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: UMLS:C0011570 (depression)
172,036 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Incubation of freshly isolated rat hepatocytes with highly purified radiolabeled rat transferrin in weakly buffered medium in the presence of 10 mM ethanol resulted in a marked diminution of iron uptake by these cells, associated with a greater pH depression than in ethanol-free control studies. This effect on iron uptake persisted, even when the cells were preincubated for 90 min with ethanol before the addition of transferrin. Increasing the buffering capacity of the system or the addition of a metabolic inhibitor of alcohol dehydrogenase (4-methylpyrazole) returned iron uptake to control values. Acetaldehyde, acetate, lactate (products of ethanol metabolism), and 3-butanol (an alcohol not metabolized by alcohol dehydrogenase) had no influence on iron uptake. Further investigation of iron uptake over the pH range 6-8.5 revealed a marked dependency of iron uptake on the extracellular pH. Leucine incorporation into cell protein was also found to be pH dependent. It is suggested that, in the light of current understanding of transferrin recycling by other cell types, the disturbances of iron homeostasis observed in alcoholics can be partially accounted for by alterations in their acid-base metabolism.
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PMID:Depression of iron uptake from transferrin by isolated hepatocytes in the presence of ethanol is a pH-dependent consequence of ethanol metabolism. 353 28

Prolonged ingestion of ethanol may lead to a cardiomyopathy, and studies in the experimental animal have demonstrated alterations in protein metabolism. These changes include depression of protein synthesis with acetaldehyde in the acute experiment, in vitro, and after chronic ethanol ingestion in vivo. The present studies were initiated to see if the inhibition of protein synthesis following prolonged ethanol ingestion involved myocardial contractile proteins. Newly weaned guinea pigs, weighing 350 g, were placed on a regimen of normal laboratory diet with 10% ethanol in the drinking water. Calorie-matched controls, drinking dextromaltose in the water, were simultaneously run. After 40 weeks of ingesting 10% ethanol in the drinking water, hearts from growing guinea pigs were removed and synthesis of myocardial contractile proteins (myosin heavy chains, light chains (LC1, LC2), actin, and tropomyosin) assayed in vitro with 3H-labeled amino acids. With aging, there was a decrease in the rates of synthesis of all the contractile proteins. After 40 weeks of ethanol ingestion, the synthetic rates of myosin heavy and light chains and tropomyosin were the same as in calorie-matched controls, but the synthetic rate of actin was significantly decreased by 20% (p less than 0.01). This decrease in actin synthesis may be the first indication of ultimate inhibition of synthesis of all the contractile proteins which may lead to myofibrillar disorganization and vacuolization reported after chronic ethanol ingestion.
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PMID:Prolonged feeding of ethanol to the young growing guinea pig. III. Effect on the synthesis of the myocardial contractile proteins. 354 78

The oxygen consumption of cerebral arterioles from anesthetized cats was measured using the Cartesian diver microrespirometer following in vitro incubation with 200 micrograms/ml of arachidonate or 50 micrograms/ml of 15-hydroperoxy-eicosatetraenoic acid (15-HPETE). Both agents depressed oxygen consumption severely. This effect was inhibited completely by a combination of superoxide dismutase (SOD) and catalase, indicating that it is mediated by oxygen radicals. Similar depression of oxygen consumption was observed during incubation of the vessels with xanthine oxidase and acetaldehyde as substrate. This enzymic system is known to generate superoxide and hydrogen peroxide. The effect of xanthine oxidase was also partially inhibited by SOD and catalase. The effect of arachidonate was partially inhibited by cyclooxygenase inhibitors. The effect of lipoxygenase inhibitors could not be adequately tested because they depressed oxygen consumption by themselves. Prostaglandins H2 and E2 had no effect on arteriolar oxygen consumption. The results show that arachidonate and 15-HPETE in high concentration depress cerebral arteriolar oxygen consumption via an oxygen radical-mediated mechanism. Furthermore, the radical is generated in the vessel wall and does not require either the brain parenchyma or the formed elements of the blood or the meninges for its production.
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PMID:Reduction in cerebral arteriolar oxygen consumption by arachidonate. 392 Sep 21

