Y-box Binding Protein-1 Enhances Oncogenic Transforming Growth Factor ß Signaling in Breast Cancer Cells via Triggering Phospho-Activation of Smad2.

BACKGROUND/AIM: Transforming growth factor ß (TGFß) plays a role in diverse oncogenic pathways including cell proliferation and cell motility and is regulated by the pleiotropic factor Y-box binding protein-1 (YB-1). In breast cancer, Sma/Mad related protein 2 (Smad2) represents the most common downstream transducer in TGFß signaling. MATERIALS AND METHODS: Here, YB-1's impact on Smad2 phospho-activation was characterized by incubation of the breast cancer cell line MCF-7 with or without TGFß1 in the absence or presence of overexpressed YB-1 protein. The phospho-status of Smad2 was assessed via western blotting. RESULTS: Analysis of MCF-7 cells revealed no induction of total Smad2 neither in the presence of TGFß1, nor during YB-1 overexpression. In contrast, incubation with TGFß1 led to an increase of phosphorylated Smad2 forms which was significantly amplified by simultaneously overexpressed YB-1 (2.8±0.2-fold). CONCLUSION: Oncogenic YB-1 indirectly enhances TGFß signaling cascades via Smad2 phospho-activation and may represent a promising factor for future diagnosis and therapy of breast cancer.

A highly potent and specific MET therapeutic protein antagonist with both ligand-dependent and ligand-independent activity.

Activation of the MET oncogenic pathway has been implicated in the development of aggressive cancers that are difficult to treat with current chemotherapies. This has led to an increased interest in developing novel therapies that target the MET pathway. However, most existing drug modalities are confounded by their inability to specifically target and/or antagonize this pathway. Anticalins, a novel class of monovalent small biologics, are hypothesized to be "fit for purpose" for developing highly specific and potent antagonists of cancer pathways. Here, we describe a monovalent full MET antagonist, PRS-110, displaying efficacy in both ligand-dependent and ligand-independent cancer models. PRS-110 specifically binds to MET with high affinity and blocks hepatocyte growth factor (HGF) interaction. Phosphorylation assays show that PRS-110 efficiently inhibits HGF-mediated signaling of MET receptor and has no agonistic activity. Confocal microscopy shows that PRS-110 results in the trafficking of MET to late endosomal/lysosomal compartments in the absence of HGF. In vivo administration of PRS-110 resulted in significant, dose-dependent tumor growth inhibition in ligand-dependent (U87-MG) and ligand-independent (Caki-1) xenograft models. Analysis of MET protein levels on xenograft biopsy samples show a significant reduction in total MET following therapy with PRS-110 supporting its ligand-independent mechanism of action. Taken together, these data indicate that the MET inhibitor PRS-110 has potentially broad anticancer activity that warrants evaluation in patients.

Antiestrogens suppress effects of transforming growth factor-ß in breast cancer cells via the signaling axis estrogen receptor-α and Y-box Binding Protein-1.

BACKGROUND: Multifunctional Y-box Binding Protein-1 (YB1) is correlated with a poor outcome in breast cancer. We found YB1 expression to be regulated by antiestrogens commonly used in the hormonal therapy of breast cancer and known as activators of Transforming Growth Factor-ß (TGFß). Thus, a putative influence of YB1 on TGFß signaling should be investigated. MATERIALS AND METHODS: The effect of YB1 on TGFß signaling was monitored by expression analysis and reporter gene assays in breast cancer cells overexpressing YB1 and treated with antiestrogens. RESULTS: Antiestrogen-mediated inhibition of estrogen receptor-α led to a suppression of YB1 protein synthesis. On the other hand, YB1 was found to be an enhancer of TGFß signaling. CONCLUSION: High levels of YB1 expression lead to a stimulation of TGFß pathways, thereby counteracting antihormonal breast cancer therapy and representing a putative resistance mechanism.

TNF: a tumor-suppressing factor or a tumor-promoting factor?

TNF-α is a major inflammatory cytokine named for its ability to induce rapid hemorrhagic necrosis of experimental cancers. During efforts to harness this antitumor activity in cancer treatments in the 1980s, a paradoxical tumor-promoting role of TNF became apparent. The cellular and molecular complexity of mammalian tumor microenvironments makes these opposing effects difficult to study. The fruit fly Drosophila melanogaster provides a simpler model system for studying complex cellular and genetic interactions that lead to tumor formation and progression. The paper from Marcos Vidal's group shows that both the tumor-suppressing and tumor-promoting roles of TNF are conserved in Drosophila, and that oncogenic Ras is the switch. The links between inflammation and cancer are now more fully understood, but it is still not clear whether TNF has potential as a target or a therapeutic in malignant disease, or both. Research in an invertebrate organism may provide important insights.

Antiestrogens induce transforming growth factor beta-mediated immunosuppression in breast cancer.

Antiestrogens are universally used to treat estrogen receptor--positive breast cancer, but relapses occur commonly due to the development of drug resistance. The ability of antiestrogen to induce transforming growth factor beta (TGFbeta) in breast cancer cells may be relevant to the emergence of resistance, not only at the level of cell autonomous effects of TGFbeta on cancer progression but also at the level of its effects on the host immune system. To evaluate the potential role of tumor-derived, antiestrogen-induced TGFbeta as an immune suppressor, we established in vitro mixed lymphocyte tumor reactions (MLTR) using MCF-7 cells and peripheral blood mononuclear cells (PBMC), as well as tumor tissue and autologous tumor infiltrating lymphocytes (TIL) obtained from primary breast cancer biopsies. In allogeneic MLTR, antiestrogen-treated MCF-7 cells caused downregulation of the effector molecules granzyme B, perforin, and Fas ligand in CD8(+) T cells, and suppressed the generation of cytotoxic effector cells in a TGFbeta-dependent manner. Furthermore, we documented induction of regulatory T cells in CD4(+) T cells, based on Foxp3 expression and T-cell activation in cocultures. In autologous MLTR, antiestrogen treatment gave rise to enhanced Foxp3 expression of TIL/PBMC and decreased the number of apoptotic tumor cells. These effects were reversed by addition of a TGFbeta neutralizing antibody. Our findings offer evidence that antiestrogen induces immunosuppression in the tumor microenvironment, through a TGFbeta-dependent mechanism that may contribute to the development of antiestrogen resistance in breast cancer.

An in vitro assay to study the transcriptional response during adherence of Candida albicans to different human epithelia.

Adhesion to mammalian epithelia is one of the prerequisites that are essential to accomplish pathogenesis of Candida albicans in the mammalian host. In this context C. albicans is able to adhere to a plethora of different cell types providing different microenvironments for colonization. To study the response of C. albicans adhering to different surfaces on the transcriptional level we have established an in vitro adhesion assay exploiting confluent monolayers of the human colorectal carcinoma cell line Caco-2 or epidermoid vulvo-vaginal A-431 cells. Candida albicans very efficiently adheres to these epithelia growing as hyphae. Using whole-genome DNA microarrays comprising probes for almost 7000 predicted ORFs we found that transcriptional profiles of C. albicans adhering to Caco-2 or to A-431 cells, although very similar, still significantly differ from those of Candida cells adhering to plastic surfaces. Differences became even more obvious when comparing C. albicans cells either growing in an adherent manner or in suspension culture. Correspondingly, we found for several cell surface genes, including PRA1, PGA23, PGA7 and HWP1, an adhesion-dependent induction of transcription. Obviously, C. albicans is able to respond specifically to very subtle differences in the environment during adhesion to various growth substrates.