Global ETD Search

41	Die Bedeutung der Thymidinphosphorylase bei Patienten mit lokal fortgeschrittenem Rektumkarzinom (UICC-Stadium-II/-III) im Kontext einer 5-FU basierten multimodalen Therapie / The significance thymidine phosphorylase has on patients with locally advanced rectal cancer (UICC-Stadium-II/-III) with regard to a 5-FU based multimodal therapy Specking, Matthias 23 June 2014 (has links) No description available. 610 Thymidinphosphorylase Rektumkarzinom 5-Fluorouracil Thymidine phosphorylase 5-Fluorouracil rectal cancer
42	Elucidation of the biochemical mechanism of glycogen phosphorylation in Escherichia coli Nepembe, Mehafo, Ndafapawa 12 1900 (has links) Thesis (MSc (Genetics. Plant Biotechnology)--University of Stellenbosch, 2009. / ENGLISH ABSTRACT: Glycogen was isolated from E. coli and analysed for the amount of phosphate present within it. It was confirmed that a significant proportion of the glucose residues were phosphorylated at the C6 position. This glycogen phosphate was found also in both glgb- (glycogen branching enzyme) and glgp- (glycogen phosphorylase enzyme) mutants, demonstrating that a mechanism for phosphate incorporation that does not involve GlgP alone, and which is capable of incorporating phosphate into linear glucans could exist. The degree of phosphorylation depended on the amount of phosphate present in the media, which less being incorporated in media where phosphate was reduced. Screening for glycogen phosphorylating genes using a E. coli genomic library in a functional expression system identified the malP gene as a possible candidate for incorporation of the phosphate at the C6 position. There was no difference, however, between the glycogen phosphate content of the mutant and wild type. Efforts were made to construct a malp-/glgp- double mutant, but these were unsuccessful. In addition the influence of plants and human proteins on yeast glycogen metabolism was also investigated. These proteins have been demonstrated to have an effect on starch or glycogen in humans, plant and E. coli, but the data from this study indicated that this was not the case in yeast. / AFRIKAANSE OPSOMMING: Glikogeen, wat geisoleer was uit E.coli was geanaliseer vir fosfaat inhoud daarin. Daar was gevind dat `n beduidende proporsie van die glukose residue gefosforileerd was op die C6 posisie. Hierdie gefosforileerde glikogeen was ook gevind in glg- (glikogeen vertakkingsensieme) en glgp- (glikogeen fosforileringsensieme) mutante wat daarop dui dat `n meganisme vir fosforilering bestaan was nie slegs aangewese is op die aktiwiteit van GlgP nie, en om fosfaat te inkorporeer in linêre glukane. Die graad van fosforilering was ook afhanklik van die hoeveelheid fosfaat teenwoordig in die medium, met gevolglik minder wat geinkorporeer kan word in medium waar fosfaat verminderd was. Seleksie-gebaseerde ondersoeking vir fosforileringsensieme van glikogeen deur gebruik te maak van E. coli genomiese biblioteke in `n funksionele uitdrukkingssisteem het die malP geen geidentifiseer as een van die moontlike kandidate wat verantwoordelik kan wees vir inkorporering van fosfaat in the C6 posisie. Daar was egter geen verskil in die fosfaat inhoud van glikogeen tussen die wilde tipe en die mutante. Pogings wat aangewend is om `n malp-/glgpdubbel mutant te konstrueer was onsuksesvol. Verder is die invloed van plant en mens proteine op gis glikogeen ook bestudeer. Vroeër is aangetoon dat hierdie proteine `n invloed op stysel en glikogeen het in mense, plante en E. coli, maar data van hierdie studie toon aan dat dit nie die geval in gis is nie. Theses -- Plant biotechnology Dissertations -- Plant biotechnology Glycogen phosphorylase Phosphorylation Escherichia coli Genetics Institute for Plant Biotechnology
43	Estrutura cristalográfica da Purina nucleosídeo foslorilase do Mycobacterium tuberculosis / Silva, Diego Oliveira Nolasco da. January 2005 (has links) Orientador: Walter Filgueira de Azevedo Júnior / Banca: Luis Fernando Delboni / Banca: Fernanda Canduri / Resumo: A Purina Nucleosídeo Fosforilase (PNP) catalisa a fosforólise de nucleosídeos de purina para suas respectivas bases e açucares (ribose ou desoxirribose) 1-fosfato. A PNP desempenha uma função central no metabolismo das purinas, normalmente operando na via de recuperação do DNA das células. Mais ainda, a PNP cliva ligações glicosídicas com inversão da configuração para produzir a-ribose 1-fosfato. Acredita-se que no organismo do Mycobacterium tuberculosis a PNP desempenha tarefas similares, o que levanta o interesse em