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Protein quality control systems (PQC), i.e. UPS and aggresome-autophagy pathway, have been suggested to be a promising target in cancer therapy. Simultaneous pharmacological inhibition of both pathways have shown increase efficacy in various tumors, such as ovarian and colon carcinoma. Here, we investigate the effect of concomitant inhibition of 26S proteasome by FDA-approved inhibitor Bortezomib, and HDAC6, as key mediator of the aggresome-autophagy system, by the highly specific inhibitor ST80 in rhabdomyosarcoma (RMS) cell lines. We demonstrated that simultaneous inhibition of 26S proteasome and selective aggresome-autophagy pathway significantly increases apoptosis in all tested RMS cell lines. Interestingly, we observed that a subpopulation of RMS cells was able to survive the co-treatment and, upon drug removal, to recover similarly to untreated cells. In this study, we identified co-chaperone BAG3 as the key mediator of this recovery: BAG3 is transcriptionally up-regulated specifically in the ST80/Bortezomib surviving cells and mediates clearance of cytotoxic protein aggregates by selective autophagy. Impairment of the autophagic pathway during the recovery phase, both by conditional knock-down of ATG7 or by inhibition of lysosomal degradation by BafylomicinA1, triggers accumulation of insoluble protein aggregates, loss of cell recovery and cell death similarly to stable short harpin RNA (shRNA) BAG3 knock-down. Our results are the first demonstration that BAG3 mediated selective autophagy is engaged to cope with proteotoxicity induced by simultaneous inhibition of constitutive PQC systems in cancer cell lines during cell recovery. Moreover, our data give new insights in the regulation of constitutive and on demand PQC mechanisms pointing to BAG3 as a promising target in RMS therapy.
HDAC inhibitors (HDACI), a new class of anticancer agents, induce apoptosis in many cancer entities. JNJ-26481585 is a second generation class І HDACI that displays improved efficacy in preclinical studies compared to the established HDACI SAHA (Vorinostat). Therefore, this study aims at evaluating the effects of JNJ-26481585 on human rhabdomyosarcoma (RMS) and at identifying novel synergistic interactions of JNJ-26481585 or the more common HDACI SAHA with different anticancer drugs in RMS cells. Indeed, we show that JNJ-26481585 and SAHA significantly increase chemotherapeutic drug-induced apoptosis in embryonal and alveolar RMS cell lines, when used in combination with chemotherapeutic agents (i.e. doxorubicin, etoposide, vincristine, and cyclophosphamide) which are currently used in the clinic for the treatment of RMS.
We demonstrate that JNJ-26481585 as single agent and in combination with doxorubicin induces apoptosis, which is characterized by activation of the caspase cascade, PARP cleavage, and DNA fragmentation. Induction of caspase-dependent apoptotic cell death is confirmed by the use of the broad-range caspase inhibitor zVAD.fmk, which significantly decreases both JNJ-26481585-triggered and combination treatment-mediated DNA fragmentation, and in addition completely abrogates loss of cell viability. Importantly, JNJ-26481585 significantly inhibits tumor growth in vivo in two preclinical RMS models, i.e. the chicken chorioallantoic membrane (CAM) model and a xenograft mouse model, supporting the notion that JNJ-26481585 hampers tumor maintenance. Also, in combination with doxorubicin JNJ-26481585 significantly reduces tumor growth in in vivo experiments using the CAM model.
Mechanistically, we identify that JNJ-26481585-induced apoptosis is mediated via the intrinsic apoptotic pathway, since we observe increased loss of mitochondrial membrane potential and activation of the proapoptotic Bcl-2 family members Bax and Bak. Interestingly, we find that JNJ-26481585 triggers induction of Bim, Bmf, Puma, and Noxa on mRNA level as well as on protein level, pointing to an altered transcription of BH3-only proteins as important event for the Bax/Bak-mediated loss of mitochondrial membrane potential as well as mitochondrial apoptosis induction upon JNJ-26481585 treatment. JNJ-26481585-initiated activation of Bax and Bak is not prevented with the addition of zVAD.fmk, suggesting that JNJ-26481585 first disrupts the mitochondria and subsequently activates the caspase cascade. When JNJ-26481585 is used in combination with doxorubicin, we observe not only an increase of proapoptotic Bcl-2 proteins, but also a decrease in the level of the antiapoptotic mitochondrial proteins Bcl-2, Mcl-1, and Bcl-xL. This indicates that Bax, Bak, Bim, and Noxa are crucial for JNJ-26481585-induced as well as JNJ/Dox treatment-induced apoptosis, since RNAi mediated silencing of Bax, Bak, Bim, and Noxa significantly impedes DNA fragmentation upon those treatments.
