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1	The role of growth differentiation factor 15 in the pathogenesis of primary myelofibrosis / 原発性骨髄線維症の病態におけるGrowth differentiation factor 15の役割 Uchiyama, Tatsuki 23 March 2016 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第19569号 / 医博第4076号 / 新制\|\|医\|\|1017(附属図書館) / 32605 / 京都大学大学院医学研究科医学専攻 / (主査)教授江藤浩之, 教授武藤学, 教授中畑龍俊 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM Growth differentiation factor 15 osteoblastic differentiation primary myelofibrosis 490
2	GDF-15 im Zusammenhang mit Therapieerfolg einer Immuncheckpointblockade: eine Pilotstudie mit fortgeschrittenen soliden Tumorerkrankungen / Connection of GDF-15 with success of an immune checkpoint blockade therapy: a pilot study with progressed solid tumors Dombrowski, Dorothea January 2022 (has links) (PDF) Kurzzusammenfassung: Dank der Einführung von Immuncheckpointinhibitoren hat sich die Therapie fortgeschrittener onkologischer Erkrankungen in den letzten Jahren dramatisch verändert. Trotz außergewöhnlicher Erfolge proﬁtieren viele Patienten jedoch weder akut noch langfristig von einer Behandlung, tragen aber alle ihre Risiken. Ein besseres Verständnis davon, bei welchen Patienten diese Therapieform wirkt, sowie prädiktive Marker werden daher dringend benötigt. Growth Differentiation Factor 15 (GDF-15) ist Teil der Transforming Growth Factor-β Superfamilie, weist in pathologischen Situationen wie Entzündungen und insbesondere bei Krebs sehr hohe Spiegel auf und besitzt in verschiedenen, auch onkologischen Erkrankungen einen starken prognostischen Wert. Möglicherweise könnte GDF-15 durch seine immunmodulierenden Eigenschaften dazu beitragen, dass Krebszellen im Körper nicht angegriffen werden, und die Wirksamkeit einer Immuncheckpointblockade (ICB) dadurch vermindern. Ziel der vorliegenden Pilotstudie war es zu untersuchen, ob ein Zusammenhang zwischen dem GDF-15-Spiegel und dem Erfolg einer ICB besteht. Hierfür wurden 37 Patienten verschiedener onkologischer Entitäten vor Beginn einer ICB auf ihre GDF-15-Spiegel untersucht, sowie nach zwölf bzw. bei Progressive Disease zum Teil auch nach vier Wochen Therapie. Die Bewertung des Therapieergebnisses erfolgte anhand der RECIST sowie der klinischen Präsentation. Ein Therapieerfolg wurde ab Erreichen einer Stable Disease klassiﬁziert. Die Rekrutierungszeit betrug 23 Monate ab Januar 2017. Die Untersuchungen zeigten vor Therapiebeginn einer ICB einen geringen Unterschied der GDF-15-Spiegel zwischen Patienten mit Therapieerfolg und Therapieversagen (Median des Therapieerfolgs: 0,63 ng/ml versus Median des Therapieversagens: 0,92 ng/ml). Dieser Unterschied war statistisch nicht signiﬁkant. Dagegen zeigte sich ein signiﬁkanter Zusammenhang zwischen einem Anstieg des GDF-15-Spiegels unter Therapie und dem Therapieversagen einer ICB. Bei Therapieerfolg sank oder stagnierte der GDF-15-Spiegel im Median um - 0,01 ng/ml. Dagegen stieg er bei Therapieversagen im Median um + 0,7 ng/ml an (p < 0,01 r = 0,43). Auch die Höhe des GDF-15-Spiegels unter Therapie zeigte einen signiﬁkanten Zusammenhang mit dem Therapieergebnis. Der GDF-15-Spiegel unter Therapie lag im Median bei Patienten mit Therapieerfolg bei 0,72 ng/ml, dagegen bei Patienten mit Therapieversagen bei 1,85 ng/ml (p < 0,01 r = 0,47). Ob der GDF-15-Spiegel vor Therapiebeginn die Wirksamkeit einer ICB vorhersagen kann, bleibt unklar, da in dieser Studie nur eine Tendenz aufgezeigt werden konnte, die in Folgestudien mit größeren Kohorten in den verschiedenen Entitäten untersucht werden sollte. Unsere Daten zeigen jedoch einen Zusammenhang zwischen einem steigenden bzw. erhöhten GDF-15-Spiegel unter Therapie mit dem Therapieergebnis einer ICB. Dieser Zusammenhang fügt sich gut in das Bild gegenwärtiger Diskussionen über immunmodulierende Eigenschaften von GDF-15 und seiner Rolle bei der Tumorprogression. Zugleich bestärkt das Studienergebnis die Annahme, in GDF-15 auch ein vielversprechendes Angriffsziel therapeutischer Ansätze gefunden zu haben. / Abstract: Thanks to the introduction of immune checkpoint inhibitors, therapy of progressed oncological diseases has changed dramatically in recent years. However, many patients benefit neither acutely nor in the long term from the treatment but bear all its risks. A better understanding of which patients profit from this therapy as well as predictive markers are therefore urgently needed. Growth Differentiation Factor 15 (GDF-15) is part of the Transforming Growth Factor-β superfamily. It shows raised levels in pathological situations such as inflammation and reaches especially in cancer remarkably high levels. It has a strong prognostic value in various, also oncological diseases. Possibly, GDF-15 