Global ETD Search

81	Aufreinigung und funktionelle Charakterisierung der peroxisomalen ABC-Transporter Pxa1p-Pxa2p aus Saccharomyces cerevisiae Schreiber, Gabriele 19 December 2007 (has links) Die peroxisomalen ABC-Transporter Pxa1p und Pxa2p sind Halbtransporter. Genetische Studien ergaben Hinweise, dass sie zur Bildung aktiver Transporter heterodimerisieren und am Import von langkettigen Fettsäuren in die Peroxisomen von S. cerevisiae beteiligt sind. Es wurden epitopmarkierte Varianten der Proteine als Komplex isoliert. Damit wurde gezeigt, dass Pxa1p und Pxa2p ein stabiles Heterodimer bilden. Zur Charakterisierung der ATP Bindeeigenschaften wurden die Transporter mit 8-azido-[alpha-32P]-ATP inkubiert und kovalent verknüpft. Dabei konnte gezeigt werden, dass Pxa1p und Pxa2p eine unsymmetrische Bindung des ATP Analogons aufweisen. Pxa2p bindet deutlich mehr azido-ATP als Pxa1p, bei sehr ähnlichen Dissoziationskonstanten. Die reduzierte ATP Bindung von Pxa1p spiegelt sich durch degenerierte Sequenzmotive der an der ATP Bindung beteiligten Sequenzen wieder. Die isolierten ABC-Transporter wurden für ATPase Messungen eingesetzt. Sie zeigten eine basale ATPase Aktivität, die durch Zugabe langkettiger Coenzym A aktivierter Fettsäuren, wie Oleoyl-CoA und Palmitoyl-CoA stimulierbar war. Eine Lysin Mutation im Walker A Motiv von Pxa1p hatte keine Funktionalitätseinbuße zur Folge. Dieselbe Mutation bei Pxa2p führte im Wachstumstest auf Festmedium mit Ölsäure als Kohlenstoffquelle zu einem deutlich verlangsamten Wachstum. Diese Ergebnisse korrespondieren mit der beobachteten unsymmetrischen ATP Bindung von Pxa1p und Pxa2p, da bei dem schwächer bindenden Pxa1p die Mutation wirkungslos blieb. Keine Übereinstimmung war bei den ATPase Aktivitätsmessungen der aufgereinigten Mutanten zu verzeichnen. Beide Mutanten zeigten eine unbeeinträchtigte ATPase Aktivität. Die ABC-Transporter wurden in Proteoliposomen eingebaut und für Transportmessungen mit einem Spin-Label markierten Oleoyl-CoA verwendet. Die Transportmessungen zeigten einen ATP abhängigen Transport, woraus geschlossen wurde, dass Pxa1p-Pxa2p tatsächlich Coenzym A Ester langkettiger Fettsäuren transportiert. / The peroxisomal ABC-transporters Pxa1p and Pxa2p are half transporters. Previous genetic investigations have demonstrated that Pxa1p and Pxa2p have to dimerise in order to build a functional transporter, which is very likely involved in the import of long chain fatty acids into peroxisomes of S. cerevisiae. In this work, tagged versions of the proteins were purified as a complex. This proved for the building of a stable hetero dimer. For characterisation of the ATP binding properties, the transporters were incubated and cross linked with 8-azido-[alpha-32P]-ATP. This revealed an asymmetric binding of the ATP analogue. Pxa2p binds much more azido-ATP, than Pxa1p, while the dissociation constants are rather similar. The poorer ATP binding of Pxa1p is reflected by degenerated sequence motifs in the nucleotide binding fold. The purified ABC-transporters have been used for ATPase assays. They showed a basal ATPase activity, which could be stimulated by addition of long chain fatty acid CoAs, like oleoyl-CoA and palmitoyl-CoA. Mutants with a lysine mutation in the walker A motive of Pxa1p led to no functional impairment, while the corresponding lysine mutation in Pxa2p led to reduced growth on agar plates with oleic acid as sole carbon source. The result corresponds with the ATP binding properties of Pxa1p. Because of the poorer ATP binding, even in the wild type protein, the mutation was not supposed to have a big influence. No accordance was found in respect to the ATPase measurements of the isolated mutant proteins. Both mutants revealed unaffected ATPase activity. The purified ABC-transporters were reconstituted in proteoliposomes and used for translocation assays of a spin-labelled oleoyl-CoA derivative. The measurements revealed an ATP dependent transport of the oleoyl-CoA analogue. This led to the conclusion, that Pxa1p-Pxa2p is indeed the transporter of long chain acetyl CoA esters, which were transported in an ATP dependent manner. ABC-Transporter Peroxisomen Fettsäuretransport ATPase Aktivität SL-Oleoyl-CoA Flippase Rekonstitution ABC-transporter peroxisomes fatty acid transport ATPase activity SL-Oleoyl-CoA flippase reconstitution 570 Biowissenschaften, Biologie 32 Biologie WD 5100 WF 9500 ddc:570
