Global ETD Search

151	The role of poly (ADP-ribose) polymerase-1 inhibitors : prevention of non glutathione-dependent carbon tetrachloride-induced hepatotoxicity Grivas, Paul Christopher. January 2007 (has links) Dissertation (Ph.D.)--University of South Florida, 2007. / Title from PDF of title page. Document formatted into pages; contains 141 pages. Includes vita. Includes bibliographical references.
152	Caracterização de cepas de Escherichia coli contendo diferentes alelos rpoS. / Characterization of Escherichia coli strains carrying different rpos alleles. Heloisa Filus Galbiati 12 August 2011 (has links) A bactéria Escherichia coli é encontrada em diversos habitats e deve estar preparada para sobreviver e crescer em condições desfavoráveis. A adaptação da bactéria a diferentes condições obriga-a a controlar a expressão de genes de forma eficiente. Uma das formas primárias de controle de expressão gênica é a competição entre os diversos fatores sigma pela ligação ao cerne da RNA polimerase. <font face=\"Symbol\">d70 é o fator sigma mais abundante e participa da transcrição da maioria dos genes de E. coli, enquanto que <font face=\"Symbol\">dS é o segundo em importância e reconhece promotores de genes relacionados à resposta geral ao estresse. O gene rpoS, que codifica para <font face=\"Symbol\">dS é altamente polimórfico, e adquiri mutações frequentemente. A mutação pontual C<font face=\"Symbol\">®T na posição 97 da ORF de rpoS, resulta em um códon de parada TAG (âmbar). Um Shine-Dalgarno alternativo e um códon de início de tradução na posição 157 dá início a uma proteína RpoS truncada, que é parcialmente funcional. Uma das situações de estresse na qual <font face=\"Symbol\">dS é ativado corresponde à privação de fosfato inorgânico. Porém, na limitação deste nutriente ocorre também a ativação do regulon PHO, cujos genes são predominantemente transcritos por <font face=\"Symbol\">d70. Neste trabalho, o efeito da versão truncada de RpoS sobre a expressão de genes dependentes de <font face=\"Symbol\">d70 (lacZ, phoA e pstS) e de genes dependentes de <font face=\"Symbol\">dS (osmY e proU) foi testado. Foram também realizados ensaios de estresse oxidativo, osmótico e pelo frio. O perfil de atividade parcial descrito para RpoSam pôde ser observado em alguns casos, porém em outros o comportamento deste alelo se assemelhou ao do mutante rpoS nulo. Paralelamente, foi testada também uma cepa de E. coli que carrega a mutação âmbar em rpoS, mas esta é suprimida, resultando na expressão de uma proteína RpoS normal. A proteína RpoS truncada não pôde ser visualizada em immunoblots, provavelmente porque esta é traduzida de forma pouco eficiente a partir do Shine-Dalgarno alternativo. Com o objetivo de incrementar a detecção de RpoS em ensaios de imuno-detecção, foi inserida por recombinação alélica uma etiqueta SPA altamente imunogênica na porção C-terminal da proteína. / Escherichia coli can be found in many different habitats and has to be prepared to survive and grow under unfavorable conditions. Bacteria adaptation to different growth conditions requires an efficient control of gene expression. One of the primary forms of gene expression control is the competition between different sigma factors for the binding to the core RNA polymerase. <font face=\"Symbol\">d70 is the most abundant sigma factor and participates in the transcription of most E. coli genes. <font face=\"Symbol\">dS is the second one in importance and recognizes promoters of genes related to the general stress response. The rpoS gene, which encodes <font face=\"Symbol\">dS, is highly polymorphic and acquires mutations very often. The transition C<font face=\"Symbol\">®T at position 97 in the rpoS ORF results in a stop codon TAG (amber). Due to the presence of an alternative Shine-Dalgarno and a translation initiation codon at position 157 a truncated RpoS protein that is partially functional is translated. One of the stress situations that <font face=\"Symbol\">dS is activated