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Apolipoprotein A5 Genetic Polymorphisms In Turkish Population And The Risk Of Ischemic StrokeSahin, Esra 01 September 2008 (has links) (PDF)
Stroke is the third leading cause of death and the most common cause of disabilities worldwide. Apolipoprotein A5 gene (APO A5), which encodes a 369 amino acid protein called Apolipoprotein AV (apo AV), has several single nucleotide polymorphisms (SNPs) found to be associated with altered triglyceride (TG) levels. Atherosclerosis is a major cause of ischemic stroke and this pathology may be associated with variability of TG levels. The main objective of this study was to investigate the coding region (c.553G> / T) and promoter region (-1131T/C) polymorphisms of the APO A5 gene as a risk factor for ischemic stroke.
The study group in Turkish population consisted of 198 unrelated ischemic stroke patients and 130 control subjects. There was no statistically significant difference between the groups with respect to age and gender. Total blood samples were obtained from Gü / lhane Military Medical Academy Hospital, Neurology Department, Ankara. In stroke patients, hypertension and diabetes were 2.5 times more common and high-density lipoprotein cholesterol (HDL-C) was significantly lower than controls. Logistic regression analysis showed that hypertension, diabetes and smoking were significant predictors of stroke. The frequency of risky alleles c.553T and -1131C were 0.003 and 0.098, respectively, in patients and were nearly the same with controls. The risk of hypertensive and diabetic individuals having ischemic stroke was higher in -1131C allele carriers (Odds ratio / OR= 3.4 and 6.4, respectively) than
-1131TT individuals (OR= 2.3 and 1.9, respectively). Stroke patients with
-1131C allele had significantly higher TG levels (1.70 mmol/L) and lower HDL-C levels (1.05 mmol/L) when compared to controls (1.35 mmol/L and 1.20 mmol/L, respectively) with the same genotype. Logistic regression analysis revealed elevated TG level to be associated with 2.2-fold and low levels of HDL-C to be associated with 1.8-fold increase in the risk of ischemic stroke versus control status.
This is the first study investigating the relation between APO A5 c.553G> / T polymorphism and stroke risk. Additionally, in Turkish population
-1131T/C polymorphism was analyzed for the first time in terms of its relation to ischemic stroke. The present study demonstrated that the frequency of risky alleles c.553T and-1131C were nearly the same in stroke patients and control subjects. Consequently, we decided that carrying minor alleles of c.553G> / T and-1131T/C polymorphisms do not constitute a risk for ischemic stroke.
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Die Bedeutung des Pyroglutamat-Abeta-Oligomer-Blutplasmaspiegels und des Apolipoprotein-E-Genotyps bei der Alzheimer-Krankheit / The relevance of oligomeric Pyroglutamate-Abeta in blood plasm and the Apolipoprotein-E-Genotype for the Alzheimer's Diseasevon Waldenfels, Gabriel 04 April 2012 (has links)
No description available.
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In Vitro Characterization of the Function of ABCA1: Effects of Naturally Occurring MutationsMok, Leo 12 February 2010 (has links)
The ATP-binding cassette (ABC) transporter, ABCA1, plays a pivotal role in reverse cholesterol transport, which is the elimination of excess sterols from peripheral cells and their transport to the liver for elimination. Early studies failed to detect significant ATPase activity, prompting the suggestion that ABCA1 was an ATP-regulated receptor, rather than an active transporter. We have provided evidence that ABCA1 can bind ATP and trap its hydrolysis product, ADP, in the presence of either ortho-vanadate or beryllium fluoride and Mg2+ or Mn2+. We have also shown that both nucleotide-binding domains (NBDs) trap nucleotide comparably, suggesting that ABCA1 is a functional ATPase. In addition, we have shown that ABCA1 can directly transport 25-hydroxycholesterol (25-OHC) in an ATP-dependent manner using a membrane vesicle uptake assay, and can do so when the physiological substrate acceptor apoA-I is replaced with BSA as a non-specific binding protein.
