地发现，由于玉米秸秆固态(SS)-AD的抑酸作用，产气停止了很长一段时间后，甲烷生成又逐渐恢复。结果表明，SS-AD的累积产甲烷量为9.32 mL/gVS，在产甲烷恢复的8天内，乙酸降解率保持在70.8% ~ 88.8%。16S rRNA扩增子测序和宏基因组分析表明，热梭菌、Defluviitalea和Hydrogenispora是抵抗极端酸性胁迫的关键菌，而mazei、Methanoculleus thermoophilus和Methanosarcina thermoophila是促进产甲烷恢复的关键古菌。微生物在极端酸性胁迫下的生存主要依靠赖氨酸脱羧和细胞膜/细胞壁和鞭毛的生物合成。同时，色氨酸合成和代谢的增强加速了TCA循环的碳供应，促进了极端酸性胁迫下微生物的生长和繁殖。此外，mazei和M. thermophila的遗传信息处理能力和CRISPR-Cas系统增强，有利于它们在SS-AD中的生存和生长。嗜热分枝杆菌主要通过CO2还原作用生成甲烷。该研究有助于开发克服极端酸性胁迫的SS-AD方法。图形抽象

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来源期刊

BioEnergy Research ENERGY & FUELS-ENVIRONMENTAL SCIENCES

CiteScore

6.70

自引率

8.30%

发文量

174

审稿时长

3 months

期刊介绍： BioEnergy Research fills a void in the rapidly growing area of feedstock biology research related to biomass, biofuels, and bioenergy. The journal publishes a wide range of articles, including peer-reviewed scientific research, reviews, perspectives and commentary, industry news, and government policy updates. Its coverage brings together a uniquely broad combination of disciplines with a common focus on feedstock biology and science, related to biomass, biofeedstock, and bioenergy production.