Furthermore, ectopic overexpression of Bcl-2 profoundly impairs both JNJ-26481585 and combination treatment-mediated apoptosis, abrogates caspase cleavage, and reduces activation of Bax and Bak, underlining the hypothesis that JNJ-26481585 initially targets the mitochondria and then activates caspases.
With the more commonly used HDACI SAHA we confirm the results obtained with the HDACI JNJ-26481585, since combination treatment with SAHA and doxorubicin also induces intrinsic apoptosis, which can be significantly diminished by zVAD.fmk or ectopic overexpression of Bcl-2. Treatment with SAHA and doxorubicin also affects expression levels of pro- and antiapoptotic mitochondrial proteins, thus shifting the balance towards the proapoptotic mitochondrial machinery, resulting in Bax/Bak activation, caspase activation, and subsequently apoptosis.
Taken together, we provide evidence that the HDACIs JNJ-26481585 and SAHA are promising therapeutic agents for the treatment of RMS and that combination regimens with HDACIs represent an efficient strategy to prime RMS cells for chemotherapy-induced apoptosis. These findings have important implications for mitochondrial apoptosis-targeted therapies of RMS.
Das Neuroblastom ist der häufigste extrakranielle solide Tumor des Kindesalters. Bei Diagnosestellung befinden sich die meisten Patienten bereits in fortgeschrittenen Tumorstadien; trotz intensiver multimodaler Therapie überleben nur 30-40% der Hochrisikopatienten die Erkrankung. Zum Therapieversagen führt in den meisten Fällen eine Resistenzentwicklung des Tumors gegenüber den Chemotherapeutika. Die Entdeckung neuer effektiver Therapieansätze und Überwindung der Chemoresistenz durch Resensibilisierung der Tumorzellen ist daher ein dringendes Forschungsanliegen.
Zur Charakterisierung der Zelllinien im ersten Teil dieser Arbeit wurde die Zellmorphologie, die Gen- und Proteinexpression verschiedener Differenzierungs- bzw. Krebsstammzell-Marker und das Anoikis-Verhalten der Neuroblastomzellen UKF-NB-2, UKF-NB-3 und UKF-NB-6 sowie ihrer Cisplatin- und Carboplatin-resistenten Sublinien untersucht. Der zytomorphologischen Phänotyp der untersuchten Zellen ließ keine eindeutigen Schlüsse auf eine neuronale, indifferente oder nicht-neuronale Differenzierung der Zellen zu. Gemessen an der Expression der neuronalen Marker NCAM, TH und der Neurofilamente L, M und H zeigte jedoch die Mehrzahl der untersuchten Cisplatin- und Carboplatin-resistenten Sublinien einen signifikanten Verlust der neuronalen Differenzierung im Vergleich zu ihren parentalen Zellen. Dieser Effekt war auch durch eine temporäre Platinkarenz nicht vollständig reversibel.
Der EGF-Rezeptor, dessen Überexpression als negativer prognostischer Marker für den Therapieerfolg gilt, wurde von allen untersuchten Zelllinien exprimiert, es ließ sich jedoch keine signifikant verstärkte Expression in den resistenten Sublinien nachweisen.
Eine Krebsstammzelle ließ sich in den untersuchten Zelllinien bei schwacher bis fehlender Stammzellmarkerexpression von CD133 und c-Kit nicht eindeutig identifizieren.
