Summary
Cell viability and homeostasis rely on the stable maintenance of the epigenetic information conveyed by chromatin, which associates DNA and histone proteins in the cell nucleus and governs gene expression programs. Yet, epigenome integrity is challenged during all DNA transactions, including DNA damage repair. While much effort has been devoted to characterizing chromatin alterations in response to DNA damage and how they contribute to the repair response, our knowledge of this fundamental process is largely incomplete, and whether and how epigenetic features are re-established following a genotoxic stress challenge is still unexplored. Thus, a comprehensive framework of the mechanisms underlying the maintenance of epigenome integrity in response to DNA damage is lacking.
The present project aims to fill this important gap by profiling the epigenome of repair patches following UVC damage in human cells and by characterizing the molecular players contributing to chromatin restoration/plasticity. I propose an integrated approach that tackles this question at different levels of chromatin organization, from histone and DNA modifications up to higher-order chromatin folding.
Building on our unique expertise and through the development of powerful novel methodologies, combining cutting-edge imaging, proteomics and epigenomic technologies, we will elucidate mechanisms for (1) histone modification re-establishment and maintenance and (2) DNA methylation inheritance at repair sites. We will also investigate how repair-associated changes in DNA and histone modifications reflect at the level of (3) higher-order chromatin organization in the tridimensional nuclear space, and dissect (4) functional crosstalks between the epigenetic changes that arise in damaged chromatin. This ambitious research project represents an unprecedented effort towards a comprehensive and integrated understanding of epigenome maintenance mechanisms in response to genotoxic stress.
The present project aims to fill this important gap by profiling the epigenome of repair patches following UVC damage in human cells and by characterizing the molecular players contributing to chromatin restoration/plasticity. I propose an integrated approach that tackles this question at different levels of chromatin organization, from histone and DNA modifications up to higher-order chromatin folding.
Building on our unique expertise and through the development of powerful novel methodologies, combining cutting-edge imaging, proteomics and epigenomic technologies, we will elucidate mechanisms for (1) histone modification re-establishment and maintenance and (2) DNA methylation inheritance at repair sites. We will also investigate how repair-associated changes in DNA and histone modifications reflect at the level of (3) higher-order chromatin organization in the tridimensional nuclear space, and dissect (4) functional crosstalks between the epigenetic changes that arise in damaged chromatin. This ambitious research project represents an unprecedented effort towards a comprehensive and integrated understanding of epigenome maintenance mechanisms in response to genotoxic stress.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/818625 |
| Start date: | 01-03-2019 |
| End date: | 28-02-2025 |
| Total budget - Public funding: | 1 738 750,00 Euro - 1 738 750,00 Euro |
Cordis data
Original description
Cell viability and homeostasis rely on the stable maintenance of the epigenetic information conveyed by chromatin, which associates DNA and histone proteins in the cell nucleus and governs gene expression programs. Yet, epigenome integrity is challenged during all DNA transactions, including DNA damage repair. While much effort has been devoted to characterizing chromatin alterations in response to DNA damage and how they contribute to the repair response, our knowledge of this fundamental process is largely incomplete, and whether and how epigenetic features are re-established following a genotoxic stress challenge is still unexplored. Thus, a comprehensive framework of the mechanisms underlying the maintenance of epigenome integrity in response to DNA damage is lacking.The present project aims to fill this important gap by profiling the epigenome of repair patches following UVC damage in human cells and by characterizing the molecular players contributing to chromatin restoration/plasticity. I propose an integrated approach that tackles this question at different levels of chromatin organization, from histone and DNA modifications up to higher-order chromatin folding.
Building on our unique expertise and through the development of powerful novel methodologies, combining cutting-edge imaging, proteomics and epigenomic technologies, we will elucidate mechanisms for (1) histone modification re-establishment and maintenance and (2) DNA methylation inheritance at repair sites. We will also investigate how repair-associated changes in DNA and histone modifications reflect at the level of (3) higher-order chromatin organization in the tridimensional nuclear space, and dissect (4) functional crosstalks between the epigenetic changes that arise in damaged chromatin. This ambitious research project represents an unprecedented effort towards a comprehensive and integrated understanding of epigenome maintenance mechanisms in response to genotoxic stress.
Status
SIGNEDCall topic
ERC-2018-COGUpdate Date
27-04-2024
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