Inhibition of extracellular matrix mediated TGF-β signalling suppresses endometrial cancer metastasis.

Subhransu S Sahoo,Murray J Cairns,Pradeep S Tanwar,Sarah Nielsen,Gough G Au,Joshua Atkins,Pravin Nahar,Min Yuan Quah,Janine M Lombard

doi:10.18632/oncotarget.18069

Subhransu S Sahoo, Murray J Cairns + Show 7 more

Open Access

https://doi.org/10.18632/oncotarget.18069

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Abstract

Although aggressive invasion and distant metastases are an important cause of morbidity and mortality in patients with endometrial cancer (EC), the requisite events determining this propensity are currently unknown. Using organotypic three-dimensional culture of endometrial cancer cell lines, we demonstrated anti-correlated TGF-β signalling gene expression patterns that arise among extracellular matrix (ECM)-attached cells. TGF-β pathway seemed to be active in EC cells forming non-glandular colonies in 3D-matrix but weaker in glandular colonies. Functionally we found that out of several ECM proteins, fibronectin relatively promotes Smad phosphorylation suggesting a potential role in regulating TGF-β signalling in non-glandular colonies. Importantly, alteration of TGF-β pathway induced EMT and MET in both type of colonies through slug protein. The results exemplify a crucial role of TGF-β pathway during EC metastasis in human patients and inhibition of the pathway in a murine model impaired tumour cell invasion and metastasis depicting an attractive target for therapeutic intervention of malignant tumour progression. These findings provide key insights into the role of ECM-derived TGF-β signalling to promote endometrial cancer metastasis and offer an avenue for therapeutic targeting of microenvironment derived signals along with tumour cells.

Highlights

The extracellular matrix (ECM) is a major component of the cellular microenvironment and regulates normal tissue development and homoeostasis
Normal epithelial cells in the human uterus organize into an inner single layer of columnar epithelium as endometrium and into acinar structures in the stroma as endometrial glands [33]
Endometrial hyperplasia or cancer develops with the disruption of the acinar architecture of endometrial glands [34] and can be categorized as a hallmark of cancer

Summary

Introduction

The extracellular matrix (ECM) is a major component of the cellular microenvironment and regulates normal tissue development and homoeostasis. Stromalepithelial communication in early development and steroid signalling is important for normal uterine functions. The signalling alteration in uterine stroma or ECM that regulates remodelling of the differentiated endometrium to a disease or metastatic cancerous state is currently unclear. Studies have shown the crucial role of stromal signals in controlling the proliferative potential of endometrial epithelium [2,3,4]. Epi-genome wide methylation analysis revealed hypermethylation of Hand gene in endometrial stroma significantly contributes to endometrial cancer www.impactjournals.com/oncotarget [5]. Given that stromal components probably significantly contribute to growth and development of endometrial cancer, relatively limited work has been carried out to address the role of the ECM in uterine biology and cancer

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