Effect of Inhibitors on Phenoloxidase of Mycobacterium leprae

Previous results had shown that the human leprosy bacilli possess a phenoloxidase, which, when compared with the enzyme from mammalian and plant sources, seemed unique in the range of substrates utilized and in the nature of the products formed. The effect of several inhibitors on the enzyme in Mycobacterium leprae was tested. Compounds which bind copper were found to be more effective than substrate analogues. Diethyldithiocarbamate penetrated the bacillus and completely suppressed its phenolase activity. Diasone (a derivative of diaminodiphenylsulfone used in the treatment of leprosy) proved to be a potent inhibitor of phenoloxidase of mammalian and plant origin. However, it was less efficient in the case of M. leprae. A biochemical peculiarity of M. leprae was observed in its ability to metabolize mimosine and penicillamine. These compounds produced total inhibition of tyrosinase in melanoma extract and of mushroom tyrosinase. Nontoxic inhibitors of phenoloxidase in the leprosy bacilli may be of value in developing a rational approach to chemotherapy of the disease.     

Unusual Effects of Reducing Agents on o-Diphenoloxidase of Mycobacterium leprae

Reducing agents had no effect on the oxidation of 3,4-dihydroxyphenylalanine (DOPA) to quinone by Mycobacterium leprae; no quinone formation by o-diphenoloxidase of mammalian or plant origin was detected under similar experimental conditions. Ascorbic acid and reduced glutathione prevented further oxidation and polymerization of the quinone to melanin by M. leprae; cysteine was less effective. In the presence of reducing agents, the quinone (indole-5,6-quinone) formed from DOPA by M. leprae was not reduced back to diphenol. On the other hand, the quinone (dopachrome) produced from DOPA by mammalian or plant phenolase was rapidly decolorized by reducing agents. Oxidized glutathione and cystine had little effect on o-diphenoloxidase from all of the three sources. Cyanide, which completely inhibited mammalian and plant phenolases, had only a partial effect on the enzyme in the bacilli. Various lines of evidence suggest that the properties of o-diphenoloxidase in M. leprae are different from those of similar enzymes obtained from other sources.     

Temperature-induced changes in viability, diphenoloxidase and permeability of Mycobacterium leprae

Among mycobacteria secretion of the enzyme diphenoloxidase has been established as a property of Mycobacterium leprae. The antileprosy drug dapsone (DDS), which completely inhibits the enzyme from plant and mammalian sources, does not readily penetrate intact M. leprae. When the drug is complexed with polylysine, it easily permeates the bacteria and produces 100% inhibition of its diphenoloxidase, suggesting a permeability barrier of the cytoplasmic membrane of M. leprae to dapsone. In this study: (1) when the organisms, purified from fresh tissues of experimentally infected armadillos, were treated with dilute alkali or exposed to warmer temperatures, DDS penetrated the bacteria and inhibited the diphenoloxidase. Washing with trypsin had no effect. Dapsone easily permeated the bacilli, purified from tissues stored at 0 degrees C or at -80 degrees C. (2) Diphenoloxidase of freshly-prepared M. leprae was stimulated when the bacteria were exposed to 50 degrees C for 10 min; at 60 degrees C the activity decreased, and at 100 degrees C the enzyme was completely inactivated. When the enzyme was assayed at temperatures below 37 degrees C, the activity was considerably lower, indicating that M. leprae may not be a psychrophilic organism in this respect. (3) The bacteria exposed to 50 degrees C failed to multiply in mouse footpads. M. leprae remained viable in tissues stored at 0 degrees C or -80 degrees C; but when the bacteria purified from these tissues were frozen, they lost their viability. On the other hand, the organisms separated from fresh tissues remained viable when frozen at -80 degrees C. The inhibition of diphenoloxidase of M. leprae by dapsone could serve as an indirect method to assess the integrity of the bacterial cell membrane and to predict whether the bacteria would retain their viability on freezing.     

