UMLS:C0028754 - FACTA Search

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Query: UMLS:C0028754 (obesity)
124,988 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Hepatic plasma membranes of female obese mice C57 BL-6 orl ob/ob (ob/ob mice) completely lack vasopressin (VP) receptors of the V1 type whereas kidney VP receptors are normally expressed and functionally coupled to adenylate cyclase. To discover if these alterations are linked to a genetic defect of the V1 receptor, we have studied the binding of VP on liver and kidney membranes of two other models, female diabetic mice C57 BL-6 orl db/db (db/db mice) and female Zucker rats Fatty/orl fa/fa (fa/fa rats), which exhibit different temporal pattern of obesity, hyperinsulinemia and insulin resistance. In addition, since VP is known to exert its vascular response through stimulation of V1 receptors, we have studied the reactivity of VP of isolated tail artery in the three different models, ob/ob and db/db mice and fa/fa rats, and in their respective controls. In all cases, VP kidney receptors and VP vascular reactivity are normal. db/db mice exhibit a marked decrease in hepatic VP receptors whereas a 50% decrease was observed in 32 week fa/fa rats. Angiotensin II and prazosin binding sites are still present as well as the adenylate cyclase response to glucagon. These results suggest that the specific alteration in liver VP receptors is not related to a defect in V1 receptor genetic expression but is specific for liver and appears to parallel the level of hyperinsulinemia and/or insulin resistance.
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PMID:Reduction in hepatic but not in renal and vascular vasopressin receptor number in hyperinsulinemic mice and rats. 609 84

Angiotensin II exerts its action via at least two distinct receptor subtypes designated AT1 and AT2. AT1 receptors seem to be responsible for most of the known angiotensin II effects while the role of AT2 receptors is not yet clear. Adipocytes of adult rats express exclusively the AT1 subtype. Angiotensin II stimulates prostacyclin release in adult rat adipocytes and in mouse preadipocytes. In the latter prostacyclin release is completely blocked by an AT2 receptor antagonist. Adipocyte angiotensin II receptors seem to be regulated by age and fat mass. Blockade of these receptors by an AT1 antagonist seems to prevent adipose tissue hypertrophy. Moreover, adipose tissue contains all the main components of the renin-angiotensin system such as angiotensinogen, angiotensin converting enzyme, angiotensin II and angiotensin II receptors. Angiotensinogen expression in adipocytes is stimulated by a high fat diet concurrent with enlargement of fat mass, associated with insulin resistance. Angiotensin converting enzyme inhibitors improve insulin sensitivity. Taken together, there is evidence of interaction between insulin and angiotensin II in regulation of adipose tissue metabolism and cellularity. Clarification of these interactions could lead to significant progress in pharmacological treatment of obesity and its comorbidity.
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PMID:The role of angiotensin II and its receptors in regulation of adipose tissue metabolism and cellularity. 878 38

Diabetes mellitus and hypertension each confer increased cardiovascular risk. That risk is much greater when the diseases coexist and is further magnified by their frequent association with dyslipidemia and central obesity. Insulin resistance appears to be an important common component to these four entities, whether or not the relationship is truly cause and effect. Increased renal tubule absorption of sodium and increased sympathetic nervous system stimulation from insulin have been said to be the mechanisms by which elevated levels of insulin cause hypertension. However, animal experiments suggest that these are short-term effects only and that long-term insulin may actually increase peripheral blood flow and reduce blood pressure. Experiments in humans suggest that the insulin resistant state in obese patients and type II diabetics is associated with a decrease of the usual vasodilatory effect of insulin. Antihypertensive drugs have differing effects on insulin resistance. Angiotensin converting enzyme inhibitors, alpha-adrenergic blockers, and dihydropyridines appear to improve insulin sensitivity. Other calcium channel blockers appear to be neutral, as is furosemide. Thiazide diuretics, spironolactone, and beta-adrenergic blockers impair insulin sensitivity. The drugs that increase insulin sensitivity also tend to improve dyslipidemia or remain lipid neutral. In contrast, those drugs that tend to impair insulin sensitivity also tend to worsen dyslipidemia.
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PMID:Hypertension in patients with diabetes mellitus. 884 91

