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: DrugBank:EXPT00514 (Amiloride)
1,513 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We used an in vitro model, MDCK cyst, to determine the extent to which pharmacologic compounds known to inhibit plasma membrane solute transport mechanisms could alter the enlargement of renal epithelial cysts. Solitary MDCK cells cultured within collagen gel undergo clonal growth to form true epithelial cysts in which a single layer of polarized cells (apex toward lumen) encloses a fluid-filled cavity. Repeated observations by light microscopy were used to quantitate the rate of cyst growth in diameter, and demonstrated that cyst enlargement involved an increase in cell number (proliferation) and a net increase in intracystic volume (fluid secretion). Intracyst pressure was greater than the interstitium (6.7 mm H2O +/- 3.1 SD), indicating that fluid entry was secondary to net solute accumulation. Amiloride and seven amiloride analogs that inhibited to different degrees conductive Na+ transport, Na+-dependent H+ transport and Na+-dependent Ca++ transport reversibly decreased the rate of cyst enlargement. The effectiveness of these agents to retard cyst enlargement correlated with their relative potencies to inhibit Na+-dependent Ca++ transport. Morphologic examination indicated that amiloride and amiloride analogs decreased cell proliferation and fluid secretion to the same degree. Ouabain and vanadate (Na+K,ATPase inhibitors), and L-645,695 (Na+-dependent Cl-/HCO3- inhibitor) potently slowed cyst expansion. In contrast to amiloride and amiloride analogs, these agents caused an unusual degree of cellular stratification within the cyst walls, a finding consistent with the notion that fluid secretion was inhibited to a greater extent then cellular proliferation. We conclude that chemical inhibitors of primary and secondary active solute transport can diminish or halt the enlargement of epithelial cysts in vitro by decreasing the rate of cellular proliferation and/or net fluid secretion.
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PMID:Chemical modification of cell proliferation and fluid secretion in renal cysts. 277 Jan 16

Whether Na+ movement through the plasma membrane plays a role in thyroid hormone uptake was investigated in intact rat soleus muscles. After preincubation for 120 min at 37 degrees C in modified Krebs-Ringer bicarbonate containing 140 or 5 mM Na+ plus choline or lithium to maintain osmolarity, muscles were incubated with 50 pM [125I]triiodo-L-thyronine (T3) or [125I]L-thyroxine (T4) for 60 min. T3 uptake was decreased when extracellular Na+ was replaced by either choline or lithium, the amount of decrease corresponding to the specific (or saturable) uptake component. Monensin, an ionophore that stimulates Na+ entry, increased T3 uptake at 140 mM Na+ but not at 5 mM Na+. Amiloride, a Na+/H+ exchange inhibitor, had no effect on T3 uptake under basal conditions or when Na+ was replaced by choline, but reversed the action of lithium. Ouabain, an inhibitor of Na+/K+ ATPase, reduced specific T3 uptake. T4 uptake was unaffected by low extracellular Na+. These results are consistent with a major role of Na+ movement in T3 uptake by skeletal muscle, but not in T4 uptake, and suggest an involvement of membrane pumps in this process.
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PMID:Role of sodium in thyroid hormone uptake by rat skeletal muscle. 282 Oct 72

We have recently shown that substitution of Li+ for perfusate Na+ eliminates the HCO3(-)-rich choleresis produced by ursodeoxycholic acid (UDCA) in isolated perfused rat liver and that the increase in bile flow produced by both UDCA and taurocholic acid is partially inhibited by 1 mM amiloride. Although these findings are consistent with a role for Na+-H+ exchange in the choleresis produced by these bile acids, both Li+ substitution and amiloride affect other cellular processes, including Na+-K+-ATPase activity. We have now further explored both the relationship between UDCA-stimulated bile flow and biliary HCO3- secretion and the possible role of Na+-H+ exchange in this process by comparing the effects of amiloride with two of its more potent and presumably more specific analogues, 5-(N,N-dimethyl)amiloride hydrochloride (DMA) and 5-(N-ethyl-N-isopropyl)amiloride (EIA). In the absence of inhibitor, UDCA increased biliary HCO3- concentration ([HCO3-]) up to an apparent maximum of 60-70 mM, and bile flow and biliary HCO3- output appeared to be linearly related over a sixfold range of bile flow rates. Amiloride, DMA, and EIA each produced a concentration-dependent inhibition of UDCA-stimulated bile flow and biliary HCO3- output with an apparent rank order potency (EIA greater than DMA greater than amiloride) similar to that reported for inhibition of Na+-H+ exchange in other systems. None of the inhibitors significantly altered biliary UDCA output or the relationship between UDCA-induced bile flow and either biliary [HCO3-] or biliary HCO3- output. Effects of these inhibitors did not appear attributable either to nonspecific toxicity, as reflected by hepatic release of lactate dehydrogenase or K+, or to inhibition of hepatic Na+-K+-ATPase, measured as Na+-dependent uptake of 86Rb. In contrast to their effects on UDCA choleresis, these inhibitors had little or no effect on basal bile flow, biliary [HCO3-], and biliary HCO3- output. These findings indicate that UDCA-induced but not basal bile formation is closely coupled to biliary HCO3- concentration and output, and they provide additional evidence that UDCA choleresis requires an intact Na+-H+ exchange mechanism.
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PMID:Ursodeoxycholic acid choleresis: relationship to biliary HCO-3 and effects of Na+-H+ exchange inhibitors. 283 31