Antifouling Bastadin Congeners Target Mussel Phenoloxidase and Complex Copper(II) Ions

Synthetically prepared congeners of sponge-derived bastadin derivatives such as 5,5′-dibromohemibastadin-1 (DBHB) that suppress the settling of barnacle larvae were identified in this study as strong inhibitors of blue mussel phenoloxidase that is involved in the firm attachment of mussels to a given substrate. The IC₅₀ value of DBHB as the most active enzyme inhibitor encountered in this study amounts to 0.84 μM. Inhibition of phenoloxidase by DBHB is likely due to complexation of copper(II) ions from the catalytic centre of the enzyme by the α-oxo-oxime moiety of the compound as shown here for the first time by structure activity studies and by X-ray structure determination of a copper(II) complex of DBHB.     

Studies on prephenoloxidase-activating enzyme from cuticle of the silkworm Bombyx mori. I. Activation reaction by the enzyme

Prephenoloxidase-activating enzyme from larval cuticle of the silkworm catalyzes the activation reaction of hemolymphal prephenoloxidase to the active enzyme. The activation reaction of prephenoloxidase by the enzyme has been analyzed with respect to effect of salts, dependency on pH and substrate concentration, and susceptibility to inhibitors. It has been demonstrated that the reaction is highly sensitive to specific inhibitors for “serine enzyme.”Difference in substrate specificity of phenoloxidase preparations, produced by two enzyme fractions which can be separated by chromatography on DEAE-cellulose, is also described.     

Kinetic properties of catecholoxidase activity of tarantula hemocyanin

Phenoloxidases occur in almost all organisms, being essentially involved in various processes such as the immune response, wound healing, pigmentation and sclerotization in arthropods. Many hemocyanins are also capable of phenoloxidase activity after activation. Notably, in chelicerates, a phenoloxidase has not been identified in the hemolymph, and thus hemocyanin is assumed to be the physiological phenoloxidase in these animals. Although phenoloxidase activity has been shown for hemocyanin from several chelicerate species, a characterization of the enzymatic properties is still lacking. In this article, the enzymatic properties of activated hemocyanin from the tarantula Eurypelma californicum are reported, which was activated by SDS at concentrations above the critical micellar concentration. The activated state of Eurypelma hemocyanin is stable for several hours. Dopamine is a preferred substrate of activated hemocyanin. For dopamine, a K(M) value of 1.45 +/- 0.16 mm and strong substrate inhibition at high substrate concentrations were observed. Typical inhibitors of catecholoxidase, such as l-mimosine, kojic acid, tyramine, phenylthiourea and azide, also inhibit the phenoloxidase activity of activated hemocyanin. This indicates that the activated hemocyanin behaves as a normal phenoloxidase.     

Inhibition of mammalian xanthine oxidase by folate compounds and amethopterin

We have examined the effects of folate compounds and the folate analog amethopterin (methotrexate) as inhibitors of mammalian xanthine oxidase and have found that they offer potent inhibition of the enzyme. We have compared the inhibitory potency of folic acid and its coenzyme derivative tetrahydrofolic acid to that of allopurinol, a known inhibitor of xanthine oxidase, and have demonstrated that folic acid and tetrahydrofolic acid are severalfold more potent than allopurinol as inhibitors of xanthine oxidase. Comparative inhibition constants calculated were 5.0 X 10(-7) M for folic acid. 1.25 X 10(-6) M for tetrahydrofolic acid, and 4.88 X 10(-6) M for allopurinol. Incubation of xanthine oxidase with folic acid at a concentration of 10(-6) M abolished 94% of the enzymic activity within 1 min of incubation with the enzyme. At the same concentration, allopurinol was almost ineffective as an inhibitor of xanthine oxidase. The substrate xanthine protected the enzyme against total inhibition by folic acid. Reversibility of the enzymic inhibition by folic acid was demonstrated. Folic acid-inactivated enzyme was totally regenerated either by filtration through Sephadex G-200 or by precipitation with ammonium sulfate. 2-Amino-4-hydroxypteridine was a poor substrate for the enzyme but a potent inhibitor for the oxidation of xanthine by the enzyme. The inhibition constant calculated was 1.50 X 10(-6) M. In the presence of an excess of xanthine oxidase, neither folic acid nor tetrahydrofolic acid and allopurinol exhibited any change in intensity of their absorbance or in the wavelength of their maximal absorbance that might have been suggestive of substrate utility. The folate analog amethopterin was also determined a potent inhibitor of mammalian xanthine oxidase. The inhibition constant calculated was 3.0 X 10(-5) M.     

