DNA Damage Follows Repair Factor Depletion and Portends Genome Variation in Cancer Cells after Pore Migration

Irianto, Jerome; Xia, Yuntao; Pfeifer, Charlotte R.; Athirasala, Avathamsa; Ji, Jiazheng; Alvey, Cory; Tewari, Manorama; Bennett, Rachel R.; Harding, Shane M.; Liu, Andrea J.; Greenberg, Roger A.; Discher, Dennis E.

doi:10.1016/j.cub.2016.11.049

Cited by 254 publications

(335 citation statements)

References 50 publications

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“…When MCF10A cells were subjected to migration through 3µm pores we observed cGAS localization to both micronuclei and nuclear blebs consistent with nuclear envelop disruption and transient DSB production (Extended data 4d and 4e) 20 . cGAS positivity of these subcellular structures still occurred in the presence of CDKi, demonstrating that mechanical nuclear rupture bypasses the need for mitotic progression.…”

mentioning

confidence: 58%

Mitotic progression following DNA damage enables pattern recognition within micronuclei

Harding

Benci

Irianto

et al. 2017

Nature

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Inflammatory gene expression following genotoxic cancer therapy is well documented, yet the events underlying its induction remain poorly understood. Inflammatory cytokines modify the tumor microenvironment by recruiting immune cells and are critical for both local and systemic (abscopal) tumor responses to radiotherapy1. An enigmatic feature of this phenomenon is its delayed onset (days), in contrast to the acute DNA damage responses that occur in minutes to hours. Such dichotomous kinetics implicate additional rate limiting steps that are essential for DNA-damage induced inflammation. Here, we show that cell cycle progression through mitosis following DNA double-strand breaks (DSBs) leads to the formation of micronuclei, which precede activation of inflammatory signaling and are a repository for the pattern recognition receptor cGAS. Inhibiting progression through mitosis or loss of pattern recognition by cGAS-STING impaired interferon signaling. Moreover, STING loss prevented the regression of abscopal tumors in the context of ionizing radiation and immune checkpoint blockade in vivo. These findings implicate temporal modulation of the cell cycle as an important consideration in the context of therapeutic strategies that combine genotoxic agents with immune checkpoint blockade.

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mentioning

confidence: 58%

Mitotic progression following DNA damage enables pattern recognition within micronuclei

Harding

Benci

Irianto

et al. 2017

Nature

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718

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“…During interphase, cGAS can be rapidly detected at sites of NE rupture at the nuclear periphery, which is subsequently followed by the focal acquisition of DNA damage [43, 44]. Similar rupturing events were reported to promote genomic copy number aberrations [48], and cGAS has been shown to associate with condensed chromosomes after NE breakdown during mitosis [49]. Consistent with this, recent work confirmed that cGAS could indeed sense micronuclear DNAs exposed to the cytoplasm following micro-NE disruption as cytosolic self-DNA [50], although the downstream consequences on the micronuclear chromosome itself are unknown.…”

Section: Sources Of Micronuclear Dna Damagementioning

confidence: 92%

Rebuilding Chromosomes After Catastrophe: Emerging Mechanisms of Chromothripsis

Cleveland

2017

Trends in Cell Biology

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Cancer genome sequencing has identified chromothripsis, a complex class of structural genomic rearrangements involving the apparent shattering of an individual chromosome into tens to hundreds of fragments. An initial error during mitosis, producing either chromosome missegregation into a micronucleus or chromatin bridge interconnecting two daughter cells, can trigger the catastrophic pulverization of the spatially isolated chromosome. The resultant chromosomal fragments are re-ligated in random order by DNA double-strand break repair during the subsequent interphase. Chromothripsis scars the cancer genome with localized DNA rearrangements that frequently generate extensive copy number alterations, oncogenic gene fusion products, and/or tumor suppressor gene inactivation. Here we review emerging mechanisms underlying chromothripsis with a focus on the contribution of cell division errors caused by centromere dysfunction.

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“…37–40 Note that in the absence of CDK inhibitors, DNA-damaged cells acquire deformed polyploid nuclei. 41,42 In response to Shh-mediated developmental signals, NOTCH1/2 facilitate the clearance of the tumor suppressor Ptch1, the concurrent accumulation of the Shh signal-transducing protein encoded by SMO , and the increased downstream conversion of the proteins encoded by the oncogenes GLI1/3 into cell cycle transcriptional activators. 43,44 Note that Notch is critical for an Shh-induced medulloblastoma brain cancer tumor’s development.…”

Section: Astrocytoma Tumor-exclusive Genotype and Phenotypementioning

confidence: 99%

Mathematically universal and biologically consistent astrocytoma genotype encodes for transformation and predicts survival phenotype

2018

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DNA alterations have been observed in astrocytoma for decades. A copy-number genotype predictive of a survival phenotype was only discovered by using the generalized singular value decomposition (GSVD) formulated as a comparative spectral decomposition. Here, we use the GSVD to compare whole-genome sequencing (WGS) profiles of patient-matched astrocytoma and normal DNA. First, the GSVD uncovers a genome-wide pattern of copy-number alterations, which is bounded by patterns recently uncovered by the GSVDs of microarray-profiled patient-matched glioblastoma (GBM) and, separately, lower-grade astrocytoma and normal genomes. Like the microarray patterns, the WGS pattern is correlated with an approximately one-year median survival time. By filling in gaps in the microarray patterns, the WGS pattern reveals that this biologically consistent genotype encodes for transformation via the Notch together with the Ras and Shh pathways. Second, like the GSVDs of the microarray profiles, the GSVD of the WGS profiles separates the tumor-exclusive pattern from normal copy-number variations and experimental inconsistencies. These include the WGS technology-specific effects of guaninecytosine content variations across the genomes that are correlated with experimental batches. Third, by identifying the biologically consistent phenotype among the WGS-profiled tumors, the GBM pattern proves to be a technology-independent predictor of survival and response to chemotherapy and radiation, statistically better than the patient’s age and tumor’s grade, the best other indicators, and MGMT promoter methylation and IDH1 mutation. We conclude that by using the complex structure of the data, comparative spectral decompositions underlie a mathematically universal description of the genotype-phenotype relations in cancer that other methods miss.

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DNA Damage Follows Repair Factor Depletion and Portends Genome Variation in Cancer Cells after Pore Migration

Cited by 254 publications

References 50 publications

Mitotic progression following DNA damage enables pattern recognition within micronuclei

Mitotic progression following DNA damage enables pattern recognition within micronuclei

Rebuilding Chromosomes After Catastrophe: Emerging Mechanisms of Chromothripsis

Mathematically universal and biologically consistent astrocytoma genotype encodes for transformation and predicts survival phenotype

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