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: KEGG:D02011 (FAD)
5,530 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The interconversion of polyamines in the parasite nematode Ascaris suum by a novel type of polyamine oxidase was demonstrated. The nematode enzyme was clearly distinguishable from monoamine and diamine oxidases as well as from the mammalian polyamine oxidase, as shown by the use of the specific inhibitors pargyline, aminoguanidine and MDL 72527 respectively. All three inhibitors had no effect on the parasite polyamine oxidase, and the enzyme did not accept diamines such as putrescine, cadaverine or histamine as substrates. The parasite polyamine oxidase selectively oxidizes spermine and spermidine but not N-acetylated polyamines, whereas the mammalian tissue-type polyamine oxidase shows preference for the N-acetylated polyamines. These results suggest a regulatory function of the nematode polyamine oxidase in the degradation and interconversion of polyamines in parasite nematodes. The enzyme was purified to homogeneity by gel filtration, preparative isoelectric focusing and subsequent affinity chromatography on spermine- and berenil-Sepharose 4B. With respect to reaction type, the prosthetic group FAD, the molecular mass (66 kDa) and the contents of thiol and carbonyl groups, the polyamine oxidase from A. suum is similar to the isofunctional enzyme of mammalian tissue.
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PMID:Purification and characterization of polyamine oxidase from Ascaris suum. 156 80

1. It has previously been established that monoamine oxidase (MAO)-B participates in the metabolism of milacemide [2-(pentylamino)acetamide]. Furthermore, in rats, inhibition of FAD-dependent polyamine oxidase (PAO) was found to decrease the urinary excretion of two milacemide metabolites, termed UK1 and UK2. 2. Using gas chromatography-mass spectrometry, UK1 was identified as oxamic acid and UK2 as 2-hydroxyacetamide, confirming that PAO is involved in the metabolism of milacemide. 3. Thus, two FAD-dependent amine-oxidizing enzymes, MAO and PAO, contribute to the metabolism of milacemide. Milacemide appears to be the first non-polyamine xenobiotic in the metabolism of which PAO participates.
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PMID:Involvement of FAD-dependent polyamine oxidase in the metabolism of milacemide in the rat. 163 8

N1-Acetylspermidine (N1AcSpd) accumulates in late exponential phase, or after certain stresses such as heat shock, in both human tumour (A549) and rodent (HTC, CHO) cells, grown in medium containing an inhibitor of the FAD-dependent polyamine oxidase (PAO). Inhibition of PAO has little effect on cell growth or on the cellular content of the major polyamines, putrescine, spermidine or spermine, found in proliferating cells in culture, but decreases cellular putrescine content in heat shocked cells. Putrescine and spermidine are generated when N1AcSpd or N1-acetylspermine (N1AcSpm) respectively is added to either human or rodent cells depleted of the former amines by alpha-difluoromethylornithine. N1AcSpm is formed in polyamine-depleted human A549 cells when N1AcSpd is added to cultures treated with the PAO inhibitor. This reaction does not occur in either rodent line, suggesting that N1AcSpd can be converted directly into N1AcSpm in human, but not rodent, cells under specific conditions. The data presented demonstrate that a variety of human and rodent cells express PAO activity and catabolize polyamines by a mechanism which includes PAO. PAO activity is of little consequence to proliferating A549, HTC or CHO cells in culture, but does produce new putrescine in both late-exponential-phase and heat-shocked cells. These findings suggest that polyamine catabolism is part of a general response of both rodent and human cells to a variety of environmental and physiological stresses.
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PMID:Polyamine catabolism in rodent and human cells in culture. 174 2

Milacemide, a secondary amine derivative, was previously demonstrated to be a substrate of MAO-B and to be insensitive to the action of copper-dependent amine oxidases. In the present study, it was investigated whether the FAD-dependent secondary amine metabolizing enzyme polyamine oxidase (PAO), could participate in the metabolism of milacemide. For this purpose, the urinary metabolic pattern of oral 14C-milacemide was determined in rats with and without pretreatment with the irreversible PAO inhibitor MDL 72527 and, for comparison, after inhibition of MAO-B by l-deprenyl. While l-deprenyl was shown to significantly decrease the urinary excretion of glycinamide and of an unknown metabolite (UK1), pretreatment with MDL 72527 did not modify the elimination of milacemide as glycinamide but produced a decrease in UK1 equal to that induced by l-deprenyl. The percent of the dose of milacemide eliminated as unchanged drug was slightly but significantly increased after PAO inhibition, though considerably less than after l-deprenyl. These data suggest that milacemide might be a substrate of PAO. If confirmed, this result would constitute the first example of the involvement of the FAD-dependent PAO in drug metabolism.
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PMID:Does FAD-dependent polyamine oxidase contribute to the metabolism of milacemide? 212 9