helps cancer cells not to be attacked by the immune system and could thereby reduce the effectiveness of an immune checkpoint blockade (ICB). The aim of the presented pilot study was investigating whether there is a connection between the GDF-15 level and the success of an ICB. For this purpose, the GDF-15 level of 37 patients of different oncological entities were examined before the start of an ICB, as well as after twelve weeks of therapy, or in the case of progressive disease, after four weeks of therapy. The evaluation of the therapy results was based on RECIST and the clinical presentation. The time of recruitment was 23 months since January 2017. For the GDF-15 level before start of an ICB therapy, the investigations showed a small difference between patients with therapy success and therapy failure (median when success of the therapy: 0.63 ng/ml versus median when treatment failure: 0.92 ng/ml). But this difference was not statistically signiﬁcant. In contrast, during therapy there was a signiﬁcant connection between an increase in the GDF-15 level and therapy failure of the ICB. In case of successful therapy, the GDF-15 level fell or stagnated with a median of -0.01 ng/ml. In contrast, the GDF-15 level rose with a median of +0.7 ng/ml in case of therapy failure (p<0.01 r=0.43). Also, the absolute height of the GDF-15 level during therapy showed a signiﬁcant connection with the therapy result. The median of the GDF-15 level during therapy of patients with therapy success was 0.72 ng/ml, but of patients with treatment failure was 1.85 ng/ml (p<0.01 r = 0.47). Whether the GDF-15 level can predict the effectiveness of an ICB before the start of therapy remains unclear, since this study could only show a trend that follow-up studies with larger cohorts for the different entities should further examine. However, our data show a correlation between increasing and increased GDF-15 levels under therapy with the therapy result of an ICB. This correlation fits well with current discussions about immunomodulating properties of GDF-15 and its role in tumor progression. Simultaneously, the study result confirms the assumption of GDF-15 being a promising target of new therapeutic approaches. Immun-Checkpoint Growth-differentiation Factor 15 GDF 15 ddc:610
3	Development and characterization of monoclonal antibodies to GDF-15 for potential use in cancer therapy / Die Entwicklung und Charakterisierung monoklonaler Antikörper gegen GDF-15 zur potenziellen Anwendung in der Krebstherapie Junker, Markus January 2015 (has links) (PDF) Background GDF-15 is a divergent member of the TGF-superfamily, which was first described as macrophage inhibitory cytokine-1 (MIC-1), revealing an immune modulatory function. GDF-15 is a soluble protein which is, under physiological conditions, highly expressed in the placenta and found in elevated levels in blood sera of pregnant women. Apart from the placenta, GDF-15 is expressed in healthy tissue, albeit to a lower extent and overexpressed in many solid tumors. A variety of different functions are attributed to GDF-15 in healthy as well as diseased humans. On the one hand, GDF-15 is required for successful pregnancy and low GDF-15 serum levels during pregnancy correlate with fetal abortion. On the other hand, overexpression of GDF-15, which can be observed in several malignancies is correlated with a poor prognosis. Furthermore, tumor derived GDF-15 leads to cancer associated anorexia-cachexia syndrome in mice. The aim of my PhD thesis was to further investigate the role of GDF-15 as an immune modulatory factor in cancer, in particular, by inhibiting the target molecule in vitro and in vivo. Therefore, the main focus was placed on the generation and characterization of monoclonal GDF-15 specific blocking antibodies, which were tested in vitro and in vivo, which represents a substantial part of my work. Results Here, GDF-15 was shown to be highly expressed in human gynecological cancer and brain tumors. We could then demonstrate that GDF-15 modulates effector immune cells in vitro. GDF-15 mediated a slight downregulation of the activating NKG2D receptor on NK and CD8+ T cells, which is crucial for proper anti-tumoral immune responses. Furthermore, we could demonstrate that GDF-15 reduces the adhesion of CD4+ and CD8+ T cells on endothelial cells in vitro. A negatively affected trans-endothelial migration of leukocytes into inflamed tissue could explain the low T cell infiltration in GDF-15 expressing tumors, which were observed in vivo, where mice bearing (shRNA mediated) GDF-15 deficient glioma cells revealed enhanced immune cell infiltrates in the tumor microenvironment, compared with the GDF-15 expressing control group. Those