Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.6.1.3 (ATPase)
 65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Two types of proton-translocating ATPases, H-ATPase and H-K-ATPase, are found in the renal tubular cells. H-ATPase is present in both endocytic vesicles and apical membranes in almost all nephron segments. On the other hand, H-K-ATPase is present only in the connecting tubule and collecting duct. There is evidence to suggest that H-ATPase may be involved in H secretion in almost all nephron segments. H-K-ATPase is involved not only in H secretion but also in K absorption in the collecting duct segments. Aldosterone administration and metabolic acidosis stimulate the activity of H-ATPase in all collecting duct segments, whereas hypokalemia has only a limited effect on H-ATPase activity. On the other hand, hypokalemia, as well as metabolic acidosis, stimulates H-K-ATPase activity in the collecting duct segments, whereas aldosterone administration alone plays a minor role in the regulation of this enzyme. The physiological role and regulation of H-ATPase in the proximal tubule has not been established.
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PMID:Respective roles of H-ATPase and H-K-ATPase in ion transport in the kidney. 183 66

Cellular cystine loading with cystine dimethyl ester inhibits volume absorption, transepithelial potential difference, glucose transport, and bicarbonate transport in proximal convoluted tubules perfused in vitro. This study examined the roles of ATP and NaK ATPase in this in vitro model of the Fanconi syndrome of cystinosis. Intracellular ATP was measured using the luciferin-luciferase assay. Intracellular ATP was reduced by 60% in proximal convoluted tubules incubated with 0.5 mM cystine dimethyl ester for 15 min at 37 degrees C (P less than 0.001). Incubation of cystine loaded tubules with 1 mM exogenous ATP increased intracellular ATP to levels not significantly different than that of controls. On the other hand, Vmax NaK ATPase activity was unchanged even though the incubation times and the concentration of cystine dimethyl ester were doubled to 30 min and 1 mM, respectively. In proximal convoluted tubules perfused in vitro, 0.5 mM cystine dimethyl ester resulted in an 89% inhibition in volume absorption (0.81 +/- 0.14 to 0.09 +/- 0.09 nl/mm.min), while there was only a 45% inhibition in volume absorption (P less than 0.01) due to cellular cystine loading in the presence of 1 mM lumen and bath ATP (0.94 +/- 0.05 to 0.52 +/- 0.11 nl/mm.min). These data demonstrate that proximal tubule cellular cystine loading decreases cellular ATP concentration, but does not directly inhibit NaK ATPase activity. The inhibition in transport and decrease in intracellular ATP due to cellular cystine loading was ameliorated by exogenous ATP. These data are consistent with cellular ATP depletion playing a major role in the inhibition of proximal tubule transport due to intracellular cystine loading.
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PMID:Role of adenosine triphosphate (ATP) and NaK ATPase in the inhibition of proximal tubule transport with intracellular cystine loading. 184 41

We have described the overall process that is responsible for the efficient transfer of ammonium from its production site in the proximal tubule cells to the final urine. The mechanism depends on direct NH4+ transport at a number of sites. There appears to be a predominance of NH3 over NH4+ transport in net total ammonia transport only in the collecting ducts and possibly the descending limbs of Henle's loop. Several examples of physiologically important direct NH4+ transport in the kidney were described. First, coupled Na/NH4/2Cl transport across the apical membrane of the thick ascending limb of Henle's loop mediates secondary active transport of ammonium, which drives countercurrent multiplication of ammonium in the renal medulla. Second, part of the NH4+ uptake across the apical membrane of the thick ascending limb may occur as a result of penetration by NH4+ through apical K+ channels. It is unknown whether NH4+ penetrates K+ channels in other tubule segments. Third, NH4+ can be actively transported into cells by substitution of NH4+ for K+ on the Na-K-ATPase. This NH4+ transport process is likely to be rapid enough to be physiologically significant only in the inner medulla, where NH4+ concentrations are high enough to successfully compete with K+. Fourth, NH4+ penetrates the paracellular pathway in some nephron segments such as the proximal tubule and thick ascending limb. Simple passive diffusion of NH4+ via the paracellular pathway is thought to be physiologically important in the thick ascending limb where it contributes to net NH4+ absorption.
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PMID:NH4+ transport in the kidney. 189 Aug 4

