Summary
Genomics research combined with revolutionary genome editing tools has created new opportunities to explore fundamental aspects of biology and develop novel (bio)technologies for medicine, agriculture, and industry. The OMEGA project is designed to build on these developments by enabling Megabase-scale engineering of plant genomes. Experimentally-determined lists of essential genes have been crucial for such large-scale projects in other species but are currently unavailable in plants. Therefore, the OMEGA project needs to determine which plant genes are essential for growth and development. However, the standard technologies used to identify essential genes are limited by genetic interactions (e.g. redundancy, synthetic lethality). My group is developing multiplex CRISPR screens in plants to specifically overcome these limitations. The OMEGA project will use this capability to identify genome-wide essential genes and genetic interactions in Physcomitrium patens. This will be the first systematic genetic interaction screen in plants and will likely identify interactions conserved across the green lineage. The OMEGA project will also develop technologies to move, edit, and delete DNA at the Megabase scale. As proof-of-concept, I aim to reduce ~10% of the P. patens genome and remove all non-essential DNA from one chromosome. The SCRaMbLE system will be adapted for P. patens and used as an alternative approach to minimize chromosomes and also perform in planta directed evolution. Lastly, we will use a DNA assembly method developed in my lab to build biosynthetic pathways in vivo using modular DNA assembly methods. These tools will create opportunities to explore fundamental aspects of genomics, chromosomal biology and synthetic biology. The objectives of project OMEGA are necessarily ambitious as these technologies will allow us to perform controlled, Megabase-scale engineering projects in plant genomes not possible with the current generation of genome editing tools.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101043132 |
| Start date: | 01-07-2022 |
| End date: | 30-06-2027 |
| Total budget - Public funding: | 1 496 250,00 Euro - 1 496 250,00 Euro |
Cordis data
Original description
Genomics research combined with revolutionary genome editing tools has created new opportunities to explore fundamental aspects of biology and develop novel (bio)technologies for medicine, agriculture, and industry. The OMEGA project is designed to build on these developments by enabling Megabase-scale engineering of plant genomes. Experimentally-determined lists of essential genes have been crucial for such large-scale projects in other species but are currently unavailable in plants. Therefore, the OMEGA project needs to determine which plant genes are essential for growth and development. However, the standard technologies used to identify essential genes are limited by genetic interactions (e.g. redundancy, synthetic lethality). My group is developing multiplex CRISPR screens in plants to specifically overcome these limitations. The OMEGA project will use this capability to identify genome-wide essential genes and genetic interactions in Physcomitrium patens. This will be the first systematic genetic interaction screen in plants and will likely identify interactions conserved across the green lineage. The OMEGA project will also develop technologies to move, edit, and delete DNA at the Megabase scale. As proof-of-concept, I aim to reduce ~10% of the P. patens genome and remove all non-essential DNA from one chromosome. The SCRaMbLE system will be adapted for P. patens and used as an alternative approach to minimize chromosomes and also perform in planta directed evolution. Lastly, we will use a DNA assembly method developed in my lab to build biosynthetic pathways in vivo using modular DNA assembly methods. These tools will create opportunities to explore fundamental aspects of genomics, chromosomal biology and synthetic biology. The objectives of project OMEGA are necessarily ambitious as these technologies will allow us to perform controlled, Megabase-scale engineering projects in plant genomes not possible with the current generation of genome editing tools.Status
SIGNEDCall topic
ERC-2021-STGUpdate Date
09-02-2023
Images
No images available.
Geographical location(s)
