Purpose: Ion channel activity is involved in several basic cellular behaviors that are integral to metastasis (e.g., proliferation, motility, secretion, and invasion), although their contribution to cancer progression has largely been ignored. The purpose of this study was to investigate voltagegated Na + channel (VGSC) expression and its possible role in human breast cancer. Experimental Design: Functional VGSC expression was investigated in human breast cancer cell lines by patch clamp recording. The contribution of VGSC activity to directional motility, endocytosis, and invasion was evaluated by in vitro assays. Subsequent identification of the VGSC a-subunit(s) expressed in vitro was achieved using reverse transcription-PCR, immunocytochemistry, and Western blot techniques and used to investigate VGSCa expression and its association with metastasis in vivo. Results:VGSC expression was significantly up-regulated in metastatic human breast cancer cells and tissues, and VGSC activity potentiated cellular directional motility, endocytosis, and invasion. Reverse transcription-PCR revealed that Na v 1.5, in its newly identified ''neonatal'' splice form, was specifically associated with strong metastatic potential in vitro and breast cancer progression in vivo. An antibody specific for this form confirmed up-regulation of neonatal Na v 1.5 protein in breast cancer cells and tissues. Furthermore, a strong correlation was found between neonatal Na v 1.5 expression and clinically assessed lymph node metastasis. Conclusions: Up-regulation of neonatal Na v 1.5 occurs as an integral part of the metastatic process in human breast cancer and could serve both as a novel marker of the metastatic phenotype and a therapeutic target.Breast cancer is the most common cancer of women and the second leading cause of female cancer mortality, accounting for about 10% of all cancer deaths in the western world (1, 2). To date, several breast cancer metastasis -associated genes have been identified both individually and in combination in microarray analyses (3, 4). These include oncogenes (e.g., ras and c-myc), cell cycle -associated markers (e.g., Ki67), adhesion molecules (e.g., E-cadherins), motility factors (e.g., hepatic growth factor), growth factors and their receptors (e.g., epidermal growth factor/Her-2 and fibroblast growth factor), and the well-established steroid hormones (e.g., estrogen and progesterone; refs. 3, 4). However, indirect measures of metastatic progression (including size of primary carcinoma, assessment of intratumoral vascular invasion, and lymph node involvement) remain the most widely used methods in clinical management. At present, although it is possible to detect micrometastases, approximately one third of women who seem disease-free at primary diagnosis eventually develop overt metastases (5, 6). Clinicians, therefore, require a more accurate diagnosis to predict the development of metastatic disease.Ion channels are major signaling molecules expressed in a wide range of tissues where they hav...
Upregulation of functional voltage-gated Na + channels (VGSCs) occurs in metastatic human breast cancer (BCa) in vitro and in vivo. The present study aimed to ascertain the specific involvement of the 'neonatal' splice variant of Nav1.5 (nNav1.5), thought to be predominant, in the VGSC-dependent invasive behaviour of MDA-MB-231 cells. Functional activity of nNav1.5 was suppressed by two different methods targeting nNav1.5: (i) small interfering RNA (siRNA), and (ii) a polyclonal antibody (NESO-pAb); effects upon migration and invasion were determined. nNav1.5 mRNA, protein and signalling were measured using real-time PCR, Western blotting, and patch clamp recording, respectively. Treatment with the siRNA rapidly reduced (by ~90 %) the level of nNav1.5 (but not adult Nav1.5) mRNA, but the protein reduction was much smaller (~30 %), even after 13 days. Nevertheless, the siRNA reduced peak VGSC current density by 33 %, and significantly increased the cells' sensitivity to nanomolar tetrodotoxin (TTX). Importantly, the siRNA suppressed in vitro migration by 43 %, and eliminated the normally inhibitory effect of TTX. Migrated MDA-MB-231 cells expressed more nNav1.5 protein at the plasma membrane than non-migrated cells. Furthermore, NESO-pAb reduced migration by up to 42 %, in a dosedependent manner. NESO-pAb also reduced Matrigel invasion without affecting proliferation. TTX had no effect on cells already treated with NESO-pAb. It was concluded that nNav1.5 is primarily responsible for the VGSC-dependent enhancement of invasive behaviour in MDA-MB-231 cells. Accordingly, targeting nNav1.5 expression/activity may be useful in clinical management of metastatic BCa.
FGFR1 cleavage by Granzyme B induces its nuclear translocation, in which it stimulates cell migration through effects on gene expression.
The epithelial isoform of fibroblast growth factor receptor 2 (Fgfr2b) is essential for embryogenesis, and Fgfr2b-null mice die at birth. Using Cre-Lox transgenics to delete Fgfr2b in cells expressing keratin 5, we show that mice lacking epidermal Fgfr2b survive into adulthood but display striking abnormalities in hair and sebaceous gland development. Epidermal hyperthickening develops with age, and 10% of mutant mice develop spontaneous papillomas, demonstrating the role of Fgfr2b in post-natal skin development and in adult skin homeostasis. Mice lacking epithelial Fgfr2b show great sensitivity to chemical carcinogenic insult, displaying several oncogenic ha-ras mutations with dramatic development of papillomas and squamous cell carcinomas. Mutant mice have increased inflammation in the skin, with increased numbers of macrophages and cdT cells with abnormal morphology. Mutant skin shows several changes in gene expression, including enhanced expression of the pro-inflammatory cytokine interleukin 18 and decreased expression of Serpin a3b, a potential tumor suppressor. Thus we describe a novel role of Fgfr2b and provide the first evidence of a tyrosine kinase receptor playing a tumor suppressive role in the skin.
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