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: EC:3.6.1.3 (ATPase)
65,361 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The activities of 13 liver and 6 brain enzymes were studied in 7-12 week old CD2F1 male mice that had been fed ad libitum and standardized either to 12 hours of light (0600-1800) alternating with 12 hours of darkness (1800-0600) (LD12:12); or to a reversed light-dark cycle (darkness 0600-1800; light 1800-0600) (DL12:12). Three separate studies were performed on two different days; in each experiment, subgroups of 14 animals were sacrificed at 3-hour intervals. Livers were assayed for: isocitrate dehydrogenase, glutamate dehydrogenase, lactate dehydrogenase, alcohol dehydrogenase, glutathione reductase, glyoxylate reductase, L-alanine aminotransferase, glutamate oxalacetate transaminase, pyruvate decarboxylase, fructose-1-phosphate aldolase, fructose diphosphate aldolase, fructose 1,6-diphosphatase, and fatty acid synthetase. Brains were assayed for phosphoglucose isomerase, adenosine triphosphatase, creatine phosphokinase, pyruvate kinase, adenylate kinase, and malate dehydrogenase. All 19 enzymes demonstrated a prominent circadian rhythm in at least one experiment. Moreover, each rhythmic variable showed a statistically significant fit to a 24-hour cosine (sine) curve by the method of least squares. In general, peak activities of the liver enzymes analyzed were associated with the beginning of the dark cycle and initiation of the animal's activity, while the group of brain enzymes had peak activities which occurred at the beginning of the animals' rest span and were near the beginning of the light cycle. The phasing of each of the rhythms could be reversed within a two-week span after reversing the environmental light-dark cycle 180 degrees.
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PMID:Circadian organization of thirteen liver and six brain enzymes of the mouse. 731 49

We assessed the effects of antidiuretic hormone and cyclic adenosine monophosphate (cAMP) analogues on transepithelial voltage, Ve, and/or net chloride absorption in isolated mouse medullary (mTALH) and cortical (cTALH) thick ascending limbs of Henle; the passive NaCl permeability characteristics and electrical properties of the mTALH; and the effects of anion and cation substitutions and transport inhibitors on both basal and ADH-stimulated Ve and/or net chloride absorption in the mTALH. The data demonstrate that these two segments are functionally heterogeneous: ADH, at concentrations comparable to plasma levels seen in mammalian species during ordinary antidiuresis, and/or cAMP increase three- to fourfold the rate of NaCl absorption in the mTALH but not in the cTALH. The ion substitution and inhibitor data are consistent with the view that NaCl absorption in the mTALH depends on a secondary active transport process: NaCl entry across luminal membranes is a coupled process of indeterminate stoichiometry that is driven by the transmembrane electrochemical gradient for Na+, which is maintained by Na+-K+-ATPase. Finally, the data demonstrate that the mTALH is electrically leaky whether measured electrically, 11 omega . cm2, or isotopically, 50 omega . cm2, but essentially water impermeable; and that the mTALH is perm-selective for Na+ with respect to Cl-. The disparity between electrical resistances measured directly with respect to those calculated from tracer fluxes, together with the hybrid characteristics of mTALH junctional complexes (leaky to Na+ and Cl-; tight to water), may be reconciled by assuming that mTALH junctional complexes contain passive ion permeation pathways composed of narrow channels through which ions pass in single-file fashion.
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PMID:NaCl transport in mouse medullary thick ascending limbs. I. Functional nephron heterogeneity and ADH-stimulated NaCl cotransport. 731 65

Gastric intubation of female Sprague-Dawley rats (80-150 g) with one large dose (5 g/kg) of ethanol nearly doubled oxygen uptake of the isolated, perfused rat liver in only 2.5 hours. This increased hepatic respiration can account for the Swift Increase in Alcohol Metabolism (SIAM). Inhibition of enhanced oxygen and ethanol uptake by KCN (2 mM) and 4-methylpyrazole (0.8 mM) indicated the involvement of the mitochondrial respiratory chain and alcohol dehydrogenase in this phenomenon, respectively. Epinephrine (2 mg/kg, i.p.) mimicked the increase in respiration observed with ethanol; however, the effects of epinephrine and ethanol were not additive. Pretreatment with alpha- and beta-adrenergic blocking agents, hypophysectomy and adrenalectomy prevented the increase in oxygen and ethanol uptake due to ethanol treatment. These data suggest that hormones including epinephrine are involved in the mechanism of SIAM. Hormone action in all likelihood activates a number of metabolic ATPase activities which lead to elevated oxygen uptake. One such process involved in the activation of oxygen uptake is diminished glycolysis, a ATP producing reaction sequence. The ADP not phosphorylated in the cytosol then enters the mitochondria where it stimulates oxygen uptake and NADH reoxidation. This ultimately leads to an acceleration of ADH-dependent ethanol metabolism.
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PMID:Mechanism of the swift increase in alcohol metabolism ("SIAM") in the rat. 742 36