Biochemical studies of phenoloxidase and utilization of catecholamines in Cryptococcus neoformans

Protoplasts of Cryptococcus neoformans contain phenoloxidase as a membrane-bound enzyme. The enzyme appeared to be attached on the inner side of cytoplasmic membranes. Synthesis of the enzyme was derepressed by low levels of glucose but was not affected by the level of ammonium. Copper chelators which inhibited the phenoloxidase of other organisms did not affect cryptococcal enzymes. However, cyanide- or iron-chelating agents such as hydroximide derivates or 8-hydroxyquinoline were effective inhibitors, suggesting that cryptococcal phenoloxidase is an iron-containing enzyme. Phenoloxidase of C. neoformans catalyzed the oxidation of various diphenols via dopachrome and labile intermediates to melanin polymers. The kinetic constants (Km) of the phenoloxidase and the permease for dopamine and norepinephrine were low. The correlation between phenoloxidase and the preferential growth of C. neoformans in the host brain is discussed.     

The biosynthesis of cyanogenic glucosides in higher plants. N-Hydroxytyrosine as an intermediate in the biosynthesis of dhurrin by Sorghum bicolor (Linn) Moench.

The following compounds were tested as early intermediates in the conversion of tyrosine to p-hydroxymandelonitrile by a microsomal preparation from dark grown sorghum seedlings: p-hydroxyphenylacetamide, 1-nitro-2-p-hydroxyphenylethane, p-hydroxyphenyl-pyruvic acid oxime, tyramine, N-hydroxytyramine, and N-hydroxytyrosine. Of these, only N-hydroxytyrosine was metabolized to p-hydroxymandelonitrile. N-Hydroxytyrosine was produced from L-[U-14C]tyrosine in tracer experiments when unlabeled N-hydroxytyrosine was added as a trap. These data indicate N-hydroxytyrosine as the first intermediate in the biosynthesis of dhurrin, the cyanogenic glucoside of sorghum, and represent the first demonstration of the formation of an alpha-N-hydroxy-amino acid in a biological system. The enzyme system involved in this reaction was partially characterized with respect to substrate specificity and the effect of various inhibitors. The enzyme was shown to have properties different than those reported for the mammalian enzyme system(s) involved in the N-hydroxylation of amine drugs. The possible involvement of N-hydroxyamino acids in the biosynthesis of other secondary plant products is discussed.     

Reactivity of liver monoamine oxidase in the seal Phoca hispida ladogensis

The goal of this work consisted in substrate and inhibitor specificity of liver monoamine oxidase (MAO) of the freshwater Ladoga subspecies of the ringed seal Phoca hispida ladogensis. The studied enzyme has been found to have the large substrate specificity by deaminating, apart from eight classic substrates of the terrestrial mammalian MAO, also histamine, the substrate of diamino oxidase. It has been revealed that the studied enzyme realizes wide substrate specificity by deaminating, apart from eight classic MAO substrates of terrestrial mammals, also histamine, the substrate of diamino oxidase. The deamination rates of benzylamine, β-phenylethylamine, and N-methylhistamine are found to be almost by one order higher than the deamination rates of serotonin and noradrenaline. The seal liver MAO did not deaminate putrescine and cadaverine and was insensitive to 10^?2 M semicarbaside. There were calculated bimolecular rate constants of interaction of inhibitors: chlorgyline, deprenyl, berberine, sanguinarine, chelidonine, and four derivatives of acridine with the enzyme at deamination of nine substrates. By the method of substrate-inhibitor analysis we have shown heterogeneity of the enzyme, i.e., the presence in the seal liver of at least of two different MAO.     

