Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0004153 (atherosclerosis)
 77,401 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The paraoxonase gene family contains at least three members, including PON1, PON2 and PON3, which are located on chromosome 7q21.3-22.1. Until recently, there has been little insight into the role of the respective gene products in human physiology and pathology. However, emerging evidence from biochemical and genetic experiments is providing clues about the role(s) of the products of these genes. For example, the PON1 gene product is serum paraoxonase, which is expressed mainly in the liver and which hydrolyzes organophosphates. Serum paraoxonase circulates on a subfraction of high-density lipoproteins and appears to use phospholipids on both low and high-density lipoprotein particles as a physiological substrate. This functional relationship could explain the reported associations between common variation in the PON1 gene and phenotypes related to atherosclerosis and lipoprotein metabolism. In contrast, the PON2 mRNA is expressed ubiquitously, and to date there are no mechanistic experiments that yield insights into its physiological role. However, there have been reports of association between common variation in PON2 and some metabolic quantitative phenotypes, such as plasma lipoproteins, plasma glucose, birthweight and atherosclerosis. Such genetic associations could point to the possible physiological role(s) of PON2. At present, the role of the PON3 gene product is very poorly understood. Complementary lines of research should soon clarify whether there might be merit in clinical testing for genetic variation in the paraoxonase gene family or whether the gene products might be good candidates for therapeutic interventions.
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PMID:Paraoxonase genes and disease. 1044 77

Paraoxonase 1 (PON1) is proposed to have an anti-atherogenic action. Two polymorphisms at the PON1 (M/L55 and Q/R192) have been shown to be associated with coronary artery disease (CAD). This conclusion is not drawn universally, however, and specific ethnic characteristics may be important determinants in this association. Recently two homologues of PON1 - PON2 and PON3 - were identified and Sanghera et al. demonstrated C/S311 polymorphism at PON2 was associated with the risk of CAD. Within that context, we investigated the association between the aforementioned three polymorphisms and CAD and ischemic stroke in a Japanese population. The study population included 431 control subjects, 210 CAD patients, and 235 ischemic stroke patients. Genotype distributions and allele frequencies of M/L55 and C/S311 were similar among the control and patient groups, whereas the R192 allele frequency was significantly higher (P<0.001) in CAD (75%) and ischemic stroke (76%) patients than in control subjects (65%). When confounding influences of other risk factors were controlled for by multivariate analysis, R192 remained an independent risk determinant (additive model: OR (95% CI), P value CAD: 2.01 (1.45-2.79), 0.0001; ischemic stroke: 1.84 (1.34-2.52), 0.0002 (three genotypes into calculation)). Taken together, our data indicate that the Q/R192 is principally associated with both CAD and ischemic stroke in Japanese.
Atherosclerosis 2000 Apr
PMID:Evidence for association between paraoxonase gene polymorphisms and atherosclerotic diseases. 1072 95

The antioxidant activity of HDL is largely due to the paraoxonase (PON1) located on it. Experiments with transgenic PON1 knock-out mice indicate the potential for PON1 to protect against atherogenesis. This effect of HDL in decreasing LDL lipid peroxidation is maintained for longer than that of antioxidant vitamins and could thus be more protective. Several important advances in the field of PON research have occurred recently, not least the discovery that two other members of the PON gene family PON2 and PON3 may also have important antioxidant properties. Significant advances have been made in understanding the basic biochemical function of PON1 and the discovery of possible modulators of its activity. Decreased coronary heart disease (CHD) risk associated with polymorphisms of PON1 which are most active in lipid peroxide hydrolysis revealed by meta-analysis is likely to be an underestimate of the true contribution of PON1 to CHD because these polymorphisms explain only a small component of the variation in PON1 activity. However, it is a very important observation because genetic influences are not likely to be confounded by other factors linked with both CHD and diminished PON1 activity. PON1 is extensively researched and strategies will hopefully emerge to increase its activity and provide a more satisfactory test of the antioxidant hypothesis of atherosclerosis than antioxidant vitamins have done.
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PMID:Paraoxonase and coronary heart disease. 1257 63