The present overview indicates that the various nephron segments take part in the Na+Cl- reabsorption, the primary driving force for it is the (Na+, K+)-ATPase, which is localized in the basolateral membrane. The various segments have different modalities of Na+ uptake: in is by Na+/H+ exchange in the proximal tubule, by Na+/2Cl-/K+ co-transport in TAL, Na+Cl- cotransport in the distal tubule, and via Na+ channels in the principal cell of the collecting duct. In the proximal tubule bulk reabsorption occurs, but very small ionic gradients are built up, there for the transport here is so economical. In the TAL transport is already less economical, however ionic gradients are built up by this nephron segment inasmuch as Na+Cl- is reabsorbed and water cannot follow (the urinary concentrating mechanism). The distal tubule is concerned with defined control of Na+ and K+ excretion. Transport at this side is expensive, but very steep ionic gradients can be built up. The control is mediated by several hormones amongst which ADH and aldosterone are the most important ones.
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PMID:[The principles of studying ion transport in the kidney tubules]. 753 Oct 74

1. Endosulfan insecticide is a polychlorinated compound used for controlling a variety of insects; it is practically water-insoluble, but readily adheres to clay particles and persists in soil and water for several years. Its mode of action involves repetitive nerve-discharges positively correlated to increase in temperature. This compound is extremely toxic to most fish and can cause massive mortalities. In fish, it causes marked changes in Na and K concentrations, decrease in blood Ca(2+) and Mg levels and inhibits Na, K and Mg-dependent ATPase (in brain). 2. Bioaccumulation of endosulfan is reported for marine animals; however, freshwater animals (e.g., crayfish) accumulate it to some extent, but they lose the compound rapidly during depuration. Endosulfan is generally less toxic to aquatic invertebrates than fish. However, it causes decreases in adenylate energy charge, oxygen consumption, hemolymph amino acids, succinate dehydrogenase, heart-beat (mussel) and altered osmoregulation. 3. Generally, mammals are less susceptible to endosulfan's toxicity than aquatic animals. The majority of studies conducted on laboratory mammals can be summarized. (a) Neurotoxicity: male rats are more sensitive than females to endosulfan, which decreases brain and plasma acetylcholinesterase activity. Endosulfan I (a metabolite) causes a significant change in norepinephrine, 5-HT and GABA. (b) Renal toxicity: inhibition of MFOs activity was noticed in rats; other effects included changes in proximal convoluted tubules and necrosis of the tubular epithelium. (c) Hepatotoxicity: chemically-induced aminopyrine N-demethylase and aniline hydrolase were found in rat liver, and reduction in the glycogen level occurred. (d) Hematologic toxicity: endosulfan exposure resulted in a significant decrease in the level occurred. (d) Hematologic toxicity: endosulfan exposure resulted in a significant decrease in the erythrocyte glutathione reductase, hemoglobin amount, RBC number and mean corpuscular volume. 4. Respiratory toxicity: involved dyspnea, acute emphysema, cyanosis and hemorrhages in teh interalveolar portions of rat's lungs. 5. Biochemical: in rats, endosulfan caused increased glucose-6-phosphate dehydrogenase activity, blood glucose level, phospholipid contents of the microsomal and surfactant system, and profoundly induced the activity of alcohol dehydrogenase and cytosolic glutathione S-transferases. It also decreased significantly Na+, K+ and Mg(2+) ATPases, plasma calcium level and alkaline phosphatase in the intestinal epithelium. 6. Immunologic toxicity: rat serum antibody titer to tetanus toxin, IgG, IgM and gammaglobulins were significantly reduced. 7. Reproductive toxicity: degenerative changes in the seminiferous epithelium, induction of the rate-limiting enzyme in testosterone production (3beta-hydroxysteroid transferase and 17 beta-hydroxysteroid transferase), histological changes in reproductive organs, testicular atrophy and the occurrence of ovarian cysts were noticed in rat. Reduction in the weight of secondary sex organ was also observed.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Bioaccumulative potential and toxicity of endosulfan insecticide to non-target animals. 790 Sep 59

