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Displaying results 31 to 40 of 1436.
Anti-infectives from Microbiota
The department of Prof Christine Beemelmanns focuses on the identification and functional analysis of novel anti-infective natural products from microbial communities. Co-cultivation studies as well as cell-based assays in combination with chemical-analytical and molecular-biological methods are used to evaluate and prioritize novel natural product producers. The department uses established and innovative metabolomic-, activity and genome-based methods to identify and determine the structure of the secreted natural products. Based on the isolated novel natural substances, the functional analysis and evaluation of their range of effects is carried out. This department is located at the Helmholtz Institute for Pharmaceutical Research Saarland (HIPS) .
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.
Microbial Proteomics
A genome contains all the information that is needed to build an organism like, for instance, a bacterium. One of functional genomics’ central questions is: How are these blueprints implemented so that relatively simple molecular codes ultimately give rise to a microorganism with the potential of getting us sick? What are some of the underlying mechanisms and under what conditions do they become activated?
Experimental Virology
Viruses are tiny vehicles that transport biological information to reprogram the functions of human, animal, or plant cells in order to replicate. So-called "enveloped" viruses consist of only one layer of proteins, are filled with genetic material, and are surrounded by a thin shell of lipids in which viral proteins are embedded. Even though viruses are tiny and have a simple build, viral pathogens such as the hepatitis C virus (HCV), respiratory syncytial virus (RSV), and SARS-CoV-2 have the potential to threaten the health of millions of people. Here at the Institute for Experimental Virology, we focus on fundamental and translational RNA virus research. Our research groups combine the expertise of molecular and cell biological approaches with computational methods to help elucidate viral replication mechanisms to develop new therapeutic and preventive strategies.
Biological Barriers and Drug Delivery
While considering the confusing flood of drugs in the pharmacies it is hard to believe in a lack of medication. But there are still many infectious diseases and also cancer that cannot be treated sufficiently. During a medical treatment it is essential that the drug arrives at the envisaged body region. Read more about the research of the department “Biological Barriers and Drug Delivery” on techniques for the correct distribution of novel drugs. This group is located at the Helmholtz Institute for Pharmaceutical Research Saarland (HIPS) .
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.
Virology and Innate Immunity
Pathogens (germs) infiltrate our bodies daily but do not remain undetected. They encounter the strong defenses of our immune system, which recognizes invaders and promptly takes appropriate measures. However, many pathogens can produce life-long infections even with an intact immune system. The herpesvirus family is one such group of pathogens. Upon infection, herpesviruses establish a chronic infection and become lifelong companions.
Vaccinology and Applied Microbiology
Vaccination is the most efficient strategy to prevent infectious diseases. The art of the vaccine researcher lies in finding substances that prevent us from falling ill with diseases such as influenza or viral hepatitis. But what makes a vaccine successful and ensures effective protection? Our scientists study the reaction of the immune system to answer that question – and to develop better vaccination strategies.
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) .
Computational Biology for Infection Research
The Department of “Computational Biology for Infection Research” studies the human microbiome, viral and bacterial pathogens, and human cell lineages within individual patients by analysis of large-scale biological and epidemiological data sets with computational techniques. Focusing on high throughput meta’omics, population genomic and single cell sequencing data, we produce testable hypotheses, such as sets of key sites or relevant genes associated with the presence of a disease, of antibiotic resistance or pathogenic evasion of immune defense. We interact with experimental collaborators to verify our findings and to promote their translation into medical treatment or diagnosis procedures. To achieve its research goals, the department also develops novel algorithms and software.
