Enhanced invasion and tumor growth of fibroblast growth factor 8b-overexpressing MCF-7 human breast cancer cells.

Fibroblast growth factor 8 (FGF-8) is a secreted heparin-binding protein, which has mitogenic and transforming activity. Increased expression of FGF-8 has been found in human breast cancer, and it has a potential autocrine role in its progression. Human FGF-8 is alternatively spliced to generate four protein isoforms (a, b, e, and f). Isoform b has been shown to be the most transforming. In this work, we studied the role of FGF-8b in the growth (in vitro and in vivo) of MCF-7 human breast cancer cells, which proliferate in an estrogen-dependent manner. Constitutive overexpression of FGF-8b in MCF-7 cells down-regulated FGF-8b-binding receptors FGF receptor (FGFR) 1IIIc, FGFR2IIIc, and FGFR4 found to be expressed in these cells. FGF-8b overexpression led to an increase in the anchorage-independent proliferation rate in suspension culture and colony formation in soft agar, when MCF-7 cells were cultured with or without estradiol. FGF-8b also provided an additional growth advantage for cells stimulated with estradiol. In addition, FGF-8b-transfected cells invaded more actively through Matrigel than did control cells. This was possibly due to the increased secretion of matrix metalloproteinase 9. In vivo, FGF-8b-transfected MCF-7 cells formed faster growing tumors than vector-only-transfected cells when xenografted into nude mice. The tumors formed by FGF-8b-transfected cells were more vascular than the tumors formed by vector-only-transfected cells. In conclusion, FGF-8b expression confers a growth advantage to MCF-7 breast carcinoma cells, both in vitro and in vivo. In addition to stimulation of proliferation, this growth advantage probably arises from increased invasion and tumor vascularization induced by FGF-8b. The results suggest that FGF-8b signaling may be an important factor in the regulation of tumorigenesis and progression of human breast cancer.

FGF-8b increases angiogenic capacity and tumor growth of androgen-regulated S115 breast cancer cells.

Fibroblast growth factor 8 (FGF-8) is a secreted heparin-binding protein, which has transforming potential. Alternative splicing of the mouse Fgf-8 gene potentially codes for eight protein isoforms (a-h) which differ in their transforming capacity in transfected cells. S115 mouse mammary tumor cells express a transformed phenotype and secrete FGF-8 in an androgen-dependent manner. In order to study the role of FGF-8 isoforms in the induction of transformed phenotype of breast cancer cells, we over-expressed FGF-8 isoforms a, b and e in S115 cells. Over-expression of FGF-8b, but not FGF-8a or FGF-8e, induced androgen and anchorage independent growth of S115 cells. FGF-8b-transfected S115 cells formed rapidly growing tumors with increased vascularization when injected s.c. into nude mice. FGF-8a also slightly increased tumor growth and probably tumor vascularization but FGF-8e was not found to have any effects. The angiogenic activity of FGF-8b and heparin-binding growth factor fraction (HBGF) of S115 cell conditioned media was tested in in vitro and in vivo models for angiogenesis using immortomouse brain capillary endothelial cells (IBEC) and chorion allantoic membrane (CAM) assays. Recombinant FGF-8b protein was able to stimulate proliferation, migration, and vessel-like tube formation of IBECs. In addition, stimulatory effect of S115-HBGF on IBE cell proliferation was evident. A positive angiogenic response to FGF-8b was also seen in CAM assay. The results demonstrate that the expression of Fgf-8b is able to promote vessel formation. Angiogenic capacity probably markedly contributes to the ability of FGF-8b to increase tumor growth of androgen-regulated S115 mouse breast cancer cells.

Androgen and fibroblast growth factor (FGF) regulation of FGF receptors in S115 mouse mammary tumor cells.

We studied the androgen regulation of fibroblast growth factor (FGF) receptors (FGFRs) in the Shionogi 115 (S115) mouse mammary tumor cell line and its genetic variant Clone 22. In S115 cells, androgen maintains a transformed morphology, rate of proliferation, and serum and anchorage independence. Similar effects were induced by treatment of the cells with FGF-2 or a heparin-binding growth factor (HBGF) fraction prepared from the medium conditioned by the cells. The effects of androgen and FGF-2 could be partly reversed with a specific anti-FGF-2 immunoglobulin G or by suramin, which inhibits binding of FGFs to their high affinity receptors. Testosterone and FGF-2 increased the expression of FGFR-1 messenger RNA (mRNA) and, to a lesser extent, FGFR-3 mRNA, but down-regulated FGFR-2 mRNA in S115 cells. No FGFR-4 mRNA was detected. FGF-2 also down-regulated the expression of syndecan-1, a heparan sulfate proteoglycan that binds FGF with low affinity. The binding of radiolabeled FGF-2 to FGFRs was lower in the cells cultured with testosterone or in the presence of the HBGFs from androgen-treated cells, presumably because of the autocrine production of FGF-like factors. In Clone 22 cells, FGFRs and syndecan-1 responded to androgen as in S115 cells, but they were less sensitive to FGF-2. Androgen or FGF-2 could not induce morphological transformation, although both stimulated proliferation. Androgen-increased proliferation was not, however, decreased by anti-FGF-2 immunoglobulin G in Clone 22 cells. These data suggest that of the HBGFs produced, FGF-2 is required in androgen induction of morphological change, whereas the effect on proliferation involves other factors as well (perhaps mostly FGF-8). The results show that androgen differentially regulates the expression of the high and low affinity FGF receptors, which could mediate androgen induction of the transformed phenotype in S115 cells by an autocrine mechanism. The differential responses of the Clone 22 variant cells to androgen and FGF-2 suggest that the pathways of steroid induction of different parameters of the transformed phenotype, such as transition to fibroblastic morphology and stimulation of proliferation, are divergent.

