Project description:Bacterial artificial chromosomes establish replication timing and sub-nuclear compartment de novo as extra-chromosomal vectors [4C]
Project description:The role of DNA sequence in determining replication timing (RT) and chromatin higher order organization remains elusive. To address this question, we have developed an extra-chromosomal replication system consisting of ~200kb human bacteria artificial chromosomes (BACs) modified with Epstein-Barr virus (EBV) replication origin elements (E-BACs). E-BACs were stably maintained as autonomous mini-chromosomes in both HeLa and human induced pluripotent stem cells (hiPSCs) and established their RT de novo. We applied repli-seq to evaluate E-BACs' replication timing.
Project description:The role of DNA sequence in determining replication timing (RT) and chromatin higher order organization remains elusive. To address this question, we have developed an extra-chromosomal replication system consisting of ~200kb human bacteria artificial chromosomes (BACs) modified with Epstein-Barr virus (EBV) replication origin elements (E-BACs). E-BACs were stably maintained as autonomous mini-chromosomes in both HeLa and human induced pluripotent stem cells (hiPSCs) and established their RT de novo. We applied 4C-seq to evaluate E-BACs' sub-nuclear compartment.
Project description:Whole genome doubling (WGD) is a recurrent event in human cancers and it promotes chromosomal instability and acquisition of aneuploidies. However, the 3D organization of the chromatin in WGD cells and its contribution to oncogenic phenotypes are currently unknown. Here, we show that in p53 deficient cells WGD induces loss of chromatin segregation (LCS), characterized by reduced segregation between short and long chromosomes, A and B sub-compartments, and adjacent chromatin domains. LCS is driven by downregulation of CTCF and H3K9me3 in cells that bypassed activation of the tetraploid checkpoint. Longitudinal analyses revealed that LCS primed genomic regions for sub-compartment repositioning in WGD cells, which resulted in chromatin and epigenetic changes associated with oncogene activation in tumours ensuing from WGD cells. Importantly, sub-compartment repositioning events were largely independent of chromosomal alterations, indicating that these were complementary mechanisms contributing to tumour development and progression. Overall, LCS initiates chromatin conformation changes that ultimately result in oncogenic epigenetic and transcriptional modifications, suggesting that chromatin evolution is a hallmark of WGD-driven cancer.
Project description:Whole genome doubling (WGD) is a recurrent event in human cancers and it promotes chromosomal instability and acquisition of aneuploidies. However, the 3D organization of the chromatin in WGD cells and its contribution to oncogenic phenotypes are currently unknown. Here, we show that in p53 deficient cells WGD induces loss of chromatin segregation (LCS), characterized by reduced segregation between short and long chromosomes, A and B sub-compartments, and adjacent chromatin domains. LCS is driven by downregulation of CTCF and H3K9me3 in cells that bypassed activation of the tetraploid checkpoint. Longitudinal analyses revealed that LCS primed genomic regions for sub-compartment repositioning in WGD cells, which resulted in chromatin and epigenetic changes associated with oncogene activation in tumours ensuing from WGD cells. Importantly, sub-compartment repositioning events were largely independent of chromosomal alterations, indicating that these were complementary mechanisms contributing to tumour development and progression. Overall, LCS initiates chromatin conformation changes that ultimately result in oncogenic epigenetic and transcriptional modifications, suggesting that chromatin evolution is a hallmark of WGD-driven cancer.
Project description:Whole genome doubling (WGD) is a recurrent event in human cancers and it promotes chromosomal instability and acquisition of aneuploidies. However, the 3D organization of the chromatin in WGD cells and its contribution to oncogenic phenotypes are currently unknown. Here, we show that in p53 deficient cells WGD induces loss of chromatin segregation (LCS), characterized by reduced segregation between short and long chromosomes, A and B sub-compartments, and adjacent chromatin domains. LCS is driven by downregulation of CTCF and H3K9me3 in cells that bypassed activation of the tetraploid checkpoint. Longitudinal analyses revealed that LCS primed genomic regions for sub-compartment repositioning in WGD cells, which resulted in chromatin and epigenetic changes associated with oncogene activation in tumours ensuing from WGD cells. Importantly, sub-compartment repositioning events were largely independent of chromosomal alterations, indicating that these were complementary mechanisms contributing to tumour development and progression. Overall, LCS initiates chromatin conformation changes that ultimately result in oncogenic epigenetic and transcriptional modifications, suggesting that chromatin evolution is a hallmark of WGD-driven cancer.