desenvolver ciência que dê suporte para o desenvolvimento de drogas baseadas na estrutura desta proteína. A proteína é um homotrímero simétrico com um arranjo triangular das subunidades, similar às PNPs triméricas de mamíferos. Cada monômero consiste de um enovelamento a/ß formado por onze fitas ß circundadas por oito hélices a. O estudo desta PNP visa proporcionar comparações com outras estruturas, na intenção de identificar as bases estruturais de possíveis diferenças ou similaridades funcionais entre esta e outras PNPs, num esforço para desenvolver pesquisa que dê suporte para o desenho de novas drogas mais seletivas e poderosas contra a tuberculose. / Abstract: The Purine nucleoside phosphorylase (PNP) catalyses the phosphorolysis of purine nucleosides to corresponding bases and ribose 1-phosphate. PNP plays a central role in purine metabolism, normally operating in the purine salvage pathway of cells. Moreover, PNP cleaves glycosidic bond with inversion of configuration to produce á-ribose 1-phosphate. It is believed that in the MtPNP is responsible for the same labor in the Mycobacterium tuberculosis organism, which arouses the interest in developing science for giving support to the development of structure based drugs. The protein is a symmetrical homotrimer with triangular arrangement of the subunits, similar to the trimeric mammalian PNPs. Each monomer consist of a á/â folding formed by eleven â sheet surrounded by eight á helices. The study of this PNP aims the possibility of caring out comparisons with other structures, in order to identify the structural basis of possible differences or functional similarities between this and other PNPs, in an effort to develop research which gives support to the design of more selective and powerful new drugs against tuberculosis. / Mestre Biologia molecular. Cristalografia. Proteínas - Estrutura. Mycobacterium tuberculosis. Purine nucleoside phosphorylase. eng Tuberculosis. eng
44	Determinação estrutural e funcional da enzima 5´-deoxi-5´-metiltioadenosina Fosforilase de Schistosoma mansoni / Structural and Functional Determination of 5´-deoxy-5´-methylthioadenosine Phosphorylase enzyme from Schistosoma mansoni Juliana Roberta Torini de Souza 16 April 2012 (has links) As doenças parasitárias são uma das maiores causas de morte em países em desenvolvimento, e recebem pouca ou nenhuma atenção das indústrias farmacêuticas para o desenvolvimento de terapias. A esquistossomose mansoni também conhecida como barriga d´água ou doença do caramujo é uma doença parasitária crônica que afeta aproximadamente 207 milhões de pessoas no mundo sendo aproximadamente 6 milhões somente no Brasil. Os medicamentos disponíveis no mercado causam graves efeitos colaterais. Além disso, há relatos de cepas de S. mansoni resistentes à esses medicamentos, justificando assim a busca por novos fármacos. O Schistosoma mansoni não possui a via de novo para a biosíntese de bases púricas e depende integralmente da via de salvação para o suprimento dessa. Assim, este trabalho teve como objetivo determinar as constantes catalíticas e a estrutura tridimensional da MTAP (EC 2.4.2.28), enzima esta que participam da via de salvação de purinas, e é desta forma essencial para a reprodução do parasita. Esta enzima foi expressa de forma heteróloga, purificada e cristalizada. A proteína foi submetida à ensaios cinéticos em sistema acoplado, onde foram determinadas as constantes catalíticas. A proteína foi também cristalizada em condições que continham 100 mM de Bis-tris ou MES com pH variando entre 6,1 a 6,5 e PEG3350, cuja concentração variou ente 14-18%. Os cristais foram submetidos à difração de raios-X no LNLS e no DLS. Foram obtidos, quatro conjuntos de dados, que foram processados, refinados e analisados. Obteve-se estrutura apoenzima em complexo com fosfato, em complexo com adenina e sulfato, em complexo com tubercidina e sulfato e em complexo com adenina e glicerol em um grupo espacial diferente dos demais. Através da estrutura secundária, foi possível analisar o sítio ativo, além de obter informações preliminares do mecanismo catalítico da enzima alvo. Este trabalho colabora para a futura elucidação completa da via de salvação de purinas em S. mansoni, e fornece informações básicas para que a busca por novos fármacos tenha novos ramos a serem explorados. / The parasitic illness are the leading cause of deaths in developing countries, and receives little or no attention from drug companies to develop therapies. Schistosomiasis mansoni also known as water belly or snail´s