Purification and characterization of methylamine oxidase induced in Aspergillus niger AKU 3302

Crude extract of Aspergillus niger AKU 3302 mycelia incubated with methylamine showed a single amine oxidase activity band in a developed polyacrylamide gel that weakly cross-reacted with the antibody against a copper/topa quinone-containing amine oxidase (AO-II) from the same strain induced by n-butylamine. Since the organism cannot grow on methylamine and the already known quinoprotein amine oxidases of the organism cannot catalyze oxidation of methylamine, the organism was forced to produce another enzyme that could oxidize methylamine when the mycelia were incubated with methylamine. The enzyme was separated and purified from the already known two quinoprotein amine oxidases formed in the same mycelia. The purified enzyme showed a sharp symmetric sedimentation peak in analytical ultracentrifugation showing S20,w0 of 6.5s. The molecular mass of 133 kDa estimated by gel chromatography and 66.6 kDa found by SDS-PAGE confirmed the dimeric structure of the enzyme. The purified enzyme was pink in color with an absorption maximum at 494 nm. The enzyme readily oxidized methylamine, n-hexylamine, and n-butylamine, but not benzylamine, histamine, or tyramine, favorite substrates for the already known two quinoprotein amine oxidases. Inactivation by carbonyl reagents and copper chelators suggested the presence of a copper/topa quinone cofactor. Spectrophotometric titration by p-nitrophenylhydrazine showed one reactive carbonyl group per subunit and redox-cyclic quinone staining confirmed the presence of a quinone cofactor. pH-dependent shift of the absorption spectrum of the enzyme-p-nitrophenylhydrazone (469 nm at neutral to 577 nm at alkaline pH) supported the identity of the cofactor with topaquinone. Nothern blot analysis indicated that the methylamine oxidase encoding gene is largely different from the already known amine oxidase in the organism.     

Characterization of a model compound for the lysine tyrosylquinone cofactor of lysyl oxidase

We characterized a model compound for the lysine tyrosylquinone (LTQ) cofactor of lysyl oxidase which is one of the mammalian copper-dependent amine oxidases. The model compound, 4-butylamino-5-methyl-o-quinone, was prepared from n-butylamine and 4-methylcatechol by the oxidation with sodium iodate and characterized by spectroscopic analyses. The absorption maximum at 494 nm is consistent with that of lysyl oxidase. The model compound was capable of deaminating benzylamine to benzaldehyde at 37 degrees C in buffered aqueous acetonitrile. The aldehyde production was markedly elevated in the presence of the Cu(II)-EDTA complex but inhibited by free Cu(II). The catalytic cycle was observed at pH 10 in the presence of Cu(II), and the pH activity profile showed a broad optimum at about pH 9.0. In the presence of beta-aminopropionitrile and upon deoxygenation with N2 aldelyde, production was decreased. The important features of the reaction were consistent with the enzymatic reaction.     

Vicinal diamines as pyrroloquinoline quinone-directed irreversible inhibitors of lysyl oxidase

The observation that aliphatic diamines become poor substrates as the carbon chain length decreases and that ethylenediamine, the shortest diamine, is an irreversible inhibitor of lysyl oxidase led to the investigation of the mechanism of inhibition by ethylenediamine. The cis but not the trans isomer of 1,2-diaminocyclohexane was also a potent irreversible inhibitor of lysyl oxidase, consistent with the interaction of both amino groups of vicinal diamines with an enzyme moiety. Both cis-1,2-diaminocyclohexane and ethylenediamine but not trans-1,2-diaminocyclohexane markedly perturbed the spectrum of free pyrroloquinoline quinone (PQQ), a covalently linked form of which is the carbonyl cofactor of lysyl oxidase. cis-1,2-Diaminocyclohexane also induced similar changes in the spectrum of lysyl oxidase. The perturbations of the spectra of PQQ or of lysyl oxidase by cis-1,2-diaminocyclohexane or ethylenediamine as well as the development of irreversible inhibition of the enzyme by cis-1,2-diaminocyclohexane or ethylenediamine were all markedly reduced under anaerobic conditions. Moreover, approximately 1 mol of H2O2 was released per mol of PQQ or lysyl oxidase upon aerobic incubation with cis-1,2-diaminocyclohexane, while approximately 2 mol of 3H+ were released from cis-[1,2-3H] 1,2-diaminocyclohexane per mol of PQQ or lysyl oxidase under corresponding conditions. A proposal for the mechanism of inhibition of lysyl oxidase by vicinal diamines is presented which involves limited oxidation of the diamine linked to PQQ at the active site so that the PQQ-diamine complex is finally stabilized by a conjugated 6-membered ring.     

