Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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 endothelium plays an obligatory role in a number of relaxations of isolated arteries. These endothelium-dependent relaxations are due to the release by the endothelial cells of potent vasodilator substances [endothelium-derived relaxing factors (EDRF)]. The best characterized EDRF is nitric oxide (NO). Nitric oxide is formed by the metabolism of L-arginine by the constitutive NO synthase of endothelial cells. In arterial smooth muscle, the relaxations evoked by EDRF are explained best by the stimulation by NO of soluble guanylate cyclase that leads to the accumulation of cyclic GMP. The endothelial cells also release an unidentified substance that causes hyperpolarization of the cell membrane (endothelium-derived hyperpolarizing factor, EDHF). The release of EDRF from the endothelium can be mediated by both pertussis toxin-sensitive (alpha2-adrenergic activation, serotonin, thrombin, aggregating platelets) and insensitive (adenosine diphosphate, bradykinin) G-proteins. In blood vessels from animals with regenerated endothelium, and/or atherosclerosis, there is a selective loss of the pertussis-toxin sensitive mechanism of EDRF-release which favors the occurrence of vasospasm, thrombosis and cellular growth.
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PMID:Endothelial dysfunction and vascular disease. 980 82

To conclude, an impairment of the NO synthase pathway may be one of the earliest events in atherogenesis. A reduction in NO synthesis and/or activity may contribute to the initiation and progressive of atherosclerosis. Derangement of the NO synthase pathway may occur by several mechanisms, including lipoproptein-induced alterations in signal transduction; increases in superoxide anion elaboration (and degradation of NO); reduced affinity of NOS for L-arginine; and/or elevated levels of circulating antagonists. NO is a potent vasodilator, a regulator of vascular structure, and an inhibitor of endothelial interactions and circulating blood elements. A loss of endothelial NO activity may contribute to the abnormal vasomotion observed in coronary artery disease, as well as the progression of atherosclerosis. Strategies to enhance NO synthesis and/or activity may be useful in maintaining cardiovascular health.
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PMID:Is atherosclerosis an arginine deficiency disease? 980 22

1. Nitric oxide (NO) has important roles in physiological vasodilatation, cytotoxicity and vascular disease. Nitric oxide and prostacyclin (PGI2), both released from the endothelium, act synergistically to inhibit platelet aggregation and adhesion. These autacoids also inhibit the adhesion and migration of leucocytes and, in some arteries, they synergize in terms of vasodilation. 2. The development of atherosclerosis and hyperlipaemia per se is accompanied by impairment of endothelium-dependent vasodilation. 3. Atherosclerosis is associated with marked changes in the activity of isoforms of NO synthase (NOS) in the artery wall, including increased expression of the NOS2 (inducible) isoform in complex human lesions as well as in the neointima of experimental animal models. 4. Failure of NO release from the endothelium with normal physiological stimuli, which has been attributed to a defect in the operation of the endothelial NOS (NOS3), provides conditions propitious for leucocyte adhesion, vasospasm, thrombosis and, in addition, may promote increased proliferation of intimal cells. 5. Nitric oxide and superoxide anions generated by inflammatory cells in atherosclerosis react to form cytodestructive peroxynitrite radicals, potentially causing injury to the endothelium and myocytes, and this may be a factor in apoptosis of cells leading to plaque rupture. 6. We have been able to reverse these NO defects with therapeutic agents, including angiotensin-converting enzyme inhibitors, antagonists of platelet-activating factor and NO donor compounds, all offering promise in protecting against some manifestations of vascular disease.
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PMID:Nitric oxide in atherosclerosis: vascular protector or villain? 980 90

