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Displaying results 1 to 10 of 72.
Molecular Principles of RNA Phages
The research group led by Jens Hör investigates the dynamics of infection, host takeover, and anti-phage defense during the interaction between RNA phages and their hosts. They seek to understand the molecular principles underlying these processes to develop new and improved antibacterial strategies such as phage therapy.
Integrative Informatics for Infection Biology
Recent years have seen accelerating development of high-throughput technologies in infection biology. Now, thousands of genetic loci can be simultaneously interrogated in a single experiment, providing an array of measurements of transcription, translation, regulatory interactions, and fitness effects. The bottleneck in advancing our understanding of pathogens now lies in moving from hypothesis-free screening through data integration to hypothesis generation. We develop new statistical, computational, and visualization approaches to overcome this bottleneck in the interpretation of complex post-genomic data. This group is located at the Helmholtz Institute for RNA-based Infection Research (HIRI).
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 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.
Single-cell Analysis
Pathogenic bacteria can reside in a mammalian host for a life-long period and chronic carriers form a reservoir leading to recurrent infections. Despite the importance of chronic infections for public health, how a subset of pathogens escape the host’s immune surveillance and how the host contains the spread of bacteria are still poorly understood. Scientists within the Single-Cell Analysis group develop and use single-cell transcriptomics and computational approaches to decipher the microenvironments of individual pathogens and ultimately their functional consequences on infection outcome. This group is located at the Helmholtz Institute for RNA-based Infection Research (HIRI).
Chemical Biology
In their ongoing quest for new therapies against pathogens, scientists are focusing primarily on chemical agents. Discovering new bioactive compounds, characterising their functionality and optimising their properties are the three main goals of the Department of Chemical Biology (CBIO) at the HZI.
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) .
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) .
Cell Biology
Recent reports published by the World Health Organization (WHO) entitled "The Global Burden of Disease" (GBD) highlights the importance of research on host-pathogen interactions. Evolution is an ongoing process driving the development of highly virulent and multi-resistant bacteria strains or so called “emerging pathogens“. A deeper understanding of the complex interaction between pathogenic bacteria and their host is inevitable to face these problems in the future. As Cell biologists, we address host-pathogen interaction on the level of single cells, embodying the smallest living unit on both sides. Upon contact, pathogens need to manipulate the normal behavior of host cells in order to establish a niche for survival and to evade the hosts defense mechanisms. We study these induced changes on the cellular and molecular level, in order to exactly understand which host process is targeted by a given virulence mechanism an why.
