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Engineering the biological conversion of formate into crotonate in Cupriavidus necator.

Authors :
Collas, Florent
Dronsella, Beau B.
Kubis, Armin
Schann, Karin
Binder, Sebastian
Arto, Nils
Claassens, Nico J.
Kensy, Frank
Orsi, Enrico
Source :
Metabolic Engineering. Sep2023, Vol. 79, p49-65. 17p.
Publication Year :
2023

Abstract

To advance the sustainability of the biobased economy, our society needs to develop novel bioprocesses based on truly renewable resources. The C1-molecule formate is increasingly proposed as carbon and energy source for microbial fermentations, as it can be efficiently generated electrochemically from CO 2 and renewable energy. Yet, its biotechnological conversion into value-added compounds has been limited to a handful of examples. In this work, we engineered the natural formatotrophic bacterium C. necator as cell factory to enable biological conversion of formate into crotonate, a platform short-chain unsaturated carboxylic acid of biotechnological relevance. First, we developed a small-scale (150-mL working volume) cultivation setup for growing C. necator in minimal medium using formate as only carbon and energy source. By using a fed-batch strategy with automatic feeding of formic acid, we could increase final biomass concentrations 15-fold compared to batch cultivations in flasks. Then, we engineered a heterologous crotonate pathway in the bacterium via a modular approach, where each pathway section was assessed using multiple candidates. The best performing modules included a malonyl-CoA bypass for increasing the thermodynamic drive towards the intermediate acetoacetyl-CoA and subsequent conversion to crotonyl-CoA through partial reverse β-oxidation. This pathway architecture was then tested for formate-based biosynthesis in our fed-batch setup, resulting in a two-fold higher titer, three-fold higher productivity, and five-fold higher yield compared to the strain not harboring the bypass. Eventually, we reached a maximum product titer of 148.0 ± 6.8 mg/L. Altogether, this work consists in a proof-of-principle integrating bioprocess and metabolic engineering approaches for the biological upgrading of formate into a value-added platform chemical. [Display omitted] • Combination of process and metabolic engineering strategies for the biological upgrading of formate into a platform chemical. • Formate toxicity is assessed in C. necator under both formatotrophic and mixotrophic growth modes. • A small-scale, pH-stat system with addition of formic acid is developed to obtain formatotrophic growth in the g/L range. • Engineering a crotonate biosynthetic pathway results in product formation under heterotrophic and formatotrophic conditions. • An ATP-dependent, thermodynamically favorable malonyl-CoA bypass increases crotonate titers, rates and yields. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
10967176
Volume :
79
Database :
Academic Search Index
Journal :
Metabolic Engineering
Publication Type :
Academic Journal
Accession number :
171849958
Full Text :
https://doi.org/10.1016/j.ymben.2023.06.015