An international team led by Professor Tobias M. Böckers from Ulm University Medical Centre has been awarded up to 1.7 million euros to develop a novel therapy for a rare, syndromic form of autism. The research project focuses on a gene whose loss of function can manifest itself in severe impairments in language, behaviour and everyday functions of those affected.

The powerhouse of the cells, known as mitochondria, appear to be able to influence the number of lipid droplets in the cell. Research into this previously unknown mechanism was conducted using baker’s yeast. This is shown by a recent study by the University of Freiburg, the University of Bonn and the University Hospital Bonn and the University of Freiburg. The results have now been published in the journal Nature Cell Biology.

Illuminating the tiniest details of living cells just got a major boost: Scientists at the Max Planck Institute for Medical Research have developed new markers that glow in the far-red range and are activated by light. They are stable, easy to control, and compatible with several super-resolution microscopy techniques, as outlined in a paper published in the journal Chem.

Technology impulse for the Lake Constance region: The new Single Cell Centre at the University of Konstanz offers technology and expertise to study cells individually and at high resolution – for applications in medical diagnostics, medication development and basic research at universities.

Even before a tumour in the pancreas becomes discernible, an activated cancer gene actively remodels its future environment and creates an inflammatory and immune-defensive microenvironment in which the carcinoma can grow. The scientists' study opens up new possibilities for developing personalised intervention strategies - before a difficult-to-treat tumour even develops.

A key molecular mechanism drives the growth of liver cell cancer while simultaneously suppressing the body's immune response to the tumor. This has now been published in the journal Nature by a team led by researchers from the DKFZ, the UKT, and the Sanford Burnham Prebys Medical Discovery Institute. However, the results also show that this very mechanism could help identify patients who respond particularly well to immunotherapy in the…

Inflammation has to work fast against pathogens—but it can't get out of control. Researchers at the German Cancer Research Center (DKFZ) have now deciphered in more detail how the organism masters this balancing act. Their work shows that cells use two different strategies to precisely control inflammatory genes and thus precisely regulate the inflammatory response.

To ensure that protein production in our cells runs smoothly, the protein complex NAC slows down the rate of protein synthesis right at the start. An international research team with significant involvement of Konstanz biologists has now discovered what underlies this previously unknown function of NAC.

Recreating tumour tissue in the laboratory as realistically as possible and developing new approaches for personalised cancer medicine: A total of 20 doctoral students in the life sciences and ten Medicine students will be researching this in the new "Organoid-Based mOdelling of Solid Tumours" research training group. They want to gain a better understanding of cancer and better predict the course of the disease and the effect of…

Can the weakened immune systems of older individuals be rejuvenated? Researchers from the DKFZ, HI-STEM*, and the Broad Institute have demonstrated that this is possible with an innovative approach. In a study, the team showed that mRNA technology can be used to transform the liver in mice into a temporary source of important immune regulatory factors that are naturally lost during aging.

It has only recently become known that two parallel systems of blood formation exist in the body. Researchers at the DKFZ have developed a method to examine both systems separately in mice for the first time. Their surprising finding: the majority of immune cells do not originate from classic blood stem cells in the bone marrow, but from precursor cells that are independent of blood stem cells and are already present in the embryo.

In the current selection round, the German Research Foundation (DFG) has granted funding for two new Collaborative Research Centres at the University of Konstanz. Over the next four years, the research teams will be working intensively on trigger signals in biological cells as well as on "silence" and "noise" in human speech.

Researchers from the German Cancer Research Center and the University of Freiburg show how certain painkillers influence the iron metabolism of liver cancer cells and can thus contribute to iron deficiency and anemia in cancer patients.

A team from the DZHK sites in Heidelberg/Mannheim and Berlin has discovered that a single enzyme in the heart plays a key role in determining whether the organ develops in a healthy manner. If this molecular protective factor is missing, serious congenital heart defects can develop.

The German Research Foundation (DFG) is funding a new Emmy Noether project led by Jens Puschhof from the German Cancer Research Center (DKFZ). With this project, the junior researcher aims to decipher the role of certain intestinal bacteria in the earliest stages of colorectal cancer development and investigate how this process can be halted. The long-term goal is to develop new preventive strategies against colorectal cancer.

EMBL scientists created SDR-seq, a tool for single-cell DNA-RNA-sequencing that studies both DNA and RNA simultaneously, linking coding and non-coding genetic variants to gene expression in the same single cell.

Since their discovery in 2004, the grid cells in the brain, which are important for our orientation, have been regarded as a kind of “GPS in the head.” However, scientists at the DKFZ and Heidelberg University Hospital have now shown that grid cells work much more flexibly than previously assumed. In experiments with mice, the researchers found that the cells adapt their activity to different reference points depending on the situation.

