EC:1.9.3.1 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.9.3.1 (cytochrome oxidase)
8,822 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The in vivo effects of sodium cyanide and its antidotes, sodium nitrite, sodium thiosulfate and 4-dimethylaminophenol (DMAP), as well as the alpha-adrenergic blocking agent phentolamine, on rat brain cytochrome oxidase were studied. The course of inhibition was time-dependent and a peak of 40% was attained between 15 and 20 min after the s.c. injection of 1.3 LD50 (12 mg/kg) of cyanide. Pronounced dose-dependence was observed in the inhibition of the enzyme, at this relatively low, but lethal dose. Further observation was impossible because of rapidly lethal effects of cyanide. In animals artificially ventilated with room air, observation was possible up to 60 min. However, maximum inhibition was also 40%. When antidotes were applied 30 min after 20 mg/kg of cyanide, marked reactivation of cytochrome oxidase activity was observed with all antidotes (particularly with thiosulfate) except for phentolamine which had no effect. Prevention of methemoglobin forming with toluidine blue did not affect the reactivating ability of nitrite or DMAP, thus suggesting more complex protective mechanisms then simple methemoglobin formation. The high efficacy of thiosulfate may be attributed to its rhodanese catalyzed, direct binding to free blood cyanide, leading thus to its dissociation from cytochrome oxidase. The theory that cytochrome oxidase inhibition is a basic mechanism of cyanide toxicity could not be disproved.
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PMID:The in vivo effects of cyanide and its antidotes on rat brain cytochrome oxidase activity. 133 20

1. Some in vitro studies were performed to elucidate the action of S-adenosyl-L-methionine (SAM) and thiosulphate on liver rhodanese, delta-amino-levulinic acid dehydratase (Al A-D) and cytochrome oxidase affected by cyanide in the experimental conditions. 2. SAM was unable to interact with the sulfur substituted rhodanese complex suggesting that SAM would blockade the thiosulphate binding sites on rhodanese. 3. Cyanide and thiosulphate inhibited ALA-D activity when both compounds were present in the incubation or the preincubation mixture. Cyanide binding on the enzyme was irreversible. 4. Cyanide inhibited cytochrome oxidase activity and the reversible nature of the binding was demonstrated by gel filtration. 5. SAM had no effect on either ALA-D or cytochrome oxidase activities.
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PMID:In vitro effect of cyanide, thiosulphate and S-adenosyl-L-methionine on the activity of rhodanese and other enzymes. 164 44

1. The effect of acute cyanide administration to mice in a lethal and a non-lethal dose and the anti-cyanide effect of S-adenosyl-L-methionine (SAM) and thiosulphate were investigated. 2. The poisoning action was determined by measuring cytochrome oxidase, rhodanese and delta-aminolevulinic acid dehydratase (ALA-D) activity. 3. The toxic metabolizing degree was investigated by measuring plasma and urine thiocyanate levels. 4. The state of the sulfane sulfur pool was investigated by determining cyanide labile-sulfur levels. 5. These results support the belief that rhodanese plays a fundamental role in the detoxification process only when high levels of cyanide are administered.
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PMID:Cyanide intoxication--III. On the analogous and different effects provoked by non-lethal and lethal challenged doses. 215 8

Age-related changes in toxicity and biotransformation of KCN, an ubiquitous environmental toxicant, have not been previously examined. Male C57BL/6N mice aged 2-3 (young), 10-12 (middle-aged), and 25-30 (old) months were administered KCN at 1, 2, 4, and 6 mg/kg po, and toxic manifestations were monitored for up to 2 hr. The toxic response to KCN (prostration and labored breathing) was significantly greater in 10-12 and 25-30 month vs that in 2-3 month mice at 4 and 6 mg/kg KCN. The basis for this age-related difference in in vivo toxicity was examined by studying biotransformation of KCN to thiocyanate by liver and brain rhodanese (RHO), as well as activity of liver and brain cytochrome oxidase (C-OX), inhibition of C-OX by KCN, and activity of beta-mercaptopyruvate transsulfurase (MT). Tissue and blood levels of CN- following a toxic dose of 6 mg/kg KCN were also measured. No age-related differences were observed in the specific activity of liver and brain RHO, MT, or C-OX. In addition, no differences were observed in the percentage inhibition of C-OX by KCN, or in the Ki for inhibition of brain and liver C-OX. However, activity of brain RHO on a per gram tissue basis was significantly lower in 10-12 and 25-30 months vs that in 2-3 month mice. Liver and blood concentrations of CN- were not significantly different in 2-3 vs 10-12 month mice following treatment with 6 mg/kg KCN; however, significantly greater concentrations of CN- were observed at 4 and 25 min in brains of 10-12 month mice compared to that in 2-3 month mice. These results indicate that increased sensitivity to KCN in older mice may be due in part to a decrease in the amount of brain RHO and altered tissue kinetics of CN- following a toxic dose in older mice.
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PMID:Age-related changes in toxicity and biotransformation of potassium cyanide in male C57BL/6N mice. 217 Nov 58