Lysyl oxidase: evidence that pyridoxal phosphate is a cofactor

Both crude and partially purified preparations of embryonic chick aortic lysyl oxidase tend to gradually lose enzymic activity when illuminated, or when urea is removed by dialysis. Full activity is restored to such preparations by dialysis versus low concentrations of pyridoxal 5′-phosphate prior to assay. Upon treatment with potassium cyanide or semicarbazide, purified embryonic chick aortic lysyl oxidase gives rise to fluorescent derivatives. The fluorescence spectrum of the semicarbazide adduct closely resembles that of pyridoxal phosphate semicarbazone. A preliminary ultraviolet/visible spectrum of bovine aortic lysyl oxidase is also presented; this shows features which add to the existing evidence that lysyl oxidase contains an essential pyridoxal phosphate cofactor.     

Reaction pathway of bovine aortic lysyl oxidase

The catalysis of amine oxidation by lysyl oxidase has been probed to assess for the likely order of substrate binding and product release and to discriminate between mechanistic alternatives previously proposed for other copper-dependent amine oxidases using molecular oxygen as a substrate. Lineweaver-Burk plots revealed a pattern of parallel lines when the oxidation of n-butylamine was followed at different fixed concentrations of oxygen consistent with a "ping-pong" kinetic mechanism in which the aldehyde is produced and released before the binding of oxygen, the second substrate. Initial burst experiments revealed the ability of lysyl oxidase to form and release n-butyraldehyde in amounts stoichiometric with functional active site content in the absence of oxygen, consistent with the ping-pong kinetics obtained. Reciprocal plots of n-butylamine oxidation in the presence of fixed concentrations of the reaction products were consistent with a Uni Uni Uni Bi ping-pong kinetic mechanism with the aldehyde being the first, H2O2 the second, and ammonia the last departing product. Moreover, spectral studies of the oxidation of p-hydroxybenzylamine by lysyl oxidase indicated that the enzyme does not process the amine substrate to a noncovalently bound p-hydroxybenzaldimine intermediate subsequently to be hydrolyzed to p-hydroxybenzaldehyde. The kinetic mechanism of lysyl oxidase thus appears to be similar to those described for diamine oxidase and pig plasma monoamine oxidase.     

Amine Oxidases of Microorganisms

There was an increase in copper content proportional to the increase in specific activity of the enzyme during the purification of amine oxidase of Aspergillus niger. The recrystallized enzyme preparation contained 1 g atom of copper per 83,000 g of protein. This indicated that the enzyme contained 3 g atoms of copper per mole of enzyme. The copper in the enzyme was removed by dialysis against sodium diethyldithiocarbamate with concomitant loss of activity. The dialyzed enzyme was reactivated by the addition of cupric copper.

The copper in the enzyme was present in cupric state. No valency change of the copper was observed in the catalytic activity.

The enzyme was inhibited by various chelating agents, and potently inhibited by various carbonyl reagents.     

