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Displaying results 21 to 30 of 73.
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).
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.
Microbial Immune Regulation
The microbiota encompasses a diverse population of microorganisms that colonize many body sites such as skin and intestine of multicellular hosts. The composition of the microbiota in humans is highly variable and is influenced by nutrition, immune competence, illness and use of medication (especially antibiotics). We are interested to enhance our understanding on how these microbial communities affect human infectious diseases and how they can be manipulated to treat diseases.
Cellular Metabolism in Infection
With a focus on applying mass spectrometry and tracing approaches, the research group “Cellular Metabolism in Infection” (CMII) headed by Prof Thekla Cordes tracks metabolic pathways, leading to discoveries about the role of small molecules influencing immune cell metabolism and function.
Genome Architecture and Evolution of RNA Viruses
RNA viruses are a major threat to human health and responsible for millions of deaths each year. Their replication is orchestrated by the RNA genome, which encodes for viral proteins needed to hijack the host cell. Traditionally, infectious disease research has focused on blocking viral replication by inhibiting these proteins. However, we now appreciate that the genomes of RNA viruses are not just passive carriers of protein coding information, but active participants in the viral infection process through the action of non-coding RNA. We study the structure and function of viral non-coding RNA, with the goal of harnessing the resulting knowledge in the design of next generation RNA-based therapies. This group is located at the Helmholtz Institute for RNA-based Infection Research (HIRI) .
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?
Microbial Natural Products
Even today efficient drugs against many diseases are missing but finding new active substances is very complex. Support comes out of the ground. Myxobacteria are soil-living microorganisms that produce many active agents. Here you learn more about the search for new compounds with biological activity. This department is located at the Helmholtz Institute for Pharmaceutical Research Saarland (HIPS) .
Microbial Interactions and Processes
Microorganisms in the environment are living in complex and interacting communities. Also the surfaces of the human body are inhabited by microorganisms, where the bacterial cell number significantly exceeds that of the human cells. These communities have co-evolved with the human host and are important for human health. They can, however, also be a reservoir for pathogenic microorganisms.
Model Systems for Infection and Immunity
In infection research experiments on cells and mice have a pivotal role. Frequently such model systems have to be tailored to allow tackling a specific scientific question. To this end, genetic modification of cell lines and mice is being pursued.
Human-Microbe Systems Bioinformatics
The human body encompasses fewer human cells than microbes. They constantly interact with each other and the host and greatly affect an individual's health and well-being. In our group, we develop and apply state-of-the-art bioinformatics software to study the human-microbe systems and aim to discover natural products involved in communication between the two realms. This group is located at the Helmholtz Institute for Pharmaceutical Research Saarland (HIPS) .
