Formate-induced CO tolerance and methanogenesis inhibition in fermentation of syngas and plant biomass for carboxylate production

Flávio C F Baleeiro; Lukas Varchmin; Sabine Kleinsteuber; Heike Sträuber; Anke Neumann

doi:10.1186/s13068-023-02271-w

Formate-induced CO tolerance and methanogenesis inhibition in fermentation of syngas and plant biomass for carboxylate production

Biotechnol Biofuels Bioprod. 2023 Feb 17;16(1):26. doi: 10.1186/s13068-023-02271-w.

Authors

Flávio C F Baleeiro^{1

2}, Lukas Varchmin², Sabine Kleinsteuber¹, Heike Sträuber¹, Anke Neumann³

Affiliations

¹ Department of Environmental Microbiology, Helmholtz Centre for Environmental Research - UFZ, Leipzig, Germany.
² Technical Biology, Institute of Process Engineering in Life Science, Karlsruhe Institute of Technology - KIT, Karlsruhe, Germany.
³ Technical Biology, Institute of Process Engineering in Life Science, Karlsruhe Institute of Technology - KIT, Karlsruhe, Germany. anke.neumann@kit.edu.

Abstract

Background: Production of monocarboxylates using microbial communities is highly dependent on local and degradable biomass feedstocks. Syngas or different mixtures of H₂, CO, and CO₂ can be sourced from biomass gasification, excess renewable electricity, industrial off-gases, and carbon capture plants and co-fed to a fermenter to alleviate dependence on local biomass. To understand the effects of adding these gases during anaerobic fermentation of plant biomass, a series of batch experiments was carried out with different syngas compositions and corn silage (pH 6.0, 32 °C).

Results: Co-fermentation of syngas with corn silage increased the overall carboxylate yield per gram of volatile solids (VS) by up to 29% (0.47 ± 0.07 g g_VS^-1; in comparison to 0.37 ± 0.02 g g_VS^-1 with a N₂/CO₂ headspace), despite slowing down biomass degradation. Ethylene and CO exerted a synergistic effect in preventing methanogenesis, leading to net carbon fixation. Less than 12% of the electrons were misrouted to CH₄ when either 15 kPa CO or 5 kPa CO + 1.5 kPa ethylene was used. CO increased the selectivity to acetate and propionate, which accounted for 85% (electron equivalents) of all products at 49 kPa CO, by favoring lactic acid bacteria and actinobacteria over n-butyrate and n-caproate producers. Inhibition of n-butyrate and n-caproate production by CO happened even when an inoculum preacclimatized to syngas and lactate was used. Intriguingly, the effect of CO on n-butyrate and n-caproate production was reversed when formate was present in the broth.

Conclusions: The concept of co-fermenting syngas and plant biomass shows promise in three aspects: by making anaerobic fermentation a carbon-fixing process, by increasing the yields of short-chain carboxylates (propionate and acetate), and by minimizing electron losses to CH₄. Moreover, a model was proposed for how formate can alleviate CO inhibition in certain acidogenic bacteria. Testing the fermentation of syngas and plant biomass in a continuous process could potentially improve selectivity to n-butyrate and n-caproate by enriching chain-elongating bacteria adapted to CO and complex biomass.

Keywords: Carbon monoxide; Chain elongation; Ethene; Formic acid; Hexanoic acid; Lactic acid bacteria; Medium-chain carboxylic acids; Microbiome; Mixotrophy; Volatile fatty acids.

Abstract

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