is the starvation for inorganic phosphate. Phosphate limitation also triggers the activation of the PHO regulon, whose genes are predominantly transcribed by <font face=\"Symbol\">d70. In the present study, the effect of the truncated version of RpoS on the expression of <font face=\"Symbol\">d70 dependent genes (lacZ, phoA e pstS) and <font face=\"Symbol\">dS dependent genes (osmY e proU) was tested. Bacteria were also assayed for sensitivity to oxidative, osmotic and cold stress. The profile of partial activity described for the truncated RpoS could be observed in some cases, while in others the behavior of this allele resembled the rpoS null mutant. In parallel, an E. coli strain which suppresses the amber mutation in RpoS, resulting in the expression of a normal protein was also tested. A band correponding to the truncated RpoS could not be detected in immunoblots probably due to inefficient translation from the alternative Shine-Dalgarno. To improve the detection of RpoS, a highly immunogenic SPA tag was inserted in the C-terminal region of the protein. Escherichia coli Ativação enzimática Genética bacteriana Mutação genética RNA polimerases Escherichia coli Bacterial genetics Enzyme activation Genetic mutation RNA polymerases
153	Influence de la variation de la concentration intracellulaire des désoxyribonucléotides et rubbonucléotides sur la stabilité génomique chez Pyrococcus abyssi / Influence of desoxyribonucleotides and ribonucleotides concentrations on the genome integrity in Pyrococcus abyssi Lemor, Mélanie 17 November 2017 (has links) Dans les trois domaines du vivant, que constituent les bactéries, les eucaryotes et les archées, une molécule a la capacité souveraine de gouverner la vie, la mère à l’origine de tous les mécanismes biologiques, l’ADN. S’il est évident de dire que le maintien de l’intégrité des génomes est essentiel à la vie, il existe deux systèmes qui le permettent, la réplication et la réparation de l’ADN. La fidélité de ces derniers est finement influencée par la disponibilité (ratio et balance) des précurseurs nucléotidiques désoxyribonucléotides (dNTPs) et ribonucléotides (rNTPs) au cours du cycle cellulaire. Même si la concentration intracellulaire en nucléotides est largement documentée chez les eucaryotes et les bactéries, ça n’est malheureusement pas le cas chez les archées. En ce qui concerne l’étude de la maintenance génomique, un groupe d’archées a intéressé les chercheurs de par leurs capacités à survivre dans des milieux dits extrêmes. Pyrococcus abyssi est l’une d’entre elles qui depuis de nombreuses années sert de modèle biologique pour répondre aux questions de la stabilité de l’ADN à haute température. Cette étude est centrée sur cette thématique et particulièrement sur les caractéristiques fonctionnelles des ADN polymérases: PolD, PolB et le complexe p41/p46. Initialement, le contenu en nucléotides a été évalué dans des cellules en phase exponentielle de croissance par la technique de chromatographie couplée à une double détection en spectrométrie de masse (zicHILIC-MS-MS). Les résultats montrent que le contenu en rNTPs est de 20 fois supérieur à celui en dNTPs. Pour cette raison, la discrimination sélective des dNTPs par les ADN polymérases est mise à l’épreuve. Même si, des mécanismes permettent d’exclure les rNMPs durant la synthèse de l’ADN, de récentes études ont montrées que des rNMPs étaient incorporés par des ADN pols. Ainsi, le ratio en nucléotides obtenu a été utilisé pour l’analyse de son effet sur la synthèse d’ADN par les ADN Pols et les extraits cellulaires de P. abyssi. Les résultats démontrent clairement que les rNMPs sont incorporés par l’ADN polymérase PolD. Puis, les conséquences de la présence des rNMPs dans l’ADN sur la réplication ont été étudiées et ont mis en évidence que les extraits cellulaires, tout comme les ADN Pols de P. abyssi étaient capables de « passer » un rNMP présent dans l’ADN. Pour finir, une étude de l’incorporation préférentielle de chaque dNMP et