Human serum paraoxonase (PON1), an HDL-associated esterase, protects lipoproteins against oxidation, probably by hydrolyzing specific lipid peroxides. As arterial macrophages play a key role in oxidative stress in early atherogenesis, the aim of the present study was to examine the effect of PON1 on macrophage oxidative stress. For this purpose we used mouse arterial and peritoneal macrophages (MPM) that were harvested from two populations of PON1 knockout (KO) mice: one on the genetic background of C57BL/6J (PON1(0)) and the other one on the genetic background of apolipoproteinE KO (PON1(0)/E(0)). Serum and LDL, but not HDL, lipids peroxidation was increased in PON1(0), compared to C57BL/6J mice, by 84% and by 220%, respectively. Increased oxidative stress was shown in peritoneal and in arterial macrophages derived from either PON1(0) or PON1(0)/E(0) mice, compared to their appropriate controls. Macrophage oxidative stress was expressed by increased lipid peroxides content in MPM from PON1(0) and from PON1(0)/E(0) mice by 48% and by 80%, respectively, and by decreased reduced glutathione (GSH) content, compared to the appropriate controls. Furthermore, increased capacity of MPM from PON1(0) and PON1(0)/E(0) mice to oxidize LDL (by 40% and by 19%, respectively) and to release superoxide anions was observed. In accordance with these results, PON1(0) mice MPM exhibited 130% increased translocation of the cytosolic p47phox component of NADPH-oxidase to the macrophage plasma membrane, suggesting increased activation of macrophage NADPH-oxidase in PON1(0) mice, compared to control mice MPM. The increase in oxidative stress in PON1-deficient mice was observed despite the presence of the two other members of the PON gene family. PON2 and PON3 activities and mRNA expression were both found to be present in PON1-deficient mice MPM. Upon incubation of PON1(0)/E(0) derived macrophages with human PON1 (7.5 arylesterase units/ml), cellular peroxides content was decreased by 18%, macrophage superoxide anion release was decreased by 33%, and macrophage-mediated oxidation of LDL was reduced by 22%. Finally, a 42% increase in the atherosclerotic lesion area was observed in PON1(0)/E(0) mice, in comparison to E(0) mice under regular chow diet. We thus concluded that PON1 can directly reduce oxidative stress in macrophages and in serum, and that PON1-deficiency results in increased oxidative stress not only in serum, but also in macrophages, a phenomenon that can contribute to the accelerated atherosclerosis shown in PON1-deficient mice.
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PMID:Paraoxonase (PON1) deficiency is associated with increased macrophage oxidative stress: studies in PON1-knockout mice. 1263 54

The human paraoxonase (PON) gene family consists of three members, PON1, PON2, and PON3, aligned next to each other on chromosome 7. By far the most-studied member of the family is the serum paraoxonase 1 (PON1), a high-density lipoprotein-associated esterase/lactonase. Early research focused on its capability to hydrolyze toxic organophosphates, and its name derives from one of its most commonly used in vitro substrates, paraoxon. Studies in the last 2 decades have demonstrated PON1's ability to protect against atherosclerosis by hydrolyzing specific derivatives of oxidized cholesterol and/or phospholipids in oxidized low-density lipoprotein and in atherosclerotic lesions. Levels and genetic variability of PON1 influence sensitivity to specific insecticides and nerve agents, as well as the risk of cardiovascular disease. More recently, the other two members of the PON family, PON2 and PON3, have also been shown to have antioxidant properties. A major goal in present research on the paraoxonases is to identify their natural substrates and to elucidate the mechanism(s) of their catalytic activities.
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PMID:Pharmacogenetics of paraoxonases: a brief review. 1457 13

The paraoxonase (PON) gene family contains at least three members: PON1, PON2, and PON3. The enzyme PON1 has been implicated in the pathogenesis of atherosclerosis. Recently, an association between PON2 and quantitative metabolic phenotypes, such as plasma lipoproteins, plasma glucose, and coronary artery disease (CAD), has been reported. We analyzed two common polymorphisms in PON1 (i.e., M/L55 and R/Q 192 mutations) and PON2 (i.e., G/A148 and C/S311 mutations) in 352 high-risk patients with angiographically defined CAD. These results were compared to those in 380 age- and sex-matched control subjects at high risk for CAD. Polymerase chain reaction with specific primers followed by Hsp92, Alw1, DdeI and Fnu4HI restriction digestion were employed to identify the PON1 M/L55 and R/Q192 and the PON2 G/A148 and C/S311 genotypes, respectively. Univariate analysis showed a higher prevalence of the MM genotype (12% vs. 5%; p=0.004) for the PON1 M/L55 polymorphism and the GG genotype (21% vs. 15%; p=0.047) PON2 G/A148 polymorphism in the control subjects. The PON1 M/L55 mutation (MM genotype) was associated with lower triglyceride levels and the PON2 G/A148 mutation (GG genotype), with higher total and low-density lipoprotein (LDL)-cholesterol levels. No mutation was associated with the number of major coronary artery vessels with a >50% reduction in lumen diameter. Multiple regression analysis disclosed smoking, a family history of CAD, high-density lipoprotein (HDL)-cholesterol and the PON1 M/L55 mutation [OR=0.59 (CI95%: 0.42-0.82); p=0.002] as independent markers for CAD. In contrast to traditional coronary risk factors, the PON1 M/L mutation can be considered predictive of protection against CAD.
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PMID:PON1 M/L55 mutation protects high-risk patients against coronary artery disease. 1499 78