Proximal tubule cells play an essential role in the reabsorption of ions, water, and solutes from the glomerular filtrate. This is accomplished, in large part, by having a surface membrane polarized into structurally, biochemically, and physiologically distinct apical and basolateral membrane domains separated by cellular junctional complexes. Establishment and maintenance of these unique membrane domains are essential for the normal functioning of the cell. Ischemia results in the duration-dependent loss of apical and basolateral surface membrane lipid and protein polarity. Loss of surface membrane polarity is preceded by disruption of the microfilament network and opening of cellular tight junctions. Surface membrane lipids and proteins are then free to diffuse laterally within the bilayer into the alternate membrane domain. Functionally, ischemia-induced loss of epithelial polarity has been shown to be responsible for reduced sodium and glucose reabsorption. Reduced Na+ reabsorption has been related to redistribution of Na+, K(+)-ATPase into the apical membrane. During recovery from ischemic injury, proximal tubule cells undergo remodeling of the surface membrane such that the unique apical and basolateral membrane domains are reestablished, allowing for the return of normal cellular function.
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PMID:New insights into the cell biology of ischemic acute renal failure. 191 88

Oxygen deprivation to the kidney causes a multifactorial series of morphological, physiological, and biochemical alterations that occur as a function of time. One of the earliest events involves significant changes in the cellular contents of the physiologically important elements (ions) Na and K. Controversy exists as to the nature of changes in the content of the regulatory ion Ca, in either its free or bound form, and much less is known regarding in situ distribution and amounts of other elements such as Mg, P, S, and Cl during physiological or pathophysiological states. The objective of these studies was to evaluate element compartmentation in proximal renal tubules by using quantitative electron probe x-ray microanalysis, during specific conditions which are at least partially manifested during oxygen deprivation. Cells from control proximal tubule suspensions were compared with those exposed to (1) ouabain, to inhibit (Na+, K+)-ATPase; (2) mitochondrial uncouplers, to rapidly deplete ATP content; or (3) calcium ionophores, to cause a rapid elevation in cytoplasmic free calcium. In parallel with electron probe x-ray microanalysis imaging of subcellular elemental content, total cell potassium and ATP contents, enzyme release, oxygen consumption, cytoplasmic free calcium levels, and ultrastructural alterations were assessed. Results indicated that ATP depletion was, in the short term, more deleterious to renal proximal tubules than any of the tested ionic alterations. Intracellular organelles including mitochondria and nuclei appeared to be readily permeable to Na, K, and Cl, altering their concentrations of these ions in parallel with cytoplasmic concentrations. Lysosomes exhibited evidence of Cl accumulation, consistent with an inwardly directed proton ATPase with accompanying Cl transport. Whereas in the cytoplasm Na, K and Cl appeared to be mostly free, a large fraction of these ions within intracellular organelles seemed bound.
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PMID:Elemental microanalysis of organelles in proximal tubules. I. Alterations in transport and metabolism. 191 93

Enzyme histochemistry was assessed in semi-thin glycolmethacrylate sections after 100 mg/kg 2-bromoethanamine (BEA) hydrobromide had been given ip to male Wistar rats to induce renal papillary necrosis. Changes in the proximal tubular marker enzymes alkaline phosphatase (Alk Phos), gamma-glutamytranspeptidase (GGT) and adenosine triphosphatase (ATPase) were not apparent before 8 hr, but there was a progressive loss up to 144 hr. The proteinaceous PAS-positive casts in the loops of Henle and the collecting ducts stained for Alk Phos and GGT (from 12 hr) and for ATPase (from 18 hr). Acid phosphatase (Acid Phos) staining was increased in the proximal tubule lysosomes from 18 hr. There was a marked increase in Alk Phos in all hyperplastic upper urothelial cells from 8 to 24 hr, and a mosaic of staining remained in the pelvis adjacent to the necrosed papilla at 144 hr. At 12 hr, there was an increase in the staining of the pelvic, ureter and bladder vascular endothelial ATPase, the intensity and area of which increased progressively from 18 hr and almost occluded the capillary lumens in the worst affected areas by 144 hr. These data show several distinct series of pathological changes after the administration of BEA. The subtle degenerative changes in the proximal tubule followed the papillary lesion, but exfoliated brush border and proximal tubular cells were important components of the protein casts in the distal nephron. Similarly, the intense Alk Phos staining in the hyperplastic regions of the upper urothelium and the increased pelvic, ureteric and bladder endothelial ATPase staining suggested they develop as a consequence of the papillary lesion.
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PMID:Enzyme histochemical changes in an acutely induced renal papillary necrosis. 197

