UMLS:C0011849 - FACTA Search

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Query: UMLS:C0011849 (diabetes)
277,896 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

To test the hypothesis that the function of glomerular mesangial cells is impaired in diabetes, we examined the responsiveness of mesangial cells cultured under high concentrations of glucose to atrial natriuretic peptide (ANP1) and angiotensin II (Ang II). The ANP-induced accumulation of cGMP was enhanced in mesangial cells cultured under high glucose conditions, possibly due to the activation of particulate guanylate cyclase. Ang II action in mesangial cells was evaluated by measuring the ability of Ang II to inhibit ANP-induced cGMP accumulation through both activating phosphodiesterase (initial phase) and inhibiting guanylate cyclase (maintenance phase). The inhibition of both ANP-induced cellular cGMP accumulation and particulate guanylate cyclase activity by Ang II was significantly reduced in mesangial cells cultured under high concentrations of glucose. Moreover, in the cells exposed to high concentrations of glucose, both basal and Ang II-stimulated levels of inositol 1,4,5-trisphosphate (IP3) were significantly reduced. These results indicate that, in high glucose conditions, the actions of ANP and Ang II are modulated differently, resulting in the impairment of contractile responsiveness of mesangial cells.
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PMID:Alteration of mesangial response to ANP and angiotensin II by glucose. 823 Oct 24

Ramipril blocks the conversion of angiotensin I to II. The literature indicates that diabetes is often associated with mild impairment of learning and memory. The study reports the effects of ramipril on memory retention in diabetic and non-diabetic mice. Mice were made diabetic by an injection of streptozocin. After overt signs of diabetes were present, diabetic or vehicle-treated mice were partially trained on a footshock active avoidance task. Immediately after training, ramipril (0.5-1.5 mg/kg s.c.) was administered and retention was tested by continuing training one week later until mice avoided footshock on five out of six trails. The results indicate that ramipril enhanced retention of both diabetic and control mice but it required about 5 times as much ramipril in diabetic as control mice to achieve the same effect on retention. Increased sensitivity to angiotensin II may play a role in cognitive impairment in diabetes.
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PMID:Dose-response differences in the ability of ramipril to improve retention in diabetic mice. 824 47

1. The combined effect of diabetes and hypertension on the plasma angiotensin II (AII)/glomerular AII receptor (AII-R) relationship in streptozotocin-induced diabetes was investigated as well as the effect of glycaemic control on this relationship. 2. Diabetes was induced in spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats with streptozotocin 60 mg/kg and blood sugars maintained between 18-21 mmol/L (uncontrolled diabetes) and 4-8 mmol/L (controlled diabetes). Rats were killed on days 1 and 7. Angiotensin II receptor was estimated by saturation analysis and plasma AII by radio-immunoassay. 3. Angiotensin II receptors were significantly higher in non-diabetic SHR than WKY rats (708 +/- 62 and 388 +/- 36 fmol/mg protein, respectively, P = 0.0008). Plasma AII were comparable in both groups (47 +/- 2.7, 38 +/- 3.5 pg/mL, respectively) and a significant inverse relationship between AII/AII-R was observed (WKY P = 0.02 and SHR P = 0.004). 4. On day 7, plasma AII and AII-R levels in diabetic groups were comparable with those of their non-diabetic controls. Diabetic WKY rats maintained an inverse correlation between AII and AII-R (controlled P = 0.04 and uncontrolled P = 0.015), but this did not occur in the SHR. 5. Absence of receptor response to varying ligand concentrations in the diabetic SHR may contribute to the development of nephropathy. Glycaemic control does not appear to reverse this abnormality in the SHR, so that co-existent hypertension may have a more direct influence on renal function.
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PMID:Abnormality of the glomerular angiotensin II receptor in experimental diabetic nephropathy. 832 23