rNMP a été menée démontrant que la complémentarité des bases était respectée même lors de l’incorporation de rNMPs. Enfin, la caractérisation de la petite sous-unité, DP1, de PolD a permis de montrer sa capacité à retirer des rNMPs grâce à son activité de relecture, suggérant un premier rempart à la présence de rNMPs dans l’ADN. Pour conclure, ces résultats montrent que la présence de rNMPs dans l’ADN est un phénomène conservé dans les trois domaines du vivant. / In the three domains of life that include Bacteria, Eukarya and Archaea, one molecule has the sovereign ability to govern life, and not the least one, the mother of all biological mechanisms, DNA. Maintaining the integrity of genomes is obviously essential for life, and faithful DNA replication and repair are the guarantees. The fidelity of these two processes may vary depending on the availability and levels (balance and ratio) of deoxyribonucleotides (dNTPs) and ribonucleotides (rNTPs) during the cell-cycle. Even if intracellular concentration of nucleotides is largely documented in Eukarya and Bacteria, it remains limited in Archaea. From many years one group of Archaea is of great interest for studying genomic maintenance, because of its ability to survive in extremes environments. Pyrococcus abyssi is one of them that is used as biological model for deciphering the stability of DNA at elevated temperature in LM2E. The present work focuses on genomic integrity and particularly on the functional characterization of the three DNA polymerases: PolD, PolB and the p41/p46 complex. Initially, the nucleotide pool has been evaluated in exponentially growing cells using the highly sensitive method that combined chromatography and mass spectrometry (zicHILIC-MS-MS). The results show that rNTPs content is 20-fold higher than dNTPs. For that reason, fidelities of DNA polymerases are challenged to select the correct dNTP over the most abundant rNTP during DNA synthesis. Despite the fact that some mechanisms allow the exclusion of rNTPs from entry to the Pol active site, recent findings indicate that ribonucleotides are incorporated by different DNA Pols with surprisingly high frequency. In this work, the obtained intracellular balance and ratio of rNTPs and dNTP have been used to analyze their effect on DNA synthesis by P. abyssi DNA Pols and cell-free extracts. Our results clearly demonstrate that rNTP incorporation is detectable with distinct efficiencies among DNA pols. Secondly, the consequences of the presence of rNMPs in a DNA template on DNA polymerisation has been examined and highlights that cell-free extracts are able to bypass a single rNMP as well as replicative DNA polymerases. To strengthen that study, single nucleotide incorporation opposite rNMP or dNMP has been carried out and the results demonstrate that replicative Pyrococcus abyssi DNA Pols can basepair the complementary rNTPs opposite dNMPs, and vice-versa, the complementary dNTPs opposite rNMPs.Furthermore, the preliminary results obtained about the nucleolysis activities of the PolD small subunit, DP1, show that the DNA polymerase D is able to remove rNMPs from a DNA strand, suggesting a first level of protection against ribonucleotide contamination of DNA. Definitely, these data indicate that the presence of transient embedded rNMPs in genomic DNA represents a universally conserved phenomenon across Archaea, Bacteria and Eukarya. Contenu en nucléotides Archée ADN polymérases Ribonucléotide Maintenance génomique Nucleotide pool Archaea DNA polymerases Ribonucleotide Genomic maintenance 579.321