Vascular endothelial growth factors are differentially regulated by steroid hormones and antiestrogens in breast cancer cells.

Vascular endothelial growth factor (VEGF) is a major inducer of tumor angiogenesis and an important prognostic factor in breast cancer. Hypoxia is an important inducer of VEGF expression but less is known of the role of hormones in VEGF regulation. We have studied the regulation of VEGF, VEGF-B, VEGF-C, and VEGF-D mRNAs in human MCF-7 and mouse S115 breast carcinoma cells stimulated by estrogens and androgens, respectively. VEGF, VEGF-B, and VEGF-C were expressed in both cell lines, whereas VEGF-D was expressed only in S115 cells. Addition of estradiol (E2) caused a biphasic increase of VEGF mRNA in MCF-7 cells and led to accumulation of the VEGF protein in the culture medium. The VEGF-B mRNA was not affected, while a decrease occurred in VEGF-C mRNA. Similarly, testosterone upregulated the expression of VEGF mRNA in the S115 cells. Experiments with actinomycin D and cycloheximide suggested that estrogen induction of VEGF mRNA is dependent on the synthesis of new mRNA and increased mRNA half-life. The antiestrogen ICI 182.780 inhibited E2 stimulation of VEGF, suggesting that the effect was mediated by the estrogen receptor. In contrast, the antiestrogens tamoxifen and toremifene which inhibit MCF-7 cell growth in vivo and in vitro did not inhibit estrogen effect but induced VEGF mRNA expression when used alone. The antiandrogen cyprosterone acetate inhibited T induction of VEGF mRNA in S115 cells, thus suggesting that activation of androgen receptor must be involved in the increase of VEGF mRNA. Our results suggest that both estrogen and androgen stimulate the expression of VEGF by increasing gene transcription and mRNA stability. In addition, the antiestrogens tamoxifen and toremifene also increased VEGF expression. Estrogen and androgen induction of VEGF expression and promotion of new vessel formation may be an important paracrine mechanism by which these hormones contribute to the early phase of tumor growth of hormonal cancer.

Expression of the androgen-dependent MMTV-specific orf gene in Shionogi 115 mouse mammary tumor cells.

The Shionogi 115 (S115) mouse mammary tumor cells express the MMTV-specific 1.7 kb mRNA (orf) at a high level in the presence of androgens. In lymphoid cells the orf-gene encodes a superantigen which has an important role in establishing self-tolerance but in mammary and breast cancer cells the function of the orf gene is unclear. In the present work we studied the expression of the S115 mammary tumor cell orf sequence and its role in the androgen regulated growth of S115 cells. The cloning and sequencing of the cDNA specific for the 1.7 kb mRNA from the S115 mouse mammary tumor cells revealed a 990 bp DNA sequence with a 99.8% homology to the Mtv-17 proviral strain. There was a difference of only one amino acid (isoleu-tyr) in the coding region. A peptide was synthesized according to the hypervariable C-terminal part of the predicted protein and used to raise a rabbit antiserum. The anti-S115-orf antiserum immunoprecipitated an approximately 45 kDa protein from the metabolically labeled S115 cell lysates. In order to analyze the putative functions of the protein, the orf-sequence was linked to MoMLV-LTR and to the human ss-actin promoter in the mammalian expression vectors pLTRpoly and pHssAPr-1-neo, respectively, and transfected into NIH3T3 and S115 cells. NIH3T3 transfectants expressing orf mRNA did not show a transformed phenotype in vitro. The S115 orf transfectants proliferated somewhat more slowly than the vector transfected control cells in cell culture, both in the presence or absence of androgen, but there was no obvious change in the phenotype of S115 cells or in expression of the fibroblast growth factor 8 (FGF-8). This factor is activated by Mtv-6 integration and mediates androgen effects in these cells. Unexpectedly, however, the formation of tumors by S115 orf cells in nude mice was considerably prolonged and tumor growth retarded when compared with vector transfected control or parent S115 cells. The results suggest that MMTV-orf can be functional in breast cancer cells but the mechanism of the growth repressive effect in mammary tumor remains to be analyzed.

Activation of Fgf8 in S115 mouse mammary tumor cells is associated with genomic integration of mouse mammary tumor virus.

Fgf8 is an embryonally expressed mitogenic fibroblast growth factor which has transforming capacity. It is expressed in S115 mouse mammary tumor cells (S115 cells) and in parental tumors of DD/Sio mice as well as in some human breast and prostate cancer cell lines. In S115 cells androgens induce the expression of Fgf8 which seems to be associated with the androgen-maintained malignant phenotype of the cells. S115 cells also contain and express Mtv proviruses known to insertionally activate oncogenes in other tumor cells. Here we studied the possibility of insertional activation of Fgf8 in S115 cells by MMTV proviral integration. We demonstrate by Southern blotting that the genomic DNA from DD/Sio tumors and S115 cells contains Mtv-sequences (Mtv-6 and Mtv-17) which are not found in the DNA from spleen or liver of the DD/Sio mice. In addition, the newly integrated Mtv-6 was localized to the DNA fragment containing the Fgf8 gene. Furthermore, the expression of Fgf8 mRNA in DD/Sio tumors and S115 cells was not found in mammary gland or spleen and liver of DD/Sio mice. In S115 cells, Fgf8 mRNA expression was induced in parallel to MMTV mRNA by androgen and glucocorticoids which supports the possibility that Fgf8 is controlled by the steroid-regulated MMTV-LTR. In conclusion, our data provide evidence that the insertion of MMTV into the DD/Sio tumor DNA is associated with the transcriptional activation of Fgf8 in DD/Sio tumor and consequently in S115 mouse mammary tumor cells.