Mechanism of inactivation of monoamine oxidase by 1-phenylcyclopropylamine

1-Phenylcyclopropylamine (1-PCPA) is shown to be a mechanism-based inactivator of mitochondrial monoamine oxidase (MAO). The strained cyclopropyl ring is important to inactivation since alpha,alpha-dimethylbenzylamine, the acyclic analogue of 1-PCPA, is neither an inactivator nor a substrate of MAO. Two different pathways occur during inactivation by 1-PCPA, both believed to be derived from a common intermediate. One pathway leads to irreversible inactivation of the enzyme and a 1:1 stoichiometry of radioactivity to the active site when 1-[phenyl-14C]PCPA is used as the inactivator; the other pathway results in a covalent reversible adduct. Three organic reactions are carried out on the irreversibly labeled enzyme in order to determine the structure of the active site adduct. Sodium boro[3H]hydride reduction results in the incorporation of 0.73 equiv of tritium, suggesting a carbonyl functionality. Baeyer-Villiger oxidation followed by saponification gives 0.8 equiv of phenol, indicating the presence of a phenyl ketone. Treatment of the labeled enzyme with hydroxide produces acrylophenone, as would be expected from the retro-Michael reaction of beta-X-propiophenone. The identity of X is determined in two ways. The optical spectrum of the flavin cofactor is reduced during inactivation; no reoxidation occurs upon denaturation. Pronase treatment of the radioactively labeled enzyme produces fragments that contain both the radioactivity and the flavin. The X group, therefore, is the flavin. The results of two tests designed to differentiate N5 from C4a attachment to the flavin suggest an N5 adduct. In addition to formation of this stable covalent adduct, another pathway occurs 7 times as often. This alternate reaction of 1-[phenyl-14C]PCPA with MAO produces 7 equiv of [14C]acrylophenone during the course of irreversible inactivation and is believed to arise from formation of the same type of adduct as described above except that X is something other than the N5-flavin (Y). Upon denaturation of this labeled enzyme, the flavin is completely oxidized when most of the radioactivity is still bound to the enzyme. This indicates that Y is not a C4a-flavin adduct and suggests attachment to an active site amino acid residue. More facile elimination of Y from this beta-substituted propiophenone adduct would give acrylophenone on the time scale of the inactivation. Treatment of the reversible adduct with sodium borohydride prior to denaturation prevents release of radioactivity.(ABSTRACT TRUNCATED AT 400 WORDS)     

Mechanism of inactivation of monoamine oxidase by trans-2-phenylcyclopropylamine and the structure of the enzyme-inactivator adduct

Mitochondrial monoamine oxidase was inactivated with 2-[2-14C]phenylcyclopropylamine, dialyzed, and treated with acidic 2,4-dinitrophenylhydrazine. Contrary to the report of Paech et al. (Paech, C., Salach, J. I., and Singer, T. P. (1980) J. Biol. Chem. 255, 2700-2704), the 2,4-dinitrophenylhydrazone obtained was not that of 2-phenylcyclopropanone, but rather of cinnamaldehyde. Furthermore, denaturation of the labeled enzyme in the presence of sodium borohydride resulted in retention of 5.6 times more radioactivity than in its absence. Based on these results, a mechanism of inactivation of monoamine oxidase by 2-phenylcyclopropylamine and the structure of the enzyme-inactivator adduct are proposed.     

Spectrometric evidence for the flavin-1-phenylcyclopropylamine inactivator adduct with monoamine oxidase N

1-Phenylcyclopropylamine (1-PCPA) is shown to be an inactivator of the fungal flavoenzyme monoamine oxidase (MAO) N. Inactivation results in an increase in absorbance at 410 nm and is accompanied by the concomitant loss of the flavin absorption band at 458 nm. The spectral properties of the covalent adduct formed between the flavin cofactor of MAO N and 1-PCPA are similar to those reported for the irreversible inactivation product formed with 1-PCPA and mammalian mitochondrial monoamine oxidase B [Silverman, R. B., and Zieske, P. A. (1985) Biochemistry 24, 2128-2138]. There is a hypsochromic shift of the 410 nm band upon lowering the pH to 2, indicating that an N(5)-flavin adduct formed upon inactivation. Use of the fungal enzyme, MAO N, which lacks the covalent attachment to the flavin adenine dinucleotide (FAD) cofactor present in the mammalian forms MAO A and MAO B, has allowed for the isolation and further structural identification of the flavin-inactivator adduct. The incorporation of two (13)C labels into the inactivator, [2,3-(13)C(2)]-1-PCPA, followed by analysis using on-line liquid chromatography/electrospray ionization mass spectrometry and nuclear magnetic resonance spectroscopy, provided a means to explore the structure of the flavin-inactivator adduct of MAO N. The spectral evidence supports covalent attachment of the 1-PCPA inactivator to the cofactor as N(5)-3-oxo-3-phenylpropyl-FAD.     

