Abstract

Understanding the dynamics of microbial community and metabolic pathways involved in methanogenesis during municipal solid waste (MSW) decomposition is crucial for effective methane (CH 4 ) management in landfills. This study investigated bacterial and methanogenic community composition, methanogenic metabolism, and their dynamics across typical phases of MSW decomposition-anaerobic acid phase, accelerated methanogenic phase, and decelerated methanogenic phase. Parallel bioreactors (A and B) were analyzed using metagenomics and natural stable carbon isotope analyses. CH 4 production kinetics for both reactors were accurately simulated by the Gompertz kinetic model (R 2 ​> ​0.98), Capturing key MSW decomposition phases characterized by variations in CH 4 production, pH, and volatile fatty acids (VFAs) concentrations. Concurrently, the methanogenic community transitioned from an initial dominance of acetoclastic methanogens Methanothrix in reactor A, and Methanothrix and Methanosarcina in reactor B to a co-dominance of hydrogenotrophic methanogens Methanobacterium and acetoclastic methanogens Methanothrix and Methanosarcina in both reactors. Acetate concentration and CH 4 yield were identified as primary factors shaping methanogen community structure. Acetoclastic methanogenesis remained the predominant pathway, accounting for 66.5–85.9 ​% of total methanogenesis modules., This dominance was supported by stable carbon isotope (α c constantly below 1.055 in both reactors) and metagenomic analyses, particularly the prevalence of acetate-metabolizing genes such as acetate kinase and acetyl-CoA synthetase . Despite substantial variability in microbial community composition, acetoclastic methanogenesis consistently dominated CH 4 production throughout MSW decomposition. These findings enhance understanding of methanogenesis in MSW landfills, supporting strategies to mitigate CH 4 emissions and address climate goals. • Acetate and methane yield shaped methanogen community structure. • Methanothrix and Methanosarcina competed for acetate. • Acetoclastic methanogenesis exhibited a strong correlation with acetate availability. • Acetoclastic methanogenesis predominated throughout the MSW decomposition.