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Developmental Regulation of Prion Expression in Cattle and Mouse Embryonic Stem CellsPeralta, Oscar A. 03 September 2008 (has links)
The host encoded cellular prion protein (PrPC) is an N-linked glycoprotein tethered to the cell membrane by a glycophosphatidylinositol (GPI) anchor. Under certain conditions, PrPC can undergo conversion into a conformationally-altered isoform (PrPSc) widely believed to be the pathogenic agent of transmissible spongiform encephalopathies (TSEs). Thus, tissues expressing PrPC are potential sites for conversion of PrPSc during TSE pathogenesis. Although much is known about the role of PrPSc in prion diseases, the normal function of PrPC is poorly understood. Lines of mice and cattle in which PrPC has been ablated by gene knockout show no major phenotypical alterations other than resistance to TSE infection. However, recent reports using Prnp-null mouse models have suggested the participation of PrPC in neural stem/progenitor cell proliferation and differentiation. The first objective in our study was to map the expression of PrPC in twenty six somatic and reproductive tissues in ruminants. Our second objective was to characterize the ontogeny of PrPC expression during bovine embryonic and early fetal development. Finally, we used a mouse embryonic stem cell (mESC) model to study the potential role of PrPC during neurogenesis. In adult tissues, intense expression of PrPC was detected in the central nervous system (CNS), thymus and testes, whereas the liver, striated muscle and female reproductive tissues showed the lowest expression. We observed that PrPC was associated with tissues undergoing cellular differentiation including spermatogenesis, lymphocyte activation and hair follicle regeneration. Analyses in bovine embryos and fetuses indicated peaks in expression of PrPC at days 4 and 18 post-fertilization, stages associated with the maternal-zygote transition and the maternal recognition of pregnancy and initiation of placental attachment, respectively. Later in development, PrPC was expressed in the CNS where it was localized in mature neurons of the neuroepithelium and emerging neural trunks. Based on these observations, we hypothesized that PrPC was involved in neurogenesis. We tested this hypothesis in a murine embryonic stem cell model (mESC). mESC were induced to form embryoid bodies (EBs) by placing them in suspension culture under differentiating conditions and allowed to differentiate in vitro for 20 days. We detected increasing levels of PrPC starting on day 12 (8.21- fold higher vs. day 0; P < 0.05) and continuing until day 20 (20.77-fold higher vs. day 0; P < 0.05). PrPC expression was negatively correlated with pluripotency marker Oct-4 (r= -0.85) confirming that mESC had indeed differentiated. To provide a more robust system for assessing the role of PrPC in neural differentiation, mESC were cultured with or without retinoic acid (RA) to encourage differentiation into neural lineages. Induction of EBs with retinoic acid (RA) resulted in an earlier up-regulation of PrPC and nestin (day 12 vs. day 16; P < 0.05). In addition, immunofluorescence studies indicated co-expression of PrPC and nestin in the same cells. The results of these experiments suggested a temporal link between PrPC expression and expression of nestin, a marker of neural progenitor cells. We next tested whether PrPC was involved in RA-enhanced neural differentiation from mESC using a PrPC knockdown model. Plasmid vectors designed to express either a PrP-targeted shRNA or scrambled, control shRNA were transfected into mESC. Stable transfectants were selected under G418 and cloned. PrP-targeted and control shRNA clones, as well as wild-type mESC, were differentiated in presence of RA and sampled as above. PrPC expression was knocked down in PrP-targeted shRNA cultures between days 12 and 20 (62.2 % average reduction vs. scrambled shRNA controls). Nestin expression was reduced at days 16 and 20 in PrPC knockdown cells (61.3% and 70.7%, respectively vs. scrambled shRNA controls). These results provide evidence that PrPC plays a role in the neural differentiation at a point up-stream from the stages at which nestin is expressed. In conclusion, the widely distributed expression of PrPC in ruminant tissues suggests an important biological role for this protein. In the present work we have provided evidence for the participation of PrPC in the differentiation of mESC along the neurogenic pathway. / Ph. D.