With the FeMEA project – Ferroelectric Microelectrodes for Biomedical Applications – Hahn-Schickard is setting a pioneering course in bioelectronics research. The aim of the project is to develop novel microelectrode arrays in which ferroelectric materials are used as functional interfaces in CMOS chips for the first time.

When embryos grow, cells and tissue are constantly bumping into each other. This creates mechanical tensions that could endanger their development. A team from University of Hohenheim and the Japanese RIKEN Center have discovered that fly embryos have strategies to deal with this pressure. The different species have developed two different solutions. This ability to control mechanical tension could be a key to why so many body plans have evolved.

Researchers from the German Cancer Research Center (DKFZ) have collaborated with the SILVACX project group at Heidelberg University to develop a therapeutic vaccination concept that can mobilize the immune system to target cancer cells. The team showed that virus peptides coupled to silica nanoparticles can elicit effective T-cell responses against HPV-related tumors.

Scientists at the Max Planck Institutes for Medical Research in Heidelberg with its new departments based in Heilbronn, and for Neurobiology of Behavior – caesar in Bonn, and at the Institute for Basic Science at Yonsei University in Seoul will pool their expertise in future. The aim of the new Max Planck Center is to visualize cellular processes deep within human tissue and influence them in a targeted manner — without damaging the tissue.

Diabetics have a higher risk of colorectal cancer and often a poorer prognosis after developing the disease. The biological mechanisms behind this association were largely unknown. A research team at the German Cancer Research Center (DKFZ) has now discovered that tumors with a low number of immune cells appear to be particularly susceptible to the harmful effects of diabetes.

Many people with cancer experience dramatic loss of muscle and fat tissue. In many cases, even the heart muscle is affected. This wasting syndrome, affects around half of all cancer patients. Researchers from Helmholtz Munich, in collaboration with Heidelberg University Hospital, the Technical University of Munich, and the German Center for Diabetes Research, have now identified a previously overlooked driver of cachexia: the liver.

Researchers from the Max Planck Institute of Immunobiology and Epigenetics in Freiburg and ETH Zürich have created the first integrated map detailing the metabolic and molecular changes in human blood stem cells as they age, specialize, or turn cancerous. Their innovative research, made possible by highly sensitive low-input techniques, identifies the nutrient choline, as a key player in preserving youthful stem cell traits.

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.

For his outstanding achievements in his doctorate at the interface between chemistry and biology, Jonas Wilhelm is awarded an Otto Hahn Medal 2025 by the Max Planck Society. He wrote his thesis in the department Chemical Biology of Kai Johnsson at the Max Planck Institute for Medical Research. In his doctorate, Jonas Wilhelm developed a molecular tool, a biosensor that records and permanently stores biological activities at the cellular level.

Dr Dr Varun Venkataramani and Dr Moritz Mall have been awarded this year’s Hella Bühler Prize for their outstanding research on the interaction between nerve and tumor cells and on tumor plasticity. The award granted by Heidelberg University goes to young researchers from the Heidelberg research location who have already drawn attention to themselves through the outstanding scientific quality of their cancer research.

VDI Guideline 5708 “Bioprinting, methods and definitions”: What sounds technical and sober at first glance is an important step forward in the future field of 3D bioprinting. The guideline was developed under Dr. Hanna Hartmann from the NMI in Reutlingen and Prof. Dr. Jürgen Groll from the University Hospital of Würzburg. It creates a binding, practical basis for reproducible and quality-assured bioprinting procedures.

Researchers from the universities in Konstanz and Vienna discover a new class of antibiotic that selectively targets Neisseria gonorrhoeae, the bacterium that causes gonorrhoea. These substances trigger a self-destruction program, which also operates in multi-resistant variants of the pathogen. The novel findings are published in the current issue of Nature Microbiology.

With the goal of creating living cells from non-living components, scientists in the field of synthetic biology work with RNA origami. This tool uses RNA biomolecule to fold new building blocks, making protein synthesis superfluous. In pursuit of the artificial cell, a research team has cleared a crucial hurdle. Using the new RNA origami technique, they succeeded in producing nanotubes that fold into cytoskeleton-like structures.

A recent study by the Hector Institute for Translational Brain Research at the CIMH provides the first cellular insights into how psilocin promotes the growth and networking of human nerve cells.

This year, the Brain Prize worth more than one million euros, honors pioneering work on nervous system-cancer interactions: Neurologist Frank Winkler, who researches at the Heidelberg University and at the German Cancer Research Center and treats patients with brain tumors at the Heidelberg University Hospital, discovered that nerve cells in the brain communicate with brain tumor cells. This causes the disease to progress.