154	In vitro, in silico and in vivo studies of the structure and conformational dynamics of DNA polymerase I Sustarsic, Marko January 2016 (has links) DNA polymerases are a family of molecular machines involved in high-fidelity DNA replication and repair, of which DNA polymerase I (Pol) is one the best-characterized members. Pol is a strand-displacing polymerase responsible for Okazaki fragment synthesis and base-excision repair in bacteria; it consists of three protein domains, which harbour its 5’-3' polymerase, 3’-5’ exonuclease and 5’ endonuclease activities. In the first part of the thesis, we use a combination of single-molecule Förster resonance energy transfer (smFRET) and rigid-body docking to probe the structure of Pol bound to its gapped-DNA substrate. We show that the DNA substrate is highly bent in the complex, and that the downstream portion of the DNA is partly unwound. Using all-atom molecular dynamics (MD) simulations, we identify residues in the polymerase important for strand displacement and for downstream DNA binding. Moreover, we use coarse-grained simulations to investigate the dynamics of the gapped-DNA substrate alone, allowing us to propose a model for specific recognition and binding of gapped DNA by Pol. In the second part of the thesis, we focus on the catalytically important conformational change in Pol that involves the closing of the ‘fingers’ subdomain of the protein around an incoming nucleotide. We make use of the energy decomposition method (EDM) to predict the stability-determining residues for the closed and open conformations of Pol, and test their relevance by site-directed mutagenesis. We apply the unnatural amino acid approach and a single-molecule FRET assay of Pol fingers-closing, to show that substitutions in the stability-determining residues significantly affect the conformational equilibrium of Pol. In the final part of the thesis, we attempt to study Pol in its native environment of the living cell. We make use of the recently developed method of internalization by electroporation, and optimize it for organically labelled proteins. We demonstrate the internalization and single-molecule tracking of Pol, and provide preliminary data of intra-molecular FRET in Pol, both at the single-cell and single-molecule levels. Finally, by measuring smFRET within an internalized gapped-DNA construct, we observe DNA binding and bending by endogenous Pol, confirming the physiological relevance of our in vitro Pol-DNA structure. 572.8
155	Identification of SARS-CoV-2 Polymerase and Exonuclease Inhibitors and Novel Methods for Single-Color Fluorescent DNA Sequencing by Synthesis Wang, Xuanting January 2021 (has links) This dissertation is divided into two main sections describing major portions of my Ph.D. research: (1) development of two enzymatic assays for identifying inhibitors of SARS-CoV-2 RNA dependent RNA polymerase (RdRp) and the associated proofreading exonuclease complexes, two key enzymatic activities of SARS-CoV-2, the virus responsible for the COVID-19 pandemic and (2) the design and implementation of four novel single-color fluorescent DNA sequencing by synthesis (SBS) methods, including the synthesis of many of the key nucleotide analogues required for these studies. In response to the COVID-19 pandemic, the first part of my research is focused on the discovery of potential therapeutics for combating coronavirus infections. Chapter 1 describes the identification of several polymerase and exonuclease inhibitors for SARS-CoV-2 using novel mass spectrometry-based molecular assays. SARS-CoV-2 has an exonuclease complex, which removes nucleotide inhibitors such as Remdesivir that are incorporated into the viral RNA during replication, reducing the efficacy of these drugs for treating COVID-19. Combinations of inhibitors of both the viral RdRp and the exonuclease could overcome this deficiency. Chapter 1 reports the identification of hepatitis C virus NS5A inhibitors Pibrentasvir and Ombitasvir as SARS-CoV-2 exonuclease inhibitors. In the presence of identified exonuclease inhibitors, RNAs terminated with the active forms of the prodrugs like Sofosbuvir, Remdesivir and Favipiravir were largely protected from excision by the exonuclease, while in the absence of exonuclease inhibitors, there was rapid excision. Viral cell culture studies also demonstrate significant synergy using this combination strategy. This study