Die Resistenz gegenüber Anoikis ist eine Grundvoraussetzung für die Metastasierung von Tumorzellen. Bei den in dieser Arbeit untersuchten Neuroblastomzelllinien zeigten 3 von 8 Zelllinien, UKF-NB-2, UKF-NB-2rCDDP500 und UKF-NB-6, eine Anoikis-Resistenz. UKF-NB-3 sowie ihre beiden Sublinien waren Anoikis-sensibel, sie zeigten alle einen signifikanten Viabilitätsverlust durch Kultivierung auf Poly-HEMA-Beschichtung und daraus resultierendem Adhärenzverlust. Bei UKF-NB-6 nahm durch den Erwerb der Platinresistenz die Toleranz gegenüber Anoikis ab, wie man an dem signifikanten Viabilitätsverlust der Sublinien UKF-NB-6rCDDP1000 und UKF-NB6rCarbo1000 unter nicht-adhärenten Bedingungen sieht. Die Ausbildung der Cisplatin- und insbesondere der Carboplatinresistenz geht hier mit einer signifikant verstärkten Sensitivität der Zellen gegenüber Anoikis einher. Ein synergistischer Effekt auf die Zellviabilität durch Anoikis-induzierende PolyHEMA-Beschichtung und simultane Cisplatin- oder Carboplatin-Exposition ließ sich jedoch nicht beobachten.
Im zweiten Teil dieser Arbeit wurden die durch die Connectivity Map ermittelten potentiellen Resensitizer für Cisplatin (Pararosanilin, Tolbutamid, Fludrocortison, 12,13-EODE und Topiramat) und deren Wirkung auf die Viabilität der Neuroblastomzelllinien (IMR-5, NGP, SK-N-AS, UKF-NB-2, UKF-NB-3 und UKF-NB-6) sowie ihrer Cisplatin-resistenten Sublinien untersucht.
Hierbei zeigte die Kombinationstherapie von Cisplatin mit 12,13-EODE, Topiramat oder Fludrocortison keine signifikante Reduktion der Zellviabilität im Vergleich zur Therapie mit Cisplatin alleine. Ein z. T. signifikanter Anstieg des IC50-Werts von Cisplatin in den getesteten parentalen Zellen und resistenten Sublinien ließ eher einen desensibilisierenden Effekt dieser Stoffe gegenüber Cisplatin vermuten.
Die Kombination von Cisplatin mit Pararosanilin oder Tolbutamid hingegen hatte einen deutlich wachstumshemmenden Effekt auf alle untersuchten resistenten Sublinien. Die IC50-Werte von Cisplatin wurden hier in fast allen Zelllinien signifikant reduziert, z. T. bis um den Faktor 2,45, was einer Halbierung der Cisplatindosis entspricht. Pararosanilin und Tolbutamid erwiesen sich somit als mögliche Resensitizer für Cisplatin in Cisplatin-resistenten Neuroblastomzellen.
Diese Daten lassen erkennen, dass die Connectivity Map ein vielversprechendes Werkzeug in der gezielten Therapie von chemoresistenten Neuroblastomen sein kann. In Kombination mit bisher gängigen Therapieschemata könnten Resensitizer den Erfolg der Behandlung möglicherweise deutlich verbessern. Die mögliche Toxizität der identifizierten Resensitizer, insbesondere Pararosanilin, und damit den tatsächlichen Stellenwert dieses Therapieansatzes wird man jedoch zunächst in vivo noch weiter untersuchen müssen.
Rhabdomyosarcoma (RMS) is the most frequent pediatric soft-tissue sarcoma comprising two major subtypes – the alveolar and the embryonal rhabdomyosarcoma. The current therapeutic regime is multimodal including surgery, radiation and chemotherapy with cytostatic drugs. Although the prognosis for RMS patients has steadily improved to a 5-year overall survival rate of 70% for ERMS and 50% for ARMS, prognosis for subgroups with primary metastases or relapsed patients is still less than 25%, highlighting the need for development of new therapies for these subgroups. Since cancer cells are addicted to their cancer promoting transcriptional program, remodeling transcription by targeting bromodomain and extraterminal (BET) proteins has emerged as compelling anticancer strategy. However, in many cancer types BET inhibition was proved cytostatic but not cytotoxic emphasizing the need for combination protocols.
In this study we identify a novel synergistic interaction of the BET inhibitor JQ1 with p110α-isoform-specific Phosphoinositid-3-Kinase (PI3K) inhibitor BYL719 (Alpelisib) to induce mitochondrial apoptosis and global reallocation of BRD4 to chromatin. At first, we showed that JQ1 single treatment had cytostatic effects at nanomolar concentrations and inhibited MYC and Hedgehog (Hh) signaling in RMS known to promote proliferation of RMS. However, JQ1 single treatment barely induced cell death in RMS cells even at concentrations of up to 20 µM (< 20% cell death). Thus, we next tested combination approaches to elicit cell death. Since we previously identified synergistic cell death induction of Hh inhibition and PI3K inhibition in RMS cells we tested JQ1 in combination with the pan-PI3K/mTOR inhibitor PI-103 and the p110α-isoform-specific PI3K inhibitor BYL719. In addition, we tested JQ1 in combination with distinct HDAC inhibitors namely JNJ-26481585, SAHA (Vorinostat), MS-275 (Entinostat) and LBH-589 (Panobinostat) since the synergistic interaction of BET and HDAC inhibition has previously been described for other tumor entities.