Blood flow autoregulation is impaired in early diabetes mellitus, predisposing the renal microcirculation to injury. These hemodynamic changes have been strongly implicated in the development and progression of diabetic glomerulopathy. Blood flow autoregulation is predominantly a myogenic reflex which is strongly dependent on Ca2+ uptake by vascular smooth muscle cells (VSMC). Because impaired blood flow autoregulation may be responsive to glycemic control, the present study examined the effects of elevated extracellular glucose concentrations on basal, voltage sensitive and receptor operated Ca2+ uptake by VSMC. Confluent cultured rat VSMC were exposed to: (1) control medium (CM; 5 mM glucose); (2) high glucose medium (HGM; 10 to 30 mM glucose); or (3) osmotic control medium (OCM; glucose 5 mM + L-glucose 25 mM or mannitol 25 mM). A threshold glucose concentration of 15 mM markedly and maximally depressed basal Ca2+ uptake by VSMC (HGM 52% vs. CM). In addition, HGM significantly depressed voltage sensitive Ca2+ uptake by VSMC as determined by responses to BAY K 8644 (10(-7) M) or high extracellular [K+] (65 mM, HGM 50% vs. CM). HGM similarly depressed pressor hormone-stimulated Ca2+ uptake (AVP or Ang II 10(-7) M) by VSMC. The effects of HGM on Ca2+ uptake were time exposure dependent and reversible. Ca2+ uptake by VSMC in the presence of OCM did not differ from CM. Elevated extracellular glucose concentrations thus exert a direct and profound effect on basal, voltage sensitive and receptor operated Ca2+ uptake by VSMC. These observations may provide a biochemical basis for glucose-induced dysregulation of regional blood flow autoregulation in early diabetes mellitus.
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PMID:Effect of elevated extracellular glucose concentrations on transmembrane calcium ion fluxes in cultured rat VSMC. 839 16

In this article, we have discussed the localization of components of the renal renin-angiotensin system, as well as the existing information on the regulation of this axis and the effects of Ang II on renal function. All the components of the renin-angiotensin system are present in both fetal and adult kidney. In the adult kidney, renin is principally localized to jg cells of the distal afferent arteriole, where release is stimulated by increases in intracellular cAMP and inhibited by increases in cytosolic calcium. Four distinct stimuli mediating renin release are (1) NaCl sensed at the macula densa, (2) the sympathetic nervous system, (3) humoral factors, with Ang II, vasopressin, endothelin, and adenosine inhibiting renin release, and (4) changes in intrarenal blood pressure. Alterations in renal renin gene expression have been reported in pathophysiological states, such as salt depletion, diabetes mellitus, ureteral obstruction, Bartter's syndrome, and with high protein feeding. The highest renal concentrations of mRNA for the renin substrate angiotensinogen are found in the PT, where the protein is localized to subapical granules. Both salt depletion and androgens upregulate renal angiotensinogen mRNA. Of interest, renal angiotensinogen mRNA levels are lower in SHR than in normotensive WKY rats. As with angiotensinogen, renal ACE is mainly localized to the PT, with highest concentration on the brush border. The mechanisms of regulation of both renal angiotensinogen and ACE require further study. Using recently developed specific nonpeptide Ang II receptor antagonists, it appears that adult renal Ang II receptors are principally of the AT1 class, whereas fetal kidney Ang II receptors are of the AT2 subtype. By binding to AT1 receptors, Ang II exerts constrictive effects on both afferent and efferent arterioles, with increased effect reported on efferent arterioles. Glomerular Ang II receptors are localized to mesangial cells, mediating contractile responses resulting in changes in glomerular surface area and Kf, and potentially regulating mesangial sieving and phagocytosis. These receptors are reduced with salt restriction or in experimental diabetes. The highest concentrations of tubular Ang II receptors are found in PT, on both brush border and basolateral membranes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The intrarenal renin-angiotensin system. 843 83

