Activin A is anti-lymphangiogenic in a melanoma mouse model.

Melanoma spreads primarily to the sentinel lymph nodes, and its risk correlates with lymphangiogenesis, which is mainly driven by vascular endothelial growth factor (VEGF)-C. However, anti-lymphangiogenic factors are poorly characterized. We have shown in a melanoma model that Wnt1 reduces lymphangiogenesis by reducing VEGF-C expression. Screening this model for additional potentially anti-lymphangiogenic factors identified increased activin A expression and reduced expression of the antagonist, follistatin (FST), in Wnt1(+) cells. Activin A is known to reduce blood vessel formation, but the effects on lymphangiogenesis are unknown. Here we show that human primary melanoma expresses significantly higher levels of activin A and lower levels of FST compared with nevi and melanoma metastasis. Using our mouse model with melanoma cells overexpressing Wnt1, FST, Wnt1/FST, or the inhibin ßA subunit (INHBA, resulting in activin A expression), we found both activin A and Wnt1 to reduce lymphangiogenesis. Whereas Wnt1 also reduced metastasis, this was not seen with activin A. In vitro, activin A phosphorylated SMAD2 in both melanoma and lymphatic endothelium but, although it reduced sprouting of lymphatic endothelium, it enhanced the migration of melanoma cells. In conclusion, activin A is an anti-lymphangiogenic factor, but because of its pleiotropic effects on cell mobility it appears not suitable as a pharmacological target.

Epidermal growth factor facilitates melanoma lymph node metastasis by influencing tumor lymphangiogenesis.

Alterations in epidermal growth factor (EGF) expression are known to be of prognostic relevance in human melanoma, but EGF-mediated effects on melanoma have not been extensively studied. As lymph node metastasis usually represents the first major step in melanoma progression, we were trying to identify a potential role of primary tumor-derived EGF in the mediation of melanoma lymph node metastases. Stable EGF knockdown (EGFkd) in EGF-high (M24met) and EGF-low (A375) expressing melanoma cells was generated. Only in EGF-high melanoma cells, EGFkd led to a significant reduction of lymph node metastasis and primary tumor lymphangiogenesis in vivo, as well as impairment of tumor cell migration in vitro. Moreover, EGF-induced sprouting of lymphatic but not of blood endothelial cells was abolished using supernatants of M24met EGFkd cells. In addition, M24met EGFkd tumors showed reduced vascular endothelial growth factor-C (VEGF-C) expression levels. Similarly, in human primary melanomas, a direct correlation between EGF/VEGF-C and EGF/Prox-1 expression levels was found. Finally, melanoma patients with lymph node micrometastases undergoing sentinel node biopsy were found to have significantly elevated EGF serum levels as compared with sentinel lymph node-negative patients. Our data indicate that tumor-derived EGF is important in mediating melanoma lymph node metastasis.

Wnt1 is anti-lymphangiogenic in a melanoma mouse model.

Wnt signals contribute to melanoma progression by boosting their proliferation and survival. Initially, we expected that activated Wnt signaling also improves their proficiency to recruit blood and lymph vessels. To assess this, we added cell culture supernatants (SNs) of Wnt1(+) and Wnt1(-) melanoma to endothelial spheroids. Whereas SNs of Wnt1(-) melanoma cells induced lymphatic sprouts, those of Wnt1(+) cells were unable to do so and this was restored by vascular endothelial growth factor C (VEGF-C). Subsequent testing of several human melanoma lines revealed that Wnt1 suppressed their VEGF-C expression. This Wnt1 effect did not depend on glycogen synthase kinase-3ß (GSK3ß), ß-catenin, or activator protein-1, but was blocked by cyclosporine A (CsA). To analyze Wnt1 effects in melanoma in vivo, we selected Wnt1(-) melanoma cell lines, overexpressed Wnt1, and injected them subepidermally into severe combined immunodeficient (SCID) mice. We found reduced VEGF-C expression, reduced lymphangiogenesis, and delayed metastasis to sentinel nodes in Wnt1(+) as compared with Wnt1(-) melanoma (P<0.05). Concomitant overexpression of VEGF-C or feeding of animals with CsA restored lymphangiogenesis and metastasis in Wnt1(+) melanoma. In conclusion, Wnt1 is anti-lymphangiogenic by suppressing melanoma-derived VEGF-C expression.

The transcription factor SOX18 regulates the expression of matrix metalloproteinase 7 and guidance molecules in human endothelial cells.

