Novel quantitative method for individual isotopomer of organic acids from 13C tracer experiments determines carbon flow in acetogenesis

Abstract

Anaerobic microbial acetogenesis is ubiquitous on Earth, and thus plays an important role in the global carbon cycle. The mechanism of carbon fixation in acetogens has attracted great interest from various studies for combatting climate change, and even for studying ancient metabolic pathways. Here, we developed a new, simple method for investigating carbon flows in the metabolic reaction of acetogen by conveniently and accurately determining the relative abundance of individual acetate- and/or formate-isotopomers formed in 13C labeling experiments. We measured the underivatized analyte by gas chromatography-mass spectrometry (GC-MS) coupled with a direct aqueous sample injection technique. The individual abundance of analyte isotopomers was calculated by the mass spectrum analysis using the least-squares approach. The validity of the method was demonstrated by determining known mixtures of unlabeled and 13C-labeled analytes. The developed method was applied to study the carbon fixation mechanism of the well-known acetogen Acetobacterium woodii grown on methanol and bicarbonate. We provided a quantitative reaction model for methanol metabolism of A. woodii, which indicated that methanol was not the sole carbon precursor of the acetate methyl group and that 20−22% of the methyl group was formed from CO2. In contrast, the carboxyl group of acetate appeared to form exclusively by CO2 fixation. Thus, our simple method, without laborious analytical procedures, has broad utility for the study of biochemical and chemical processes related to acetogenesis on Earth.