Hypertension and diabetes mellitus are common chronic conditions which frequently coexist. Diabetic nephropathy is a major cause of elevated blood pressure in patients with insulin-dependent diabetes mellitus (IDDM). Diabetic nephropathy, arterial sclerosis, obesity and association of essential hypertension can be the causes of hypertension in patients with non-insulin-dependent diabetes mellitus (NIDDM). Ambulatory blood pressure monitoring has revealed that the nocturnal fall of blood pressure is blunted in patients with diabetic nephropathy. A blunted diurnal blood pressure variation is seen in microalbuminuric diabetic patients and even in some normoalbuminuric patients. Accumulating data suggest that normalisation of blood pressure in hypertensive IDDM patients is most important to minimise the loss of kidney function. Angiotensin converting enzyme (ACE) inhibitors have been reported to be effective in postponing the development of nephropathy and in slowing its progression. Whether only ACE inhibitors have such beneficial renal effects on diabetic nephropathy is under discussion. While many studies have suggested that insulin resistance and hyperinsulinaemia are related to an elevated blood pressure in hypertensive patients, there does not seem to be enough evidence to prove that insulin per se can raise blood pressure in humans. Neither an insulin infusion within a physiological range nor sustained hyperinsulinaemia and insulin resistance (e.g. patients with insulinoma, cystic ovary syndrome) have been associated with an elevated blood pressure. Insulin resistance in some hypertensive patients may be a consequence of a decreased blood flow due to an increased peripheral resistance. Preliminary evidence suggests that low birth weight or impaired fetal growth is related to hypertension and NIDDM. Familial clustering of diabetic nephropathy suggests the contribution of genetic susceptibility and/or environmental inheritance. The frequent association of nephropathy with hypertension has led to research on the genes related to hypertension (ACE, angiotensinogen). Nevertheless, to date no reliable and clinically useful genetic marker has been found. Attempts to correct the metabolic abnormalities derived from diabetes are a new topic in the treatment of diabetic nephropathy. The effects of HMG CoA reductase inhibitors (antihypercholesterolaemic drugs), aldose reductase inhibitors (inhibitors of the polyol pathway) and glycation inhibitors (inhibitors of formation of advanced glycosylation end-products) on diabetic nephropathy have been evaluated in animal studies and in some clinical trials. Thus far, results with HMG CoA reductase and aldose reductase inhibitors have been somewhat conflicting. The potential therapeutic role of glycation inhibition in the treatment of diabetes deserves further study.
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PMID:Diabetic nephropathy. Its relationship to hypertension and means of pharmacological intervention. 925 79

The increasing prevalence of traditional atherosclerotic risk factors have been documented in Asia but the real impact on prevalence of coronary heart disease (CHD) remains unclear. Smoking, hypertension, hypercholesterolaemia, diabetes mellitus and obesity are present in only 50% of CHD. In community studies of Chinese in Hong Kong and southern mainland-China, aging, smoking and hypercholesterolaemia were found to have a less impact on endothelial function in the Chinese compared with Caucasians in London and Sydney. As endothelial dysfunction is an early event in atherogenesis, there will be a strong need to search for newer risk factors for CHD in Asia, which may become more important in many Asian countries now in the process of modernization. Recently, heterozygous hyperhomocysteinaemia (with or without folate deficiency) was found to be an independent risk factor for arterial endothelial dysfunction, and hyperhomocysteinaemia in association with smoking was a significant risk factor for premature coronary heart disease in Hong Kong Chinese. Other newer factors which have emerged include folate deficiency, low HDL-cholesterol, insulin resistance, abdominal obesity, Methylene-tetrahydrofolate Reductase and Angiotensin Converting Enzyme gene polymorphism.
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PMID:New risk factors for coronary heart disease in Asia. 946 82