82	Substratbindung und -freigabe während des Katalysezyklus eines biotinspezifischen ECF-Transporters Finkenwirth, Friedrich 10 April 2017 (has links) ECF (Energy-Coupling Factor)-Transporter sind prokaryotische Aufnahmesysteme für Mikronährstoffe, die eine spezielle Gruppe von Transportern mit ATP-Bindekassette (ABC) darstellen. Sie beinhalten zwei asymmetrische Membranproteine, von denen eins (S) für die spezifische Bindung und Translokation des Substrates und das andere (T) für die Kopplung mit den ATPasen (A1,A2) zuständig ist. Bei ECF-Transportern der Subklasse I bilden diese Komponenten eine Einheit, während bei Vertretern der Subklasse II ein AAT-Modul mit wechselnden S-Einheiten interagiert. In der vorliegenden Arbeit wurde der Transportmechanismus, der eine Drehung der kompletten S-Einheit in der Membran beinhaltet, anhand des Biotintransporters BioMNY erstmals experimentell validiert. Durch Rekonstitution in Lipid-Nanodiscs, chemische Quervernetzung, fluoreszenz- und ESR-spektroskopische Techniken sowie einen Bindungstest mit radioaktivem Biotin wurde gezeigt, dass (i) die ATP-Bindung an die ATPasen zu einer Aufrichtung der S-Einheit (BioY) führt, (ii) diese Bewegung die Substratbeladung ermöglicht und (iii) BioY dabei ununterbrochen mit der T-Einheit (BioN) interagiert. Dies stellt einen Gegensatz zu Systemen der Subklasse II dar, für die ein ATP-abhängiger Austausch von S-Einheiten im Transportzyklus gezeigt worden war. Darüber hinaus wurde ein Escherichia coli-Stamm konstruiert, der durch Blockierung seines hochaffinen Biotintransporters und des -synthesewegs auf Spuren von Biotin nicht wachsen kann. Dieser Stamm ermöglichte einen eindeutigen Nachweis der Transportaktivität einiger solitärer BioY-Proteine. Aufgrund der einheitlichen Topologie von S-Einheiten ist ein Kippen auch für solitäre BioY-Varianten wahrscheinlich. Auch die metallspezifischen S-Einheiten CbiM und NikM besitzen ohne AAT-Modul eine basale Co2+- bzw. Ni2+-Transportaktivität. Ein ESR-spektroskopischer Kobaltnachweises zeigte, dass die aus nur zwei Membranhelices bestehende CbiN-Einheit für die Metallbeladung von CbiM essentiell ist. / ECF (Energy-Coupling Factor) transporters are a subgroup of ABC transporters that mediate uptake of micronutrients into prokaryotic cells. In contrast to canonical ABC importers, ECF transporters comprise two unrelated membrane proteins, one of which is responsible for specific and high affinity substrate binding (S) and the other one constitutes the coupling component (T) between S and the cytosolic ABC-ATPases (A1,A2). Subclass I transporters consist of four dedicated components whereas in subclass II transporters, a central AAT-module may interact with various S units. The biotin specific subclass I ECF transporter BioMNY was used to experimentally verify the hitherto hypothetic transport mechanism, which involves a rotation of the S unit within the membrane. With a series of experiments including reconstitution of BioMNY into lipid nanodiscs, site-specific cross-linking, a substrate binding assay with radioactive biotin and both fluorescence and EPR spectroscopic techniques, the ATP-dependent rotation of BioY (S) as a prerequisite for substrate binding and release was shown for the first time for an ECF transporter. Unlike subclass II transporters, for which an ATP-dependent release of the S unit was proposed, BioY interacts