Global ETD Search

101	Characterization of arginine methyltransferase PRMT8 in cells with increased plasticity Hernandez, Sarah 17 January 2016 (has links) Identification of therapeutically relevant molecules is necessary for the advancement of non-viral reprogramming of human cells for regenerative medicine. We have developed a novel non-viral model system that transforms primary human dermal fibroblasts into cells with induced regeneration competence (iRC). Low oxygen-mediated effects of fibroblast growth factor FGF2 lead to an increased cellular lifespan with a two fold increase in population doublings before senescence, remaining non-tumorigenic when injected into SCID mice while maintaining regeneration competence. This system allows us to study molecules that participate in increased cellular lifespan in a non-tumorigenic system. Analysis of chromatin modification enzymes by hybridization array, RT-PCR, and Western blots revealed upregulation of the arginine methyltransferase PRMT8 in iRC cells, challenging the paradigm that PRMT8 is solely expressed in brain tissue at the plasma membrane. Possibly leading to the erroneous conclusions that PRMT8 is brain specific at the plasma membrane is the fact that PRMT8 has several mRNA variants and protein isoforms. Here, I report expression of a novel PRMT8 variant in human dermal fibroblasts. Essential participation of PRMT8 in cellular proliferation was identified as a novel function for this enzyme through siRNA-mediated knockdown in both non-tumorigenic and tumorigenic cell lines. While other members of the PRMT family have known roles in cell cycle progression, I show for the first time that PRMT8 expression is reduced in both natural senescence and by premature induction of replicative senescence using sub-cytotoxic levels of hydrogen peroxide, implicating a correlation between PRMT8 expression and cell cycle progression. However, PRMT8 overexpression causes no significant change in the number of population doublings or the amount of time spent in culture prior to senescence, and does not alter the expression of key cell cycle regulatory genes. These results suggest that maintenance of PRMT8 expression is critical for cellular proliferation, but overexpression of PRMT8 alone is not sufficient to increase cellular lifespan. I determined that oxygen is the primary mediator of PRMT8 upregulation in the iRC system and therefore investigate histone occupancy of the PRMT8 promoter at hypoxia response elements. Through this analysis, I found bivalent occupancy regardless of culture conditions, indicating that PRMT8 maintains a state of poised readiness for transcriptional accessibility. The mechanism by which PRMT8 participates in cellular proliferation was investigated through binding partner identification. A binding partner of endogenous PRMT8 is identified here for the first time as FGF2 using co-IP and mass spectrometry. As iRC cells demonstrate a unique phenotype that uncouples the mechanisms of increased lifespan from tumorigenesis, I investigated the feasibility of PRMT8 as a cancer biomarker by mining publically available data in light of our own. I showed that PRMT8 is not only expressed in a variety of cancers, but that its expression is amplified. Moreover, PRMT8 expression significantly correlates to patient survival in specific cancers, strengthening the feasibility of this molecule as a biomarker. Aberrant expression of most PRMT family members has been described in various cancers, and specific PRMT variants are currently being used as prognostic markers. As such, I analyzed variant-specific PRMT8 expression in primary cancer cell lines and show that tumorigenic glioblastomas express PRMT8 mRNA variant 2. These data suggest that PRMT8 is a viable candidate for further study as a prognostic cancer biomarker, specifically for brain cancer. arginine methylation cancer biology proliferation reprogramming senesence
