High-resolution clonal mapping of multi-organ metastasis in triple negative breast cancer

Echeverria, Gloria V.; Powell, Emily; Seth, Sahil; Ge, Zhongqi; Carugo, Alessandro; Bristow, Christopher A.; Peoples, Michael; Robinson, Frederick S.; Qiu, Huan; Shao, Jin; Jeter-Jones, Sabrina; Zhang, Xiaomei; Ramamoorthy, Vandhana; Cai, Shirong; Wu, Wenhui; Draetta, Giulio; Moulder, Stacy L.; Symmans, W. Fraser; Chang, Jeffrey T.; Heffernan, Timothy P.; Piwnica‐Worms, Helen

doi:10.1038/s41467-018-07406-4

Cited by 97 publications

(102 citation statements)

References 67 publications

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“…Despite the improvement made by chemotherapy, radiotherapy and targeted therapy in recent years, the treatment outcome remain unsatisfactory for breast cancer with distant metastasis. Notably, triple negative breast cancer (TNBC), characterized by high malignant degree, high incidence of metastasis and poor prognosis, has no effective treatment currently because of an absence of therapeutic targets . Therefore, understanding the transcription regulatory programs of TNBC distant metastasis holds important implications for the identification of novel therapy and prognosis targets.…”

Section: Introductionmentioning

confidence: 99%

Comprehensive epigenetic analyses reveal master regulators driving lung metastasis of breast cancer

et al. 2019

J Cellular Molecular Medi

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The lung metastasis of breast cancer involves complicated regulatory changes driven by chromatin remodelling. However, the epigenetic reprogramming and regulatory mechanisms in lung metastasis of breast cancer remain unclear. Here, we generated and analysed genome‐wide profiles of multiple histone modifications (H3K4me3, H3K27ac, H3K27me3, H3K4me1 and H3K9me3), as well as transcriptome data in lung‐metastatic and non‐lung‐metastatic breast cancer cells. Our results showed that the expression changes were correlated with the enrichment of specific histone modifications in promoters and enhancers. Promoter and enhancer reprogramming regulated gene expression in a synergetic way, and involved in multiple important biological processes and pathways. In addition, lots of gained super‐enhancers were identified in lung‐metastatic cells. We also identified master regulators driving differential gene expression during lung metastasis of breast cancer. We found that the cooperations between regulators were much closer in lung‐metastatic cells. Moreover, regulators such as TFAP2C, GTF2I and LMO4 were found to have potential prognostic value for lung metastasis free (LMF) survival of breast cancer. Functional studies motivated by our data analyses uncovered an important role of LMO4 in regulating metastasis. This study provided comprehensive insights into regulatory mechanisms, as well as potential prognostic markers for lung metastasis of breast cancer.

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Section: Introductionmentioning

confidence: 99%

Comprehensive epigenetic analyses reveal master regulators driving lung metastasis of breast cancer

et al. 2019

J Cellular Molecular Medi

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“…The genomic analysis of matched primary and metastatic samples has revealed fascinating insight regarding the evolution of metastatic disease [73,75,[82][83][84]86,90,[98][99][100]. Such efforts reveal, for example, that driver mutations that are enriched in metastasis are indeed rarely found in the matched primary tumour, indicating they arose either in a small subclone not sampled when the primary tumour was sequenced, or they occurred during the metastatic process after cells had disseminated from the breast (i.e., treatment induced mutations) [39,73,79,80,82,101].…”

Section: Genomics and Clonal Dynamic Changes During Metastatic Progrementioning

confidence: 99%

Morphologic and Genomic Heterogeneity in the Evolution and Progression of Breast Cancer

Kutasovic

Reed

Sokolova

et al. 2020

Cancers

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Breast cancer is a remarkably complex and diverse disease. Subtyping based on morphology, genomics, biomarkers and/or clinical parameters seeks to stratify optimal approaches for management, but it is clear that every breast cancer is fundamentally unique. Intra-tumour heterogeneity adds further complexity and impacts a patient’s response to neoadjuvant or adjuvant therapy. Here, we review some established and more recent evidence related to the complex nature of breast cancer evolution. We describe morphologic and genomic diversity as it arises spontaneously during the early stages of tumour evolution, and also in the context of treatment where the changing subclonal architecture of a tumour is driven by the inherent adaptability of tumour cells to evolve and resist the selective pressures of therapy.

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“…Cancer consists of multiple genetically related, distinct subclones 1 that evolve in parallel and display heterogeneity at genomic 2,3 , epigenetic [4][5][6][7] , or phenotypic level [8][9][10] . As malignancy progresses, particular subclonal populations of cancer cells develop differing aggressive phenotypes, such as faster proliferation, metastatic potential 11,12 , or drug resistance 13,14 . To understand which molecular features promote an aggressive phenotype in particular subclones, and hence, further the tumor progression, elucidating the biology of individual cell lineages would be particularly insightful.…”

Section: Introductionmentioning

confidence: 99%

“…DNA barcoding (tagging of individual cells with unique DNA sequences) enables highthroughput tracking of individual clonal lineages by next-generation sequencing (NGS). The barcoding approach accurately and quantitatively determines the lineages that get enriched or depleted following tumor initiation 15,16 , drug resistance 13,[17][18][19] , metastatic spread 11,12,20 , or another type of phenotype selection. Moreover, current developments allow for the use of DNA barcoding to link multiple phenotypes to a lineage 21 , or even to couple lineage tracing with single-cell transcriptomics 22 .…”

Section: Introductionmentioning

confidence: 99%

DNA barcode-guided lentiviral CRISPRa tool to trace and isolate individual clonal lineages in heterogeneous cancer cell populations

Akimov

Bulanova

Abyzova

et al. 2019

Preprint

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The genetic and functional heterogeneity of tumors imposes the challenge of understanding how a cancer progresses, evolves and adapts to treatment at the subclonal level. Therefore, there is a critical need for methods that enable profiling of individual cancer cell lineages. Here, we report a novel system that couples an established DNA barcoding technique for lineage tracing with a controlled DNA barcode-guided lineage isolation (B-GLI). B-GLI allows both high-complexity of lineage tracing and effective isolation of individual clones by CRISPRa-mediated induction of puromycin resistance, making it possible to unbiasedly trace, isolate, and study individual cancer cell lineages. We present experimental evaluation of the system performance in isolation of lineages and outline a comprehensive workflow for B-GLI applications. We believe the system has broad applications aimed at molecular and phenotypic profiling of individual lineages in heterogeneous cell populations.

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High-resolution clonal mapping of multi-organ metastasis in triple negative breast cancer

Cited by 97 publications

References 67 publications

Comprehensive epigenetic analyses reveal master regulators driving lung metastasis of breast cancer

Comprehensive epigenetic analyses reveal master regulators driving lung metastasis of breast cancer

Morphologic and Genomic Heterogeneity in the Evolution and Progression of Breast Cancer

DNA barcode-guided lentiviral CRISPRa tool to trace and isolate individual clonal lineages in heterogeneous cancer cell populations

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