Global ETD Search

71	mRNA Cap Methylation in Pluripotency and Differentiation Grasso, L., Suska, O., Davidson, L., Gonatopolous-Pournatzis, T., Williamson, Ritchie, Wasmus, L., Wiedlich, S., Peggie, M., Stavridis, M.P., Cowling, V.H. 02 August 2016 (has links) Yes / The mRNA cap stabilizes transcripts and recruits processing and translation factors. Grasso et al. report that the mRNA cap methyltransferase RNMTRAM is highly expressed in embryonic stem cells and is important for pluripotency-associated gene expression. Repression of RAM occurs during neural differentiation and is important for expression of neuralassociated genes. / Wellcome Trust mRNA cap methyltransferase RNMT-RAM Gene expression Neural-associated genes
72	Glycine Betaine and Proline Betaine Specific Methyltransferases of the MttB Superfamily Picking, Jonathan William 30 September 2019 (has links) No description available. Biochemistry Microbiology corrinoid-dependent methyltransferase quaternary amine proline betaine MtgB MtpB MttB superfamily microbial metabolism corrinoid methyltransferase
73	Regulation der Enzymaktivität der Restriktionsendonuklease EcoRII durch Autoinhibition Szczepek, Michal 25 February 2011 (has links) DNA-Restriktions und -Modifikationssysteme sind in Prokaryoten weit verbreitet und stellen einen wirksamen Schutz gegen das Eindringen mobiler genetischer Elemente dar. Sie kodieren für eine Restriktionsendonuklease (REase) und eine DNA-Methyltransferase (MTase) gleicher Nukleotidsequenz Spezifität. Die MTase methyliert die zelluläre DNA und schützt sie durch diesen epigenetischen Marker vor der Wirkung der REase. Die REase verhindert die Aufnahme fremder, unmethylierter DNA durch sequenzspezifische Spaltung. EcoRII ist eine REase, die für die effiziente DNA-Spaltung mindestens zwei Kopien ihrer Erkennungssequenz benötigt. Untersuchungen der EcoRII-Struktur und -Funktion offenbarten, dass das Protein aus zwei stabilen Domänen aufgebaut ist, wobei die N-terminale Domäne wie ein Repressor die C-terminale Domäne sterisch blockiert und deren katalytische Aktivität verhindert. Dieser als Autoinhibition bezeichnete und von eukaryotischen Proteinen gut bekannter Regulationsmechanismus wurde erstmals für eine REase vorgeschlagen. In dieser Arbeit konnten wir die Regulation der EcoRII-Enzymaktivität durch Autoinhibition auf molekularer Ebene beweisen. Wir identifizierten ß-Strang 1 (B1: 18YFVYIKR24) und a-Helix 2 (H2: 26SANDT30) als essenzielle inhibitorische Elemente der N-terminalen Domäne des EcoRII-Moleküls. Die Deletion von B1 oder H2 führte zu einer vollständigen Aufhebung der Autoinhibition. Darüber hinaus ist es uns gelungen, die 3D-Röntgenkristallstruktur von EcoRII mit 1,9 Å zu lösen und mit Hilfe von Computermodellen neue Interaktionen des Enzyms mit der DNA „minor groove“ zu beschreiben sowie eine Mg2+-Bindungstasche zu charakterisieren. Die Untersuchung der EcoRII-MTase durch limitierte Proteolyse zeigte, dass das Enzym in Abhängigkeit von der DNA-Sequenz und von seinen Kofaktoren, DNA auf unterschiedliche Weise binden kann. Kristallisierungsversuche der EcoRII-MTase in Anwesenheit der hemi-methylierten DNA-Erkennungssequenz ergaben erste diffraktierende Kristalle, deren Qualität optimiert werden muss und zur Strukturlösung führen soll. / Restriction and modification systems are wide spread among prokaryotes and pre-sent an efficient protection against invasion of mobile genetic elements. In general, they code for a restriction endonuclease (REase) and a DNA-methyltransferase (MTase) of the same DNA specificity. The MTase methylates the cellular DNA and by this epigenetic marker protects it against the action of the REase. The REase pre-vents the entry of foreign unmethylated DNA by site-specific cleavage. EcoRII is an REase which needs at least two copies of the recognition sequence for efficient cleavage. Investigations of the EcoRII structure and function revealed that the pro-tein is composed of two stable domains: the N-terminal domain acts as a repressor by sterically blocking