BACKGROUND: Mutations in the transcription factor SOX18 are responsible for specific cardiovascular defects in humans and mice. In order to gain insight into the molecular basis of its action, we identified target genes of SOX18 and analyzed one, MMP7, in detail. METHODOLOGY/PRINCIPAL FINDINGS: SOX18 was expressed in HUVEC using a recombinant adenoviral vector and the altered gene expression profile was analyzed using microarrays. Expression of several regulated candidate SOX18 target genes was verified by real-time PCR. Knock-down of SOX18 using RNA interference was then used to confirm the effect of the transcription factor on selected genes that included the guidance molecules ephrin B2 and semaphorin 3G. One gene, MMP7, was chosen for further analysis, including detailed promoter studies using reporter gene assays, electrophoretic mobility shift analysis and chromatin-immunoprecipitation, revealing that it responds directly to SOX18. Immunohistochemical analysis demonstrated the co-expression of SOX18 and MMP7 in blood vessels of human skin. CONCLUSIONS/SIGNIFICANCE: The identification of MMP7 as a direct SOX18 target gene as well as other potential candidates including guidance molecules provides a molecular basis for the proposed function of this transcription factor in the regulation of vessel formation.

Autocrine VEGF signaling synergizes with EGFR in tumor cells to promote epithelial cancer development.

It is established that tumor cell-derived VEGF acts on endothelial cells to promote angiogenesis and tumor growth. Here, we demonstrate that in K5-SOS-dependent mouse skin tumors, autocrine VEGF is required for tumor cell proliferation in a cell-autonomous and angiogenesis-independent manner. VEGF is upregulated in SOS-expressing tumors, and its deletion in epidermal cells delays tumorigenesis by suppressing angiogenesis and tumor cell proliferation. Epidermis-specific Flt1 deletion also impairs tumorigenesis and proliferation. Surprisingly, complete tumor inhibition occurs in the absence of VEGF in EGFR mutant mice, demonstrating that VEGFR and EGFR synergize in neoplastic cells to promote tumor growth. Mechanistically, K5-SOS upregulates VEGF, Flt1, and Neuropilin-1 in an Erk-dependent manner, thereby activating an autocrine proliferation loop, whereas EGFR prevents tumor cells from apoptosis. Moreover, Flt1 is upregulated in human SCC, and its inhibition in SCC cells impairs proliferation. Thus, in addition to regulating angiogenesis, VEGF has to be considered as a potent growth factor for epidermal tumors.

Combination of dacarbazine and dimethylfumarate efficiently reduces melanoma lymph node metastasis.

Dimethylfumarate (DMF) has been shown to reduce melanoma growth and metastasis in animal models. We addressed the question of whether DMF is as effective in its antitumor activity as the US Food and Drug Administration-approved alkylating agent dacarbazine (DTIC). We also tested the possibility of an improved antitumoral effect when both therapeutics were used together. Using our severe combined immunodeficiency (SCID) mouse model, in which xenografted human melanoma cells metastasize from primary skin sites to sentinel nodes, we show that these treatments, alone or in combination, reduce tumor growth at primary sites. Our main finding was that metastasis to sentinel nodes is significantly delayed only in mice treated with a combination of DTIC and DMF. Subsequent experiments were able to show that a combination of DTIC/DMF significantly reduced lymph vessel density in primary tumors as examined by real-time PCR and immunohistochemistry. In addition, DTIC/DMF treatment significantly impaired melanoma cell migration in vitro. In vivo, DTIC/DMF therapy significantly reduced mRNA expression and protein concentration of the promigratory chemokines CXCL2 and CXCL11. In addition, our data suggest that this xenotransplantation model is suitable for preclinical testing of various combinations of antimelanoma agents.

A previously unknown dermal blood vessel phenotype in skin inflammation.

Podoplanin and lymphatic vascular endothelial hyaluronan receptor-1 (LYVE-1) are considered as lineage markers for lymphatic vessel (LV) endothelial cells (LECs). We have recently shown that IL-3 induces de novo expression of these genes in cultured blood vessel (BV) endothelial cells (BEC). To ask, if this is trans-differentiation or activation, we analyzed inflamed skin samples and cytokine-stimulated organ-cultured skin and found a subset of blood capillaries within the papillary dermis expressing low amounts of podoplanin and LYVE-1 as well as high amounts of cytokine-inducible adhesion molecules. In contrast, neighboring lymphatic capillaries express high amounts of podoplanin, LYVE-1 and low amounts of cytokine-inducible adhesion molecules. The different response patterns to inflammatory stimuli were reproducible in cell culture, when cytokine-stimulated BEC and LEC were analyzed. These findings signify that expression of "lymphatic proteins" on BEC corresponds to cell activation.