Breast Cancer Brain Metastases: Clonal Evolution in Clinical Context

Saunus, Jodi M.; Reed, Amy E. McCart; Lim, Malcolm; Lakhani, Sunil R.

doi:10.20944/preprints201612.0113.v1

Cited by 7 publications

(8 citation statements)

References 38 publications

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“…Micrometastasis to brain is detected in ~30% of mice within 1 month of xenografting DCIS cells induced to express high levels of SOX11. SOX11 is amplified and overexpressed in ~30% of brain metastases in a recent study of a small cohort of breast cancer patients that were profiled using an integrated genomic and transcriptomic analysis of fresh frozen tumour samples ( Saunus et al, 2017 ; Saunus et al, 2015 ) and highly expressed by ~30% of BCBM in another independent study ( Varešlija et al, 2019 ). Our finding that iSOX11 mammary tumours spontaneously metastasize to the brain is clinically relevant.…”

Section: Discussionmentioning

confidence: 99%

SOX11 promotes epithelial/mesenchymal hybrid state and alters tropism of invasive breast cancer cells

Oliemuller

Newman

Tsang

et al. 2020

eLife

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SOX11 is an embryonic mammary epithelial marker that is normally silenced prior to birth. High SOX11 levels in breast tumours are significantly associated with distant metastasis and poor outcome in breast cancer patients. Here, we show that SOX11 confers distinct features to ER-negative DCIS.com breast cancer cells, leading to populations enriched with highly plastic hybrid epithelial/mesenchymal cells, which display invasive features and alterations in metastatic tropism when xenografted into mice. We found that SOX11+DCIS tumour cells metastasize to brain and bone at greater frequency and to lungs at lower frequency compared to cells with lower SOX11 levels. High levels of SOX11 leads to the expression of markers associated with mesenchymal state and embryonic cellular phenotypes. Our results suggest that SOX11 may be a potential biomarker for breast tumours with elevated risk of developing metastases and may require more aggressive therapies.

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Section: Discussionmentioning

confidence: 99%

SOX11 promotes epithelial/mesenchymal hybrid state and alters tropism of invasive breast cancer cells

Oliemuller

Newman

Tsang

et al. 2020

eLife

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“…The technical and clinical advantages and disadvantages of xenografts and genetically engineered mouse models as well as combinational breast cancer models have recently been reviewed by Holen et al Studies are also exploring the use of microfluidic devices for 3D breast tumor models to better mimic the physiological microenvironment in vitro . However, current breast cancer models are limited in that many do not account for the dynamic transformation of the cancer genome to include the spatiotemporal mutations and genomic rearrangements that inevitably arise as the breast cancer progresses through clonal evolution . Advances in CRISPR gene editing can not only be used to characterize and diagnose breast cancer, but also precisely mimic breast cancer progression at discrete intervals, thus enabling the development of more accurate preclinical models for breast cancer research.…”

Section: Crispr Technology For Breast Cancer Modelingmentioning

confidence: 99%

CRISPR Technology for Breast Cancer: Diagnostics, Modeling, and Therapy

Mintz

Gao

et al. 2018

Adv. Biosys.

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Molecularly, breast cancer represents a highly heterogenous family of neoplastic disorders, with substantial interpatient variations regarding genetic mutations, cell composition, transcriptional profiles, and treatment response. Consequently, there is an increasing demand for alternative diagnostic approaches aimed at the molecular annotation of the disease on a patient‐by‐patient basis and the design of more personalized treatments. The clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR‐associated (Cas) technology enables the development of such novel approaches. For instance, in diagnostics, the use of the RNA‐specific C2c2 system allows ultrasensitive nucleic acid detection and could be used to characterize the mutational repertoire and transcriptional breast cancer signatures. In disease modeling, CRISPR/Cas9 technology can be applied to selectively engineer oncogenes and tumor‐suppressor genes involved in disease pathogenesis. In treatment, CRISPR/Cas9 can be used to develop gene‐therapy, while its catalytically‐dead variant (dCas9) can be applied to reprogram the epigenetic landscape of malignant cells. As immunotherapy becomes increasingly prominent in cancer treatment, CRISPR/Cas9 can engineer the immune cells to redirect them against cancer cells and potentiate antitumor immune responses. In this review, CRISPR strategies for the advancement of breast cancer diagnostics, modeling, and treatment are highlighted, culminating in a perspective on developing a precision medicine‐based approach against breast cancer.

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“…131 However, it is not clear whether these data derived from mouse models adequately recapitulate the human disease in terms of drug delivery to brain tumors. 208 Recent data suggest that gadolinium-DTPAimpermeable cerebral breast metastases have significantly more proliferative nuclei compared to gadolinium-DTPA-permeable tumors in the mouse brain. 209 In contrast, another study showed that melanoma metastases having a permeable vasculature grow faster than those having an intact BTB.…”

Section: Vascularization and The Blood-tumor Barrier Of Metastatic Brmentioning

confidence: 99%

Foe or friend? Janus-faces of the neurovascular unit in the formation of brain metastases

Wilhelm

Fazakas

Molnár

et al. 2017

J Cereb Blood Flow Metab

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Despite the potential obstacle represented by the blood-brain barrier for extravasating malignant cells, metastases are more frequent than primary tumors in the central nervous system. Not only tightly interconnected endothelial cells can hinder metastasis formation, other cells of the brain microenvironment (like astrocytes and microglia) can also be very hostile, destroying the large majority of metastatic cells. However, malignant cells that are able to overcome these harmful mechanisms may benefit from the shielding and even support provided by cerebral endothelial cells, astrocytes and microglia, rendering the brain a sanctuary site against anti-tumor strategies. Thus, cells of the neurovascular unit have a Janus-faced attitude towards brain metastatic cells, being both destructive and protective. In this review, we present the main mechanisms of brain metastasis formation, including those involved in extravasation through the brain vasculature and survival in the cerebral environment.

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Breast Cancer Brain Metastases: Clonal Evolution in Clinical Context

Cited by 7 publications

References 38 publications

SOX11 promotes epithelial/mesenchymal hybrid state and alters tropism of invasive breast cancer cells

SOX11 promotes epithelial/mesenchymal hybrid state and alters tropism of invasive breast cancer cells

CRISPR Technology for Breast Cancer: Diagnostics, Modeling, and Therapy

Foe or friend? Janus-faces of the neurovascular unit in the formation of brain metastases

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