Global ETD Search

1	Rasterkraftmikroskopische Untersuchungen an nativen biologischen Membranen und Sucroseporin als Beispiel eines rekonstituierten Membranproteins Weiland, Ulrich Michael. Unknown Date (has links) (PDF) Universiẗat, Diss., 2001--Konstanz.
2	Das Photoreaktionszentrum aus Rhodobacter sphaeroides als Modellmembranprotein zur Reinigung, Rekonstitution in Liposomen aus ungewöhnlichen Phospholipiden, Charakterisierung und heterologen Expression Peters, Heinz. January 2001 (has links) Stuttgart, Univ., Diss., 2001.
3	Charakterisierung der Aktivität und Inhibition des rekombinanten, spannungsgesteuerten Protonenkanals HV1: Funktionelle Rekonstitution in unilamellare Vesikel / Characterisation of activation and inhibition of the recombinant voltage-gated proton channel Hv1: functional reconstitution in unilamellare vesicles Gerdes, Benjamin 08 December 2017 (has links) No description available. 540 Hv1 spannungsgesteuerter Protonenkanal funktionelle Rekonstitution Impedanz Spektroskopie SEIRA Hv1 voltage-gated proton channel 2-guanidinbenzimidazole impedance spectroscopy surface enhanced infrared absorption Oregon Green 488 Chemie (PPN62138352X)
4	Chemische Totalsynthese der γ-Untereinheit der Escherichia coli ATP-Synthase und Rekonstitution des (αβ)3γ-Minimalkomplexes Wintermann, Frank 13 December 2012 (has links) In dieser Arbeit werden die Synthese eines 286-Reste-langen Proteins, der γ-Untereinheit der ATP-Synthase, seine Rückfaltung und Rekonstitution zum aktiven Proteinkomplex gezeigt. Peptidsynthese Ligation ATP-Synthase EF1 Dissoziation Rekonstitution γ-Untereinheit Escherichia coli Totalsynthese native chemical ligation NCL SPPS ddc:570 ddc:540
5	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
6	Reconstituting APP and BACE in proteoliposomes to characterize lipid requirements for β-secretase activity / Rekonstitution der Proteine APP und BACE in Proteoliposomen zur Bestimmung des Einflusses von Lipiden auf die Regulation der beta-sekretase Aktivität Kalvodova, Lucie 14 September 2006 (has links) (PDF) Proteolytic processing of the amyloid precursor protein (APP) may lead to the formation of the Abeta peptide, the major constituent of amyloid plaques in Alzheimer`s disease. The full-length APP is a substrate for at least 2 different (alpha and beta) proteases (&quot;secretases&quot;). The beta-secretase, BACE, cleaves APP in the first step of processing leading to the formation of the neurotoxic Abeta. BACE competes for APP with alpha-secretase, which cleaves APP within its Abeta sequence, thus precluding Abeta formation. It is thus important to understand how is the access of the alpha- and beta-secretase to APP regulated and how are the individual activities of these secretases modulated. Both these regulatory mechanisms, access to substrate and direct activity modulation, can be determined by the lipid composition of the membrane. Integral membrane proteins (like APP and BACE), can be viewed as solutes in a two-dimensional liquid membrane, and as such their state, and biological activity, critically depend on the physico-chemical character (fluidity, curvature, surface charge distribution, lateral domain heterogeneity etc.) of the lipid bilayer. These collective membrane properties will influence the activity of embedded membrane proteins. In addition, activity regulation may involve a direct interaction with a specific lipid (cofactor or co-structure function). Interactions of membrane proteins are furthermore affected by lateral domain organization of the membrane. Previous results had suggested that the regulation of the activity of the alpha- and beta-secretases and of their access to APP is lipid dependent, and involves lipid rafts. Using the baculovirus expression system, we have purified recombinant human full-length APP and BACE to homogeneity, and reconstituted them in large (~100nm, LUVs) and giant (10-150microm, GUVs) unilamellar vesicles. Using a soluble peptide substrate mimicking the beta-cleavage site of APP, we have examined the involvement of individual lipid species in modulating BACE activity in LUVs of various lipid compositions. We have identified 3 groups of lipids that stimulate proteolytic activity of BACE: 1.cerebrosides, 2.anionic glycerophospholipids, 3. cholesterol. Furthermore, we have co-reconstituted APP and BACE together in LUVs and demonstrated that BACE cleaves APP at the correct site, generating the beta-cleaved ectodomain identical to that from cells. We have developed an assay to quantitatively follow the beta-cleavage in proteoliposomes, and we have shown that the rate of cleavage in total brain lipid proteoliposomes is higher than in phosphatidylcholine vesicles. We have also studied partitioning of APP and BACE in GUVs between liquid ordered (lo) and liquid disordered (ld) phases. In this system, significant