Interestingly the synergism of cell death induction of JQ1/BYL719 co-treatment is superior to the synergism of JQ1 with pan-PI3K/mTOR inhibitor PI-103 or the tested HDAC inhibitors as confirmed by calculation of combination index. To investigate the molecular mechanisms underlying the synergy of JQ1/BYL719 co-treatment, we performed RNA-Seq and BRD4 ChIP-Seq experiments. RNA-Seq exhibited, that JQ1/BYL719 co-treatment shifted the overall balance of BCL-2 family gene expression towards apoptosis and increased gene expression of proapoptotic BMF, BCL2L11 (BIM) and PMAIP1 (NOXA) while decreasing gene expression of antiapoptotic BCL2L1 (BCL xL). These changes were verified by qRT-PCR and Western blot. Notably, BRD4 is phosphorylated upon JQ1/BYL719 co-treatment and globally reallocates BRD4 to chromatin. This BRD4 reallocation includes enrichment of BRD4 at the super-enhancer site of BMF, at the super-enhancer, typical enhancer and promoter regions of BCL2L11 (BIM) and at the PMAIP1 (NOXA) promoter, while JQ1 alone, as expected, reduces global chromatin binding of BRD4. Integration of RNA-Seq and BRD4 ChIP-Seq data underlines the transcriptional relevance of reallocated BRD4 upon JQ1/BYL719 co-treatment. Immunopreciptation studies showed, that RMS cells are initially primed to undergo mitochondrial apoptosis since BIM is constitutively bound to antiapoptotic BCL-2, BCL xL and MCL-1. JQ1/BYL719 co-treatment increased BIM expression and its neutralization of antiapoptotic BCL-2, BCL-xL and MCL-1 thereby rebalancing the ratio of pro- and antiapoptotic BCL-2 proteins in favor of apoptosis. This promotes activation of BAK and BAX resulting in caspase-dependent apoptosis. The functional relevance of proapoptotic re-balancing for the execution of JQ1/BYL719-mediated apoptosis was confirmed by individual silencing of BMF, BIM, NOXA or overexpression of BCL-2 or MCL-1, which all significantly rescued JQ1/BYL719-induced cell death. Execution of cell death by mitochondrial caspase-dependent apoptosis was veryfied by individual knockdown of BAK and BAX or caspase inhibitor N-Benzyloxycarbonyl-Val-Ala-Asp(O-Me) fluoromethylketone (zVAD.fmk), which all significantly rescued JQ1/BYL719-induced cell death.
In summary, combined BET and PI3Kα inhibition cooperatively induces mitochondrial apoptosis by proapoptotic re-balancing of BCL-2 family proteins accompanied by reallocation of BRD4 to transcriptional regulatory elements of BH3-only proteins.
HCMV ist ein Pathogen mit einer weltweit sehr hohen Prävalenz und stellt nach wie vor ein großes Problem für Immunsupprimierte (Transplantations- und AIDS-Patienten) und für ungeborene Kinder dar. Seine Pathogenese ist weiterhin nur unzureichend bekannt, eine Impfprophylaxe existiert nicht und es stehen nur wenige, unzureichende Medikamente zur Therapie zur Verfügung. Auch ein verstärkender Einfluss des Virus auf die Tumormalignität ist gezeigt. Aber die der viralen Onkomodulation zugrundeliegenden Mechanismen, insbesondere die Frage, wie und wann Tumorwachstum und -invasion durch HCMV beschleunigt werden, bedürfen weiterer Aufklärung.
Die immediate early-Proteine IE1 und IE2 sind wichtige Regulatorproteine einer HCMV-Infektion – insbesondere IE1, welches einen entscheidenden Einfluss auf die Genexpression der Wirtszelle nimmt. Es wurde a-priori die Hypothese erstellt, dass über einen positiven Einfluss von IE1 auf die Enterokinaseexpression die Trypsin-vermittelte Tumorinvasion gefördert wird.