Reactivation by copper of phenolase pre-inactivated by oxalate

The activity of spinach chloroplast phenolase which had been repressed by ammonium oxalate was restored by adding copper. Oxalate appears to bind to the enzyme at a single site, the binding paralleling the inhibition produced at neutral pH. The inhibition of oxalate is due to its binding with copper at the active centre to form an inactive complex, the oxalate moiety of which is releasable when more copper is added. Similar reactivation by copper was obtained with pure mushroom phenolase.     

Uptake of radioactive DOPA by Mycobacterium leprae in vitro.

Our previous studies demonstrated that Mycobacterium leprae contains a characteristic o-diphenoloxidase which converts a variety of phenolic compounds to quinones in vitro. This enzyme was not present in any other mycobacteria tested. The results reported here deal with the uptake and binding of radioactive DOPA by M. leprae. The leprosy bacilli incubated with tritium-labelled DOPA, readily took up the substrate. The binding of DOPA by the bacilli was markedly inhibited by diethyldithiocarbamate. The organisms also bound tritiated norepinephrine. Mycobacterium phlei which does not oxidize phenolic substrates failed to bind DOPA. Cultures of melanocytes which contain o-diphenoloxidase took up tritiated DOPA. Catecholamine metabolism is known to be important in myocardial cells. Cultures of turtle-heart cells did not oxidize DOPA to quinone; however, these cells bound the labelled substrate. A cell line of fibroblasts derived from armadillo skin neither oxidized nor took up DOPA. The results indicate that, like melanocytes and turtle-heart cells, M. leprae probably possesses specific receptor sites for the binding and subsequent metabolism of phenolic substrates.     

Adenosine deaminase from Saccharomyces cerevisiae: kinetics and interaction with transition and ground state inhibitors.

Several adenosine analogs, such as coformycin, 2'-deoxycoformycin and erythro-9-(3-nonyl-p-aminobenzyl)adenine (EHNA), which are strong inhibitors of mammalian adenosine deaminase, are much weaker inhibitors of the Saccharomyces cerevisiae enzyme. The specificity of the yeast enzyme is more restricted than that of mammalian adenosine deaminase, particularly towards the ribose moiety and around position 6 and 1 of the substrate. The sulphydryl group appears to be more masked in the yeast than in the mammalian enzyme. The kinetic effects of pH with adenosine substrate and with the inhibitor purine riboside are reported. The findings on specificity and pH kinetic effects can be interpreted in a model involving proton transfer from the -SH group of the enzyme to the N-1 atom of the substrate.     

Inhibition by oxalates of spinach chloroplast phenolase in unfrozen and frozen states

Spinach chloroplast phenolase was inhibited by oxalic acid and its salts. Complete inhibitions were induced instantly in the acidic region (e.g. by 1 and 5 mM oxalate at pH 5 and 5.5, respectively), and in the neutral region pre-incubation of the enzyme with oxalates could also lead to complete loss of activity. The inhibition mode was non-competitive for phenol substrate with K_i of 0.9 mM pH 6.8. Reduction of enzyme activity in a crude extract of chloroplasts induced by freezing at neutral pH was due to the presence of ammonium oxalate. With 0.5 mM oxalate, the inhibition attained 75% under frozen conditions, whilst no inhibition could be detected in the enzyme which had not been frozen. Free oxalic acid and K⁺ and Na⁺ salts also caused freezing inhibition. Glyoxylic and oxamic acids acted as inhibitors with less efficiency. With a pure mushroom tyrosinase (phenolase), essentially the identical results were obtained using the same conditions.     