disease is a chronic parasitic illness that affects approximately 207 million people worldwide with approximately 6 million in Brazil. Schistosomiasis is treated by the use of drugs that are not-in fact effective for the eradication of the disease, and although their efficiency cause serious side effects. In addition, there are reports of S. mansoni´s resistant strains to these drugs, thus justifying the search for new drugs. The Schistosoma mansoni parasite does not possess the de novo pathway for purine bases biosynthesis and depends entirely on salvage pathways for its purine requirement. Thus this study aimed to determine the catalytic constants and three-dimensional structure of MTAP (EC 2.4.2.28), an enzyme that is involved in purine salvation pathway, and is thus essential to the reproduction of the parasite. The MTAP was heterologously expressed, purified and crystallized. The protein was submitted to kinetic assays in coupled system, to determine the catalytic constants. The protein was crystallized in 100mM Bis-tris or MES pH 6.1-6.5 and 14-18% PEG 3350. The crystals were submitted to diffraction of rays-X in the LNLS and DLS. Data sets were obtained, processed, refined and analyzed. Structures were obtained in apoenzyme form complexed with fosfate, complexed with adenine and sulfate, complexed with tubercidin and sulfate, and with adenine and glycerol in a space group different of the others. Through the secondary structure, it was possible to analyze the active site and obtained preliminary information of the catalytic mechanism of the target enzyme. This study contributes to the complete elucidation of the purine salvation pathway in S. mansoni, and provides basic information for the research of the new drugs. Schistosoma mansoni Estrutura cristalográfica Metiltioadenosina Fosforilase Schistosoma mansoni Crystallographic structure Methylthioadenosine Phosphorylase
45	Towards new enzymes:protein engineering versus bioinformatic studies Casteleijn, M. G. (Marinus G.) 02 February 2010 (has links) Abstract The aim of this PhD-study was to address some of the overlapping bottlenecks in protein engineering and metagenomics by developing or applying new tools which are useful for both disciplines. Two enzymes were studied as an example: Triosephosphate Isomerase (TIM) and Uridine Phosphorylase (UP). TIM is an important enzyme of the glycolysis pathway and has been investigated via means of protein engineering, while UP is a key enzyme in the pyrimidine-salvage pathway. In this thesis TIM was used to address protein engineering aspects, while UP was used in regards to some metagenomic and bioinformatic aspects. The aspects of a structural driven rational design approach and its implications for further engineering of monomeric TIM variants are discussed. Process development based on a new technology, EnBase®, addresses the relative instability of new variants, compared to its ancestors, for further studies. EnBase® is then applied for the production of 15N isotope labeling of a monomeric TIM variant, A-TIM. Systematical function- and engineering studies on dimeric TIM and monomeric TIM in regards to the hinges of the catalytic loop-6 were conducted to investigate enzyme activity and stability. Both the A178L and P168A were proposed to induce loop-6 closure, a wanted feature for A-TIM variants. The P168A mutants are hardly active, but gave great insight into the catalytic machinery, while the A178L mutants did induce partial loop-6 closure, however in addition, monomeric A178L was destabilized. Homology driven genome mining and subsequent isolation- high throughput (HTP) overexpression of a thermostable UP from the Archaea Aeopyrum pernix was carried out as an example for the production of recombinant proteins. In addition an alternative kinetic method to study the kinetics of UP by means of NMR directly from cell lysate is discussed. The combination of expression libraries and EnBase® in a HTP manner may relieve up the gene-to-product bottleneck. The structural aspects of A. pernix UP are explored by means of simple bioinformatic tools in the last section of this thesis. A thermostable, truncated version of UP was created and its use for protein engineering in the future is explored. The long N-terminal and C-terminal ends of A. pernix UP seem to be involved in stabilizing the dimeric and hexameric structures of UP. However, deletion of the N-terminal end of A. pernix UP yielded a thermostable protein. Overall, the finding in regards to process optimization and HTP expression and optimization and the underlying methods used in the TIM studies and the UP studies are interchangeable. TIM UP biocatalyst bioinformatics enzyme high throughput kinetic studies metagenomics protein engineering triosephosphate isomerase uridine phosphorylase
