Potential contribution of acetogenesis to anaerobic degradation in methanogenic rice field soils

Bo Fu, Ralf Conrad, Martin Blaser.                                         全文下载

School of Environmental and Civil Engineering, Jiangsu Key Laboratory of Anaerobic Biotechnology, Jiangnan University, Wuxi 214122, China

Department of Biogeochemistry, Max Planck Institute for Terrestrial Microbiology, Marburg, Germany

ABSTRACT:Acetate is an important intermediate in the anaerobic degradation of organic matter. It is not only produced by fermentation but also by the reduction of CO₂ via the acetyl-CoA pathway (acetogenesis). However, the interplay of this process in methanogenic rice field soils is not fully understood. Chemolithotrophic acetogenesis results in a rather strong depletion of the ¹³C of acetate. Therefore, we measured the δ ¹³C of acetate, CO₂ and CH₄ that were produced during methanogenic degradation of organic matter in rice paddy soils from two geographical origins (Philippines and Italy) and used three different strategies to estimate the contribution of acetogenesis to acetate formation: (1) Incubation of soil slurries under elevated concentrations of H₂ /CO₂ to specifically activate the H₂ -dependent communities; (2) incubation at three different temperatures (15, 30, 50 °C) to shift the conditions for H₂ consumption; (3) incubation in the presence of inhibitors presumed to inhibit acetogenesis (KCN) or methanogenesis (BES). Only incubations under elevated H₂ /CO₂ resulted in ¹³C-depleted acetate (δ ¹³C of −68 to −65‰) compared to the control (δ ¹³C of −25‰). Temperature and presence of inhibitors also affected the δ ¹³C of acetate, CO₂ and/or CH₄ , but δ ¹³C of acetate was never as low as after addition H₂ /CO₂ . A significant ¹³C enrichment of acetate at 15 °C in presence of BES and KCN indicated that H₂ -dependent acetogenesis is a favoured process at low temperature. Copy numbers in the Philippine soil of the fhs gene coding for the formyl-tetrahydrofolate synthetase of the acetyl-CoA pathway were on a similar order of magnitude (10⁶ per gram dry soil) irrespectively of the different incubation conditions. Our results indicate that chemolithotrophic acetogenesis was operative in methanogenic rice soil at 15 °C but was more important at elevated H₂ /CO₂ concentrations.

KEYWORDS:Acetate; Acetogenesis;Carbon isotope; Full-scale; Temperature;Rice soil

JOURNAL:Soil Biology and Biochemistry

SOURCE:Elsevierjournal

DOI:10.1016/j.soilbio.2017.10.034

YEAR:2018

PAGES:1-10