Although more than 50 naturally occurring missense mutations and polymorphisms in ABCA1 have been identified in individuals with HDL-C levels within the lowest 5th percentile of the general population, the extent to which many of these mutations affect ABCA1 function is not known and cannot be predicted. Naturally occurring extracellular loop (ECL) mutations W590S and C1477R have both been shown to effectively eliminate the ability to mediate lipid efflux, despite the fact that the W590S mutant protein retains the ability to bind apoA-I. We show that neither mutant can transport nor efflux 25-OHC, whether in the presence of apoA-I or BSA, despite apparently full retention of the ability to bind and trap nucleotide. This suggests that these two ECL mutations inhibit transport by a mechanism that is independent of their effect on apoA-I binding. By introduction of naturally occurring mutations in the NBDs, we show that although some mutations associated with Tangier Disease, such as N935S, essentially eliminate nucleotide trapping and substrate translocation, other polymorphisms such as L1026P and T2073A associated with low HDL-C, appear to be fully functional. Lastly, we observed differences in the behaviour of both wild-type and mutant forms of ABCA1-GFP depending on whether they were expressed in insect or mammalian cell lines. / Thesis (Ph.D, Pathology & Molecular Medicine) -- Queen's University, 2010-02-12 11:14:11.381
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Effect of gastric bypass and gastric banding on lipid absorption and their influence on glucose metabolismVizhul, Andrey Unknown Date
No description available.
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Biogénèse des lipoprotéines de haute densité (HDL): implication du transporteur ABCA1Hajj Hassan, Houssein 07 1900 (has links)
Les patients atteints de la maladie de Tangier présentent des niveaux très bas de lipoprotéines de haute densité (HDL), un facteur de risque pour le développement des maladies cardiovasculaires. In vivo, les HDL ont un effet protecteur important contre l’athérosclérose puisqu’elles effectuèrent le transport à rebours du cholestérol des tissus périphériques vers le foie. Or, la maladie de Tangier est causée par des mutations dans le gène du transporteur « ATP-binding cassette A1 » (ABCA1). Le modèle actuel stipule que ce transporteur assure la lipidation de l’apolipoprotéine A-I (apoA-I), la composante protéique majeure des HDL, pour former des particules HDL naissantes discoïdales. Un défaut dans la lipidation de l’apoA-I par l’ABCA1 abolit la biogénèse des HDL. Nous avons voulu étudier les sites d’interaction de l’ABCA1 avec son ligand (l’apoA-I), les voies de biogénèse impliquées, et l’implication des pré-β-HDL dans l’efflux du cholestérol par la voie de l’ABCA1. D’abord, nous avons utilisé un système de culture cellulaire (fibroblastes humaines et BHK-ABCA1-inductible) afin de déterminer les sites de liaison cellulaires de l’apoA-I, leurs localisations et l’implication de l’ABCA1. Nous avons trouvé que la majorité de l’apoA-I n’est pas associée à l’ABCA1 et, deux tiers de cet apoA-I, était à la membrane plasmique. Ensuite, Une étude plus détaillée examinait les voies de lipidation de l’apoA-I, soit au niveau de la membrane plasmique (MP), soit aux compartiments intracellulaires (CICs). Nous avons montré que la lipidation de l’apoA-I a lieu aux deux niveaux (MP et CICs) selon deux voies différentes cinétiquement. Finalement, nous avons montré que les pré-β-HDL effluent aussi (efficacement que l’apoA-I) le cholestérol par la voie de l’ABCA1. Ces observations réunies démontrent que 1) la majorité de l’apoA-I s’est trouvé non-associée à l’ABCA1; 2) deux tiers de l’apoA-I s’associent a la membrane plasmique; 3) la lipidation de l’apoA-I se fait en partie à la membrane plasmique et, par la voie de retro-endocytose du complexe apoA-I/ABCA1. / Patients affected with Tangier disease show abnormal low levels of high density lipoproteins (HDL), a risk factor for the development of cardiovascular diseases. In vivo, HDL has an important protective effect against atherosclerosis since they accomplish the reverse cholesterol transport from peripheral