Members of the serum paraoxonase (PON) family have been identified in mammals and other vertebrates, and in invertebrates. PONs exhibit a wide range of physiologically important hydrolytic activities, including drug metabolism and detoxification of nerve agents. PON1 and PON3 reside on high-density lipoprotein (HDL, 'good cholesterol') and are involved in the prevention of atherosclerosis. We describe the first crystal structure of a PON family member, a variant of PON1 obtained by directed evolution, at a resolution of 2.2 A. PON1 is a six-bladed beta-propeller with a unique active site lid that is also involved in HDL binding. The three-dimensional structure and directed evolution studies permit a detailed description of PON1's active site and catalytic mechanism, which are reminiscent of secreted phospholipase A2, and of the routes by which PON family members diverged toward different substrate and reaction selectivities.
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PMID:Structure and evolution of the serum paraoxonase family of detoxifying and anti-atherosclerotic enzymes. 1509 21

The antioxidant activity of high density lipoprotein (HDL) is largely due to the paraoxonase (PON) 1 located on it. Experiments with transgenic PON1 knockout mice indicate the potential for PON1 to protect against atherogenesis. This effect of HDL in decreasing low density lipoprotein (LDL) lipid peroxidation is maintained for longer than that of antioxidant vitamins and could therefore be more protective. Several important advances in the field of PON research have occurred recently, not least the discovery that two other members of the PON gene family -PON2 and PON3 - may also have important antioxidant properties. Significant advances have been made in understanding the basic biochemical function of PON1 and the discovery of possible modulators of its activity. Case-control studies of PON1 activity and coronary heart disease (CHD) have shown a clear association between CHD and low serum PON1 activity. This relationship has been further strengthened by the publication of the first prospective study showing low serum PON1 activity to be an independent predictor of new CHD events. Furthermore, decreased CHD risk has been revealed by meta-analysis to be associated with the polymorphisms of PON1, which are most active in lipid peroxide hydrolysis. Although this is likely to be an underestimate of the true contribution of PON1 to CHD (because these polymorphisms explain only a small component of the variation in PON1 activity), it is important because genetic influences are unlikely to be confounded by other factors linked with both CHD and diminished PON1 activity. PON1 is being extensively researched and it is hoped that therapeutic approaches will emerge to increase its activity. Clinical trials of these, if successful, will not only provide a novel means of preventing atherosclerosis, but also provide a more satisfactory means of testing the oxidant hypothesis of atherosclerosis than antioxidant vitamin supplementation has proved to be.
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PMID:The role of paraoxonase 1 activity in cardiovascular disease: potential for therapeutic intervention. 1528 96

Paraoxonases PON1 and PON3, which are both associated in serum with HDL, protect the serum lipids from oxidation, probably as a result of their ability to hydrolyze specific oxidized lipids. The activity of HDL-associated PON1 seems to involve an activity (phospholipase A2-like activity, peroxidase-like activity, lactonase activity) which produces LPC. To study the possible role of PON1 in macrophage foam cell formation and atherogenesis we used macrophages from control mice, from PON1 knockout mice, and from PON1 transgenic mice. Furthermore, we analyzed PON1-treated macrophages and PON1-transfected cells to demonstrate the contribution of PON1 to the attenuation of macrophage cholesterol and oxidized lipid accumulation and foam cell formation. PON1 was shown to inhibit cholesterol influx [by reducing the formation of oxidized LDL (Ox-LDL), increasing the breakdown of specific oxidized lipids in Ox-LDL, and decreasing macrophage uptake of Ox-LDL]. PON1 also inhibits cholesterol biosynthesis and stimulates HDL-mediated cholesterol efflux from macrophages. PON2 and PON3 protect against oxidative stress, with PON2 acting mainly at the cellular level. Whereas serum PON1 and PON3 were inactivated under oxidative stress, macrophage PON2 expression and activity were increased under oxidative stress, probably as a compensatory mechanism against oxidative stress. Intervention to increase the paraoxonases (cellular and humoral) by dietary or pharmacological means can reduce macrophage foam cell formation and attenuate atherosclerosis development.
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PMID:Paraoxonases 1, 2, and 3, oxidative stress, and macrophage foam cell formation during atherosclerosis development. 1545 71

Epidemiologic, genetic, and biochemical studies support an antiatherogenic role for paraoxonase (PON) 1. While the precise mechanism by which PON1 protects against the development of atherosclerosis is unclear, in vitro studies and the results from PON1 knockout and transgenic mice suggest that this protective effect may be attributed to PON1's ability to attenuate the oxidative modification of lipoprotein particles. The two other members of the PON gene family, namely, PON2 and PON3, have also been reported to possess antioxidant properties and may exhibit antiatherogenic capacities as well. Previous studies have demonstrated that PON1 expression is downregulated by oxidative stress. In contrast, more recent studies have shown that PON2 expression is upregulated in response to oxidative stress-inducing agents, while PON3 expression remains unchanged. While the physiological function of these proteins is unknown, studies currently underway using PON2 and PON3 knockout and transgenic mice should enable us to tease out the apparently redundant functions of these three proteins and yield clues as to their physiological function as well as their role in atherogenesis.
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PMID:The paraoxonase gene family and atherosclerosis. 1560 99


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