NF-κB Inhibition through Proteasome Inhibition or IKKβ Blockade Increases the Susceptibility of Melanoma Cells to Cytostatic Treatment through Distinct Pathways

Metastasized melanoma is almost universally resistant to chemotherapy. Given that constitutive or drug-induced upregulation of NF-κB activity is associated with this chemoresistance, NF-κB inhibition may increase the susceptibility to antitumoral therapy. On the cellular level, two principles of NF-κB inhibition, proteasome inhibition by bortezomib and IκB kinase-β (IKKβ) inhibition by the kinase inhibitor of NF-κB-1 (KINK-1), significantly increased the antitumoral efficacy of camptothecin. When combined with camptothecin, either of the two NF-κB-inhibiting principles synergistically influenced progression-related in vitro functions, including cell growth, apoptosis, and invasion through an artificial basement membrane. In addition, when C57BL/6 mice were intravenously injected with B16F10 melanoma cells, the combination of cytostatic treatment with either of the NF-κB-inhibiting compounds revealed significantly reduced pulmonary metastasis compared to either treatment alone. However, on the molecular level, nuclear translocation of p65, cell cycle analysis, and expression of NF-κB-dependent gene products disclosed distinctly different molecular mechanisms, resulting in the same functional effect. That proteasome inhibition and IKKβ inhibition affect distinct molecular pathways downstream of NF-κB, both leading to increased chemosensitivity, is previously unreported. Thus, it is conceivable that switching the two principles of NF-κB inhibition, once resistance to one of the agents occurs, will improve future treatment regimens

Susceptibility of melanoma cells to cytostatic treatment via distinct mechanisms of NF-kB-inhibition

Die vorliegende Arbeit zeigt eine Möglichkeit auf, die bisher meist erfolglose Chemotherapie des malignen Melanoms zu verbessern: Durch Inhibition des Transkriptionsfaktors NF-kB, der für die Regulation vieler tumorrelevanter Gene verantwortlich ist, konnten die Tumorzellen gegenüber der Wirkung von Zytostatika sensibilisiert werden. Zunächst wurden acht verschiedene Melanomzellen in Bezug auf ihre NF-kB-Aktivität und der Expression NF-kB-regulierter Proteine vergleichen. Es konnte gezeigt werden, dass die Mehrzahl der Melanomzellen über konstitutive Aktivität von NF-κB verfügt. Dabei bestand kein eindeutiger Zusammenhang zwischen der Expression NF-kB-regulierter Proteine und der Aktivität dieses Transkriptionsfaktors im Kern, was komplexe Regulationsmechanismen bei der Transkription und Translation vermuten lässt. Anhand einer ausgewählten Melanomzelllinie konnte gezeigt werden, dass zwei verschiedene NF-kB-Inhibitoren, der Proteasom-Inhibitor Bortezomib und der neue IKK-Inhibitor KINK-1 die Aktivität von NF-kB deutlich hemmen. Beim Vergleich beider NF-kB-Inhibitoren ließen sich unerwartet verschiedene molekulare Wirkungsmechanismen nachweisen: Während Bortezomib konzentrationsabhängig eine sehr starke Induktion von NOXA, eine Induktion von p53 sowie eine Abnahme von Cyclin D1 bewirkte, zeigte KINK-1 seine Effekte vor allem in der Reduktion von Chemokinen wie IL-8 und MCP-1. Passend zur Veränderung der Expression zellzyklus-relevanter Proteine hatte Bortezomib einen stärkeren Effekt auf den Zellzyklus als KINK-1. Beide Inhibitoren wurden mit verschiedenen Zytostatika kombiniert und konnten einerseits die Apoptoseinduktion durch Zytostatika verstärken und andererseits die durch Zytostatika reduzierte Invasion weiter reduzieren. Allerdings zeigte sich bei der Untersuchung tumorrelevanter Chemokine, dass KINK-1 im Gegensatz zu Bortezomib synergistische Effekte mit Camptothecin und Doxorubicin aufweist. Trotz molekularer Unterschiede bewirkten beide NF-kB-Inhibitoren vergleichbare funktionelle Effekte auf zellulärer Ebene. Dies galt auch für ein präklinisches in-vivo-Modell, in dem die experimentelle Lungenmetastasierung von B16F10-Melanomzellen in Mäusen ermittelt wurde: Hier wurden die Mäuse mit Camptothecin, KINK-1 und Bortezomib allein im Vergleich zu den jeweiligen Kombinationen aus Zytostatikum und NF-kB-Inhibitor behandelt. Beide Kombinationen zeigten eine signifikante Reduktion des Lungengewichts im Vergleich zu Camptothecin allein. Diese Arbeit konnte also den Nutzen aus NF-kB-Inhibition in Kombination mit Zytostatika für die hier verwendeten Substanzen bekräftigen und dabei einige molekulare Unterschiede aufdecken.Metastasized melanoma is almost resistant to chemotherapie. Constitutive or drug-induced upregulation of NF-kB is one reason for this chemoresistance. That's why inhibition of NF-kB may increase susceptibility to cytostatic drugs. Here, two different mechanisms of NF-kB-inhibition, proteasome inhibition by bortezomib and IkB kinase-beta (IKKbeta) inhibition by the kinase inhibitor of NF-kB-1 (KINK-1) are examined in their antitumoral efficacy and combined with camptothecin. When combined with camptothecin, either of the two NF-kB-inhibiting principles synergistically increased apoptosis and decreased invasion in vitro. In addition, when C57BL/6 mice were intravenously injected with B16F10 melanoma cells, the combination of camptothecin and either of the two compounds (bortezomib and KINK-1) significantly reduced pulmonary metastasis compared to either mono-treatment. However, molecular analysis revealed different mechanisms of the two NF-kB-inhibitors, resulting in the same functional effect. This study shows tow principles of NF-kB-inhibition that successfully augment susceptibility to cytostatic drugs in malignant melanoma