part of the BACE pool (about 20%) partitions into the lo phase, and its partitioning into lo phase can be further enhanced by cross-linking of membrane components. Only negligible fraction of APP can be found in the lo phase. We continue to study the behavior of co-reconstituted APP and BACE in GUVs The work presented in this thesis has yielded some interesting results and raised further questions. One of the important assignments of this project will in the next stage be the characterization of the impact of membrane domain organization on the beta-cleavage. Different domain arrangements that can be hypothesized in cell membranes can be modeled by varying the degree of phase fragmentation in proteoliposomes comprising reconstituted APP and BACE. APP BACE lipid rafts beta-secretase proteoliposomes detergent-mediated reconstitution GUV cholesterol lipids APP BACE lipid rafts beta-Sekretase Proteoliposomen GUV Cholesterin Lipiden ddc:570 rvk:WD 5400 Cholesterin Lipide Proteine Sekretorische Proteine Liposom
7	Reconstituting APP and BACE in proteoliposomes to characterize lipid requirements for β-secretase activity Kalvodova, Lucie 11 September 2006 (has links) Proteolytic processing of the amyloid precursor protein (APP) may lead to the formation of the Abeta peptide, the major constituent of amyloid plaques in Alzheimer`s disease. The full-length APP is a substrate for at least 2 different (alpha and beta) proteases (&quot;secretases&quot;). The beta-secretase, BACE, cleaves APP in the first step of processing leading to the formation of the neurotoxic Abeta. BACE competes for APP with alpha-secretase, which cleaves APP within its Abeta sequence, thus precluding Abeta formation. It is thus important to understand how is the access of the alpha- and beta-secretase to APP regulated and how are the individual activities of these secretases modulated. Both these regulatory mechanisms, access to substrate and direct activity modulation, can be determined by the lipid composition of the membrane. Integral membrane proteins (like APP and BACE), can be viewed as solutes in a two-dimensional liquid membrane, and as such their state, and biological activity, critically depend on the physico-chemical character (fluidity, curvature, surface charge distribution, lateral domain heterogeneity etc.) of the lipid bilayer. These collective membrane properties will influence the activity of embedded membrane proteins. In addition, activity regulation may involve a direct interaction with a specific lipid (cofactor or co-structure function). Interactions of membrane proteins are furthermore affected by lateral domain organization of the membrane. Previous results had suggested that the regulation of the activity of the alpha- and beta-secretases and of their access to APP is lipid dependent, and involves lipid rafts. Using the baculovirus expression system, we have purified recombinant human full-length APP and BACE to homogeneity, and reconstituted them in large (~100nm, LUVs) and giant (10-150microm, GUVs) unilamellar vesicles. Using a soluble peptide substrate mimicking the beta-cleavage site of APP, we have examined the involvement of individual lipid species in modulating BACE activity in LUVs of various lipid compositions. We have identified 3 groups of lipids that stimulate proteolytic activity of BACE: 1.cerebrosides, 2.anionic glycerophospholipids, 3. cholesterol. Furthermore, we have co-reconstituted APP and BACE together in LUVs and demonstrated that BACE cleaves APP at the correct site, generating the beta-cleaved ectodomain identical to that from cells. We have developed an assay to quantitatively follow the beta-cleavage in proteoliposomes, and we have shown that the rate of cleavage in total brain lipid proteoliposomes is higher than in phosphatidylcholine vesicles. We have also studied partitioning of APP and BACE in GUVs between liquid ordered (lo) and liquid disordered (ld) phases. In this system, significant part of the BACE pool (about 20%) partitions into the lo phase, and its partitioning into lo phase can be further enhanced by cross-linking of membrane components. Only negligible fraction of APP can be found in the lo phase. We continue to study the behavior of co-reconstituted APP and BACE in GUVs The work presented in this thesis has yielded some interesting results and raised further questions. One of the important assignments of this project will in the next stage be the characterization of the impact of membrane domain organization on the beta-cleavage. Different domain arrangements that can be hypothesized in cell membranes can be modeled by varying the degree of phase fragmentation in proteoliposomes comprising reconstituted APP and BACE. info:eu-repo/classification/ddc/570 ddc:570
