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- melanoma (20) (entfernen)
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- Theodor-Boveri-Institut für Biowissenschaften (20) (entfernen)
Xmrk encodes a putative transmembrane glycoprotein of the tyrosine kinase family and is a melanoma-inducing gene in Xiphophorus. We attempted to investigate the biological function of the putative Xmrk receptor by characterizing its signalling properties. Since a potential Iigand for Xmrk has not yet been identified, it has been difficult to analyse the biochemical properlies and biological function of this cell surface protein. In an approach towards such analyses, the Xmrk extracellular domain was replaced by the closely related Iigand-binding domain sequences of the human epidennal growth factor receptor (HER) and the ligand-induced activity of the chimeric HER-Xmrk proteinwas examined. We show that the Xmrk protein is a functional receptor tyrosine kinase, is highly active in malignant melanoma and displays a constitutive autophosphorylation activity possibly due to an activating mutation in its extracellular or transmembrane domain. In the focus formation assay the HER-Xmrk chimera is a potent transfonning protein equivalent to other tyrosine kinase oncoproteins.
HRAS belongs to the RAS genes superfamily. RAS genes are important players in several human tumors and the single-nucleotide polymorphism rs12628 has been shown to contribute to the risk of bladder, colon, gastrointestinal, oral, and thyroid carcinoma. We hypothesized that this SNP may affect the risk of cutaneous melanoma as well. HRAS gene contains a polymorphic region (rs112587690), a repeated hexanucleotide -GGGCCT- located in intron 1. Three alleles of this region, P1, P2, and P3, have been identified that contain two, three, and four repeats of the hexanucleotide, respectively. We investigated the clinical impact of these polymorphisms in a case–control study. A total of 141 melanoma patients and 118 healthy donors from the North America Caucasian population were screened for rs12628 and rs112587690 polymorphisms. Genotypes were assessed by capillary sequencing or fragment analysis, respectively, and rs12628 CC and rs112587690 P1P1 genotypes significantly associated with increased melanoma risk (OR = 3.83, p = 0.003; OR = 11.3, p = 0.033, respectively), while rs112587690 P1P3 frequency resulted significantly higher in the control group (OR = 0.5, p = 0.017). These results suggest that rs12628 C homozygosis may be considered a potential risk factor for melanoma development in the North American population possibly through the linkage to rs112587690.
Melanome stellen die gefährlichste Form von Hautkrebs mit der höchsten Mortalitätsrate dar. Der Transformation normaler Melanozyten zu malignen Melanomen liegen komplexe molekulare und biochemische Veränderungen zu Grunde. Im Xiphophorus-Melanom-Modell ist die onkogene Rezeptortyrosinkinase "Xiphophorus melanoma receptor kinase" (Xmrk) der alleinige Auslöser der Melanominitiation und -progression. Die Aufklärung der Xmrk-vermittelten Signaltransduktion kann zum besseren Verständnis von Ereignissen, die auch bei der humanen Melanomentwicklung eine Rolle spielen, beitragen. In der vorliegenden Arbeit wurde mit Hilfe der Microarray-Technologie die Regulation der Genexpression durch Xmrk analysiert. Zu den nach Rezeptoraktivierung am stärksten herabregulierten Genen gehörten "son of sevenless homolog 1" (Sos1) und "ubiquitin-conjugating enzyme E2I" (Ube2i); stark hochreguliert waren "early growth response 1" (Egr1), "cysteine-rich protein 61" (Cyr61), "dual-specificity phosphatase 4" (Dusp4), "fos-like antigen 1" (Fosl1), "epithelial membrane