Bacteria as a role model: Conversion of chemical energy into rotational energy at the supramolecular level for the first time
Synthetic mini-motor with enormous power developed
Until now, the conversion of chemical energy into rotational energy on a supramolecular level, i.e. for small objects consisting of more than one molecule, was only known from biology. Primitive bacteria, known as archaea, use the chemical fuel ATP to rotate their tiny fin-like locomotion organs, the flagella, and thus move around. Synthetic replicas of this process have not existed until now. In the future, the new development could be used in nanorobots that swim through blood vessels to detect tumor cells, for example.
Chemical fuel drives the rotation
The peptide ribbons developed by a team led by Brigitte and Christine Kriebisch and Job Boekhoven, Professor of Supramolecular Chemistry, are a few micrometers long and just a few nanometers wide. When chemical fuel is added, they gain structure and the ribbons curl up into small tubes, causing them to begin to rotate. This process can even be observed live under the microscope.
The researchers discovered that they can control the rotation speed of the ribbons by the amount of fuel added. In addition, the direction of rotation - clockwise or anti-clockwise - can be influenced by the structure of the molecular building blocks of the ribbons. The research results were published in the renowned journal Chem.
Crawling on surfaces
Together with Prof. Matthias Rief, TUM Professor of Molecular Biophysics, who works on state-of-the-art optical measurement methods, the researchers found that the ribbons exert enough force on their surroundings to move micrometer-sized objects. Determining the force is one of the most important results for practical use.
If several rotating ribbons are brought together at a central point, for example, small “micro-walkers” are created that can crawl along surfaces. In the future, after further improvements, these micro-walkers could possibly be used for medical applications such as transporting drugs in the body. The fuel used is not yet suitable for this, as it would be harmful to the organism.
Kriebisch et al., „Synthetic flagella spin and contract at the expense of chemical fuel“ published in Chem, September 16, 2024 https://doi.org/10.1016/j.chempr.2024.08.016
- The first authors Brigitte and Christine Kriebisch, who work at the Chair of Supramolecular Chemistry of Prof. Job Boekhoven at the TUM School of Natural Sciences, are currently in the final stages of their doctorates.
- The study was funded by the Volkswagen Foundation and the German Research Foundation (DFG) as part of the Excellence Strategy of the German federal and state governments. Additionally, a Kekulé Fellowship from the German Chemical Industry Association (VCI) and funding from the European Research Council (ERC Starting Grant) and the Carnegie Trust contributed to the project.
- Prof. Boekhoven is a member of the Excellence Cluster Origins and is involved in the research of artificial life, among other topics.
- The ORIGINS Cluster of Excellence is investigating the formation of the universe and the origins of life. It brings together researchers from TUM, LMU, ESO, the Max Planck Institute for Astrophysics, the Max Planck Institute for Extraterrestrial Physics, the Max Planck Institute for Physics, the Max Planck Institute of Biochemistry, the Max Planck Institute for Plasma Physics and the Leibniz Supercomputing Centre.
- Cluster of Excellence at TUM
Technical University of Munich
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Contacts to this article:
Prof. Dr. Job Boekhoven
Technical University of Munich (TUM)
Professorship of Supramolecular Chemistry
+49 89 289 54400
job.boekhoven@tum.de