Mode of action of the Spiroplasma CpG methylase M.SssI.

The cytosine DNA methylase from the wall-less prokaryote, Spiroplasma strain MQ1 (M.SssI) methylates completely and exclusively CpG-containing sequences, thus showing sequence specificity which is similar to that of mammalian DNA methylases. M.SssI is shown here to methylate duplex DNA processively as judged by kinetic analysis of methylated intermediates. The cytosine DNA methylases, M.HpaII and M.HhaI, from other prokaryotic organisms, appear to methylate in a non-processive manner or with a very low degree of processivity. The Spiroplasma enzyme interacts with duplex DNA irrespective to the presence of CpG sequences in the substrate DNA. The enzyme proceeds along a CpG-containing DNA substrate molecule methylating one strand of DNA at a time.     

Characterization of thimet- and neurolysin-like activities in Escherichia coli M 3 A peptidases and description of a specific substrate

M 3 A oligopeptidases from Escherichia coli, with hydrolytic properties similar to Zn-dependent mammalian thimet oligopeptidase (EP 24.15) and neurolysin (EP 24.16), were studied aiming at identification of comparative enzyme and substrate specificity, hydrolytic products, and susceptibility to inhibitors. Fluorescent peptides, neurotensin (NT) and bradykinin (BK), were used as substrates for bacterial lysates. Bacterial enzymes were totally inhibited by o-phenanthrolin, JA-2 and partially by Pro-Ile, but not by leupeptin, PMSF, E-64, and Z-Pro-Prolinal, using internally quenched Abz-GFSPFRQ-EDDnp as substrate. The molecular mass of the bacterial oligopeptidase activity (77--78 kDa) was determined by gel filtration, and the effect of inhibitors, including captopril, suggested that it results from a combination of oligopeptidase A (OpdA) and peptidyl dipeptidase Dcp (77.1 and 77.5 kDa, respectively). Recombinant OpdA cloned from the same E. coli strain entirely reproduced the primary cleavage of fluorescent peptides, NT and BK, by the bacterial lysate. Genes encoding these M 3 A enzymes were those recognized in E. coli genome, bearing identity at the amino acid level (25--31%) with mammalian Zn-dependent oligopeptidases. We also describe a substrate, Abz-GFSPFRQ-EDDnp, that differentiates bacterial and mammalian oligopeptidases.     

Purification and properties of a neutral thiol protease from larval trematode parasite Paragonimus westermani metacercariae

1. A neutral thiol protease was isolated from the extract of larvae of the mammalian trematode parasite, Paragonimus westermani metacercariae, by arginine-Sepharose, Ultrogel AcA-54 and DEAE-toyopearl column chromatography, measuring its activity by the hydrolysis of Boc-Val-Leu-Lys-MCA as a substrate. 2. The molecular weight of the purified enzyme was estimated to be 22,000 as a single polypeptide by SDS-polyacrylamide gel electrophoresis and was estimated to be 20,000 by size exclusion high-performance liquid chromatography. 3. The activity was suppressed by antipain, E-64, leupeptin, chymostatin, N-tosyl-L-lysine chloromethyl ketone, but was not affected by metallo protease inhibitors or serine protease inhibitors. 4. Studies on the substrate specificity showed that the enzyme hydrolyzed Boc-Val-Leu-Lys-MCA, Z-Phe-Arg-MCA, fluorescein isothiocyanate-labeled collagen, azocoll and casein. 5. The enzyme was found to hydrolyze peptide bonds of oxidized insulin B chain preferentially at the carboxy side of hydrophobic and basic amino acids.     