continuously with BioN (T) during the transport cycle. In a second focus of the work, an Escherichia coli reporter strain for biotin transporters was constructed. Due to inactivation of both biotin synthesis and the intrinsic high affinity biotin transporter, this strain was not capable of growing on trace amounts of biotin. With the use of this strain, transport activity of recombinantly produced solitary BioY proteins that naturally lack other ECF components was evidenced. Transport activity in the absence of AAT modules is also a feature of the Co2+ and Ni2+ specific S components CbiM and NikM. An EPR spectroscopic Co2+ detection assay helped underscoring the essential role of the small membrane protein CbiN for Co2+ loading of CbiM. ABC-Transporter Fluoreszenz ECF-Transporter ATP Nanodiscs Vitaminaufnahme Elektronenspinresonanz (ESR) ABC transporter fluorescence ECF transporter ATP nanodiscs vitamin uptake electron paramagnetic resonance (EPR) 570 Biowissenschaften, Biologie 32 Biologie WX 1101 WE 5440 ddc:570
83	Modulation unterschiedlicher Formen der Multidrug-Resistenz mittels eines Multitargetmultiribozymes Kowalski, Petra 27 July 2006 (has links) Tumorzellen entwickeln häufig Resistenzen gegen verschiedene strukturell und funktionell unabhängige Zytostatika, was als Multidrug-Resistenz (MDR) bezeichnet wird und die Hauptursache für das Scheitern einer Chemotherapie ist. Mit Hilfe von in vitro-Untersuchungen wurden erhöhte Genexpressionen der ABC-Transporter MDR1, MRP2 und BCRP als maßgebliche Resistenzfaktoren identifiziert, wie z.B. in den Magenkarzinomzellinien EPG85-257RDB (MDR1) und EPG85-257RNOV (BCRP) sowie in der Ovarialkarzinomzellinie A2780RCIS (MRP2). Ziel der Arbeit war die Entwicklung eines auf Ribozym-Technologie basierenden Therapieansatzes, welcher die Expressionen der oben genannten ABC-Transporter simultan inhibiert und dessen Anwendung zur Reversion der zellulären MDR führt. Dazu wurde ein Multitargetmultiribozym (MTMR) entwickelt, das aus in trans-aktiven Ribozymen besteht, die gegen die ABC-Transporter mRNAs gerichtet sind sowie aus in cis-spaltenden Ribozymen und aus Spacer-RNA-Sequenzen. Durch autokatalytische Spaltung in cis konnten die in trans-aktiven Ribozyme aus dem Gesamt-MTMR freigesetzt werden. Die Analyse der kinetischen Parameter des MTMRs ergab, daß die autokatalytisch entstandenen MTMR-Fragmente ihre Substrat-RNAs im Vergleich zu den korrespondierenden Monoribozymen ohne Einbuße an Effizienz spalten können. Darüber hinaus wurde die MTMR-Sequenz stabil in den drei eingangs genannten MDR-Zellinien exprimiert, was in einer signifikanten Reduktion der jeweiligen Ziel-mRNAs (97 % MDR1-, 80 % BCRP-, 96 % MRP2-mRNA) und der entsprechenden Proteine resultierte. Die Multidrug-Resistenz konnte aufgrund der MTMR-Expression um 70% (A2780RCIS), 95% (257RNOV), 100% (257RDB) und die Zytostatikumsakkumulation um 90% (257RNOV-Zellen) sowie 100% (257RDB-Zellen) revertiert werden. Das MTMR stellt erstmalig ein RNA-Konstrukt dar, welches in der Lage ist, simultan mehrere unabhängige Gene funktionell auszuschalten. Es besitzt daher ein großes Potential für zukünftige gentherapeutische Ansätze. / Cancer cells are often insensible against structurally and functionally unrelated drugs that is known as multiple drug resistance (MDR) and the main cause for treatment failure. Overexpression of the ABC-transporters P-gp (ABCB1), MRP2 (ABCC2), and BCRP (ABCG2) is associated with MDR in several cancer cell lines, e.g. in the stomach carcinoma cell lines EPG85-257RDB (P-gp), EPG85-257RNOV (BCRP), and in the ovarian carcinoma cell line A2780RCIS (MRP2). We aimed the development of a novel hammerhead ribozyme-based therapeutic approach capable of simultaneous silencing of the prementioned ABC-transporters, and consequently of reversing MDR phenotypes. We designed a so-called multitarget multiribozyme (MTMR) consisting of trans-acting hammerhead