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Estudo da interação entre PrPC e STI1/HOP na biologia de células-tronco de glioblastoma humano in vivo. / Role of PrPC and STI1/HOP in human glioblastoma stem cells biology in vivo.Iglesia, Rebeca Piatniczka 10 April 2017 (has links)
O GBM é o tipo mais agressivo de glioma, apresentando células indiferenciadas (CTGs), responsáveis pela proliferação, invasão e recidiva tumoral. Avaliamos o papel da proteína PrPC e seu ligante HOP na proliferação e autorrenovação de CTGs. Cultivamos linhagens de GBM humano em neuroesferas e geramos populações knockdown para PrPC e HOP. Observamos co-localização de PrPC e CD133 na superfície e sua internalização conjunta estimulada por cobre, sugerindo recrutamento de CD133 mediado por PrPC. O silenciamento de PrPC reduz a expressão de marcadores de células-tronco e autorrenovação, diminui a expressão de proteínas de adesão e afeta a migração celular. O silenciamento de HOP reduz a proliferação, recuperada com o tratamento com HOP em células PrPC+. A capacidade tumorigênica e proliferativa de neuroesferas knockdown para PrPC e/ou HOP in vivo é reduzida. Finalmente, um peptídeo de HOP que bloqueia a interação com PrPC inibe a proliferação e autorrenovação em células PrPC+, indicando potencial do complexo PrPC-HOP como alvo para terapias contra o GBM. / GBM is the most aggressive type of glioma, presenting undifferentiated cells (GSCs), responsible for proliferation, invasion and tumor recurrence. We evaluated the role of the PrPC and its ligand HOP in the proliferation and self-renewal of GSCs. We cultured human GBM lineages in neurospheres and generated knockdown populations for PrPC and HOP. We observed co-localization of PrPC and CD133 on the surface and their co-stimulated copper internalization, suggesting PrPC-mediated recruitment of CD133. PrPC silencing reduces the expression of stem cell markers and self-renewal, decreases adhesion proteins expression, and affects cell migration. HOP silencing reduces proliferation, recovered with HOP treatment in PrPC+ cells. The tumorigenic and proliferative capacity of neurospheres PrPC and/or HOP knockdown in vivo is decreased. Finally, a HOP peptide which blocks PrPC-HOP interaction inhibits proliferation and self-renewal in PrPC+ cells, indicating PrPC-HOP complex potential as a target for therapies against GBM.
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Zur Funktion des zellulären Prion-Proteins: eine Verhaltensstudie / The function of the cellular Prion protein: a behavioral studyGreis, Catharina Marlies 21 November 2012 (has links)
No description available.
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Immunologisches Profil und PrPC-Expression von Patienten mit subkortikaler vaskulärer Enzephalopathie und vaskulärem kognitivem Impairment / Immunological profile and PrPC expression of patients with subcortical vascular encephalopathy and vascular cognitive impairmentOikonomou, Panteleimon 21 March 2017 (has links)
No description available.
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Analyse der Proteinexpression zur Untersuchung der physiologischen Funktion des zellulären Prionproteins (PrPc) / Analysis of the protein expression to investigate the physiological funktion of the cellular prion protein (PrPc)Weiß, Eva Annabelle 10 January 2012 (has links)
No description available.