8	Spectroscopic Investigation of Conformational Transitions in the Copper-transporting P1B-ATPase CopA from Legionella pneumophila Sayed, Ahmed 22 May 2015 (has links) (PDF) All cells maintain essential metal nutrients at optimal levels by metal homeostasis. P-type ATPases, a crucial superfamily of integral membrane proteins, are involved in the active transport of metal ions across biological membranes driven by the motive force of ATP- hydrolysis. The PIB-type ATPase subfamily, also called CPx-ATPases, fulfills a key role in heavy metal homoeostasis among the most widespread species from bacteria to human. In humans, the defect in copper transporters is the direct cause of severe neurological and hepatic disorders such as Wilson and Menkes diseases, therefore, understanding the molecular function of these pumps is of paramount importance in human health. Cu+-ATPases have two transmembrane metal binding sites (TM-MBS) and three cytosolic domains, namely the actuator (A-domain) and phosphorylation and nucleotide-binding domain (PN), and regulatory N-terminal heavy metal binding domain (HMBD). Here, we have studied the Legionella pneumophila CopA (LpCopA) and its isolated cytosolic domains to improve our understanding of the functional interaction of the protein domains during metal transport relate this to the known structure of this ATPase. To elucidate how cytosolic ligands (Cu+ and nucleotide) stimulate the interactions among the cytosolic domains and may transmit conformational changes to the TM-MBS, the interactions among recombinant isolated cytosolic domains were first examined biochemically by co-purification and spectroscopically by circular dichroism, time-resolved fluorescence and site-directed fluorescent labeling assays. The Cu+-dependent interaction between the A-domain and HMBD has been postulated as a mechanism for activating the ATPase cycle. This question was addressed here by studying copper-dependent interactions between the isolated expressed domains. Spectroscopic evidence is provided that an HMBD-A complex is formed in the presence of Cu+ which binds with 100-200 nM affinity to the recombinant HMBD. In contrast, the A-domain interacts with the PN domain in a nucleotide-dependent fashion. This molecular recognition is required for the dephosphorylation step in the catalytic cycle. The interaction was investigated in more detail by the use of a decameric peptide derived from the PN-binding interface of the A-domain and carrying the conserved TGE-motif involved in dephosphorylation. Its binding to the isolated PN domain in a weakly nucleotide-dependent manner, is demonstrated here by stopped-flow fluorescence spectroscopy. Several ATPase assays were modified to assess the functionality of the PN-domain and full length LpCopA. The peptide was found to reduce the catalytic turnover of full length LpCopA. This agrees with the expected slowing down of the reformation of the PN-A-domain interaction since the peptide occupies their binding interface. Thus, the synthetic peptide provides a means to study specifically the influence of PN-A-domain interactions on the structure and function of LpCopA. This was done by time-correlated single photon counting (TCSPC) method. The time-dependent Stokes shift of the environmentally sensitive fluorophore BADAN which was covalently attached to the conserved CPC-motif in the TM-MBS was measured. The data indicate that the interior of the ATPase is hydrated and the mobility of the intra-protein water varies from high to low at C382 at the “luminal side” and C384 at the “cytosolic side” of the TM-MBS, respectively. This finding is consistent with the recent MD simulation of LpCopA, bringing the first experimental evidence on a luminal-open conformation of E2~P state. The A-domain-derived decapeptide, although binding to the cytosolic head piece, induces structural changes also at the TM-MBS. The peptide-stabilized state (with a disrupted PN-A interface) renders the C384 environment more hydrophobic as evidenced by TCSPC. Taken together, the data from cytosolic domain interactions, ATPase assays and of time-dependent Stoke shift analyses of BADAN-labeled LpCopA reveal the presence of hydrated intramembraneous sites whose degree of hydration is regulated by the rearrangement of cytosolic domains, particularly during the association and dissociation of the PN-A domains. Copper affects this arrangement by inducing the linkage of the A-domain to the HMBD. The latter appears to play not only an autoinhibitory but also a chaperone-like role in transferring Cu+ to the TM-MBS during catalytic turnover. LpCopA CPx-ATPase Legionella pneumophila Kupfer-Transport-ATPase Cytosolic Domains Interaktion Spektroskopie TCSPC Stopped-Flow Membranprotein Strukturdynamik die synthetische Biologie Lipid Protein Rekonstitution CPC Motiv LpCopA CPx-ATPase Legionella pneumophila Copper-transporting ATPase Cytosolic domains interaction spectroscopy TCSPC Stopped-flow membrane protein structural dynamics synthetic biology lipid protein reconstitution CPC motif ddc:570 rvk:WF 5700