protein" (Emp1), Osteopontin (Opn), "insulin-like growth factor binding protein 3" (Igfbp3) und "tumor-associated antigen L6" (Taal6). Die für die Regulation dieser Gene verantwortlichen Signalwege wurden durch die Anwendung von niedermolekularen Inhibitoren und siRNA identifiziert, wobei für die SRC-Kinase FYN eine zentrale Bedeutung bei der Xmrk-abhängigen Regulation der Genexpression festgestellt wurde. Darüber hinaus wurde die Expression der Gene in humanen Melanomzelllinien im Vergleich zu normalen humanen Melanozyten untersucht. Als besonders vielversprechende Kandidaten stellten sich dabei DUSP4 und TAAL6 heraus, deren Rolle in der humanen Melanominduktion und -progression Gegenstand zukünftiger Studien sein wird. In einem anderen Ansatz zur Aufklärung des Signalnetzwerkes sollten Zielproteine von Xmrk durch Protein-Protein-Interaktionsstudien mit Hilfe des Split-Ubiquitin-Systems ermittelt werden. Aufgrund ungünstiger Expressions- oder Faltungseigenschaften von Xmrk in diesem System war es aber nicht möglich, den Rezeptor als Köderprotein einzusetzen. Das für die Xmrk-vermittelte Melanomentstehung zentrale Protein FYN konnte jedoch als Köder etabliert und seine Wechselwirkung mit der Tyrosinkinase FAK analysiert werden. Es wurde gezeigt, dass der phosphorylierte Tyrosinrest an Position 397 von FAK für die Interaktion einer N-terminal trunkierten FAK-Variante mit FYN notwendig ist und dass diese Phosphorylierung in Hefe gewährleistet zu sein scheint. Die Suche nach neuen Interaktionspartnern von FYN mittels der Split-Ubiquitin-Technologie könnte Einblicke in weitere FYN-abhängige Ereignisse bieten, die zur Aufklärung seiner zentralen Rolle bei der Tumorentstehung dienen könnte.
T-Zellimmunantworten werden normalerweise durch folgenden Weg initiiert: unreife dendritische Zellen nehmen Antigen in der Peripherie auf, wandern in die sekundären lymphatischen Organe, wobei sie auf ihrem Weg sowohl reifen als auch das Antigen prozessieren. In den sekundären lymphatischen Organen angekommen, präsentieren sie als reife dendritische Zellen den T-Zellen die Antigene in Form von Peptiden zusammen mit kostimulierenden Molekülen. Dadurch rufen sie eine spezifische T-Zellantwort hervor. In der vorliegenden Arbeit wurde untersucht, ob nicht Situationen herbeigeführt werden können, die ein T-Zell priming außerhalb der sekundären lymphatischen Organe erlauben. Dazu wurden ein murines Modell, bei dem das Zytokin Lymphotoxin-alpha spezifisch am Tumor angereichert wurde, und ein humanes Modell, bei dem reife, antigenbeladene DC intradermal appliziert wurden, untersucht. Im murinen Modell zeigte sich, dass die gerichtete Anreicherung von Lymphotoxin-alpha am Tumor zu dessen Zerstörung führte, welche durch T-Zellen vermittelt wurde, und mit der Induktion eines tertiären lymphatischen Gewebes am Tumor assoziiert war. Dieses tertiäre lymphatische Gewebe war durch die Kompartimentalisierung von T- und B-Zellen und der Präsenz von high endothelial venules charakterisiert und besaß zudem mit dendritischen Zellen und naïven T-Zellen alle Voraussetzungen für ein in loco priming. Dementsprechend konnte in der Folge der gerichteten Lymphotoxin-alpa Therapie im Tumor ein Anstieg am T-Zellinfiltrat, welches sich oligoklonal zusammensetzte, beobachtet werden. In vitro Experimente verdeutlichte die Tumorspezifität der Therapie-induzierten T-Zellantwort, da die T-Zellen auf ein Tumorantigen mit der Ausschüttung von Interferon gamma reagierten und die Tumorzellen lysierten. Im humanen Modell wurden Hautbiopsien von Melanompatienten untersucht, denen im Rahmen einer klinischen Studie autologe, in vitro generierte und antigenbeladene DC intradermal appliziert wurden. Die Patienten erlaubten die