Im ersten Teil dieser Arbeit wurde ein effizientes, zuverlässiges Protokoll zur Herstellung IE1- und IE2-exprimierender Tumorzelllinien mit Hilfe von lentiviralem Gentransfer ausgearbeitet. Damit verbunden konnten zwei persistent-transduzierte humane Tumorzelllinien, U-251 MGIE1 und U-251 MGIE2, mit hohen Expressionsraten etabliert werden. Weiter konnte im zweiten Teil der Arbeit, sowohl im Akutmodell als auch an persistent-transduzierten Zellen, gezeigt werden, dass die Enterokinaseexpression nicht im Zusammenhang mit der IE1-Expression steht.
Durch die Erarbeitung des Transduktions-Protokolls und die Etablierung der persistent-transduzierten humanen Tumorzelllinien ist es nun möglich, die isolierten Auswirkungen von IE1 und IE2 auf humane Tumorzellen zu untersuchen. Die Widerlegung der Hypothese über die Beeinflussung der Enterokinaseexpression durch IE1 liefert eine Erkenntnis, um die Mechanismen der erhöhten Tumorinvasion besser verstehen zu können. Insgesamt konnte durch diese Arbeit ein Beitrag geliefert werden, die durch HCMV verursachten onkomodulatorischen Effekte noch besser nachvollziehen zu können. Dies wiederum kann künftig dazu dienen therapeutische Strategien, welche der Invasion und Metastasierung entgegen wirken, zu verbessern bzw. zu entwickeln.
BH3 mimetics are novel anticancer therapeutics that induce apoptosis by targeting anti‐apoptotic BCL‐2 proteins. Highly specific inhibitors of the main anti-apoptotic proteins BCL-2, BCL‐XL and MCL‐1 promise new opportunities for the treatment of AML. However, it is currently unclear which of these anti-apoptotic BCL-2 proteins represents the most promising target in AML. Therefore, we investigated the effect of BH3 mimetics targeting either BCL-2 (ABT-199, S55746), BCL-XL (A-1331852) or MCL-1 (S63845) on eleven AML cell lines. Drug sensitivity screening revealed heterogeneous sensitivity towards the different BH3 mimetics, with the best responses observed upon targeting of MCL-1. Selected cell lines that displayed sensitivity towards the specific BH3 mimetics underwent intrinsic apoptosis, which was characterized by loss of mitochondrial membrane potential, exposure of phosphatidylserine and activation of caspases. Furthermore, S63845 turned out to displace BIMS and NOXA from MCL-1 to induce apoptotic cell death. Importantly, the translational relevance of this study was demonstrated by experiments in primary AML blasts, which displayed similar sensitivity towards BH3 mimetics as the cell lines did. Additionally, experiments with nonmalignant cells could confirm the clinical relevance of the MCL-1 inhibitor. There we could show, that S63845 does not cause cytotoxicity on HPCs at efficacious doses.
In conclusion, our findings reveal that the inhibition of BCL-2 proteins, especially MCL-1, by BH3 mimetics can be a promising strategy in AML treatment.
Glioblastoma multiforme accounts for more than 80% of all malignant gliomas in adults and a minor fraction of new annual cases occurs in children. In the last decades, research shed light onto the molecular patterns underlying human malignancies which resulted in a better understanding of the disease and finally an improved long term survival for cancer patients. However, malignancies of the central nervous system and especially glioblastomas are still related to poor outcomes with median survivals of less than 6 months despite extensive surgery, chemotherapy and radiation. Hence, a better understanding of the molecular mechanism driving and sustaining cancerous mutations in glioblastomas is crucial for the development of targeted therapies. Apoptosis, a form of programmed cell death, is an important feature of eukaryotic cells and crucial for the maintenance of multicellular homeostasis. Because apoptosis is a highly complex and tightly regulated signaling pathway, resisting apoptotic stimuli and avoiding cell death is a hallmark of the cancerous transformation of cells. Hence, targeting molecular structures to reestablish apoptotic signaling in tumor cells is a promising approach for the treatment of malignancies. Smac mimetics are a group of small molecular protein inhibitors that structurally derive from an intracellular protein termed Smac and selectively block Inhibitor of apoptosis (IAP) proteins, which are often aberrantly expressed in cancer. Several studies confirmed the antitumoral effects of Smac mimetics in different human malignancies, including glioblastoma, and give rationales for the development of potent Smac mimetics and Smac mimetic-based combination protocols. This study investigates the antitumoral activity of the bivalent Smac mimetic BV6 in combination with Interferon α. Latter is a well characterized cytokine with an essential role in immunity, cell differentiation and apoptosis. This study further aims to address the molecular mechanisms underlying the antitumoral activity of the combination treatment by using well established molecular cell death assays, flow cytometry, western blot analysis, genetic approaches and selective pharmacological inhibition. Since different Smac mimetics and Smac mimetic-based combination therapies are currently under clinical evaluations, findings of this study may have broad implications for the application of Smac mimetics as clinical cancer therapeutics.