Inhibition of DNA polymerases and DNA topoisomerase II by triterpenes produced by plant callus

We found that some triterpene compounds could not only selectively inhibit the activities of mammalian DNA polymerase alpha (pol alpha) and beta (pol beta), but could also potently inhibit DNA topoisomerase II (topo II) [Biochem. J. 350 (2000) 757]. Here, we report that natural triterpenes produced by callus from an ancient Chinese medicinal plant were also inhibitors of the enzymes, and some were more selective than others. The natural triterpenes with a carboxyl group equally inhibited the activities of pol alpha, pol beta, and topo II, while the olide-type triterpenes with a ketone group suppressed the activities of pol beta and topo II, but not pol alpha. The other triterpenes from the callus hardly influenced these enzyme activities. As also described previously [J. Biochem. 130 (2001) 657], pol beta and topo II have a three-dimensionally similar triterpene-binding region, which is a pocket in which specific compounds can insert. The newly found triterpene inhibitors might structure-dependently insert into the pocket, and the pocket structure of each enzyme might, three-dimensionally but slightly, differ among them. The triterpene frames could be used for screening new inhibitors of the enzymes, and computer-simulated drug design using the frame and pocket structure may in theory be a possible approach to develop new inhibitors.     

Binding specificity and reactivity studies on a broad-specificity beta-glycosidase from porcine kidney

A broad-specificity beta-glycosidase from porcine kidney was purified to homogeneity. Sodium dodecyl sulfate - polyacrylamide gel electrophoresis showed that it had a monomeric molecular weight of 55,000-60,000. Gel filtration showed native molecular weight of about 115,000. These data imply that the native enzyme is a dimer. The enzyme can catalyze the hydrolysis of beta bonds between glycosides and 4-methylumbelliferone or nitrophenol yielding D-fucopyranose, D-galactopyranose, D-glucopyranose, D-xylopyranose, and D-mannopyranose and of alpha bonds to yield L-arabinopyranose. This is the first study that shows a mammalian broad-specificity cytosolic beta-glycosidase carrying out a reaction with a beta-D-mannopyranoside. The nature of the broad specificity was studied with inhibitors. Similar inhibitor constants were found regardless of whether the substrate was a beta-D-glucopyranoside or a beta-D-galactopyranoside, so the enzyme probably has only one binding site with a broad specificity. The enzyme prefers to bind compounds with an axial hydroxyl at the 2 position and an equatorial hydroxyl at the 4 position; the 3 position does not affect binding significantly. The hydroxyl at the 6 position affects binding, but binding at that position depends on the configurations at the 2 and 4 positions. Thus, there must be some interactions between these three positions (2, 4, and 6). Lactones are also good inhibitors and this may relate to strain effects.     

Effects of divalent metals on the specificity of inhibitors of the cyclic nucleotide phosphodiesterases from bovine heart

Divalent metals used to support phosphodiesterase (EC 3.1.4.-) activity have been found to influence the substrate and enzyme specificity of many phosphodiesterase inhibitors in studies of the hydrolysis of cyclic AMP and cyclic GMP by the calmodulin-dependent and cyclic AMP-specific phosphodiesterases from bovine heart. Many compounds displayed marked differences in substrate specificity and inhibitory potency in the presence of Mg2+, as compared with Mn2+, when studied with the unactivated form of calmodulin-dependent phosphodiesterase, while few compounds displayed differences in the presence of calmodulin. With a single divalent metal, marked differences in inhibitory potency and substrate specificity were also observed in the absence or presence of calmodulin suggesting that alterations in calmodulin and/or Ca2+ levels may greatly affect the response to phosphodiesterase inhibitors. Divalent metals did not alter the effects of inhibitors on the hydrolysis of cyclic AMP by the cyclic AMP-specific phosphodiesterase, however divalent metals would probably indirectly influence the relative cellular level of cyclic AMP hydrolyzed by this enzyme, and therefore the effects of inhibitors, through metal effects on the calmodulin-dependent phosphodiesterase. No correlation was found between the inhibitory activity of the compounds, many of which were cyclic nucleotide analogs, and their ability to activate cyclic AMP-dependent or cyclic GMP-dependent protein kinases or to affect cyclic AMP-dependent protein kinase activity by displacing bound cyclic AMP.