TY - JOUR A1 - Djuzenova, Cholpon S. A1 - Fiedler, Vanessa A1 - Memmel, Simon A1 - Katzer, Astrid A1 - Sisario, Dmitri A1 - Brosch, Philippa K. A1 - Göhrung, Alexander A1 - Frister, Svenja A1 - Zimmermann, Heiko A1 - Flentje, Michael A1 - Sukhorukov, Vladimir L. T1 - Differential effects of the Akt inhibitor MK-2206 on migration and radiation sensitivity of glioblastoma cells JF - BMC Cancer N2 - Background Most tumor cells show aberrantly activated Akt which leads to increased cell survival and resistance to cancer radiotherapy. Therefore, targeting Akt can be a promising strategy for radiosensitization. Here, we explore the impact of the Akt inhibitor MK-2206 alone and in combination with the dual PI3K and mTOR inhibitor PI-103 on the radiation sensitivity of glioblastoma cells. In addition, we examine migration of drug-treated cells. Methods Using single-cell tracking and wound healing migration tests, colony-forming assay, Western blotting, flow cytometry and electrorotation we examined the effects of MK-2206 and PI-103 and/or irradiation on the migration, radiation sensitivity, expression of several marker proteins, DNA damage, cell cycle progression and the plasma membrane properties in two glioblastoma (DK-MG and SNB19) cell lines, previously shown to differ markedly in their migratory behavior and response to PI3K/mTOR inhibition. Results We found that MK-2206 strongly reduces the migration of DK-MG but only moderately reduces the migration of SNB19 cells. Surprisingly, MK-2206 did not cause radiosensitization, but even increased colony-forming ability after irradiation. Moreover, MK-2206 did not enhance the radiosensitizing effect of PI-103. The results appear to contradict the strong depletion of p-Akt in MK-2206-treated cells. Possible reasons for the radioresistance of MK-2206-treated cells could be unaltered or in case of SNB19 cells even increased levels of p-mTOR and p-S6, as compared to the reduced expression of these proteins in PI-103-treated samples. We also found that MK-2206 did not enhance IR-induced DNA damage, neither did it cause cell cycle distortion, nor apoptosis nor excessive autophagy. Conclusions Our study provides proof that MK-2206 can effectively inhibit the expression of Akt in two glioblastoma cell lines. However, due to an aberrant activation of mTOR in response to Akt inhibition in PTEN mutated cells, the therapeutic window needs to be carefully defined, or a combination of Akt and mTOR inhibitors should be considered. KW - DNA damage KW - glioblastoma multiforme KW - histone H2AX KW - irradiation KW - migration KW - mTOR KW - PTEN KW - p53 KW - radiation sensitivity KW - wound healing Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-200290 VL - 19 ER - TY - JOUR A1 - Djuzenova, Cholpon S. A1 - Fischer, Thomas A1 - Katzer, Astrid A1 - Sisario, Dmitri A1 - Korsa, Tessa A1 - Streussloff, Gudrun A1 - Sukhorukov, Vladimir L. A1 - Flentje, Michael T1 - Opposite effects of the triple target (DNA-PK/PI3K/mTOR) inhibitor PI-103 on the radiation sensitivity of glioblastoma cell lines proficient and deficient in DNA-PKcs JF - BMC Cancer N2 - Background: Radiotherapy is routinely used to combat glioblastoma (GBM). However, the treatment efficacy is often limited by the radioresistance of GBM cells. Methods: Two GBM lines MO59K and MO59J, differing in intrinsic radiosensitivity and mutational status of DNA-PK and ATM, were analyzed regarding their response to DNA-PK/PI3K/mTOR inhibition by PI-103 in combination with radiation. To this end we assessed colony-forming ability, induction and repair of DNA damage by gamma H2AX and 53BP1, expression of marker proteins, including those belonging to NHEJ and HR repair pathways, degree of apoptosis, autophagy, and