Enzymatically Active Paraoxonase-1 Is Located at the External Membrane of Producing Cells and Released by a High Affinity, Saturable, Desorption Mechanism
Paraoxonase-1 (PON1) is a high density lipoprotein (HDL)-associated serum enzyme that protects low density lipoproteins from oxidative modifications. There is a relative lack of information on mechanisms implicated in PON1 release from cells. The present study focused on a model derived from stable transfection of CHO cells, to avoid co-secretion of apolipoprotein (apo) A-I and lipids, which could lead to formation of HDL-like complexes. Our results indicate that, in the absence of an appropriate acceptor, little PON1 is released. The results designate HDL as the predominant, physiological acceptor, whose efficiency is influenced by size and composition. Neither lipid-poor apoA-I or apoA-II nor low density lipoproteins could substitute for HDL. Protein-free phospholipid complexes promoted PON1 release. However, the presence of both apolipoprotein and phospholipid were necessary to promote release and stabilize the enzyme. Immunofluorescence studies demonstrated that PON1 was inserted into the external membrane of CHO cells, where it was enzymatically active. Accumulation of PON1 in the cell membrane was not influenced by the ability of the cell to co-secrete of apoA-I. Release appeared to involve desorption by HDL; human and reconstituted HDL promoted PON1 release in a saturable, high affinity manner (apparent affinity 1.59 ؎ 0.3 g of HDL protein/ml). Studies with PON1-transfected hepatocytes (HuH-7) revealed comparable structural features with the peptide located in a punctate pattern at the external membrane and enzymatically active. We hypothesize that release of PON1 involves a docking process whereby HDL transiently associate with the cell membrane and remove the peptide from the external membrane. The secretory process may be of importance for assuring the correct lipoprotein destination of PON1 and thus its functional efficiency. Paraoxonase-1 (PON1)1 is a high density lipoprotein (HDL)-associated serum enzyme that protects low density lipoproteins (LDL) from oxidative modifications. In vitro studies have demonstrated the capacity of PON1 to prevent LDL (and HDL) oxidation by a variety of pro-oxidant factors, including cellinduced LDL oxidation (1, 2). Complementary studies have shown that the anti-oxidant activity of PON1 prevents LDL from acquiring a number of pathological characteristics associated with the atherosclerotic process, notably monocyte mobilization and gene activation (3). The PON1 knockout mouse model confirmed that absence of serum PON1 activity increases the level of lipoprotein oxidation, renders LDL more susceptible to oxidation, decreases the anti-oxidant capacity of HDL and leads to more extensive atheroma formation (4, 5). In man, we first demonstrated that PON1 was an independent, genetic risk factor for coronary disease (6, 7). This has been confirmed independently (8 -11), although not consistently (12,13). In subsequent studies we have shown that PON1 promoter polymorphisms, which affect promoter activity and serum PON1 concentrations (14), are also independent risk factors for...
Abstract-There are several potential mechanisms by which HDLs protect against the development of vascular disease.One relates to the unique ability of these lipoproteins to remove cholesterol from the arterial wall. Another is the ability of HDL to prevent and eventually correct endothelial dysfunction, a key variable in the pathogenesis of atherosclerosis and its complications. HDLs help maintain endothelial integrity, facilitate vascular relaxation, inhibit blood cell adhesion to vascular endothelium, reduce platelet aggregability and coagulation, and may favor fibrinolysis. These functions of HDLs complement their activity in arterial cholesterol removal by providing an excellent rationale for favorably influencing pathological processes underlying a variety of clinical conditions, such as accelerated atherosclerosis, acute coronary syndromes, and restenosis after coronary angioplasty, through a chronic or acute elevation of plasma HDL concentration. Key Words: high-density lipoproteins Ⅲ endothelium Ⅲ endothelial dysfunction Ⅲ atherosclerosis H uman HDLs are a heterogeneous class of lipoproteins of high density (1.063 to 1.21 g/mL) and small diameter (5 to 17 nm). Most HDL particles contain apolipoprotein A-I (apoA-I) as the major protein component. Several other proteins, including apolipoprotein (apo) A-II, apoCs, apoE, minor apolipoproteins, lecithin:cholesterol acyltransferase (LCAT), paraoxonase (PON), and platelet-activating factor acetylhydrolase (PAF-AH), are associated with HDL and impart significant physiological functions. The plasma concentration of HDL is routinely quantified as HDL cholesterol (HDL-C). However, differences in lipid and protein composition characterize several major and minor HDL particle subpopulations, which differ in density, size, shape, and surface charge. 1 Although the physiological significance of these different particles is mostly undefined, some of them display peculiar functional properties, at least in vitro. [2][3][4] Several prospective epidemiological studies provided overwhelming evidence that a low plasma HDL-C is a major, independent risk factor for the development of an acute coronary event. 5 Studies in patients with rare disorders of HDL metabolism and in genetically modified animal models support a causal relationship between low HDL and development of atherosclerotic vascular disease. The atheroprotective activity of HDL is often explained by the unique ability of these lipoproteins to remove cholesterol from peripheral tissues, including the arterial wall, and transport it to the liver The present review will focus on the effects of HDL on vascular endothelium and will discuss how the in vitro evidence from cell-culture studies translates into in vivo HDL-mediated endothelial protection, which may be relevant in the development and prevention of vascular disease. Endothelial Dysfunction and Cardiovascular DiseaseTraditionally, the endothelium has been considered an inert component of the vessel wall. During the past 2 decades it has become evident that t...
