@phdthesis{Jessen2021, author = {Jessen, Christina}, title = {NRF2 links antioxidant and immune-relevant features in melanoma}, doi = {10.25972/OPUS-23349}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-233495}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2021}, abstract = {The transcription factor NRF2 is considered as the master regulator of cytoprotective and ROS-detoxifying gene expression. Due to their vulnerability to accumulating reactive oxygen species, melanomas are dependent on an efficient oxidative stress response, but to what extent melanomas rely on NRF2 is only scarcely investigated so far. In tumor entities harboring activating mutations of NRF2, such as lung adenocarcinoma, NRF2 activation is closely connected to therapy resistance. In melanoma, activating mutations are rare and triggers and effectors of NRF2 are less well characterized. This work revealed that NRF2 is activated by oncogenic signaling, cytokines and pro-oxidant triggers, released cell-autonomously or by the tumor microenvironment. Moreover, silencing of NRF2 significantly reduced melanoma cell proliferation and repressed well-known NRF2 target genes, indicating basal transcriptional activity of NRF2 in melanoma. Transcriptomic analysis showed a large set of deregulated gene sets, besides the well-known antioxidant effectors. NRF2 suppressed the activity of MITF, a marker for the melanocyte lineage, and induced expression of epidermal growth factor receptor (EGFR), thereby stabilizing the dedifferentiated melanoma phenotype and limiting pigmentation markers and melanoma-associated antigens. In general, the dedifferentiated melanoma phenotype is associated with a reduced tumor immunogenicity. Furthermore, stress-inducible cyclooxygenase 2 (COX2) expression, a crucial immune-modulating gene, was regulated by NRF2 in an ATF4-dependent manner. Only in presence of both transcription factors was COX2 robustly induced by H2O2 or TNFα. COX2 catalyzes the first step of the prostaglandin E2 (PGE2) synthesis, which was described to be associated with tumor immune evasion and reduction of the innate immune response. In accordance with these potentially immune-suppressive features, immunocompetent mice injected with NRF2 knockout melanoma cells had a strikingly longer tumor-free survival compared to NRF2-proficient cells. In line with the in vitro data, NRF2-deficient tumors showed suppression of COX2 and induction of MITF. Furthermore, transcriptomic analyses of available tumors revealed a strong induction of genes belonging to the innate immune response, such as RSAD2 and IFIH1. The expression of these genes strongly correlated with immune evasion parameters in human melanoma datasets and NRF2 activation or PGE2 supplementation limited the innate immune response in vitro. In summary, the stress dependent NRF2 activation stabilizes the dedifferentiated melanoma phenotype and facilitates the synthesis of PGE2. As a result, NRF2 reduces gene expression of the innate immune response and promotes the generation of an immune-cold tumor microenvironment. Therefore, NRF2 not only elevated the ROS resilience, but also strongly contributed to tumor growth, maintenance, and immune control in cutaneous melanoma.}, subject = {Melanom}, language = {en} } @phdthesis{Wong2001, author = {Wong, Amanda}, title = {Implications of Advanced Glycation Endproducts in Oxidative Stress and Neurodegenerative Disorders}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-2537}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2001}, abstract = {The reactions of reducing sugars with primary amino groups are the most common nonenzymatic modifications of proteins. Subsequent rearrangements, oxidations, and dehydrations yield a heterogeneous group of mostly colored and fluorescent compounds, termed "Maillard products" or advanced glycation end products (AGEs). AGE formation has been observed on long-lived proteins such as collagen, eye lens crystalline, and in pathological protein deposits in Alzheimer's (AD) and Parkinson's disease (PD) and dialysis-related amyloidosis. AGE-modified proteins are also involved in the complications of diabetes. AGEs accumulate in the the ß-amyloid plaques and neurofibrillary tangles (NFT) associated