Suspensions of renal proximal tubules (RPT) are the in vitro model for many biochemical and physiologic investigations. Inasmuch as there are numerous procedures for tubule isolation and the more commonly used enzymatic procedures may disrupt the basement membrane, there is a need for information comparing the influence of various isolation methods on RPT viability and function in long-term suspension. Rabbit RPT isolated a) enzymatically (ENZ) by in vitro collagenase digestion and Percoll size and density purification, and b) mechanically (MECH) by in vitro iron oxide perfusion and purification by sieving and magnetic removal of glomeruli were compared for viability, morphology, and functional stability during long-term suspension. RPT isolated by ENZ and MECH methods had excellent viability (less than 15% lactate dehydrogenase release), limited lipid peroxidation (less than 0.2 nmol MDA.mg protein-1), and stable nystatin-stimulated oxygen consumption (QO2) (38 and 36 nmol O2.mg protein-1.min-1) throughout 24 h of incubation. Basal QO2 was higher in ENZ than MECH tubules (27 and 19 nmol O2.mg protein-1.min-1, respectively), and was unchanged over 24 h in each preparation. The higher basal QO2 in ENZ tubules was ouabain-sensitive, suggesting an increased rate of Na+,K(+)-ATPase activity in these tubules. Total glutathione content (oxidized + reduced) in ENZ and MECH tubules increased over the 24-h incubation from 8 to 18 nmol.mg protein-1. gamma-Glutamyltranspeptidase (GGT) activity of the RPT homogenates was equivalent in both preparations and stable over time. The ratio of suspension GGT activity to homogenate GGT activity doubled (0.4 to 0.8) during the incubation period. MECH tubules retained their tubule structure during 24 h of incubation whereas the ENZ tubules had a striking loss of tubular morphology over time. These results show that ENZ- and MECH-isolated renal proximal tubule suspensions exhibit similar biochemical properties in long-term incubations but differ in ouabain-sensitive QO2 and the retention of tubular morphology. The loss of tubular morphology and the increase in the rate of Na+,K(+)-ATPase activity in ENZ tubules may be secondary to the disruption of the tubular basement membrane.
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PMID:Differences in enzymatic and mechanical isolated rabbit renal proximal tubules: comparison in long-term incubation. 197 32

This study examines the receptor mechanisms by which dopamine (DA) inhibits Na(+)-K(+)-adenosinetriphosphatase (ATPase) activity in single permeabilized proximal tubule (PCT). Na(+)-K(+)-ATPase activity was inhibited in the presence of both DA1- and DA2-specific agonists but not by either agonist alone. The inhibition induced by DA (10(-6) M) was attenuated in the presence of either of the two DA2-specific antagonists S-sulpiride and YM 09151 at 10(-5) M and in the presence of the DA1 antagonist SCH 23390 (10(-5) M). PCT adenosine 3',5'-cyclic monophosphate (cAMP) levels were significantly increased in the presence of DA and DA1 agonist, but DA2 agonist had no effect on cell cAMP levels. Na(+)-K(+)-ATPase activity was significantly inhibited in PCT incubated with DA2 agonist (10(-5) M) and dibutyryl (DB)-cAMP (10(-6) M) but not with DA2 agonist (10(-5) M) only. PCT Na(+)-K(+)-ATPase activity was also significantly inhibited in the presence of both DA2 agonist (10(-5) M) and forskolin (10(-6) M). Neither DBcAMP (10(-6) M) nor forskolin (10(-6) M) alone inhibited Na(+)-K(+)-ATPase activity. In tubules incubated with DA (10(-8) to 10(-9) M), the presence of DBcAMP (10(-6) M) enhanced the sensitivity by which DA inhibited Na(+)-K(+)-ATPase activity. We conclude that PCT Na(+)-K(+)-ATPase activity is inhibited by a synergistic action of the DA1 and DA2 receptors, with the DA1 receptor acting to increase cell cAMP levels.
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PMID:Inhibition of proximal tubule Na(+)-K(+)-ATPase activity requires simultaneous activation of DA1 and DA2 receptors. 197 19