46	The metabolic dysregulation of calciphylaxis patients: the link between IL-6, PKM-2, and TYMP Morrissey, Austin Patrick 06 March 2024 (has links) This thesis explores the pathogenesis of calciphylaxis, a rare and potentially fatal complication of chronic kidney disease (CKD) characterized by calcification and thrombosis of small- to medium-sized arteries. A range of bench techniques, including cell culture, genetic analysis, and immunofluorescence, were utilized in combination with human samples from patients with calciphylaxis and healthy controls. The results revealed a pathway that may modulate the thrombotic phenotype in these patients and, in turn, may serve as a targetable therapeutic axis. This work provides a foundation for further research and clinical advances in the field of calciphylaxis. Moreover, this study has the potential to inform the development of therapeutic interventions that could greatly improve the outcomes of CKD patients suffering from calciphylaxis. / 2026-03-05T00:00:00Z Medicine Calciphylaxis Interleukin-6 Pyruvate kinase Thrombosis Thymidine phosphorylase Tissue factor
47	The Commercilazation of a Noval Antithrombotic Drug Dai, Yuheng 01 February 2018 (has links) No description available. Biology Medicine
48	Transcriptional Regulation of the Glycogen Phosphorylase-2 Gene in <I>Dictyostelium discoideum</i> Warner, Nikita 25 September 1999 (has links) The expression of the <I>glycogen phosphorylase- 2</I> gene (<I>gp2</I>) is initiated during early development and regulated by the extracellular morphogens cAMP and Differentiation Inducing Factor (DIF-1) [1-3]. Glycogen phosphorylase- 2 catalyzes the breakdown of glycogen reserves in developing cells to generate glucose precursors required for the synthesis of the end products of differentiation [4-6]. Thus, the expression of <I>gp2</I> is a significant event for cellular differentiation. The sequence of the <I>gp2</I> promoter, like other <I>Dictyostelium</I> promoters, has an AT-rich bias (88%) [7]. Previous deletional analyses of the promoter provided a map of the regions that contained transcriptional regulatory elements. The regions thus identified contained either "TAAAAATGGA" or C-rich repeat sequences [2]. These regions were dissected further by site-directed mutagenesis (SDM) to better define the physical boundaries of the regulatory elements. It was shown that the mutation of either one of the C-rich repeats resulted in a dramatic drop of about 95% in reporter gene levels. These data strongly suggested that both the C-rich repeats of <I>gp2</I> functioned as transcriptional regulatory elements. I have identified and purified a factor called TF2 that demonstrates a high specificity for a C-rich transcriptional regulatory element, the 5' C box. TF2 was first detected with electrophoretic mobility shift assays of DEAE chromatographic fractions of cell-free extracts. The specificity of TF2 for the 5' C box was tested by competition analysis using six other oligonucleotides. Purification of TF2 was achieved by ion-exchange chromatography, DNA affinity chromatography, gel filtration chromatography, and preparative SDS-PAGE. SDS-PAGE analysis indicated an apparent subunit molecular weight of 28 kDa. The apparent molecular weight of the native protein as estimated by gel filtration was about 53 kDa. This suggested that TF2 binds gp2 as a homodimer. A cDNA clone of the tf2 gene was provided by the Japanese <I>Dictyostelium</I> cDNA project. This allowed me to synthesize probes for Southern and Northern blot analyses. Southern blot analysis indicated that there is only one form of the <I>tf2</I> gene. Northern analysis showed little or no expression of <I>tf2</I> in undifferentiated cells. During development <I>tf2</I> expression increases up to a maximum at 8 h, then decreases in later stages. Attempts to disrupt the gene suggest that <I>tf2</I> mutation may be lethal. / Ph. D. Transcriptional regulation Dictyostelium discoideum Glycogen phosphorylase