ribozymes directed against the MDR1, MRP2, and BCRP transcripts, of MDR1 homologous spacer sequences, and of cis-acting ribozymes against the spacer sequences. Autocatalytic cleavage in cis excised the full-length MTMR, and released trans-acting hammerhead ribozymes. We also evaluated the catalytic features of the MTMR using large RNA target molecules. Comparison of the kinetic values of the autocatalytically derived MTMR fragments with those of corresponding mono-ribozymes demonstrated an MTMR-mediated substrate cleavage without distinct loss in catalytic efficiency. Moreover, the MTMR was stably expressed in the prementioned multidrug-resistant cancer cell lines, and decreased the targeted transcripts about 97% (MDR1), 80% (MRP2), and 96% (BCRP) as well as the corresponding protein levels, respectively. Cellular MDR could be reverted about 70% (A2780RCIS), 95% (257RNOV), and 100% (257RDB). Additionally, the MTMR reversed mitoxantrone accumulation entirely, and daunorubicin accumulation about 90% in stomach carcinoma cells, respectively. Taken together, the MTMRs capability of simultaneous silencing of multiple genes provides an effective instrument to knockdown genes of interest. RNA Technologie Ribozyme ABC Transporter MDR ABCG2 ABCC2 ABCB1 RNA technology ribozymes ABC transporter MDR ABCG2 ABCC2 ABCB1 570 Biowissenschaften, Biologie 32 Biologie XD 3000 XH 3200 ddc:570
84	Untersuchungen zum Fettsäuretransport durch zelluläre und peroxisomale Membranen / Investigation of fatty acid transport across cellular and peroxisomal membranes Scharnewski, Michael 19 January 2010 (has links) No description available. 570 Biowissenschaften, Biologie Mathematics and Computer Science Fettsäuretransport ABC-Transporter Acyl-CoA-Synthetase Acyl-CoA-Thioesterase fatty acid transport ABC-transporter acyl-CoA synthetase acyl-CoA thioesterase 35.78 42.13 42.30 42.43 WUE200 WVE200 WVE410
85	Bio-crude transcriptomics: Gene discovery and metabolic network reconstruction for the biosynthesis of the terpenome of the hydrocarbon oil-producing green alga, Botryococcus braunii race B (Showa)* Molnar, Istvan, Lopez, David, Wisecaver, Jennifer, Devarenne, Timothy, Weiss, Taylor, Pellegrini, Matteo, Hackett, Jeremiah January 2012 (has links) BACKGROUND:Microalgae hold promise for yielding a biofuel feedstock that is sustainable, carbon-neutral, distributed, and only minimally disruptive for the production of food and feed by traditional agriculture. Amongst oleaginous eukaryotic algae, the B race of Botryococcus braunii is unique in that it produces large amounts of liquid hydrocarbons of terpenoid origin. These are comparable to fossil crude oil, and are sequestered outside the cells in a communal extracellular polymeric matrix material. Biosynthetic engineering of terpenoid bio-crude production requires identification of genes and reconstruction of metabolic pathways responsible for production of both hydrocarbons and other metabolites of the alga that compete for photosynthetic carbon and energy.RESULTS:A de novo assembly of 1,334,609 next-generation pyrosequencing reads form the Showa strain of the B race of B. braunii yielded a transcriptomic database of 46,422 contigs with an average length of 756 bp. Contigs were annotated with pathway, ontology, and protein domain identifiers. Manual curation allowed the reconstruction of pathways that produce terpenoid liquid hydrocarbons from primary metabolites, and pathways that divert photosynthetic carbon into tetraterpenoid carotenoids, diterpenoids, and the prenyl chains of meroterpenoid quinones and chlorophyll. Inventories of machine-assembled contigs are also presented for reconstructed pathways for the biosynthesis of competing storage compounds including triacylglycerol and starch. Regeneration of S-adenosylmethionine, and the extracellular localization of the hydrocarbon oils by active transport and possibly autophagy are