the C-terminal domain and thereby inhibiting its catalytic activity. This regulatory mechanism is known as autoinhibition and has been often described for eukaryotic proteins, but for the first time was proposed for a REase. In this work, we verified the regulation of the EcoRII enzyme activity by autoinhibition at the molecular level. We identified ß-strand 1 (B1: 18YFVYIKR24) and a-helix 2 (H2: 26SANDT30) as essential inhibitory elements of the N-terminal domain. Deletion of B1 or H2 caused a complete abolishment of the autoinhibition. Fur-thermore, we were able to solve the 3D-X-ray crystal structure of EcoRII at 1.9 Å. Based on computer modelling we discovered new interactions between EcoRII and the DNA minor groove and defined the position of the Mg2+ binding pocket. Investigations of the EcoRII MTase by limited proteolysis showed that the enzyme binds DNA depending on DNA sequence and cofactors in different manners. Crystallography experiments with EcoRII MTase in the presence of hemimethylated recognition site DNA showed for the first time diffracting crystals which need further optimisation to create high quality crystals which allow structure solution. Kristallstruktur Autoinhibition EcoRII Methyltransferase Restriktions-endonuklease crystal structure autoinhibition EcoRII methyltransferase restriction enzyme 570 Biowissenschaften, Biologie 32 Biologie WG 4050 ddc:570
74	Duplex-Oligonukleotide mit C-nukleosidisch gebundenen Basensurrogaten und Binder bakterieller DNA-Methyltransferasen Hainke, Sven 10 February 2010 (has links) Die hydrolysestabile C-C-Bindung von Nukleosiden, deren Nukleobase über ein aromatisches oder methylen-verbrücktes Kohlenstoffatom an Ribose oder 2-Desoxyribose gebunden ist, ermöglicht die Synthese von neuartigen Strukturen und Eigenschaften, die bei N-Nukleosiden nicht stabil oder nicht gegeben wären. In dieser Arbeit wurde die die Cuprat-vermittelte Glycosylierung und die Friedel-Crafts-Alkylierung als Methoden zur Darstellung von Desoxyribose-basierenden C-Nukleosiden weiterentwickelt. Die Cuprat-vermittelte Glycosilierung ermöglichte die Synthese von C-Nukleosiden in bis zu 93% Ausbeute, wenn Grignard-basierende Normant-Cuprate verwendet wurden. Die Verwendung Organolithium-basierender Gilman-Cuprate war ebenfalls möglich. In Gegenwart von Sauerstoff wurden O-Glycoside isoliert in über 80 % Ausbeute isoliert. Mit den C-Nukleosiden wurden modifizierte Oligonukleotide, die als potentiell verbesserte Binder an M.TaqI und E.coli Dam dienen, dargestellt. Nach ihrer Charakterisierung über Schmelzwerte und Fluoreszenzeigenschaften wurde diese an die Arbeitsgruppe von Prof. Elmar Weinhold weitergereicht und dort erfolgreich als optimierte Binder an an M.TaqI und E.coli Dam getestet. Oligonukleotide, die ein oder mehrere 1,1-Binaphthyl-Chromophore als einen neuen Typus eines torsionsflexiblen Farbstoffes enthalten, wurden untersucht. Die Einführung mehrerer aufeinander folgender Binaphthyle führte zu einer thermodynamischen Stabilisierung von Duplex-Oligonukleotiden. Die geringe Neigung Binaphthyls zur Selbstlöschung bewirkte dabei einen starken Anstieg der Fluoreszenz. / The stable C-C-bond of ncleosides, whose nucleobase is attached to the ribose or 2-deoxyribose via an aromatic or methylen-bridged carbon atom, is stable to hydrolyses. This allows the synthesis of new structures and properties, which would not be available in N-nucleosides. In this work, a cuprate-mediated glycosilation and the Friedel-Crafts-alkylation as methods for the preparation of doxyribose-based C-nucleosides were developed. The cuprate-mediated glycosilation allowed the synthesis of C-nucleosides in up to 93 % yield, when Grignard-based Normant-Cuprates were used. The use of Organolithium-based Gilman-Cuprates was also possible. In the presence of oxygen O-glycosides were isolated in over 80 % yield. With the C-nucleosides modified oligonucleotides, which serve as potentially improved binders of the DNA-methyltransferases M.TaqI und E.coli, were prepared. After their