Project description
Deciphering the mechanisms of the viral infection process
The molecular mechanisms of viral infection and evasion of the immune system in mammalian hosts remains poorly understood. The EU-funded CHUbVi project will identify the pathways involved in the infection process, with the goal of providing molecular targets for broad-spectrum antiviral compounds. The team's previous studies observed that histone deacetylase 6 and unanchored ubiquitin chains act as key mediators of viral entry via the aggresome processing pathway that organises misfolded proteins into particular locations, when the protein-degradation system of the cell is overwhelmed. Detailed studies of the involvement of this pathway will allow the development of biochemical and cellular assays for influenza A infection as well as the investigation of whether this pathway relates to the infection process of other viruses including Zika, dengue, Ebola and MERS.
Objective
Viruses such as Influenza A (IAV) and others remain one of the greatest threats to human health and society. Despite their danger and widespread prevalence, the molecular mechanisms of how they infect mammalian hosts and evade the immune system remains poorly understood. Recent studies from our team implicate two common proteins – HDAC6 and unanchored ubiquitin chains – in host cells as key mediators of viral entry via the aggresome processing pathway. This discovery offers a new line of investigation for understanding and preventing viral infections.
By identifying the pathways and interactions involved in this infection process, we will provide new molecular targets for the development of broad-spectrum antiviral compounds. Multidisciplinary studies by a team consisting of a molecular biologist, a virologist, and a chemical biologist will use a diverse set of tools to validate these pathways and gain fundamental knowledge about their regulation. To achieve this, detailed studies on the exact nature of the ubiquitin chains needed to activate HDAC6 will allow the development of biochemical and cellular assays of Influenza A infection and enable the determination of the precise mechanism and the downstream cellular pathways necessary for viral infection. The chemical synthesis of labeled ubiquitin chains will support detailed structural studies and a clear understanding of how they are formed and packaged into infectious viral particles. The strong possibility that numerous other virus types also utilize this pathway will be tested with life-threatening agents of current concern including Zika, Dengue, Ebola, and MERS viruses.
By demonstrating – with both biological approaches and small molecule compounds – that blocking these cellular processes in cells and animal models reduces viral infection, this project will provide a wealth a novel insights and the basis for the development of a new generation of anti-viral therapies.
Fields of science
- natural sciencesbiological sciencesmicrobiologyvirology
- medical and health scienceshealth sciencesinfectious diseasesRNA virusesebola
- natural sciencesbiological sciencesbiochemistrybiomoleculesproteins
- medical and health scienceshealth sciencesinfectious diseasesRNA virusesinfluenza
- medical and health sciencesbasic medicineimmunology
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Funding Scheme
ERC-SyG - Synergy grantHost institution
4056 BASEL
Switzerland