In vitro studies have shown that acetaldehyde is a more potent inhibitor of testicular steroidogenesis than ethanol. The present study examined the in vivo role of acetaldehyde in ethanol-induced reduction of testosterone by (1) determining the levels of acetaldehyde to which the testes were exposed subsequent to acute ethanol administration to mice; and (2) examining the effect of ethanol on testosterone in animals subsequent to drug pretreatment which decreased or increased ethanol-derived acetaldehyde. Ethanol-induced (3 g/kg) depression of testosterone was dependent upon gonadotropin stimulation. The increase in hCG-induced testosterone was suppressed (P less than 0.01) in ethanol- as compared to saline-treated animals [39.8 +/- 2.6 (S.E.M.) vs 28.1 +/- 2.3 ng/ml]. Pargyline (100 mg/kg) or cyanamide (8.4 mg/kg) increased (P less than 0.05) plasma and testicular acetaldehyde, while having no effect on the testosterone response to ethanol. Similarly, 4-methylpyrazole (25 mg/kg) reduced blood and testicular acetaldehyde to nondetectable levels, while having no effect on testosterone. Testicular acetaldehyde was lower (P less than 0.001) than plasma levels (14 +/- 2 vs 2.0 +/- 0.2 microM). This functional blood-testis barrier to acetaldehyde could be explained by testicular aldehyde dehydrogenases in the mitochondria (Km for acetaldehyde = 1.5 microM) and in the cytosol (Km = 123 microM) whose maximal activities totaled to more than 25-fold greater than that of testicular alcohol dehydrogenase (ADH). ADH was concentrated in the Leydig cells, while aldehyde dehydrogenase was evenly distributed in the testis. Ethanol prevented further hCG-induced rises in testosterone rather than inhibiting testosterone production to below pre-ethanol values. The above data argue against a significant role of acetaldehyde in the in vivo response of testosterone to ethanol. Ethanol appears to impair gonadotropin-testicular receptor interaction in vivo.
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PMID:Demonstration of a functional blood-testis barrier to acetaldehyde. Evidence for lack of acetaldehyde effect on ethanol-induced depression of testosterone in vivo. 397 44

Pretreatment of Fischer-344 (F-344) rats with formaldehyde (HCHO) induces significant cross tolerance to the sensory irritation properties of Cl2. The purpose of this study was to determine if HCHO pretreatment would cause sensory irritation cross tolerance to other inhaled aldehydes. Male F-344 rats, weighing 190 to 210 g, were pretreated with 15 ppm HCHO, 6 hr/day for 9 days, and challenged on the 10th day with a saturated (acetaldehyde, propionaldehyde, and butyraldehyde), unsaturated (acrolein and crotonaldehyde), or cyclic (cyclohexanecarboxaldehyde, 3-cyclohexene-1-carboxaldehyde, and benzaldehyde) aldehyde. The sensory irritation response in these animals was quantified by measuring respiratory rate depression in a head-only inhalation chamber using plethysmographic techniques. Control animals were challenged identically without prior pretreatment. In naive (nonpretreated) animals, the concentration eliciting a 50% decrease in respiratory rate (RD50) was 23 ppm or less for unsaturated aliphatic aldehydes. For cyclic and saturated aliphatic aldehydes, the RD50 ranged from 600 to 1000 ppm and 3000 to 6800 ppm, respectively. Formaldehyde pretreatment resulted in cross tolerance only with acetaldehyde (RD50 increased 3.5-fold) and acrolein (RD50 increased 5-fold). These results indicate that the development of cross tolerance following HCHO pretreatment is not a general phenomenon. Prediction of acceptable concentrations of occupational exposure for the prevention of sensory irritation in humans has been based primarily on RD50 data for mice. Comparison of the RD50 values obtained for rats in this investigation with previously published results for mice varied by over one-half an order of magnitude, thereby disputing the usefulness of data from F-344 rats in setting threshold limit values for the prevention of sensory irritation.
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PMID:Sensory irritation response to inhaled aldehydes after formaldehyde pretreatment. 404 1

Pretreatment with ammonium acetate (NH4Ac) (6 mmol/kg s.c.) approximately doubled the time morphine-treated mice remained on a hot surface and similarly increased muscular incoordination by diazepam, but NH4Ac treatment alone had no effect. Thus, hyperammonemia is capable of altering drug action and must be considered along with impaired drug metabolism in enhanced drug responses associated with liver disease. Experiments in vitro showed that acetylcholine-induced catecholamine release from bovine adrenal medulla is depressed as much as 50% by 0.3 mM NH4Ac and KCl-induced contractions of guinea-pig ileum were inhibited 20% by 5 mM NH4Ac. Addition of excess calcium reversed the depression in both tissues, but calcium-independent catecholamine release by acetaldehyde was not blocked by NH4Ac. These results suggested that ammonia blocks calcium channels. Parallels in the actions of NH4Ac and the calcium channel blocker verapamil support this concept. Both verapamil (10 mg/kg i.p.) and NH4Ac pretreatment enhanced morphine analgesia- and diazepam-induced muscular incoordination and antagonized amphetamine-induced motor activity, and neither verapamil nor NH4Ac affected the convulsant action of metrazol. The data suggest that hyperammonemia exerts a calcium channel blocking action which enhances the effects of central nervous system depressants and certain opioid analgesics.
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PMID:Modification of drug action by hyperammonemia. 632 92

Albumin synthesis was studied in the isolated perfused rabbit liver under the influence of the stresses of fasting and acute alcohol and acetaldehyde exposure. Fasting clearly depressed albumin production and disaggregated the endoplasmic membrane-bound polysomes. Acute exposure to alcohol produced the same results. Acetaldehyde 2 mg% resulted in a depression of albumin synthesis but the polysomes were not disaggregated. The metabolism of alcohol was necessary for polysome disaggregation. The acute effects of ethanol and fasting were quite similar and it might be considered that the alcohol was acting like a pharmacologic fast. Employing the liver from a fasted donor specific amino acids infused into the liver at levels of 10 mM reversed the acute effects of fasting and the acute effects of exposure to ethanol. However when the two stresses of fasting and alcohol were combined the same amino acids were not effective. In studying albumin synthesis and/or secretion it is necessary to carefully define the nutritional status of the experimental model.
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PMID:Effects of nutrition and alcohol on albumin synthesis. 634 44