animals further exhibited a decreased tumor growth and prolonged survival. GDF-15 is a soluble protein, secreted by more than 50 % of solid tumors and associated with grade of malignancy. Therefore a neutralizing monoclonal antibody to GDF-15 was assumed to be an auspicious therapeutically anti-cancer tool. Such an antibody was thus generated in GDF-15 knock out mice against human GFD-15. Amongst many clones, the GDF-15 antibody clone B1-23 was found to be applicable in Western Blot as well as in ELISA techniques, detecting a three-dimensional epitope of the mature GDF-15 dimer with high affinity and specificity. To enable the humanization for a later administration in humans, the variable regions of antibody B1-23 were identified by a special PCR method using degenerate primers and cloned into a sequencing vector. The sequence obtained thereby enabled the generation of chimeric and humanized B1-23 variants. After further comprehensive characterization, the original mouse antibody B1-23 as well as the chimeric antibody (ChimB1-23) and the humanized B1-23 antibody (H1L5) were applied in a melanoma xenograft study in vivo. None of the antibodies could significantly inhibit tumor growth. .However of utmost importance, body weight loss mediated by tumor derived GDF-15 could be significantly prevented upon administration of all three GDF-15 specific antibodies, which confirmed the antagonizing functionality of the immunoglobulin. Conclusion GDF-15 is a promising cancer target, involved in tumor progression and cancer related cachexia. A monoclonal GDF-15 antibody was generated, which served on one hand as a tool for molecular biological applications (Western Blot, ELISA, etc.) and on the other hand was applied as an antagonizing antibody in vitro and in vivo. Even though tumor growth inhibition by GDF-15 depletion in T cell deficient athymic mice failed using B1-23, the same antibody and derivates thereof (chimeric and humanized) impressively prevented tumor associated cachexia in UACC-257 melanoma bearing nude mice. The missing anti-tumor effect in our own melanoma model in nude mice can only partially be explained by the missing secondary immunity, in particular cytotoxic T cells, in the athymic animals, since in a similar melanoma model, performed by an external company, a tumor reduction in immunocompromised animals was observed, when B1-23 was administered. These findings support the idea that T cells are substantial for an effective tumor immunity and are in line with the results of the syngeneic, T cell comprising, mouse glioma model, where silencing of tumor expressed GDF-15 led to an enhanced intratumoral T cell infiltration and a prolonged survival. Taken together our data allow for the conclusion that tumor associated cachexia can be combatted with the GDF-15 antibody B1-23. Further, B1-23 might elicit direct anti-tumor effects in immune competent models, which contain T cells, rather than in an athymic, T cell deficient nude mouse model. / Hintergrund GDF-15 ist ein divergentes Mitglied der TGF-Superfamilie, welches zuerst als „macrophage inhibitory cytokine-1“ (MIC-1) mit immunmodulatorischen Eigenschaften beschrieben wurde. GDF-15 ist ein lösliches Protein, das unter physiologischen Bedingungen hauptsächlich in der Plazenta exprimiert wird und welches im Serum von Schwangeren in erhöhten Konzentrationen nachgewiesen werden kann. Mit Ausnahme der Plazenta wird GDF-15 in verschiedenen gesunden Geweben gefunden, hier jedoch in deutlich niedrigeren Konzentrationen, und ist in vielen soliden Tumoren überexprimiert. GDF-15 werden sowohl bei gesunden, als auch bei kranken Menschen, unterschiedlichste Funktionen zugeschrieben. Zum einen ist GDF-15 für eine erfolgreiche Schwangerschaft notwendig. Niedrige GDF-15 Spiegel im Serum während der Schwangerschaft korrelieren mit dem Verlust des Fötus. Zum anderen korreliert die Überexpression von GDF-15, welche bei unterschiedlichen Malignitäten beobachtet werden kann, mit einer schlechten Prognose. Darüber hinaus verursacht das von Tumorzellen sezernierte GDF-15 das sogenannte „Anorexie-Kachexie Syndrom“ in Mäusen. Das Ziel meiner Arbeit war es, die immunmodulatorische Funktion von GDF-15 im Tumorkontext zu untersuchen, insbesondere durch eine Hemmung des Zielmoleküls in vitro und in vivo. Aus diesem Grund wurde der Schwerpunkt auf die Generierung und Charakterisierung monoklonaler, GDF-15 spezifischer, blockierender Antikörper gelegt. Diese wurden sowohl in vitro als auch in vivo getestet, was einen großen Teil dieser Arbeit darstellt. Ergebnisse Es konnte gezeigt werden, dass GDF-15 in humanen gynäkologischen Tumoren wie auch in Hirntumoren überexprimiert ist. Weiterhin ließ sich zeigen, dass GDF-15 Effektorzellen