The Na(+)-dependent hexose carrier, an endogenous apical marker, develops during differentiation of LLC-PK1, an established cell line with characteristics of the proximal tubule. This development was inhibited by the microtubule-disrupting drugs, colchicine and nocodazole, while it was insensitive to lumicolchicine. This strongly suggests that microtubules are involved in the plasma membrane expression of the Na(+)-dependent hexose carrier. We also analyzed the increase in activity of endogenous apical and basolateral membrane proteins during the polarization process. The development of three apical (Na(+)-dependent hexose carrier, gamma-glutamyltransferase and alkaline phosphatase) and one basolateral membrane protein (Na+/K(+)-ATPase) was studied during the reorganization of LLC-PK1 cells into a polarized epithelium. Colchicine inhibited the rapid, transient increase in the expression of the Na(+)-dependent hexose carrier during this polarization process. A similar result was observed for the development of the other apical proteins, while the development of Na+/K(+)-ATPase seemed to be largely insensitive to colchicine. Our results are in agreement with the model that the vesicles containing the apical membrane proteins use microtubules as tracks to reach the plasma membrane. The transport of vesicles containing basolateral membrane proteins clearly occurs by a different pathway which is independent on an intact microtubular network. Since the inhibition by the microtubule-disrupting drugs was complete, it can be concluded that after disruption of microtubules, the apical vesicles do not use the basolateral pathway by default.
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PMID:Development of the Na(+)-dependent hexose carrier in LLC-PK1 cells is dependent on microtubules. 197 53

The present study was designed to quantitate the amount and to map the localization of N-ethylmaleimide (NEM)-sensitive adenosinetriphosphatase (ATPase) activity in microdissected segments of the rat nephron. After complete nephron mapping the effect of chronic metabolic acidosis and alkalosis on enzyme activity was determined. In control animals the highest enzyme activity was found in the early proximal convoluted tubule of juxtamedullary nephrons; superficial early proximal tubule as well as medullary and cortical thick ascending limbs and collecting ducts also contained substantial activity. Enzyme activity in the papillary collecting duct before entry into the ducts of Bellini was 329 +/- 93 pmol.mm-1.h-1 (n = 8); after entry, however, enzyme activity was approximately one-fourth that value (60 +/- 9 pmol.mm-1.h-1, n = 8, P less than 0.01). No NEM-sensitive ATPase activity was found in the thin limbs of the loop of Henle. Enzyme activity increased in both the medullary and cortical thick ascending limbs as well as in the cortical collecting tubule in response to NH4Cl-induced chronic metabolic acidosis; in the cortical collecting duct, metabolic acidosis increased maximum activity (Vmax) but did not change Michaelis-Menten constant (Km). In the proximal convoluted tubule, enzyme activity decreased with metabolic acidosis. Bicarbonate loading had no effect on enzyme activity except in the most distal portion of the collecting duct where it was stimulated. These results show that NEM-sensitive ATPase activity exists throughout much of the rat nephron. These data suggest that both the cortical collecting tubule and thick ascending limb are regulatory sites of distal urinary acidification during acid loading.
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PMID:NEM-sensitive ATPase activity in rat nephron: effect of metabolic acidosis and alkalosis. 213 83


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