also investigated.CONCLUSIONS:The construction of an annotated transcriptomic database, publicly available in a web-based data depository and annotation tool, provides a foundation for metabolic pathway and network reconstruction, and facilitates further omics studies in the absence of a genome sequence for the Showa strain of B. braunii, race B. Further, the transcriptome database empowers future biosynthetic engineering approaches for strain improvement and the transfer of desirable traits to heterologous hosts. Biofuel Terpene biosynthesis Fatty acid biosynthesis Triacylglycerol biosynthesis Starch biosynthesis ABC transporter Autophagy Transcriptome Botryococcus braunii Botryococcene
86	Papel do transportador ABC PRP1 na resistência à pentamidina em Leishmania spp. / Role of the ABC transporter PRP1 in pentamidine resistance in Leishmania spp. Coelho, Adriano Cappellazzo 03 September 2007 (has links) Pouco se sabe sobre o mecanismo de ação da pentamidina, um composto utilizado no tratamento das leishmanioses. Para uma melhor compreensão do mecanismo de ação assim como o mecanismo de resistência à pentamidina, foi isolado um gene que codifica um membro da família de transportadores ABC, chamado PRP1 capaz de conferir resistência à pentamidina em formas promastigotas e amastigotas de Leishmania spp. O tratamento dos transfectantes que superexpressam a PRP1 com pentamidina em presença de concentrações não tóxicas de verapamil, um inibidor de transportadores ABC, foi capaz de reverter a resistência mediada por esse transportador. Foram ainda isolados nesse estudo duas linhagens de L. amazonensis resistentes à pentamidina. A análise molecular dos parasitos indicou que esses mutantes não apresentaram nenhuma amplificação de DNA, inclusive do gene PRP1 que também não se mostrou superexpresso em ambas as linhagens. As duas linhagens resistentes à pentamidina tiveram sua resistência revertida quando tratadas com verapamil, indicando que o mecanismo de resistência nesses mutantes pode estar associado a um transportador ABC. Os resultados obtidos nesse estudo fornecem dados para uma melhor compreensão do mecanismo de resistência à pentamidina e sugerem um provável potencial da associação pentamidina e verapamil no tratamento da doença. / Little it is known about the mechanism of action of pentamidine, an compound used for leishmaniases chemotherapy. To understand the mechanism of action and resistance of pentamidine, it was isolated a gene that codifies a member of ABC transporter family, named as PRP1 able to confer pentamidine resistance in promastigotes and amastigotes of Leishmania spp. Treatment of transfectants overexpressing PRP1 with pentamidine in presence of non toxic concentration of verapamil, an inhibitor of ABC transporters, was able to reverse the drug resistance mediated by this transporter. Two lines of L. amazonensis resistant to pentamidine were selected. Molecular analysis of parasites indicated that these mutants do not contain amplified DNA, including the PRP1 gene either not associated with overexpression in both lines. The two lines resistant to pentamidine had their resistance reversed when treated with verapamil, indicating that the mechanism of resistance may be associated to an ABC transporter. The results of this work lead to new insights for a better understanding of the mechanism of of resistance suggesting a probably potencial of pentamidine and verapamil association in the chemotherapy. Leishmania Leishmania ABC transporter Pentamidina Pentamidine Resistance to drugs Resistência à drogas Transfecção gene Transfecção gênica Transportador ABC