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Importance of dimerization in aggregation and neurotoxicity of Prion and [alpha]-Synuclein in prion and Parkinson's diseasesRoostaee, Alireza January 2012 (has links)
Abstract: Neurodegenerative diseases are associated with progressive loss of structure or function of neurons which results in cell death. Recent evidence indicate that all neurodegenerative disorders, sporadic or transmissible, may have a common pathological mechanism at the molecular level. This common feature consists of protein aggregation and accumulation of harmful aggregates in neuronal cells resulting in cellular apoptosis and neurotoxicity. Neurodegenerative diseases can affect abstract thinking, skilled movements, emotional feelings, cognition, memory and other abilities. This diverse group of diseases includes Alzheimer's disease (AD), Parkinson's disease (PD), Huntington's disease (HD), prion diseases or transmissible spongiform encephalopathies (TSEs) and amyotrophic lateral sclerosis. In my project I worked on the molecular mechanism of protein aggregation, propagation and neurotoxicity in Parkinson's disease and prion disease. Prion disease and PD are associated with misfolding and aggregation of PrPc and a-Synuclein (a-Syn), respectively. Despite being two important neurodegenerative disorders, molecular mechanisms of a-Syn or PrPC aggregation and amyloidogenesis are still unclear in PD and prion disease. Furthermore, the toxic protein species in PD have not been characterized yet. In this study we characterize the mechanism of a-Syn and PrPc misfolding in a physiological-like cell free condition in the absence of a-Syn aggregates, PrPc ggregated isoform (Pre's), denaturants or acidic environment. A number of studies indicate that dimerization of PrPc or a-Syn may be a key step in the aggregation process. To test this hypothesis we verified if enforced dimerization of PrPc or a-Syn may induce a conformational change reminiscent of the conversion of PrPc or a-Syn to PrPR' or a-Syn aggregates, respectively. We used a well-described inducible dimerization strategy where a dimerizing domain called FK506-binding protein (Fv) was fused to PrPc or a-Syn in order to produce chimeric proteins Fv-PrP and a-SynF'''. A divalent ligand AP20187 was used to induce protein dimerization. Addition of AP20187 to recombinant Fv-PrP in physiological-like conditions resulted in a rapid conformational change characterized by an increase in beta-sheet (13-Sheet) structure and simultaneous aggregation of the proteins. However, non-dimerized PrP formed 13-Sheet conformation in very slower rates. In the presence of AP20187, we also report a rapid random coil into 13-sheet conformational transformation of a-SynF" within 24 h, whereas wild type a-Syn showed 24 h delay to achieve P-sheet structure after 48 h. Electron microscopy experiments demonstrated that dimerization induced amyloid fibril formation after 48 h for both Fv-PrP and a-Syr?", whereas in the absence of dimerizing ligand AP20187, PrP or a-Syn converted into amyloid fibrils after 3 days or even later. Dimerization-induced Fv-PrP aggregates were partially resistant to PK digestion which is a characteristics of the naturally occurring PrPR'. The rates of amyloidogenesis in the presence of dimerization was also characterized by Thioflavin T (ThT) fluorescence probing. Whereas the stable structure of Fv-PrP showed no ThT binding for over 60 h of incubation at 37°C, the addition of AP20187 to Fv-PrP resulted in a time-dependent increase in ThT binding. As for a-SynR, dimerization accelerated the rate of ThT binding and amyloid formation comparing to the slower amyloidogenesis rate of wild type a-Syn in the absence of dimerizer AP20187. The impact of dimerization on a-Syn aggregation was further determined by Fluorescence ANS probing, indicating a higher affinity of dimerization-induced a-SynF" aggregates for binding to ANS comparing to wild type a-Syn aggregates. These results indicate that dimerization increases the aggregation and amyloidogenesis processes for Fv-PrP and a-SynF". Both Fv-PrP and a-SynF" amyloids were successfully propagated in vitro by protein misfolding amplification (PMCA) cycle. These results ar in agreement with the theory that all protein aggregates in neurodegenerative diseases propagate with the same molecular mechanism. Neurotoxicity of recombinant Fv-PrP and a-SynF" aggregates was determined in cellulo and in vivo, respectively. Aggregates of Fv-PrP were toxic to cultured cells whilst soluble Fv-PrP and amyloid fibres were harmless to the cells. When injected to the mice brain, both a-Syni" and a-Syn pre-fibrillar aggregates internalized cells and induced neurotoxicity in the hippocampus of wild-type mice. These recombinant toxic aggregates further converted into non-toxic amyloids which were successfully amplified by PMCA method, providing the first evidence for the in vitro propagation of synthetic a-Syn aggregates. These results suggest an important role for protein dimerization in aggregation and amyloidogenesis, and therefore, in the pathology of PD and prion disease. The