102	Wechselwirkungen zwischen Replikationsproteinen und Origin-DNA während Proliferation und terminaler Differenzierung / Interactions between replication proteins and origin DNA during proliferation and terminal differentiation Zellner, Elisabeth January 2005 (has links) (PDF) Ein Teil dieser Arbeit befasste sich mit der Fragestellung, ob beim Übergang von Proliferation zu Teilungsruhe und Differenzierung irreversible Veränderungen in der Zusammensetzung des präreplikativen Komplexes auftreten. Ein dafür geeignetes System ist die murine C2C12-Zell-Linie, die durch Kultivierung in Hungermedium zu Myotuben differenziert werden können. FACS-Analyse und BrdU-Einbau ergaben, dass in den Muskelzellen keine signifikante DNA-Synthese mehr stattfindet. Die Fluktuation von Replikationsproteinen wurde im Verlauf der terminalen Differenzierung untersucht. Gleiche Mengen an Kern- und Cytoplasma-Extrakten von proliferierenden, konfluenten und sich differenzierenden Zellen wurden durch SDS-PAGE aufgetrennt und im Immunblot mit Antikörpern gegen Replikationsproteine untersucht ORC1, CDC6, MCM6 und Geminin konnten nach 132 h nicht mehr detektiert werden, während ORC2, ORC3, MCM3, CDT1 und CDC45 zwar noch vorhanden waren, jedoch in geringerer Menge als in proliferierenden Zellen. Weiterhin wurde die Menge an Replikationsproteinen in durch Serummangel transient aus dem Zellzyklus ausgetretenen G0-Phase-Zellen und Zellen, die durch Serum reaktiviert wurden, untersucht. Die Replikationsproteine waren in quieszenten C2C12- und 3T3-Zellen gleichermaßen wie in den terminal differenzierten Zellen in verringerter Menge vorhanden. Weiterhin konnte gezeigt werden, dass eine Restimulierung von quieszenten, nicht aber terminal differenzierten Zellen, die erneute Expression von Replikationsproteinen zur Folge hat. Im Rahmen dieser Arbeit wurden Chromatin-Immunpräzipitations-Experimente (ChIP) mit proliferierenden und terminal differenzierten C2C12-Zellen durchgeführt. Eine preRC-Assemblierungsstelle befindet sich im OBR-Bereich der murinen rRNA-Gene von -2519 bis -2152 (Fragment B). In proliferierenden C2C12-Zellen konnte die Bindung von ORC1-5, CDC6, CDT1, MCM3, MCM6, CDC45 und HP1 an Fragment B nachgewiesen werden. Während der terminalen Differenzierung werden ORC1, CDC6, CDT1 und CDC45 von der preRC-Bindungsstelle entfernt, ORC2-5, MCM3, MCM6 und HP1 bleiben an Fragment B gebunden. Die Bindung von preRC-Proteinen an Fragment B sollte durch Electrophoretic Mobility Shift Assays (EMSAs) in vitro detailliert untersucht werden. Dazu mussten zunächst preRC-Proteine nativ aus dem Kernextrakt proliferierender FM3A-Zellen durch Ionenaustausch- und Gelfiltrations-Chromatographie angereichert werden. Proteine in den Fraktionen B4 bis B12 bilden einen DNA-Protein-Komplex mit Fragment B. Die ATP-Abhängigkeit der Bildung des DNA-Protein-Komplexes wurde nachgewiesen. Die Ausbildung des DNA-Protein-Komplexes erfolgt sequenzspezifisch an Fragment B. Durch Zugabe spezifischer Antikörper gegen ORC3 und CDT1 zur Bindungsreaktion konnte die Ausbildung des DNA-Protein-Komplexes reduziert werden. Es konnte gezeigt werden, dass die Bildung des DNA-Protein-Komplexes unabhängig von ATP-Hydrolyse erfolgt und dass Diadenosin-Tetraphosphat (Ap4A) die Bindung von preRC-Proteinen an die DNA nicht signifikant stimuliert. Zur Eingrenzung der preRC-Bindungsstelle wurden sowohl am 5´- als auch am 3´-Ende partiell deletierte B-Fragmente eingesetzt. Mit den um 100 bp verkürzten Fragmenten kann der DNA-Protein-Komplex weiterhin gebildet werden. Deletionen von 200 bp entweder vom 5´- oder 3´-Ende verhindern hingegen die Ausbildung des DNA-Protein-Komplexes. Auf einem 119 bp langen Fragment (-2365 bis -2247), das zentral in Fragment B gelegen ist, kann sich der DNA-Protein-Komplex in einer ATP-stimulierten Weise wiederum ausbilden. Die Analyse dieses Bereiches zeigte, dass sich darin zwei auffällige 9 bp-Sequenzen (CTCGGGAGA) befinden, die im Abstand von 63 bp wiederholt werden (-2343 bis -2335; -2280 bis -2272) und die durch die 200 bp-Deletionen ganz oder teilweise eliminiert wurden. Durch ortsgerichtete Mutagenese mittels PCR wurden innerhalb dieser 9 bp-Wiederholungen die Basen C zu A, T zu G und umgekehrt ausgetauscht. In vier sukzessiven Klonierungen wurden je 4 bp ersetzt (S1 bis S4), wobei die erhaltenen Konstrukte als Ausgangs-DNA für die nachfolgende Klonierung dienten. Die Substitutionen S1, S2 und S3 beeinträchtigten die Ausbildung des DNA-Protein-Komplexes im Wesentlichen nicht. Wurden jedoch 8 bp in beiden 9 bp-Wiederholungen ersetzt (S4), war die Ausbildung des DNA-Protein-Komplexes nahezu vollständig inhibiert. S4 hat außerdem eine leichte reduzierte elektrophoretische Mobilität der proteinfreien DNA-Fragmente zur Folge. Vermutlich stellen die 9 bp-Sequenzen jedoch keine Konsensus-Sequenz für die Bindung der preRC-Proteine per se dar, sondern haben vielmehr Effekte auf die Ausbildung spezifischer Sekundär-Strukturen, die wiederum das Binden der preRC-Proteine an diese Region im OBR der murinen rRNA-Gene erlauben könnten. / One task of this work was to analyse the