Ther are several main mechanisms that allow us to understand a number of the hepatic and metabolic effects of ethanol. Ethanol is oxidized in the liver to two products (hydrogen and acetaldehyde), to which many of the effects of ethanol can be attributed. The hydrogen generated alters the redox state, and though this effect is attenuated after chronic ethanol consumption, it may still be sufficient to explain alterations in lipid metabolism, possibly increased collagen deposition, and, under special circumstances, depression of protein synthesis. Acetaldehyde impairs microtubules, decreases protein secretion, and causes protein retention and ballooning of the hepatocyte. Acetaldehyde exerts toxicity also with regard to other key cellular functions, particularly in the mitochondria, and it may promote peroxidation of the cellular membranes. It is noteworthy that after chronic consumption of ethanol, there is increased acetaldehyde, in part because of decreased disposition in the mitochondria and partly because of induction of an alternative pathway of ethanol metabolism, namely the microsomal ethanol-oxidizing system. Indeed, this MEOS increases in activity after chronic ethanol consumption, with cross induction and acceleration of the metabolism of other drugs and increased lipoprotein production with hyperlipemia. There is also increased microsomal activation of hepatotoxic compounds (including drugs and possibly vitamin A). Fibrosis and cirrhosis can develop despite an associated adequate diet and even in the absence of alcoholic hepatitis. They are preceded by myofibroblasts and fibroblast proliferation. What eventually causes the increased number of myofibroblasts and promotes fibrosis is unclear, nor do we know the relative role of hepatocytes or mesenchymal cells in the process of fibroplasis. Possibly selective roles in this process of specific nutritional factors remain to be elucidated.
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PMID:Alcohol, protein nutrition, and liver injury. 634 74

Infections and chronic liver injury are common causes of morbidity and mortality in alcoholics, and both of these may be related to an altered immune response. This study describes a guinea pig model of chronic ethanolism designed to selectively study the cellular immune system in a setting free from the malnutrition, socioeconomic deprivation, and severe underlying hepatic dysfunction seen in human disease. Animals were given 2.5 g/kg/day of ethanol as a 15% solution in 0.9% NaCl or isocaloric-dextrose-saline control solution intraperitoneally in 2 divided doses for 5 weeks. At 2 weeks, the mean serum ethanol level 1 hr after treatment was 20.4 mM (range 8.9-30.6) while the mean serum acetaldehyde level was 55.1 microM (range 17.0-111). At 5 weeks the serum levels for ethanol and acetaldehyde were 20.1 mM (13.3-32.9) and 41.5 microM (2.4-87.6), respectively. Weight gain was persistent throughout the study and did not differ significantly between ethanol and control groups. After 5 weeks of treatment, lymphocyte response to the mitogens, phytohemagglutinin, and concanavalin A was significantly decreased in the ethanol treated group (p less than 0.05). Response to the specific antigen, picrylated human serum albumin, T & B cell per cent and number, skin test reactivity, peripheral white blood cell count, total lymphocyte count, and migration inhibitory factor production were not significantly altered by 5 weeks of ethanol treatment. Therefore, in a controlled animal model of chronic ethanolism, we observed a significant depression of lymphocyte blastogenic response which may, in part, explain the increased propensity to infection by intracellular pathogens seen in alcoholics.
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PMID:Ethanol-induced alterations in lymphocyte function in the guinea pig. 637 25

Hemodynamics, energetics, and mechanics of isolated working rat hearts were studied during perfusion with Krebs-Henseleit medium containing either ethanol (24 +/- 2 mM) or acetaldehyde (74 +/- 6 microM). After 60-min perfusion with agent, mitochondria were isolated from the hearts and assayed polarographically using glutamate, alpha-keto-glutarate, pyruvate-malate, and succinate-rotenone substrates. Hemodynamic and mechanical function of the ethanol-treated hearts declined significantly more than that of control hearts during the 60-min perfusion. The acetaldehyde-perfused hearts did not differ from the controls. A 90-sec washout period reversed the ethanol-induced depression of physiologic function. Respiratory function (respiratory control ratio and Qo2) of mitochondria isolated from the ethanol- and acetaldehyde-treated hearts was slightly, though not significantly, depressed compared with control hearts. These data indicate that ethanol and acetaldehyde, at physiologically significant concentrations, have dissimilar effects on cardiac hemodynamics and mechanics: ethanol has a direct depressive effect which is reversible; acetaldehyde has no significant effect. Mitochondrial respiration is not irreversibly affected by brief exposure to ethanol or acetaldehyde at the concentrations tested.
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PMID:Mitochondrial respiration after cardiac perfusion with ethanol or acetaldehyde. 639 8


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