Live-cell imaging shows uneven segregation of extrachromosomal DNA elements and transcriptionally active extrachromosomal DNA clusters in cancer

Yi, Eunhee; Gujar, Amit D.; Guthrie, Molly; Kim, Hoon; Johnson, Kevin C.; Amin, Samirkumar B.; Das, Sunit; Clow, Patricia A.; Cheng, Albert W.; Verhaak, Roel G.W.

doi:10.1101/2020.10.20.335216

2020

DOI: 10.1101/2020.10.20.335216

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Live-cell imaging shows uneven segregation of extrachromosomal DNA elements and transcriptionally active extrachromosomal DNA clusters in cancer

Eunhee Yi

Amit D. Gujar

Molly Guthrie

et al.

Abstract: Oncogenic extrachromosomal DNA elements (ecDNAs) promote intratumoral heterogeneity, creating a barrier for successful cancer treatments. The underlying mechanisms are poorly understood and studies are hampered in part by a lack of adequate tools enabling studies of ecDNA behavior. Here, we show that single-cell ecDNA copy numbers follow a Gaussian distribution across tumor cells in vitro and in patient glioblastoma specimens, suggesting uneven ecDNA segregation during mitosis. We established a CRISPR-based ap… Show more

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Cited by 3 publications

References 38 publications

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Did circular DNA shape the evolution of mammalian genomes?

Holt

Tane

Regenberg

2022

Preprint

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Extrachromosomal circular DNA of chromosomal origin (eccDNA) can rapidly shape the evolution and adaptation of mitotically dividing cells such as tumor cells. However, whether eccDNA has a permanent impact on genome evolution through the germline is largely unexplored. Here, we propose that a large fraction of the syntenic changes that are found between mammalian species are caused by germline transposition of eccDNA. We have previously shown the existence of eccDNA in mammalian meiotic cells. By reanalysis of available synteny maps, we now find that up to 6% of mammalian genomes might have rearranged via a circular DNA intermediate. Hence, eccDNA in the germline is expected to have large effects on evolution of gene order.

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Did circular DNA shape the evolution of mammalian genomes?

Holt

Tane

Regenberg

2022

Preprint

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Robust identification of extrachromosomal DNA and genetic variants using multiple genetic abnormality sequencing (MGA-Seq)

Lin

Zou

Wang

et al. 2022

Preprint

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Genomic abnormalities, including structural variation (SV), copy number variation (CNV), single-nucleotide polymorphism (SNP), homogenously staining regions (HSR) and extrachromosomal DNA (ecDNA), are strongly associated with cancer, rare diseases and infertility. A robust technology to simultaneously detect these genomic abnormalities is highly desired for clinical diagnosis and basic research. In this study, we developed a simple and cost-effective method - multiple genetic abnormality sequencing (MGA-Seq) - to simultaneously detect SNPs, CNVs, SVs, ecDNA and HSRs in a single tube. This method has been successfully applied in both cancer cell lines and clinical tumour samples and revealed that focal amplification in tumour tissue is substantially heterogeneous. Notably, we delineated the architecture of focal amplification and the ecDNA network by MGA-Seq, which facilitated the exploration of the regulation of gene expression in ecDNA. This method could be extensively applied for diagnosis and may greatly facilitate the investigation of the genomic mechanism for genetic diseases.

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Intercellular extrachromosomal DNA copy number heterogeneity drives cancer cell state diversity

Stoeber

González

Brueckner

et al. 2023

Preprint

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Neuroblastoma is characterised by extensive inter- and intra-tumour genetic heterogeneity and varying clinical outcomes. One possible driver for this heterogeneity are extrachromosomal DNAs (ecDNA), which segregate independently to the daughter cells during cell division and can lead to rapid amplification of oncogenes. While ecDNA-mediated oncogene amplification has been shown to be associated with poor prognosis in many cancer entities, the effects of ecDNA copy number heterogeneity on intermediate phenotypes are still poorly understood. Here, we leverage DNA and RNA sequencing data from the same single cells in cell lines and neuroblastoma patients to investigate these effects. We utilise ecDNA amplicon structures to determine precise ecDNA copy numbers and reveal extensive intercellular ecDNA copy number heterogeneity. We further provide direct evidence for the effects of this heterogeneity on gene expression of cargo genes, including MYCN and its downstream targets, and the overall transcriptional state of neuroblastoma cells. These results highlight the potential for rapid adaptability of cellular states within a tumour cell population mediated by ecDNA copy number, emphasising the need for ecDNA-specific treatment strategies to tackle tumour formation and adaptation.

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Live-cell imaging shows uneven segregation of extrachromosomal DNA elements and transcriptionally active extrachromosomal DNA clusters in cancer

Cited by 3 publications

References 38 publications

Did circular DNA shape the evolution of mammalian genomes?

Did circular DNA shape the evolution of mammalian genomes?

Robust identification of extrachromosomal DNA and genetic variants using multiple genetic abnormality sequencing (MGA-Seq)

Intercellular extrachromosomal DNA copy number heterogeneity drives cancer cell state diversity

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