Rhabdomyosarcoma is the most common paediatric soft-tissue sarcoma, and for tumour recurrence, the prognosis is still unfavourable. The current standard therapy consisting of surgery, radiation and combined chemotherapy does not consider the specific biology of this tumour.
Histone deacetylases (HDACs) and the Lysine-specific demethylase-1 (LSD1) are two epigenetic modifiers which are both part of repressor complexes leading to transcriptional silencing of target genes. Whereas HDACs lead to deacetylation of several lysine-residues within the histone tail, LSD1 is specific for demethylation of H3K4me2 and H3K4me1, as well as in a different context for H3K9me2. Rhabdomyosarcoma is reported to harbour high levels of LSD1, but the functional relevance is yet unclear. HDAC inhibition proved to be effective as single agent treatment, however, the proximity of HDAC1/2 and LSD1 in repressor complexes at the DNA implies a suitable rationale for a combination therapy potentially leading to cooperative effects on target gene transcription. In this study, we aimed to evaluate the potential of a combined LSD1 and HDAC inhibition for cell death induction in rhabdomyosarcoma cell lines. Whereas LSD1 inhibitors failed to induce cell death on their own, the combined inhibition of HDACs and LSD1 resulted in highly synergistic cell death induction. This effect extended to several combinations of LSD1 and HDAC inhibitors as well as to four different rhabdomyosarcoma cell lines, two of embryonal and two of alveolar histology.
With the use of the HDAC inhibitor JNJ-26481585 and the reversible LSD1 inhibitor GSK690, we demonstrated that the cell death induced by the combination matches with the details of intrinsic mitochondrial apoptosis. JNJ-26481585/GSK690-induced cell death is partially caspase-dependent and leads to caspase cleavage, followed by substrate cleavage as shown for PARP, as well as loss of the mitochondrial membrane potential.
Furthermore, JNJ-26481585 and GSK690 acted together to transcriptionally upregulate the proapoptotic proteins NOXA, BIM and BMF, which resulted in respective changes on protein level for both cell lines. However, the antiapoptotic BCL-2 family proteins BCL-2, MCL-1 and BCL-xL displayed only minor changes in protein levels upon treatment with GSK690 and JNJ-26481585, which did not rely on transcriptional activity. Therefore, the increase in proapoptotic proteins induces a shift towards proapoptotic signalling at the mitochondrial membrane. This shift is functionally relevant since knockdown of a proapoptotic protein or overexpression of one of the antiapoptotic proteins BCL-2 and MCL-1, as well as a stabilized mutant MCL-1, can significantly protect from GSK690/JNJ-26481585-induced cell death.
Knockdown of the mitochondrial membrane protein BAK, which is directly guarding the mitochondrial membrane integrity, potently protected from GSK690/JNJ-26481585- induced cell death, directly linking the shift in the BCL-2 family proteins to the observed loss of mitochondrial membrane potential and the further downstream activation of caspases. Furthermore, treatment with JNJ-26481585 and GSK690 resulted in a cell cycle arrest in G2/M phase, indicating additional effects on the tumour cells beside apoptosis induction. Taken together, the combined inhibition of LSD1 and HDACs is a promising strategy for rhabdomyosarcoma treatment.