supports the use of combination drugs that inhibit both the SARS-CoV-2 polymerase and exonuclease for effective COVID-19 treatment. Chapters 2-6 describe the single-color DNA SBS studies. Chapter 2 provides essential background on the structure of DNA, the DNA polymerase reaction, and several key DNA sequencing technologies, with an emphasis on the design of nucleotide analogues for the DNA SBS approach. Chapter 3 delineates a one-color fluorescent DNA SBS method based on a set of nucleotide reversible terminators (NRTs) comprising two orthogonal cleavable linkers, one fluorescent dye and one anchor. Chapter 4 describes a one-color hybrid DNA sequencing approach using a set of dideoxynucleotide analogues bearing two orthogonal cleavable linkers, one fluorophore and one anchor as well as a set of unlabeled NRTs. By introducing a pH responsive fluorophore into the design of nucleotide analogues, Chapter 5 demonstrates a novel type of single-color DNA SBS method using a set of NRTs comprising one pH-responsive fluorescent dye or one non-responsive fluorescent dye tethered with one cleavable linker. Chapter 6 presents another option for the single-color DNA sequencing technique using a set of deoxynucleotide analogues comprising the above pH responsive or non-responsive dyes tethered with a cleavable linker, along with a set of unlabeled NRTs. The one-color SBS approaches have the potential for higher sensitivity, miniaturization and cost effectiveness compared with four-color SBS methods. Finally, Chapter 7 summarizes the SARS-CoV-2 antiviral drug discovery and one-color sequencing techniques and discusses potential follow-up research on these projects. Chemical engineering COVID-19 (Disease)--Treatment Nucleotide sequence Color codes Sofosbuvir RNA polymerases--Inhibitors Antiviral agents--Therapeutic use
156	The role of Rtr1 and Rrp6 in RNAPII in transcription termination Fox, Melanie Joy 31 August 2015 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / RNA Polymerase II (RNAPII) is responsible for transcription of messenger RNA (mRNA) and many small non-coding RNAs. Progression through the RNAPII transcription cycle is orchestrated by combinatorial posttranslational modifications of the C-terminal domain (CTD) of the largest subunit of RNAPII, Rpb1, consisting of the repetitive sequence (Y1S2P3T4S5P6S7)n. Disruptions of proteins that control CTD phosphorylation, including the phosphatase Rtr1, cause defects in gene expression and transcription termination. There are two described RNAPII termination mechanisms. Most mRNAs are terminated by the polyadenylation-dependent cleavage and polyadenylation complex. Most short noncoding RNAs are terminated by the Nrd1 complex. Nrd1-dependent termination is coupled to RNA 3' end processing and/or degradation by Rrp6, a nuclear specific subunit of the exosome. The Rrp6-containing form a 3'-5' exonuclease complex that regulates diverse aspects of nuclear RNA biology including 3' end processing and degradation of a variety of noncoding RNAs (ncRNAs). It remains unclear whether Rrp6 is directly involved in termination. We discovered that deletion of RRP6 promotes extension of multiple Nrd1-dependent transcripts resulting from improperly processed 3' RNA ends and faulty transcript termination at specific target genes. Defects in RNAPII termination cause transcriptome-wide changes in mRNA expression through transcription interference and/or antisense repression, similar to previously reported effects of Nrd1 depletion from the nucleus. Our data indicate Rrp6 acts with Nrd1 globally to promote transcription termination in addition to RNA processing and/or degradation. Furthermore, we found that deletion of the CTD phosphatase Rtr1 shortens the distance of transcription before Nrd1-dependent termination of specific regulatory antisense transcripts (ASTs), increases Nrd1 occupancy at these sites, and increases the interaction between Nrd1 and RNAPII. The RTR1/RRP6 double deletion phenocopies an RRP6 deletion, indicating that the regulation of ASTs by Rtr1 requires Rrp6 activity and the Nrd1 termination pathway. ChIP-Seq RNAPII Transcription RNA-Sequencing Transcription Termination RNA polymerases -- Research Gene expression Protein kinases Proteins -- Metabolism Phosphorylation