87	Die Bedeutung der ABC-Transportsysteme ABCB1 und Abcb11 in der Arzneimitteltherapie und bei cholestatischen Lebererkrankungen Gerloff, Thomas 05 March 2004 (has links) ABC-Transmembrantransporter sind an der Aufnahme, Verteilung und Ausscheidung vieler Arznei- und Fremdstoffe beteiligt. Sie spielen eine Schlüsselrolle in der Pharmakokinetik und in der Ausscheidung toxischer endogener oder exogener Substanzen. Das Ziel der hier präsentierten Untersuchungen war deshalb, den Einfluss genetischer Polymorphismen des bekanntesten Vertreters dieser Proteinfamilie, MDR1 (ABCB1) zu untersuchen. Darüberhinaus sollte der ebenfalls zur ABC-Transporterfamilie gehörende hepatozelluläre Exporter für monoanionische Gallensäuren identifiziert und charakterisiert werden. MDR1 erwies sich als ein hochpolymorphes Gen mit zahlreichen Einzelbasenaustauschen (SNPs). Die meisten SNPs waren intronisch oder stumm. Für den nichtkodierenden SNP im Exon 26 3435C>T ergab sich bei homozygoten Trägern des T-Allels eine im Vergleich zum Wildtyp geringere intestinale P-Glykoprotein Expression mit einer entsprechend höheren und schnelleren Absorption von Digoxin. Die Auswertung pharmakokinetischer Profile von Digoxin in Individuen mit MDR1-Haplotypen der miteinander verbundenen SNPs in Exon 21 2677 und Exon 26 3435 untermauerte die beobachteten pharmakogenetischen Effekte. Nach oraler Einzelgabe von 1 mg Digoxin konnten wahrscheinlich aufgrund der Überschreitung der P-Glykoprotein Transportkapazität keine genotypischen Unterschiede beobachtet werden. Der biliäre Exporter für monoanionische Gallensäuren (Bsep) konnte als ein 160 kDa Glykoprotein aus einer Rattenleber cDNA-Bibliothek identifiziert werden und gehört ebenfalls zur ABC Transporter-Familie. Die transkriptionelle Regulation und Möglichkeiten der Modulation der Expression des Bsep-Gens wurden in vitro und in Tiermodellen der Cholestase untersucht. Dabei zeigte sich, dass Gallensäuren über ein proximales FXRE-Motiv die Bsep Promotoraktivität stimulierten. Arzneistoffe hatten ebenfalls einen Einfluss auf die Transkription des Bsep-Gens. Die adaptive Regulation hepatozellulärer Transporter während der Cholestase ergab eine verminderte Expression der meisten basolateralen Aufnahmetransporter und eine unveränderte oder heraufregulierte Proteinmasse kanalikulärer (apikaler) Efflux-Transporter. Dieses Regulationsmuster dient dem Schutz der Leberzelle, indem eine intrazelluläre Anreicherung toxischer Gallensäuren vermindert und der Gallefluss für eine intakte biliäre Clearance aufrechterhalten wird. / ABC transmembrane transporters are involved in absorption, distribution and excretion of diverse drugs and xenobiotics. They are key factors in pharmacokinetics and in the elimination of toxic endogenous or exogenous compounds. Therefore, the aim of the present study was to investigate the influence of genetic polymorphisms of the best known member of this protein family, MDR1 (ABCB1). In addition, the identity of another ABC transporter assumed to be the major hepatocellular export pump for monoanionic bile acids should be revealed and characterized. MDR1 turned out as a highly polymorphic gene with many single nucleotide polymorphisms (SNPs). Most of the SNPs were intronic or silent. Homozygous carriers of the non-coding SNP in exon 26 3435C>T had lower intestinal P-glycoprotein expression rates and thus enhanced absorption of the model compound digoxin as compared to wildtype controls. The analysis of pharmacokinetic profiles in different MDR1-haplotypes of the linked SNPs in exon 21 2677 and exon 26 3435 supported the above data. An oral single dose of 1 mg digoxin did not result in genotypic differences of tested genotypes, probably because this dose was above the maximal transport capacity of P-glycoprotein. The biliary export pump for monoanionic bile acids (Bsep) was identified as an 160 kDa glycoprotein of the ABC transporter family by screening a rat liver cDNA library. The transcriptional regulation and modulatory factors of Bsep (Abcb11) gene expression were analyzed in vitro and in animal models of cholestasis. The promoter activity of Bsep was stimulated by bile acids via a proximal FXRE motif. Drugs