Vascular endothelium releases nitric oxide (NO), an important vasodilator that is continuously synthesised by the constitutive enzyme, endothelial nitric oxide synthase (NOS). This maintains a constant vasodilator tone which is diminished in adult hypertension, due to reduced endothelium-dependent vascular relaxation, which is NO dependent. In childhood, however, hypertension is often secondary, and normalisation of blood pressure by removal of cause (e.g. renal artery stenosis, catecholamine-producing tumour) suggests reversibility of endothelial dysfunction, if it is present. Raised plasma levels of endogenous inhibitors have been found, especially in children with secondary hypertension due to renal parenchymal and renovascular disease, and may contribute to hypertension by more than just inhibition of vascular NO release; e.g. by reduction of glomerular filtration rate and promotion of salt and water retention. These inhibitors also modulate renin release, which may be of relevance in cardiovascular physiology, and may also interfere with the anti-platelet properties of NO, increasing the likelihood of vascular thrombotic events. NO inhibitors also promote endothelial activation, with increased expression of adhesion molecules that may form seedlings of atherosclerosis. In chronic renal impairment, accumulation of NO inhibitors may contribute to hypertension. Efficient long-session dialysis helps better interdialysis control of blood pressure in these subjects, independent of salt and water removal, suggesting that removal of such vasoactive agents may be important for efficient blood pressure control. There are a few studies assessing NO generation in hypertensive children via plasma nitrite and nitrate, the NO end products, which suggest normal or increased production as opposed to a reduction, perhaps as a compensatory phenomenon. In the treatment of hypertension, nitroprusside and nitrates exert their actions via NO donation. Excessive production of NO (usually via inducible NOS) or excessive administration (nitrovasodilators) can be cytotoxic and may cause hypotension and shock, as in severe sepsis. NOS inhibitors and NO therefore appear to play a crucial role in aetiology, complications and therapy of childhood hypertension.
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PMID:Vascular endothelium and nitric oxide in childhood hypertension. 981 94

Local gene transfer into the vascular wall offers a promising alternative to treat atherosclerosis-related diseases at cellular and molecular levels. Blood vessels are among the easiest targets for gene therapy because of novel percutaneous, catheter-based treatment methods. On the other hand, gene transfer to the artery wall can also be accomplished from adventitia, and in some situations intramuscular gene delivery is also a possibility. In most conditions, such as postangioplasty restenosis, only a temporary expression of the transfected gene will be required. Promising therapeutic effects have been obtained in animal models of restenosis with the transfer of genes for vascular endothelial growth factor, fibroblast growth factor, thymidine kinase, p53, bcl-x, nitric oxide synthase and retinoblastoma. Also, growth arrest homeobox gene and antisense oligonucleotides against transcription factors or cell cycle regulatory proteins have produced beneficial therapeutic effects. Angiogenesis is an emerging new target for gene therapy of ischemic diseases. In addition, hyperlipoproteinemias may be improved by transferring functional lipoprotein-receptor genes into hepatocytes of affected individuals. First experiences of gene transfer methods in the human vascular system have been reported. However, further studies regarding gene delivery methods, vectors and safety of the procedures are needed before a full therapeutic potential of gene therapy in vascular diseases can be evaluated.
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PMID:Vascular gene transfer for the treatment of restenosis and atherosclerosis. 981 1

Diabetes mellitus is associated with early development of cardiovascular complications. Under physiological conditions the endothelium protects against the development of atherosclerosis. Endothelial cells produce, e.g., nitric oxide (NO), a substance which is capable of keeping vascular tone, coagulation and inflammation well balanced. However, in pathological conditions, such as in diabetes mellitus, impaired NO activity may be present. Decreased NO activity can be caused by impaired production of NO, due to uncoupling of receptor-mediated signal transduction, a deficiency of the NO synthase (NOS) substrate L-arginine, or a decreased availability of one or more cofactors essential for optimal functioning of NOS. However, hyperglycaemia also stimulates the production of advanced glycosylated end products, enhances the polyol pathway and activates protein kinase C. These conditions may lead to increased oxidative stress. Reactive oxygen species rapidly inactivate NO leading to the formation of peroxynitrite. Peroxynitrite is a toxic oxidant capable of damaging many biological molecules. Reduced NO availability may not only be of relevance to the development of atherosclerotic complications in diabetes but may also interfere with insulin-mediated postprandial glucose disposal and possibly contribute to the development of insulin resistance. Understanding of the complex metabolic disturbances interacting with the NO system may provide us with further therapeutic options to decrease cardiovascular morbidity and mortality in diabetes mellitus.
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PMID:Nitric oxide availability in diabetes mellitus. 981 72

Nitric oxide (NO.) is produced from L-arginine, as result of a reaction catalyzed by the enzyme nitric oxide synthase (NOS). The reaction is the sole source of NO. in animal tissues. NO. can control physiological processes (or systems) such as (a) blood pressure; (b) relaxation of arterial smooth muscle; (c) platelet aggregation and adhesion; (d) neurotransmission; (e) neuroendocrine secretion. NO. contributes to the killing of pathogenic microorganisms and tumoral cells by phagocytes. NO. reacts with superoxide anion thus producing peroxynitrite, a cytotoxic ion capable of destroying many biological targets. The superoxide/peroxinitrite balance determines the ONOO- production and, accordingly, is essential for the development of hypertension, atherosclerosis, neurodegenerative diseases, viral infections, ischemia-reperfusion injury, and cancer.
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PMID:[Physiopathologic effects of nitric oxide and their relationship with oxidative stress]. 981 98