Angiotensin II regulates blood pressure and may affect adipogenesis and adipocyte metabolism. Angiotensin II is produced by cleavage of angiotensinogen by renin and angiotensin-converting enzyme in the circulation. In addition, angiotensin II may be produced in various tissues by enzymes of the renin-angiotensin system (RAS) or the nonrenin-angiotensin system (NRAS). We have analyzed the expression of angiotensinogen and enzymes required for its conversion to angiotensin II in human adipose tissue. Northern blot demonstrated angiotensinogen expression in adipose tissue from nine obese subjects. Western blot revealed a distinct band of expected size of the angiotensinogen protein (61 kDa) in isolated adipocytes. RT-PCR, followed by Southern blot, demonstrated renin expression in human adipose tissue. Angiotensin-converting enzyme messenger RNA was detected by RT-PCR, and the identity of the PCR products was verified by restriction enzyme cleavage. Transcripts for cathepsin D and cathepsin G, components of the NRAS, were detected by RT-PCR, verified by restriction enzyme cleavage. We conclude that human adipose tissue expresses angiotensinogen and enzymes of RAS and NRAS. This opens the possibility that angiotensinogen-derived peptides, produced in adipose tissue itself, may affect adipogenesis and play a role in the pathogenesis of obesity.
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PMID:Human adipose tissue expresses angiotensinogen and enzymes required for its conversion to angiotensin II. 981 70

Angiotensin (Ang) II is the active component of the renin-angiotensin-system (RAS), but its degradation products have also been shown to exhibit biological activity. This system, which mainly controls blood pressure and electrolyte homeostasis, was recently found to be completely expressed in human adipose tissue. The major determinant in the fibrinolytic system is the plasminogen activator inhibitor-1 (PAI-1). Both PAI-1 and components of the RAS are over-expressed in the obese state. We have recently shown that Ang II is able to induce PAI-1 expression and release via the AT1-receptor in human fat cells in primary culture, and have provided the first evidence that two metabolites, Ang III and Ang IV, may have a similar stimulatory effect on PAI-1 release. We have now performed additional experiments to further characterize the role of the angiotensin peptides in the production of PAI-1. Ang III and Ang IV showed a time- and dose-dependent stimulation of PAI-1 protein release. Concomitantly, mRNA-levels were markedly elevated. Using specific receptor blockers, all angiotensin peptides seem to induce PAI-1 expression via the angiotensin receptor subtype 1. However, components of the renin-angiotensin-system seem to play an important role in the control of fibrinolysis in adipose tissue. We conclude that PAI-1 production by adipose tissue may contribute to the elevated thromboembolic risk in obesity.
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PMID:Effect of angiotensin peptides on PAI-1 expression and production in human adipocytes. 1138 21

Numerous prospective studies have shown that high heart rate is related to the development of hypertension, atherosclerosis, and incidence of cardiovascular events. Experimental studies in monkeys have shown that high heart rate has direct atherogenic effects on the arteries as a result of increased wall stress. However, clustering of several risk factors for coronary artery disease in persons with high heart rate suggests that sympathetic overactivity also accounts for part of the increased cardiovascular morbidity that is observed in persons with tachycardia. Indeed, experimental studies have shown that heightened sympathetic tone can cause obesity, hyperinsulinemia, and insulin resistance, which in the long term can promote the development of atherosclerosis. Through its interaction with plasma insulin, sympathetic overactivity can promote the development of left ventricular hypertrophy. Sympathetic activation can also increase hematocrit and precipitate a procoagulant state. Angiotensin II has an effect both on the central nervous system, enhancing sympathetic outflow, and on the peripheral sympathetic nerves. Among the angiotensin II receptor antagonists, eprosartan showed a particular ability to block presynaptic angiotensin II receptor 1 (AT(1)) receptors at neuro-effector junctions in the sympathetic nervous system, as well as AT(1) receptors in blood vessels. This dual action may represent an important advance in treatment of elevated blood pressure.
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PMID:Sympathetic overactivity in hypertension: a risk factor for cardiovascular disease. 1158 Aug 82

