Jacob T Sanders scite author profile

The three-dimensional structure of chromosomes plays an important role in gene expression regulation and also influences the repair of radiation-induced DNA damage. Genomic aberrations that disrupt chromosome spatial domains can lead to diseases including cancer, but how the 3D genome structure responds to DNA damage is poorly understood. Here, we investigate the impact of DNA damage response and repair on 3D genome folding using Hi-C experiments on wild type cells and ataxia telangiectasia mutated (ATM) patient cells. We irradiate fibroblasts, lymphoblasts, and ATM-deficient fibroblasts with 5 Gy X-rays and perform Hi-C at 30 minutes, 24 hours, or 5 days after irradiation. We observe that 3D genome changes after irradiation are cell type-specific, with lymphoblastoid cells generally showing more contact changes than irradiated fibroblasts. However, all tested repair-proficient cell types exhibit an increased segregation of topologically associating domains (TADs). This TAD boundary strengthening after irradiation is not observed in ATM deficient fibroblasts and may indicate the presence of a mechanism to protect 3D genome structure integrity during DNA damage repair.

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Iteratively improving Hi-C experiments one step at a time

Golloshi

Sanders

McCord

2018

Methods

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The 3D organization of eukaryotic chromosomes affects key processes such as gene expression, DNA replication, cell division, and response to DNA damage. The genome-wide chromosome conformation capture (Hi-C) approach can characterize the landscape of 3D genome organization by measuring interaction frequencies between all genomic regions. Hi-C protocol improvements and rapid advances in DNA sequencing power have made Hi-C useful to study diverse biological systems, not only to elucidate the role of 3D genome structure in proper cellular function, but also to characterize genomic rearrangements, assemble new genomes, and consider chromatin interactions as potential biomarkers for diseases. Yet, the Hi-C protocol is still complex and subject to variations at numerous steps that can affect the resulting data. Thus, there is still a need for better understanding and control of factors that contribute to Hi-C experiment success and data quality. Here, we evaluate recently proposed Hi-C protocol modifications as well as often overlooked variables in sample preparation and examine their effects on Hi-C data quality. We examine artifacts that can occur during Hi-C library preparation, including microhomology-based artificial template copying and chimera formation that can add noise to the downstream data. Exploring the mechanisms underlying Hi-C artifacts pinpoints steps that should be further optimized in the future. To improve the utility of Hi-C in characterizing the 3D genome of specialized populations of cells or small samples of primary tissue, we identify steps prone to DNA loss which should be considered to adapt Hi-C to lower cell numbers.

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Mitotic clustering of pulverized chromosomes from micronuclei

Lin

Mazzagatti

et al. 2023

Nature

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Complex genome rearrangements can be generated by the catastrophic pulverization of missegregated chromosomes trapped within micronuclei through a process known as chromothripsis1–5. As each chromosome contains a single centromere, it remains unclear how acentric fragments derived from shattered chromosomes are inherited between daughter cells during mitosis6. Here we tracked micronucleated chromosomes with live-cell imaging and show that acentric fragments cluster in close spatial proximity throughout mitosis for asymmetric inheritance by a single daughter cell. Mechanistically, the CIP2A–TOPBP1 complex prematurely associates with DNA lesions within ruptured micronuclei during interphase, which poises pulverized chromosomes for clustering upon mitotic entry. Inactivation of CIP2A–TOPBP1 caused acentric fragments to disperse throughout the mitotic cytoplasm, stochastically partition into the nucleus of both daughter cells and aberrantly misaccumulate as cytoplasmic DNA. Mitotic clustering facilitates the reassembly of acentric fragments into rearranged chromosomes lacking the extensive DNA copy-number losses that are characteristic of canonical chromothripsis. Comprehensive analysis of pan-cancer genomes revealed clusters of DNA copy-number-neutral rearrangements—termed balanced chromothripsis—across diverse tumour types resulting in the acquisition of known cancer driver events. Thus, distinct patterns of chromothripsis can be explained by the spatial clustering of pulverized chromosomes from micronuclei.

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Investigation of Spatial Organization of Chromosome Territories in Chromosome Exchange Aberrations After Ionizing Radiation Exposure

et al. 2018

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Higher-order organization of the human genome is well established with chromosomes occupying distinct domains or territories in the interphase nucleus. Spatial organization of chromosome territories in the interphase nucleus occurs in a cell-type-specific manner. Since both stable and unstable aberrations induced by ionizing radiation involve the exchange of material between two or more chromosomes, this study investigated the role of spatial organization of chromosome domains in ionizing-radiation-induced chromosome translocation events. Using multicolor fluorescence in situ hybridization, the study characterized the positioning of each human chromosome relative to its neighborhood territories in the interphase nucleus of lymphocytes and B-lymphoblastoid cells before ionizing radiation and compared this interphase positioning with the spectrum of exchanges observed after ionizing radiation in the metaphase chromosomes. In addition to multicolor fluorescence in situ hybridization, the genome-wide chromosome conformation capture technique (Hi-C) was also performed in mock and x-ray-irradiated human B-lymphoblastoid and fibroblast cells to characterize the interactions among chromosomes and to assess the genome reorganization changes, if any, after ionizing radiation exposure. On average, 35-50% of the total translocations induced by x rays and neutrons correlated with proximity of chromosome territories detected by multicolor fluorescence in situ hybridization in both lymphocytes and lymphoblastoid cells. The translocation rate observed in proximally positioned chromosome territories was consistently higher than distally located territories and was found to be statistically significant (p = 0.01) in human lymphoblastoid cells after x rays. The interchromosome interaction frequencies detected by Hi-C correlate fairly well with ionizing-radiation-induced translocations detected by multicolor fluorescence in situ hybridization, suggesting the importance of chromosome proximity effects in ionizing-radiation-induced chromosomal translocation events.

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Jacob T Sanders

Radiation-induced DNA damage and repair effects on 3D genome organization

Iteratively improving Hi-C experiments one step at a time

Mitotic clustering of pulverized chromosomes from micronuclei

Investigation of Spatial Organization of Chromosome Territories in Chromosome Exchange Aberrations After Ionizing Radiation Exposure

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