Synthetic plant biology: The ultimate way to ‘go green’ - Lightdriven production of structurally complex diterpenoids
Activity: Talk or presentation types › Lecture and oral contribution
Birger Lindberg Møller - Lecturer
Synthetic plant biology: The ultimate way to ‘go green’ - Lightdriven
production of structurally complex diterpenoids
Keynote Speaker: Prof. Birger Lindberg Møller
Birger Lindberg Møller, Irini Pateraki, Allison Maree Heskes, Johan Andersen-Ranberg, Agnieszka Zygadlo Nielsen and Poul Erik Jensen,University of Copenhagen, Denmark
With 12,000+ known structures, diterpenoids are a prime example of bio-active natural products produced by plants. Many are used as highly valuable pharmaceuticals, fragrances, natural plant growth promoters, food ingredients such as flavors or as colorants and spices. Unfortunately, they are typically produced in minute amounts in plants and their structural complexity render them difficult to prepare from fossil resources using organic chemical synthesis. Terpenoid synthases, cytochrome P450s and acyl transferases are key multienzyme families involved in diterpenoid synthesis. Using mass spec based imaging of the target plant tissue, tracer studies, single cell-type based metabolomics and transcriptomics, functional characterization of gene candidates using transient expression in tobacco and LC-MS-NMR based structural identification, elucidation of even highly complex biosynthetic pathways is now possible within a short time frame. Terpenoid metabolism is modular right from assembly of the C5 building blocks to the final structurally complex diterpenoid. Using the approaches of synthetic biology for combinatorial biosynthesis, the functional modules may be assembled in new combinations to expand the landscape of diterpenoid structural diversity into new-to-nature structures. The entire pathway for forskolin was elucidated. Forskolin is a cyclic AMP booster approved for treatment of glaucoma but also used as a weight loss aid. The forskolin pathway is being used as test model system for large scale light driven production of high value diterpenoids following targeting of the pathway to the thylaloid membrane and using cyanobacteria or moss as photosynthetic production hosts grown in contained photo-bioreactors.
References
1. J. Andersen-Ranberg et al., Angewandte Chemie (2016)
2. A. Wlodarczyk et al., Metabolic Engineering (2016)
3. L.M. Lassen et al., ACS Synthetic Biology (2014)
4. I. Pateraki et al., Plant Physiology (2014)
Keynote speaker
production of structurally complex diterpenoids
Keynote Speaker: Prof. Birger Lindberg Møller
Birger Lindberg Møller, Irini Pateraki, Allison Maree Heskes, Johan Andersen-Ranberg, Agnieszka Zygadlo Nielsen and Poul Erik Jensen,University of Copenhagen, Denmark
With 12,000+ known structures, diterpenoids are a prime example of bio-active natural products produced by plants. Many are used as highly valuable pharmaceuticals, fragrances, natural plant growth promoters, food ingredients such as flavors or as colorants and spices. Unfortunately, they are typically produced in minute amounts in plants and their structural complexity render them difficult to prepare from fossil resources using organic chemical synthesis. Terpenoid synthases, cytochrome P450s and acyl transferases are key multienzyme families involved in diterpenoid synthesis. Using mass spec based imaging of the target plant tissue, tracer studies, single cell-type based metabolomics and transcriptomics, functional characterization of gene candidates using transient expression in tobacco and LC-MS-NMR based structural identification, elucidation of even highly complex biosynthetic pathways is now possible within a short time frame. Terpenoid metabolism is modular right from assembly of the C5 building blocks to the final structurally complex diterpenoid. Using the approaches of synthetic biology for combinatorial biosynthesis, the functional modules may be assembled in new combinations to expand the landscape of diterpenoid structural diversity into new-to-nature structures. The entire pathway for forskolin was elucidated. Forskolin is a cyclic AMP booster approved for treatment of glaucoma but also used as a weight loss aid. The forskolin pathway is being used as test model system for large scale light driven production of high value diterpenoids following targeting of the pathway to the thylaloid membrane and using cyanobacteria or moss as photosynthetic production hosts grown in contained photo-bioreactors.
References
1. J. Andersen-Ranberg et al., Angewandte Chemie (2016)
2. A. Wlodarczyk et al., Metabolic Engineering (2016)
3. L.M. Lassen et al., ACS Synthetic Biology (2014)
4. I. Pateraki et al., Plant Physiology (2014)
Keynote speaker
28 Apr 2016
Event (Conference)
| Title | ENCAPP 2016 |
|---|---|
| Abbreviated title | ENCAPP |
| Date | 26/04/2016 → 29/04/2016 |
| Website | |
| Location | San Antonio |
| City | Qawra |
| Country/Territory | Malta |
| Degree of recognition | International event |
ID: 164465758