charakterisation via melting point measurements and fluorescence properties, the oligonucleotides were given to the working group of Prof. Elmar Weinhold and successfully tested as improved binders of the DNA-methyltransferases M.TaqI und E.coli. Oligonucleotides, which contain one or multiple 1,1-binaphthyles as a new type of a torsionally flexible chromophore, were charakterised. The incorporation of several successive binaphthyls led to a thermodynamical stabilisation of the duplex-oligonucleotides. The low tendency of the Binaphthyl for self-quenching caused a remarkable increase of the fluorescence. C-Nukleoside Oligonukleotide Cuprat-vermittelte Synthese DNA-Methyltransferase-Binder C-nucleosides oligonucleotides cuprate-mediated synthesis DNA-methyltransferase-binders 540 Chemie 30 Chemie ddc:540
75	Regulation of DNA methylation during development Aguirre-Arteta, Ana Maria 28 June 2000 (has links) Die DNA Methyltransferasen sind verantwortlich für die spezifische Methylierung von DNA-Basen. Mehrere DNA Methyltransferasen sind bekannt, wobei die Dnmt1 das hauptsächlich vorkommende Enzym ist. Bei Säugetieren korreliert die DNA-Methylierung mit der Genaktivität und ist essentiell für die Embryonalentwicklung. Eine beeinträchtigte Funktion oder Verfügbarkeit des Enzyms kann zu pathologisch veränderten Zuständen führen. Die Regulation der Dnmt1 und die damit verbundene Bedeutung bei der Entstehung von Krankheiten ist bisher nur unvollständig untersucht. In der Frühphase der Embryonalentwicklung von Säugetieren ändert sich das Methylierungsmuster des Genoms dramatisch. In zeitlich aufeinander folgenden Phasen wird die DNA demethyliert (Verlust der Methylgruppen) und neu methyliert (De-Novo Methylierung). Die Hypothese dieser Arbeit ist, dass verschiedene Isoformen der Dnmt1 in spezifischen Entwicklungsstadien exprimiert werden und zu Veränderungen des Methylierungsmusters der DNA beitragen. Um diese Regulation zu untersuchen, wurde die Struktur der Maus Dnmt1-Gens bestimmt. Außerdem wurde in verschiedenen Gewebetypen die Transkriptionsgröße und die Transkriptionsintensität der mRNA mit Hilfe von Northern-Blots quantifiziert. Mit diesen Experimenten konnte im Hoden- und Skelettmuskelgewebe ein längeres Dnmt1-Transkript als in anderen Geweben identifiziert werden. Dieses neue Dnmt1-Transkript wurde mit Hilfe von RT-PCR und RACE-Techniken kloniert und ist in beiden Geweben identisch. Es unterscheidet sich auf DNA-Ebene in der Sequenz des 5'-Endes von der bisher bekannten Form der Dnmt1 und besitzt einen anderen Startpunkt für die Transkription. Darüber hinaus besitzt das neue Dnmt1-Transkript ein 800 Basenpaar großes erstes Exon, welches sich von dem des bekannten Dnmt1-Transkripts unterscheidet. Die spezifische zelluläre Lokalisation des neuen Transkripts wurde mit Hilfe der In-Situ-Hybridisierung analysiert. Mit dieser Technik wurde das alternative Transkript in stärker spezialisierten, haploiden spermatogenen Zellen (Spermatiden) und zu einem geringen Maß im Skelettmuskel nachgewiesen. Während der Differenzierung von Muskelzellen wurde eine verminderte Expression des bereits bekannten mRNA-Transkripts und eine verstärkte Expression des neu identifizierten mRNA-Transkripts festgestellt. Obwohl die mRNA der alternativen Isoform verschiedene, kurze offene Leserahmen enthält, welche die Translation eines spezifischen Dnmt1 Proteins verhindern könnten, wurde durch Immunofluoreszenz- und Western-Blot Analysen ein Translationsprodukt nachgewiesen. Nach den hier aufgezeigten Ergebnissen werden alternative Dnmt1 Isoformen in vivo exprimiert, welche eine aktive Rolle bei der Regulation der DNA-Methylierung spielen könnten. / DNA methyltransferases (DNA MTases) are enzymes responsible for DNA methylation (transfer of methyl groups to a base in the DNA) and are vital for the development of mammals. Several MTases have been identified in eukaryotes but the most abundant is Dnmt1. Furthermore, many pathological conditions are often attributed to an altered availability or function of