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:6.2.1.7 (BAL)
1,977 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The hydrolysis of o-nitrophenyl-beta-D-galactopyranoside (ONPG) by BAL-31, a marine Pseudomonas that acts as a host for bacteriophage PM2, was studied with intact cells and with cell-free extracts. A transport system for ONPG in whole cells and a beta-galactosidase activity in extracts were evident for cells grown on lactose minimal medium. It was found that the addition of isopropylthio-beta-D-galactopyranoside (IPTG) to cells growing in rich medium induced an ONPG hydrolytic activity detectable in cell extracts but cryptic in whole cells. The existence of a transport system for IPTG, which remained cryptic for ONPG, became apparent from studies of the rates of induction of beta-galactosidase as a function of cell mass at different concentrations of IPTG. The main properties of beta-galactosidase and the lactose transport system of BAL-31 were studied in terms of how they were affected by pH, temperature, or by the presence of several sugars. IPTG competitively inhibits the hydrolysis of ONPG by cell extracts. In cells pregrown on lactose, IPTG slightly inhibits the transport of ONPG. Glucose, and with less efficiency lactose, also inhibits the hydrolysis of ONPG in cell extracts. The growth of cells on lactose minimal medium was inhibited by the addition of IPTG. A mechanism for this inhibition and for the inhibition of ONPG transport by IPTG is discussed.
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PMID:Induction and general properties of beta-galactosidase and beta-galactoside permease in Pseudomonas BAL-31. 1 11

The effect of the dithiols British Anti-Kewisite (BAL), dimercaptopropanesulfonic acid (DMPS), dimercaptosuccinic acid (DMSA) and a new metal binding agent 2,3-bis-(acetylthio)- propanesulfonamide (BAPSA) on the biliary excretion of arsenic in perfused livers of guinea pigs after acute experimental poisoning with As2O3 was investigated. Guinea pigs received As2O3, 10.0 mg/kg subcutaneously at 9 a.m. as a single injection. One hour after the injection the livers were perfused (2.5 ml x min.-1 x g-1 liver) with Krebs-Henseleit buffer and glucose for 80 min. After 40 min. of saline perfusion (control) 0.1 or 0.7 mmol/l BAL, DMSA, DMPS, or BAPSA were added to the perfusate and arsenic elimination in the bile and effluent perfusate was measured. The biliary excretion of arsenic in control livers between 40 and 80 min. was 0.7% of the total arsenic liver content before perfusion (= arsenic liver content after perfusion + portion excreted in the bile+perfusate). After antidote addition (0.1 mmol/l) the excretion was 0.2% for livers perfused with BAL, 6.8% for DMSA, 10.6% for DMPS, and 11.1% for BAPSA, respectively. After 0.7 mmol/l antidote the excretion of arsenic was 0.1% in livers perfused with BAL, 9.6% for DMSA, 12.3% for DMPS, and 13.3% for BAPSA, respectively. Except BAL, all compounds and most effectively BAPSA increased biliary excretion of arsenic. This indicates that excretion of arsenic which normally is mainly renal is shifted towards faecal excretion by the dithiols.
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PMID:Effect of various antidotes on biliary excretion of arsenic in isolated perfused livers of guinea pigs after acute experimental poisoning with As2O3. 160 23

The effects of a new aldose reductase inhibitor, 7-fluoro-2-(N-methyl-N-carboxymethyl)sulfamoyl xanthone (BAL-ARI8, CAS 124066-40-6), on the diabetic complications of streptozotocin-induced diabetic rats were studied. The daily administration of BAL-ARI8 throughout the 8-week course of the experiment sharply decreased the sorbitol accumulation in the lens of the diabetic rats. The incidence of cataract formation was also reduced, being detected in only 45% of BAL-ARI8 treated animals, against the 100% of diabetic controls showing cataract after 8 weeks from diabetes onset. On the other hand, the serum glucose levels remained unchanged. In diabetic controls, there was about a 2.5-fold increase of the total protein urinary excretion during the 24 h. Treatment with BAL-ARI8 prevented up to 70% of this increase. Individual protein components were examined by polyacrylamide gel electrophoresis and quantitated by laser densitometric analysis. Diabetic-induced proteinuria primarily resulted from excretion of newly detected proteins with molecular weight in the range 30,000-60,000 D, together with an increase of albumin (25% of the total excretion) and the presence of new higher molecular weight proteins (greater than 66,000 D). BAL-ARI8 administration resulted in a shift of the protein profile back toward normality i.e. 73% of proteins with molecular weight below 30,000 D, 7.5% albumin and no proteins above 66,000 D. These results suggest that BAL-ARI8 may represent a therapeutic approach for the management of diabetic complications.
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PMID:Effects of a new aldose reductase inhibitor on diabetic complications in rats. 181 Feb 61