157	Investigating Current Mechanistic Models of DNA Replication and Repair Wallenmeyer, Petra C., Wallenmeyer January 2017 (has links) No description available. Biochemistry Chemistry DNA polymerases DNA repair DNA replication epigenetics modified cytosine x-ray crystallography pre-steady state kinetics
158	Phagenähnliche RNA-Polymerasen Swiatecka-Hagenbruch, Monika 26 May 2009 (has links) Chloroplasten höherer Pflanzen haben kleine Genome. Trotzdem ist ihre Transkriptionsmaschinerie sehr komplex. Plastidäre Gene werden von plastidenkodierten (PEP) und kernkodierten RNA-Polymerasen (NEP) transkribiert. In der vorliegenden Arbeit wurden Promotoren plastidärer Gene und Operons von Arabidopsis thaliana charakterisiert. Zur Unterscheidung zwischen NEP- und PEP-Promotoren wurden erstmals spectinomycinbehandelte, chlorophylldefiziente Arabidopsis-Pflanzen mit fehlender PEP-Aktivität verwendet. Obwohl für einige Gene auch einzelne Promotoren lokalisiert wurden, wird die Transkription der meisten plastidären Gene und Operons an multiplen Promotoren initiiert. Der Vergleich plastidärer Promotoren von Tabak und Arabidopsis zeigte eine hohe Vielfältigkeit der Promotornutzung, die möglicherweise auch in anderen höheren Pflanzen vorkommt. Dabei stellt die individuelle Promotornutzung eine speziesspezifische Kontrollmöglichkeit der plastidären Genexpression dar. Das Kerngenom von Arabidopsis beinhaltet zwei Kandidatengene der NEP, RpoTp und RpoTmp, welche Phagentyp-RNA-Polymerasen kodieren. In der vorliegenden Arbeit wurde die Wirkung veränderter RpoTp-Aktivität auf die Nutzung von NEP- und PEP-Promotoren in transgenen Arabidopsis-Pflanzen mit verminderter und fehlender RpoTp-Aktivität untersucht. Im Keimlingsstadium konnten Unterschiede in der Promotornutzung zwischen Wildtyp und Mutanten beobachtet werden. Fast alle NEP-Promotoren wurden in Pflanzen mit verringerter oder fehlender RpoTp-Aktivität genutzt. Dabei zeigten nur einige von ihnen eine geringere Aktivität, andere wiederum waren sogar verstärkt aktiv. Der starke NEP-Promotor des essentiellen ycf1 Gens wurde in jungen Keimlingen ohne funktionelle RpoTp nicht genutzt. Die Ergebnisse zeigen, dass NEP gemeinsam von beiden Phagentyp-RNA-Polymerasen RpoTp und RpoTmp repräsentiert wird und dass beide sowohl eine überlappende, als auch eine spezifische Rolle in der Transkription plastidärer Gene innehaben. / Although chloroplasts of higher plants have small genomes, their transcription machinery is very complex. Plastid genes of higher plants are transcribed by the plastid-encoded plastid RNA polymerase PEP and the nuclear-encoded plastid RNA polymerases NEP. Here, promoters of plastid genes and operons have been characterized in Arabidopsis thaliana. For the first time spectinomycin-treated, chlorophyll-deficient Arabidopsis plants lacking PEP activity have been used to discriminate between NEP and PEP promoters. Although there are plastid genes that are transcribed from a single promoter, the transcription of plastid genes and operons by multiple promoters seems to be a common feature. Comparison of plastid promoters from tobacco and Arabidopsis revealed a high diversity, which my also apply to other plants. The diversity in individual promoter usage in different plants suggests that there are species-specific solutions for attaining control over gene expression in plastids. The nuclear genome of Arabidopsis contains two candidate genes for NEP transcription activity, RpoTp and RpoTmp, both coding for phage-type RNA polymerases. In this study the usage of NEP and PEP promoters has been analysed in transgenic Arabidopsis plants with reduced and lacking RpoTp activity. Differences in promoter usage between wild type and