The effect of harmaline on the transport of organic ions was determined in rabbit kidney cortical slices. Harmaline inhibited p-aminohippurate (PAH) uptake noncompetitively in a dose-dependent manner over the concentration range of 0.1 and 10 mM, with the 50% inhibition at 0.65 mM. Harmaline also inhibited the microsomal Na-K-ATPase activity and the tissue oxygen consumption and altered cellular Na and K contents, the effective dose being similar to that on PAH uptake. Under anaerobic conditions, harmaline inhibited Na-dependent PAH uptake in Na, K-depleted slices. Harmaline was a strong competitive inhibitor of TEA transport, showing the 50% inhibition at 8 microM. Amiloride (0.5 mM) and choline (1 mM) inhibited TEA uptake by 74 and 75%, respectively. Harmaline did not inhibit additively the TEA uptake in the presence of amiloride or choline. These results suggest that harmaline affects PAH uptake across the basolateral membrane by inhibiting Na-K-ATPase in aerobic slices, and probably by interacting with the Na sensitive site on the PAH carrier in anaerobic slices. Harmaline inhibits TEA uptake by direct action on the organic cation transport system in the basolateral membrane of the rabbit renal proximal tubule.
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PMID:Effect of harmaline on organic ion transport in rabbit renal cortical slices. 285 31

Unidirectional 45Ca fluxes were measured in the turtle bladder under open-circuit and short-circuit conditions. In the open-circuited state net calcium flux (JnetCa) was secretory (serosa to mucosa) and was 388.3 +/- 84.5 pmol.mg-1.h-1 (n = 20, P less than 0.001). Ouabain (5 X 10(-4) M) reversed JnetCa to an absorptive flux (serosal minus mucosal flux = -195.8 +/- 41.3 pmol.mg-1.h-1; n = 20, P less than 0.001). Amiloride (1 X 10(-5) M) reduced both fluxes such that JnetCa was not significantly different from zero. Removal of mucosal sodium caused net calcium absorption; removal of serosal sodium caused calcium secretion. When bladders were short circuited, JnetCa decreased to approximately one-third of control value but remained secretory (138.4 +/- 54.3 pmol.mg-1.h-1; n = 9, P less than 0.025). When ouabain was added under short-circuit conditions, JnetCa was similar in magnitude and direction to ouabain under open-circuited conditions (i.e., absorptive). Tissue 45Ca content was approximately equal to 30-fold lower when the isotope was placed in the mucosal bath, suggesting that the apical membrane is the resistance barrier to calcium transport. The results obtained in this study are best explained by postulating a Ca2+-ATPase on the serosa of the turtle bladder epithelium and a sodium-calcium antiporter on the mucosa. In this model, the energy for calcium movement would be supplied, in large part, by the Na+-K+-ATPase. By increasing cell sodium, ouabain would decrease the activity of the mucosal sodium-calcium exchanger (or reverse it), uncovering active calcium transport across the serosa.
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PMID:Calcium transport in turtle bladder. 296 12

In brush border membrane vesicles prepared from mammalian kidney cortex, amiloride is a potent inhibitor of the Na+/H+ exchanger. In the present study, in vivo microperfusion was used to examine the effect of luminal amiloride on transport in the rat superficial proximal convoluted tubule. At a perfusion rate of 14 nl/min, addition of 10(-3) M amiloride to artificial early proximal tubular fluid reduced bicarbonate absorption from 103 +/- 7 to 81 +/- 5 pmol mm-1 X min-1 and volume absorption from 2.03 +/- 0.15 to 1.57 +/- 0.06 nl X mm-1 X min-1. Glucose efflux was unchanged, excluding nonspecific inhibition of Na+-K+-ATPase. Luminal amiloride at 10(-4) M did not affect bicarbonate absorption or volume absorption. At a perfusion rate of 41 nl/min, 10(-3) M amiloride reduced bicarbonate absorption from 179 +/- 8 to 114 +/- 9 pmol X mm-1 X min-1, a significantly greater inhibition than that seen in tubules perfused at 14 nl/min. Amiloride at 10(-3) M had no significant effect on sodium chloride absorption as measured by volume flux from an artificial late proximal tubular fluid. The results show that luminal amiloride specifically inhibits proximal acidification and demonstrate involvement of the Na+/H+ antiporter in proximal tubular acidification. However, the inhibition of acidification is less than the inhibition of Na+/H+ exchange predicted by vesicle studies.
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PMID:Amiloride inhibition of proximal tubular acidification. 298 47