with AD and in the Lewy bodies characteristic of PD. Increasing evidence supports a role for oxidative stress in neurodegenerative disorders such as AD and PD. AGEs have been shown to contribute towards oxidative damage and chronic inflammation, whereby activated microglia secrete cytokines and free radicals, including nitric oxide (NO). Roles proposed for NO in the pathophysiology of the central nervous system are increasingly diverse and range from intercellular signaling, through necrosis of cells and invading pathogens, to the involvement of NO in apoptosis. Using in vitro experiments, it was shown that AGE-modified bovine serum albumin (BSA-AGE) and AGE-modified ß-amyloid, but not their unmodified proteins, induce NO production in N-11 murine microglia cells. This was mediated by the receptor for AGEs (RAGE) and upregulation of the inducible nitric oxide synthase (iNOS). AGE-induced enzyme activation and NO production could be blocked by intracellular-acting antioxidants: Ginkgo biloba special extract EGb 761, the estrogen derivative, 17ß-estradiol, R-(+)-thioctic acid, and a nitrone-based free radical trap, N-tert.-butyl-*-phenylnitrone (PBN). Methylglyoxal (MG) and 3-deoxyglucosone (3-DG), common precursors in the Maillard reaction, were also tested for their ability to induce the production of NO in N-11 microglia. However, no significant changes in nitrite levels were detected in the cell culture medium. The significance of these findings was supported by in vivo immunostaining of AD brains. Single and double immunostaining of cryostat sections of normal aged and AD brains was performed with polyclonal antibodies to AGEs and iNOS and monoclonal antibodies to Aß and PHF-1 (marker for NFT) and reactive microglia. In aged normal individuals as well as early stage AD brains (i.e. no pathological findings in isocortical areas), a few astrocytes showed co-localisation of AGE and iNOS in the upper neuronal layers of the temporal (Area 22) and entorhinal (Area 28, 34) cortices compared with no astrocytes detected in young controls. In late AD brains, there was a much denser accumulation of astrocytes co-localised with AGE and iNOS in the deeper and particularly upper neuronal layers. Also, numerous neurons with diffuse AGE but not iNOS reactivity and some AGE and iNOS-positive microglia were demonstrated, compared with only a few AGE-reactive neurons and no microglia in controls. Finally, astrocytes co-localised with AGE and iNOS as well as AGE and ß-amyloid were found surrounding mature but not diffuse ß-amyloid plaques in the AD brain. Parts of NFT were AGE-immunoreactive. Immunohistochemical staining of cryostat sections of normal aged and PD brains was performed with polyclonal antibodies to AGEs. The sections were counterstained with monoclonal antibodies to neurofilament components and a-synuclein. AGEs and a-synuclein were colocalized in very early Lewy bodies in the substantia nigra of cases with incidental Lewy body disease. These results support an AGE-induced oxidative damage due to the action of free radicals, such as NO, occurring in the AD and PD brains. Furthermore, the involvement of astrocytes and microglia in this pathological process was confirmed immunohistochemically in the AD brain. It is suggested that oxidative stress and AGEs participate in the very early steps of Lewy body formation and resulting cell death in PD. Since the iNOS gene can be regulated by redox-sensitive transcription factors, the use of membrane permeable antioxidants could be a promising strategy for the treatment and prevention of chronic inflammation in neurodegenerative disorders.