tissues towards the liver. However, Tangier disease is caused by mutations in the gene of the transporter “ATP-binding cassette A1” (ABCA1). The current model believe that ABCA1 promotes the lipidation of apolipoprotein AI (apoA-I), the major protein component of HDLs, to form nascent discoid HDL particles. A defect in the lipidation of apoA-I by ABCA1 abolishes the biogenesis of HDL. We wanted to study interaction sites of ABCA1 with its ligand (the apoA-I), the implicated biogenesis’s pathways, and the implication of pre-β-HDLs in the cholesterol efflux by the ABCA1 pathway. Initially, we used a cell culture system (human skin fibroblasts and BHK-ABCA1) in order to determine the cellular sites of apoA-I binding and their localizations and the implication of ABCA1. We found that the majority of apoA-I was not associated with ABCA1 and, 2 thirds of this apoA-I bound to the plasma membrane. Then, a more detailed study examined the lipidation pathways of apoA-I either at plasma membrane (PM) level, or in the intracellular compartments (ICCs). We showed that the lipidation apoA-I occurs at the two levels (PM and ICCs) with two kinetically different pathways. Finally, we showed that the pre-β-HDLs efflux (as efficiently as apoA-I) the cholesterol via the ABCA1 pathway. Taken together, these observations show that 1) the majority of apoA-I was found non-associated with ABCA1; 2) two thirds of apoA-I bind the plasma membrane; 3) the lipidation of the apoA-I occurs, in part at the plasma membrane and, in the other, by the retro-endocytosis pathway of the apoA-I/ABCA1complexe.
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A Novel ELISA to Detect Methionine Sulfoxide−Containing Apolipoprotein A−IWang, Xiao suo January 2009 (has links)
Doctor of Philosophy(PhD) / Atherosclerosis manifests a state of increased oxidative stress characterized by comparable lipid and protein oxidation in the affected arterial wall. While oxidative modification of low density lipoprotein (LDL) has been extensively studied, increasing attention has been focused recently on oxidation of high-density lipoproteins (HDL) and its functional consequences in relation to atherosclerosis. Oxidative modification is thought to generate “dysfunctional” HDL that has lost anti-atherosclerotic activities, including the ability to remove cholesterol from lipid-laden cells. Therefore, there has been much interest in the detection of oxidized HDL. Unfortunately, available methods to detect oxidized HDL are limited at present, in part because oxidative modification of HDL is a complex process and ‘oxidized HDL’ is not a chemically defined entity. What is known however is that conversion of methionine (Met) residues of apolipoprotein (apo) A-I to methionine sulfoxide (MetO) is a process that occurs commonly as HDL undergoes oxidative modification. For example, human apoA-I+16 (containing MetO86 or MetO112) and apoA-I+32 (MetO86 plus MetO112) are generated when apoA-I reacts with lipid hydroperoxides formed as a consequence of the lipoprotein being exposed to 1e−oxidants. The formation of MetO in apoA−I induced by 2e−oxidants (i.e., hydrogen peroxide, hypochlorous acid or myeloperoxidase/hydrogen peroxide/chloride system) is associated with an impaired ability of the apolipoprotein to facilitate reactions relevant to reverse cholesterol transport. In addition, a previous study has suggested the plasma content of apoA-I+32 to be increased in certain subjects that have an increased risk to develop cardiovascular disease (CVD). Moreover, the MetO content in circulating, HDL−associated apoA−I is elevated in type 1 diabetes, a disorder commonly associated with increased oxidative stress and a risk factor for atherosclerosis. Therefore, in the present study, an existing HPLC method was applied to HDL samples from the Fletcher−Challenge study, a nested case control study, to test the potential usefulness of MetO-containing apoA-I as a marker of oxidative stress and/or CVD in a general population. Plasma samples whose HDL contained detectable apoA-I+16 and/or apoA-I+32 had significantly elevated levels of F2-isoprostanes, a marker of in vivo lipid oxidation, consistent with MetO-containing