cell cycle alterations. Results: We found that PI-103 radiosensitized MO59K cells but, surprisingly, it induced radiation resistance in MO59J cells. Treatment of MO59K cells with PI-103 lead to protraction of the DNA damage repair as compared to drug-free irradiated cells. In PI-103-treated and irradiated MO59J cells the foci numbers of both proteins was higher than in the drug-free samples, but a large portion of DNA damage was quickly repaired. Another cell line-specific difference includes diminished expression of p53 in MO59J cells, which was further reduced by PI-103. Additionally, PI-103-treated MO59K cells exhibited an increased expression of the apoptosis marker cleaved PARP and increased subG1 fraction. Moreover, irradiation induced a strong G2 arrest in MO59J cells (similar to 80% vs. similar to 50% in MO59K), which was, however, partially reduced in the presence of PI-103. In contrast, treatment with PI-103 increased the G2 fraction in irradiated MO59K cells. Conclusions: The triple-target inhibitor PI-103 exerted radiosensitization on MO59K cells, but, unexpectedly, caused radioresistance in the MO59J line, lacking DNA-PK. The difference is most likely due to low expression of the DNA-PK substrate p53 in MO59J cells, which was further reduced by PI-103. This led to less apoptosis as compared to drug-free MO59J cells and enhanced survival via partially abolished cell-cycle arrest. The findings suggest that the lack of DNA-PK-dependent NHEJ in MO59J line might be compensated by DNA-PK independent DSB repair via a yet unknown mechanism. KW - DNA damage KW - DNA-PK KW - Histone gamma H2AX KW - p53 KW - Radiation sensitivity Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-265826 VL - 21 ER - TY - THES A1 - Kaymak, Irem T1 - Identification of metabolic liabilities in 3D models of cancer T1 - Identifikation metabolischer Abhängigkeiten in 3D Tumormodellen N2 - Inefficient vascularisation of solid tumours leads to the formation of oxygen and nutrient gradients. In order to mimic this specific feature of the tumour microenvironment, a multicellular tumour spheroid (SPH) culture system was used. These experiments were implemented in p53 isogenic colon cancer cell lines (HCT116 p53 +/+ and HCT116 p53-/-) since Tp53 has important regulatory functions in tumour metabolism. First, the characteristics of the cells cultured as monolayers and as spheroids were investigated by using RNA sequencing and metabolomics to compare gene expression and metabolic features of cells grown in different conditions. This analysis showed that certain features of gene expression found in tumours are also present in spheroids but not in monolayer cultures, including reduced proliferation and induction of hypoxia related genes. Moreover, comparison between the different genotypes revealed that the expression of genes involved in cholesterol homeostasis is induced in p53 deficient cells compared to p53 wild type cells and this difference was only detected in spheroids and tumour samples but not in monolayer cultures. In addition, it was established that loss of p53 leads to the induction of enzymes of the mevalonate pathway via activation of the transcription factor SREBP2, resulting in a metabolic rewiring that supports the generation of ubiquinone (coenzyme Q10). An adequate supply of ubiquinone was essential to support mitochondrial electron transport and pyrimidine biosynthesis in p53 deficient cancer cells under conditions of metabolic stress. Moreover, inhibition of the mevalonate pathway using statins selectively induced oxidative stress and apoptosis in p53 deficient colon cancer cells exposed to oxygen and nutrient deprivation. This was caused by ubiquinone being required for electron