The crystal structure of Pichia pastoris lysyl oxidase

Pichia pastoris lysyl oxidase (PPLO) is unique among the structurally characterized copper amine oxidases in being able to oxidize the side chain of lysine residues in polypeptides. Remarkably, the yeast PPLO is nearly as effective in oxidizing a mammalian tropoelastin substrate as is a true mammalian lysyl oxidase isolated from bovine aorta. Thus, PPLO is functionally related to the copper-containing lysyl oxidases despite the lack of any significant sequence similarity with these enzymes. The structure of PPLO has been determined at 1.65 A resolution. PPLO is a homodimer in which each subunit contains a Type II copper atom and a topaquinone cofactor (TPQ) formed by the posttranslational modification of a tyrosine residue. While PPLO has tertiary and quaternary topologies similar to those found in other quinone-containing copper amine oxidases, its active site is substantially more exposed and accessible. The structural elements that are responsible for the accessibility of the active site are identified and discussed.     

formation for phenylethylamine oxidase expressed in Escherichia coli K-12

Abstract Arthrobacter globiformis amine oxidase produced by Escherichia coli cells grown in copper-depleted media was reported to undergo activation due to formation of its topaquinone cofactor in a copper-dependent autocatalytic reaction. Likewise, a mutated E. coli amine oxidase located in the cytoplasm was reported to form topaquinone autocatalytically in an EDTA-sensitive reaction. Here we show unequivocally that formation of an amine oxidase lacking topaquinone is primarily a consequence of the location of the enzyme in the cytoplasm rather than the level of copper in the growth medium. For E. coli , insertion of copper into apoamine oxidase and subsequent topaquinone formation occur after export of the apoenzyme into the periplasm.     

Cryoenzymology and spectrophotometry of pea seedling diamine oxidase

Diamine oxidase follows bi-ter ping-pong kinetics, with an intermediate, "reduced" free-enzyme form being generated after the anaerobic conversion of amine to aldehyde. Visible spectra of diamine oxidase reacting at subzero temperatures provide evidence that this intermediate enzyme form is obtained via several other intermediates and that the environment of the Cu(II) changes dramatically during the course of the reaction [even though it is not reduced to Cu(I) during the catalytic cycle]. The spectrum of this form of diamine oxidase, which is obtained 0.5--2 h after the addition of amine at -5 to -15 degrees C, is independent of substrate, is identical with that obtained by anaerobic addition of substrate at room temperature, and provides evidence for a direct interaction of Cu(II) with the organic cofactor of the enzyme. This interaction is apparently charge transfer in nature. Upon removal of Cu(II) from the native enzyme, one obtains spectral evidence that the organic cofactor is still present. However, removal of the Cu(II) from the reduced (intermediate) enzyme form yields a featureless enzyme spectrum and a Cu(II)--chelate complex which contains a new ligand, which is presumably the second prosthetic group.     

A substrate-cofactor free radical intermediate in the reaction mechanism of copper amine oxidase.

Reduction of copper amine oxidase with substrate led to the appearance of a free radical which can be detected in anaerobiosis by ESR and optical spectroscopy. The origin of this radical was examined through studies of the semiquinones of 6-hydroxydopamine, an analogue of the recently identified cofactor 6-hydroxydopa. The ESR spectrum of the 6-hydroxydopamine radical was too narrow to account for the enzyme radical signal; however, after spontaneous reaction with primary amines the hyperfine splittings and spectral width obtained by modulation broadening became very similar to those observed for the oxidase radical species. This effect was ascribed to covalent binding of a nitrogen atom directly to the aromatic ring structure, suggesting that the amine oxidase radical is an amino-6-hydroxydopa semiquinone. Identical ESR spectra were obtained using the amines putrescine, cadaverine, p-[(dimethylamino)methyl]benzylamine, and ethylenediamine; these oxidase substrates gave identical enzyme radical spectra as well. The interaction between cofactor and substrate was proved unambiguously by the technique of isotopic labeling: addition of [15N2]ethylenediamine instead of the normal 14N-labeled compound changed the ESR spectra of both the enzyme radical and its 6-hydroxydopamine counterpart. The results were confirmed by optical spectroscopy measurements; 6-hydroxydopamine and oxidized 6-hydroxydopamine gave spectra identical to those of reduced and oxidized amine oxidase, respectively. The 6-hydroxydopamine radical showed a sharp peak at 440 nm; upon addition of amines the maximum shifted to 460 nm, as found for the enzyme. It is proposed that copper amine oxidase represents the first example of a mixed substrate-cofactor radical within the family of tyrosine radical enzymes.     