mutant plants were most obvious early in development. Nearly all NEP promoters were active in plants with low or lacking RpoTp activity, though certain promoters showed reduced or even increased usage. The strong NEP promoter of the essential ycf1 gene was not transcribed in young seedlings without functional RpoTp. These results provide evidence for NEP being represented by two phage-type RNA polymerases RpoTp and RpoTmp that have overlapping as well as specific functions in the transcription of plastid genes. Promotor Transkription Plastiden Phagentyp-RNA-Polymerasen NEP-Transkriptionsaktivität Plastids Promoters Transcription Phage-type RNA-Polymerases NEP transcription activity 580 Pflanzen (Botanik) 32 Biologie WG 1800 ddc:580
159	Influence of light and cytokinin on organellar phage-type RNA polymerase transcript levels and transcription of organellar genes in Arabidopsis thaliana Borsellino, Liliana 09 January 2012 (has links) Licht und Pflanzenhormone sind essentiell für das Wachstum und die Entwicklung von Pflanzen. Es ist nur wenig darüber bekannt, wie sie die Transkription organellärer Gene beeinflussen. In Arabidopsis thaliana gibt es drei kernkodierte Phagentyp-RNA-Polymerasen (RpoT), welche für die organelläre Transkription verantwortlich sind. Diese werden in die Plastiden (RpoTp), die Mitochondrien (RpoTm) oder zu beiden Organellen (RpoTmp) transportiert. Neben den beiden kernkodierten RNA-Polymerasen (NEP) existiert in den Plastiden eine plastidärkodierte RNA-Polymerase (PEP), welche zusätzliche Sigmafaktoren zur Promotererkennung benötigt. Um die Lichtabhängigkeit der Expression der RpoT Gene sowie NEP-transkribierter Chloroplastengene zu analysieren, wurde die Akkumulation von RpoT- und rpoB-Transkripten in 7-Tage alten Keimlingen unter verschiedenen Lichtbedingungen mittels quantitativer real-time PCR untersucht. Die Änderungen in der Transkriptakkumulation deuten darauf hin, dass rote, blaue und grüne Wellenlängen die Expression der drei RpoT Gene unterschiedlich stark stimulieren. Untersuchungen an verschiedenen Lichtrezeptor-Mutanten zeigten, dass die Lichtinduktion der RpoT Genexpression überaus komplex ist und ein interagierendes Netzwerk aus multiplen Rezeptoren und Transkriptionsfaktoren an der Signalweiterleitung beteiligt ist. Das Phytohormon Cytokinin wird durch Histidin Kinase Rezeptoren (AHK) detektiert. Es gibt drei unterschiedliche Rezeptoren: AHK2, AHK3 und AHK4. Diese sind Teil eines Zwei-Komponenten-Systems, welches Signale mit Hilfe einer Phosphorylierungskette überträgt. Der Einfluss von Cytokinin auf die plastidäre Transkription wurde mit Hilfe von Cytokininrezeptor-Mutanten untersucht, um die Funktion von AHK2, AHK3 und AHK4 zu analysieren. Um weitere Informationen darüber zu erhalten, wie die plastidäre Transkription durch PEP mittels Cytokinin reguliert wird, wurden die Hormoneffekte auf die plastidäre Transkription in Sigmafaktor-Mutanten untersucht. / Light and plant hormones are essential for plant growth and development. Only little information is available about how these signals influence the transcription of organellar genes. Arabidopsis thaliana possesses three nuclear-encoded phage-type RNA polymerases (RpoT) for organellar transcription. They are imported into plastids (RpoTp), mitochondria (RpoTm), or into both organelles (RpoTmp). Besides the two nuclear-encoded plastid polymerases (NEP), plastids contain an additional plastid-encoded RNA polymerase (PEP), which needs additional sigma factors for promoter recognition. Interested in the expression of RpoT genes and NEP-transcribed plastid genes in response to light we analyzed transcript levels of RpoT and rpoB genes in 7-day-old wild-type plants under different light conditions by quantitative real-time-PCR. The observed changes in transcript accumulation indicated that red, blue, and green light differentially stimulated the expression of all three RpoT genes. Further analyses using different photoreceptor mutants showed that light