Currently, two major pathways are distinguished along which the polyamines are metabolized: the interconversion pathway and the so-called terminal polyamine catabolism. In vertebrates, the interconversion pathway is a cyclic process which controls polyamine turnover. In conjunction with polyamine transport, it regulates intracellular polyamine homeostasis. In vertebrates, putrescine, the precursor of spermidine and spermine, is exclusively formed by decarboxylation of ornithine--as far as de novo synthesis is concerned. Spermidine and spermine synthase form spermidine from putrescine, and spermine from spermidine, by transfer of aminopropyl residues from decarboxylated S-adenosylmethionine. In the catabolic branch of the interconversion cycle, spermine is degraded to spermidine, and spermidine to putrescine. The first step in this sequence is acetylation in the N1 position. This is followed by oxidative splitting of the acetylated polyamines, whereby the aminopropyl residues which originated from decarboxylated S-adenosylmethionine are removed. The enzyme catalyzing this step is an FAD-dependent oxidase (polyamine oxidase). Ornithine decarboxylase, S-adenosylmethionine decarboxylase, and acetyl CoA:polyamine N1-acetyltransferase are highly regulated, inducible enzymes with a high turnover rate. Depending on the physiological situation, each of these enzymes may become rate limiting. Terminal polyamine catabolism is catalyzed by Cu2(+)-dependent amine oxidases, of which only diamine oxidase has been well defined. By oxidative deamination of a primary amino group, each intermediate of the interconversion cycle can be transformed into an aldehyde, which is further oxidized to an amino acid or a gamma-lactam. The products of the terminal catabolism as well as the acetylated polyamines are urinary excretory products. In addition to intracellularly synthesized polyamines, polyamines from various tissues and from exogenous sources (such as the gastrointestinal tract) may be utilized by those tissues which have a high demand. Polyamines play a paramount role in growth processes. In order to control growth (for example of tumors), it is necessary to block all major polyamine sources. If only one source is blocked, the remaining sources are usually capable of furnishing sufficient polyamines to support growth processes.
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PMID:Polyamine metabolism. 226 65

In this study we investigated polyamine metabolism during inhibition of two polyamine-catabolizing enzymes. This was performed by treating rats with aminoguanidine [an inhibitor of Cu-dependent amine oxidase (CuAO)], NN'-bis(buta-2,3-dienyl)butane-1,4-diamine [MDL 72527, an inhibitor of FAD-dependent polyamine oxidase (PAO)], tetrachloromethane (hepatotoxic agent) and combinations of these compounds. Emphasis was laid on the origin and possible clinical usefulness of two polyamine metabolites: acetylisoputreanine-gamma-lactam and N1N12-diacetylspermine. Acetylisoputreanine-gamma-lactam is a normal constituent of human and rat urine. Treatment of rats with aminoguanidine led to undetectable urinary levels of acetylisoputreanine-gamma-lactam, whereas MDL 72527 treatment resulted in a 12-fold increase. Under normal conditions this compound represents a minor CuAO catabolite of N1-acetylspermidine, but may become of more importance under CuAO-induced conditions. N1N12-diacetylspermine was undetectable in urine samples from non-pregnant adults and rats, but became detectable after treating rats with MDL 72527. Additional tetrachloromethane poisoning resulted in a 35-fold increase of N1N12-diacetylspermine in urine and its appearance in liver. Hence urinary excretion of N1N12-diacetylspermine during PAO inhibition may serve as a sensitive marker for cell death. This was confirmed by myeloid-leukaemia-bearing rats treated with MDL 72527, which also excreted N1N12-diacetylspermine in urine in relatively high amounts from at least day 14 until spontaneous death.
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PMID:Inhibition of polyamine oxidase in rats improves the sensitivity of urinary polyamines as markers for cell death. 232 69