The effect of the dithiols British Anti-Lewisite (Bal), dimercapto-propanesulfonic acid (DMPS), dimercaptosuccinic acid (DMSA) and a new metal binding agent 2,3-bis-(acetylthio)-propanesulfonamide (BAPSA) on the biliary excretion of arsenic in perfused livers of guinea pigs pretreated with As2O3 was investigated. Guinea pigs received As2O3, 2.5 mg/kg sc twice daily for 5 consecutive days. Sixteen hours after the last dose the livers were perfused (35 ml/min) with Krebs-Henseleit buffer with glucose for 80 min. After 50 min of perfusion 0.1 mmol/L or 0.7 mmol/L BAL, DMSA, DMPS, or BAPSA were added to the perfusate and arsenic elimination in the bile and effusate was measured. The total arsenic excretion in control livers between the 50th and 80th min was 6.1% of the total arsenic liver content. After antidote addition (0.1 mmol/L) the excretion increased to 7.9% (DMSA), 9.2% (BAL), 23.9% (BAPSA), and 27.1% (DMPS), respectively. After 0.7 mmol/L of antidote the excretion of arsenic was found to be 19.3% (DMSA), 19.9% (DMSA), 24.0% (BAL), and 43.3% (BAPSA), respectively. The increase resulted mainly from increased biliary excretion. In these experiments BAPSA was significantly more effective in the overall elimination of arsenic than DMSA, DMPS, and BAL. The treatment with chelating agents may cause a substantial shift to fecal elimination by the increase in biliary excretion (BAL less than DMSA less than DMPS less than BAPSA). From the therapeutic view the shift to fecal elimination may have the advantage that the amount of the toxicant which passes the kidney is reduced and thereby also the portion which might be harmful for the organ.
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PMID:Effect of chelating agents on biliary excretion of arsenic in perfused livers of guinea pigs pretreated with As2O3. 235 32

Alloxan is known to inhibit pancreatic B cell and liver glucokinase and glucose protects the enzyme against inhibition. The dithiol 1,4-dithiothreitol (1,4-DTT) protected against and reversed the inhibition of glucokinase by alloxan. An investigation into the structure-activity relationship using a variety of different dithiols demonstrated that the ability of the dithiols to protect against and to reverse the inhibition of glucokinase by alloxan was dependent on the spacing between the SH (thiol) groups of the various dithiols. Only 1,3-dimercaptopropane, 1,4-dimercaptobutane, 1,4-dithioerythritol, and 1,4-DTT, with intermediate spacing between the SH groups, reversed the inhibition of glucokinase induced by alloxan. Dithiols with two vicinal SH groups such as 1,2-dimercaptoethane and 2,3-dimercaptopropanol (BAL) were ineffective in the same way as dithiols with more widely spaced SH groups such as 1,5-dimercaptopentane and 1,6-dimercaptohexane. Except for 1,6-dimercaptohexane, all dithiols also protected glucokinase against the inhibition of alloxan. The monothiol cysteine, but not glutathione, a tripeptide monothiol, also protected glucokinase against alloxan inhibition but both were unable to reverse the inhibition. Like alloxan, other dithiol reagents such as ninhydrin, N-ethylmaleimide, and maleimide inhibited glucokinase. Glucose and 1,4-DTT protected glucokinase against this inhibition. 1,4-DTT partially reversed this inhibition. It is concluded, therefore, that the mechanism of inhibition of glucokinase by alloxan is a reaction of alloxan with two adjacent SH groups in the depth of the sugar-binding site of the glucokinase, with formation of a disulfide bond and concomitant inactivation of the enzyme. Because glucokinase can couple changes in the blood glucose concentration to changes in the glycolytic flux rate and corresponding changes in the rate of insulin secretion, it may function as a glucose signal recognition enzyme in the pancreatic B cell. This mechanism of interaction of alloxan with glucokinase may thereby provide an explanation for the ability of alloxan to inhibit glucose-induced insulin secretion.
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PMID:Inhibition of glucokinase by alloxan through interaction with SH groups in the sugar-binding site of the enzyme. 341 26