composition of preRCs in proliferating and terminally differentiated cells with the aim to monitor irreversible changes in the nature of preRCs upon transition from proliferation to differentiation. Murine C2C12 cells were used which can be triggered to become terminally differentiated myotubes by exposure to low mitogen medium. Differentiation was assessed by morphological examination. FACS analyses and BrdU incorporation showed the cessation of dna replication. Fluctuation of replication proteins during terminal differentiation was examined. Same amounts of nuclear and cytoplasmatic extracts, respectively, prepared from proliferating, confluent or differentiating C2C12 cells were resolved by SDS-PAGE. Immunoblot analyses were carried out using specific antibodies. After 132 h in DM ORC1, CDC6, MCM6 and geminin could not be detected in terminally differentiated myotubes at all, whereas ORC2, ORC3, MCM3, CDT1 and CDC45 were detectable, albeit at lower levels than in proliferating myoblasts. Levels of replication proteins in serum starved G0 phase cells and cells which were induced to reenter the cell cycle upon serum readdition, were investigated. Levels of replication proteins decreased in quiescent C2C12 and 3T3 cells, although different proteins were reduced to various extends. Reactivation of quiescent cells, but not terminally differentiated myotubes, resulted in reexpression of replication proteins. Chromatin immunoprecipitation analyses (ChIP) were performed comparing chromatin of proliferating cells to that of differentiated cells. A preRC binding site is localized within the OBR of the murine rRNA genes from position -2519 to -2152 (fragment B) upstream of the transcription start site. The in vivo binding of ORC1-5, CDC6, CDT1, MCM3, MCM6, CDC45 and HP1 to fragment B was observed in proliferating C2C12 cells. During terminal differentiation of C2C12 cells ORC1, CDC6, CDT1 and CDC45 are released. ORC2-5, MCM3, MCM6 and HP1, however, remain bound to fragment B. The removal of essential regulatory replication proteins like ORC1, CDC6, CDT1 and CDC45 from chromatin in terminally differentiated cells might contribute to the establishment and maintenance of an “out-of-cycle” state. One aim of the present work was to further characterize the binding of preRC proteins to fragment B in vitro by electrophoretic mobility shift assays (EMSAs). For that purpose, preRC proteins were enriched from nuclear extracts of proliferating FM3A cells by a combination of ion-exchange and gelfiltration chromatography. Purified proteins of fractions B4 to B12 caused a DNA/protein complex with fragment B. Purified preRC proteins bind exclusively to fragment B. When ORC3 and CDT1 antibodies were added to the DNA/protein binding reaction, formation of the DNA/protein complex was reduced, indicating that these proteins may play a role in formation of this DNA/protein complex. It was shown that this DNA/protein complex is formed independently of ATP hydrolysis and that diadenosine tetraphosphate (Ap4A) does not significantly stimulate binding of preRC proteins to DNA. In order to further narrow down the preRC binding site, EMSAs were performed using fragments shortened by 100 bp and 200 bp, respectively, at the 3´- or 5´-end. The DNA/protein complex is formed with both fragments truncated 100 bp at each end. However, if 200 bp are deleted, no shifts were observed, neither with fragment 5.200 nor with 3.200. On a central 119 bp fragment (-2365 to -2247) the DNA/protein complex is formed in an ATP-stimulated manner. Two conspicuous 9 bp sequence elements, CTCGGGAGA, were observed which are repeated at intervals of 63 bp (-2343 to -2335; -2280 to -2272). The sequence of these elements was altered by introducing C to A, T to G and vice versa substitutions. 4 successive substitutions of 4 bp each were constructed and the constructs were used as template DNA for subsequent mutageneses. Substitutions S1, S2 or S3 did not affect formation of the DNA/protein complex. If, however, 8 bp out of 9 bp in both sequence elements were substituted (S4), formation of the DNA/protein complex is abrogated. A naked S4 DNA fragment migrates distinctly slower than WT and S1-S3 suggesting that the secondary structure of the DNA is altered as a result of nucleotide substitutions. Probably, the 9 bp repeats do not constitute a consensus binding site per se, but rather have effects on formation of specific secondary DNA structures which in turn allow binding of preRC proteins to this region of murine rDNA. Replikation Proteine Replikationsursprung Proliferation Zelldifferenzierung ddc:540
