How do antimetabolite cancer drugs damage the genetic material of malignantly transformed cells and thereby destroy them? How might these drugs be used more precisely, particularly in the treatment of pediatric tumors? A new research group led by Dr. Christopher Carnie, a scientist at the Heidelberg Faculty of Medicine at Heidelberg University, will address these questions.

Living systems such as cells rely on membrane pores and channels to transport molecules, exchange signals, and organize biochemical reactions. These functions emerge from dynamic interactions between molecular components. Researchers at the University of Stuttgart have used DNA nanotechnology to develop a synthetic membrane architecture that mimics such interactions.

Medical Center – University of Freiburg demonstrates a fundamental therapeutic approach for hereditary immune system defects in a mouse model. The safety profile of genome editing varies significantly depending on the method and cell type.

The Collaborative Research Centre (CRC) 1550 “Molecular Circuits of Heart Disease” at Heidelberg University is entering its second funding period. The German Research Foundation (DFG) has approved approximately EUR 17.4 million in funding for the next four years. The spokesperson is Johannes Backs, Professor of Experimental Cardiology at the Heidelberg Faculty of Medicine.

Prof. Dr Simon Elsässer will be awarded one of this year’s Alexander von Humboldt Professorships in Berlin on 12 May 2026. With funding of five million euros, Elsässer will strengthen Freiburg’s research focus ‘Signals of Life’ over the next five years. In this interview, he discusses complex decision-making processes in cells, the significance of signals and what makes the research environment in Freiburg so special.

Her ground-breaking research studies on the regulation of gene activity have earned Dr Angelika Feldmann the Hella Bühler Prize for 2026, which is endowed with 100,000 euros.

Led by researchers from Heidelberg Faculty of Medicine at Heidelberg University and the University of California, San Francisco (USA), an international research team has evaluated a novel approach for the diagnosis of pulmonary tuberculosis. The method enables detection of Mycobacterium tuberculosis without laboratory infrastructure, within a markedly shorter time frame than conventional diagnostics, and using a simple swab.

Within biological cells, molecules are constantly in motion. Investigating these motions, however, is still difficult, due to the fact that these processes occur on very small length and time scales. To overcome these challenges, researchers from HITS and MPI-P have developed a simulation method that works rapidly and can predict chemical processes in cells with high precision. Their findings have been published in Nature Communications.

Not only actual chronological age, but also individual aging at the molecular level is a key factor in the development of cancer. This was discovered by scientists at the DKFZ and the Saarland Cancer Registry. If the so-called “epigenetic clocks” indicate accelerated biological aging, the likelihood of a cancer diagnosis increases. This finding could help identify at-risk groups and make early detection screenings more targeted

Genome duplication probably gave biodiversity a decisive evolutionary boost. A Chinese-German research team led by Axel Meyer from the University of Konstanz has now investigated the early phases of the process known as re-diploidization. The results show that the fusion of chromosome sets is asynchronous.

SPT Labtech, a global leader in the design and development of laboratory automation and liquid handling solutions, and the European Molecular Biology Laboratory’s Genomics Core Facility (EMBL GeneCore), today announced a collaboration to advance fully walkaway automated genomics workflows.

Can Aztekin and his team have discovered how oxygen-sensing explains why amphibians regenerate limbs and mammals do not.

For over a decade, a class of drugs called BET inhibitors has been tested in cancer trials with high expectations. The biology looked promising. Many cancers depend on oncogenes that (BET) proteins help activate, so blocking BET proteins should slow tumor growth. In the lab, it often did. In patients, results were mostly disappointing: limited responses, significant side effects, and no clear way to predict which tumors would respond at all.

In a published scientific study, researchers have succeeded in accurately diagnosing common types of brain tumors in children and adolescents based on tumor-derived genetic material in cerebrospinal fluid. Until now, these so-called liquid biopsies were not capable enough for such reliable diagnostics. The international research team has therefore optimized a sequencing technique and developed an AI-based computational method. In a later step,…

Rewriting the transcript to heal diseases - 29/01/2026

Therapy involving the umlauts of the genetic alphabet

tRNAs are essential components of the protein synthesis machinery that also act as molecular switches in gene regulation and consequently in disease processes such as cancer. The Heidelberg-based start-up Umlaut.bio is developing novel therapeutics that specifically target tRNAs to intervene at the molecular origin of disease.

Artificial intelligence allows tracing the evolution of genetic control elements in the developing mammalian cerebellum. An international research team led by biologists from Heidelberg University as well as the Vlaams Instituut voor Biotechnologie and KU Leuven has now developed advanced AI models that can predict the activity of these elements based solely on their DNA sequence.

Researchers at the National Center for Tumor Diseases (NCT) Heidelberg and the German Cancer Research Center (DKFZ) have developed a digital tool that significantly accelerates and improves clinical decisions in molecular precision oncology. The Knowledge Connector enables the structured and standardized evaluation of very extensive molecular tumor profiles and makes them available for personalized therapy decisions faster than before.

In a joint study conducted by the DZHK sites in Heidelberg, Munich and Göttingen, researchers are deciphering how the spatial organisation of the genome in the heart determines genetic disease risks.

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.

Hummingbird Diagnostics GmbH, a pioneer in harnessing blood-based small RNAs for early disease detection and characterization, today announced the publication of a new study in Nature Communications Medicine introducing an Oxford Nanopore Technologies (ONT)-based method for detecting small RNA modifications in blood.

Researchers at the Hopp Children's Cancer Center Heidelberg, the German Cancer Research Center, the Heidelberg Medical Faculty of Heidelberg University, and Heidelberg University Hospital have taken a decisive step toward more precise diagnosis of brain tumors. The latest version of the AI-based Heidelberg CNS Tumor Methylation Classifier can identify more than 180 tumor types —twice as many as the previous version.

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.

The technology company KyooBe Tech GmbH and the German Center for Infection Research (DZIF) have signed a memorandum of understanding to collaborate on future research and development projects. The aim of the collaboration is to evaluate an innovative technology for inactivating pathogens using the specific effect of low-energy accelerated electrons (Low Energy Electron Irradiation—LEEI) and to make it available to DZIF scientists.

A method developed at the Fraunhofer Institute for Interfacial Engineering and Biotechnology IGB enables bacterial, viral, fungal, or parasitic pathogens in sepsis patients to be identified much faster than before and with the highest precision. The approach is based on high-throughput sequencing of cell-free DNA circulating in the blood and was honored with the EARTO Innovation Award in the "Impact Delivered" category on October 14,…

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.