Inactivation of monoamine oxidase B by 1-phenylcyclopropylamine: mass spectral evidence for the flavin adduct.

Incubation of 1-phenylcyclopropylamine with bovine liver MAO (MAO B), followed by complete enzymatic digestion to single amino acid residues and subsequent analysis by on-line liquid chromatography-electrospray ionization mass spectrometry, was used to investigate the resulting flavin adduct structure.     

Inactivation of monoamine oxidase A by the monoamine oxidase B inactivators 1-phenylcyclopropylamine, 1-benzylcyclopropylamine, and N-cyclopropyl-alpha-methylbenzylamine

Three known mechanism-based inactivators of beef liver mitochondrial monoamine oxidase (MAO) B are tested as inactivators of human placental mitochondrial MAO A. 1-Phenylcyclopropylamine (1-PCPA), 1-benzylcyclopropylamine (1-BCPA), and N-cyclopropyl-alpha-methylbenzylamine (N-C alpha MBA) are time-dependent irreversible inactivators of MAO A. The KI values for 1-PCPA and N-C alpha MBA, analogues of the MAO B substrate benzylamine, are much higher with MAO A than with MAO B. Evidence is presented to show that 1-PCPA inactivates MAO A by attachment to the flavin cofactor, unlike the reaction with MAO B in which 1-PCPA can attach to both a cysteine residue and the flavin [Silverman, R.B., & Zieske, P.A. (1985) Biochemistry 24, 2128-2138]. The reaction of 1-BCPA with MAO A was too slow to study in detail. N-C alpha MBA exhibits the same properties toward inactivation of MAO A that it does for inactivation of MAO B. Attachment in both cases is shown to be to one cysteine residue per enzyme molecule. The results with 1-PCPA indicate that the active site topographies of MAO A and MAO B are different. The ability of N-C alpha MBA to undergo attachment to a cysteine residue in both MAO A and MAO B may lead the way toward peptide mapping of the two isozymes in order to determine differences in their primary structures.     

Inhibition and inactivation of monoamine oxidase by 3-amino-1-phenyl-prop-1-enes.

We have previously shown that E-3-amino-1-phenyl-prop-1-ene (E-cinnamylamine) is readily oxidised by monoamine oxidase (MAO) type B from either rat or bovine liver (Williams et al. (1988), Biochem. J. 256, 411-415) in each case producing a non-linear progress curve which was attributed to inhibition by the reaction product E-cinnamaldehyde. We have now found that although this aldehyde inhibits MAO B competitively (Ki 0.017 mM) this cannot account for the inhibitory process, since during a 60 min incubation with the substrate (0.5 mM; Km, 0.074 mM) more than 95% inhibition of MAO B was observed and the concentration of aldehyde had reached approx. 0.025 mM. Inhibition was relieved either by dialysis or dilution of inhibited samples. The activity of MAO A from rat liver was largely unaffected by E-cinnamylamine. Oxidation of N-methyl-E-cinnamylamine and its Z-isomer by MAO B produced progress curves similar to that obtained with the primary amine, but in these cases inhibition was not reversed either by dilution or dialysis. Partition ratios for the pair of N-methyl isomers with bovine MAO B were calculated to be 1640 (E-isomer) and 1430 (Z-isomer). The time-dependent inhibition process for all three amines obeyed pseudo-first-order kinetics. A tritiated form of N-methyl-E-cinnamylamine, incubated with MAO B from bovine liver, resulted in incorporation of radioactivity into the enzyme. This labelling was stable to dialysis and to SDS-PAGE.     

Partial amino acid sequence analysis of human placenta monoamine oxidase A and bovine liver monoamine oxidase B

We have prepared peptide maps from human placenta monoamine oxidase type A (MAO-A) and bovine monoamine oxidase type B (MAO-B) and determined the amino acid sequences of 21 of these peptides. These sequences have been compared to the cDNA deduced amino acid sequences of human MAO-A and -B. A result of special interest is the identification of two sets of MAO-A peptides which have sequences different from those deduced from cDNA sequences. This observation is consistent with the notion that MAO-A may be composed of at two subunits which are similar but not identical in primary amino acid sequence.     

