SubsidieMeestersHow domain mimicry shapes genetic conflicts between hosts and viruses
This project aims to uncover the evolutionary dynamics of viral mimicry and host interactions using advanced modeling and analyses to understand genetic conflicts and predict viral emergence.
Projectdetails
Introduction
Viral mimicry is a prevalent evolutionary mechanism for the acquisition of host-protein domains in order to hijack cellular pathways. By leveraging the similarity between the original host and the mimicked domain, the viral mimic forms interactions with host proteins. This introduces genetic conflict since these interactions are advantageous for the virus and deleterious for the host.
Host Limitations
The host is limited in its capacity to avoid mimics because evolving to escape them can disrupt the host interactome. Elucidating the way in which hosts evolve in the face of mimicry, and the constraints placed on viral mimics, are central to understanding the evolution of genetic conflicts.
Research Approach
To address these questions, we will uniquely combine advanced structural modelling, comparative interactomics, evolutionary analyses, and functional validations to map the functions, interactions, and constraints of viral mimics and their host-interacting proteins. Specifically, we will:
- Map the landscape of mimicry occurrence in viral proteomes to find which domains are mimicked and which viral families tend to acquire such domains.
- Characterize the cellular interactomes of both mimics and host-mimicked domains to identify shared targets between host and mimic, and to find mimic-specific interactions, pointing to neo-functionalization.
- Study the sequence evolution of interface residues between mimics and their host targets.
- Characterize evolutionary mechanisms, such as gene duplication, that may be adaptive for the host or the virus.
Expected Outcomes
Using these novel techniques and integrative analyses, we will unravel the factors shaping the evolution of mimics and their resulting genetic conflicts with the host. These principles are important for understanding the evolution of mechanisms by which viruses acquire new functions, and ultimately for predicting zoonotic potential and viral emergence.
Financiële details & Tijdlijn
Financiële details
| Subsidiebedrag | € 2.000.000 |
| Totale projectbegroting | € 2.000.000 |
Tijdlijn
| Startdatum | 1-10-2025 |
| Einddatum | 30-9-2030 |
| Subsidiejaar | 2025 |
Partners & Locaties
Projectpartners
- TEL AVIV UNIVERSITYpenvoerder
Land(en)
Vergelijkbare projecten binnen European Research Council
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Proving causality of liquid-liquid phase separation for the acquisition of nuclear-like functions by Giant Viruses Viral Factories
ViDaMa aims to elucidate the functions of Mimivirus's viral factories through genome-wide screens and biochemistry, enhancing understanding of viral evolution and improving mRNA production methods.
Deciphering the nanobiophysics of virus-host interactions in 3D cellular systems
This project aims to elucidate virus-host interactions during entry in 3D environments using advanced nanotechniques, potentially leading to new antiviral drug discoveries.
Molecular mimicry as a key parameter shaping T cell immunity
The MIMIC project aims to explore molecular mimicry's role in T cell recognition to enhance cancer immunotherapy by optimizing antigen selection based on pre-existing immunity insights.
Traitor-virus-guided discovery of antiviral factors
This project aims to use CRISPR/Cas9 technology with HIV-1 to uncover antiviral mechanisms, enhancing our understanding and control of viral pathogens for better prevention and therapy.
Functional evolution of giant virus capsids
CAPSOLUTION aims to characterize unique capsid structures of giant viruses in freshwater ecosystems to understand their host attachment strategies and evolutionary adaptations.
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