Estrogen receptor alpha attenuates transforming growth factor-beta signaling in breast cancer cells independent from agonistic and antagonistic ligands.

To investigate a presumed crosstalk between estrogen receptor alpha (ERalpha) and the TGF-beta signaling pathway in breast cancer, we analyzed the TGF-beta-induced expression of the plasminogen activator inhibitor 1 (PAI-1) gene in ER-positive MCF-7 cells. After siRNA-mediated knock-down of endogenous ERalpha, the transcription level of PAI-1 was upregulated, pointing to an attenuation of TGF-beta signaling by the presence of ERalpha. We verified these findings by a vice versa approach using a primary ER-negative cell model transiently overexpressing either ERalpha or ERbeta. We found that ERalpha, but not ERbeta, led to a strong inhibition of the TGF-beta1 signal, monitored by TGF-beta reporter assays. This attenuation was completely independent of receptor stimulation by beta-estradiol (E2) or inhibition by the pure antagonist ICI 182.780 (ICI). Our results indicate a permanent repression of PAI-1 by ERalpha and suggest a ligand-independent crosstalk between ERalpha and TGF-beta signaling in breast cancer cells.

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.

ADAM17 is the main sheddase for the generation of human triggering receptor expressed in myeloid cells (hTREM2) ectodomain and cleaves TREM2 after Histidine 157.

Triggering receptor expressed in myeloid cells (TREM2) is a member of the immunoglobulin superfamily and is expressed in macrophages, dendritic cells, microglia, and osteoclasts. TREM2 plays a role in phagocytosis, regulates release of cytokine, contributes to microglia maintenance, and its ectodomain is shed from the cell surface. Here, the question was addressed at which position sheddases cleave TREM2 and what are the proteases involved in this process. Using both pharmacological and genetic approaches we report that the main protease contributing to the release of TREM2 ectodomain is ADAM17, (a disintegrin and metalloproteinase domain containing protein, also called TACE, TNFα converting enzyme) while ADAM10 plays a minor role. Complementary biochemical experiments reveal that cleavage occurs between histidine 157 and serine 158. Shedding is not altered for the R47H-mutated TREM2 protein that confers an increased risk for the development of Alzheimers disease. These findings reveal a link between shedding of TREM2 and its regulation during inflammatory conditions or chronic neurodegenerative disease like AD in which activity or expression of sheddases might be altered.

Structural dynamics of the DnaK-peptide complex.

The molecular chaperone DnaK recognizes and binds substrate proteins via a stretch of seven amino acid residues that is usually only exposed in unfolded proteins. The binding kinetics are regulated by the nucleotide state of DnaK, which alternates between DnaK.ATP (fast exchange) and DnaK.ADP (slow exchange). These two forms cycle with a rate mainly determined by the ATPase activity of DnaK and nucleotide exchange. The different substrate binding properties of DnaK are mainly attributed to changes of the position and mobility of a helical region in the C-terminal peptide-binding domain, the so-called LID. It closes the peptide-binding pocket and thus makes peptide binding less dynamic in the ADP-bound state, but does not (strongly) interact with peptides directly. Here, we address the question if nucleotide-dependent structural changes may be observed in the peptide-binding region that could also be connected to peptide binding kinetics and more importantly could induce structural changes in peptide stretches using the energy available from ATP hydrolysis. Model peptides containing two cysteine residues at varying positions were derived from the structurally well-documented peptide NRLLLTG and labelled with electron spin sensitive probes. Measurements of distances and mobilities of these spin labels by electron paramagnetic resonance spectroscopy (EPR) of free peptides or peptides bound to the ATP and ADP-state of DnaK, respectively, showed no significant changes of mobility nor distance of the two labels. This indicates that no structural changes that could be sensed by the probes at the position of central leucine residues located in the center of the binding region occur due to different nucleotide states. We conclude from these studies that the ATPase activity of DnaK is not connected to structural changes of the peptide-binding pocket but rather only has an effect on the LID domain or other further remote residues.