The effects of oral chronic cyanide administration to mice were studied. Cyanide intoxication was confirmed by the increased levels of this poison and the concomitant inhibition of cytochrome oxidase activity in liver, brain, heart and blood. The detoxifying enzyme rhodanese was measured. The state of the sulfane sulfur pool was investigated by determination of the cyanide labile-sulfur levels. A clear correlation between rhodanese activity and sulfur content was obtained as a consequence of cyanide action. These results support the belief that rhodanese plays a fundamental role in the detoxification process of cyanide, in preventing cyanide reaching the target tissues.
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PMID:Cyanide intoxication--I. An oral chronic animal model. 254 8

Anti-cyanide action by sodium thiosulfate (ST) was enhanced by prior administration of chlorpromazine (CPZ). However, CPZ (alone) provided no protection against cyanide lethality. To investigate the possibility that CPZ enhances thiocyanate formation in ST-pretreated mice, the effects of CPZ on rhodanese activity and the time course of plasma thiocyanate concentrations were investigated. CPZ did not alter hepatic rhodanese kinetics nor did it enhance plasma thiocyanate concentrations in ST-pretreated mice. The effect of CPZ and ST on the time course of cytochrome oxidase inhibition and recovery, in vivo, was also investigated. At 4 mg KCN/kg, maximal inhibition of brain (40%) and heart (60%) cytochrome oxidase occurred 10 to 20 min post-challenge in control and CPZ-pretreated mice, while no inhibition occurred in ST- and CPZ/ST-pretreated mice. Twenty milligrams KCN/kg caused 100% lethality in control and CPZ-pretreated mice and 6/25 and 4/20 deaths were observed in ST- and CPZ/ST-pretreated mice, respectively. No significant inhibition of brain, heart, and liver cytochrome oxidase activities was observed in surviving ST- and CPZ/ST-pretreated mice challenged with 20 mg KCN/kg. Control and CPZ-pretreated mice died within 5 min of KCN challenge and had almost the same degree of inhibition of brain (35 and 29%, respectively) and heart (60 and 55%, respectively) cytochrome oxidase as did similarly pretreated mice 5 min after challenge with a nonlethal cyanide dose (4 mg/kg). Our results suggest that CPZ does not enhance the formation of thiocyanate in ST-pretreated mice. In addition, the similar degree of cytochrome oxidase inhibition noted after both lethal and nonlethal KCN treatments raises questions as to the ultimate target in cyanide-induced lethality.
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PMID:Antagonism of cyanide poisoning by chlorpromazine and sodium thiosulfate. 299 48

The mechanism of cyanide intoxication has been attributed to the inhibition of cytochrome oxidase, thereby decreasing the tissue utilization of oxygen. One mechanism of cyanide antagonism is by sequestering cyanide with methaemoglobin to form cyanmethaemoglobin and another mechanism is detoxifying with a sulphur donor to thiocyanate. Questions have been raised with regard to these classical mechanisms. Oxygen with nitrite-thiosulphate antagonizes the lethal effects of cyanide. Theoretically, increased oxygen should serve no useful purpose, as it is the tissue utilization of oxygen which is inhibited. In the nitrite-thiosulphate antidotal combination, the proposal is made that the predominate antidotal action of nitrite is a vasogenic action, rather than methaemoglobin formation, because when methaemoglobin formation is inhibited by methylene blue the protective action of sodium nitrite persists. This suggests that methaemoglobin formation plays only a small part, if any, in the therapeutic antagonism of the lethal effects of cyanide. The roles and implications of sodium thiosulphate and non-rhodanese substrates in the detoxification mechanism are compared. Lastly, a new approach to cyanide antagonism has been initiated which involves the erythrocyte encapsulation of thiosulphate and sulphurtransferase as an antidote and prophylaxis against cyanide.
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PMID:The mechanism of cyanide intoxication and its antagonism. 307 59