Age-related hypertrophy of adipose tissue has been associated with a significant decrease in the number of angiotensin II receptors. The aim of this study was to investigate the characteristics of angiotensin II receptors in hypertrophic adipose tissue in animal obesity model using rats postnatally treated with monosodium glutamate. Angiotensin II is known to induce hypertrophy in several tissues of the cardiovascular system and might do the same in fat tissue. The expression and binding properties of angiotensin II AT(1) receptors in epididymal fat tissue of adult rats were studied using membrane-binding, RT-PCR, and immunoblotting. The amount of AT(1) receptor mRNA did not differ significantly between obese and control rats. Despite that glutamate-treated rats displayed approximately 4-times more AT(1) receptor immunoreactive protein content in fat tissue cell membranes than the controls did. In contrast, binding experiments showed a significant (40.3 +/- 6.2 %) decrease of (125)I-Sar(1)-Ile(8)-angiotensin II-binding to fat tissue cell membranes in obese rats compared to controls. In conclusion, the present study provides evidence for the low binding properties associated with an accumulation of AT(1) receptor protein in cell membranes of the fat tissue of rats with glutamate-induced obesity. Discrepancies among angiotensin II-binding, AT(1) receptor protein, and AT(1) receptor mRNA levels indicate a possible defect in the receptor protein, which remains to be identified. The results obtained support a role of angiotensin II and AT(1) receptors in the pathogenesis of obesity.
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PMID:Elevated AT1 receptor protein but lower angiotensin II-binding in adipose tissue of rats with monosodium glutamate-induced obesity. 1175 55

The introduction of new immunosuppressive regimens results in the significant improvement in the outcome of patients after kidney transplantation. However, about 5 percent of renal transplants are lost every year. Not only immunological (alloantigendependent) but also nonimmunological (alloantigen-independent) factors are involved in late graft loss. Among them, hypertension, hyperlipidemia, proteinuria, genetic predisposition, viral infection and nephrotoxicity of immunosuppressive drugs contribute to the development and to the progression of chronic post-transplant nephropathy. Hypertension can be both the cause and the consequence of chronic allograft failure. Hypertension is frequently observed before transplantation, persists after grafting and increases the risk of chronic allograft nephropathy. Hypercholesterolemia, obesity, atheromatosis, polycythemia, and excessive salt intake are factors contributing in post-transplant hypertension. However, in some cases, hypertension can be transferred with the grafted kidney, as observed in normotensive patients before renal transplantation. In 1 to 12 percent of cases, the cause of post transplant hypertension is the stenosis of the transplant artery. Sometimes the presence of hypertension in renal recipients may result from the recurrence of glomerulonephritis or from the development of glomerulonephritis de novo in the graft. Also immunosuppressive treatment with corticosteroids and cyclosporine A contributes to the increased prevalence of hypertension by 20-30 percent. The development of the graft nephroarteriolosclerosis as a consequence of hypertension accelerates the progression of the post-transplant nephropathy. Adequate control of the arterial pressure (< 140/90) should be achieved in all renal transplant recipients. Reduction in protein and salt intake is important to reduce hyper-filtration and slows the progression of transplant nephropathy. However, pharmacological treatment is usually needed. Angiotensin-converting-enzyme inhibitors, angiotensin II type I receptor antagonists exhibit beneficial hemodynamic effect leading to the reduction of glomerular hypertension and proteinuria. Calcium antagonists besides their systemic antihypertensive effect, can protect renal grafts from vascular and renal toxicity of CyA. Sometimes, combined therapy with these and other antihypertensive drugs and diuretics is necessary.
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PMID:[Post-transplant nephropathy and arterial hypertension]. 1186 48

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