des Immunsystems in vitro moduliert. Dabei verursacht GDF-15 eine moderate Herunterregulation des aktivierenden Killing Rezeptors NKG2D auf NK und CD8+ T Zellen, welcher eine hohe Bedeutung für eine effektive anti-tumorale Immunantwort hat. Darüber hinaus konnten wir zeigen, dass GDF-15 die Adhäsion von CD4+ und CD8+ T Zellen auf Endothelzellen in vitro herabsetzt. Eine daraus resultierende Reduktion der trans-endothelialen Migration von Leukozyten in entzündetes Gewebe erklärt möglicherweise die niedrige T Zell Infiltration in GDF-15 exprimierenden Tumoren, welche in vivo beobachtet werden konnten. Mäuse, denen (auf shRNA basierende) GDF-15-defiziente Gliomzellen appliziert wurden, zeigten im Vergleich zur Kontrollgruppe, welche GDF-15-exprimierenden Gliomzellen erhalten hatte, ein verlängertes Überleben, vermindertes Tumorwachstum und eine erhöhte Immunzellinfiltration in das Tumormikromillieu. GDF-15 ist ein lösliches Protein, das von mehr als 50 % aller soliden Tumore sezerniert wird und mit dem Grad der Malignität korreliert. Daher wurde postuliert, dass ein neutralisierender monoklonaler Antikörper gegen GDF-15 eine effektive neue Antikrebstherapie ermöglichen sollte. Solch ein Antikörper wurde entsprechend in GDF-15-defizienten Mäusen generiert. Unter verschiedenen Klonen wurde der Antikörper Klon B1-23 identifiziert, welcher sowohl im Western Blot als auch im ELISA anwendbar ist. Dieser Klon detektiert ein drei-dimensionales Epitop des maturen GDF-15 Dimers mit hoher Affinität und Spezifität. Um den Antikörper für eine spätere Anwendung im Menschen humanisieren zu können, wurden die variablen Regionen des Klons B1-23 durch eine spezielle PCR Methode unter Verwendung degenerierter Primer und nachfolgender Klonierung in einen Sequenzierungsvektor identifiziert. Die hierdurch gewonnenen Sequenzen ermöglichten die Generierung von chimären und humanisierten Varianten von B1-23. Nach anschließender intensiver Charakterisierung konnte sowohl der ursprüngliche Maus-Antikörper B1-23 als auch der chimäre B1-23 Antikörper (ChimB1-23) und der humanisierte B1-23 Antikörper (H1L5) in einer Melanom Xenograft Studie in vivo getestet werden. Zwar ließ sich mit keinem der Antikörper eine signifikante Hemmung des Tumorwachstums beobachten. Als herausragendes Ergebnis zeigte sich allerdings, dass der durch GDF-15 induzierte Gewichtsverlust signifikant durch die Verabreichung der GDF-15 spezifischen Antikörper verhindert werden konnte, was die antagonisierende Funktionalität des entwickelten Immunglobulins bestätigte. Schlussfolgerung GDF-15 ist ein vielversprechendes Zielmolekül bei Krebserkrankungen, welches bei der Tumorprogression und Tumor-assoziierter Kachexie beteiligt ist. Es konnte ein monoklonaler Anti-GDF-15 Antikörper generiert werden, welcher zum einen molekularbiologisch zum Einsatz kam (z.B. Western Blot, ELISA, etc.) und zum anderen als antagonisierender Antikörper sowohl in vitro als auch in vivo Anwendung fand. Auch wenn B1-23 scheinbar keine Tumorwachstumshemmung durch die Depletion von GDF-15 in T Zell defizienten athymischen Mäusen zeigte, konnte derselbe Antikörper wie auch die abgeleiteten Varianten (chimärisiert und humanisiert) eindrücklich die Tumor assoziierte Kachexie im UACC-257 Melanom Modell verhindern. Der ausgebliebene antitumorale Effekt in unserem Melanom Modell in Nacktmäusen lässt sich nur zum Teil durch eine fehlende sekundäre Immunkomponente, insbesondere das Fehlen zytotoxischer T Zellen, erklären, da es in einem ähnlichen Xenograft Melanom Modell, welches in Auftragsforschung (CRO) durchgeführt wurde, zu einer Reduktion des Tumorwachstums durch die Applikation von B1-23 kam. Diese Ergebnisse lassen vermuten, dass T Zellen unerlässlich für eine effektive antitumorale Antwort sind, eine Annahme, die durch die Ergebnisse des syngenen Gliom Maus-Modells unterstützt wird, in welchem es durch das Ausschalten von Tumor produziertem GDF-15 zu einer erhöhten intratumoralen T Zell Infiltration und einem längeren Überleben kam. Zusammengenommen erlauben uns diese Daten den Schluss, dass eine tumorbedingte Kachexie durch den GDF-15-Antikörper B1-23 bekämpft werden kann. Allerdings sind direkte B1-23 vermittelte antitumorale Effekte eher in immunkompetenten Modellen mit T Zellen als in einem athymischen, T Zell defizienten Nacktmaus-Modell zu erwarten. Growth-differentiation Factor 15 Monoklonaler Antikörper Krebs <Medizin> Therapie ddc:570
4	The essential role of macrophages and TLR signaling in the host response to Mycoplasma pneumoniae Lai, Jen-Feng. January 2009 (has links) (PDF) Thesis (Ph.D.)--University of Alabama at Birmingham, 2009. / Title from PDF title page (viewed on July 14, 2010). Includes bibliographical references.