apoA-I being a useful marker of in vivo protein oxidation. Despite this however, there was no significant difference between controls and cases in their concentrations of HDL apoA-I+16 and apoA-I+32 or F2-isoprostanes, suggesting that markers of protein and lipid oxidation are not associated with the risk of coronary heart disease (CHD) in this general population. A limitation of the Fletcher−Challenge study was that only 22% of the 534 HDL samples analyzed contained apoA-I+16 and/or apoA-I+32. In addition, the HPLC−based method used is expensive and time−consuming and may lack the sensitivity needed for apolipoproteins to clinical studies. Thus, a mouse monoclonal anti-human apoA-I+32 antibody (MOA−1) was raised using HPLC−purified apoA-I+32 as immunogen. A sensitive ELISA was then developed using a commercial anti-human apoA-I monoclonal antibody as capture and biotinylated MOA−1 as detection antibody, respectively. The assay detected lipid−free HPLC−purified human apoA-I+32 in a concentration-dependent manner and with a significantly lower limit of detection (i.e., 3 ng/mL) than the HPLC method (1 μg/mL). The ELISA also detected lipid-free apoA-I modified by 2e-oxidants (hydrogen peroxide, hypochlorous acid, peroxynitrite), and HDL oxidized by 1e- or 2e-oxidants and present in buffer or human plasma. Moreover, the extent of recognition of MetO by MOA−1 increased with increasing numbers of MetO in apoA−I, as assessed by the experiments with H2O2−oxidized forms of apoA−I mutants, in which one, two or three Met residues were replaced with Leu. Their detection was concentration-dependent, reproducible, and exhibited a linear response over a physiologically plausible range of concentrations of oxidized HDL. In contrast, MOA-I failed to recognize native apoA-I, native apoA-II, apoA-I modified by hydroxyl radicals or metal ions, or LDL modified by 2e-oxidants. Furthermore, MOA−1 did not detect other Met−containing proteins oxidized by either hypochlorous acid or hydrogen peroxide. Taken together, the results showed that recognition of oxidized proteins by MOA−1 is limited to MetO contained in apoA−I. Finally, in a pilot study, plasma samples obtained from subjects with coronary artery disease (CAD) proven by angiography, and samples from CAD patients undergoing percutaneous coronary intervention (PCI) were analyzed by the ELISA. The preliminary data obtained showed elevated levels of MetO-containing apoA-I in plasma samples of CAD patients compared to those of corresponding control subjects. Unexpectedly, levels of MetOcontaining apoA-I decreased PCI compared to before PCI. A possible explanation for these results is that HDL−associated apoA−I become displaced by acute phase proteins, such as serum amyloid A, in response to PCI. In summary, the ELISA developed here specifically detects apoA-I containing MetO in HDL and human plasma. As such it may provide a useful tool for investigating the relationship between oxidized HDL and CAD.
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Protein kinase A and related pathways in the regulation of apolipoprotein E secretion and catalase activityGuo, Dongni Lily, Centre for Vascular Research, Faculty of Medicine, UNSW January 2009 (has links)
Cyclic-AMP dependent protein kinase A (PKA) regulates traffic of multiple proteins at different stages along the constitutive secretory pathway. PKA effects are regulated by protein phosphatases, which reverse the actions of PKA by dephosphorylation of PKA-substrates. Localization of specific PKA effects is mediated by the binding of A-kinase anchoring proteins (AKAPs). Apolipoprotein E (apoE) is an important regulator of lipid metabolism and atherosclerosis, and represents a large proportion of total protein constitutively secreted from macrophages. The signalling and trafficking pathways regulating secretion of apoE are unknown. Catalase is a peroxisomal enzyme which contributes to defence against hydrogen peroxide (H2O2). The primary hypothesis of this thesis is PKA and related protein phosphatase pathways are involved in the regulation of apoE secretion. The secondary hypothesis is that these pathways also regulate cellular clearance of H2O2. In Chapter