were also able to modify Bsep gene transcription. Adaptive regulation of hepatocellular transporters during cholestasis followed a pattern of diminished expression of most basolateral uptake carrier systems and maintained or even upregulated protein mass of canalicular (apical) exporters. This pattern serves as a protective mechanism of the liver cells preventing intracellular accumulation of toxic bile acids and providing unimpaired biliary flow and clearance. MDR1 ABC-Transporter Pharmakogenetik Bsep MDR1 pharmacogenetics ABC-transporters Bsep 610 Medizin 33 Medizin VS 5900 ddc:610
88	Intestinal barriers to oral drug absorption: Cytochrome P450 3A and ABC-transport proteins Engman, Helena January 2003 (has links) <p>The subject of this thesis was to study two intestinal barriers to oral drug bioavailability, drug efflux proteins of the ABC-transporter family, and in particular ABCB1/P-glycoprotein (Pgp), and the drug metabolizing enzyme cytochrome P450 (CYP) 3A4. At the onset of this thesis, similarities between CYP3A4 and Pgp in terms of their tissue distribution and gene regulation, along with overlapping substrate specificities, had generated the hypothesis that CYP3A4 and Pgp may have a complementary function and thus form a coordinated intestinal barrier to drug absorption and gut wall metabolism.</p><p>In the first part of this thesis, a cell culture model of the intestinal epithelium that expressed both functional Pgp and CYP3A4 was developed. This model was then used to investigate the steroselective drug efflux and metabolism of R/S-verapamil. In summary, the results indicated that the two barriers in the cell culture model were in agreement with those in the human intestine.</p><p>Both ABC-transporters and CYPs are regulated by drugs that interact with nuclear receptors. However, while the regulation of CYPs is quite well understood, less is known about how repeated drug administration regulates the most abundantly expressed ABC-transporters. Therefore, in the second part of this thesis, the effects of repeated drug administration on the gene regulation of four ABC-transporters and CYP3A4 were studied in intestinal epithelial cell lines in vitro and in the perfused human jejunum in vivo. The in vitro studies revealed that the ABC-transporters are induced by drugs that interact with slightly different sets of nuclear receptors. The in vivo study showed that repeated oral administration of St John’s wort decreased the bioavailability of verapamil, predominantly by induction of intestinal CYP3A4. This part of the thesis provides new information about the regulation of ABC-transporters, shows that the intestinal metabolism is the most significant barrier to oral bioavailability of verapamil and provides evidence for a clinically significant interaction between verapamil and St John’s wort in vivo.</p> Pharmaceutics oral drug delivery bioavailability human jejunum Caco-2 ABC-transporter P-glycoprotein CYP3A Galenisk farmaci Pharmaceutics Galenisk farmaci
89	Intestinal barriers to oral drug absorption: Cytochrome P450 3A and ABC-transport proteins Engman, Helena January 2003 (has links) The subject of this thesis was to study two intestinal barriers to oral drug bioavailability, drug efflux proteins of the ABC-transporter family, and in particular ABCB1/P-glycoprotein (Pgp), and the drug metabolizing enzyme cytochrome P450 (CYP) 3A4. At the onset of this thesis, similarities between CYP3A4 and Pgp in terms of their tissue distribution and gene regulation, along with overlapping substrate specificities, had generated the hypothesis that CYP3A4 and Pgp may have a complementary function and thus form a coordinated intestinal barrier to drug absorption and gut wall metabolism. In the first part of this thesis, a cell culture model of the intestinal epithelium that expressed both functional Pgp and CYP3A4 was developed. This model was then used to