similarities between aggregation, amyloidogenesis and toxicity of PrPC and ct-Syn provide further evidence on the existance of a prion-like mechanism in all neurodegenerative disorders. // Résumé: Les maladies neurodégénératives sont associées à la perte progressive des propriétés structurales ou fonctionnelles des neurones, ce qui engendre la mort des cellules. De récentes études indiquent que tous les désordres neurodégénératifs, sporadiques ou transmissibles, peuvent avoir un mécanisme pathologique commun au niveau moléculaire. Ce dispositif commun se compose de l'agrégation de protéines, de la propagation des agrégats, et de l'accumulation d’agrégats toxiques dans les cellules neuronales, menant à l'apoptose et à la neurotoxicité cellulaire. Les maladies neurodégénératives peuvent affecter la pensée abstraite, les mouvements habiles, les sentiments émotifs, la connaissance, la Mémoire et d'autres capacités cognitives. Ce groupe divers de maladies inclut la maladie d'Alzheimer (AD), de Parkinson (PD), de Huntington (HD), les maladies à prions ou encéphalopathies spongiformes transmissibles (TSEs) et la sclérose latérale amyotrophique (ALS). [symboles non conformes]
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Exprese a funkce buněčného prionového proteinu na krevních buňkách / Expression and function of cellular prion protein in blood cellsGlier, Hana January 2012 (has links)
The cellular prion protein (PrPc) is essential for pathogenesis of fatal neurodegenerative prion diseases. Recently reported four cases of vCJD transmission by blood transfusion raise concerns about the safety of blood products. Proper understanding of PrPc in blood is necessary for development of currently unavailable blood screening tests for prion diseases. Flow cytometry is an attractive method for prion detection, however, the reports on the quantity of PrPc on human blood cells are contradictory. We showed that the majority of PrPc in resting platelets is present in the intracellular pool and is localized in α-granules. We demostrated that both, human platelets and red blood cells (RBC) express significant amount of PrPc and thus may play an important role in the transmission of prions by blood transfusion. Our results suggest a unique modification of PrPc on human RBC. Such modification of pathological prion protein could distort the results of blood screening tests for prions. Further we showed that the storage of blood prior to analysis and the choice of anti-prion antibody greatly affect the detection of PrPc by flow cytometry and we identified platelet satellitism as a factor contributing to the heterogeneity of PrPc detection in blood cells. Moreover, we demonstrated existence of...
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Exprese a funkce buněčného prionového proteinu na krevních buňkách / Expression and function of cellular prion protein in blood cellsGlier, Hana January 2012 (has links)
The cellular prion protein (PrPc) is essential for pathogenesis of fatal neurodegenerative prion diseases. Recently reported four cases of vCJD transmission by blood transfusion raise concerns about the safety of blood products. Proper understanding of PrPc in blood is necessary for development of currently unavailable blood screening tests for prion diseases. Flow cytometry is an attractive method for prion detection, however, the reports on the quantity of PrPc on human blood cells are contradictory. We showed that the majority of PrPc in resting platelets is present in the intracellular pool and is localized in α-granules. We demostrated that both, human platelets and red blood cells (RBC) express significant amount of PrPc and thus may play an important role in the transmission of prions by blood transfusion. Our results suggest a unique modification of PrPc on human RBC. Such modification of pathological prion protein could distort the results of blood screening tests for prions. Further we showed that the storage of blood prior to analysis and the choice of anti-prion antibody greatly affect the detection of PrPc by flow cytometry and we identified platelet satellitism as a factor contributing to the heterogeneity of PrPc detection in blood cells. Moreover, we demonstrated existence of...
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Einfluss des zellulären Prion-Proteins auf die LDH-Expression unter oxidativen Stressbedingungen / Influence of the cellular prion protein to the LDH expression under oxidative stress conditionsSchenkel, Sara 23 November 2015 (has links)
Die genaue physiologische Funktion des zellulären Prion-Proteins (PrPC) ist noch immer nicht vollständig verstanden. Eine mögliche Funktion des PrPC auf das neuronale Überleben nach einem hypoxischen oder ischämischen Insult wird diskutiert. In einem Vorversuch zeigten sich nach zerebraler Ischämie deutlich größere Infarktvolumina in den Gehirnen von Prion-Knock-Out-Mäusen im Vergleich zu denen der Wild-Typ-Mäuse. Das Identifizieren der molekularen Mechanismen der PrPC-vermittelten Neuroprotektion ist daher von großem Interesse und machte die Etablierung eines Zell-Modells erforderlich.