103	The Dragon's Fuel: Developing Chinese-Iranian Cooperation Khorassani, Nader James January 2010 (has links) Thesis advisor: Robert Ross / In recent years, economic and political cooperation between China and Iran has deepened to levels never before reached. This thesis discusses the potentially far reaching implications the development in relations between China and Iran poses for controlling nuclear proliferation, international energy security, and the role the US plays in Middle Eastern and East Asian power politics. Monitoring the Chinese-Iranian relationship is thus important to the US, as its own influence across the globe could potentially be reduced as a result of cooperation between these two nations. With China newly confident following the global financial crisis of 2008, it appears that despite US pressure to stop, China is continuing to deepen its cooperation with Iran in pursuit of its own national interests. / Thesis (BA) — Boston College, 2010. / Submitted to: Boston College. College of Arts and Sciences. / Discipline: Political Science Honors Program. / Discipline: Political Science. China Iran Energy Nuclear Proliferation US
104	Wilson and the bomb : the politics and economics of British nuclear diplomacy, 1964-1970 Gill, David James January 2010 (has links) This thesis explores the British government’s approach to international negotiations concerning nuclear weapons during Harold Wilson’s first two terms of office (1964-1970). It focuses on three distinct but interrelated strands of British nuclear diplomacy: ‘hardware solutions’, the sharing of nuclear weapons between states in the form of a multilateral force; ‘software solutions’, non-physical measures of cooperation, such as consultative and planning arrangements, between alliance members; and a global non-proliferation treaty. In looking at how and why these interrelated policies evolved, this thesis considers party, domestic and international influences on decision-making within the government. It pays particular attention to political and economic events, building on existing diplomatic and strategic accounts of the period. 327
105	Envolvimento da proteína SAM68 na regulação da proliferação celular em tumores de sistema nervoso central / SAM68 involvement in the regulation of proliferation and cellular death in tumors of the central nervous system Leite, Carolina de Seixas Couto 19 March 2018 (has links) Meduloblastoma é o câncer do Sistema Nervoso Central mais comum em crianças entre 0 e 4 anos. Ele é originado de células precursoras neuronais, que falharam em se diferenciar e continuaram a se proliferar. A proteína SAM68 está desregulada em várias linhagens de células de cânceres humanos e é uma proteína que pode estar envolvida em uma ampla gama de vias de sinalização importantes, incluindo metabolismo de RNA, regulação do ciclo celular, apoptose, regulação de splicing e transdução de sinal. Em células-tronco neurais (NSC), níveis elevados de SAM68 levam a uma redução importante na proliferação celular. Contudo, na maioria dos cânceres estudados até o momento, a SAM68 está envolvida com progressão tumoral. Com este trabalho, buscou-se entender o envolvimento de SAM68 na proliferação e morte de células de meduloblastoma. Por meio da análise de expressão transcricional e proteica, do silenciamento de SAM68, análise de apoptose por citometria de fluxo e análise de proliferação por índice mitótico e incorporação de EdU, observou-se que, em linhagens de meduloblastoma, a SAM68 está envolvida com proliferação, mas não com apoptose. Seu funcionamento em meduloblastoma é similar aos resultados obtidos com NCS do que com outros tipos de câncer, visto que o silenciamento dessa proteína favorece a proliferação das células de meduloblastoma. Em vista dos resultados aparentemente conflitantes, tendo um papel mais semelhante a um supressor tumoral, porém sendo altamente expressa em meduloblasoma, sugeriram-se algumas hipóteses, que foram apenas inicialmente testadas neste trabalho, mas precisam ser aprofundadas em trabalhos futuros / SAM68 is considered a prototype of STAR proteins (Signal Transducers and Activators of RNA protein), that are involved in the signal translation and RNA activation. In cancer, the intracellular levels of Sam68 are crucial to the progression of the disease. Recent observations indicate Sam68 with both pro-oncogenic and tumor suppressor activities, depending