Chaperonin 60 and chaperonin 10 (GroEL and GroES homologues, respectively) have been isolated from extracts of the anaerobic thermophile Thermoanaerobacter brockii. A simple and rapid purification for chaperonin 60 made use of hydrophobic and anion-exchange chromatographies, and could be readily scaled up; approximately 2 mg pure chaperonin 60 was obtained/g cells. In contrast with all other prokaryotic chaperonin 60 proteins that have been studied, which are tetradecamers, including those from Thermus sp., the T. brockii protein is a heptamer, and as isolated was not in association with chaperonin 10. The preparation is readily crystallized using 2-propanol or poly(ethylene glycol) with MgCl2. The N-terminal amino acid sequence of this preparation is similar to other thermophilic chaperonin 60 proteins. Chaperonin 10 was purified from the flow-through of the first hydrophobic column (which bound chaperonin 60) using a more hydrophobic adsorbent to remove contaminating proteins, followed by anion-exchange chromatography. Chaperonin 10 was obtained with a yield of approximately 10% that of chaperonin 60. The subunit molecular mass of chaperonin 10 determined by electrospray mass spectrometry is 10254 +/- 0.4 Da, which is very similar to the molecular mass of Escherichia coli GroES. Similarly, the subunit size of chaperonin 60 determined by mass spectrometry is very similar to that of GroEL, at 57949 +/- 10 Da. T. brockii chaperonin 60 has an ATPase activity that is suppressed by chaperonin 10, and the two proteins together are active in protein-folding assays. Mitochondrial malate dehydrogenase was successfully refolded at 37 degrees C after denaturation in guanidine hydrochloride, using T. brockii chaperonin 60 and chaperonin 10, or chaperonin 60 and E. coli GroES. The denatured enzyme was protected from aggregation by association with chaperonin 60. Guanidine-hydrochloride-denatured preparations of isocitrate dehydrogenase and secondary alcohol dehydrogenase isolated from T. brockii were also refolded at 60-65 degrees C. In each case, refolding required chaperonin 60, chaperonin 10 and ATP, giving up to 80% regeneration of control activity.
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PMID:Purification and characterization of chaperonin 60 and chaperonin 10 from the anaerobic thermophile Thermoanaerobacter brockii. 791 71

Fluoride released from methoxyflurane (MOF) during its hepatic and extrahepatic metabolism has been regarded as the major culprit responsible for MOF-induced nephrotoxicity. In the isolated, perfused rat kidney model, admixture of 1500 mumol/l fluoride to the perfusate resulted in tubular and glomerular damage with concomitant anuria. Fluoride administration in Fischer 344 rats in vivo elicited a renal diabetes insipidus-like syndrome that had also been observed in patients after MOF anaesthesia. The renal concentrating defect is most probably due to both dissipation of the corticomedullary osmolality gradient in the interstitium and failure of water reabsorption due to ADH refractoriness of the distal tubular cells. Hypothetically, the underlying mechanism may be a fluoride-induced inhibition of enzymes involved in intracellular energy production such as ATPase or enolase. The degree of nephrotoxicity correlates loosely with maximal serum fluoride levels, but can probably be modulated by further factors like intrarenal in situ formation of fluoride, urinary pH and flow, and especially, the presence of other nephrotoxins. This mitigates the importance of maximal fluoride serum levels, especially the 50 mumol threshold, as predictors of clinically relevant nephrotoxicity. To date, no nephrotoxic effects of sevoflurane could be demonstrated.
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PMID:[Nephrotoxicity and fluoride from the viewpoint of the nephrologist]. 877 2