In rat pancreatic islets, cysteine analogues, including glutathione, acetylcysteine, cysteamine, D-penicillamine, L-cysteine ethyl ester, and cysteine-potentiated glucose (11.1 mM) induced insulin secretion in a concentration-dependent manner. Their maximal effects were similar and occurred at approximately 0.05, 0.05, 0.1, 0.5, 1.0, 1.0 mM, respectively. At substimulatory glucose levels (2.8 mM), insulin release was not affected by these compounds. In contrast, thiol compounds, structurally different from cysteine and its analogues, such as mesna, tiopronin, meso-2,3-dimercaptosuccinic acid (DMSA), dimercaprol (BAL), beta-thio-D-glucose, as well as those cysteine analogues that lack a free-thiol group, including L-cystine, cystamine, D-penicillamine disulfide, S-carbocysteine, and S-carbamoyl-L-cysteine, did not enhance insulin release at stimulatory glucose levels (11.1 mM); cystine (5 mM) was inhibitory. These in vitro data indicate that among the thiols tested here, only cysteine and its analogues potentiate glucose-induced insulin secretion, whereas thiols that are structurally not related to cysteine do not. This suggests that a cysteine moiety in the molecule is necessary for the insulinotropic effect. For their synergistic action to glucose, the availability of a sulfhydryl group is also a prerequisite. The maximal synergistic action is similar for all cysteine analogues tested, whereas the potency of action is different, suggesting similarity in the mechanism of action but differences in the affinity to the secretory system.
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PMID:Cysteine analogues potentiate glucose-induced insulin release in vitro. 353 85

The relative efficacy of thiol-containing mercurial scavengers was assayed by using cellular suspensions of erythrocytes or isolated hepatocytes. The blood cells incubated in a buffer (pH 7.4) containing 1 mM glucose (10% hematocrit) were exposed to 5 microM methyl mercuric chloride. In the absence of extracellular thiols the red blood cells took up more than 90% of methyl mercury from the surrounding medium during 5--10 min. This uptake was almost completely inhibited by dimercaptosuccinic acid (DMSA) (1 mM) and the same chelant could rapidly remove 80% of the mercury from 'pre-loaded' erythrocytes. Hepatocytes prepared according to the method of Seglen [11] in a suspension of 10(6) cells/ml in a buffer containing 5 mM glucose and 5 mg/ml of bovine serum albumin were also exposed to methyl mercuric chloride (4 microM). Almost 50% of the mercurial was taken up by the cells slowly during the incubation period of 240 min. DMSA (1 mM) almost completely blocked the methyl mercury binding by the hepatocytes. 2-Mercaptopropionylglycin (Thiola) or mercaptosuccinic acid (MSA) was almost as effective mercurial scavengers as DMSA in hepatocytes and in red blood cells. Diethyldithiocarbamate (DDC) and dimercaptopropanol (BAL) were considerably less effective than DMSA to inhibit the mercurial binding to hepatocytes. Experiments in vivo have shown that DMSA is a better mercurial chelator than Thiola or MSA, whereas DDC and BAL may both be considered to be inapplicable in methyl mercury poisonings. Our cellular assay provides preliminary information of the efficiency of chelating thiols and may serve as a useful first approximation when planning further experiments.
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PMID:Evaluation of methyl mercury chelating agents using red blood cells and isolated hepatocytes. 728 35

It has been shown that oxophenylarsine (PhAsO) inhibits glucose uptake in MDCK cells. In addition to the known impairment of cellular energy metabolism, this inhibition may contribute to the acute toxicity of trivalent organic arsenicals. We have investigated the effect of BAL, DMPS, DMSA, and other sulfur compounds on cellular incorporation of [U-14C]PhAsO and their efficacy to revert PhAsO-induced inhibition of glucose uptake. In the presence of [U-14C]PhAsO (2 microM), the radiolabel was steadily accumulated by the cells over 150 min without any signs of severe cell damage (e.g., altered morphology, increased LDH release). A notable decrease of cellular ATP was only observed at 150 min, whereas within 30 min uptake of D-[6-(14)C]glucose was reduced to 40% of controls. When BAL, DMPS, or DMSA was added after 30 min, the inhibition of glucose uptake was reversed, accompanied by a decrease in cell-associated radiolabel from [U-14C]-PhAsO. Water-soluble DMPS and DMSA required longer times than BAL for comparable effects. 2,3-Bis(acetylthio)propanesulfonamide, a thioester derivative, and dithiothreitol, a 1,4-dithiol, were effective only with the highest concentration tested (200 microM). 2-Mercaptoethanol neither reversed inhibition of glucose uptake nor influenced [U-14C]PhAsO incorporation. Our results show that inhibition of glucose uptake is a very early event in PhAsO cytotoxicity which occurs before any decrease of cellular energy metabolism and/or full cellular loading with arsenic comes into effect. The more rapid onset of action of lipophilic BAL compared to PhAsO action.
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PMID:Reversal of oxophenylarsine-induced inhibition of glucose uptake in MDCK cells. 758 19