on the type of cell. Here, we analyzed SAM68 expression by real time PCR and western blot, proliferation of cell with and without SAM68 by mitotic index and incorporation of EdU and cell death by flux cytometry to define the relevance of the presence of SAM68 to cell proliferation and death. We found that proliferation of medulloblastoma cell lines are affected for absent SAM68, but not apoptosis. Because the contrast of an action similar to a tumor suppressor and a high expression level, we hypothesized that the increase of SAM68 levels is important during the neuronal development, regulating splicing variants. Our results allied to some literature data corroborate this hypothesis Cancer Câncer Medulloblastoma Meduloblastoma Proliferação Proliferation
106	Identification and characterization of novel signalling pathways involved in peroxisome proliferation in humans Sadeghi Azadi, Afsoon January 2018 (has links) Peroxisomes represent crucial subcellular compartments for human life and health. They are remarkably dynamic organelles which respond to stimulation by adapting their structure, abundance, and metabolic functions according to cellular needs. Peroxisomes can form from pre-existing organelles by membrane growth and division, which results in peroxisome multiplication/proliferation. Growth and division in mammalian cells follows a well-defined multi-step process of morphological alterations including elongation/remodeling of the peroxisomal membrane (by PEX11β), constriction and recruitment of division factors (e.g. Fis1, MFF), and final membrane scission (by the dynamin-related GTPase Drp1) (Chapter 1). Although our understanding of the mechanisms by which peroxisomes proliferate is increasing, our knowledge on how the division/multiplication process is linked to extracellular signals is limited, in particular in humans. The classical pathway involved in peroxisome proliferation is mediated by a family of ligand-activated transcription factors known as peroxisome proliferator activated receptors (PPARs) (Chapter 1). This project focused on identifying novel signaling pathways and associated factors involved in peroxisome proliferation in humans. In this study, a cell-based peroxisome proliferation assay using the HepG2 cell model with spherical peroxisomal forms has been developed to investigate different stimuli and their ability to induce peroxisome proliferation (Chapters 2 and 3). In this system, peroxisome elongation has been used as the read-out for peroxisome 4 proliferation. We also showed that the number of peroxisomes increased after division of elongated peroxisomes indicating peroxisome proliferation. Different stimuli, such as fatty acids, PPAR agonists and antagonists, have been used in this study. PPAR agonists and antagonists had no stimulatory or inhibitory effect on peroxisome elongation in our assay, suggesting PPAR-independent regulatory processes. However, arachidonic acid and linoleic acid were able to induce peroxisome elongation, whereas palmitic acid and oleic acid were not effective. These findings indicate that general stimulation of fatty acid β-oxidation is not sufficient to induce peroxisome elongation/proliferation in HepG2 cells. Moreover, mRNA expression levels of peroxismal genes have been monitored during a time course in the HepG2 cell-based assay by qPCR. This analysis shows a regulation of expression of peroxins during peroxisome proliferation in human cells and suggests differences in the regulation pattern of PEX11α and PEX11β. In Chapter 4, motif binding sites for transcription factors in peroxisomal genes were analyzed. An initial map of candidate regulatory motif sites across the human peroxisomal genes has been developed (Secondment at the University of Sevilla, Spain with Prof. D. Devos). This analysis also revealed the presence of different transcription factor binding sites in the promoter regions of PEX11α and PEX11β, supporting different regulatory mechanisms. Based on the computational analysis, PEX11β contained a putative SMAD2/3 binding site suggesting a novel link between the canonical TGFβ signaling pathway and expression of PEX11β, a key regulator of peroxisome dynamics and proliferation. 