Algae as living biocatalysts for a green industry
Credit: RUB, Marquard
Better still: living algae can be used as biocatalysts for certain substances, and they bring the co-substrate along, producing it in an environmentally friendly manner through photosynthesis. The team published its report in Algal Research on 17. June 2020.
It’s a question of 3D structure
Many chemical substances in cosmetics, food or medicines can assume slightly different three-dimensional structures, with only one of them generating the desired fragrance or medical effect. The chemical production of the right substances is often not environmentally friendly, as it requires high temperatures or special solvents. In nature, however, certain proteins do exist that produce the required product at mild temperatures and in water. In the process, they often generate exactly the 3D structure of the substance that is needed by the industry.
These so-called old yellow enzymes, OYEs for short, owe their name to their naturally yellow colour. They occur in bacteria, fungi and plants, are in part well studied and offer considerable potential for a bio-based economy. However, they have one disadvantage: in order to carry out their reaction, they need the co-substrate NADPH (nicotinamide adenine dinucleotide phosphate). In living cells, this small molecule is generated through metabolic processes, whereas its chemical production is very expensive; as a result, the commercial use of OYEs is thwarted.
OYEs from unicellular green algae: two birds with one stone
The research team from Bochum has discovered several OYEs in unicellular green algae. “For a broad application, industry needs OYEs that can also produce unusual molecules,” explains Professor Thomas Happe, Head of the Photobiotechnology research group at RUB. “Algae possess very complex metabolic pathways and are therefore ideal sources for novel biocatalysts.” The researchers analysed algal OYEs in the test tube and showed that they are able to convert many commercially viable substances. “The exciting thing is that living algae can also carry out the reactions needed in the industry,” points out PhD student Stefanie Böhmer, lead author of the study. “Since algae produce NADPH using photosynthesis, i.e. with sunlight, the co-substrate of the OYEs is supplied in an environmentally friendly and cost-effective way.”
The authors point out that the study demonstrates the importance of the collaboration between researchers from different disciplines, and that the industry can be a valuable partner who initiates basic research. Four researches from the Research Training Group “Micon – Microbial substrate conversion”, which is funded by the German Research Foundation, contributed their expertise to the study. The project was the brainchild of Solarbioproducts Ruhr, a spin-off established by Wirtschaftsförderungsgesellschaft Herne and Thomas Happe with the aim of developing concepts for environmentally friendly algae biotechnologies. “We have taken a big step towards a green industry,” concludes Happe. “This would not have been possible without collaboration.”
The study was funded by the German Research Foundation in the Research Training Group GRK 2341 Microbial Substrate Conversion Micon, the Chembiocat project funded by the Ministry of Innovation, Science and Research NRW, and Wirtschaftsförderungsgesellschaft Herne.
Stefanie Böhmer, Christina Marx, Álvaro Gómez-Baraibar, Marc M. Nowaczyk, Dirk Tischler, Anja Hemschemeier, Thomas Happe: Evolutionary diverse Chlamydomonas reinhardtii old yellow enzymes reveal distinctive catalytic properties and potential for whole-cell biotransformations, in: Algal Research, 2020, DOI: 10.1016/j.algal.2020.101970
Prof. Dr. Thomas Happe
Faculty of Biology and Biotechnology
Phone: +49 234 32 27026
Email: [email protected]
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