This review will discuss generalized myxedema as it develops in hypothyroidism. First, the precipitating conditions (thyroprivic trophoprivic + goitrous forms) and the clinical manifestations of thyroid hormone deficiency are presented. Pathobiochemical and pathophysiological factors that lead to the main manifestations include retention of fluid, retention of sodium and hyponatremia. In particular are primary and direct consequences of reduced thyroid hormone levels, and secondary or indirect consequences, such as cardiovascular and renal derangements. In hypothyroidism many biochemical disturbances result. Most important is the interstitial deposition of hydrophilic mucopolysaccharides, which in turn lead to fluid and Na retention and impairment of blood circulation and lymphatic drainage. Myxedema, therefore, is to a large extent a lymphatic edema. Hyponatremia is an indirect consequence of the lack of T3 and is directly caused by impaired renal Na reabsorption. Renal Na,K-ATPase is reduced in specific segments. The often discussed role of inappropriate elevation of circulating ADH does not seem to be a key factor in myxedema. Impaired capacity of renal water excretion is caused by reduced GFR. We discuss the time dependent development of the derangement of different organ systems, and include recently published biochemical results, according to which the lack of T3 interferes not only with the metabolism of numerous compounds of the interstitial matrix, but also with cell surface proteins and intracellular proteins of microfilaments. Finally, we refer briefly to pretibial myxedema in states of hyperthyroidism, that is, infiltrative dermopathy in Graves' disease, which is caused by poorly understood autoimmune processes.
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PMID:Myxedema. 918 11

Zymomonas mobilis growing aerobically with 20 g glucose-1 (carbon-limited) in a chemostat exhibited an increase in both the molar growth yield (Yx/s) and the maximum molar growth yield (Yx/smax) and a decrease in both the specific substrate consumption rate (qs) and the maintenance energy consumption rate (me). Stepwise increase in the input oxygen partial pressure showed that anaerobic-to-aerobic transitional adaptation occurred in four stages: anaerobic (0 mm HgO2), oxygen-limited (7.6- 230 mm HgO2), intermediate (273 mm HgO2), and oxygen excess (290 mm HgO2). The steady-state biomass concentration, Yx/s, and intracellular ATP content increased between oxygen partial pressures of 7.6 and 120 mm HgO2, accompanied by a decrease in the qs and the specific acid production rate. The membrane ATPase activity decreased with increasing oxygen partial pressure and reached its lowest levels at 273 mm HgO2, which was the highest input oxygen partial pressure where steady-state conditions were possible. Glucokinase, glucose-6-phosphate dehydrogenase, glyceraldehyde-3-phosphate dehydrogenase, and alcohol dehydrogenase activities also decreased when the oxygen partial pressure was increased above 15 mm Hg, whereas pyruvate decarboxylase was unaffected by aeration. Growth inhibition at 290 mm HgO2 was characterised by a drastic reduction in the pyruvate kinase activity and a collapse in the intracellular ATP pool. The growth and enzyme data suggest that at low glucose concentrations and oxygen-limited conditions, the increase in biomass yields is a reflection of a redirection of ATP usage rather than a net increase in energy production.
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PMID:Changes in the growth and enzyme level of Zymomonas mobilis under oxygen-limited conditions at low glucose concentration. 921 13

In the present study we have analyzed protein oxidation on Escherichia coli when these cells were submitted to different stress conditions such as hydrogen peroxide, superoxide-generating compounds, and iron overloading. Carbonyl groups on oxidized cell proteins were examined by Western blot immunoassay. When anaerobically grown E. coli cells were exposed to hydrogen peroxide stress, alcohol dehydrogenase E, elongation factor G, the heat shock protein DNA K, oligopeptide-binding protein A, enolase, and the outer membrane protein A were identified as the major protein targets. A similar immunostained band pattern was found when cells were shifted from anaerobic to aerobic conditions in the presence of different concentrations of iron; it is relevant to note that oxidation of outer membrane protein C, not observed in peroxide stress conditions, was clearly detected as the concentration of iron was increased in the culture media. The hydrogen peroxide stress performed under aerobic conditions affected the beta-subunit of F0F1-ATPase; the rest of the oxidized protein pattern was very similar to that found for anaerobic conditions, with the exception of alcohol dehydrogenase E, a protein not synthesized aerobically. Cells submitted to superoxide stress using menadione showed a more specific pattern in which elongation factor G and the beta-subunit of F0F1-ATPase were affected significantly. When paraquat was used, although the degree of oxidative damage was lower, the same two modified proteins were detected, and DNA K was also clearly damaged. Cell viability was affected to different extents depending on the type of stress exerted. The results described in this paper provide data about the in vivo effects of oxidative stress on protein oxidation and give insights into understanding how such modifications can affect cellular functions.
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PMID:Identification of the major oxidatively damaged proteins in Escherichia coli cells exposed to oxidative stress. 944 17


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