The endothelium is a physical barrier between the blood and vascular smooth muscle, a source of enzymes activating and deactivating cardiovascular hormones and a site of production of relaxing and contracting factors. In addition, the endothelium is a source of growth inhibitors and promoters of vascular smooth muscle cells. Monoaminooxidase deactivates catecholamines and serotonin. Angiotensin converting enzyme transforms angiotensin I into angiotensin II and breaks down bradykinin into inactive products. Nitric oxide is a potent vasodilator and inhibitor of platelet function that under most circumstances is released together with prostacyclin, which exerts similar effects. Both substances play an important protective role in the coronary circulation in that they cause continuous vasodilation and inhibition of platelet function. In addition, the endothelium is a source of contracting factors such as endothelin-1, thromboxane A2, and endoperoxides. Endothelium-derived growth inhibitors include heparin (sulfates) and transforming growth factor beta 1, while basic fibroblast growth factors and platelet-derived growth factor and possibly endothelin promote proliferation. Because of its strategic anatomic position, the endothelium is a primary target for injuries and cardiovascular risk factors. In particular, aging, low density lipoproteins, hypertension, diabetes, and ischemia alter endothelium function. In arterial coronary bypass grafts, the release of nitric oxide is more pronounced than in vein grafts. Alterations of endothelial function may contribute to vasospasm, thrombus formation, and vascular proliferation and in turn myocardial ischemia, all common events in patients with coronary artery disease.
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PMID:Endothelial dysfunction in coronary artery disease. 847 60

Roughly 40% of all diabetic patients, whether insulin dependent or not, develop persistent albuminuria (over 300 mg/24 hr), a decrease in the glomerular filtration rate, and elevated blood pressure, ie, diabetic nephropathy. Diabetic nephropathy is the single most important cause of end stage renal disease in the Western world, and accounts for over a quarter of all end stage renal disease. It also is a major cause of the increased morbidity and mortality seen in diabetic patients; for example, the cost of end stage renal care in the United States currently exceeds +1.8 billion per year for diabetic nephropathy alone and is rapidly rising. Increased arterial blood pressure is an early and common finding in incipient and overt diabetic nephropathy. Fluid and sodium retention with normal concentrations of active renin, angiotensin I and II, and aldosterone has been demonstrated in diabetic renal disease. An impaired nocturnal decline in blood pressure is more prevalent in patients with diabetic nephropathy and autonomic neuropathy, and may contribute to the enhanced cardiovascular morbidity found in such patients. Moreover, raised blood pressure accelerates both the development and progression of diabetic nephropathy in insulin-dependent and non-insulin-dependent diabetes. The relationship between arterial blood pressure and diabetic nephropathy thus seems to be a complex one: nephropathy increasing blood pressure and blood pressure accelerating the course of nephropathy. Effective blood pressure reduction reduces albuminuria, delays the progression of nephropathy, and postpones renal insufficiency in diabetic nephropathy. Calcium antagonists and angiotensin converting enzyme inhibitors induce an acute increase in the glomerular filtration rate, renal plasma flow, and renal sodium excretion.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Calcium antagonists and the diabetic hypertensive patient. 850 35

The expression of angiotensin (Ang) II receptors, active renin and prorenin in porcine and bovine ovarian follicles and corpora lutea was investigated and compared. In the wall tissue of porcine follicles, the Ang II receptor density was 47 (range 19-97; n = 13) fmol/mg membrane protein. The active renin concentration was 1.32 (0.40-3.43; n = 23) GU/kg wet tissue. These values were about 35-fold and 15-fold lower, respectively, than previously found in bovine follicles. No prorenin could be detected in the porcine follicular wall tissue. Ang II receptors of subtype 2 (AT2 receptors) with a dissociation constant (Kd) of 1.01 (0.64-1.79; n = 8) nmol/l for [Sar1-Ile5-Ile8]-Ang II were demonstrated in the bovine corpus luteum. The receptor density was 22.7 (1.9-93; n = 26) fmol/mg membrane protein, which was about 10-fold higher than in porcine corpora lutea. The active renin concentration was 20.7 (2.2-60.0; n = 26) GU/kg tissue in bovine and 0.40 (0.16-1.09; n = 17) GU/kg tissue in porcine corpora lutea. No prorenin could be detected in corpora lutea from both species. The variation between species in expression of the ovarian renin-angiotensin system indicates the existence of species differences in the physiological role.
Exp Clin Endocrinol Diabetes 1995
PMID:Differences in expression of angiotensin II receptors and renin in porcine and bovine ovaries. 853 63