this enzyme, however the understanding of the regulation of Dnmt1 and the concomitant relationship to diseases is far from being complete. In mammals the methylation of DNA correlates with gene activity, and methylation patterns change dramatically during early development when the genome of the mammalian embryo undergoes consecutive waves of demethylation (loss of methylation) and de novo methylation (methylation of DNA sites that have not been previously methylated). The hypothesis of this study was that alternative Dnmt1 isoforms are expressed at specific developmental stages and thus contribute to changes in the DNA methylation pattern. To study this regulation the structure of the Dnmt1 gene was determined. In this work, the tissue distribution and abundance of Dnmt1 mRNA was analyzed by Northern blot and a new, longer transcript was identified that is present in testis and skeletal muscle tissue. The novel isoform was cloned by a combination of RT-PCR and RACE techniques and found to be identical in both tissues. This new isoform differs from the ubiquitous cDNA in the 5' end, utilizing a new transcriptional start site and an 800 bp long alternative first exon. The cellular localization of this new transcript was determined by in situ hybridization and found to be present in the more specialized haploid spermatogenic cells, spermatids and at lower level in skeletal muscle. During muscle differentiation, the ubiquitous isoform is downregulated while the alternative isoform is upregulated. Although this mRNA codes for several short upstream ORFs which could prevent translation of the Dnmt1-specific ORF, it was found by immunofluorescence and Western blot analyses that this transcript can be translated in vivo producing a shorter Dnmt1 protein. The results shown here indicate that alternative Dnmt1 isoforms are expressed in vivo and might play an active role in the regulation of DNA methylation. DNA methyltransferase Dnmt1 methylierung isoform DNA methyltransferase Dnmt1 methylation isoform 570 Biowissenschaften, Biologie 32 Biologie WD 5060 WD 5360 ddc:570
76	Humane Thiopurin-S-Methyltransferase (TPMT): Neue Methode zum Mutationsscreening und Untersuchung zum Genotyp-Phänotyp-Zusammenhang / Humane Thiopurin-S-Methyltransferase (TPMT): Neue Methode zum Mutationsscreening und Untersuchung zum Genotyp-Phänotyp-Zusammenhang Barthoff, Tim 02 October 2012 (has links) No description available. 610 Medizin, Gesundheit MED 000 Medicine Thiopurin-S-methyltransferase Gene-scanning High-Resolution Melting Thiopurin-S-methyltransferase Gene-scanning High-Resolution Melting 44.46
77	Tagging methods as a tool to investigate histone H3 methylation dynamics in mouse embryonic stem cells Ciotta, Giovanni 20 July 2011 (has links) (PDF) Covalent modification of histones is an important factor in the regulation of the chromatin structure implicated in DNA replication, repair, recombination, and transcription, as well as in RNA processing. In recent years, histone methylation has emerged as one of the key modifications regulating chromatin function. However, the mechanisms involved are complex and not well understood. Histone 3 lysine 4 (H3K4) methylation is deposited by a family of histone H3K4 methyltransferases (HMTs) that share a conserved SET domain. In mammalian cells, six family members have been characterized: Setd1a and Setd1b (the mammalian orthologs of yeast Set1) and four Mixed lineage leukemia (Mll) family HMTs, which share limited similarity with yeast Set1 beyond the SET domain. Several studies demonstrated that the H3K4 methyltransferases exist as multiprotein complexes. To functionally dissect H3K4 methyltransferase complexes, GFP tagging of the core subunit Ash2l and the complex-specific subunits Cxxc1 and Wdr82 (Setd1a/b complexes) Men1 (Mll1/2 complexes), and Ptip (Mll3/Mll4 complexes), was used. The fusion proteins were successfully expressed in mouse embryonic stem cells (ES cells), analyzed by confocal microscopy, Mass Spectrometry (MS) and ChIP-seq. Ptip was the only