Three, I have investigated the role of PKA in apoE secretion from primary human macrophages. Structurally distinct inhibitors of PKA (H89, KT5720, inhibitory peptide PKI14-22) all decreased basal secretion of apoE by between 50-80% whereas apoE mRNA or cellular protein are unaffected. Disruption of PKA-AKAP anchoring also significantly inhibited apoE secretion from human macrophages. Secretion of apoE was not immediately stimulated by PKA activity, suggesting that although PKA activity may be permissive for apoE secretion, it is in itself insufficient to stimulate apoE secretion above basal levels. Data from confocal microscopy and live cell imaging revealed PKA inhibition paralysed apoE vesicular movement from and to the plasma membrane. In Chapter Four, I investigated the effects of protein phosphatase 2B (PP2B) inhibition on apoE secretion by cyclosporin A (CsA). This was found to dose- and time-dependently inhibit secretion of apoE from primary human macrophages and increased cellular accumulation of apoE without affecting apoE mRNA levels. The role of PP2B in regulating apoE secretion was confirmed by using additional peptide and chemical inhibitors of PP2B. This effect was independent of the known inhibition of ABCA1 by CsA. Live cell imaging and confocal microscopy all demonstrated that inhibition of PP2B did not affect the apparent cellular distribution of apoE. Biochemical and microscopy studies indicated distinct mechanisms for PKA and PP2B regulation of apoE secretion. Chapter Five identified PKA-anchoring AKAPs in human macrophages, and investigated AKAP220 expression and its role in PKA-dependent processes relevant to atherosclerosis. AKAP220 protein was absent in human monocytes but was detectable after their differentiation into macrophages, with stable expression during late stages of maturation. It was also present in Chinese Hamster Ovary cells (CHO) cells. AKAP220 silencing had no effects on lipoprotein cholesteryl ester accumulation, total cellular apoE levels, apoE secretion or cholesterol efflux from human macrophages. Confocal microscopy in CHO cells revealed peroxisomal localisation of AKAP220. Catalase activity was confirmed to be PKA-regulated process, and AKAP220 was found to be a negative regulator of catalase activity, such that cell lysate catalase activity increased during AKAP220 silencing. AKAP220 silencing also decreased basal secretion of H2O2, detected using a sensitive and specific Amplex?? Red assay kit from intact CHO monolayers. In conclusion, this thesis has provided evidence that apoE secretion occurs via PKA- and PP2B-dependent pathways in human macrophages, and has identified the A-kinase anchoring protein AKAP220 as a regulator of cellular H2O2 clearance. These results will provide a basis for future investigations into the roles of PKA-related pathways in apoE secretion and catalase activity.
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Protein kinase A and related pathways in the regulation of apolipoprotein E secretion and catalase activityGuo, Dongni Lily, Centre for Vascular Research, Faculty of Medicine, UNSW January 2009 (has links)
Cyclic-AMP dependent protein kinase A (PKA) regulates traffic of multiple proteins at different stages along the constitutive secretory pathway. PKA effects are regulated by protein phosphatases, which reverse the actions of PKA by dephosphorylation of PKA-substrates. Localization of specific PKA effects is mediated by the binding of A-kinase anchoring proteins (AKAPs). Apolipoprotein E (apoE) is an important regulator of lipid metabolism and atherosclerosis, and represents a large proportion of total protein constitutively secreted from macrophages. The signalling and trafficking pathways regulating secretion of apoE are unknown. Catalase is a peroxisomal enzyme which contributes to defence against hydrogen peroxide (H2O2). The primary hypothesis of this thesis is PKA and related protein phosphatase pathways are involved in the regulation of apoE secretion. The secondary hypothesis is that these pathways also regulate cellular clearance of H2O2. In Chapter Three, I have investigated the role of PKA in apoE secretion from primary human