Improved cancer immunotherapy by a CD25-mimobody conferring selectivity to human interleukin-2.

Interleukin-2 (IL-2) immunotherapy is an attractive approach in treating advanced cancer. However, by binding to its IL-2 receptor α (CD25) subunit, IL-2 exerts unwanted effects, including stimulation of immunosuppressive regulatory T cells (Tregs) and contribution to vascular leak syndrome. We used a rational approach to develop a monoclonal antibody to human IL-2, termed NARA1, which acts as a high-affinity CD25 mimic, thereby minimizing association of IL-2 with CD25. The structure of the IL-2-NARA1 complex revealed that NARA1 occupies the CD25 epitope of IL-2 and precisely overlaps with CD25. Association of NARA1 with IL-2 occurs with 10-fold higher affinity compared to CD25 and forms IL-2/NARA1 complexes, which, in vivo, preferentially stimulate CD8+ T cells while disfavoring CD25+ Tregs and improving the benefit-to-adverse effect ratio of IL-2. In two transplantable and one spontaneous metastatic melanoma model, IL-2/NARA1 complex immunotherapy resulted in efficient expansion of tumor-specific and polyclonal CD8+ T cells. These CD8+ T cells showed robust interferon-γ production and expressed low levels of exhaustion markers programmed cell death protein-1, lymphocyte activation gene-3, and T cell immunoglobulin and mucin domain-3. These effects resulted in potent anticancer immune responses and prolonged survival in the tumor models. Collectively, our data demonstrate that NARA1 acts as a CD25-mimobody that confers selectivity and increased potency to IL-2 and warrant further assessment of NARA1 as a therapeutic.

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.

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.

Microsomal epoxide hydrolase expression in the endometrial uterine corpus is regulated by progesterone during the menstrual cycle.

We have shown previously that high expression levels of microsomal epoxide hydrolase (mEH) correlate with a poor prognosis of breast cancer patients receiving tamoxifen, suggesting that enhanced mEH expression could lead to antiestrogen resistance (Fritz et al. in J Clin Oncol 19:3-9, 2001). Thus, the purpose of this study was to gain insights into the role of mEH in hormone-responsive tissues. We analyzed biopsy samples of the endometrium by immunohistochemical staining, pointing to a regulation of mEH during the menstrual cycle: during the first half mEH expression was low, increased during the second half and reached highest levels during pregnancy. Additionally, the progesterone receptor (PR) positive human endometrial cell lines IKPRAB-36 (estrogene receptor alpha [ERalpha] negative) and ECC1-PRAB72 (ERalpha positive) were chosen to further investigate the hormonal regulation of mEH expression. Western Blot and quantitative RT-PCR analysis revealed an increase of mEH expression after treatment with medroxy-progesterone 17-acetate (MPA) in the ERalpha containing ECC1-PRAB72 cells. In contrast our results suggest that MPA had no influence on the mEH protein level in the ERalpha- IKPRAB-36 cells. In conclusion, mEH expression is regulated by progesterone in the presence of both PRs and ERalpha.

Functional characterization of the DnaK chaperone system from the archaeon Methanothermobacter thermautotrophicus DeltaH.

We characterized the biochemical and functional properties of the DnaK system from the archaeon Methanothermobacter thermautotrophicus DeltaH. In contrast to the eubacterial chaperone components the archaeal Hsp70 system shows thermal transitions only slightly above the optimal environmental temperature (65 degrees C). Nevertheless, it prevents aggregation of luciferase in the physiological temperature range of the organism, but is also fully functional at 30 degrees C in luciferase refolding. Additionally, GrpE(M.th.) and DnaJ(M.th.) substitute their eubacterial counterparts whereas DnaK(M.th.) is only functional with its native cochaperones which could be attributed to a functional specialization of the eubacterial chaperones during evolution.