Is the first enzyme of the shikimate pathway, 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase (tyrosine sensitive), a copper metalloenzyme?

3-Deoxy-D-arabino-heptulosonate-7-phosphate synthase (tyrosine sensitive) was purified from Escherichia coli carrying the plasmid pKB45. Enzyme of high specific catalytic activity (70 mu/mg) was obtained from cells grown only to the early log phase. The purified protein contained Cu(II) and showed an absorption band at 350 nm. Metal-free, catalytically inactive apoenzyme could be produced by dialysis against cyanide ion, and the holoenzyme could be reconstituted in terms of both catalytic activity and A350 by the binding of one Cu(II) ion per enzyme subunit. Zn(II) also reactivated the apoenzyme to about 50% of the level seen with Cu(II), although in this case no band appeared at 350 nm. In contrast to earlier reports that the enzyme contains substoichiometric levels of iron, insignificant amounts of iron were found in the isolated enzyme, and neither Fe(II) nor FE(III) regenerated either an absorption band at 350 nm or any catalytic activity from the apoenzyme. The evident preference of the enzyme as isolated for (Cu)II suggests that the synthase might naturally be a copper metalloenzyme.     

Protein lysine 6-oxidase (lysyl oxidase) cofactor: methoxatin (PQQ) or pyridoxal?

1. Treatment of chick embryos with two lathyrogens lowered lysyl oxidase and increased collagen extractability. 2. Subsequent treatment with pyridoxal restored both parameters towards normal, whereas PQQ treatment was less effective. 3. These results suggest the requirement of a pyridoxal derivative for the formation of the enzyme, acting either as cofactor or because its formation requires some pyridoxal-dependent enzyme. The cochromatography of the enzyme with [3H]pyridoxine-derived radioactivity supports the cofactor role. 4. The conclusions of other authors that lysyl oxidase contains PQQ relates to enzymes from other species or to amine oxidases not characterised as lysyl oxidase.     

氨基酰化酶中金属锌离子的功能作用

 氨基酰化酶是含锌金属酶。该酶每摩尔蛋白中含2摩尔Zn(Ⅱ)离子。金属鳌合剂与酶作用,通过竞争螯合Zn(Ⅱ)离子使酶活力下降。残余活力与残留金属含量呈正相关。竞争螯合的结果,生成不含金属的脱辅基酶蛋白,并导致酶活力的丧失。脱辅基酶由于加入Zn(Ⅱ)离子而恢复其活力。实验表明金属锌离子是氨基酰化酶催化活力所必需。与Zn(Ⅱ)离子相似,Co(Ⅱ)离子也可与脱辅基酶相结合并使之复活。 在190—240nm区域内对比了天然酶、脱辅基酶蛋白与Co(Ⅱ)置换氨基酰化酶的圆二色谱。远紫外圆二色谱表明,与天然酶相比,在脱辅基酶中由于金属离子的丧失导致主链构象发生变化,其中α螺旋增加约7％。因而锌离子(钴离子)对蛋白主链的反应最适构象有一定的稳定作用。脱辅基酶与Co(Ⅱ)离子结合,酶的主链构象恢复至与天然酶几近相同。可认为这是促使酶复活的内在因素。     

Evidence for pyrroloquinolinequinone as the carbonyl cofactor in lysyl oxidase by absorption and resonance Raman spectroscopy

The present study investigated the possibility that pyrroloquinolinequinone (PQQ), an aromatic carbonyl recently indicated to be the carbonyl cofactor in bovine plasma amine oxidase, may also be present at the active site of lysyl oxidase. The absorption and resonance Raman spectra of the phenylhydrazones of bovine plasma amine oxidase, of peptides derived from the active site of bovine aorta lysyl oxidase, and of PQQ were very similar, indicating that the carbonyl cofactor of lysyl oxidase is PQQ or a compound which closely resembles PQQ.     