Entnahme von Hautbiopsien aus den Injektionsstellen für wissenschaftliche Untersuchungen. Eine Induktion bzw. Verstärkung einer spezifischen T-Zellantwort durch die Vakzinierung mit antigenbeladenen dendritischen Zellen konnte bereits in zahlreichen Arbeiten und auch in dem in dieser Arbeit untersuchten Patientenkollektiv gezeigt werden. Bei der Analyse der Injektionsstellen zeigt sich, dass ein großer Teil der injizierten dendritischen Zellen in der Vakzinierungsstelle verharren und dass diese unabhängig von einer Beladung mit Antigen zu einer Induktion von high endothelial venules Charakteristika führte. Waren die dendritischen Zellen mit Antigen beladen, so führte dies zu einem stärkeren T-Zellinfiltrat in den Injektionsstellen, wobei sowohl naïve als auch central memory T-Zellen nachgewiesen wurde. Diese Zellen wurden vermutlich durch die Überexpression der DC CK1 und SDF1 Chemokinen in den Injektionsstellen, die chemotaktisch auf T-Zellen wirken, angezogen. Das Infiltrat in den Injektionsstellen war oligoklonal und wies tumorspezifische T-Zellen auf. Nachdem diese T-Zellklone im Blut der Patienten vor der Vakzinierung nicht nachweisbar waren, müssen sie zumindest in den Injektionsstellen expandiert sein. Interessanterweise konnte einer dieser Klone in Metastasen nachgewiesen werden, die nach der Vakzinierung dem Patienten entfernt wurden. In beiden Modellen wurde also durch die Manipulation des Mikromilieus, d.h. Lymphotoxin-alpa Anreicherung am Tumor bzw. Injektion von reifen dendritischen Zellen in die Haut, Strukturen wie z.B. high endothelial venules induziert, die ein in loco priming ermöglichen sollten. Dementsprechend riefen diese Veränderungen ein Tumorantigen-spezifisches Infiltrat hervor. Diese Ergebnisse deuten darauf hin, dass T-Zell priming auch außerhalb sekundärer lymphatischer Organe erfolgen kann. Prinzipiell scheint also nur der Kontakt von reifen, antigenbeladenen dendritischen Zellen mit den entsprechenden antigenspezifischen, naïven T-Zellen entscheiden zu sein. Die Möglichkeit des in vitro primings bekräftigt diese These. In vivo erfolgt dieses Aufeinandertreffen normalerweise in den sekundären lymphatischen Organen, doch konnte in der vorliegenden Arbeit gezeigt werden, dass Veränderungen des Mikromilieus diesen Kontakt auch in anderen Geweben ermöglicht.
Peroxiredoxin 6 (PRDX6) is a bifunctional enzyme comprising a peroxidase and a Ca2+-independent phospholipase (iPLA2) activity. This renders the enzyme capable of detoxifying reactive oxygen species (ROS) and of catalyzing the liberation of arachidonic acid (AA) from cellular membranes. Released AA can be further metabolized to bioactive lipids including eicosanoids, which are involved in inflammation, cell growth, differentiation, invasion and proliferation. Human melanoma cells are often characterized by imbalances in both ROS and lipid levels, which can be generated by oncogenic signaling, altered metabolism or UV irradiation.
In previous studies, a comparative proteome analysis of the Xiphophorus fish melanoma model revealed a strong upregulation of Prdx6 in benign and malignant lesions compared to healthy skin. As the Xiphophorus melanoma model displays in many respects molecular characteristics that are similar to human melanoma, I investigated the functional role of PRDX6 in human melanoma cells.
The first part of the study deals with the regulation of PRDX6 in melanocytes and human melanoma cells. I could demonstrate that the protein level of PRDX6 was strongly enhanced by the induction of the EGFR orthologue Xmrk from the Xiphophorus fish as well as the human EGFR. The upregulation of PRDX6 was further shown to be mediated in a PI3K-dependent and ROS-independent manner.