The metabolism and fate of polyamines during cell proliferation, differentiation, and cell loss were investigated by measuring the concentration of polyamines, their conjugates and some of their metabolites in amniotic fluid of 24 subjects, and in urine of 85 women during pregnancy. The increase of putrescine and spermine in acid-hydrolysed urines during pregnancy appeared to be almost completely due to increases in monoacetylated putrescine and N1,N12 diacetylated spermine, respectively. The latter two were the quantitatively most important polyamines in amniotic fluid. In urine, monoacetylated putrescine showed the highest levels at the end of pregnancy, whereas N1,N12 diacetylated spermine reached the highest values at about 32 weeks gestation. It was impossible to establish whether extracellular monoacetylated putrescine is linked either to cell growth or cell loss. The appearance of N1,N12 diacetylated spermine is probably due to cell loss and dependent on the degree of differentiation during fetal development. The decline and eventual disappearance of urinary N1,N12 diacetylated spermine during the first 2 years after birth may be coherent with maturation of the FAD-dependent polyamine oxidase activity.
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PMID:Gestational-age-dependent concentrations of polyamines, their conjugates and metabolites in urine and amniotic fluid. 341 33

An extracellular polyamine oxidase produced by Penicillium sp. No. PO-1 was completely purified using the chromatofocusing method with a very high yield (93%) of the activity. The enzyme was composed of two identical subunits (Mr 64 000) and contained FAD. The optimal pH for activity was approx. 4.0. The enzyme oxidized spermidine and spermine. Km and Vmax values for spermidine were respectively 8.2 microM and 16.4 mumol H2O2/mg protein per min. Corresponding values for spermine were 5.3 microM and 13.3 mumol H2O2/mg protein per min. The enzyme attacked the secondary amino group of spermidine and spermine, and produced putrescine, 3-aminopropionaldehyde and H2O2. The enzyme activity was completely inhibited by phenylhydrazine. However, sulfhydryl reagents showed no effect on the activity. It is expected that the enzyme will be useful in determining the amount of polyamine in body fluids.
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PMID:Purification and characterization of extracellular polyamine oxidase produced by Penicillium sp. no. PO-1. 711 36

Polyamines and their related monoacetyl derivatives were studied in rod outer segment (ROS) and cone outer segment (COS) of photoreceptor cells from chick embryo retina during eye development (7th-18th days). Putrescine was found to be necessary, in the second phase of retinogenesis, to sustain both ROS and COS differentiation and, after acetylation, gamma-aminobutyric acid synthesis. On the other hand, spermidine and even more spermine intervene in the third phase of development when photoreceptors mature. Moreover, the presence of N1-acetylspermidine already at the 7th day indicates that in the outer segment of photoreceptor cells too, as in the whole retina, putrescine synthesis comes about by two pathways. One pathway involves ornithine decarboxylase; the other, spermidine/spermine N1-acetyltransferase and FAD-dependent polyamine oxidase activities that convert spermidine to putrescine via N1-acetylspermidine. These different biosynthetic pathways are probably also decisive in permitting gamma-aminobutyric acid synthesis, which is very important in the ripening process of neural retina.
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PMID:Polyamines and ripening of photoreceptor outer segments in chicken embryos. 878 66

Spermine is a constituent of all vertebrate cells. Nevertheless, it exerts toxic effects if it accumulates in cells. Spermine is a natural substrate of the FAD-dependent polyamine oxidase, a constitutive enzyme of many cell types. It has been reported that the toxicity of spermine was enhanced if polyamine oxidase was inhibited. We were interested to examine spermine toxicity to human colon carcinoma-derived CaCo-2 cells because, in contrast to most tumor cell lines, CaCo-2 cells undergo differentiation, which is paralleled by changes in polyamine metabolism. CaCo-2 cells were remarkably resistant to spermine accumulation, presumably because spermine is degraded by polyamine oxidase at a rate sufficient to provide spermidine for the maintenance of growth. Inactivation of polyamine oxidase increased the sensitivity to spermine. A major reason for the enhanced spermine cytotoxicity at low polyamine oxidase activity is presumably the profound depletion of spermidine, and the consequent occupation of spermidine binding sites by spermine. Hydrogen peroxide and the aldehydes 3-aminopropanal and 3-acetamidopropanal, the products of polyamine oxidase-catalyzed splitting of spermine and N1-acetylspermine, contribute little to spermine cytotoxicity. Activation of caspase by spermine was insignificant, and the formation of DNA ladders, another indicator of apoptotic cell death, could not be observed. Thus it appears that cell death due to excessive accumulation of spermine in CaCo-2 cells was mainly nonapoptotic. The content of brush border membranes did not change between days 6 and 8 after seeding, and it was not affected by exposure of the cells to spermine. However, the activities of alkaline phosphatase, sucrase, and aminopeptidase in nontreated cells were considerably enhanced during this period, but remained low if cells were exposed to spermine. These changes appear to indicate that differentiation is prevented by intoxication with spermine, although other explanations cannot be excluded.
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PMID:Spermine cytotoxicity to human colon carcinoma-derived cells (CaCo-2). 1091 67


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