induction of RpoT gene expression is surprisingly complex based on a network of multiple photoreceptors an d downstream pathways. Cytokinin signals are perceived by the histidine kinase (AHK) receptor family. There exist three different membrane-bound receptors: AHK2, AHK3 and AHK4/CRE1. These receptors are part of a two-component signaling system which transfers signals via phosphorelay mechanisms. Interested in the potential role of AHK2, AHK3 and AHK4/CRE1 in the transduction of cytokinin signals into the chloroplast, we analyzed the influence of cytokinin on plastidial transcription in receptor mutants. To gain more information on how plastid transcription by PEP is regulated by cytokinin, the influence of cytokinin in sigma factor mutants was also studied. Cytokinin Phagentyp-RNA-Polymerasen Lichtinduktion Photorezeptoren Organelläre Gentranskription light-induction photoreceptors phage-type RNA polymerases organellar gene transcription cytokinin 580 Pflanzen (Botanik) 32 Biologie WG 1840 ddc:580
160	Studies of the metal binding properties and DNA recognition mode of the unusual zinc fingers in poly(ADP-ribose) Polymerase-1 and the investigation of its interaction with apoptosis inducing factor (AIF) Zhou, Ying, 1977- 04 November 2013 (has links) Poly(ADP-ribosyl)ation, a covalent modification of proteins catalyzed by poly(ADP-ribose) polymerases (PARPs), plays a crucial role in regulating DNA repair, DNA replication, and cell death. Poly(ADP-ribose) Polymerase-1 (PARP-1) is a nuclear zinc-finger DNA-binding protein that is the most extensively studied member of the PARP family. The activation of PARP-1 depends on the N-terminal DNA-binding domain, which consists of two unusually long zinc finger-like motifs (termed FI and FII) of the form CX₂CX₂₈/₃₀HX₂C and a newly discovered zinc-ribbon motif (FIII). Though zinc is indispensible for PARP-1 activity, the metal binding affinities of the unusual zinc fingers of PARP-1 is not yet known. In this dissertation, the second zinc finger of PARP-1 was used as a model peptide to study the binding properties of several divalent metal ions (Co²⁺, Cd²⁺, Zn²⁺, and Pb²⁺). Metal-induced protein folding was investigated by circular dichroism, and the effects of the metal ions on PARP-1 activity were investigated by poly(ADP-ribosyl)ation activity assays. This study represents the first detailed biochemical characterization of the PARP zinc fingers. The functional role of each zinc finger in DNA damage recognition is critical for understanding how PARP-1 is involved in DNA repair. Thus, we constructed a series of PARP-1 zinc finger variant proteins and investigated their DNA binding properties and their effects on PARP activity. Using a combination of southwestern blotting and activity assays, we demonstrated that FII is more important for DNA binding, while FI and FIII seem to facilitate PARP activity. The DNA sequence-independent binding properties of PARP-1 were further characterized using DNA probes bearing defined secondary structures. Together, our results indicate that the zinc fingers help position the enzyme at specific DNA damage sites, and also help to activate the catalytic domain upon DNA binding. PARP-1 is involved in caspase-independent apoptosis, and the translocation of apoptosis inducing factor (AIF) out of the mitochondrial matrix has been shown to require PARP-1 activity. However, it is not readily apparent how the catalytic activity of PARP-1 (a nuclear protein) triggers the release of AIF from the mitochondrial matrix. In an attempt to understand the relationship between PARP-1 activity and caspase-independent apoptosis, we demonstrate here that AIF is an in vitro protein substrate for PARP-1. The possible implications of this finding will be discussed. / text DNA repair Poly(ADP-ribosyl)ation Poly(ADP-ribose) polymerases Poly(ADP-ribose) Polymerase-1 Zinc fingers PARP DNA-binding protein DNA-binding properties Apoptosis

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