The main part of the thesis comprises the investigation of the functional role of PRDX6 in human melanoma cells as well as the analysis of the underlying mechanism. I could show that knockdown of PRDX6 enhanced the oxidative stress response and led to decreased proliferation of melanoma cells. This cell growth effect was mainly mediated by the iPLA2 activity of PRDX6. Under conditions of strongly enhanced oxidative stress, the peroxidase activity became also important for cellular proliferation. Furthermore, the anti-proliferative effect in cells with lowered PRDX6 levels was the result of reduced cellular AA content and the decrease in the activation of SRC family proteins. Similarly, supplementation with AA led to regeneration of SRC family kinase activity and to an improvement in the reduced proliferation after knockdown of PRDX6. Since AA can be further processed into the prostaglandin PGE2, which has a pro-tumorigenic function in some cancer types, I further examined whether this eicosanoid is involved in the proliferative function of PRDX6. In contrast to AA, PGE2 was not consistently required for melanoma proliferation.
In summary, I could demonstrate that PRDX6 plays a major role in AA-dependent lipid signaling in melanoma cells and thereby regulates proliferation. Interestingly, the proliferation relevant iPLA2 activity can be pharmacologically targeted, and melanoma cell growth was clearly blocked by the inhibitor BEL. Thus, I could identify the phospholipase activity of PRDX6 as a new therapeutically interesting target for melanoma treatment.
The Ras/RAF/MEK/ERK cascade is a central cellular signal transduction pathway involved in cell proliferation, differentiation, and survival where RAF kinases are pivotal kinases implicated in cancer. The development of specific irreversible kinase inhibitors is a rewarding but difficult aim. CI-1033 was developed to irreversibly inhibit erbB receptor tyrosine kinases by reacting to the Cys113 residue (p38alpha MAP kinase numbering) of the kinase domain. In this study we tried a similar approach to target the RAF oncoproteins which posses a similar cysteine at position 108 in the hinge region between the small n-lobe and the large c-lobe of the kinase domain. A novel synthetic approach including a lyophilization step allowed us the synthesis of a diphenyl urea compound with an epoxide moiety (compound 1). Compound 1 possessed inhibitory activity in vitro. However our time kinetics experiments and mass spectroscopic studies clearly indicate that compound 1 does not react covalently with the cysteine residue in the hinge region. Moreover, in cell culture experiments, a strong activation of the RAF signaling pathway was observed, an effect which is known from several other RAF kinase inhibitors and is here reported for the first time for a diphenyl urea compound, to which the clinically used unspecific kinase inhibitor BAY 43-9006 (Sorafinib, Nexavar) belongs. Although activation was apparently independent on B- and C-RAF hetero-oligomerization in vitro, in vivo experiments support such a mechanism as the activation did not occur in starved knockout cells lacking either B-RAF or C-RAF. Furthermore, we developed a mathematical model of the Ras/RAF/MEK/ERK cascade demonstrating how stimuli induce different signal patterns and thereby different cellular responses, depending on cell type and the ratio between B-RAF and C-RAF. Based on biochemical data for activation and dephosphorylation, we set up differential equations for a dynamical model of the Ras/RAF/MEK/ERK cascade. We find a different signaling pattern and response result for B-RAF (strong activation, sustained signal) and C-RAF (steep activation, transient signal). We further support the significance of such differential modulatory signaling by showing different RAF isoform expression in various cell lines and experimental testing of the predicted kinase activities in B-RAF, C-RAF as well as mutated versions. Additionally the effect of the tumor suppressor DiRas3 (also known as Noey2 or ARHI) on RAF signaling was studied. I could show that DiRas3 down-regulates the mitogenic pathway by inhibition of MEK, a basis for a refined model of the Ras/RAF/MEK/ERK cascade.
