Absence of Brca2 causes genome instability by chromosome breakage and loss associated with centrosome amplification

Genome instability (GIN) is a main contributing factor to congenital and somatic diseases, but its sporadic occurrence in individual cell cycles makes it difficult to study mechanistically. One profound manifestation of GIN is the formation of micronuclei (MN), the engulfment of chromosomes or chromosome fragments in their own nuclear structures separate from the main nucleus. Here, we developed MN-seq, an approach for sequencing the DNA contained within micronuclei. We applied MN-seq to mice with mutations in Mcm4 and Rad9a, which disrupt DNA replication, repair, and damage responses. Data analysis and simulations show that centromere presence, fragment length, and a heterogenous landscape of chromosomal fragility all contribute to the patterns of DNA present within MN. In particular, we show that long genes, but also gene-poor regions, are associated with chromosome breaks that lead to the enrichment of particular genomic sequences in MN, in a genetic background-specific manner. Finally, we introduce single-cell micronucleus sequencing (scMN-seq), an approach to sequence the DNA present in MN of individual cells. Together, sequencing micronuclei provides a systematic approach for studying GIN and reveals novel molecular associations with chromosome breakage and segregation.

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Mechanisms generating cancer genome complexity from a single cell division error

Science ◽

10.1126/science.aba0712 ◽

2020 ◽

Vol 368 (6488) ◽

pp. eaba0712 ◽

Cited By ~ 42

Author(s):

Neil T. Umbreit ◽

Cheng-Zhong Zhang ◽

Luke D. Lynch ◽

Logan J. Blaine ◽

Anna M. Cheng ◽

...

Keyword(s):

Cell Division ◽

Single Cell ◽

Genome Instability ◽

Chromosome Breakage ◽

Genomic Complexity ◽

Genome Complexity ◽

Cancer Genomes ◽

Chromosome Bridge ◽

Bfb Cycle ◽

Mutational Process

The chromosome breakage-fusion-bridge (BFB) cycle is a mutational process that produces gene amplification and genome instability. Signatures of BFB cycles can be observed in cancer genomes alongside chromothripsis, another catastrophic mutational phenomenon. We explain this association by elucidating a mutational cascade that is triggered by a single cell division error—chromosome bridge formation—that rapidly increases genomic complexity. We show that actomyosin forces are required for initial bridge breakage. Chromothripsis accumulates, beginning with aberrant interphase replication of bridge DNA. A subsequent burst of DNA replication in the next mitosis generates extensive DNA damage. During this second cell division, broken bridge chromosomes frequently missegregate and form micronuclei, promoting additional chromothripsis. We propose that iterations of this mutational cascade generate the continuing evolution and subclonal heterogeneity characteristic of many human cancers.

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Mechanisms Generating Cancer Genome Complexity From A Single Cell Division Error

10.1101/835058 ◽

2019 ◽

Author(s):

Neil T. Umbreit ◽

Cheng-Zhong Zhang ◽

Luke D. Lynch ◽

Logan J. Blaine ◽

Anna M. Cheng ◽

...

Keyword(s):

Genome Instability ◽

Chromosome Breakage ◽

Epigenetic Mark ◽

Clonal Heterogeneity ◽

Bridge Formation ◽

Genome Complexity ◽

Cancer Genomes ◽

Chromosome Bridge ◽

Bfb Cycle ◽

Mutational Process

ABSTRACTThe chromosome breakage-fusion-bridge (BFB) cycle is a mutational process that produces gene amplification and genome instability. Signatures of BFB cycles can be observed in cancer genomes with chromothripsis, another catastrophic mutational process. Here, we explain this association by identifying a mutational cascade downstream of chromosome bridge formation that generates increasing amounts of chromothripsis. We uncover a new role for actomyosin forces in bridge breakage and mutagenesis. Chromothripsis then accumulates starting with aberrant interphase replication of bridge DNA, followed by an unexpected burst of mitotic DNA replication, generating extensive DNA damage. Bridge formation also disrupts the centromeric epigenetic mark, leading to micronucleus formation that itself promotes chromothripsis. We show that this mutational cascade generates the continuing evolution and sub-clonal heterogeneity characteristic of many human cancers.

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TopBP1/Dpb11 binds DNA anaphase bridges to prevent genome instability

The Journal of Cell Biology ◽

10.1083/jcb.201305157 ◽

2013 ◽

Vol 204 (1) ◽

pp. 45-59 ◽

Cited By ~ 61

Author(s):

Susanne M. Germann ◽

Vera Schramke ◽

Rune Troelsgaard Pedersen ◽

Irene Gallina ◽

Nadine Eckert-Boulet ◽

...

Keyword(s):

Genome Instability ◽

Chromosome Breakage ◽

Model Systems ◽

Yeast Saccharomyces Cerevisiae ◽

Anaphase Bridges ◽

Potential Source ◽

Evolutionarily Conserved ◽

Atr Kinase ◽

Chromatin Bridges ◽

Stimulation Of

DNA anaphase bridges are a potential source of genome instability that may lead to chromosome breakage or nondisjunction during mitosis. Two classes of anaphase bridges can be distinguished: DAPI-positive chromatin bridges and DAPI-negative ultrafine DNA bridges (UFBs). Here, we establish budding yeast Saccharomyces cerevisiae and the avian DT40 cell line as model systems for studying DNA anaphase bridges and show that TopBP1/Dpb11 plays an evolutionarily conserved role in their metabolism. Together with the single-stranded DNA binding protein RPA, TopBP1/Dpb11 binds to UFBs, and depletion of TopBP1/Dpb11 led to an accumulation of chromatin bridges. Importantly, the NoCut checkpoint that delays progression from anaphase to abscission in yeast was activated by both UFBs and chromatin bridges independently of Dpb11, and disruption of the NoCut checkpoint in Dpb11-depleted cells led to genome instability. In conclusion, we propose that TopBP1/Dpb11 prevents accumulation of anaphase bridges via stimulation of the Mec1/ATR kinase and suppression of homologous recombination.

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Extraordinary genome instability and widespread chromosome rearrangements during vegetative growth

10.1101/304915 ◽

2018 ◽

Cited By ~ 4

Author(s):

Mareike Möller ◽

Michael Habig ◽

Michael Freitag ◽

Eva H. Stukenbrock

Keyword(s):

Incubation Temperature ◽

Genome Instability ◽

Pathogenic Fungus ◽

Chromosome Instability ◽

Chromosome Breakage ◽

Chromosome Loss ◽

In Planta ◽

Zymoseptoria Tritici ◽

Accessory Chromosomes

AbstractThe haploid genome of the pathogenic fungusZymoseptoria triticiis contained on “core” and “accessory” chromosomes. While 13 core chromosomes are found in all strains, as many as eight accessory chromosomes show presence/absence variation and rearrangements among field isolates. We investigated chromosome stability using experimental evolution, karyotyping and genome sequencing. We report extremely high and variable rates of accessory chromosome loss during mitotic propagationin vitroandin planta. Spontaneous chromosome loss was observed in 2 to >50 % of cells during four weeks of incubation. Similar rates of chromosome loss in the closely relatedZ. ardabiliaesuggest that this extreme chromosome dynamic is a conserved phenomenon in the genus. Elevating the incubation temperature greatly increases instability of accessory and even core chromosomes, causing severe rearrangements involving telomere fusion and chromosome breakage. Chromosome losses do not impact the fitness ofZ. tritici in vitro, but some lead to increased virulence suggesting an adaptive role of this extraordinary chromosome instability.

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