Effects of amiloride on the inotropic and toxic actions of cardiac glycosides were examined using left atrial muscle isolated from guinea pig heart. Preincubation of atrial muscle with amiloride significantly decreased the maximum positive inotropic effect of dihydrodigoxin but failed to reduce that of isoproterenol. Amiloride prevented the contracture and significantly reduced the incidence of arrhythmias induced by 2 microM digoxin. Similar experiments examining 5 microM digoxin-induced arrhythmias showed that amiloride increased both the time required to produce arrhythmias and the fractional occupancy of sarcolemmal Na,K-ATPase by digoxin at the onset of arrhythmias. The antagonism of cardiac glycoside actions was best observed during the decline in developed tension elicited by amiloride subsequent to its initial positive inotropic effect. Amiloride had no effect on binding site concentration for ATP-dependent [3H]ouabain binding but decreased affinity of the binding sites for ouabain in membrane preparations obtained from guinea pig heart. Furthermore, amiloride inhibited Na,K-ATPase activity and increased the IC50 value for ouabain inhibition of the enzyme. These results indicate that amiloride antagonizes the positive inotropic and toxic effects of cardiac glycosides. Possible mechanisms for the antagonism include inhibition of sarcolemmal Na+/Ca2+ or Na+/H+ exchange.
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PMID:Suppression of positive inotropic and toxic effects of cardiac glycosides by amiloride. 299 21

Amiloride (8 X 10(-4), an inhibitor of sodium channels of nonexcited membranes, inhibits the activity of Na+,K+-ATPase in the kidney cortex homogenate as well as that of the partially purified membrane-bound and lubrol-soluble Na+,K+-ATPase preparations from the cattle brain. Inhibition of Na+,K+-ATPase from different organs of various animals by amiloride, a blocker of sodium channels, indicates similarity of the molecular organization of the Na+-recognizing component both of sodium channels and sodium centres of Na+,K+-ATPase.
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PMID:[Effect of amiloride on the activity of membrane-bound and soluble Na+-,K+-ATPase preparations]. 300 40

Iodide uptake by primary cultures of turtle thyroid cells decreased linearly with reduction of Na+ concentration in the medium, but changes in medium Cl- concentration did not affect iodide uptake. Ouabain, furosemide, monensin, and perchlorate all decreased 125I-uptake by cultured thyroid cells, whereas amiloride and triamterene did not. Ouabain, monensin, perchlorate, and amiloride depolarized the membrane of cultured cells, whereas furosemide and triamterene had no effect. Ouabain and perchlorate increased intracellular Na+ and Cl- and decreased K+ activities; furosemide and monensin reduced all three ions, but triamterene had no effect. Amiloride decreased intracellular Na+ and increased intracellular Cl- activities, however, its effect on K+ activity could not be determined because of interference by this compound of the K+ ion exchanger. All the agents, except furosemide, inhibited Na+-K+-ATPase activity. These experiments demonstrate that 1) Na+-I- cotransport is responsible for most iodide accumulation in thyroid cells; 2) Na+-I- cotransport system is linked to the Na+-K+ pump; 3) active iodide transport does not always correlate with Na+-K+-ATPase activity; 4) a perchlorate-sensitive iodide transport system is present in thyroid cells; 5) transport processes, not involved in active iodide transport (Na+-Cl- cotransport and Na+-H+ counter transport), are also present in cultured thyroid cells.
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PMID:Effects of sodium on iodide transport in primary cultures of turtle thyroid cells. 300 70

Aldosterone and insulin stimulate Na+ transport through mechanisms involving protein synthesis. Na+-K+-ATPase has been implicated in the action of both hormones. We examined the effect of aldosterone and insulin on Na+-K+-ATPase in epithelial cells in culture derived from toad urinary bladder (TB6C) and toad kidney (A6). Aldosterone, but not insulin, increases short-circuit current (ISC) in TB6C cells. Aldosterone increases Na+-K+-ATPase activity after 18 h of incubation, but no effect can be seen at 3 and 6 h. Amiloride, which inhibits aldosterone-induced increases in ISC, has no effect on either basal or aldosterone stimulated enzyme activity. Both aldosterone and insulin increase ISC in A6 cells and when added together are synergistic. Aldosterone stimulates enzyme activity in A6 cells, but insulin alone has no effect. However, aldosterone and insulin together stimulate enzyme activity more than aldosterone alone. It appears that stimulation of Na+-K+-ATPase activity is involved in aldosterone action in both cell lines but does not appear to be due to increased Na+ entry, since enhanced enzyme activity is not inhibited by amiloride. In contrast, insulin alone has no direct effect on Na+-K+-ATPase, although the increased enzyme activity following both agents in combination may explain their synergism on ISC.
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PMID:Hormonal regulation of Na+-K+-ATPase in cultured epithelial cells. 301 19


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