macrophages. Structurally distinct inhibitors of PKA (H89, KT5720, inhibitory peptide PKI14-22) all decreased basal secretion of apoE by between 50-80% whereas apoE mRNA or cellular protein are unaffected. Disruption of PKA-AKAP anchoring also significantly inhibited apoE secretion from human macrophages. Secretion of apoE was not immediately stimulated by PKA activity, suggesting that although PKA activity may be permissive for apoE secretion, it is in itself insufficient to stimulate apoE secretion above basal levels. Data from confocal microscopy and live cell imaging revealed PKA inhibition paralysed apoE vesicular movement from and to the plasma membrane. In Chapter Four, I investigated the effects of protein phosphatase 2B (PP2B) inhibition on apoE secretion by cyclosporin A (CsA). This was found to dose- and time-dependently inhibit secretion of apoE from primary human macrophages and increased cellular accumulation of apoE without affecting apoE mRNA levels. The role of PP2B in regulating apoE secretion was confirmed by using additional peptide and chemical inhibitors of PP2B. This effect was independent of the known inhibition of ABCA1 by CsA. Live cell imaging and confocal microscopy all demonstrated that inhibition of PP2B did not affect the apparent cellular distribution of apoE. Biochemical and microscopy studies indicated distinct mechanisms for PKA and PP2B regulation of apoE secretion. Chapter Five identified PKA-anchoring AKAPs in human macrophages, and investigated AKAP220 expression and its role in PKA-dependent processes relevant to atherosclerosis. AKAP220 protein was absent in human monocytes but was detectable after their differentiation into macrophages, with stable expression during late stages of maturation. It was also present in Chinese Hamster Ovary cells (CHO) cells. AKAP220 silencing had no effects on lipoprotein cholesteryl ester accumulation, total cellular apoE levels, apoE secretion or cholesterol efflux from human macrophages. Confocal microscopy in CHO cells revealed peroxisomal localisation of AKAP220. Catalase activity was confirmed to be PKA-regulated process, and AKAP220 was found to be a negative regulator of catalase activity, such that cell lysate catalase activity increased during AKAP220 silencing. AKAP220 silencing also decreased basal secretion of H2O2, detected using a sensitive and specific Amplex?? Red assay kit from intact CHO monolayers. In conclusion, this thesis has provided evidence that apoE secretion occurs via PKA- and PP2B-dependent pathways in human macrophages, and has identified the A-kinase anchoring protein AKAP220 as a regulator of cellular H2O2 clearance. These results will provide a basis for future investigations into the roles of PKA-related pathways in apoE secretion and catalase activity.
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A Novel ELISA to Detect Methionine Sulfoxide−Containing Apolipoprotein A−IWang, Xiao suo January 2009 (has links)
Doctor of Philosophy(PhD) / Atherosclerosis manifests a state of increased oxidative stress characterized by comparable lipid and protein oxidation in the affected arterial wall. While oxidative modification of low density lipoprotein (LDL) has been extensively studied, increasing attention has been focused recently on oxidation of high-density lipoproteins (HDL) and its functional consequences in relation to atherosclerosis. Oxidative modification is thought to generate “dysfunctional” HDL that has lost anti-atherosclerotic activities, including the ability to remove cholesterol from lipid-laden cells. Therefore, there has been much interest in the detection of oxidized HDL. Unfortunately, available methods to detect oxidized HDL are limited at present, in part because oxidative modification of HDL is a complex process and ‘oxidized HDL’ is not a chemically defined entity. What is known however is that conversion of methionine (Met) residues of apolipoprotein (apo) A-I to methionine sulfoxide (MetO) is a process that occurs commonly as HDL undergoes oxidative modification. For example, human apoA-I+16 (containing MetO86 or MetO112) and apoA-I+32 (MetO86 plus MetO112) are generated when apoA-I reacts with lipid hydroperoxides