Modulating Tumor Cell Functions by Tunable Nanopatterned Ligand Presentation

Cancer comprises a large group of complex diseases which arise from the misrouted interplay of mutated cells with other cells and the extracellular matrix. The extracellular matrix is a highly dynamic structure providing biochemical and biophysical cues that regulate tumor cell behavior. While the relevance of biochemical signals has been appreciated, the complex input of biophysical properties like the variation of ligand density and distribution is a relatively new field in cancer research. Nanotechnology has become a very promising tool to mimic the physiological dimension of biophysical signals and their positive (i.e., growth-promoting) and negative (i.e., anti-tumoral or cytotoxic) effects on cellular functions. Here, we review tumor-associated cellular functions such as proliferation, epithelial-mesenchymal transition (EMT), invasion, and phenotype switch that are regulated by biophysical parameters such as ligand density or substrate elasticity. We also address the question of how such factors exert inhibitory or even toxic effects upon tumor cells. We describe three principles of nanostructured model systems based on block copolymer nanolithography, electron beam lithography, and DNA origami that have contributed to our understanding of how biophysical signals direct cancer cell fate

Dynamics of Vascular Protective and Immune Supportive Sphingosine-1-Phosphate During Cardiac Surgery

Introduction Sphingosine-1-phosphate (S1P) is a signaling lipid and crucial in vascular protection and immune response. S1P mediated processes involve regulation of the endothelial barrier, blood pressure and S1P is the only known inducer of lymphocyte migration. Low levels of circulatory S1P correlate with severe systemic inflammatory syndromes such as sepsis and shock states, which are associated with endothelial barrier breakdown and immunosuppression. We investigated whether S1P levels are affected by sterile inflammation induced by cardiac surgery. Materials and Methods In this prospective observational study we included 46 cardiac surgery patients, with cardiopulmonary bypass (CPB, n=31) and without CPB (off-pump, n=15). Serum-S1P, S1P-sources and carriers, von-Willebrand factor (vWF), C-reactive protein (CRP), procalcitonin (PCT) and interleukin-6 (IL-6) were measured at baseline, post-surgery and at day 1 (POD 1) and day 4 (POD 4) after surgical stimulus. Results Median S1P levels at baseline were 0.77 nmol/mL (IQR 0.61-0.99) and dropped significantly post-surgery. S1P was lowest post-surgery with median levels of 0.37 nmol/mL (IQR 0.31-0.47) after CPB and 0.46 nmol/mL (IQR 0.36-0.51) after off-pump procedures (P<0.001). The decrease of S1P was independent of surgical technique and observed in all individuals. In patients, in which S1P levels did not recover to preoperative baseline ICU stay was longer and postoperative inflammation was more severe. S1P levels are associated with its sources and carriers and vWF, as a more specific endothelial injury marker, in different phases of the postoperative course. Determination of S1P levels during surgery suggested that also the anticoagulative effect of heparin might influence systemic S1P. Discussion In summary, serum-S1P levels are disrupted by major cardiac surgery. Low S1P levels post-surgery may play a role as a new marker for severity of cardiac surgery induced inflammation. Due to well-known protective effects of S1P, low S1P levels may further contribute to the observed prolonged ICU stay and worse clinical status. Moreover, we cannot exclude a potential inhibitory effect on circulating S1P levels by heparin anticoagulation during surgery, which would be a new pro-inflammatory pleiotropic effect of high dose heparin in patients undergoing cardiac surgery

Adhesion Maturation of Neutrophils on Nanoscopically Presented Platelet Glycoprotein Ibα

Neutrophilic granulocytes play a fundamental role in cardiovascular disease. They interact with platelet aggregates <i>via</i> the integrin Mac-1 and the platelet receptor glycoprotein Ibα (GPIbα). <i>In vivo</i>, GPIbα presentation is highly variable under different physiological and pathophysiological conditions. Here, we quantitatively determined the conditions for neutrophil adhesion in a biomimetic <i>in vitro</i> system, which allowed precise adjustment of the spacings between human GPIbα presented on the nanoscale from 60 to 200 nm. Unlike most conventional nanopatterning approaches, this method provided control over the local receptor density (spacing) rather than just the global receptor density. Under physiological flow conditions, neutrophils required a minimum spacing of GPIbα molecules to successfully adhere. In contrast, under low-flow conditions, neutrophils adhered on all tested spacings with subtle but nonlinear differences in cell response, including spreading area, spreading kinetics, adhesion maturation, and mobility. Surprisingly, Mac-1-dependent neutrophil adhesion was very robust to GPIbα density variations up to 1 order of magnitude. This complex response map indicates that neutrophil adhesion under flow and adhesion maturation are differentially regulated by GPIbα density. Our study reveals how Mac-1/GPIbα interactions govern cell adhesion and how neutrophils process the number of available surface receptors on the nanoscale. In the future, such <i>in vitro</i> studies can be useful to determine optimum therapeutic ranges for targeting this interaction