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 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.

The spliceosome, ensures that the genetic information from the genome, after being transcribed into mRNA precursors, is correctly assembled into mature mRNA. Splicing is a basic requirement for producing proteins. Researchers at the Heidelberg University Biochemistry Center (BZH) have succeeded for the first time in depicting a faultily “blocked” spliceosome at high resolution and reconstructing how it is recognized and eliminated in the cell.

A research team from Freiburg and Frankfurt has discovered how cells recognise and internally break down waste. The results are relevant for the development of therapies for diseases such as Alzheimer’s.

Researchers at the Medical Faculty of Heidelberg University and the Heidelberg University Hospital have used modified rabies viruses to label glioblastoma tumour cells and their direct cell contacts in the mouse brain. The new method showed that the tumour cells are connected to different types of nerve cells throughout the entire brain at a very early stage of the disease.

Cell division, cell differentiation, cell repair and cell death play fundamental roles in the human organism, its development, health and reproduction. Cellular transformation processes are governed by two regulatory mechanisms: chromatin modifications and cell signaling networks. The EpiSignal Research Training Group sheds light on the hitherto little-researched interplay between these two complex systems.

On 25 November, the German Research Foundation (DFG) announced the continued funding of two existing Collaborative Research Centres (CRC) at the University of Freiburg’s Faculty of Medicine. In CRC 1453 Nephrogenetics (NephGen), doctors and researchers are using genetic information to search for mechanisms underlying kidney diseases.

3D tumor models, simulations of drug responses or plant stems used for testing heart stents: the 3R-BioMedicUS center at the University of Stuttgart is developing innovative biomedical approaches to improve preclinical studies, to be seen in the new video.

Heidelberg scientist Dr Venera Weinhardt has received an ERC Synergy Grant for a pioneering biomedical research project. The European Research Council (ERC) is granting this funding to advance soft X-ray microscopy. This imaging technique along with other innovations will be used to investigate the hepatitis E virus.

They are underestimated genetic control elements: it is known that changes in the genome can trigger diabetes. But now researchers at the University Hospital Ulm and the INSERM Cochin Institute in Paris have shown that a previously under-researched region of the genome also plays a crucial role in the development of this disease.

Chronic inflammatory bowel diseases - 25/09/2024

Proinflammatory regulatory T lymphocytes as a therapeutic target in Crohn's disease

Chronic inflammatory bowel diseases are very stressful for those affected and increase the risk of bowel cancer. PD Dr. Robyn Laura Kosinsky from the Bosch Health Campus in Stuttgart, together with researchers from the USA, identified disfunctional regulatory T cells as important drivers of inflammation in Crohn's disease. They also found that with the help of an epigenetically active drug, it was possible to restore the cells’ original…

Research teams from the Universities of Konstanz and Potsdam are analyzing how proteins work together to enable our cells to both stick and move. The marker protein paxillin is at the centre of their interest.

With mice, researchers showed that experimentally induced lack of blood flow in the brain epigenetically reprograms astrocytes into brain stem cells, which in turn can give rise to nerve progenitor cells. This discovery shows that astrocytes could potentially be used in regenerative medicine to replace damaged nerve cells.

Freiburg-Prague research collaboration achieves scientific breakthrough in understanding cell division. The international research collaboration has uncovered a new mechanism of the crosstalk between microtubules and actin cytoskeleton during cell division and revealed unique characteristics of the previously unexplored protein FAM110A.

The summer reception hosted by BioRegio STERN Management GmbH has once again provided a fitting backdrop for the Science2Start award ceremony. Last Thursday, at Tübingen observatory, was the 15th time that scientists and start-up founders were celebrated for outstanding ideas that a panel of experts judged to have special economic potential.

With "OrgaPlexing", scientists at the MPI of Immunobiology and Epigenetics have developed a new method that shows how guardian cells of the immune system, the macrophages, orchestrate their cell structures during inflammation or bacterial infection, making it possible to observe the interactions between several organelles simultaneously and thus providing insights into cell metabolism and the production of inflammatory molecules.

Cancer genomes are the result of diverse mutation processes. Scientists have analyzed the molecular evolution of tumors after exposure to mutagenic chemicals. DNA lesions that persists unrepaired over several cell generations lead to sequence variations at the site of damage. This enabled the researchers to distinguish the contribution of the triggering lesion from that of the subsequent repair in shaping the mutation pattern.

Depending on whether the cell nucleus of an epithelial cell is located on the outer or inner side of the tissue, the genome is more or less acetylated - genes can therefore be translated easier or harder. Scientists from the German Cancer Research Center (DKFZ) have demonstrated this for the first time in the development of the Drosophila wing.