Neuere Studien konnten einen Einfluss des zellulären Prion-Proteins auf die Glykolyse nachweisen. Unter Sauerstoffmangelbedingungen kommt es zu einer vermehrten Bildung von Laktat durch das Enzym Laktat-Dehydrogenase (LDH). Neurone benötigen unter hypoxischen oder ischämischen Bedingungen dieses Laktat als Energiesubstrat. Je mehr Laktat den Neuronen zur Verfügung steht, umso höher ist das neuronale Überleben.
In dieser Arbeit konnte die Beteiligung der Laktat-Dehydrogenase an der durch das zelluläre Prion-Protein vermittelten Neuroprotektion nach Hypoxie nachgewiesen werden. Das Ziel dieser Arbeit bestand darin, mögliche Unterschiede der LDH-Expression in WT-Zellen, Prnp0/0-Zellen und HEK-293-Zellen unter normalen und hypoxischen Bedingungen in vitro zu untersuchen. Die Expression der LDH war unter hypoxischen Bedingungen in den WT-Zellen im Vergleich zu den Prnp0/0-Zellen deutlich höher. Dies konnte auch in PrPC-überexprimierenden HEK-293-Zellen nach Hypoxie gezeigt werden. Ebenso konnte nachgewiesen werden, dass Hypoxie zu einem größeren Schaden des Tubulinzytoskelettes in Prnp0/0-Zellen führt als in WT-Zellen, was eine neuroprotektive Wirkung von PrPC vermuten lässt.
Eine direkte oder indirekte Interaktion von LDH-A und PrPC konnte durch eine Co-Immunpräzipitation in HEK-293-Zellen nachgewiesen werden. Die genauen Mechanismen über die PrPC möglicherweise zu einer vermehrten Laktat-Produktion führt, sind noch nicht eindeutig identifiziert und müssen noch näher untersucht werden.
Zusammengefasst kann gesagt werden, dass die erhobenen Daten die Vermutung verstärken, dass das Enzym LDH und sein Produkt Laktat in die durch das zelluläre Prion-Protein vermittelte Neuroprotektion nach Hypoxie involviert sind. Es ist das erste Mal, dass gezeigt wurde, durch welchen Mechanismus PrPC zur Neuroprotektion beiträgt.
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Mise au point d’un nouveau modèle d’organoïde cérébral humain pour l’étude des mécanismes d’interaction de la protéine prion et de l’amyloïde β / Set Up of a New Human Cerebral Organoid Model to Study the Interaction Mechanisms of Prion and β Amyloid ProteinsPavoni, Serena 13 December 2017 (has links)
Les mécanismes de type prion sont désormais reconnus comme sous-tendant la plupart des maladies neurodégénératives humaines, avec en premier lieu la maladie d’Alzheimer (MA) au niveau de ses 2 marqueurs spécifiques, l’amyloïde β (Aβ à l’origine de l’hypothèse étiopathogénique de la cascade amyloïde) et la protéine Tau phosphorylée. Par ailleurs la protéine du prion (PrPC) est décrite comme interagissant à de multiples niveaux avec le métabolisme de l’Aβ sans que les mécanismes physiopathologiques sous-jacents n’aient pu être expliqués. Pour sortir de l’impasse actuelle concernant le développement d’approches thérapeutiques efficaces pour la MA, l’industrie pharmaceutique a besoin de modèles expérimentaux innovants. En effet, à ce jour aucun modèle in vivo, en dépit des progrès réalisés avec les souris transgéniques, n’arrive à refléter la complexité cérébrale humaine ni à mimer une MA clinique. Les cultures in vitro en 2D sont quant à elles très éloignées des situations conduisant à l’accumulation d’agrégats protéiques pathologiques. Le but de notre thèse a été d’utiliser dans le domaine des neurosciences les nouvelles perspectives de recherche ouvertes par les technologies des cellules souches pluripotentes induites (cellules iPS) en développant un modèle de différentiation en 3D pour obtenir des organoïdes cérébraux humains (OC) (mini cerveaux). Leur capacité d’auto-organisation en 3D de tissu neuroectodermique nous a permis de recréer un système complexe mimant différentes structures cérébrales humaines dans lesquelles nous avons pu caractériser les marqueurs attendus. L’étude de l’expression des protéines d’intérêt APP et PrPC pendant la différentiation neurale a permis de caractériser la modulation des niveaux des deux protéines en fonction du temps de culture. Afin d’orienter le modèle vers des mécanismes d’accumulation protéique de type MA, nous avons testé différents inducteurs chimiques dont l’Aftin-5 qui est capable de moduler les voies post-traductionnelles