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Displaying results 61 to 70 of 80.
Ecology and Emergence of Zoonoses
Zoonoses, diseases transmitted between animals and humans, substantially threaten human health, but also domestic animals and wildlife. Influenced by climate change, globalization, anthropogenic disturbance and habitat fragmentation, contacts at human-animal interfaces become more frequent, thus increasing the risk of zoonotic emergence and, ultimately, pandemics. Our research aims to understand emergence and ecology of such zoonoses, i.e., how pathogens are transmitted between populations, landscapes and ecosystems. By incorporating data on the biotic and abiotic context of these transmissions, we generate evidence that allows us to contribute to pandemic preparedness and prevention. This department is located at the Helmholtz Institute for One Health (HIOH) .
Neuroinflammation and Neurodegeneration
What kind of role play infections and the associated inflammatory reactions for the progression or even for the onset of neurodegenerative diseases? Recurrent infections and the involved inflammation may trigger a series of processes in the brain that finally lead to neuronal damage due to the immune response. Thus, better understanding of neurodegenerative processes could improve the therapeutic approach in neurodegenerative disease.
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.
Molecular Cell Biology
The cytoskeleton is responsible for mechanical stabilisation of the cell, for its motility and intracellular transport processes as well as for maintenance and change of its overall shape. The research group Molecular Cell Biology focusses on one specific part of the so called cytoskeleton: the actin cytoskeleton. The dynamics and turnover of filaments of the actin cytoskeleton are particularly relevant for effective immune responses, and are also frequently targeted by pathogens. Understanding the molecular mechanisms mediating assembly and disassembly of this filament system is thus among the main goals of Klemens Rottner and his team.
Molecular Structural Biology
Combating infectious diseases depends critically on a deep understanding of the underlying molecular processes. Structural biology plays a crucial role in advancing biomedicine by providing valuable insights into the structure, function, and interactions of biological macromolecules at the atomic and molecular level. It combines state-of-the-art techniques such as X-ray crystallography, nuclear magnetic resonance (NMR) spectroscopy and cryo-electron microscopy (cryo-EM) as well as advanced computer-based structure prediction methods to elucidate and analyze the three-dimensional structures of proteins, nucleic acids, and other biomolecules. Thus structural biology plays a critical role in infection research by providing a precise view on virulence factors, host-pathogen interactions, and the mechanisms of pathogenesis and host defense, paving the way towards the development of new anti-infectives and vaccines.
Molecular Bacteriology
Hospital-acquired infections are a major challenge and cause suffering, incapacity and death. In many cases the pathogens are resistant to antibiotics and, therefore, very difficult to combat. Read more about how bacteria join forces and what the researchers can do to avoid that. The group Molecular Bacteriology is based at the HZI and the TWINCORE in Hannover.
Laboratory of Transmission Immunology
Transmission of viruses is only possible during a specific time frame after infection: we can call this the “window of transmission”. A major gap in mitigating (e.g., airborne) transmission and closing this window quickly is the lack of understanding of critical immune determinants of efficient transmission. To be able to close the window of transmission through the design of better mitigation strategies, we develop a mechanistic understanding of the spatial and longitudinal interplay between virus tropism, innate and adaptive immune responses, changes in host physiology, and exhalation or shedding of infectious virus in droplets or fluids.
Genome Analytics
The Genome Analytics (GMAK) facility provides next-generation sequencing (NGS) technology to the HZI. External users may also have access to the technology, e.g. upon collaborative arrangements. In addition to sample DNA/RNA quality check, library preparation and sequencing, the facility provides primary data processing, data quality check and analysis. A number of pipelines for secondary data processing are established.
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.
Immune Regulation
Due to their physiological functions our mucosal surfaces are in direct contact to the environment and thus represent the major port of entry for pathogens. To protect the body from severe infections an effective mucosal immune system is indispensable. We are studying respiratory tract infections with the focus on influenza and pneumococci, which represent the most frequent viral and bacterial infectious agents for pneumonia in humans. A major focus of our research is to study molecular and cellular processes during coinfection with influenza and pneumococci and here in particular the immunological functions of the alveolar epithelium in host defense.
