SeleCHEM | Overcoming the Selectivity Challenge in Chemistry and Chemical Biology via Innovative Tethering Strategies

Summary
In the last two centuries, synthetic organic chemistry has undergone an unprecedented revolution. The ability to understand and modify the molecular structure of matter has changed our life in many areas, such as medicine, agriculture or commodity materials. These major successes gave the impression that synthetic chemistry is a mature field. However, this impression is completely misleading, as current synthetic methods still lack the selectivity needed for the modification of complex molecules. Both selecting between different reactive groups and functionalizing inert bonds in their presence represent formidable challenges.
In this project, we propose to develop highly selective “molecular tethers” for the functionalization of both natural/synthetic organic compounds and biomolecules. The envisioned tethers are bifunctional small organic molecules having three fundamental properties:
1) A “biting end” with unique reactivity to be selectively installed in situ onto naturally occurring thiols, alcohols and amines. We will use tethers based on acetals and hypervalent iodine reagents.
2) A “functional end”, whose reactivity can be revealed “at will” to functionalize bonds that cannot be accessed with the current state of the art of synthetic chemistry, especially inert C-H and C=C bonds.
3) Being traceless, meaning that they can be removed easily once the desired functionalization has been achieved.
The main impact of this project will be in fundamental synthetic organic chemistry, as it will contribute to overcoming major selectivity hurdles in the functionalization of complex molecules. It will therefore result in faster progress in all the fields depending on synthetic molecules, such as medicine, agriculture or materials. A more efficient functionalization of biomolecules will allow us to soften the boundaries between synthetic chemistry and biology, leading to major progress in our understanding of living systems and our ability to modify them.
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More information & hyperlinks
Web resources: https://cordis.europa.eu/project/id/771170
Start date: 01-01-2019
End date: 31-12-2023
Total budget - Public funding: 2 000 000,00 Euro - 2 000 000,00 Euro
Cordis data

Original description

In the last two centuries, synthetic organic chemistry has undergone an unprecedented revolution. The ability to understand and modify the molecular structure of matter has changed our life in many areas, such as medicine, agriculture or commodity materials. These major successes gave the impression that synthetic chemistry is a mature field. However, this impression is completely misleading, as current synthetic methods still lack the selectivity needed for the modification of complex molecules. Both selecting between different reactive groups and functionalizing inert bonds in their presence represent formidable challenges.
In this project, we propose to develop highly selective “molecular tethers” for the functionalization of both natural/synthetic organic compounds and biomolecules. The envisioned tethers are bifunctional small organic molecules having three fundamental properties:
1) A “biting end” with unique reactivity to be selectively installed in situ onto naturally occurring thiols, alcohols and amines. We will use tethers based on acetals and hypervalent iodine reagents.
2) A “functional end”, whose reactivity can be revealed “at will” to functionalize bonds that cannot be accessed with the current state of the art of synthetic chemistry, especially inert C-H and C=C bonds.
3) Being traceless, meaning that they can be removed easily once the desired functionalization has been achieved.
The main impact of this project will be in fundamental synthetic organic chemistry, as it will contribute to overcoming major selectivity hurdles in the functionalization of complex molecules. It will therefore result in faster progress in all the fields depending on synthetic molecules, such as medicine, agriculture or materials. A more efficient functionalization of biomolecules will allow us to soften the boundaries between synthetic chemistry and biology, leading to major progress in our understanding of living systems and our ability to modify them.

Status

CLOSED

Call topic

ERC-2017-COG

Update Date

27-04-2024
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Horizon 2020
H2020-EU.1. EXCELLENT SCIENCE
H2020-EU.1.1. EXCELLENT SCIENCE - European Research Council (ERC)
ERC-2017
ERC-2017-COG