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RNA Synthetic Biology
RNA is a ubiquitous molecule of life that plays intimate roles in how cells function and make decisions. These same properties can be harnessed to create a new generation of engineering tools to further interrogate the properties of biology and control how cells behave. The “RNA synthetic biology” group aims to better understand the roles RNA plays in biology and to exploit these roles to improve how we study, diagnose, and treat infectious diseases in humans. This department is located at the Helmholtz Institute for RNA-based Infection Research (HIRI).
RNA Biology of bacterial infections
The Vogel lab strives to chart the diversity of noncoding RNA functions and RNA-binding proteins in major bacterial pathogens and in the hundreds of different bacteria that make up the human microbiome. We develop new RNA deep sequencing-based techniques to capture the RNA world of any microbe, ideally at the single cell level. We want to understand how and why bacteria use RNA as a regulator during infection and exploit this knowledge to target pathogens and edit the microbiota with precision. Projects focus on several bacteria from our major workhorse Salmonella Typhimurium to anaerobic microbes that are associated with colorectal cancer such as Fusobacterium nucleatum . This Department is located at the Helmholtz Institute for RNA-based Infection Research (HIRI).
Personalised Immunotherapy
Our motivation is to address fundamental questions of human immunology and translate them into personalized therapies and diagnostics. Specifically, our laboratory discovers new applications of antibodies and B cells to treat and prevent human infectious diseases. Effective vaccines against some viruses that escape antibody responses remain elusive. To tackle this challenge, we develop methods to better understand B cell responses, the cells that produce antibodies. We design tailored vaccines and provide novel solutions for infection diagnostics. This Department is located at the Centre for Individualised Infection Medicine ( CiiM ).
Nano Infection Biology
Viruses are nanoscale entities. Despite their size and low complexity, they efficiently enter host cells leading to infection and reprogramming of cellular functions. The critical processes involve only a handful of viral and cellular proteins. Yet this contact is critical for the outcome of infection and the cellular immune response. We look at these processes to understand which cellular processes are stimulated by viruses and how the host cell interprets an infecting virus at the molecular level. At the scale of single viruses, these processes, their dynamics and structural conditions remain mostly unclear. We thus use advanced microscopy techniques, which allow us to visualize viral and cellular nanostructures during the infection process.
Leendertz: "Human health cannot be viewed in isolation"
Contact between humans and animals is becoming increasingly closer. This is due to the growing world population, the ever deeper intrusion of humans into natural habitats, the hunting of wildlife, and intensive livestock farming and agriculture. Combined with…
New vector vaccine against COVID-19 provides long-term protection
In 2022, researchers from the department “Viral Immunology” headed by Prof. Luka Cicin-Sain at the Helmholtz Centre for Infection Research reported on the novel vector vaccine for the first time. The promising immunogenic profile of the MCMV-based vaccine has now been…
Experimental Immunology
Immune cell populations are characterized by a high degree of heterogeneity to enable efficient and specialized responses to the diverse set of pathogens. This is particularly true for cells of the adaptive immune system, but also innate immune cell populations are heterogeneous and can adapt to different environmental conditions. Adaptation of immune cells is often associated with epigenetic alterations that lead to the fixation of gene expression patterns, finally resulting in cells with highly specialized fates, phenotypes and functional properties.
Innovative Organoid Research
Organoids are miniature models of human organs cultivated from stem cells in laboratory settings. These delicate tissue structures mimic the three-dimensional architecture and function of real organs, offering researchers a unique opportunity to enhance their understanding of biological processes. Our aim is to advance the development of highly complex organoids incorporating immune cells and vessels. By doing so, we establish a platform, especially for investigating infections, conducting vaccine tests, and innovating therapeutic approaches.
LncRNA and Infection Biology
RNA is a truly remarkable molecule with functions and activities far beyond that of an intermediate information carrier. The abundant class of long non-coding RNAs (lncRNAs) contains highly specialized RNA with structural or regulatory functions that range from assembling large protein complexes to localizing, sequestering, or allosterically modifying proteins and other interaction partners. Our genome contains thousands of lncRNAs, many of which are specifically regulated during bacterial or viral infections. However, their contribution to launching and sustaining an effective host response remains elusive. Our group combines a cutting-edge suite of technologies from the fields of biochemistry, genomics, molecular biology, and computational biology to decode how lncRNA work mechanistically and how they contribute to host defense mechanisms. This group is located at the Helmholtz Institute for RNA-based Infection Research (HIRI).