transfer by dihydroorotate dehydrogenase, an essential enzyme of the pyrimidine nucleotide biosynthesis pathway. Supplementation with exogenous nucleosides relieved the demand for electron transfer and restored viability of p53 deficient cancer cells under metabolic stress. Moreover, the mevalonate pathway was also essential for the synthesis of ubiquinone for nucleotide biosynthesis to support growth of intestinal tumour organoids. Together, these findings highlight the importance of the mevalonate pathway in cancer cells and provide molecular evidence for an enhanced sensitivity towards the inhibition of mitochondrial electron transfer in tumour-like metabolic environments. N2 - In soliden Tumoren führt die ineffiziente Bildung von Blutgefäßen (Vaskularisierung) zu einem Nährstoff- und Sauerstoffgradienten im gesamten Tumor, welches eine spezifische Tumormikroumgebung schafft. Um diese Tumorumgebung nachzuahmen, wurde ein spezielles multi-zelluläres Tumorsphäroid (SPH) Zellkultursystem verwendet. Da Tp53 wichtige regulatorische Funktionen im Tumormetabolismus hat, wurde zur Generierung von Sphäroiden p53 isogene Darmkrebs-Zelllinen HCT116 (p53 +/+ und p53 -/-) verwendet. Zunächst wurden die Sphäroide mittels RNA Sequenzierung und Metabolomik charakterisiert, um die Genexpression und metabolischen Eigenschaften in verschiedenen Zellkulturbedingungen zu vergleichen. Diese Analyse hat gezeigt, dass gewisse Genexpressionsmuster in Tumoren wie beispielsweise Proliferations- und Hypoxia verwandte Gene in Sphäroiden übereinstimmen, nicht jedoch in Monolayer-Kulturen. Vergleicht man die zwei unterschiedlichen Genotypen miteinander, so sind Gene, die in der Cholesterinhomöostase involviert sind, in p53 defizienten Zellen induziert, nicht jedoch in p53 wildtypischen Zellen. Dieser Unterschied ist in Sphäroiden vorhanden, nicht jedoch in Monolayer-Kulturen. Verlust von p53 führt über die Aktivierung des Transkriptionsfaktors SREBP2 zur Induktion von Enzymen des Mevalonat-Synthesewegs und zudem zu einer neuen metabolischen Vernetzung, die die Generierung von Ubichinon (Coenzym Q10) unterstützt. Eine ausreichende Ubichinon-Versorgung ist wichtig, um den mitochondrialen Elektronentransport und die Pyrimidin-Biosynthese in p53-defizienten Krebszellen unter metabolischen Stressbedingungen zu unterstützen. Darüber hinaus induziert die Inhibition des Mevalonat-Synthesewegs durch Statine in p53-defizienten Darmkrebszellen, die Sauerstoff und Nährstoffmangel ausgesetzt sind, selektiv oxidativen Stress und Apoptose. Verursacht wird dies durch einen Mangel an Ubichinon, welches für den Elektronentransfer der Dihydroorotatdehydrogenase, einem essentiellen Enzym der Pyrimidinnukleotid-Biosynthese, notwendig ist. Gabe von exogenen Nukleosiden entlastete die Nachfrage an Elektronentransfer und stellte die Lebensfähigkeit von p53-defizienten Krebszellen unter metabolischem Stress wieder her. Darüber hinaus konnte gezeigt werden, dass der Mevalonat-Syntheseweg auch für die Synthese von Ubichinon für die Pyrimidinnukleotid-Biosynthese unerlässlich ist, um das Wachstum von Darmtumor-Organoiden zu unterstützen. Zusammengenommen interstreichen diese Ergebnisse die Bedeutung des Mevalonat-Syntheseweg in Krebszellen und liefern den molekularen Mechanismus für die erhöhte Empfindlichkeit von Tumorzellen gegenüber der Hemmung des mitochondrialen Elektronentransfers in einer Tumor-ähnlichen Stoffwechselumgebung. KW - p53 KW - cancer KW - CoQ10 KW - Tumor KW - Modell KW - Stoffwechsel Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-181544 ER - TY - JOUR A1 - Mainz, Laura A1 - Sarhan, Mohamed A. F. E. A1 - Roth, Sabine A1 - Sauer, Ursula A1 - Maurus, Katja A1 - Hartmann, Elena M. A1 - Seibert, Helen-Desiree A1 - Rosenwald, Andreas A1 - Diefenbacher, Markus E. A1 - Rosenfeldt, Mathias T. T1 - Autophagy blockage reduces the incidence of pancreatic ductal adenocarcinoma in the context of mutant Trp53 JF - Frontiers in Cell and Developmental Biology N2 - Macroautophagy (hereafter referred to as autophagy) is a homeostatic process that preserves cellular integrity. In mice, autophagy regulates pancreatic ductal adenocarcinoma (PDAC) development in a manner dependent on the status of the tumor suppressor gene Trp53. Studies published so far have investigated the impact of autophagy blockage in tumors arising from Trp53-hemizygous or -homozygous tissue. In contrast, in human PDACs the tumor suppressor gene TP53 is mutated rather than allelically lost, and TP53 mutants retain pathobiological functions that differ from complete allelic loss. In order to better represent the patient situation, we have investigated PDAC development in a well-characterized genetically engineered mouse model (GEMM) of PDAC with mutant Trp53 (Trp53\(^{R172H}\)) and deletion of the essential autophagy gene Atg7. Autophagy blockage reduced PDAC incidence but had no impact on survival time in the subset of animals that formed a tumor. In the absence of Atg7, non-tumor-bearing mice reached a similar age as animals with malignant disease. However, the architecture of autophagy-deficient, tumor-free pancreata was effaced, normal acinar tissue was largely replaced with low-grade pancreatic intraepithelial neoplasias (PanINs) and insulin expressing islet β-cells were reduced. Our data add further complexity to the interplay between Atg7 inhibition and Trp53 status in tumorigenesis. KW - pancreatic cancer KW - autophagy KW - p53 KW - metastasis KW - ATG7 Y1 - 2022 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-266005 SN - 2296-634X VL - 10 ER - TY - JOUR A1 - Prieto-Garcia, Cristian A1 - Tomašković, Ines A1 - Shah, Varun Jayeshkumar A1 - Dikic, Ivan A1 - Diefenbacher, Markus T1 - USP28: oncogene or tumor suppressor? a unifying paradigm for squamous cell carcinoma JF - Cells N2 - Squamous cell carcinomas are therapeutically challenging tumor entities. Low response rates to radiotherapy and chemotherapy are commonly observed in squamous patients and, accordingly, the mortality rate is relatively high compared to other tumor entities. Recently, targeting USP28 has been emerged as a potential alternative to improve the therapeutic response and clinical outcomes of squamous patients. USP28 is a catalytically active deubiquitinase that governs a plethora of biological processes, including cellular proliferation, DNA damage repair, apoptosis and oncogenesis. In squamous cell carcinoma, USP28 is strongly expressed and stabilizes the essential squamous transcription factor ΔNp63, together with important oncogenic factors, such as NOTCH1, c-MYC and c-JUN. It is presumed that USP28 is an oncoprotein; however, recent data suggest that the deubiquitinase also has an antineoplastic effect regulating important tumor suppressor proteins, such as p53 and CHK2. In this review, we discuss: (1) The emerging role of USP28 in cancer. (2) The complexity and mutational landscape of squamous tumors. (3) The genetic alterations and cellular pathways that determine the function of USP28 in squamous cancer. (4) The development and current state of novel USP28 inhibitors. KW - USP28 KW - SCC KW - USP25 KW - FBXW7 KW - Tp63 KW - c-MYC KW - ΔNp63 KW - p53 KW - cancer KW - DUB inhibitor KW - squamous Y1 - 2021 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-248409 SN - 2073-4409 VL - 10 IS - 10 ER - TY - THES A1 - Scherer, Stefan T1 - Regulation und funktionelle Analyse der menschlichen Mismatchreparaturgene /-proteine am speziellen Beispiel von hMSH2 