High-Density Lipoproteins Protect Isolated Rat Hearts From Ischemia-Reperfusion Injury by Reducing Cardiac Tumor Necrosis Factor-α Content and Enhancing Prostaglandin Release
Abstract-The incidence and severity of primary cardiac events are inversely related to the plasma concentration of high-density lipoproteins (HDLs). We investigated whether HDLs may exert a direct cardioprotection in buffer-perfused isolated rat hearts, which underwent a 20-minute low-flow ischemia followed by a 30-minute reperfusion. The administration of HDLs at physiological concentrations (0.5 and 1.0 mg/mL) during the 10 minutes immediately before ischemia rapidly and remarkably improved postischemic functional recovery and decreased creatine kinase release in the coronary effluent. Reconstituted HDLs containing apolipoprotein A-I (apoA-I) and phosphatidylcholine, but not lipid-free apoA-I or phosphatidylcholine liposomes, were also effective in protecting the heart from ischemiareperfusion injury. HDLs at reperfusion were less effective than when given before ischemia. HDLs caused a dose-dependent reduction of ischemia-induced cardiac tumor necrosis factor-␣ (TNF-␣) expression and content, which correlated with the improved functional recovery. A parallel increase of TNF-␣ release in the coronary effluent was observed, due to a direct binding of cardiac TNF-␣ to HDLs. Taken together, these findings argue for a cause-effect relationship between the HDL-mediated removal of TNF-␣ from the ischemic myocardium and the HDL-induced cardioprotection. Indeed, etanercept, a recombinant TNF-␣-blocking protein, caused a dose-dependent improvement of postischemic functional recovery. HDLs also enhanced ischemia-induced prostaglandin release, which may contribute to the cardioprotective effect. A low plasma HDL level may expose the heart to excessive ischemia-reperfusion damage, and HDL-targeted therapies may be helpful to induce immediate or delayed myocardial protection from ischemiareperfusion injury. Key Words: high-density lipoproteins Ⅲ myocardial ischemia Ⅲ reperfusion Ⅲ tumor necrosis factor-␣ Ⅲ prostaglandins S everal prospective studies have clearly established that plasma high-density lipoprotein (HDL) cholesterol levels are inversely related to the incidence of primary cardiac events. 1 In addition to the strong epidemiological data, there is compelling clinical trial evidence that coronary event rates may be favorably influenced by raising plasma HDL levels, especially in subjects with low HDL cholesterol and elevated triglycerides. [2][3][4] The protective effect of HDLs is believed to be due to their capacity to promote reverse cholesterol transport, the process by which cholesterol in peripheral tissues, including the arterial wall, is routed to the liver for excretion from the body. Through this pathway, HDLs retard formation of lipid-rich arterial lesions, thus preventing plaque rupture and coronary events. 5 Besides being a strong independent predictor of the occurrence of primary coronary events, a low plasma HDL cholesterol level is also associated with unfavorable prognosis in patients who have recovered from a myocardial infarction. 6 -8 Whether this association reflects accelerated atherogenesis...
SummaryLipoprotein synthesis is controlled by estrogens, but the exact mechanisms underpinning this regulation and the role of the hepatic estrogen receptor α (ERα) in cholesterol physiology are unclear. Utilizing a mouse model involving selective ablation of ERα in the liver, we demonstrate that hepatic ERα couples lipid metabolism to the reproductive cycle. We show that this receptor regulates the synthesis of cholesterol transport proteins, enzymes for lipoprotein remodeling, and receptors for cholesterol uptake. Additionally, ERα is indispensable during proestrus for the generation of high-density lipoproteins efficient in eliciting cholesterol efflux from macrophages. We propose that a specific interaction with liver X receptor α (LXRα) mediates the broad effects of ERα on the hepatic lipid metabolism.
Abstract-The purpose of this study was to investigate whether the expression of cellular adhesion molecules (CAMs) is enhanced in individuals with low HDL cholesterol (HDL-C). Plasma levels of soluble vascular cell adhesion molecule-1 (sVCAM-1), intercellular adhesion molecule-1 (sICAM-1), and E-selectin (sE-selectin) were measured in subjects with low (below the 10th percentile for the Italian population), average, or high (above the 90th percentile) HDL-C. Average sICAM-1 and sE-selectin levels were significantly higher in two groups of 65 individuals with low HDL levels, either hyperlipidemic (320.5Ϯ16.0 and 61.4Ϯ3.5 ng/mL) or normolipidemic (309.6Ϯ13.0 and 60.0Ϯ2.7 ng/mL), than in subjects with average HDL levels, either hyperlipidemic (267.0Ϯ10.1 and 50.4Ϯ2.8 ng/mL) or normolipidemic (257.9Ϯ5.4 and 51.1Ϯ2.4 ng/mL), or with high HDL levels (254.8Ϯ10.2 and 52.5Ϯ3.2 ng/mL). No significant difference was found in the plasma sVCAM-1 concentration. HDL-C was inversely correlated with sICAM-1 and sE-selectin in the low-HDL subjects (r 2 ϭ0.087 and 0.035, Pϭ0.0007 and 0.033, respectively), but not in individuals with normal or elevated HDL-C (r 2 ϭ0.012 and 0.006). A fenofibrate-induced increase of HDL-C in 20 low-HDL subjects was associated with a significant reduction of plasma sICAM-1 and sE-selectin concentrations. An increased CAMs expression may be a mechanism by which a low plasma HDL level promotes atherogenesis and causes acute atherothrombotic events.
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