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Clinical & Experimental Metastasis
Published in: Clinical & Experimental Metastasis 3/2016

Open Access 01-03-2016 | Research Paper

Oestrogen receptor positive breast cancer metastasis to bone: inhibition by targeting the bone microenvironment in vivo

Authors: I. Holen, M. Walker, F. Nutter, A. Fowles, C. A. Evans, C. L. Eaton, P. D. Ottewell

Published in: Clinical & Experimental Metastasis | Issue 3/2016

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Abstract

Clinical trials have shown that adjuvant Zoledronic acid (ZOL) reduces the development of bone metastases irrespective of ER status. However, post-menopausal patients show anti-tumour benefit with ZOL whereas pre-menopausal patients do not. Here we have developed in vivo models of spontaneous ER+ve breast cancer metastasis to bone and investigated the effects of ZOL and oestrogen on tumour cell dissemination and growth. ER+ve (MCF7, T47D) or ER−ve (MDA-MB-231) cells were administered by inter-mammary or inter-cardiac injection into female nude mice ± estradiol. Mice were administered saline or 100 μg/kg ZOL weekly. Tumour growth, dissemination of tumour cells in blood, bone and bone turnover were monitored by luciferase imaging, histology, flow cytometry, two-photon microscopy, micro-CT and TRAP/P1NP ELISA. Estradiol induced metastasis of ER+ve cells to bone in 80–100 % of animals whereas bone metastases from ER−ve cells were unaffected. Administration of ZOL had no effect on tumour growth in the fat pad but significantly inhibited dissemination of ER+ve tumour cells to bone and frequency of bone metastasis. Estradiol and ZOL increased bone volume via different mechanisms: Estradiol increased activity of bone forming osteoblasts whereas administration of ZOL to estradiol supplemented mice decreased osteoclast activity and returned osteoblast activity to levels comparable to that of saline treated mice. ER−ve cells require increased osteoclast activity to grow in bone whereas ER+ve cells do not. Zol does not affect ER+ve tumour growth in soft tissue, however, inhibition of bone turnover by ZOL reduced dissemination and growth of ER+ve breast cancer cells in bone.
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Metadata
Title
Oestrogen receptor positive breast cancer metastasis to bone: inhibition by targeting the bone microenvironment in vivo
Authors
I. Holen
M. Walker
F. Nutter
A. Fowles
C. A. Evans
C. L. Eaton
P. D. Ottewell
Publication date
01-03-2016
Publisher
Springer Netherlands
Published in
Clinical & Experimental Metastasis / Issue 3/2016
Print ISSN: 0262-0898
Electronic ISSN: 1573-7276
DOI
https://doi.org/10.1007/s10585-015-9770-x

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