The ability of protein kinases to transfer a phosphate group to target proteins plays an important role in many cellular processes. Scientists at the Max Planck Institute for Medical Research have now developed a novel molecular tool that can monitor these kinase activities both spatially and temporally. This makes it possible to investigate the link between kinase activities and cellular phenotypes in heterogenous cell populations and in vivo.

Cancer can take decades for cancer-promoting changes in the genome to eventually lead to the formation of a malignant tumor. Researchers at the German Cancer Research Center have now developed a method that allows for the first time to reconstruct the temporal development—the evolution—of cancerous cells from a single tissue sample.

An international team of researchers led by Konstanz biologists has identified a molecular mechanism that regulates the activity of N-myristoyltransferases. This enzyme plays a role in biological signalling pathways, where dysregulation can lead to serious illness.

Investing in a healthier future: The HORNBACH Group is supporting the new National Cancer Prevention Center in Heidelberg with a donation of five million euros. In the future, a new laboratory will conduct research into more effective early detection and screening methods.

Felix Glang, of the Max Planck Institute for Biological Cybernetics in Tübingen, has been awarded the Otto Hahn Medal in recognition of his achievements in developing new magnetic resonance imaging (MRI) methods. Glang's methods enable clearer and faster brain scans.

A building with 7400 m² of research space for robotics and artificial intelligence is being built on the Max Planck Campus in Büsnau. Researchers from the Max Planck Institute for Intelligent Systems (MPI-IS) and the University of Stuttgart will be working there with partners from science and industry as well as start-ups from 2027.

The human brain continuously processes sensory impulses that compete for our attention. Our ability to select enables us to process specific information and ignore irrelevant stimuli. In this way, we can recognize a familiar face in a large crowd of people. But how is this made possible?

University of Tübingen research team shortens the search for attackers that can wipe out multiresistant pathogens – with the aim of treating infections without antibiotics

The Max Planck Society and the Dieter Schwarz Foundation (DSS) have embarked on a groundbreaking initiative. On March 13, 2025, they signed an agreement through which the foundation will support an innovative approach by the Max Planck Institute for Medical Research in Heidelberg to translate basic research findings into practical applications. As part of this endeavour, two new departments of the institute will be established in Heilbronn.

Using a new combination of three sensors and artificial intelligence, researchers at Heidelberg Medical Faculty of Heidelberg University and Heidelberg University Hospital are recognising patterns in babies' movements that show whether their nervous system is developing healthily.

Zebrafish can completely replace damaged heart muscle cells: The affected organ becomes fully functional again. Researchers at Ulm University have discovered that a specific cell-to-cell communication signal helps them to cope better with replication stress. This stress inhibits tissue regeneration in humans and mammals as they age. In Zebrafish a signalling protein ensures that the cells of the damaged organ continue to divide and thus multiply.

A protein with contradictory properties: Despite its large negative surface charge, it has a strong tendency to take up electrons, which are also negatively charged. The researchers discovered positively charged calcium ions inside the protein very near the electrons, counteracting their charge. They see this as a natural way of handling opposing electrical charges and allowing the protein to optimally fulfill its biological function.

A guardian molecule ensures that liver cells do not lose their identity. The discovery is of great importance for cancer medicine because a change of identity of cells has come into focus as a fundamental principle of carcinogenesis for several years. The research team was able to show that the newly discovered guardian is so powerful that it can slow down highly potent cancer drivers and cause malignant liver tumors to regress in mice.

Project REVeyeVE - 06/02/2025

Targeted, virus-free gene therapy for the eye using degradable nanopropellers

Eye diseases that result in blindness in young people are primarily caused by genetic mutations. An interdisciplinary team of researchers from the Universities of Tübingen and Heidelberg is developing an innovative gene therapy method using biodegradable, magnetic nanopropellers. These innovative nanopropellers can effectively deliver intact genes into the affected cells, offering a potential solution for treating genetic disorders of this kind.

Like all viruses, the Ebola virus is dependent on host cells in order to replicate. Researchers at Heidelberg University Hospital, in collaboration with colleagues from the Friedrich Loeffler Institute, have been able to show for the first time using state-of-the-art imaging techniques how the replication compartments of the Ebola virus change during replication in infected cells.

Winfried Kretschmann, the Minister President of Baden-Württemberg, Germany, visited the Max Planck Institutes for Biology Tübingen and Biological Cybernetics. During his tour, he commended the outstanding basic research in the natural sciences. He was particularly impressed by the innovative research projects spanning developmental and evolutionary biology, as well as neuroscience.

The Gottfried Wilhelm Leibniz-Prize 2025 goes to Prof. Dr Robert Zeiser for his outstanding research in haematology and immunology. Zeiser’s research at the University of Freiburg and the Medical Center – University of Freiburg have led, among other things, to new types of cancer therapy that has increased survival rates and the patients’ quality of life.

Making existing cancer therapy more efficient while significantly reducing the side effects on healthy tissue - this is the aim of a project at Aalen University. It is being funded with one million euros from the Carl Zeiss Foundation. The biophysicist and his team are developing innovative nanoparticles made of gold. The particles use radiotherapy and chemotherapy simultaneously and kill the cancer cells in a targeted manner.

Advancing quantum technology into real-world applications - 06/11/2024

QSens: BMBF future cluster brings quantum sensors of the future into medicine

The BMBF-funded future cluster ‘QSens – Quantum Sensors of the Future’ is developing ultra-sensitive sensors that could open up new options in medicine, enabling faster drug research, more accurate diagnostics and improved rehabilitation. The universities of Stuttgart and Ulm are actively working with 17 industry partners to put these cutting-edge innovations to immediate practical use.

NMI project WOUNDSENS - 23/10/2024

Wound monitoring using sensory nanofibres

Monitoring the condition of chronic, non-healing wounds requires wound dressings to be changed at short, regular intervals. In the EU-funded WOUNDSENS project, researchers at the NMI in Reutlingen are using electrospinning to produce novel types of wound dressings. These consist of biosensory fibres that send information about the condition of the wound to the outside, thereby improving inflammation detection.

Whether we are predisposed to particular diseases depends to a large extent on the countless variants in our genome. However in the case of genetic variants the influence on the presentation of certain pathological traits has been difficult to determine. Researchers have introduced an algorithm based on deep learning that can predict the effects of rare genetic variants.

Five transnational and cross-institutional doctoral networks at Heidelberg University are being funded as part of the “Marie Skłodowska-Curie Actions”. They work together on current scientific topics with high innovation potential. Ruperto Carola coordinates an MSCA Doctoral Network on artificial intelligence in physics, two networks in medicine, life sciences and engineering.

Biotechnology team at University of Tübingen obtains valuable byproduct in protein production. This could be a potential to the contribution of feeding a growing world population without livestock farming.

A new molecular engineering technique can precisely influence the development of organoids. Microbeads made of specifically folded DNA are used to release growth factors or other signal molecules inside the tissue structures. This gives rise to considerably more complex organoids that imitate the respective tissues much better and have a more realistic cell mix than before.

Researchers of Karlsruhe Institute of Technology (KIT) and Voxalytic GmbH developed a new method that allows, for the first time, to elucidate the chiral structure of molecules – the exact spatial arrangement of the atoms – by nuclear magnetic resonance (NMR) spectroscopy. This important step in the development of new drugs used to be a time-consuming process until now.