Mechanism-based inactivation of mitochondrial monoamine oxidase by N-(1-methylcyclopropyl)benzylamine

Three different radioactively labeled N-(1-methylcyclopropyl)benzylamines [N-(1-Me)CBA] were synthesized and used to show which atoms of the inactivator remain bound to monoamine oxidase (MAO) after inactivation. Organic chemical reactions were employed to elucidate the structure of the enzyme adduct and clarify the mechanism of inactivation. Following inactivation and dialysis, the benzyl substituent is lost, but the methyl group and cyclopropyl carbons remain attached to the enzyme even after further dialysis against solutions containing 1 mM benzylamine or 8 M urea. Treatment of inactivated enzyme with sodium cyanoborohydride prior to dialysis results in the retention of the benzyl group, suggesting an imine linkage. One hydride from sodium boro[3H]hydride is incorporated into the dialyzed inactivated enzyme consistent with a ketone functional group. When Pronase-digested N-(1-Me)CBA-inactivated MAO is treated with basic potassium triiodide, iodoform is isolated, indicating the presence of a methyl ketone. During inactivation, the optical spectrum of the covalently bound active site flavin changes from that of oxidized to reduced flavin. After urea denaturation, the flavin remains reduced, suggesting covalent linkage of the inactivator to the cofactor. On the basis of previous results [Silverman, R. B., Hoffman, S. J., & Catus, W. B., III (1980) J. Am. Chem. Soc. 102, 7126-7128], it is proposed that the mechanism of inactivation involves transfer of one electron from N-(1-Me)CBA to the flavin, resulting in an amine radical cation and a flavin radical. Then, either the cyclopropyl ring is attacked by the flavin radical or the cyclopropyl ring opens, and the radical generated is captured by the flavin radical. The product of this mechanism is the imine of benzylamine and 4-flavinyl-2-butanone, the proposed enzyme-inactivator adduct.     

Effect of alpha-methylation on inactivation of monoamine oxidase by N-cyclopropylbenzylamine

Monoamine oxidase (MAO) was shown previously [Silverman, R. B., & Hoffman, S. J. (1980) J. Am. Chem. Soc. 102, 7126-7128] to catalyze the oxidation of N-cyclopropylbenzylamine (N-CBA) at two sites on the molecule. Oxidation at the benzyl methylene gave benzaldehyde and cyclopropylamine; oxidation of the cyclopropyl group, which involved cyclopropyl ring cleavage, led to inactivation of the enzyme. In this paper it is shown that methylation of the benzyl methylene dramatically alters this partition ratio in favor of enzyme inactivation. Contrary to a previous report [Alles, G., & Heegaard, E. V. (1943) J. Biol. Chem. 147, 487-503], it is shown here that alpha-methylbenzylamine is a substrate for MAO; consequently, N-cyclopropyl-alpha-methylbenzylamine (N-C alpha MBA) is a good candidate for mechanism-based inactivation. N-Cyclopropyl[7-14C]benzylamine, N-cyclopropyl-alpha-methyl[phenyl-14C]benzylamine, N-[1-3H]-cyclopropylbenzylamine, and N-[1-3H]cyclopropyl-alpha-methylbenzylamine are synthesized, and product formation following MAO inactivation is quantified. The results obtained with these compounds indicate that with N-C alpha MBA, alpha-methylbenzyl oxidation (which produces acetophenone and cyclopropylamine) is only 1% that of cyclopropyl oxidation (which gives enzyme inactivation), whereas with N-CBA the amount of oxidation at the corresponding sites is equal. It also is shown that the Ki values for (R)-(+)- and (S)-(-)-alpha-methylbenzylamine are similar, suggesting that dimethylation of N-CBA should not interfere with binding to MAO.(ABSTRACT TRUNCATED AT 250 WORDS)     

Revised mechanism for inactivation of mitochondrial monoamine oxidase by N-cyclopropylbenzylamine

