Summary
DNA lesions can impose serious threats to genome integrity and cell viability. Whereas DNA damage may occur anywhere in the genome, it is increasingly recognized that certain genomic loci rich in repetitive sequences display increased susceptibility to damage and are linked to chromosomal rearrangements and malignancy. Clusters of ribosomal DNA gene (rDNA) repeats, present on five different chromosomes, constitute the most heavily transcribed area of the human genome and are organized in a nuclear membrane-less organelle, the nucleolus. So far, putative links between rDNA damage and malignant processes have not been rigorously assessed.
We will address the hypothesis that rDNA repeats represent a major hub of genomic instability contributing to malignant transformation. Using state-of-the-art experimental systems that allow enrichment for nucleolar DNA damage, we will explore: (i) hypothesis-driven and mass spectrometry-based approaches to define regulators of the rDNA damage response; (ii) live imaging and advanced molecular biology tools to uncover how histone epigenetic changes and formation of RNA:DNA hybrids impact on nucleolar chromatin, nucleolar organization, rDNA transcription and repair ; (iii) cell models that recapitulate malignant transformation caused by inducible oncogene expression or epigenetic inactivation of tumour suppressors, to assess replication stress in rDNA repeats as a primary source of genomic instability and pertinent to hallmarks of cancer.
The proposed research is expected to yield novel insights into the signaling networks and biological processes regulating rDNA damage and repair within the nuclear environment and define how these mechanisms are corrupted during neoplastic transformation. This knowledge could be directly applicable to the design of new diagnostic or therapeutic strategies for cancer.
We will address the hypothesis that rDNA repeats represent a major hub of genomic instability contributing to malignant transformation. Using state-of-the-art experimental systems that allow enrichment for nucleolar DNA damage, we will explore: (i) hypothesis-driven and mass spectrometry-based approaches to define regulators of the rDNA damage response; (ii) live imaging and advanced molecular biology tools to uncover how histone epigenetic changes and formation of RNA:DNA hybrids impact on nucleolar chromatin, nucleolar organization, rDNA transcription and repair ; (iii) cell models that recapitulate malignant transformation caused by inducible oncogene expression or epigenetic inactivation of tumour suppressors, to assess replication stress in rDNA repeats as a primary source of genomic instability and pertinent to hallmarks of cancer.
The proposed research is expected to yield novel insights into the signaling networks and biological processes regulating rDNA damage and repair within the nuclear environment and define how these mechanisms are corrupted during neoplastic transformation. This knowledge could be directly applicable to the design of new diagnostic or therapeutic strategies for cancer.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/850782 |
| Start date: | 01-06-2020 |
| End date: | 31-05-2025 |
| Total budget - Public funding: | 1 499 525,00 Euro - 1 499 525,00 Euro |
Cordis data
Original description
DNA lesions can impose serious threats to genome integrity and cell viability. Whereas DNA damage may occur anywhere in the genome, it is increasingly recognized that certain genomic loci rich in repetitive sequences display increased susceptibility to damage and are linked to chromosomal rearrangements and malignancy. Clusters of ribosomal DNA gene (rDNA) repeats, present on five different chromosomes, constitute the most heavily transcribed area of the human genome and are organized in a nuclear membrane-less organelle, the nucleolus. So far, putative links between rDNA damage and malignant processes have not been rigorously assessed.We will address the hypothesis that rDNA repeats represent a major hub of genomic instability contributing to malignant transformation. Using state-of-the-art experimental systems that allow enrichment for nucleolar DNA damage, we will explore: (i) hypothesis-driven and mass spectrometry-based approaches to define regulators of the rDNA damage response; (ii) live imaging and advanced molecular biology tools to uncover how histone epigenetic changes and formation of RNA:DNA hybrids impact on nucleolar chromatin, nucleolar organization, rDNA transcription and repair ; (iii) cell models that recapitulate malignant transformation caused by inducible oncogene expression or epigenetic inactivation of tumour suppressors, to assess replication stress in rDNA repeats as a primary source of genomic instability and pertinent to hallmarks of cancer.
The proposed research is expected to yield novel insights into the signaling networks and biological processes regulating rDNA damage and repair within the nuclear environment and define how these mechanisms are corrupted during neoplastic transformation. This knowledge could be directly applicable to the design of new diagnostic or therapeutic strategies for cancer.
Status
TERMINATEDCall topic
ERC-2019-STGUpdate Date
27-04-2024
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