T1 - Regulation and Functinal Analysis of the Human MIsmatch Repair Genes/Proteines N2 - Das menschliche MHS2 Gen ist eine sehr gut charakterisierte Komponente des Mismatch-Reparatur-Systems (MMR) und häufig mit der HNPCC Erkrankung assoziiert. Der Mechanismus über den MSH2 an der Karzinomentwicklung beteiligt ist, sind Defekte in der DNA-Reparatur. Es konnte gezeigt werden, dass Mutationen in den kodierenden Regionen dieses Gens direkt in die Mikrosatelliteninstabilität involviert sind. Generell ist MSH2 ein Teil des postreplikativen Reparatursystems der Zellen, und schützt so vor der Akkumulation von Mutationen. Dadurch wird die genetische Stabilität und Integrität gewährleistet. Ein anderer Teil der zellulären Krebsabwehr ist das p53 Tumorsuppressorgen. Ein möglicher DNA Schaden, der in der Lage ist, p53 zu aktivieren, ist UV-Licht. Eine weitere gut charakterisierte Komponente der zellulären UV Reaktion ist der Transkriptionsfaktor c-Jun. Ziel der Arbeit war es die Regulation und Signalfunktion von MSH2 näher zu charakterisieren. Dazu wurde der Promotor des Gens in ein Luziferase Promotorgenkonstrukt kloniert. Dieses Konstrukt wurde in menschliche Keratinozyten transfiziert, die nachfolgend mit UV bestrahlt wurden. Es konnte eine zeit- und dosisabhängige Hochregulation von MSH2 gezeigt werden. Diese Transkriptionserhöhung wurde von p53 initiiert, denn durch eine gezielte Mutation der p53-Bindungsstelle im MSH2 Promotor war dieser Effekt vollkommen aufgehoben. Interessanterweise war dieser Effekt von einem zusätzlichen Faktor abhängig, ohne den keine Hochregulation erkennbar war. Verantwortlich hierfür war der Transkriptionsfaktor c-Jun. Dadurch konnte eine funktionelle Interaktion von p53 und c-Jun in der transkriptionellen Aktivierung von hMSH2 gezeigt werden. Dieser zeit- und dosisabhängige Effekt war sowohl auf RNA als auch auf Proteinebene nachvollziehbar. Der größte Anstieg war bei 50 J/m2 zu verzeichnen, wohin gegen bei Verwendung von 75 J/m2 die Transkriptmenge geringer wurde, um bei 100 J/m2 erneut anzusteigen. Um diesen erneuten Anstieg des Proteins näher zu beschreiben wurden bei den stark bestrahlten Zellen TUNEL-Untersuchungen durchgeführt. Hierbei zeigte sich eine positive Korrelation zwischen der Menge an MSH2 Protein und an TUNEL-positiven apoptotischen Zellen. Um weiter zu zeigen, dass der zweite Anstieg des Proteins nicht mit einer Reparaturfunktion verbunden ist, wurde ein biochemisch basierter Test durchgeführt, welcher die Reparaturkapazität semiquantitativ beschreibt. Dabei konnte klar gezeigt werden, dass die mit 100 J/m2 bestrahlten Zellen keine Reparaturfunktion mehr erfüllen. FACS-Analysen und Zellfärbungen gegen Annexin V und mit Propidiumiodid bestätigten die stattfindende Apoptose in den Zellen. Eine weitere Komponente des MMR-Systems ist MSH6. MSH6 bildet mit MSH2 ein Dimer, welches den Fehler in der DNA erkennt und das weitere Reparaturprogramm einleitet. Die Expression dieses Proteins konnte nur bis zu einer Dosis von 50-75 J/m2 UV nachgewiesen werden. Im Gegensatz zu MSH2 war MSH6 nicht in 100 J/m2 bestrahlten Keratinozyten detektierbar. Um über die Lokalisation dieser Proteine mehr zu erfahren wurden Immunfärbungen gegen MSH2 durchgeführt. Es zeigte sich eine Translokation des Proteins vom Kern in das Zytoplasma in Korrelation zum zunehmenden DNA-Schaden durch höhere Dosen an UV-Licht. Dies stellt eine mögliche Verbindung zwischen dem Mismatch-Reparatursystem und apoptotischen Signalwegen dar. N2 - MSH2 is a well-characterized component of the DNA mismatch repair system (MMR) frequently associated with Hereditary Nonpolyposis Colorectal Cancer (HNPCC). The mechanism of MSH2-induced cancer is via defects in DNA mismatch repair. Mutations in the