de l’APP. Plusieurs stratégies de traitement ont été adoptées pour induire le clivage de l’APP et la génération d’Aβ. La production des fragments solubles Aβ38, Aβ40, Aβ42 a été mise en évidence par ELISA. Les niveaux générés sont reproductibles et l’augmentation du ratio Aβ42/Aβ40 est cohérente avec les données extrapolées des modèles murins et humains, ce qui a permis de valider notre modèle. Les niveaux d’expression génique et protéique de PrPC et de APP suite au traitement ont été analysés afin de mieux déterminer le rôle de l’interaction entre ces deux facteurs. L’objectif à long terme consiste à améliorer ce modèle, dont les limites actuelles sont notamment l’absence de vascularisation et le niveau de maturation du tissu neural. Le défi majeur dans le cadre de la culture des OC consiste donc à favoriser l’intégration du système vasculaire, et par ailleurs à accélérer le vieillissement in vitro pour l’étude de maladies neurodégénératives. La perspective de pouvoir automatiser le système de culture des OC permet d’envisager l’utilisation de ce modèle à plus grande échelle dans le cadre de test de cytotoxicité et/ou de criblage pharmacologique à haut débit pour identifier de nouvelles molécules thérapeutiques pour la MA. / Prion-like mechanisms are known to underlie most of human neurodegenerative diseases including Alzheimer’s disease (AD), which is characterized by two important pathological markers, β amyloid (or Aβ at the origin of the etiopathogenic amyloid cascade hypothesis) and phosphorylated tau protein. Furthermore, the prion protein (PrPC) interacts at multiple levels with the metabolism of Aβ, by mechanisms which are not well understood. To overcome the current limits in the development of efficient strategies to treat AD, the pharmaceutical industry requires innovative experimental models. However, even if a lot of progress has been achieved by using transgenic mouse models, to date no in vivo model can reflect the complexity of human brain or reproduce a clinical context. 2D in vitro cell culture models are unable to allow the aggregation and accumulation of pathological proteins as observed in vivo. The aim of this study consists in taking advantage of the research prospects offered by induced pluripotent stem cell (iPSCs) in the field of neurosciences. iPSCs can be used to generate 3D models of differentiation also called human cerebral organoids or mini-brains (MBs). Their ability to self-organise in 3D neuroectodermic tissue leds to a complex system that mimics different human cerebral structures in which we were able to characterize the expected markers. The study of the two proteins of interest (APP and PrPC) during neural differentiation has allowed us to follow the modulation of protein expression level occurring during the in vitro development of the human MBs. In order to use this model to reproduce the protein accumulation mechanisms seen in AD, we have tested chemical inductors such as Aftin-5 in order to modulate the APP post-transcriptional pathway towards a pathological outcome. Many strategies of treatment are adopted to lead APP cleavage and Aβ generation. The production of soluble fragments Aβ38, Aβ40, Aβ42 in the supernatant of organoids has been showed using ELISA technique. The levels generated are reproducible and the increase of Aβ42/Aβ40 ratio is consistent with extrapolated data from mouse and human models thus validating our model. Analysis at the gene and protein level has been assessed in order to understand the interaction between PrPC and APP after treatment. The long-term goal consists in improving this model which is notably hampered by the absence of vascularization and the low level of maturation of the neural tissue. The main challenge in MB culture thus consists in the integration of the vascular system, and also in increasing the speed of ageing process in vitro for the study of neurodegenerative diseases. In the long term, the prospect of automating the culture of MBs would allow the use of the system for cytotoxicity testing and/or high throughput screening for the discovery of new drugs for AD.
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