9	Spectroscopic Investigation of Conformational Transitions in the Copper-transporting P1B-ATPase CopA from Legionella pneumophila Sayed, Ahmed 23 March 2015 (has links) All cells maintain essential metal nutrients at optimal levels by metal homeostasis. P-type ATPases, a crucial superfamily of integral membrane proteins, are involved in the active transport of metal ions across biological membranes driven by the motive force of ATP- hydrolysis. The PIB-type ATPase subfamily, also called CPx-ATPases, fulfills a key role in heavy metal homoeostasis among the most widespread species from bacteria to human. In humans, the defect in copper transporters is the direct cause of severe neurological and hepatic disorders such as Wilson and Menkes diseases, therefore, understanding the molecular function of these pumps is of paramount importance in human health. Cu+-ATPases have two transmembrane metal binding sites (TM-MBS) and three cytosolic domains, namely the actuator (A-domain) and phosphorylation and nucleotide-binding domain (PN), and regulatory N-terminal heavy metal binding domain (HMBD). Here, we have studied the Legionella pneumophila CopA (LpCopA) and its isolated cytosolic domains to improve our understanding of the functional interaction of the protein domains during metal transport relate this to the known structure of this ATPase. To elucidate how cytosolic ligands (Cu+ and nucleotide) stimulate the interactions among the cytosolic domains and may transmit conformational changes to the TM-MBS, the interactions among recombinant isolated cytosolic domains were first examined biochemically by co-purification and spectroscopically by circular dichroism, time-resolved fluorescence and site-directed fluorescent labeling assays. The Cu+-dependent interaction between the A-domain and HMBD has been postulated as a mechanism for activating the ATPase cycle. This question was addressed here by studying copper-dependent interactions between the isolated expressed domains. Spectroscopic evidence is provided that an HMBD-A complex is formed in the presence of Cu+ which binds with 100-200 nM affinity to the recombinant HMBD. In contrast, the A-domain interacts with the PN domain in a nucleotide-dependent fashion. This molecular recognition is required for the dephosphorylation step in the catalytic cycle. The interaction was investigated in more detail by the use of a decameric peptide derived from the PN-binding interface of the A-domain and carrying the conserved TGE-motif involved in dephosphorylation. Its binding to the isolated PN domain in a weakly nucleotide-dependent manner, is demonstrated here by stopped-flow fluorescence spectroscopy. Several ATPase assays were modified to assess the functionality of the PN-domain and full length LpCopA. The peptide was found to reduce the catalytic turnover of full length LpCopA. This agrees with the expected slowing down of the reformation of the PN-A-domain interaction since the peptide occupies their binding interface. Thus, the synthetic peptide provides a means to study specifically the influence of PN-A-domain interactions on the structure and function of LpCopA. This was done by time-correlated single photon counting (TCSPC) method. The time-dependent Stokes shift of the environmentally sensitive fluorophore BADAN which was covalently attached to the conserved CPC-motif in the TM-MBS was measured. The data indicate that the interior of the ATPase is hydrated and the mobility of the intra-protein water varies from high to low at C382 at the “luminal side” and C384 at the “cytosolic side” of the TM-MBS, respectively. This finding is consistent with the recent MD simulation of LpCopA, bringing the first experimental evidence on a luminal-open conformation of E2~P state. The A-domain-derived decapeptide, although binding to the cytosolic head piece, induces structural changes also at the TM-MBS. The peptide-stabilized state (with a disrupted PN-A interface) renders the C384 environment more hydrophobic as evidenced by TCSPC. Taken together, the data from cytosolic domain interactions, ATPase assays and of time-dependent Stoke shift analyses of BADAN-labeled LpCopA reveal the presence of hydrated intramembraneous sites whose degree of hydration is regulated by the rearrangement of cytosolic domains, particularly during the association and dissociation of the PN-A domains. Copper affects this arrangement by inducing the linkage of the A-domain to the HMBD. The latter appears to play not only an autoinhibitory but also a chaperone-like role in transferring Cu+ to the TM-MBS during catalytic turnover. info:eu-repo/classification/ddc/570 ddc:570

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