coding region of the human gene (hMSH2) have been shown to be directly involved in microsatellite instability in HNPCC. The MSH2 gene is part of the post-replicative mismatch repair system that prevents the accumulation of spontaneous mutations, and thereby ensures the integrity and stability of the genome. Another component of the cancer prevention machinery is the p53 tumor suppressor. A relevant stress that activates p53 is UV-light. Another well known component of the mammalian UV response is the transcription factor c-Jun. To study the stress regulation and signaling function of hMSH2, we cloned the promoter region of hMSH2 in a luciferase reportergene construct. This construct was transfected in human keratinocytes. The cells were then irradiated with UV light. A time and dosage dependent upregulation of hMSH2 was seen. The transcription of the human mismatch repair gene was activated by p53. This activation was lost upon mutation of the p53 binding site. Interestingly this upregulation critically depends on functional interaction of p53 with c-Jun in the transcriptional control of the hMSH2 promoter. The same effect was seen in analyses of the endogenous hMSH2 gene on the RNA level as well as on the protein level. The highest hMSH2-expression was seen at 50 J/m2. At 75 J/m2 the hMSH2 expression level decreased. Surprisingly, at 100 J /m2 hMSH2 expression increased again. The same dosage dependent function was seen on the protein level. To address the question of a second function of hMSH2 in cells irradiated at high dose, TUNEL-assays were performed. A positive correlation between the level of hMSH2 protein and the number of apoptotic cells was found. To study the repair function of hMSH2 in highly irradiated cells, we used a biochemical mismatch repair assay system. Cells treated with high dosage of UV showed no repair activity in contrast to non-irradiated cells. Annexin V staining and FACS analysis confirmed the apoptotic status of these cells. It is well-known that hMSH6 is necessary for dimer formation with hMSH2 (MutSa) to detect DNA mismatches. So far there are little data on a possible involvement of hMSH6 in apoptosis. Therefore was performed an analysis of hMSH6 protein levels in irradiated cells, revealed that hMSH6 was expressed at doses up to 50 – 75 J/m2. In contrast no hMSH6 was detectable in UV-irradiated cells treated with 100 J/m2. In addition fluorescence immuno labelling of MSH2 revealed the subcellular translocation of the protein from the nucleus to the cytoplasm in apoptotic cells. This effect may indicate a possible link between the mismatch repair system and apoptotic pathways. KW - Mensch KW - Mismatch KW - DNS-Reparatur KW - Mismatchreparatur KW - MSH2 KW - p53 KW - AP-1 KW - Mismatchrepair KW - MSH2 KW - p53 KW - AP-1 Y1 - 2003 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-8317 ER - TY - JOUR A1 - Thiem, Alexander A1 - Hesbacher, Sonja A1 - Kneitz, Hermann A1 - di Primio, Teresa A1 - Heppt, Markus V. A1 - Hermanns, Heike M. A1 - Goebeler, Matthias A1 - Meierjohann, Svenja A1 - Houben, Roland A1 - Schrama, David T1 - IFN-gamma-induced PD-L1 expression in melanoma depends on p53 expression JF - Journal of Experimental & Clinical Cancer Research N2 - Background Immune checkpoint inhibition and in particular anti-PD-1 immunotherapy have revolutionized the treatment of advanced melanoma. In this regard, higher tumoral PD-L1 protein (gene name: CD274) expression is associated with better clinical response and increased survival to anti-PD-1 therapy. Moreover, there is increasing evidence that tumor suppressor proteins are involved in immune regulation and are capable of modulating the expression of immune checkpoint proteins. Here, we determined