Adhesion Maturation of Neutrophils on Nanoscopically Presented Platelet Glycoprotein Ibα

Neutrophilic granulocytes play a fundamental role in cardiovascular disease. They interact with platelet aggregates <i>via</i> the integrin Mac-1 and the platelet receptor glycoprotein Ibα (GPIbα). <i>In vivo</i>, GPIbα presentation is highly variable under different physiological and pathophysiological conditions. Here, we quantitatively determined the conditions for neutrophil adhesion in a biomimetic <i>in vitro</i> system, which allowed precise adjustment of the spacings between human GPIbα presented on the nanoscale from 60 to 200 nm. Unlike most conventional nanopatterning approaches, this method provided control over the local receptor density (spacing) rather than just the global receptor density. Under physiological flow conditions, neutrophils required a minimum spacing of GPIbα molecules to successfully adhere. In contrast, under low-flow conditions, neutrophils adhered on all tested spacings with subtle but nonlinear differences in cell response, including spreading area, spreading kinetics, adhesion maturation, and mobility. Surprisingly, Mac-1-dependent neutrophil adhesion was very robust to GPIbα density variations up to 1 order of magnitude. This complex response map indicates that neutrophil adhesion under flow and adhesion maturation are differentially regulated by GPIbα density. Our study reveals how Mac-1/GPIbα interactions govern cell adhesion and how neutrophils process the number of available surface receptors on the nanoscale. In the future, such <i>in vitro</i> studies can be useful to determine optimum therapeutic ranges for targeting this interaction

Adhesion Maturation of Neutrophils on Nanoscopically Presented Platelet Glycoprotein Ibα

Neutrophilic granulocytes play a fundamental role in cardiovascular disease. They interact with platelet aggregates <i>via</i> the integrin Mac-1 and the platelet receptor glycoprotein Ibα (GPIbα). <i>In vivo</i>, GPIbα presentation is highly variable under different physiological and pathophysiological conditions. Here, we quantitatively determined the conditions for neutrophil adhesion in a biomimetic <i>in vitro</i> system, which allowed precise adjustment of the spacings between human GPIbα presented on the nanoscale from 60 to 200 nm. Unlike most conventional nanopatterning approaches, this method provided control over the local receptor density (spacing) rather than just the global receptor density. Under physiological flow conditions, neutrophils required a minimum spacing of GPIbα molecules to successfully adhere. In contrast, under low-flow conditions, neutrophils adhered on all tested spacings with subtle but nonlinear differences in cell response, including spreading area, spreading kinetics, adhesion maturation, and mobility. Surprisingly, Mac-1-dependent neutrophil adhesion was very robust to GPIbα density variations up to 1 order of magnitude. This complex response map indicates that neutrophil adhesion under flow and adhesion maturation are differentially regulated by GPIbα density. Our study reveals how Mac-1/GPIbα interactions govern cell adhesion and how neutrophils process the number of available surface receptors on the nanoscale. In the future, such <i>in vitro</i> studies can be useful to determine optimum therapeutic ranges for targeting this interaction

Adhesion Maturation of Neutrophils on Nanoscopically Presented Platelet Glycoprotein Ibα

Neutrophilic granulocytes play a fundamental role in cardiovascular disease. They interact with platelet aggregates <i>via</i> the integrin Mac-1 and the platelet receptor glycoprotein Ibα (GPIbα). <i>In vivo</i>, GPIbα presentation is highly variable under different physiological and pathophysiological conditions. Here, we quantitatively determined the conditions for neutrophil adhesion in a biomimetic <i>in vitro</i> system, which allowed precise adjustment of the spacings between human GPIbα presented on the nanoscale from 60 to 200 nm. Unlike most conventional nanopatterning approaches, this method provided control over the local receptor density (spacing) rather than just the global receptor density. Under physiological flow conditions, neutrophils required a minimum spacing of GPIbα molecules to successfully adhere. In contrast, under low-flow conditions, neutrophils adhered on all tested spacings with subtle but nonlinear differences in cell response, including spreading area, spreading kinetics, adhesion maturation, and mobility. Surprisingly, Mac-1-dependent neutrophil adhesion was very robust to GPIbα density variations up to 1 order of magnitude. This complex response map indicates that neutrophil adhesion under flow and adhesion maturation are differentially regulated by GPIbα density. Our study reveals how Mac-1/GPIbα interactions govern cell adhesion and how neutrophils process the number of available surface receptors on the nanoscale. In the future, such <i>in vitro</i> studies can be useful to determine optimum therapeutic ranges for targeting this interaction