Trivalent monosubstituted organoarsenicals, e.g., oxophenylarsine (PhAsO), exert various detrimental effects on mammalian cells. In addition to their well known interference with pyruvate and ketoglutaric acid oxidation, the effect on other cellular functions such as uptake of glucose may contribute to their acute toxicity. Different effects of PhAsO on insulin-stimulated and insulin-independent uptake of hexoses in various tissues have been reported. It has been shown previously that PhAsO inhibits the stereospecific uptake of glucose in MDCK cells. In this work, the insulin dependence of glucose uptake in these cells and the effects of 2,3-dimercaptopropanol (BAL), dithiothreitol (DTT) and 2-mercaptoethanol (ME) on PhAsO-induced inhibition of glucose uptake were investigated. A 200 mumol l-1 concentration of insulin had no measurable effect on cellular 14C accumulation from D-[6(-14)C]glucose, indicating an insulin-independent hexose transport system. In the presence of 2 mumol l-(-1) of PhAsO, glucose uptake was lowered to less than 50% of controls within 30 min. Greater inhibition was observed with higher concentrations of PhAsO, but cell viability as assessed by formazan formation started to decrease at concentrations > or = to 5 mumol l-1, especially after longer exposure times. When BAL was added in a ten-fold molar excess 30 min after beginning incubation with PhAsO (2 mumol l-1, virtually complete recovery of inhibited glucose uptake occurred within 10 min after addition. ME at up to a 100-fold molar excess over arsenic had no influence on the inhibition of glucose uptake within 120 min after addition.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Influence of 2,3-dimercaptopropanol and other sulfur compounds on oxophenylarsine-mediated inhibition of glucose uptake in MDCK cells. 774 Dec 27

Metabolic activity of a gel-entrapment, hollow fiber, bioartificial liver was evaluated in vitro and during extracorporeal hemoperfusion in an anhepatic rabbit model. The bioartificial liver contained either 100 million rat hepatocytes (n = 12), fibroblasts (n = 3), or no cells (n = 7) during hemoperfusion of anhepatic rabbits. Eight other anhepatic rabbits were studied without hemoperfusion as anhepatic controls, and three sham rabbits served as normal controls. Albumin production rates (mean +/- SEM) were similar during in vitro (17.0 +/- 2.8 micrograms/h) and extracorporeal (18.0 +/- 4.0 micrograms/h) application of the hepatocyte bioartificial liver. Exogenous glucose requirements were reduced (p < 0.01) and euglycemia was prolonged (p < 0.001) in anhepatic rabbits treated with the hepatocyte bioartificial liver. The maximum rate of glucose production by the hepatocyte bioartificial liver ranged from 50-80 micrograms/h. Plasma concentrations of aromatic amino acids, proline, alanine, and ammonia were normalized in anhepatic rabbits during hepatocyte hemoperfusion. Gel-entrapped hepatocytes in the bioartifical liver performed sulfation and glucuronidation of 4-methylumbelliferone. P450 activity was demonstrated during both in vitro and extracorporeal application of the BAL device by the formation of 3-hydroxy-lidocaine, the major metabolite of lidocaine biotransformation by gel-entrapped rat hepatocytes. In summary, a gel-entrapment, bioartificial liver performed multiple hepatocyte-specific functions without adverse side effects during extracorporeal application in an anhepatic, small animal model. With its potential for short term support of acute liver failure, scale-up of the current bioartificial liver device is indicated for further investigations in large animal, preclinical trials.
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PMID:Extracorporeal application of a gel-entrapment, bioartificial liver: demonstration of drug metabolism and other biochemical functions. 816 29


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