The Xiphophorus melanoma system is a useful animal model for the study of the genetic basis of tumor formation. The development of hereditary melanomas in interspecific hybrids of Xiphophorus is connected to pigment cell specific overexpression of the mutationally activated receptor tyrosine kinase Xmrk. In purebred fish the oncogenic function of xmrk is suppressed by the molecularly still unidentified locus R. The xmrk oncogene was generated by a gene duplication event from the Xiphophorus egfrb gene and thereby has acquired a new 5’ regulatory sequence, which has probably altered the transcriptional control of the oncogene. So far, the xmrk promoter region was still poorly characterized and the molecular mechanism by which R controls xmrk-induced melanoma formation in Xiphophorus still remained to be elucidated. To test the hypothesis that R controls melanoma development in Xiphophorus on the transcriptional level, the first aim of the thesis was to gain a deeper insight into the transcriptional regulation of the xmrk oncogene. To this end, a quantitative analysis of xmrk transcript levels in different Xiphophorus genotypes carrying either the highly tumorigenic xmrkB or the non-tumorigenic xmrkA allele was performed. I was able to demonstrate that expression of the tumorigenic xmrkB allele is strongly increased in malignant melanomas of R-free backcross hybrids compared to benign lesions, macromelanophore spots, and healthy skin. The expression level of the non-tumorigenic xmrkA allele, in contrast, is not influenced by the presence or absence of R. These findings strongly indicate that differential transcriptional regulation of the xmrk promoter triggers the tumorigenic potential of these xmrk alleles. To functionally characterize the xmrk promoter region, I established a luciferase assay using BAC clones containing the genomic regions where xmrk and egfrb are located for generation of reporter constructs. This approach showed for the first time a melanoma cell specific transcriptional activation of xmrkB by its flanking regions, thereby providing the first functional evidence that the xmrk oncogene is controlled by a pigment cell specific promoter region. Subsequent analysis of different deletion constructs of the xmrkB BAC reporter construct strongly indicated that the regulatory elements responsible for the tumor-inducing overexpression of xmrkB in melanoma cells are located within 67 kb upstream of the xmrk oncogene. Taken together, these data indicate that melanoma formation in Xiphophorus is regulated by a tight transcriptional control of the xmrk oncogene and that the R locus acts through this mechanism. As the identification of the R-encoded gene(s) is necessary to fully understand how melanoma formation in Xiphophorus is regulated, I furthermore searched for alternative R candidate genes in this study. To this end, three genes, which are located in the genomic region where R has been mapped, were evaluated for their potential to be a crucial constituent of the regulator locus R. Among these genes, I identified pdcd4a, the ortholog of the human tumor suppressor gene PDCD4, as promising new candidate, because this gene showed the expression pattern expected from the crucial tumor suppressor gene encoded at the R locus.
The cystine/glutamate antiporter xCT is an important source of cysteine for cancer cells. Once taken up, cystine is reduced to cysteine and serves as a building block for the synthesis of glutathione, which efficiently protects cells from oxidative damage and prevents ferroptosis. As melanomas are particularly exposed to several sources of oxidative stress, we investigated the biological role of cysteine and glutathione supply by xCT in melanoma. xCT activity was abolished by genetic depletion in the Tyr::CreER; Braf\(^{CA}\); Pten\(^{lox/+}\) melanoma model and by acute cystine withdrawal in melanoma cell lines. Both interventions profoundly impacted melanoma glutathione levels, but they were surprisingly well tolerated by murine melanomas in vivo and by most human melanoma cell lines in vitro. RNA sequencing of human melanoma cells revealed a strong adaptive upregulation of NRF2 and ATF4 pathways, which orchestrated the compensatory upregulation of genes involved in antioxidant defence and de novo cysteine biosynthesis. In addition, the joint activation of ATF4 and NRF2 triggered a phenotypic switch characterized by a reduction of differentiation genes and induction of pro-invasive features, which was also observed after erastin treatment or the inhibition of glutathione synthesis. NRF2 alone was capable of inducing the phenotypic switch in a transient manner. Together, our data show that cystine or glutathione levels regulate the phenotypic plasticity of melanoma cells by elevating ATF4 and NRF2.