the role of p53 protein (gene name: TP53) in the regulation of PD-L1 expression in melanoma. Methods We analyzed publicly available mRNA and protein expression data from the cancer genome/proteome atlas and performed immunohistochemistry on tumors with known TP53 status. Constitutive and IFN-ɣ-induced PD-L1 expression upon p53 knockdown in wildtype, TP53-mutated or JAK2-overexpressing melanoma cells or in cells, in which p53 was rendered transcriptionally inactive by CRISPR/Cas9, was determined by immunoblot or flow cytometry. Similarly, PD-L1 expression was investigated after overexpression of a transcriptionally-impaired p53 (L22Q, W23S) in TP53-wt or a TP53-knockout melanoma cell line. Immunoblot was applied to analyze the IFN-ɣ signaling pathway. Results For TP53-mutated tumors, an increased CD274 mRNA expression and a higher frequency of PD-L1 positivity was observed. Interestingly, positive correlations of IFNG mRNA and PD-L1 protein in both TP53-wt and -mutated samples and of p53 and PD-L1 protein suggest a non-transcriptional mode of action of p53. Indeed, cell line experiments revealed a diminished IFN-ɣ-induced PD-L1 expression upon p53 knockdown in both wildtype and TP53-mutated melanoma cells, which was not the case when p53 wildtype protein was rendered transcriptionally inactive or by ectopic expression of p53\(^{L22Q,W23S}\), a transcriptionally-impaired variant, in TP53-wt cells. Accordingly, expression of p53\(^{L22Q,W23S}\) in a TP53-knockout melanoma cell line boosted IFN-ɣ-induced PD-L1 expression. The impaired PD-L1-inducibility after p53 knockdown was associated with a reduced JAK2 expression in the cells and was almost abrogated by JAK2 overexpression. Conclusions While having only a small impact on basal PD-L1 expression, both wildtype and mutated p53 play an important positive role for IFN-ɣ-induced PD-L1 expression in melanoma cells by supporting JAK2 expression. Future studies should address, whether p53 expression levels might influence response to anti-PD-1 immunotherapy. KW - Melanoma KW - PD-L1 KW - CD274 KW - p53 KW - TP53 KW - JAK2 Y1 - 2019 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-201016 VL - 38 ER - TY - THES A1 - Ulrich, Tanja T1 - Function of Lin9 in vivo and MAP3K4-p38 signaling regulates p53 mediated cell cycle arrest after defective mitosis T1 - Funktion von Lin9 in vivo und MAP3K4-p38 Signalweg reguliert einen p53-vermittelten Zellzyklus-Arrest nach fehlerhafte Mitose N2 - Eine genaue Kontrolle des Verlaufs durch die Mitose ist entscheidend für die Gewährleistung genomischer Stabilität und für die Vermeidung von Aneuploidy. Der DREAM Komplex ist ein wichtiger Regulator der Expression von mitotischen Genen. Die Depletion der DREAM-Untereinheit Lin9, führt zu einer verminderten Expression von G2/M Genen und beeinträchtigt die Proliferation. In konditionellen knockout Mauszellen (MEFs) verursacht das Ausschalten von Lin9 Defekte in Mitose und Zytokinese und löst vorzeitige Seneszenz aus, um eine weitere Zellproliferation zu verhindern. In dieser Arbeit konnte gezeigt werden, dass der seneszente Phänotyp in Lin9 knockout MEFs unabhängig von den beiden Tumorsuppressor-Signalwegen p53-p21 und p16-pRB induziert wird. Untersuchungen mit dem konditionellen Lin9 knockout Mausmodell verdeutlichten die wichtige Funktion von Lin9 in der Regulierung der mitotischen Genexpression und der Proliferation in vivo. Das Fehlen von Lin9 führte zu einer verringerten Proliferation in den Krypten des Dünndarms und verursachte eine Atrophie des Darmepithels und einen schnell eintretenden Tod der Tiere. Im zweiten Teil der Arbeit wurden Signalwege untersucht, die nach fehlerhafter Zytokinese zu einem p53 vermittelten G1-Arrest führen. Hierfür wurde ein