TRANSMETECH | Translating a new metabolic engineering strategy to industrial biotech applications

Summary
Industrial biotechnology plays a key role on the road to a sustainable, climate-neutral and circular economy. However, disruptive innovations are needed to substantially increase the efficiency of bio-based processes for the production of chemicals. The ERC CoG project StrainBooster aimed to develop a generic metabolic engineering strategy to maximize the productivity of microbial cell factories. It is based on the concept of enforced ATP wasting (EAW), a targeted intervention in the energy metabolism of the cell that enhances the overall metabolic activity boosting also product synthesis. The project reached its central goals and could demonstrate in several case studies the enormous potential of EAW to improve productivity (up to tenfold increase) and product yield.
With these results, StrainBooster’s innovation is now mature to initiate a transfer from small-scale example processes in an academic lab to realistic industrial applications. This is the goal of the PoC project TRANSMETECH. Two companies, one younger startup (COLIPI) and one established big biotech player (BASF), have already indicated their high interest to collaborate with us within this PoC project to jointly explore the potential of EAW for their innovative bioprocesses (oil production by oleaginous yeast (COLIPI) and synthesis of terpenoid-based products (BASF)). In addition, to further improve the efficiency of EAW in industrial applications, we will validate different expression systems for autoinduction of EAW in two-stage processes, which are also directly relevant for our partners.
In summary, through TRANSMETECH we will establish partnerships with biotech companies to facilitate the translation of the StrainBooster approach and showcase its power in concrete industrial applications. On the long run, our method will enable higher efficiencies of commercial bioprocesses and thus contribute to the establishment of sustainable production routes, one of the most urgent societal challenges.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/101105488
Start date: 01-06-2023
End date: 30-11-2024
Total budget - Public funding: - 150 000,00 Euro
Cordis data

Original description

Industrial biotechnology plays a key role on the road to a sustainable, climate-neutral and circular economy. However, disruptive innovations are needed to substantially increase the efficiency of bio-based processes for the production of chemicals. The ERC CoG project StrainBooster aimed to develop a generic metabolic engineering strategy to maximize the productivity of microbial cell factories. It is based on the concept of enforced ATP wasting (EAW), a targeted intervention in the energy metabolism of the cell that enhances the overall metabolic activity boosting also product synthesis. The project reached its central goals and could demonstrate in several case studies the enormous potential of EAW to improve productivity (up to tenfold increase) and product yield.
With these results, StrainBooster’s innovation is now mature to initiate a transfer from small-scale example processes in an academic lab to realistic industrial applications. This is the goal of the PoC project TRANSMETECH. Two companies, one younger startup (COLIPI) and one established big biotech player (BASF), have already indicated their high interest to collaborate with us within this PoC project to jointly explore the potential of EAW for their innovative bioprocesses (oil production by oleaginous yeast (COLIPI) and synthesis of terpenoid-based products (BASF)). In addition, to further improve the efficiency of EAW in industrial applications, we will validate different expression systems for autoinduction of EAW in two-stage processes, which are also directly relevant for our partners.
In summary, through TRANSMETECH we will establish partnerships with biotech companies to facilitate the translation of the StrainBooster approach and showcase its power in concrete industrial applications. On the long run, our method will enable higher efficiencies of commercial bioprocesses and thus contribute to the establishment of sustainable production routes, one of the most urgent societal challenges.

Status

SIGNED

Call topic

ERC-2022-POC2

Update Date

31-07-2023
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Horizon Europe
HORIZON.1 Excellent Science
HORIZON.1.1 European Research Council (ERC)
HORIZON.1.1.0 Cross-cutting call topics
ERC-2022-POC2 ERC PROOF OF CONCEPT GRANTS2
HORIZON.1.1.1 Frontier science
ERC-2022-POC2 ERC PROOF OF CONCEPT GRANTS2