Onkogene RAS-Mutationen zählen mit einem Vorkommen von ca. 25% zu häufigen Genmutationen in malignen Tumoren. Auch im Rhabdomyosarkom (RMS), dem häufigsten Weichteilsarkom im Kindesalter, findet sich eine hohe Rate an wiederkehrenden RAS-Signalwegmutationen. Dabei scheint ein Zusammenhang zwischen der RMS-Risikostratifizierung und dem Vorkommen von RAS-Mutationen zu bestehen. Da Hochrisiko-RMS im Vergleich zu anderen Tumorentitäten im Kindesalter immer noch mit einer unterdurchschnittlichen Prognose einhergehen, stellen RAS-Mutationen einen interessanten Angriffspunkt für eine zielgerichtete Tumortherapie dar. Hierzu soll diese Arbeit durch eine genauere Charakterisierung der Auswirkungen onkogener RAS-Gene auf das RMS beitragen. Verwendet wurden genetisch modifizierte RMS13 Zellen mit ektoper Expression der onkogenen RAS-Mutationen HRAS12V, KRAS12V oder NRAS12V. Eine bereits gut beschriebene Eigenschaft von RAS ist die Förderung der Zellproliferation. Daneben wurde auch beschrieben, dass RAS Einfluss auf den programmierten Zelltod nehmen und in Abhängigkeit vom zellulären Kontext pro- oder auch antiapoptotisch wirken kann. Daher stellte sich die Frage, welche Auswirkungen onkogene RAS-Mutationen in diesem Kontext auf Rhabdomy-osarkomzellen haben. In dieser Arbeit wird gezeigt, dass die ektope Expression von HRAS12V, KRAS12V oder NRAS12V in RMS13 Zellen zu einer gesteigerten Zellproliferation führt, im Hinblick auf die spontane Zelltodrate jedoch keine Veränderungen bewirkt. Damit stellt die erhöhte Proliferationsrate RAS-mutierter Rhabdomyosarkome einen wichtigen Unterschied zu entsprechenden Tumoren ohne solche Mutationen dar. Chemotherapeutika wie Etoposid und Doxorubicin, die besonders effektiv gegen hochproliferierende Zellen sind, zeigen jedoch keinen signifikanten Unterschied in ihrer Wirksamkeit gegen RMS13 Zellen in Anwesenheit von onkogenem RAS. Damit scheint ein selektives Eingreifen in die proliferationsfördernden Mechanismen nötig zu sein, um RAS-mutierte Zellen gezielt in ihrem Wachstum zu hemmen. Dies verdeutlicht die Notwendigkeit, spezifischer, gezielter Tumortherapien. Neben dem Einfluss auf das Zellwachstum wurden auch Veränderungen in der Redoxhomöostase untersucht. Bisherige indirekte Hinweise auf einen erhöhten oxidativen Stress im RMS in Anwesenheit von RAS-Mutationen können in dieser Arbeit durch den direkten Nachweis erhöhter ROS-Level in RAS-mutierten RMS13 Zellen bestätigt werden. Die akzelerierte ROS-Konzentration lässt vermuten, dass das Überleben von RMS-Zellen mit konstitutiver RAS-Aktivierung in besonderem Maße von antioxidativen Zellstrukturen abhängig sein könnte. Dies könnte sie sensibler gegenüber exogenen Stimuli machen, die zu einer weiteren Erhöhung des oxidativen Stresses führen. Als hervorzuhebendes Ergebnis zeigt diese Arbeit jedoch, dass die ektope Expression von HRAS12V, KRAS12V oder NRAS12V in RMS13 Zellen vor einem oxidativen Zelltod schützt. In Anwesenheit der RAS-Mutationen zeigen RMS13 Zellen einen signifikant geringeren Zellviabilitätsverlust gegenüber einem Eingriff in verschiedene Komponenten des antioxidativen Systems wie durch RSL3 (Glutathion-Peroxidase 4 Inhibitor), Erastin (indirekter Inhibitor der Glutathion-Synthese) oder Auranofin (Thioredoxin-Reduktase-Inhibitor). Dies steht im Gegensatz zu den Erstbeschreibungen, in denen für RSL3 und Erastin eine RAS-selektive Wirkung gezeigt wurde. Als Besonderheit kann der durch RSL3 oder Erastin hervorgerufene Zelltod der RMS13 Zellen als Ferroptose identifiziert werden. Hierbei handelt es sich um eine vor kurzem neu beschriebene Form von programmiertem, oxidativem und eisenabhängigem Zelltod. Diese Arbeit verdeutlicht somit, dass onkogene RAS-Mutationen im RMS gezielt in die Redoxregulation eingreifen, jedoch nur in bestimmten zellulären Kontexten für oxidative Stressoren zu sensibilisieren scheinen. Daneben weist diese Arbeit auch einen protektiven Effekt von onkogenem RAS gegenüber dem dualen PI3K/mTOR-Inhibitor PI-103 in RMS13 Zellen nach. Zusammengenommen deutet dies darauf hin, dass RAS selektiv Einfluss auf durch zytotoxische Stimuli hervorgerufenen Zelltod nimmt. Die Ergebnisse dieser Arbeit, insbesondere der Nachweis einer erhöhten Resistenz gegenüber oxidativen Stressoren in Anwesenheit onkogener RAS-Gene, leisten einen wichtigen Beitrag zur Entwicklung neuer zielgerichteter und selektiver RMS-Therapiestrategien.