}, subject = {Maillard-Reaktion}, language = {en} } @phdthesis{Loske2000, author = {Loske, Claudia}, title = {Metabolische Ver{\"a}nderungen und Zelltod in neuralen Zellen durch "Advanced Glycation Endproducts"}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-1707}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2000}, abstract = {Advanced Glycation Endproducts (AGEs) entstehen aus nicht-enzymatisch glykierten Proteinen. In einer Folge von Dehydratations-, Kondensations- und Oxidationsschritten entsteht ein heterogenes Gemisch aus farbigen, fluoreszierenden Verbindungen. AGE-modifizierte Proteine sind unl{\"o}slich und proteaseresistent, bei ihrer Bildung entstehen freie Radikale und andere reaktive Intermediate. Von der AGE-Bildung betroffen sind vor allem langlebige Proteine mit geringem Umsatz wie Kollagen und Kristallin aber auch pathologische Proteinablagerungen, z.B. in der Alzheimer´schen Demenz (AD). Die Akkumulation von AGEs spielt in der Pathogenese von Komplikationen des Diabetes und der H{\"a}modialyse eine Rolle, f{\"u}r die AD wird eine Beteiligung von AGEs am Krankheitsverlauf diskutiert. Die Alzheimer´sche Demenz ist gekennzeichnet durch den histologischen Nachweis seniler Plaques und neurofibrill{\"a}rer B{\"u}ndel in Hirngewebe der Patienten. Auf Ebene des Stoffwechsels kommt es zu einer Verringerung des zerebralen Glukoseumsatzes, es finden sich Marker sowohl f{\"u}r eine Akutphasenreaktion als auch f{\"u}r oxidativen Stress. In dieser Arbeit wurde gezeigt, dass die AGE-Bildung in vitro die Aggregation von ßA4, dem Hauptbestandteil der senilen Plaques in der AD, beschleunigt. Der geschwindigkeits-bestimmende Schritt ist dabei die Glykierung des ßA4-Monomers. Durch Zugabe von {\"U}bergangsmetall-ionen kann die Vernetzung weiter beschleunigt werden. Dies deutet darauf hin, dass AGEs zur Plaquebildung in der AD beitragen, redox-aktive Eisenionen sind in der AD mit den Plaques assoziiert. Mit Hilfe von Metallchelatoren, Antioxidantien oder mit Substanzen, welche die zur Vernetzung notwendigen Aminogruppen abblocken, l{\"a}sst sich die Aggregation von ßA4 verlangsamen oder verhindern. AGEs wirken zytotoxisch auf BHK 21 Fibroblasten und humane SH-SY5Y Neuroblastoma Zellen. Die Toxizit{\"a}t unterschiedlicher Modell-AGEs ist abh{\"a}ngig von verschiedenen Faktoren, u.a. von dem zur Herstellung verwendeten Protein und vom Zucker. Die LD50 der Modell-AGEs korreliert mit dem AGE-Gehalt und der Radikalproduktion der Pr{\"a}parationen in vitro. Die AGE-Toxizit{\"a}t ist haupts{\"a}chlich radikalvermittelt. Oxidativer Stress l{\"a}sst sich in AGE-behandelten Zellen durch die Bildung intrazellul{\"a}rer Lipidperoxidationsprodukte nachweisen. Auf Ebene der Signaltransduktion konnte die Aktivierung des Transkriptions-faktors NfkB als Zeichen der Stressabwehr nachgewiesen werden. Die Gabe von Antioxidantien vor oder gleichzeitig mit den AGEs verringerte den Zelltod. Auch durch das Blockieren des Rezeptors f{\"u}r AGEs (RAGE) mit spezifischen Antik{\"o}rpern konnte die Zahl {\"u}berlebender Zellen gesteigert werden. Durch AGEs ausgel{\"o}ster Stress f{\"u}hrt in Neuroblastoma Zellen bereits in Konzentrationen unterhalb der LD50 zu St{\"o}rungen im Redoxstatus, es kommt zur Depletion von GSH und zu Verschiebungen im Verh{\"a}ltnis GSH/GSSG. Damit einher gehen Ver{\"a}nderungen im Energiestoffwechsel der Zelle, nach anf{\"a}nglich erh{\"o}hter Glukoseaufnahme kommt es im weiteren Verlauf der Inkubation zu einer Verringerung der Aufnahme von Glukose aus dem Medium, gefolgt von einer Zunahme der Laktataussch{\"u}ttung. Ausserdem wurde eine Depletion von ATP um bis zu 50 Prozent nachgewiesen. Antioxidantien k{\"o}nnen die St{\"o}rungen im Metabolismus der Zellen verhindern oder abschw{\"a}chen, die meisten der getesteten Substanzen konnten Redoxstatus und ATP-Gehalt der Zellen zu normalisieren. Obwohl sich in AGE-gestressten Zellkulturen durch Annexin-Fluorescein-Markierung ein geringf{\"u}gig erh{\"o}hter Prozentsatz apoptotischer Zellen nachweisen ließ und AGEs auch die Freisetzung von Cytochrom c ins Zytoplasma induzieren, verl{\"a}uft der durch AGEs ausgel{\"o}ste Zelltod verl{\"a}uft offenbar insgesamt nekrotisch. Sowohl durch Radikalproduktion als auch {\"u}ber rezeptorvermittelte Signalwege verursachen AGEs oxidativen Stress und induzieren Ver{\"a}nderungen im Metabolismus der Zelle. Dies f{\"u}hrt u. a. dazu, dass f{\"u}r die antioxidativen Schutzmechanismen der Zelle nicht mehr gen{\"u}gend Energie zur Verf{\"u}gung steht. AGE-Stress tr{\"a}gt damit in einer selbstverst{\"a}rkenden Reaktionskaskade zur Neurodegeneration bei und kann so an der Pathogenese der AD beteiligt sein. Antioxidantien und auch AGE-Inhibitoren k{\"o}nnten einen interessanten Ansatz zur Entwicklung alternativer Therapien in der AD darstellen.}, subject = {Alzheimer-Krankheit}, language = {de} }