5	GDF5 mediated enhancement of chondrocyte phenotype and its modulation by heparin and heparan sulfates Ayerst, Bethanie Imogen January 2017 (has links) Articular cartilage plays a vital role in load-bearing joints, providing an almost frictionless surface to articulating bones. However, the avascular nature and low cell density of the tissue means that following injury, there is limited potential for regeneration and repair. With the ageing population, the prevalence and economic burden associated with osteoarthritis (OA) is increasing rapidly, but as of yet there are no fully effective ways to treat the condition. Research into novel therapies has therefore become a popular avenue of investigation, and human mesenchymal stem/stromal cells (hMSCs) have been highlighted as particularly promising targets. However, current, methods for inducing the chondrogenic differentiation of hMSCs, which typically employ the use of transforming growth factor beta 1 or 3 (TGFβ1/3), result in the production of hypertrophic rather than hyaline tissue, hampering translational progress. Growth differentiation factor 5 (GDF5) belongs to the TGFβ superfamily of proteins and is vital for skeletal formation, however its use in cartilage tissue engineering (TE) strategies has been somewhat neglected. Here we demonstrate that GDF5 significantly increases aggrecan gene expression (a marker of articular cartilage), without affecting collagen type X expression (a marker of chondrocyte hypertrophy), in chondrocyte pellet cultures derived from hMSCs, making it a promising target for the formation of permanent articular cartilage. The therapeutic application of growth factors is, at present, limited due to their expense, susceptibility to proteolytic degradation, and rapid clearance, leading to large quantities being required to get anywhere near the desired outcome. The highly sulfated glycosaminoglycan (GAG), heparin, is already extensively used in the clinic as an anticoagulant, and is also able to bind and potentiate the activity of a wide range of growth factors. As such, researchers are now using it to enhance stem cell expansion/ differentiation protocols, as well as to improve the delivery/ activity of growth factors in TE strategies. Here, we identify GDF5 as a novel heparin/heparan sulfate (HS)-binding protein, and show that endogenous HS proteoglycans (HSPGs) are vital for localizing GDF5 to the cell surface, but are not required for its signalling activity. Importantly, we report that clinically relevant doses of heparin (≥ 10 nM), but not equivalent concentrations of HS, inhibit GDF5’s biological activity, in both hMSC-derived chondrocyte pellet cultures, and in the skeletal cell line ATDC5. We demonstrate that these inhibitory effects are due to heparin (but not HS) inhibiting both GDF5 binding to endogenous HSPGs and GDF5-induced induction of Smad 1/5/8 signalling. This study may therefore explain the variable (and disappointing) results seen with heparin-loaded biomaterials for skeletal TE, and the adverse skeletal effects, such as osteoporosis, that have been reported in the clinic following long-term heparin treatment. Together, our results caution the use of heparin in the clinic and in TE applications, and prompt the transition to using more specific GAGs (e.g. HS derivatives or synthetics), with better-defined structures and fewer off-target effects, if optimal therapy is to be achieved. In the case of GDF5, we have used a variety of developed techniques to begin uncovering important structural and functional information regarding the HS-GDF5 interaction, which are hoped to ultimately pave the way towards achieving this aim. Although further analysis is necessary, our data indicate that relatively long HS sequences are required for binding, and that both ionic and non-ionic interactions play a role in the interaction. In addition we suggest that low- rather than high-affinity HS variants may be key to potentiating the activity of this growth factor. 615.7
6	Blockade of myd88 Attenuates Cardiac Hypertrophy and Decreases Cardiac Myocyte Apoptosis in Pressure Overload-Induced Cardiac Hypertrophy in Vivo Ha, Tuanzhu, Hua, Fang, Li, Yuehua, Ma, Jing, Gao, Xiang, Kelley, Jim, Zhao, Aiqiu, Haddad, Georges E., Williams, David L., Browder, I. William, Kao, Race L., Li, Chuanfu 01 March 2006 (has links) In this study, we evaluated whether blocking myeloid differentiation factor-88 (MyD88) could decrease cardiac myocyte apoptosis following pressure overload. Adenovirus expressing dominant negative MyD88 (Ad5-dnMyD88) or Ad5-green fluorescent protein (GFP) (Ad5-GFP) was transfected into rat hearts (n = 8/group) immediately followed by aortic banding for 3 wk. One group of rats (n = 8) was subjected to aortic banding for 3 wk without transfection. Sham surgical operation (n = 8) served as control. The ratios of heart weight to body weight (HW/BW) and heart weight to tibia