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Novel Syntrophic Isovalerate-Degrading Bacteria and Their Energetic Cooperation with Methanogens in Methanogenic Chemostats

Ya-Ting Chen, Yan Zeng, Jie Li, Xinyu Zhao, Yue Yi, Min Gou, Yoichi Kamagata, Takashi Narihiro, Masaru K. Nobu, Yue‐Qin Tang

2020Environmental Science & Technology37 citationsDOI

Abstract

Isovalerate is an important intermediate in anaerobic degradation of proteins/amino acids. Little is known about how this compound is degraded due to challenges in cultivation and characterization of isovalerate-degrading bacteria, which are thought to symbiotically depend on methanogenic archaea. In this study, we successfully enriched novel syntrophic isovalerate degraders (uncultivated Clostridiales and Syntrophaceae members) through operation of mesophilic and thermophilic isovalerate-fed anaerobic reactors. Metagenomics- and metatranscriptomics-based metabolic reconstruction of novel putative syntrophic isovalerate metabolizers uncovered the catabolic pathway and byproducts (i.e., acetate, H2, and formate) of isovalerate degradation, mechanisms for electron transduction from isovalerate degradation to H2 and formate generation (via electron transfer flavoprotein; ETF), and biosynthetic metabolism. The identified organisms tended to prefer formate-based interspecies electron transfer with methanogenic partners. The byproduct acetate was further converted to CH4 and CO2 by either Methanothrix (mesophilic) and Methanosarcina (thermophilic), which employed different approaches for acetate degradation. This study presents insights into novel mesophilic and thermophilic isovalerate degraders and their interactions with methanogens.

Topics & Concepts

IsovalerateMethanosarcinaMethanogenesisMesophileMicrobiologyMethanogenFormateBiologyStable-isotope probingThermophileBiochemistryCrenarchaeotaBacteriaChemistryArchaeaMicroorganismFermentationEnzymeGeneButyrateGeneticsCatalysisAnaerobic Digestion and Biogas ProductionMethane Hydrates and Related PhenomenaMicrobial Fuel Cells and Bioremediation