investigate the steroselective drug efflux and metabolism of R/S-verapamil. In summary, the results indicated that the two barriers in the cell culture model were in agreement with those in the human intestine. Both ABC-transporters and CYPs are regulated by drugs that interact with nuclear receptors. However, while the regulation of CYPs is quite well understood, less is known about how repeated drug administration regulates the most abundantly expressed ABC-transporters. Therefore, in the second part of this thesis, the effects of repeated drug administration on the gene regulation of four ABC-transporters and CYP3A4 were studied in intestinal epithelial cell lines in vitro and in the perfused human jejunum in vivo. The in vitro studies revealed that the ABC-transporters are induced by drugs that interact with slightly different sets of nuclear receptors. The in vivo study showed that repeated oral administration of St John’s wort decreased the bioavailability of verapamil, predominantly by induction of intestinal CYP3A4. This part of the thesis provides new information about the regulation of ABC-transporters, shows that the intestinal metabolism is the most significant barrier to oral bioavailability of verapamil and provides evidence for a clinically significant interaction between verapamil and St John’s wort in vivo. Pharmaceutics oral drug delivery bioavailability human jejunum Caco-2 ABC-transporter P-glycoprotein CYP3A Galenisk farmaci Pharmaceutics Galenisk farmaci
90	The Role of the sia and siu ABC-Type Transporters in Iron Utilization and Virulence in Streptococcus pyogenes Montanez, Griselle Enid 12 January 2006 (has links) A limited understanding of iron uptake mechanisms is available for Streptococcus pyogenes, a hemolytic human pathogen capable of using a variety of hemoproteins in addition to ferric and ferrous iron. This study characterizes the transporters of iron-complexes siuADBG (for streptococcal iron uptake) and siaABC (for streptococcal iron acquisition). These ABC-type transporters are encoded by iron regulated operons and their protein products are homologous to components of heme and siderophore transporters found in both Gram-positive and Gram-negative bacteria. Mutants of the membrane permeases siuG and siaB were constructed and characterized. Mutations in both transporters demonstrated growth reduction in comparison to the parent strain when grown in complex medium containing iron in the form of hemoglobin. The addition of heme to the growth medium inhibited ferric uptake by the wild-type while the addition of protoporphyrin IX did not, suggesting that heme utilization as an iron source is responsible for the inhibition of ferric accumulation. Inactivation of siuG reduced the ability of heme to inhibit ferric incorporation by the cells. Inactivation of siaB in addition to siuG had a cumulative effect, indicating that both siu and sia transporters are involved in heme utilization. We also demonstrated that purified rSiaA, the surface receptor of SiaABC, binds heme and hemoglobin in vitro, and we propose a mechanism of heme binding by SiaA. Studies in a zebrafish infection model revealed that the siuG mutant was attenuated in producing disease. While the siaB mutant also presented virulence attenuation, infection by this mutant was characterized by an increase in the host inflammatory response. These observations show that iron acquisition is important for S. pyogenes virulence. We propose that the SiaABC and SiuADBG, together with the multi-metal transporter MtsABC, are involved in iron acquisition from different iron sources present in the human body, thus contributing to the survival and pathogenesis of S. pyogenes. ABC transporter bacteria ferrichrome GAS heme hemoglobin hemoproteins iron transport sia siu Streptococcus pyogenes virulence zebrafish Biology, general

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