5 Addition of TGFβ to HepG2 cells cultured under serum-free conditions induced elongation/growth of peroxisomes as well as peroxisome proliferation supporting a role for TGFβ signalling in peroxisomal growth and division (Chapter 5). Furthermore, to demonstrate that this induction is through a direct effect of TFGβ on the SMAD binding site found in PEX11β, we performed functional studies using a dual luciferase reporter assay with PEX11β wild type and mutated promoter regions (Secondment at Amsterdam Medical Center, Netherlands with Prof. H. Waterham). Whereas luciferase activity was induced by TGFβ stimulation with the PEX11β wild type promoter, mutation of the SMAD binding site abolished activation. In summary, this study revealed a new signaling pathway involved in peroxisome proliferation in humans and provided a tool to monitor peroxisome morphology and gene expression upon treatment with defined stimuli. Furthermore, I contributed to a study revealing that ER-peroxisome contacts are important for peroxisome elongation (Chapter 6). Our group identified peroxisomal acyl-CoA binding domain protein 5 (ACBD5), ACBD4 and VABP as a molecular linker between peroxisomes and the ER (Costello et al., 2017). Motif analysis of ACBD4 and ACBD5 promoter regions revealed that unlike PEX11β, these genes do not contain a binding site for SMAD, suggesting they are not co-regulated. Also, ACBD4 and ACBD5 do not share any common transcription factor binding sites suggesting different regulation. An interesting binding motif within the ACBD4 promoter is a glucocorticoid receptor binding site. In our study, we found potential glucocorticoid response elements (GRE) in other peroxisomal genes encoding β-oxidation enzymes. This may suggest an important role for glucocorticoid receptors in activating expression of peroxisomal genes resulting in the stimulation of fatty acid breakdown and energy production. 500
107	Understanding tumour suppressive responses upon inhibition of ribosome maturation Pantazi, Asimina January 2018 (has links) Ribosome biogenesis is an essential biological process that is required for cell division and growth. Cancer cells alter their physiology in order to meet their excessive growth demands and therefore maintain abnormal metabolism and homeostasis. Under normal conditions, ribosome biogenesis is tightly regulated to maintain adequate ribosomal content of the cell. However, several oncogenes promote this process and elevated ribosome biogenesis is often found in cancer cells, where it can support the high biosynthetic demand of these cells. Hence, ribosome biogenesis is a process that might provide candidate targets for therapeutic intervention. The main aim of this research was to assess whether inhibition of late stage biogenesis of the 60S ribosomal subunit would result in tumour suppressive responses in normal and cancer cells. We focused upon two GTPases, EFL1 and LSG1, that catalyse the last two cytoplasmic reactions in the maturation of the 60S subunit. We observed that RNAi-based silencing of the GTPases in human lung fibroblasts triggered growth arrest and senescence, which was mediated by the p16 and p53 pathways. Inhibition of these pathways revealed that loss of p53 could bypass the senescence response. However, when cells were plated at low density, knockdown of LSG1 conferred a tumour suppressive response, even in the absence of p53. Knockdown of LSG1 in MCF-10A mammary epithelial cells that lack the p16 locus also induced a robust senescence response and this was also observed in transformed derivatives of MCF-10A cells. Preliminary data obtained in a 3D mammosphere culture model also revealed that inhibition of 60S maturation could elicit an antiproliferative response. Taken together, these data indicate that at least some cancer cells would be responsive to a therapy based upon inhibition of 60S subunit biogenesis. We further characterised the senescence response that was obtained through knockdown of LSG1 by performing gene expression analysis. This revealed a minimal Senescence-Associated Secretory Phenotype (SASP) that was restricted to members of the TGF-β family and lacked the canonical pro-inflammatory cytokines and chemokines that are found in the SASP of cells undergoing oncogene-induced senescence (OIS). Surprisingly, we also observed a dramatic increase in expression of multiple genes in the cholesterol biosynthesis pathway, although inhibition of this pathway indicated that cholesterol biosynthesis was not required for the senescence response. Further insight into the mechanisms of induction of the ribosomal stress senescence response was sought through pilot CRISPR screen and reverse phase protein array (RPPA) analyses. These revealed some interesting leads that will direct future studies.
