James Heffernan scite author profile

Acetogenic bacteria can convert waste gases into fuels and chemicals. Design of bioprocesses for waste carbon valorization requires quantification of steady-state carbon flows. Here, steady-state quantification of autotrophic chemostats containing Clostridium autoethanogenum grown on CO 2 and H 2 revealed that captured carbon (460 ± 80 mmol/gDCW/day) had a significant distribution to ethanol (54 ± 3 C-mol% with a 2.4 ± 0.3 g/L titer). We were impressed with this initial result, but also observed limitations to biomass concentration and growth rate. Metabolic modeling predicted culture performance and indicated significant metabolic adjustments when compared to fermentation with CO as the carbon source. Moreover, modeling highlighted flux to pyruvate, and subsequently reduced ferredoxin, as a target for improving CO 2 and H 2 fermentation. Supplementation with a small amount of CO enabled co-utilization with CO 2 , and enhanced CO 2 fermentation performance significantly, while maintaining an industrially relevant product profile. Additionally, the highest specific flux through the Wood-Ljungdahl pathway was observed during co-utilization of CO 2 and CO. Furthermore, the addition of CO led to superior CO 2-valorizing characteristics (9.7 ± 0.4 g/L ethanol with a 66 ± 2 C-mol% distribution, and 540 ± 20 mmol CO 2 /gDCW/day). Similar industrial processes are commercial or currently being scaled up, indicating CO-supplemented CO 2 and H 2 fermentation has high potential for sustainable fuel and chemical production. This work also provides a reference dataset to advance our understanding of CO 2 gas fermentation, which can contribute to mitigating climate change.

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Strategies to improve viability of a circular carbon bioeconomy-A techno-economic review of microbial electrosynthesis and gas fermentation

Wood

Grové

Marcellin

et al. 2021

Water Research

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Analytical tools for unravelling the metabolism of gas-fermenting Clostridia

Heffernan

Mahamkali

Valgepea

et al. 2022

Current Opinion in Biotechnology

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Transcriptional control of Clostridium autoethanogenum using CRISPRi

Fackler

Heffernan

Juminaga

et al. 2021

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Gas fermentation by Clostridium autoethanogenum is a commercial process for the sustainable biomanufacturing of fuels and valuable chemicals using abundant, low cost C1 feedstocks (CO and CO2) from sources such as inedible biomass, unsorted and non-recyclable municipal solid waste, and industrial emissions. Efforts towards pathway engineering and elucidation of gene function in this microbe have been limited by a lack of genetic tools to control gene expression and arduous genome engineering methods. To increase the pace of progress, here we developed an inducible CRISPR interference (CRISPRi) system for C. autoethanogenum and applied that system towards transcriptional repression of genes with ostensibly crucial functions in metabolism.

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James Heffernan

Enhancing CO2-Valorization Using Clostridium autoethanogenum for Sustainable Fuel and Chemicals Production

Strategies to improve viability of a circular carbon bioeconomy-A techno-economic review of microbial electrosynthesis and gas fermentation

Analytical tools for unravelling the metabolism of gas-fermenting Clostridia

Transcriptional control of Clostridium autoethanogenum using CRISPRi

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