49	Enzymatic Production of Cellulosic Hydrogen by Cell-free Synthetic Pathway Biotransformation(SyPaB) Ye, Xinhao 30 September 2011 (has links) The goals of this research were 1) to produce hydrogen in high yields from cellulosic materials and water by synthetic pathway biotranformation (SyPaB), and 2) to increase the hydrogen production rate to a level comparable to microbe-based methods (~ 5 mmol H2/L/h). Cell-free SyPaB is a new biocatalysis technology that integrates a number of enzymatic reactions from four different metabolic pathways, e.g. glucan phosphorylation, pentose phosphate pathway, gluconeogenesis, and hydrogenase-catalyzed hydrogen production, so as to release 12 mol hydrogen per mol glucose equivalent. To ensure the artificial enzymatic pathway would work for hydrogen production, thermodynamic analysis was firstly conducted, suggesting that the artificial enzymatic pathway would spontaneously release hydrogen from cellulosic materials. A kinetic model was constructed to assess the rate-limited step(s) through metabolic control analysis. Three phosphorylases, i.e. α-glucan phosphorylase, cellobiose phosphorylase, and cellodextrin phosphorylase, were cloned from a thermophile Clostridium thermocellum, and heterologously expressed in Escherichia coli, purified and characterized in detail. Finally, up to 93% of hydrogen was produced from cellulosic materials (11.2 mol H2/mol glucose equivalent). A nearly 20-fold enhancement in hydrogen production rates has been achieved by increasing the rate-limiting hydrogenase concentration, increasing the substrate loading, and elevating the reaction temperature slightly from 30 to 32°C. The hydrogen production rates were higher than those of photobiological systems and comparable to the rates reported in dark fermentations. Now the hydrogen production is limited by the low stabilities and low activities of various phosphorylases. Therefore, non-biologically based methods have been applied to prolong the stability of α-glucan phosphorylases. The catalytic potential of cellodextrin phosphorylase has been improved to degrade insoluble cellulose by fusion of a carbohydrate-binding module (CBM) family 9 from Thermotoga maritima Xyn10A. The inactivation halftime of C. thermocellum cellobiose phosphorylase has been enhanced by three-fold at 70°C via a combination of rational design and directed evolution. The phosphorylases with improved properties would work as building blocks for SyPaB and enabled large-scale enzymatic production of cellulosic hydrogen. / Ph. D. rational design protein engineering phosphorylase biofuel directed evolution hydrogen
50	Cloning and Characterization of Replication Protein A from Dictyostelium discoideum Wen, Xiao 08 May 1997 (has links) The gene encoding the Dictyostelium replication protein A large subunit (DdRPA1) has been cloned by screening of an EcoR I partial genomic library and a Hind III genomic sub-library. The complete nucleotide sequence, including the promoter region of the gene has been obtained by sequencing. Though the DdRPA1 protein has a size shift during development, 62 kDa in undifferentiated cells and 81 kDa in differentiated cells; they are the products of the same gene. Northern blot analysis revealed that the expression level of the DdRPA1 was constant throughout differentiation and the size of mRNA is the same at all stages, corresponding to a 81 kDa protein. Thus, it seems that the size change between the 62 kDa and 81 kDa is probably due to posttranslational modification, most likely, proteolytic cleavage. The transcription start site for both sizes of DdRPA1 has been identified at 306 bp upstream of the coding sequence by primer extension reaction. A PCR fragment representing 27% of the gene encoding the DdRPA middle size subunit (DdRPA2) has been generated by using the degenerate primers. This PCR fragment has been cloned and sequenced. The mRNA for this subunit corresponds to a protein of about 35 kDa. A decrease of the DdRPA2 mRNA expression level during differentiation was found by comparison between undifferentiated and differentiated cells. In Dictyostelium, replication protein A is a heterotrimeric protein that can bind with specific DNA sequences in a stage-dependent pattern. These DNA sequences were identified as the cis-acting regulatory sites in differentiation-related genes, including the glycogen phosphorylase 2 gene (gp2). Therefore, it is possible that DdRPA is not only a single-stranded DNA binding protein that is used in multiple essential DNA metabolic processes, such as DNA replication, repair and recombination in undifferentiated cells, but also involved in the transcriptional regulation process during differentiation. / Master of Science glycogen phosphorylase 2 DNA replication Dictyostelium discoideum Replication Protein A transcription factor

Search results