108	Studying the cell cycle status during haematopoietic stem cell development Batsivari, Antoniana January 2016 (has links) In adults blood stem cells, called haematopoietic stem cells (HSC), give rise to all blood cells throughout life. The origin and biology of HSCs during embryo development has been an intensely studied topic. Definitive HSCs are generated intra-embryonically in the aorta-gonad-mesonephros (AGM) region of the mid-gestation embryo. Recent research revealed that HSCs emerge through multistep maturation of precursors: proHSC → preHSC I → preHSC II → definitive HSC (dHSC). A hallmark of the HSC emergence is the appearance of intra-aortic haematopoietic clusters that are considered to be sites of haematopoiesis. It was shown in vitro that the E11.5 HSCs are slowly cycling compared to progenitor cells. However, cell cycle status and its role during early HSC development remain unclear. Here I used Fucci transgenic mice that enable in vivo visualisation of the cell cycle. Functional and phenotypic analysis showed that in the early embryo the proHSC precursors cycle slowly, whereas committed progenitors are actively cycling. Meanwhile the preHSC I precursors arising in the E10.5 AGM region become more rapidly cycling. They are located closer to the luminal cavity of the dorsal aorta, while their ancestors, the proHSCs, are slowly cycling and are located at base of the clusters. Furthermore, in the mid-gestation embryo the preHSC I become slowly cycling and are closer to the endothelial lining of the aorta, while they give rise to the actively cycling preHSC II that are located to the luminal area of the artery. Finally, definitive HSCs are mainly slowly cycling at this stage like their foetal liver counterparts. As expected, HSCs in adult bone marrow are mainly dormant. The data suggest that transition from one precursor type to another is accompanied by distinct changes in cell cycle profile and that HSCs become progressively quiescent during development. To test the role of cell cycle in HSC maturation, we used inhibitors against signalling pathways known to play important roles in HSC development. Notch inhibitor affected the cell cycle status of haematopoietic precursors, by possibly promoting them to rapidly proliferate and potentially blocking the maturation from preHSC I to preHSC II precursors. Shh antagonist had the opposite effect and enhanced the HSC activity from the preHSC I precursors. Altogether these results suggest that the cell cycle status plays an important role in the HSC development. A better understanding of the molecules that control this process will allow us to optimize the culture condition for generation of functional HSCs in the laboratory.
109	Gene Expression Analysis of the Perinatal Heart and the Identification of MiR-205 as a Regulator of Cardiomyocyte Maturation Weldrick, Jonathan 06 November 2019 (has links) Background: Extensive research has characterized the embryonic development of a four-chambered heart in mammals. After birth, mammalian cardiomyocytes undergo a transition characterized by a final cell cycle with nuclear division (karyokinesis) in the absence of cytoplasmic division (cytokinesis), generating mature binucleated cardiomyocytes. Downregulation of pro-proliferative signaling and epigenetic changes permanently ‘lock’ cardiomyocytes out of the cell cycle, and nearly all subsequent growth is accomplished via cellular hypertrophy. Before this transition, cardiomyocytes exhibit robust proliferative potential, but afterward are unable to divide. Rationale & Hypothesis: Recent evidence suggests that non-coding RNAs influence early neonatal cardiac development and hypertrophy. We hypothesize that transient expression of regulatory miRNAs may impact the neonatal heart’s transition from proliferation to hypertrophy. Results: Cardiac mRNA and miRNA were systematically analyzed using microarrays to identify targets that were transiently and significantly changing after birth. Through our analysis we identified three primary ontogenies significantly changing: metabolism, extracellular matrix remodeling, and cell cycle regulation. Global analysis of micro-RNA expression patterns during perinatal heart development identified miR-205 as a novel candidate for modulating cardiomyocyte maturation. We observed miR-205 expression undergoing a 20-fold increase from 1-day postpartum (1D) to 5D, returning to prenatal levels by 10D. It is expressed in cardiomyocytes of the epicardium, the primary location of fetal cardiomyocyte proliferation. MiR-205 targets two important cell cycle regulators: Pten phosphatase of the PI3K/AKT pathway, and Yap1 in the Hippo pathway. Both pathways have proven to be essential for proper heart development. Previous research showed that germline deletion of miR-205 results in death at 5D. To define its role in the heart, we generated an αMHC-Cre postnatal miR-205 cardiac-specific deletion mouse model. Systematic characterization of