Evidence for the role of vitamin C-6 as a cofactor of lysyl oxidase.

At 24 h after injection of 16-day chick embryos with [C-3H]pyridoxine hydrochloride, some of this label appears in the epiphysial cartilage. Over 35% of this radioactivity appears in the form of [G-3H]pyridoxal and a further 30% as other vitamin B-6 compounds. Partial purification of lysyl oxidase from the labelled epiphysial cartilage reveals a single peak of radioactivity coinciding with a single peak of enzyme activity. On dialysis against phosphate-buffered saline, 75% of this radioactivity is found to be non-diffusible. After incubation with isonicotinic acid hydrazide, a carbonyl reagent that appears to inhibit lysyl oxidase both in vivo and in vitro, a further 70% of the radioactivity is lost, with a roughly corresponding loss of enzyme activity. It is suggested that a form of vitamin B-6 is required as a cofactor of lysyl oxidase, and that this may have important implications in terms of connective-tissue metabolism.     

Investigation of Cu(I)-dependent 2,4,5-trihydroxyphenylalanine quinone biogenesis in Hansenula polymorpha amine oxidase

Copper, a mediator of redox chemistries in biology, is often found in enzymes that bind and reduce dioxygen. Among these, the copper amine oxidases catalyze the oxidative deamination of primary amines utilizing a type(II) copper center and 2,4,5-trihydroxyphenylalanine quinone (TPQ), a covalent cofactor derived from the post-translational modification of an active site tyrosine. Previous studies established the dependence of TPQ biogenesis on Cu(II); however, the dependence of cofactor formation on the biologically relevant Cu(I) ion has remained untested. In this study, we demonstrate that the apoform of the Hansenula polymorpha amine oxidase readily binds Cu(I) under anaerobic conditions and produces the quinone cofactor at a rate of 0.28 h(-1) upon subsequent aeration to yield a mature enzyme with kinetic properties identical to the protein product of the Cu(II)-dependent reaction. Because of the change in magnetic properties associated with the oxidation of copper, electron paramagnetic resonance spectroscopy was employed to investigate the nature of the rate-limiting step of Cu(I)-dependent cofactor biogenesis. Upon aeration of the unprocessed enzyme prebound with Cu(I), an axial Cu(II) electron paramagnetic resonance signal was found to appear at a rate equivalent to that for the cofactor. These data provide strong evidence for a rate-limiting release of superoxide from a Cu(II)(O(2)(.)) complex as a prerequisite for the activation of the precursor tyrosine and its transformation for TPQ. As copper is trafficked to intracellular protein targets in the reduced, Cu(I) state, these studies offer possible clues as to the physiological significance of the acquisition of Cu(I) by nascent H. polymorpha amine oxidase.     

Expression of lysyl oxidase from cDNA constructs in mammalian cells: The propeptide region is not essential to the folding and secretion of the functional enzyme