length (HW/TL) were calculated. Cardiomyocyte size was examined by FITC-labeled wheat germ agglutinin staining of membranes. Cardiac myocyte apoptosis was determined by terminal deoxynucleotidyl transferase-mediated dUTP nick-end labeling assay, and myocardial interstitial fibrosis was examined by Masson's Trichrome staining. Aortic banding significantly increased the HW/BW by 41.0% (0.44 ± 0.013 vs. 0.31 ± 0.008), HW/TL by 47.2% (42.7 ± 1.30 vs. 29.0 ± 0.69), cardiac myocyte size by 49.6%, and cardiac myocyte apoptosis by 11.5%, and myocardial fibrosis and decreased cardiac function compared with sham controls. Transfection of Ad5-dnMyD88 significantly reduced the HW/BW by 18.2% (0.36 ± 0.006 vs. 0.44 ± 0.013) and HW/TL by 22.3% (33.2 ± 0.95 vs. 42.7 ± 1.30) and decreased cardiomyocyte size by 56.8%, cardiac myocyte apoptosis by 76.2%, as well as fibrosis, and improved cardiac function compared with aortic-banded group. Our results suggest that MyD88 is an important component in the Toll-like receptor-4-mediated nuclear factor-κB activation pathway that contributes to the development of cardiac hypertrophy. Blockade of MyD88 significantly reduced cardiac hypertrophy, cardiac myocyte apoptosis, and improved cardiac function in vivo. nuclear factor-κB signal transduction Surgery
7	GROWTH DIFFERENTIATION FACTOR-15 IS A CONTRACTION-INDUCED MYOKINE THAT MAINTAINS GLUCOSE HOMEOSTASIS IN OBESITY AND TYPE 2 DIABETES Zhang, Hui 02 June 2020 (has links) No description available. Biomedical Research Physiology
8	Role and expression of transferrin receptor 2 in erythropoiesis / Rôle et expression du récepteur de la transferrine de type 2 dans la lignée érythroïde Vieillevoye, Maud 12 July 2013 (has links) L’érythropoïèse est le processus de différentiation d’un progéniteur érythroïde multipotent en globules rouges. La différentiation érythroïde est essentiellement contrôlée par le récepteur à l’érythropoïétine (EPOR). Nous avons montré que le récepteur à la transferrine de type 2 (TFR2) est un membre important du complexe formé par l’EPOR. Le TFR2 présente, comme l’EPOR une expression restreinte qui dépend du type cellulaire. Ainsi son expression n’a pu être détectée que dans le foie, l’érythron et l’intestin grêle. Le rôle du TFR2 a été exploré dans les hépatocytes et il a été montré qu’il joue le rôle d’un senseur de fer dans cette lignée et de ce fait contribue à l’homéostasie du fer. Nous avons déterminé le rôle du TFR2 dans les érythroblastes et montré que TFR2 est une protéine escorte de l’EPOR qui contribue à l’érythropoïèse in vitro et in vivo. De plus, nos travaux montrent que le TFR2 est requis pour la production de GDF15 (Growth Differentiation Factor 15) dans les érythroblastes. D’autre part nous avons démontré que la production de GDF15 est augmentée par l’EPO, la déplétion intracellulaire en fer et l’activité transactivatrice de P53. L’inhibition de l’expression de P53, réalisée au cours de l’étude de son rôle dans la production de GDF15, a révélé son implication dans l’érythropoïèse normale. Nous avons mis en évidence l’existence de plusieurs formes du TFR2. Deux d’entre elles résultent de l’utilisation de sites distincts d’initiation de la traduction. Ces deux isoformes sont régulée différemment au cours de la maturation des érythroblastes. La troisième isoforme, appelée TFR2 soluble (sTFR2), est relargée dans le plasma suite au clivage du TFR2. Nous avons montré que la production du sTFR2 est inhibée en présence du ligand de TFR2, la transferrine saturée en fer (holoTF) alors que le TFR2 est stabilisé dans ces mêmes conditions. Les rôles spécifiques des trois formes du TFR2 doivent encore être élucidés. / Erythropoiesis is the differentiation process of a multipotent erythroid progenitor into red blood cells. Erythroid differentiation is primarily controlled by the erythropoietin receptor (EPOR). We showed that the Transferrin receptor 2 (TFR2) is an important member of the EPOR complex. TFR2 has like EPOR a lineage-restricted expression and can solely be detected in the liver, erythron and small intestine. TFR2 function has been explored in hepatocytes where it plays the role of an iron sensor and contributes to iron homeostasis. We determined the role of TFR2 in erythroblasts and showed that TFR2 is an escort protein for EPOR that contributes to optimal erythropoiesis in vitro and in vivo. Moreover we evidenced that TFR2 is absolutely required for the production of Growth differentiation factor 15 (GDF15) in erythroblasts. We further demonstrated that GDF15 production is increased by EPO levels, by intracellular iron depletion as well as by P53 trans-activation activity. The inhibition of P53 expression, realized for the study of its role in GDF15 production, revealed its implication in normal erythropoiesis. We evidenced that TFR2 is expressed under several forms, two of which result from the utilization of distinct translational initiation sites. These two isoforms are differently regulated during erythroid maturation. The third form called soluble TFR2 (sTFR2) is released in the plasma after TFR2 cleavage. We showed that sTFR2 production is inhibited in the presence of TFR2 ligand, iron loaded transferrin (holoTF) whereas cell surface TFR2 expression is stabilized by holoTF. The specific roles of the three forms of TFR2 expressed by erythroblasts remain to be elucidated. Erythropoïèse Récepteur de la transferrine de type 2 Récepteur à l’érythropoïétine GDF15 (Growth differentiation factor 15) P53 Métabolisme du fer Erythropoiesis Transferrin receptor 2 (TFR2) Erythropoietin receptor (EPOR) Growth differentiation factor 15 (GDF15) P53 Iron metabolism 612.111
