Key Info

Basic Information

Portrait: Prof. Dr. Andreas Herrmann © Copyright: Philipp Scheffler
Prof. Dr. Andreas Herrmann
Faculty / Institution:
Mathematics, Computer Science and Natural Sciences
Organizational Unit:
Chair of Macromolecular Materials
Excellent Science
Project duration:
01.09.2016 to 31.08.2021
EU contribution:
2.500.000 Euro
  EU flag and ERC logo This project has received funding from the European Research Council (ERC) under the European Union’s Horizon 2020 research and innovation programme (Grant agreement No. 694610)  


Supramolecular Protective Groups Enabling Antibiotics and Bioimaging


The pharmaceutical sector has a huge demand for new active compounds including natural products to fill the drug pipelines and to stop the global decline in novel approved active pharmaceutical ingredients. Therefore, developing new tools to fabricate complex molecular structures in a fast and reliable way is paramount. This holds especially true for the field of antibiotics. Multidrug resistant (MDR) pathogens evolve at a terrifying rate and confer resistance to all presently available antibacterial treatments and therefore WHO has identified MDR bacteria as major threat to human health.

In this ERC Advanced Grant, I propose a radically new approach to fabricate very complex molecules with minimal synthetic effort. The technology is based on nucleic acid binders (aptamers), which are evolved in a selection protocol and block several functional groups within a target molecule while allowing other functionalities not in contact with the aptamer to be selectively modified in a single reaction step. Here, we aim to establish this groundbreaking aptameric protective group (APG) method as a novel tool that gives access to compounds that would otherwise be too difficult to obtain by multistep synthesis. Toward this end, the specific objectives are:

• To develop reagents and reactions that are compatible with aptamer-mediated reactions
• To control the site of chemical modification within complex molecules by APGs
• To establish APGs as a general paradigm in natural product derivatization to modify several kinds of substrates
• To achieve site selective modification of proteins by aptamers
• To synthesize novel antibiotics that kill MDR bacteria
• To fabricate “image-and-activate” antibiotics by the APG technology
• To employ the aptamer-target complexes for live-cell imaging of RNA

The outcomes will enable future advances in drug discovery and drug design, bioimaging technologies, and the site-specific modification of therapeutic proteins.

Additional information

This grant is hosted at the University of Groningen.