miR-205-/- hearts confirmed miR-205’s interaction with Pten and Yap1 by western blot and immunohistochemistry. Postnatal miR-205-/- hearts exhibit Hippo pathway dysregulation, increased cardiomyocyte number, more actively cycling cardiomyocytes beyond 7D, and no difference in binucleation. We also generated a DOX-inducible cardiac-specific miR-205 over-expression mouse model. Perinatal miR-205OE hearts expedited the transitional period, with more cardiomyocytes present at 5D and no difference at 14D. These hearts show increased Hippo signaling immediately after birth, suggesting compensatory mechanisms to ensure sufficient cardiomyocyte number. Conclusions: Our data strongly supports miR-205 as a regulator of cardiomyocyte maturation in the neonatal heart, by promoting the neonatal cardiomyocyte transition from hyperplastic to hypertrophic growth. In turn, miR-205’s antiproliferative properties originate in part from suppressing the expression of Pten and Yap1. Neonatal Development MiRNA Cardiac Hippo Proliferation
110	Einfluss und Wirkung des HDAC-Inhibitors LBH589 auf Proliferation und Differenzierung der kolorektalen Karzinomzelllinien SW480 und SW620 / Influence and Effect of HDAC-Inhibitor LBH589 on Proliferation and Differentiation of colon cancer cell lines SW480 and SW620 Eller, David Michael January 2011 (has links) (PDF) Zahlreiche Studien schreiben Histondeacetylase-Inhibitoren einen Anti-Tumor-Effekt auf verschiedene hämatologische und solide Tumoren durch Apoptoseinduktion, vermehrte Zelldifferenzierung und verminderte Zellproliferation zu. Als Mechanismus wird eine Einflussnahme auf die Genexpression durch Modulation von Histondeacetylasen und deren Auswirkung auf den Acetylierungsstatus von Histonen und Nicht-Histon-Proteinen angenommen. Ziel dieser Arbeit war es, die Auswirkungen des Histondeacetylase-Inhibitors LBH589 auf Proliferation und Differenzierung von Kolonkarzinomzellen und dessen Metastasenzellen in Zellkulturexperimenten zu untersuchen. Die Untersuchungen wurden an Zellen der Zellkulturlinien SW480 (kolorektales Karzinom) und SW620 (Metastase des kolorektalen Karzinoms) durchgeführt. Für die Zellproliferation wurden die Zellen nach entsprechender Vorbehandlung in einer Neubauer-Zellzählkammer ausgezählt. Zur Feststellung des Verlaufs der Zelldifferenzierung diente die Bestimmung der Intestinalen Alkalischen Phosphatase als Marker. Unter LBH589-Inkubation kam es zu einer Hemmung der Zellproliferation sowohl bei SW480-Zellen als auch bei SW620-Zellen. Allerdings ergab sich kein signifikanter Unterschied bei der Auswertung der Kontrolllösungen mit jeweils äquimolaren Mengen DMSO. Daher konnte dem HDAC-Inhibitor LBH589 im Rahmen dieser Arbeit kein sicherer Effekt auf die Inhibition der Zellproliferation zugeschrieben werden. LBH589 hatte keinen nachweisbaren relevanten Einfluss auf die Differenzierung von Zellen der beiden Zelllinien. Allenfalls konnte ein leicht hemmender Einfluss auf die Zelldifferenzierung gezeigt werden, der jedoch nicht signifikant ausfiel. Weitere Untersuchungen sind anzustreben, um den Verlauf der Zellproliferation und weiterer Differenzierungsmarker unter dem Einfluss von LBH589 sowie äquimolaren Mengen DMSO detaillierter zu charakterisieren. Zukünftige Arbeiten zu Histondeacetylase-Inhibitoren und deren Effekt auf Zellen des kolorektalen Karzinoms, sowie Histondeacetylase-Inhibitoren in der Kombinationstherapie von kolorektalen Tumoren sind sicher sinnvoll. / A lot of studies have shown an anti-tumor-effect of histone deacetylase inhibitors on various hematological and solid tumors by induction of apoptosis, induction of differentiation an inhibition of proliferation. These effects are supposed to be caused by influencing gene expression through modulation of histone deacetylases and the acetylating status of histones and non-histone-proteins. In this study the influence of the histone deacetylase inhibitor LBH589 on proliferation and differentiation in colon cancer cells and its metastasis was analysed. The studies were done with cells from cell culture lines SW480 (colorectal carcinoma) and SW620 (metatasis of the colorectal carcinoma). For proliferation the cells were counted in a Neubauer-chamber and for differentiation the intestinal alkaline phosphatase was determined. Under the influence of LBH589 an inhibition of proliferation was shown in both cell lines. But there was no significant difference to the results shown by the control substance of equimolar amounts of DMSO. So there could no certain effect be related to LBH589 on cell inhibition. LBH589 has shown no influence on differentiation in both cell lines, at the most there was a light non-significant inhibition on differentiation. Further studies are needed to characterize the influence of LBH589 and equimolar amounts of DMSO on proliferation and other markers of differentiation. Dickdarmkrebs Proliferation Zelldifferenzierung Histon-Deacetylase ddc:610

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