Cancer cells, in general and especially Rhabdomyosarcoma (RMS) cells have been reported to be highly susceptible to oxidative stress. Based on this knowledge we examined whether the inhibition of the two main antioxidant defense pathways, i.e. the thioredoxin (TRX) and the glutathione (GSH) system, represents a possible new strategy to induce cell death in RMS. To do so, we combined the -glutamylcysteine synthetase (γGCL) inhibitor buthionine sulfoximine (BSO) or the cystine/glutamate antiporter (xc-) inhibitor erastin (ERA), both GSH depleting enzymes, with the thioredoxinreductase (TrxR) inhibitor auranofin (AUR) to evaluate synergistic cell death in the alveolar RMS (ARMS) cell line RH30 and the embryonal RMS (ERMS) cells RD.
Furthermore, we tried to unravel the underlying molecular mechanisms of AUR/BSO or AUR/ERA treatment in RMS cells. Thereby we showed that AUR/BSO as well as AUR/ERA treatment leads to proteasome inhibition characterized by the accumulation of ubiquitinated proteins, which is in agreement with the already published ability of AUR to inhibit proteasomeassociated deubiquitinases (DUBs) aside from TrxR. As a consequence, the protein levels of ubiquitinated short-lived proteins, like NOXA and MCL-1, increase upon treatment with AUR/BSO or AUR/ERA. Consistently, we could detect an increased binding of NOXA to MCL-1. Interestingly, not only NOXA protein levels but also mRNA levels rise upon treatment, pointing to a transcriptional regulation of pro-apoptotic NOXA through AUR/BSO or AUR/ERA combination treatment. The fact that siRNA mediated knockdown of NOXA rescues cells from combination treatment-induced cell death strengthens the role of NOXA as an important regulator of cell death induction. Apart from proteasome inhibition and subsequent NOXA accumulation, AUR cooperates with BSO or ERA to trigger BAX/BAK activation, which is needed for cell death induction, too. Additionally, loss of mitochondrial membrane potential (MMP) as well as caspase activation and PARP cleavage is detected after treatment of RMS cells with AUR/BSO or AUR/ERA.
Except of apoptotic cell death we also detected features of iron-dependent ferroptosis after treatment with AUR/BSO or AUR/ERA. This is not surprising, since BSO and ERA already have been described to induce ferroptotic cell death. Although lipid peroxidation takes place in both cell lines, only in RH30 cells, cell death seems to be partially ferroptosis-dependent, since especially in this cell line AUR/BSO- or AUR/ERA-induced cell death can be rescued with different ferroptosis inhibitors.
Although both combination treatments, AUR/BSO as well as AUR/ERA, induce production of reactive oxygen species (ROS), only the thiol-containing ROS scavengers GSH and its precursor N-acetylcysteine (NAC), but not the non-thiolcontaining antioxidant α-Tocopherol (α-Toc), consistently prevent proteasome inhibition, NOXA accumulation and cell death.
Additionally, we demonstrated that BSO and ERA abolish AUR-mediated upregulation of GSH thereby releasing the AUR cytotoxic effect on RMS cells, in line with the described ability of cysteines to inhibit the function of AUR. Together, this points to the conclusion that GSH depletion, rather than an increase in ROS levels, is important for AUR/BSO- or AUR/ERA-induced cell death.
In conclusion, through revealing that the antitumor activity of AUR is enhanced in combination with GSH depleting agents, we identified redox homeostasis as a new and promising target for the treatment of RMS cells.