9	Aspectos da regulação do metabolismo do ferro nas hemoglobinopatias / Aspects of iron metabolism regulation in hemoglobinopathies Fertrin, Kleber Yotsumoto, 1980- 19 August 2018 (has links) Orientador: Fernando Ferreira Costa / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-19T02:13:16Z (GMT). No. of bitstreams: 1 Fertrin_KleberYotsumoto_D.pdf: 1904934 bytes, checksum: a74beda8b565fcdc3f59ad37d66ca23e (MD5) Previous issue date: 2011 / Resumo: As hemoglobinopatias são distúrbios hereditários em que uma mutação genética leva a alteração da produção normal de hemoglobina, tal como na anemia falciforme e nas talassemias ß. Na maioria dessas doenças, ocorre anemia com necessidade transfusional variável, o que pode acarretar sobrecarga corporal de ferro. Na talassemia ß intermediária, ocorre aumento espontâneo e desproporcional da absorção do ferro, com consequente excesso desse metal mesmo na ausência de transfusões. Com a evolução da terapia transfusional e o aumento da expectativa de vida desses pacientes, o conhecimento sobre a regulação do metabolismo do ferro tornou-se fundamental para melhor controle da sobrecarga de ferro. O principal regulador desse metabolismo é a hepcidina, um polipeptídeo produzido majoritariamente pelo fígado, porém também sintetizado por células do sistema fagocítico-mononuclear, em que seu papel é pouco conhecido. Uma citocina capaz de suprimir a produção de hepcidina é o GDF-15 (fator de crescimento e diferenciação 15). Neste estudo, com a avaliação de amostras de sangue de 103 pacientes com anemia falciforme, talassemia ß intermediária, anemia por deficiência de cobalamina ou outros tipos de anemia, constatou-se que o aumento dos níveis desse fator ocorre tanto em quadros de hemólise crônica quanto na presença de eritropoese ineficaz, constituindo um sinal da medula óssea modulador da absorção de ferro nos estados de aumento da eritropoese. Entretanto, evidenciou-se que a associação de supressão da hepcidina com altos níveis de GDF-15 ocorre nas hemoglobinopatias, mas não nas demais causas de anemia. Na anemia megaloblástica, a ausência de sobrecarga de ferro com níveis normais de hepcidina ao diagnóstico e sua queda durante o tratamento sugerem regulação da hepcidina independente de GDF-15 neste tipo de anemia. A análise da razão hepcidina/ferritina mostrou-se mais fidedigna que os níveis de hepcidina circulante na identificação dos estados em que há propensão a absorção aumentada de ferro por alta atividade eritropoética, e sugerem que o estado inflamatório crônico da anemia falciforme poderia exercer um fator protetor contra sobrecarga de ferro, quando comparados a talassemia intermediária, pela elevação relativa da produção de hepcidina. Além disso, observou-se uma correlação negativa entre a expressão gênica de hepcidina (gene HAMP) em monócitos humanos e os níveis de GDF-15, denotando um provável efeito regulatório semelhante ao descrito em hepatócitos. Não se identificou correlação entre essa expressão nos monócitos e marcadores de sobrecarga de ferro, corroborando a hipótese de a hepcidina ter outra função nessas células, não relacionada diretamente à absorção de ferro. Pacientes com anemia falciforme em uso de hidroxiureia apresentaram maiores níveis de expressão de hepcidina monocítica e obteve-se evidência in vitro de uma ação estimuladora dessa expressão por esse fármaco, caracterizando a hidroxiureia com potencial atividade agonista de hepcidina, de futuro interesse em estudos de sua aplicação clínica nos estados em que exista deficiência monocítica dessa proteína. Trata-se do primeiro estudo avaliando comparativamente hemoglobinopatias e outros tipos de anemia com e sem componente eritropoético ineficaz do ponto de vista dos reguladores da absorção de ferro, além de caracterizar, pela primeira vez, a expressão de hepcidina extra-hepática nos distúrbios da síntese de hemoglobina / Abstract: Hemoglobinopathies are inherited diseases in which a genetic mutation leads to abnormal production of hemoglobin, such as in sickle cell anemia or in the ß-thalassemias. In the majority of these disorders, anemia causes variable degrees of transfusion dependency, which may lead to iron