chemischer Inhibitor der mitotischen Kinase Aurora B verwendet. Mit Hilfe eines Hochdurchsatz siRNA Screens wurde die MAP Kinase MAP3K4 als Aktivator des p53 Signalwegs identifiziert. Es konnte gezeigt werden, dass MAP3K4 die Stresskinase p38b aktiviert, um den p53 vermittelten Zellzyklusarrest in tetraploiden Zellen auszulösen. Dabei wurde p38b nach Hemmung von Aurora B für die transkriptionelle Aktivierung des p53 Zielgens p21 benötigt. Im Gegenteil dazu erfolgte die Phosphorylierung, Stabilisierung und die Rekrutierung von p53 an den p21 Promoter unabhängig von p38. Die teilweise Hemmung von Aurora B zeigte, dass fehlerhafte Segregation von Chromosomen auch den MAP3K4-p38-p53 Signalweg aktiviert und lässt darauf schließen, dass subtile Defekte in der Mitose ausreichen diesen Stress-Signalweg zu induzieren. Obwohl p38 für den G1 Zellzyklusarrest nach mitotischen Schäden erforderlich war, führte die gleichzeitige Inhibierung von p38 und Aurora B über einen längeren Zeitraum zu einer verringerten Proliferation, vermutlich aufgrund verstärkter Apoptose. Es ist anzunehmen, dass der MAP3K4-p38-p53 Signalweg generell nach Defekten in der Mitose oder Zytokinese aktiviert wird um Zellen in G1 zu arretieren und um chromosomale Instabilität zu vermeiden. N2 - Precise control of progression through mitosis is essential to maintain genomic stability and to prevent aneuploidy. The DREAM complex is an important regulator of mitotic gene expression. Depletion of Lin9, one core-subunit of DREAM, leads to reduced expression of G2/M genes and impaired proliferation. In conditional mouse knockout cells (MEFs) Lin9 deletion causes defects in mitosis and cytokinesis and cells undergo premature senescence in order to prevent further proliferation. In this work it could be shown that the senescence phenotype in Lin9 knockout MEFs is independently mediated by the two tumor suppressor pathways p53-p21 and p16-pRB. Studies using the conditional Lin9 knockout mouse model demonstrated an important function of Lin9 in the regulation of mitotic gene expression and proliferation in vivo. Deletion of Lin9 caused reduced proliferation in the intestinal crypts resulting in atrophy of the intestinal epithelium and in rapid death of the animals. In the second part of this work, the pathways leading to p53 mediated G1 arrest after failed cytokinesis were analyzed by using a chemical inhibitor of the mitotic kinase Aurora B. In a high throughput siRNA screen the MAP kinase MAP3K4 was identified as an upstream activator of p53. It could be shown that MAP3K4 activates the downstream stress kinase p38b to induce the p53 mediated cell cycle arrest of tetraploid cells. p38b was required for the transcriptional activation of the p53 target gene p21 in response to Aurora B inhibition. In contrast, phosphorylation, stabilization and recruitment of p53 to the p21 promoter occured independently of p38 signaling. Partial inhibition of Aurora B demonstrated that chromosome missegregation also activates the MAP3K4-p38-p53 pathway, suggesting that subtle defects in mitosis are sufficient for inducing this stress signaling pathway. Although p38 was required for the G1 cell cycle arrest after mitotic failures, long-term co-inhibition of p38 and Aurora B resulted in reduced proliferation probably due to increased apoptosis. Presumably, MAP3K4-p38-p53 signaling is a common pathway that is activated after errors in mitosis or cytokinesis to arrest cells in G1 and to prevent chromosomal instability. KW - Mitose KW - MAP-Kinase KW - Protein p53 KW - Aneuploidie KW - Lin9 KW - defective Mitosis KW - MAP3K4 KW - p53 KW - aneuploidy KW - fehlerhafte Mitose Y1 - 2012 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:bvb:20-opus-73975 ER -