formed as a consequence of the lipoprotein being exposed to 1e−oxidants. The formation of MetO in apoA−I induced by 2e−oxidants (i.e., hydrogen peroxide, hypochlorous acid or myeloperoxidase/hydrogen peroxide/chloride system) is associated with an impaired ability of the apolipoprotein to facilitate reactions relevant to reverse cholesterol transport. In addition, a previous study has suggested the plasma content of apoA-I+32 to be increased in certain subjects that have an increased risk to develop cardiovascular disease (CVD). Moreover, the MetO content in circulating, HDL−associated apoA−I is elevated in type 1 diabetes, a disorder commonly associated with increased oxidative stress and a risk factor for atherosclerosis. Therefore, in the present study, an existing HPLC method was applied to HDL samples from the Fletcher−Challenge study, a nested case control study, to test the potential usefulness of MetO-containing apoA-I as a marker of oxidative stress and/or CVD in a general population. Plasma samples whose HDL contained detectable apoA-I+16 and/or apoA-I+32 had significantly elevated levels of F2-isoprostanes, a marker of in vivo lipid oxidation, consistent with MetO-containing apoA-I being a useful marker of in vivo protein oxidation. Despite this however, there was no significant difference between controls and cases in their concentrations of HDL apoA-I+16 and apoA-I+32 or F2-isoprostanes, suggesting that markers of protein and lipid oxidation are not associated with the risk of coronary heart disease (CHD) in this general population. A limitation of the Fletcher−Challenge study was that only 22% of the 534 HDL samples analyzed contained apoA-I+16 and/or apoA-I+32. In addition, the HPLC−based method used is expensive and time−consuming and may lack the sensitivity needed for apolipoproteins to clinical studies. Thus, a mouse monoclonal anti-human apoA-I+32 antibody (MOA−1) was raised using HPLC−purified apoA-I+32 as immunogen. A sensitive ELISA was then developed using a commercial anti-human apoA-I monoclonal antibody as capture and biotinylated MOA−1 as detection antibody, respectively. The assay detected lipid−free HPLC−purified human apoA-I+32 in a concentration-dependent manner and with a significantly lower limit of detection (i.e., 3 ng/mL) than the HPLC method (1 μg/mL). The ELISA also detected lipid-free apoA-I modified by 2e-oxidants (hydrogen peroxide, hypochlorous acid, peroxynitrite), and HDL oxidized by 1e- or 2e-oxidants and present in buffer or human plasma. Moreover, the extent of recognition of MetO by MOA−1 increased with increasing numbers of MetO in apoA−I, as assessed by the experiments with H2O2−oxidized forms of apoA−I mutants, in which one, two or three Met residues were replaced with Leu. Their detection was concentration-dependent, reproducible, and exhibited a linear response over a physiologically plausible range of concentrations of oxidized HDL. In contrast, MOA-I failed to recognize native apoA-I, native apoA-II, apoA-I modified by hydroxyl radicals or metal ions, or LDL modified by 2e-oxidants. Furthermore, MOA−1 did not detect other Met−containing proteins oxidized by either hypochlorous acid or hydrogen peroxide. Taken together, the results showed that recognition of oxidized proteins by MOA−1 is limited to MetO contained in apoA−I. Finally, in a pilot study, plasma samples obtained from subjects with coronary artery disease (CAD) proven by angiography, and samples from CAD patients undergoing percutaneous coronary intervention (PCI) were analyzed by the ELISA. The preliminary data obtained showed elevated levels of MetO-containing apoA-I in plasma samples of CAD patients compared to those of corresponding control subjects. Unexpectedly, levels of MetOcontaining apoA-I decreased PCI compared to before PCI. A possible explanation for these results is that HDL−associated apoA−I become displaced by acute phase proteins, such as serum amyloid A, in response to PCI. In summary, the ELISA developed here specifically detects apoA-I containing MetO in HDL and human plasma. As such it may provide a useful tool for investigating the relationship between oxidized HDL and CAD.