Tumor angiogenesis is a process which is traditionally regarded as the tumor’s response to low nutrient supply occurring under hypoxic conditions. However, hypoxia is not a pre-requisite for angiogenesis. The fact that even single tumor cells or small tumor cell aggregates are capable of attracting blood vessels reveals the early metastatic capability of tumor cells. This review sheds light on the hypoxia-independent mechanisms of tumor angiogenesis in melanoma.
Fish of the genus Xiphophorus belong to the oldest animal models in cancer research. The oncogene responsible for the generation of spontaneous aggressive melanoma encodes for a mutated epidermal growth factor receptor (Egfr) and is called xmrk for Xiphophorus melanoma receptor kinase. Xmrk constitutive activation mechanisms and subsequent signaling pathways have already been investigated and charaterized but it is still unknown if Egfr ligands may also play a role in Xmrk-driven melanoma formation. To investigate the potential role of Egfr ligands in Xmrk-driven melanoma, I firstly analyzed the evolution of teleost and tetrapod Egfr/Egfr ligand systems. I especially focused on the analysis on the medaka fish, a closely related species to Xiphophorus, for which the whole genome has been sequenced. I could identify all seven Egfr ligands in medaka and could show that the two teleost-specific Egfr copies of medaka display dissimilar expression patterns in adult tissues together with differential expression of Egfr ligand subsets, arguing for subfunctionalization of receptor functions in this fish. Our phylogenetic and synteny analyses supported the hypothesis that only one gene in the chordate ancestor gave rise to the diversity of Egfr ligands found in vertebrate genomes today. I also could show that the Egfr extracellular subdomains implicated in ligand binding are not evolutionary conserved between tetrapods and teleosts, making the use of heterologous ligands in experiments with fish cells debatable. Despite its well understood and straight-forward process, Xmrk-driven melanomagenesis in Xiphophorus is problematic to further investigate in vivo. Our laboratory recently established a new melanoma animal model by generating transgenic mitf::xmrk medaka fishes, a Xiphophorus closely related species offering many more advantages. These fishes express xmrk under the control of the pigment-cell specific Mitf promoter. During my PhD thesis, I participated in the molecular analysis of the stably transgenic medaka and could show that the Xmrk-induced signaling pathways are similar when comparing Xiphophorus with transgenic mitf::xmrk medaka. These data together with additional RNA expression, protein, and histology analyses showed that Xmrk expression under the control of a pigment cell-specific promoter is sufficient to induce melanoma in the transgenic medaka, which develop very stereotyped tumors, including uveal and extracutaneous melanoma, with early onset during larval stages. To further investigate the potential role of Egfr ligands in Xmrk-driven melanoma, I made use of two model systems. One of them was the above mentioned mitf::xmrk medaka, the other was an in-vitro cell culture system, where the EGF-inducible Xmrk chimera HERmrk is stably expressed in murine melanocytes. Here I could show that HERmrk activation strongly induced expression of amphiregulin (Areg) and heparin-binding EGF-like growth factor (Hbegf) in melanocytes. This regulation was dependent on the MAPK and SRC signaling pathways. Moreover, upregulation of Adam10 and Adam17, the two major sheddases of Egfr ligands, was observed. I also could demonstrate the functionality of the growth factors by invitro analyses. Using the mitf::xmrk medaka model I could also show the upregulation of a subset of ligand genes, namely egf, areg, betacellulin (btc) and epigen (epgn) as well as upregulation of medaka egfrb in tumors from fish with metastatic melanoma. All these results converge to support an Xmrk-induced autocrine Egfr ligand loop. Interestingly, my in-vitro experiments with conditioned supernatant from medaka Egf- and Hbegf-producing cells revealed that not only Xiphophorus Egfrb, but also the pre-activated Xmrk could be further stimulated by the ligands. Altogether, I could show with in-vitro and in-vivo experiments that Xmrk is capable of inducing a functional autocrine Egfr ligand loop. These data confirm the importance of autocrine loops in receptor tyrosine kinase (RTK)-dependent cancer development and show the possibility for a constitutively active RTK to strengthen its oncogenic signaling by ligand binding.