Rat aortic lysyl oxidase cDNA was expressed under a metallothionein promoter in Chinese hamster ovary cells using a dihydrofolate reductase selection marker. One methotrexate-resistant cell line, LOD-06, generated by transfecting with full-length cDNA, yielded lysyl oxidase proteins consistent with the 50 kDa proenzyme and a 29 kDa mature catalyst. A second cell line, LOD32–2, was generated by transfection with a truncated cDNA lacking sequences which code for the bulk of the propeptide region. Both cell lines secreted apparently identical, 29 kDa forms of mature lysyl oxidase each of which catalyzed the deamination of human recombinant tropoelastin and alkylamines, consistent with the known specificity of lysyl oxidase. The secreted enzyme forms were inhibited by chemical inhibitors of lysyl oxidase activity, including β-aminopropionitrile, phenylhydrazine, ethylenediamine, α,α′-dipyridyl, and diethyl-dithiocarbamate. Sensitivity to these agents is consistent with the presence of copper and carbonyl cofactors in the expressed enzymes, characteristic of lysyl oxidase purified from connective tissues. These results indicate the lack of essentiality of the deleted proprotein sequence for the proper folding, generation of catalytic function, and secretion of lysyl oxidase. © 1995 Wiley-Liss, Inc.     

Inhibition of six copper-containing amine oxidases by the antidepressant drug tranylcypromine

Potential inhibitory effects of the clinically utilized monoamine oxidase inhibitor tranylcypromine (TCP) on mammalian, plant, bacterial, and fungal copper-containing amine oxidases have been examined. The following enzymes have been investigated: human kidney diamine oxidase (HKAO), bovine plasma amine oxidase (BPAO), equine plasma amine oxidase (EPAO), pea seedling amine oxidase (PSAO), Arthrobacter globiformis amine oxidase (AGAO), and Pichia pastoris lysyl oxidase (PPLO). Only BPAO, EPAO, and AGAO were found to lose significant levels of activity when incubated with varying amounts of TCP. Inhibition of BPAO was completely reversible, with dialysis restoring full activity. TCP inhibition of AGAO was also found to be ultimately reversible; however, dialysis did not remove all bound compounds. Chemical displacement with either substrate or a substrate analogue successfully removed all bound TCP, indicating that this compound has a high affinity for the active site of AGAO. The notable lack of TCP inhibition on HKAO argues against the inhibition of diamine oxidase as a potential source for some of the deleterious side effects occurring in patients treated with this antidepressant. The marked differences observed in behavior among these enzymes speaks to the importance of intrinsic structural differences between the active sites of copper amine oxidases (CAO) which affect reactivity with a given inhibitor.     

Partial conversion of Hansenula polymorpha amine oxidase into a "plant" amine oxidase: implications for copper chemistry and mechanism

The mechanism of the first electron transfer from reduced cofactor to O2 in the catalytic cycle of copper amine oxidases (CAOs) remains controversial. Two possibilities have been proposed. In the first mechanism, the reduced aminoquinol form of the TPQ cofactor transfers an electron to the copper, giving radical semiquinone and Cu(I), the latter of which reduces O2 (pathway 1). The second mechanism invokes direct transfer of the first electron from the reduced aminoquinol form of the TPQ cofactor to O2 (pathway 2). The debate over these mechanisms has arisen, in part, due to variable experimental observations with copper amine oxidases from plant versus other eukaryotic sources. One important difference is the position of the aminoquinol/Cu(II) to semiquinone/Cu(I) equilibrium on anaerobic reduction with amine substrate, which varies from almost 0% to 40% semiquinone/Cu(I). In this study we have shown how protein structure controls this equilibrium by making a single-point mutation at a second-sphere ligand to the copper, D630N in Hansenula polymorpha amine oxidase, which greatly increases the concentration of the cofactor semiquinone/Cu(I) following anaerobic reduction by substrate. The catalytic properties of this mutant, including 18O kinetic isotope effects, point to a conservation of pathway 2, despite the elevated production of the cofactor semiqunone/Cu(I). Changes in kcat/Km[O2] are attributed to an impact of D630N on an increased affinity of O2 for its hydrophobic pocket. The data in this study indicate that changes in cofactor semiquinone/Cu(I) levels are not sufficient to alter the mechanism of O2 reduction and illuminate how subtle features are able to control the reduction potential of active site metals in proteins.