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Φαρμακοκινητικός και φαρμακοδυναμικός χαρακτηρισμός μιας μεταλλαγμένης μορφής της απολιποπρωτεϊνης Ε με βελτιωμένες βιολογικές ιδιότητες / Pharmacokinetic and pharmacodynamic analysis of a recombinant apolipoprotein E variant apoE4 with improved biological propertiesΛαμπροπούλου, Αγγελική 31 January 2013 (has links)
Φυσιολογικά επίπεδα της αγρίου τύπου απολιποπρωτεϊνης Ε (apoE) στο πλάσμα διαμεσολαβούν στην κάθαρση των αθηρογενετικών λιποπρωτεϊνών ενώ υψηλότερα επίπεδα από τα φυσιολογικά προκαλούν υπερτριγλυκεριδαιμία. Αυτή η ιδιότητα της αγρίου τύπου apoE μειώνει σημαντικά την θεραπευτική της αξία ως ένα πιθανό βιολογικό φάρμακο για την αντιμετώπιση της δυσλιπιδαιμίας. Πρόσφατα, έχει δημιουργηθεί και μελετηθεί μια μεταλλαγμένη μορφή της apoE, apoE4 [ L261A, W264A, F265A, L268A, V269A ] (apoE4mut1) με βελτιωμένες βιολογικές ιδιότητες. Συγκεκριμένα, αυτή η μεταλλαγμένη μορφή μπορεί να φέρει τα υψηλά επίπεδα χοληστερόλης σε φυσιολογικές τιμές χωρίς να προκαλέσει υπερτριγλυκεριδαιμία ακόμα και όταν υπερεκφράζεται. Στην παρούσα μελέτη, πραγματοποιήθηκε φαρμακοδυναμική και φαρμακοκινητική ανάλυση της apoE4mut1 σε πειραματόζωα. Με γονιδιακή μεταφορά μέσω ιού σε ποντίκια που είχαν έλλειψη στον LDL υποδοχέα (LDLr-/-) και σε ποντίκια που είχαν έλλειψη στην apoE (apoE-/-), δείχθηκε οτι η δράση της apoE4mut1 ( μείωση της χοληστερόλης ) εξαρτάται από την έκφραση ενός λειτουργικού κλασσικού LDL υποδοχέα. Εφάπαξ έγχυση της apoE4mut1 συνδεδεμένης με λιποσώματα σε apoE-/- ποντίκια που ήταν σε δίαιτα δυτικού τύπου για 6 εβδομάδες αποκάλυψε οτι η εξωγενώς συντιθέμενη apoE4mut1 διατηρεί άθικτη την ικανότητά της να κανονικοποιεί τα υψηλά επίπεδα χοληστερόλης αυτών των ποντικιών με μια μέγιστη φαρμακολογική απόκριση που παρατηρείται σε μόλις 10 ώρες μετά την έγχυση. Ενδιαφέρον παρουσίασε το γεγονός οτι τα επίπεδα χοληστερόλης του πλάσματος παρέμειναν σημαντικώς μειωμένα για τις επόμενες 24 ώρες μετά την έγχυση της apoE4mut1- λιποσώματα. Μετρήσεις συγκεντρώσεων της apoE έδειξαν οτι η apoE4mut1 στην μορφή των πρωτεολιποσωμάτων που χρησιμοποιήθηκαν σε αυτή τη μελέτη έχει χρόνο ημίσειας ζωής 15.8 h. Τα δεδομένα αυτά οδηγούν στο συμπέρασμα οτι η καθαρή apoE4mut1 μπορεί να αποτελέσει ένα νέο υποψήφιο φάρμακο για την άμεση αντιμετώπιση της υπερχοληστερολαιμίας σε άτομα που εκφράζουν έναν λειτουργικό LDL υποδοχέα. / Physiological levels of wild-type (wt) apolipoprotein E (apoE) in plasma mediate the clearance of cholesterol-rich atherogenic lipoprotein remnants while higher than normal plasma apoE concentrations fail to do so and trigger hypertriglyceridemia. This property of wt apoE reduces significantly its therapeutic value as a potential biological drug for dyslipidemia. Recently, we reported the generation of a recombinant apoE variant, apoE4 [L261A, W264A, F265A, L268A, V269A] (apoE4mut1) with improved biological functions. Specifically, this variant can normalize high plasma cholesterol levels without triggering hypertriglyceridemia, even at supraphysiological levels of expression. In the present study we performed pharmacodynamic and pharmacokinetic analysis of apoE4mut1 in experimental mice. Using adenovirus-mediated gene transfer in LDL receptor deficient (LDLr-/-) and apoE deficient (apoE-/-) mice, we show that the cholesterol lowering potential of apoE4mut1 is dependent on the expression of a functional classical LDLr. Bolus infusion of apoE4mut1-containing proteoliposomes in apoE-/- mice fed western-type diet for 6 weeks indicated that exogenously synthesized apoE4mut1 maintains intact its ability to normalize the high cholesterol levels of these mice with a maximum pharmacological effect obtained at only 10 hours post-treatment. Interestingly, plasma cholesterol levels remained significantly reduced even 24 hours following intravenous infusion of apoE4mut1 proteoliposomes. Measurements of plasma apoE levels indicated that apoE4mut1 in the form of proteoliposomes used in the study has a half-life of 15.8 h. Our data suggest that purified apoE4mut1 may be an attractive new candidate for the acute correction of hypercholesterolemia in subjects expressing functional LDL receptor.
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