overload. In ß-thalassemia intermedia, an increase in iron absorption occurs spontaneously and regardless from the total body iron stores, generating iron overload even in the absence of repeated transfusions. Owing to advances in transfusion medicine and to the improvement in the overall life expectancy of patients with hemoglobin disorders, further knowledge on the regulation of iron metabolism has become increasingly important for appropriate management of iron overload. The main regulator of iron metabolism is hepcidin, a polypeptide mainly produced by the liver, although its synthesis also occurs in phagocytic-mononuclear cells, in which its role is less known. Growth differentiation factor 15 (GDF-15) is a cytokine capable of downregulating hepcidin production. This study analyzed 103 blood samples from patients with sickle cell anemia, ß-thalassemia intermedia, cobalamin deficiency anemia and other types of anemia, showing elevation of GDF-15 plasmatic levels both in chronic hemolytic states and ineffective erythropoiesis, thus characterizing it as a signalling molecule produced by the bone marrow to stimulate iron absorption in the presence of increased erythropoietic activity. Nevertheless, hepcidin suppression was only associated with high levels of GDF- 15 in the hemoglobinopathies. In megaloblastic anemia, absence of iron overload with normal hepcidin levels, associated with their reduction during treatment, suggest that hepcidin regulation occurs independently from GDF-15 in thie type of anemia. Analysis of hepcidin/ferritin ratio proved to be more reliable to identify patients prone to increased iron absorption due to erythropoietic hyperactivity than hepcidin levels themselves and suggests that the chronic inflammatory state in sickle cell anemia may protect from iron overload by relatively increasing hepcidin levels in comparison to levels found in thalassemia intermedia. Moreover, we found a negative correlation between GDF-15 levels and HAMP monocytic expression, a regulatory mechanism similar to what has been observed in hepatic cell lines. In further analyses of the present study, no correlation between hepcidin expression and iron overload markers was observed in monocytes from patients with hemoglobinopathies, corroborating the hypothesis that the monocytic counterpart of hepcidin could have a different function, unrelated to iron regulation. Patients with sickle cell anemia under hydroxyurea treatment have been shown to present with higher levels of hepcidin expression in monocytes, and a cell culture model managed to demonstrate the upregulating effect of hydroxyurea in vitro, thus highlighting the possibility of exploring this drug in the future as a potential hepcidin agonist and, therefore, as a therapeutic intervention in diseases with impaired monocytic hepcidin production. This is the first study of molecules involved in iron metabolism regulation comparing hemoglobinopathies and other anemia types with and without ineffective erythropoiesis. Furthermore, this is the first characterization of extra-hepatic hepcidin expression in hemoglobin disorders / Doutorado / Biologia Estrutural, Celular, Molecular e do Desenvolvimento / Doutor em Fisiopatologia Medica Talassemia beta Anemia falciforme Eritropoese Ferro Beta thalassemia Sickle cell anemia Erythropoiesis Growth differentiation factor 15
10	The RNA Binding Protein SRSF1 modulates Immune and Cancer pathways by regulating MyD88 transcription Unknown Date (has links) Serine/Arginine splicing factor 1 (SRSF1), a member of the Serine/Arginine rich (SR) RNA-binding proteins (RBPs) family, regulates mRNA biogenesis at multiple steps and is deregulated in cancer and autoimmune diseases. Preliminary studies show that members of the SR protein family play a role in cellular transcription. We investigated SRSF1’s role in cellular gene transcription utilizing time-course RNA-Seq and nuclear run-on assays, validating a subset of genes transcriptionally regulated following SRSF1 overexpression. Pathway analysis showed that genes in the TNF/IL17 pathways were enriched in this dataset. Furthermore, we showed that MyD88, a strong activator of TNF transcription through transcription factors NF-κB and AP-1, is a primary target of SRSF1’s transcriptional activity. We propose that SRSF1 activates the transcription factors NF-κB and AP-1 through MyD88 pathway. SRSF1 overexpression regulates several genes that are deregulated in malignancies and immune disease, suggesting a role for SRSF1’s transcriptional activity in oncogenesis and immune response regulation. / Includes bibliography. / Thesis (M.S.)--Florida Atlantic University, 2020. / FAU Electronic Theses and Dissertations Collection RNA-Binding Proteins Serine-Arginine Splicing Factors Cancer Autoimmune diseases Transcription, Genetic RNA, Messenger Myeloid Differentiation Factor 88.

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