Previous reports from our laboratory indicated that prophylactic protection against cyanide intoxication in mice can be enhanced by administration of chlorpromazine when it is given with sodium thiosulfate. The mechanism of potentiation of sodium thiosulfate by chlorpromazine was studied alone and in combination with sodium nitrite. Although chlorpromazine was found to induce a hypothermic response, the mechanism of enhancement of the antagonism of cyanide by chlorpromazine does not correlate with the hypothermia produced. Various other possible mechanisms were investigated, such as rate of methemoglobin formation, enzymatic activity of rhodanese and cytochrome oxidase, and alpha-adrenergic blockade. The alpha-adrenergic blocking properties of chlorpromazine may provide a basis for its antidotal effect, since this protective effect can be reversed with an alpha-agonist, methoxamine.
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PMID:Effect of chlorpromazine on cyanide intoxication. 631 90

Since oxygen was reported to be an effective cyanide antagonist in vivo, particularly in the presence of the classic antidotal combination of sodium nitrite and sodium thiosulfate, in vitro studies were initiated in an attempt to investigate the mechanism of oxygen-mediated cyanide antagonism. The effect of oxygen on cyanide-inhibited cytochrome oxidase with and without cyanide antagonist(s) was investigated in a purified membraneous enzyme system prepared from rat liver mitochondria. Cyanide produced a concentration dependent inhibition of cytochrome oxidase, and 100% oxygen did not alter the inhibition produced by KCN either in the presence or absence of sodium thiosulfate. However, the addition of sodium thiosulfate and rhodanese to the assay reactivated the cyanide-inhibited cytochrome oxidase. Kinetic analysis indicated rhodanese competes with cytochrome oxidase for cyanide, and oxygen had no effect on this coupled reaction. In conclusion, the in vivo antidotal properties of oxygen cannot be attributed to oxygen-mediated reactivation of cyanide-inhibited cytochrome oxidase or an oxygen-mediated acceleration of rhodanese detoxification.
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PMID:Effects of oxygen on the antagonism of cyanide intoxication: cytochrome oxidase, in vitro. 632 98

Oral toxicity of several cyanogens and their reversal by alpha-ketoglutarate (A-KG; oral) were studied in rats. LD(50) of acetonitrile (ATCN), acrylonitrile (ACN), malononitrile (MCN), propionitrile (PCN), sodium nitroprusside (SNP), and succinonitrile (SCN) was 4891, 143.3, 69.8, 122.9, 69.8 and 488.7 mg/kg, respectively while the protection index of A-KG (ratio of LD(50) of cyanogens in the presence or absence of A-KG) was>2.0 against MCN (7.6), PCN (2.7) and SNP (3.6) only. We further studied the efficacy of A-KG against acute toxicity of these three cyanogens (0.75 LD(50)) on various hematological and biochemical variables in blood and soft tissues 24h post-exposure. We observed increase in white blood cells (SNP), plasma alanine (PCN, SNP) and aspartate (PCN) aminotransferase, lactate dehydrogenase (MCN, PCN, SNP), Na(+) (MCN, PCN) and cyanide (PCN), and decrease in K(+) (MCN, SNP) accompanied by an increase in brain, kidney and liver malondialdehyde (PCN), decrease in brain glutathione peroxidase, glutathione reductase (PCN, SNP), reduced glutathione (MCN, PCN, SNP) and cytochrome oxidase (PCN), liver rhodanese (PCN, SNP), and kidney cytochrome oxidase (PCN). The study indicates that (i) PCN was most toxic among all the cyanogens and (ii) beside cyanide, A-KG could be considered as an effective antidote for cyanogens.
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PMID:Acute toxicity of some synthetic cyanogens in rats and their response to oral treatment with alpha-ketoglutarate. 1953 83

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