Tracing the origin of disseminated tumor cells in breast cancer using single-cell sequencing

Demeulemeester, Jonas; Kumar, Parveen; Møller, Elen K.; Nord, Silje; Wedge, David C.; Peterson, A. C.; Mathiesen, Randi R.; Fjelldal, Renathe; Esteki, Masoud Zamani; Theunis, Koen; Gallardo, Elia Fernandez; Grundstad, A. Jason; Borgen, Elin; Baumbusch, Lars Oliver; Børresen-Dale, Anne Lise; White, Kevin P.; Kristensen, Vessela N.; Loo, Peter Van; Voet, Thierry; Naume, Bjørn

doi:10.1186/s13059-016-1109-7

Cited by 74 publications

(43 citation statements)

References 50 publications

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“…In particular, the vast majority of driver mutations found in the primary cancer would also be present in the relapsing clone. Our observation of late dissemination is consistent with the findings of a recent study that combined bulk sequencing of primary tumors with single-cell sequencing of bone marrow-derived disseminated tumor cells, the presumed precursor of clinically overt metastatic disease ( Demeulemeester et al., 2016 ). Although the genome of a metastatic clone may be similar to the primary tumor at first diagnosis, by the time it has expanded to be clinically detectable, extensive further genomic changes have occurred.…”

Section: Discussionsupporting

confidence: 91%

Genomic Evolution of Breast Cancer Metastasis and Relapse

et al. 2017

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SummaryPatterns of genomic evolution between primary and metastatic breast cancer have not been studied in large numbers, despite patients with metastatic breast cancer having dismal survival. We sequenced whole genomes or a panel of 365 genes on 299 samples from 170 patients with locally relapsed or metastatic breast cancer. Several lines of analysis indicate that clones seeding metastasis or relapse disseminate late from primary tumors, but continue to acquire mutations, mostly accessing the same mutational processes active in the primary tumor. Most distant metastases acquired driver mutations not seen in the primary tumor, drawing from a wider repertoire of cancer genes than early drivers. These include a number of clinically actionable alterations and mutations inactivating SWI-SNF and JAK2-STAT3 pathways.

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Section: Discussionsupporting

confidence: 91%

Genomic Evolution of Breast Cancer Metastasis and Relapse

et al. 2017

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“…All three different methods employ the detection of cytokeratins as marker of epithelial cells. However, it should be mentioned here that the immunocytochemical staining of bone marrow aspirates for a broad spectrum of cytokeratins in patients with breast cancer, showed that the true positive rate for the detection of disseminated tumor cells was 52.6±11.5% [29]. …”

Section: Discussionmentioning

confidence: 99%

A Comparison of Three Methods for the Detection of Circulating Tumor Cells in Patients with Early and Metastatic Breast Cancer

Politaki

Agelaki

Apostolaki

et al. 2017

Cell Physiol Biochem

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Background: We directly compared CTC detection rates and prognostic significance, using three different methods in patients with breast cancer (BC). Methods: Early (n=200) and metastatic (n=164) patients were evaluated before initiating adjuvant or first-line chemotherapy, using the CellSearch^TM System, an RT-qPCR for CK-19 mRNA detection and by double immunofluorescence (IF) microscopy using A45-B/B3 and CD45 antibodies. Results: Using the CellSearch^TM System, 37% and 16.5% of early BC patients were CTC-positive (at ≥1 and ≥2 CTCs/23 ml of blood), 18.0% by RT-qPCR and 16.9% by IF; no agreement was observed between methods. By the CellSearch^TM 34.8% and 53.7% (at≥ 5 and ≥ 2 CTCs/7.5 ml) of metastatic patients were CTC-positive, 37.8% by RT-qPCR and 28.5% by IF. A significant agreement existed only between the CellSearch^TM and RT-qPCR. In 60.8% of cases, differential EpCAM and CK-19 expression on CTCs by IF could explain the discrepancies between the CellSearch^TM and RT-qPCR. CTC-positivity by either method was associated with decreased overall survival in metastatic patients. Conclusion: A significant concordance was observed between the CellSearch^TM and RT-qPCR in metastatic but not in early BC. Discordant results could be explained in part by CTC heterogeneity. CTC detection by all methods evaluated had prognostic relevance in metastatic patients.

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“…Nowadays, single-cell genotyping has become a very popular method, allowing determination of cancer "phylogenesis" and evolution. Demeulemeester et al have constructed cancer "phylogenetic" trees using singlecell sequencing (52).…”

Section: Morphology and Biological Features Morphological Evaluationmentioning

confidence: 99%

Circulating Tumor Cells in Diagnosis and Treatment of Lung Cancer

Malý

Kološtová

et al. 2019

In Vivo

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Circulating tumor cells (CTCs), detached from the primary tumor or metastases and shed in the patient's bloodstream, represent a relatively easily obtainable sample of the cancer tissue that can indicate the actual state of cancer, and their evaluation can be repeated many times during the course of treatment. As part of liquid biopsy, evaluation of CTCs provides a lot of clinically relevant information, which reflects the actual, real-time conditions of the disease. CTCs can be used in cancer diagnosis or screening, real-time longterm disease monitoring and even therapy guidance. Their analysis can include their number, morphology, and biological features by using immunocytochemistry and all "-omic" technologies. This review describes methods of CTC isolation and potential clinical utilization in lung cancer. Despite major advances in the diagnostics and treatment, lung cancer remains the most lethal cancer disease on a global scale. According to a WHO estimate, there were 2.09 million new lung cancer cases and 1.76 million lung cancer-related deaths in 2018 (1). Therefore, similarly to other cancer diagnoses, a significant effort is dedicated on the potential use of circulating tumor cells (CTCs) in prognosis assessment, disease monitoring and even in therapy management. CTCs, detached from the primary tumor or metastases and shed in patient's bloodstream, represent a relatively easily obtainable sample of cancer tissue. As a liquid biopsy, evaluation of CTCs provides a lot of clinically relevant information, which reflects the actual, real-time conditions of the disease (2). CTCs are very rare in the bloodstream; therefore, a number of different enrichment and isolation methods have been developed (2). Also, the evaluation of CTCs can be performed on many levels providing different kinds of information. The CTCs enrichment methods as well as their potential clinical use in lung cancer is introduced below. CTC Isolation and Detection Methods-Basic Principles Exploration of CTCs can provide a lot of clinically-relevant information; however, CTCs are very rare in the bloodstream. Every single CTC is surrounded by 10 6-10 7 mononuclear white blood cells (2, 3). Therefore, in order to be able to study and assess CTC-number and characteristics, it is necessary to separate them from the ambient blood cells. Although many methods have been developed to isolate CTCs, there are only two basic approaches to isolate CTCs: a) isolation methods based on detection of specific surface markers of the CTCs (and/or white blood cells), also called "label-dependent systems/methods" and b) methods independent of specific markers, based on physical or biological properties of the CTCs, "label-independent systems/methods" (2).

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Tracing the origin of disseminated tumor cells in breast cancer using single-cell sequencing

Cited by 74 publications

References 50 publications

Genomic Evolution of Breast Cancer Metastasis and Relapse

Genomic Evolution of Breast Cancer Metastasis and Relapse

A Comparison of Three Methods for the Detection of Circulating Tumor Cells in Patients with Early and Metastatic Breast Cancer

Circulating Tumor Cells in Diagnosis and Treatment of Lung Cancer

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