A mechanism previously proposed for inactivation of monoamine oxidase (MAO) by N-cyclopropylbenzylamine (N-CBA) [Silverman, R. B., & Hoffman, S. J. (1980) J. Am. Chem. Soc. 102, 884-886] is revised. Inactivation of MAO by N-[1-3H]CBA results in incorporation of about 3 equiv of tritium into the enzyme and release of [3H]acrolein. Treatment of inactivated enzyme with benzylamine, a reactivator for N-CBA-inactivated MAO, releases only 1 equiv of tritium as [3H]acrolein concomitant with reactivation of the enzyme. Even after MAO is inactivated by N-[1-3H]CBA, the reaction continues. At pH 7.2, a linear release of [3H]acrolein is observed for 70 h, which produces 55 equiv of [3H]acrolein while 2.3 equiv of tritium is incorporated into the enzyme. At pH 9, only 3.5 equiv of [3H]acrolein is detected in solution after 96 h, but 40 equiv of tritium is incorporated into the enzyme, presumably as a result of greater ionization of protein nucleophiles at the higher pH. N-[1-3H]Cyclopropyl-alpha-methylbenzylamine (N-C alpha MBA) produces the same adduct as N-CBA but gives only 1-1.35 equiv of tritium bound after inactivation of the enzyme. Denaturation of labeled enzyme results in reoxidation of the flavin without release of tritium, indicating attachment is not to the flavin but rather to an amino acid residue. Enzyme inactivated with N-[1-3H]C alpha MBA is reactivated by benzylamine with the release of 1 equiv of [3H]acrolein, which must have come from an adduct attached to an active site amino acid residue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Reactivity of the imino acids formed in the amino acid oxidase reaction.

The reactivity of the imino acids formed in the D- or L-amino acid oxidase reaction was studied. It was found that: (1) When imino acids reacted with the alpha-amino group of glycine or other amino acids, transimination yielded derivatives less stable to hydrolysis than the parent imino acids. In contrast, when imino acids reacted with the epsilon-amino group of lysine or other primary amines, transimination yielded derivatives more stable to hydrolysis than the parent imino acids. (2) Imino acids react rapidly with hydrazine and semicarbazide, forming stable hydrazones and semicarbazones. At pH 7.7, the rate of reaction of the imino acid analogue of leucine with semicarbazide was 10(4) times greater than that of the corresponding keto acid. The reaction of imino acids with these reagents is rapid enough to permit one to follow spectrophotometrically the amino acid oxidase reaction. Imino acids also reacted with cyanide to yield stable adducts. (3) The rate of hydrolysis of the imino acid analogue of leucine was independent of pH above pH 8.5. At lower pH values, the rate of hydrolysis increased with decreasing pH. At 25 degrees C and in the absence of added amino compounds, this imino acid had a half-life of 22 s at pH 8.5. Its half-life was 9.9 s at pH 7.9.     

Identification of novel monoamine oxidase B inhibitors by structure-based virtual screening

Parkinson’s disease is a severe debilitating neurodegenerative disorder. Recently, it was shown that the peroxisome proliferating-activator receptor-γ agonist pioglitazone protected mice from 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine neurotoxicity due to its ability to inhibit monoamine oxidase B (MAO-B). Docking studies were initiated to investigate pioglitazone’s interactions within the substrate cavity of MAO-B. Modeling studies indicated that the thiazolidinedione (TZD) moiety was a likely candidate for its specificity to MAO-B. To explore this potential novel MAO-B scaffold, we performed a structure-based virtual screen to identify additional MAO-B inhibitors. Our search identified eight novel compounds containing the TZD-moiety that allowed for a limited study to identify structural requirements for binding to MAO-B. Inhibition assays identified two TZDs (A6355 and L136662) which were found to inhibit recombinant human MAO-B with IC₅₀ values of 82 and 195 nM, respectively.     

Substrate and inhibitor specificities for human monoamine oxidase A and B are influenced by a single amino acid

Monoamine oxidase (MAO) is responsible for the oxidation of biogenic and dietary amines. It exists as two isoforms, A and B, which have a 70% amino acid identity and different substrate and inhibitor specificities. This study reports the identification of residues responsible for conferring this specificity in human MAO A and B. Using site-directed mutagenesis we reciprocally interchanged three pairs of corresponding nonconserved amino acids within the central portion of human MAO. Mutant MAO A-I335Y became like MAO B, which exhibits a higher preference for beta-phenylethylamine than for the MAO A preferred substrate serotonin (5-hydroxytryptamine), and became more sensitive to deprenyl (MAO B-specific inhibitor) than to clorgyline (MAO A-specific inhibitor). The reciprocal mutant MAO B-Y326I exhibited an increased preference for 5-hydroxytryptamine, a decreased preference for beta-phenylethylamine, and, similar to MAO A, was more sensitive to clorgyline than to deprenyl. These mutants also showed a distinct shift in sensitivity for the MAO A- and B-selective inhibitors Ro 41-1049 and Ro 16-6491. Mutant pair MAO A-T245I and MAO B-I236T and mutant pair MAO A-D328G and MAO B-G319D reduced catalytic activity but did not alter specificity. Our results indicate that Ile-335 in MAO A and Tyr-326 in MAO B play a critical role in determining substrate and inhibitor specificities in human MAO A and B.