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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
11

Lipid peroxidation and antioxidants in humans effects of oxidative stress and dietary n-3 fatty acids /

Oostenbrug, Gerard Simon. January 1996 (has links)
Proefschrift Universiteit Maastricht. / Met lit. opg. - Met samenvatting in het Nederlands.
12

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 ("secretases"). 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.
13

Interactions of FCHo2 with lipid membranes

Chwastek, Grzegorz 29 November 2013 (has links) (PDF)
Endocytosis is one of the most fundamental mechanisms by which the cell communicates with its surrounding. Specific signals are transduced through the cell membrane by a complex interplay between proteins and lipids. Clathrin depended endocytosis is one of important signalling pathways which leads to budding of the plasmalemma and a formation of endosomes. The FCHo2 is an essential protein at the initial stage of the this process. In is a membrane binding protein containing BAR (BIN, Amphiphysin, Rvs) domain which is responsible for a membrane binding. Although numerous valuable work on BAR proteins was published recently, the mechanistic description of a BAR domain functionality is missing. In present work we applied in vitro systems in order to gain knowledge about molecular basis of the activity of the FCHo2 BAR domain. In our studies we used supported lipid bilayers (SLBs) and lipid monolayers as s model membrane system. The experiments were carried out with a minimal number of components including the purified FCHo2 BAR domain. Using SLBs we showed that the BAR domain can bind to entirely flat bilayers. We also demonstrated that these interactions depend on the negatively charged lipid species incorporated in the membrane. We designed an assay which allows to quantify the membrane tubulation. We found out that the interaction of the FCHo2 BAR domain with the lipid membrane is concentration dependent. We showed that an area of the bilayer deformed by the protein depends on the amount of the used BAR domain. In order to study the relation between the mobility of lipids and the activity of FCHo2 BAR domain we designed a small-volume monolayer trough. The design of this micro-chamber allows for the implementation of the light microscopy. We demonstrated that the measured lipid diffusion in the monolayer by our new approach is in agreement with literature data. We carried out fluorescence correlation spectroscopy (FCS) experiments at different density of lipids at the water-air interface.We showed that the FCHo2 BAR domain binding affinity is proportional to the mean molecular area (MMA). We additionally demonstrated that the increased protein binding is correlated with the higher lipid mobility in the monolayer. Additionally, by curing out high-speed atomic force microscopy (hsAFM) we acquired the structural information about FCHo2 BAR domains orientation at the membrane with a high spatio-temporal resolution. Obtained data indicate the BAR domains interact witheach other by many different contact sites what results in a variety of protein orientations in a protein assemble.
14

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 ("secretases"). 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.
15

Interactions of FCHo2 with lipid membranes

Chwastek, Grzegorz 06 February 2013 (has links)
Endocytosis is one of the most fundamental mechanisms by which the cell communicates with its surrounding. Specific signals are transduced through the cell membrane by a complex interplay between proteins and lipids. Clathrin depended endocytosis is one of important signalling pathways which leads to budding of the plasmalemma and a formation of endosomes. The FCHo2 is an essential protein at the initial stage of the this process. In is a membrane binding protein containing BAR (BIN, Amphiphysin, Rvs) domain which is responsible for a membrane binding. Although numerous valuable work on BAR proteins was published recently, the mechanistic description of a BAR domain functionality is missing. In present work we applied in vitro systems in order to gain knowledge about molecular basis of the activity of the FCHo2 BAR domain. In our studies we used supported lipid bilayers (SLBs) and lipid monolayers as s model membrane system. The experiments were carried out with a minimal number of components including the purified FCHo2 BAR domain. Using SLBs we showed that the BAR domain can bind to entirely flat bilayers. We also demonstrated that these interactions depend on the negatively charged lipid species incorporated in the membrane. We designed an assay which allows to quantify the membrane tubulation. We found out that the interaction of the FCHo2 BAR domain with the lipid membrane is concentration dependent. We showed that an area of the bilayer deformed by the protein depends on the amount of the used BAR domain. In order to study the relation between the mobility of lipids and the activity of FCHo2 BAR domain we designed a small-volume monolayer trough. The design of this micro-chamber allows for the implementation of the light microscopy. We demonstrated that the measured lipid diffusion in the monolayer by our new approach is in agreement with literature data. We carried out fluorescence correlation spectroscopy (FCS) experiments at different density of lipids at the water-air interface.We showed that the FCHo2 BAR domain binding affinity is proportional to the mean molecular area (MMA). We additionally demonstrated that the increased protein binding is correlated with the higher lipid mobility in the monolayer. Additionally, by curing out high-speed atomic force microscopy (hsAFM) we acquired the structural information about FCHo2 BAR domains orientation at the membrane with a high spatio-temporal resolution. Obtained data indicate the BAR domains interact witheach other by many different contact sites what results in a variety of protein orientations in a protein assemble.

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