Our single channel work has characterized two ion channels capable of depolarizing mesangial cells and activating classic, voltage-activated Ca2+ channels in response to growth-stimulatory peptides (such as Ang II, ET and insulin): (1) Ca(2+)-dependent, 4 pS Cl- channel promoting Cl- efflux; and (2) Ca(2+)-dependent, 27 pS nonselective cation channels promoting cation influx. We have also characterized a third channel which provides an alternative, receptor-operated pathway for Ca2+ entry in response to the growth factor, PDGF: (3) Ca(2+)-permeable, 1 pS cation channel. Consistent with our model of mesangial cell signal transduction (Fig. 1), these three mesangial cell ion channels are activated by binding of growth factors to membrane receptors (Fig. 8). Defective channel regulation, such as occurs in early diabetes mellitus, would promote mesangial cell relaxation and pathogenic glomerular hyperfiltration. Glomerular hyperfiltration and hypertension have been proposed to be major pathogenic factors in renal disease progression [4, 29, 38, 39]. Compensatory renal growth factor responses initially provide adaptive changes in glomerular hemodynamics after loss of functional renal mass. However, chronic stimulation of these mesangial cell ion channels by renal growth factors would promote sustained extracellular Ca2+ entry, resulting in mesangial cell contraction and growth, and progressive decreases in Kf and GFR. Eventually, this process leads to irreversible renal damage due to the development of glomerulosclerosis and interstitial fibrosis.
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PMID:Role of growth factors in mesangial cell ion channel regulation. 856 77

1. In insulin-dependent diabetes mellitus, hyperglycaemia has a profound effect on renal and systemic haemodynamic function. The mechanism for this is unknown. 2. We conducted a study in 11 males with insulin-dependent diabetes mellitus, within 6 years of diagnosis. We examined the neurohumoral, haemodynamic and renal variables during euglycaemia (4.0-6.0 mmol/l) and after a 12 h period of hyperglycaemia (8.5-10.5 mmol/l). Subjects were examined in a sodium-replete state during supine rest and during simulated orthostatic stress induced by lower body negative pressure at -15 mmHg. 3. Variations in glycaemia markedly influenced plasma renin activity, which was increased at baseline during hyperglycaemia (3.82 +/- 0.66 pmol of angiotensin I h-1 ml-1 compared with 2.13 +/- 0.33 pmol of angiotensin I h-1 ml-1 during euglycaemia, P = 0.009), and rose further during simulated orthostatic stress. Mean arterial pressure was also elevated during hyperglycaemia (89 +/- 2 mmHg compared with 81 +/- 3 mmHg during euglycaemia, P = 0.03), both at rest and during orthostatic stress. 4. The renal haemodynamic effects of hyperglycaemia included maintenance of glomerular filtration rate in the face of significant declines in renal blood flow, and a probable increase in filtration fraction (0.21 +/- 0.01 compared with 0.18 +/- 0.01 during euglycaemia, P = 0.06). The responses of mean arterial pressure and renal blood flow to simulated orthostatic stress were not affected by hyperglycaemia, but the forearm vascular response was significantly augmented. 5. These data suggest that sustained hyperglycaemia activates the renin-angiotensin system, thereby increasing systemic and renal vasomotor tone. Over time such changes may have deleterious microvascular consequences.
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PMID:Effect of hyperglycaemia on arterial pressure, plasma renin activity and renal function in early diabetes. 877 24

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