subunit able to bind mitotic chromatin. Additionally, both Ptip and Wdr82 were found to associate with cell cycle regulators, suggesting a possible role of the two proteins or respective complexes in cell cycle regulation. Mass Spectrometry revealed that Wdr82 and Ptip interact with members of he PAF complex, and ChIP-seq showed that Wdr82, Cxxc1 and Ptip positively modulate pluripotency genes. Thus, Setd1a/b and Mll3/4 complexes might act together in the regulation of embryonic stem cells identity. Protein pull downs identified at least one new Setd1a/b interactor, Bod1l that is orthologous to the yeast protein Sgh1, a component of the Set1C complex. Furthermore, our MS and ChIP-seq data suggested that only Mll2 complex binds to bivalent promoters, wheras Mll2 and Setd1a complexes might function together in a set of promoters. Tag GFP H3K4 methyltransferase ChIP-seq Massenspektrometrie Tag GFP H3K4 methyltransferase ChIP-seq Mass Spectrometry ddc:570 rvk:WE 2000 rvk:VG 9800
78	Étude structurale de l’histoneméthyltransférase « CARM1 » et de ses complexes biologiquement significatifs : des structures 3D vers la conception rationnelle de composés à action pharmacologique / Structural study of CARM1 a histone methyltransferase and its biologically significant complexes : from 3D structures to rational conception of pharmacologically active compounds Mailliot, Justine 19 April 2013 (has links) Les "protéine arginine méthyltransférases" (PRMT) sont impliquées dans de nombreux processus cellulaires : transcription, maturation et transport des ARN, traduction, transduction du signal, réplication et réparation de l'ADN, et apoptose. Différents travaux ont montré que des dérégulations de ces mécanismes impliquant les PRMT peuvent induire certains cancers, faisant de ces enzymes de nouvelles cibles potentielles en chimiothérapie. Il s’avère donc crucial de comprendre le mode d’action des PRMT à l’échelle atomique, à la fois au niveau fondamental et pour le développement de nouveaux médicaments. Les travaux décrits ici s’intéressent à la protéine PRMT4/CARM1 et s’appuient sur des études structurales par bio-cristallographie, pour comprendre les mécanismes de la réaction de méthylation catalysée par CARM1 et découvrir des inhibiteurs spécifiques, mais aussi sur des études en solution, pour caractériser l’interaction entre CARM1 et ses substrats. / Protein arginine methyltransferases (PRMTs) are involved in several cellular mechanisms: transcription, RNA maturation and transport, translation, signal transduction, DNA replication and repair, and apoptosis. Different studies showed that deregulation of those mechanisms involving PRMTs can induce some cancers, making these enzymes new potential targets for chemotherapy. It is therefore crucial to understand the mode of action of PRMTs at the atomic scale, both at the fundamental level and for the development of new drugs. The studies described here focus on PRMT4/CARM1 and rely on structural studies by bio-crystallography, in order to understand the methylation mechanisms catalyzed by CARM1 and to discover specific inhibitors, but also on in vitro studies, to characterize the interaction between CARM1 and its substrates. CARM1 PRMT Biologie structurale CARM1 Nuclear receptor coactivator PRMT Structural biology 572.8
79	Tagging methods as a tool to investigate histone H3 methylation dynamics in mouse embryonic stem cells Ciotta, Giovanni 20 May 2011 (has links) Covalent modification of histones is an important factor in the regulation of the chromatin structure implicated in DNA replication, repair, recombination, and transcription, as well as in RNA processing. In recent years, histone methylation has emerged as one of the key modifications regulating chromatin function. However, the mechanisms involved are complex and not well understood. Histone 3 lysine 4 (H3K4) methylation is deposited by a family of histone H3K4 methyltransferases (HMTs) that share a conserved SET domain. In mammalian cells, six family members have been characterized: Setd1a and Setd1b (the mammalian orthologs of yeast Set1) and four Mixed lineage leukemia (Mll) family HMTs, which share limited similarity with yeast Set1 beyond the SET domain. Several studies demonstrated that the H3K4 methyltransferases exist as multiprotein complexes. To functionally dissect H3K4 methyltransferase complexes, GFP tagging of the core subunit Ash2l and the complex-specific subunits Cxxc1 and Wdr82 (Setd1a/b complexes) Men1 (Mll1/2 complexes), and Ptip (Mll3/Mll4 complexes), was used. The fusion proteins were successfully expressed in mouse embryonic stem cells (ES cells), analyzed by confocal microscopy, Mass Spectrometry (MS) and ChIP-seq. Ptip was the only subunit able to bind mitotic chromatin. Additionally, both Ptip and Wdr82 were found to associate with cell cycle regulators, suggesting a possible role of the two proteins or respective complexes in cell cycle regulation. Mass Spectrometry revealed that Wdr82 and Ptip interact with members of he PAF complex, and ChIP-seq showed that Wdr82, Cxxc1 and Ptip positively modulate pluripotency genes. Thus, Setd1a/b and Mll3/4 complexes might act together in the regulation of embryonic stem cells identity. Protein pull downs identified at least one new Setd1a/b interactor, Bod1l that is orthologous to the yeast protein Sgh1, a component of the Set1C complex. Furthermore, our MS and ChIP-seq data suggested that only Mll2 complex binds to bivalent promoters, wheras Mll2 and Setd1a complexes might function together in a set of promoters. info:eu-repo/classification/ddc/570 ddc:570
80	ISOLATION AND CHARACTERIZATION OF A SECOND PROTEIN L-ISOASPARTYL METHYLTRANSFERASE GENE IN ARABIDOPSIS THALIANA Xu, Qilong 01 January 2004 (has links) Conversion of aspartate and asparagine residues to isoaspartate is a prevalent covalent protein modification in cells. The accumulation of these altered residues can lead to the loss of protein function and the consequent loss of cellular function. The L-ISOASPARTATE METHYLTRANSFERASE (EC 2.1.1.77) (PIMT) iteratively methylates abnormal isoaspartyl residues leading to conversion to L-aspartate, thereby mitigating the injurious effects of aging. Arabidopsis thaliana is unique among eukaryotes studied to date in that it possesses two genes (At3g48330 (PIMT1) and At5g50240 (PIMT2)) encoding PIMT. The PIMT2 gene exhibits a complex transcriptional control involving different transcriptional initiation sites and 5'- and 3'- alternative splice site selection in the first intron. Varying the transcriptional initiation site results in alternative targeting of the PIMT2 proteins thus produced to: 1) the nucleus, or 2) the cytoplasm, while PIMT1 is cytosolic. Inclusion of a 51 nucleotide 5 alternatively spliced sequence with or without a nine nucleotide 3 alternatively spliced sequence dramatically alteres the subcellular protein localization from the cytoplasm and around the chloroplast to inside the chloroplast. All recombinant PIMT2 isoform tested exhibit PIMT activity, although solubility varied among them. Multiplex RT-PCR was used to establish PIMT1 and PIMT2 transcript presence and abundance, relative to -TUBULIN, in various tissues and under a variety of stresses imposed on seeds and seedlings. PIMT1 transcript is constitutively present but can increase, along with PIMT2, in developing seeds presumably in response to increasing endogenous ABA. Transcript from PIMT2 also increases in establishing seedlings due to exogenous ABA application or applied stress presumably through an ABA-dependent pathway. Furthermore, Cleaved Amplified Polymorphic Sequence analysis of the PIMT2 amplicons has shown that the ratio among the splicing variants alters upon ABA application, implicating a role for the spliceosome or differential RNA stability in orchestrating the plant's response to stress. T-DNA insertional mutants of both genes were isolated but no obvious phenotype has been identified. The double mutant has been generated and will be evaluated.

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