The Kampo medicine Shichimotsu-koka-to (SKT) is used to treat hypertension and atherosclerosis in Japan. The action of SKT was studied, focusing on nitric oxide, which is intimately involved in regulation of blood pressure and cell functions associated with atherogenesis and inflammation. Oral administration of SKT enhanced serum nitric oxide (NOx) levels dose-dependently and 3 d administration was enough to detect its effect. The maximal level of serum NOx was maintained at around 27 microM, a concentration which did not result in harmful effects on cells. On the other hand, L-arginine, the substrate of NO synthase (NOS), was also increased by SKT administration. When the source of L-arginine was studied, only 12.7 mg of L-arginine was contained in 1 g of SKT and this amount of L-arginine could not explain the increased L-arginine levels in serum. These results suggest that SKT may enhance serum L-arginine by acting on L-arginine metabolism, but not by supplying L-arginine itself, resulting in enhancement of serum NOx. In conclusion, the antihypertensive and antiatherosclerotic action shown by SKT may be in part due to enhanced serum NOx, thus suggesting that SKT may become a unique orally active drug for cardiovascular diseases as a new NO donor.
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PMID:Enhancement of serum nitric oxide by Shichimotsu-koka-to (Kampo medicine). 982 14

Using fluorescence optical and electron spin resonance spectroscopy, we have investigated the production of superoxide by bovine endothelial nitric oxide synthase (NOS). In contrast to neuronal NOS, the heme moiety is identified as the exclusive source of superoxide production by endothelial NOS. Thus, calmodulin-mediated enzyme regulation affects production of nitric oxide and superoxide simultaneously and inseparably. The balance between the nitric oxide/superoxide reaction pathways may be shifted by addition of exogenous heme-specific agents, such as tetrahydrobiopterin. Our results have direct relevance for the pathophysiology of atherosclerosis.
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PMID:Origin of superoxide production by endothelial nitric oxide synthase. 982 38

Non-restrictive, porous, external stents inhibit neointima formation in porcine vein grafts. Since the mechanisms underlying these effects are unknown we investigated the impact of this external stent on factors known to inhibit vascular smooth muscle cell proliferation: prostacyclin (PGI2), nitric oxide (NO), cAMP and cGMP formation in different regions of stented and unstented porcine vein grafts. Paired stented and unstented saphenous vein-carotid artery interposition grafting was carried out in Landrace pigs. One month after surgery, the vessels were excised and the formation of PGI2, cAMP and cGMP determined using radioimmunoassay and nitric oxide synthase (NOS) distribution studied using autoradiography and histochemistry. There were no significant differences between PGI2, cAMP and cGMP (nitroprusside-stimulated) formation in the medial/intimal regions of grafts of stented vein graft and ungrafted saphenous vein whereas all were significantly reduced in unstented vein graft. A23187-stimulated cGMP formation (mediated by NO release) and NOS content was significantly greater in the medial/intimal region of stented and unstented vein graft compared to ungrafted saphenous vein, indicating induction of endothelial NOS (eNOS) in both types of graft. This normalisation of the PGI2-cAMP axis and guanylyl cyclase activity in the medial/intimal region may contribute to the beneficial impact of the external stent on vein graft thickening. The increase in eNOS in both stented and unstented vein grafts mitigates against this isoform as playing a role in mediating the inhibitory effect of the stent on neointima formation. In the adventitia of both stented and unstented grafts there was an increase in PGI2, cAMP and cGMP formation compared to ungrafted saphenous vein, the production being greater in the stented compared to the unstented graft. In the adventitia of stented veini grafts, NOS, detected with NAPDH diaphorase staining, was associated with microvessels as well as with inflammatory cells. Taken together, these data are suggestive of a role for PGI2 and NO in promoting microangiogenesis in the adventitia of stented vein grafts which may in turn minimize graft hypoxia, an established contributory factor to neointima formation.
Atherosclerosis 1998 Dec
PMID:Nitric oxide, prostacyclin and cyclic nucleotide formation in externally stented porcine vein grafts. 986 78


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