Thiols liberate covalently bonded flavin from monoamine oxidase

The Influence of Cationic Nitrosyl Iron Complex with Penicillamine Ligands on Model Membranes, Membrane-Bound Enzymes and Lipid Peroxidation

This paper shows the biological effects of cationic binuclear tetranitrosyl iron complex with penicillamine ligands (TNIC-PA). Interaction with a model membrane was assessed using a fluorescent probes technique. Antioxidant activity was studied using a thiobarbituric acid reactive species assay (TBARS) and a chemiluminescence assay. The catalytic activity of monoamine oxidase (MAO) was determined by measuring liberation of ammonia. Antiglycation activity was determined fluometrically by thermal glycation of albumine by D-glucose. The higher values of Stern-Volmer constants (K_SV) obtained for the pyrene located in hydrophobic regions (3.9 × 10⁴ M^-1) compared to K_SV obtained for eosin Y located in the polar headgroup region (0.9 × 10⁴ M^-1) confirms that TNIC-PA molecules prefer to be located in the hydrophobic acyl chain region, close to the glycerol group of lipid molecules. TNIC-PA effectively inhibited the process of spontaneous lipid peroxidation, due to additive contributions from releasing NO and penicillamine ligand (IC50 = 21.4 µM) and quenched luminol chemiluminescence (IC50 = 3.6 μM). High activity of TNIC-PA in both tests allows us to assume a significant role of its radical-scavenging activity in the realization of antioxidant activity. It was shown that TNIC-PA (50-1000 μM) selectively inhibits the membrane-bound enzyme MAO-A, a major source of ROS in the heart. In addition, TNIC-PA is an effective inhibitor of non-enzymatic protein glycation. Thus, the evaluated biological effects of TNIC-PA open up the possibility of its practical application in chemotherapy for socially significant diseases, especially cardiovascular diseases.

Flavinylation of monoamine oxidase B

Monoamine oxidase B (MAO B) catalyzes the oxidative deamination of biogenic and xenobiotic amines. The oxidative step is coupled to the reduction of an obligatory cofactor, FAD, which is covalently linked to the enzyme at Cys397. In this study, we developed a novel riboflavin-depleted (Rib-) COS-7 cell line to study the flavinylation of MAO B. ApoMAO B can be obtained by expressing MAO B cDNA in these cells. We found that MAO B is expressed equally in the presence or absence of FAD and that apoMAO B can be inserted into the outer mitochondrial membrane. Flavinylation of MAO B was achieved by introducing MAO B cDNA and different flavin derivatives simultaneously into Rib- COS-7 cells via electroporation. Since the addition of riboflavin, FMN, or FAD resulted in equal levels of MAO B activity, we conclude that the flavin which initially binds to apoMAO B is FAD. In our previous work, we used site-directed mutagenesis to show that Glu34 in the dinucleotide-binding motif of MAO B is essential for MAO B activity, and we postulated that this residue is involved in FAD binding. In this study, we tested the role of residue 34 in flavin binding by expressing wild-type or mutant MAO B cDNA in Rib- COS-7 cells with the addition of [14C]FAD. We found that Glu34 is essential for both FAD binding and catalytic activity. Thus, FAD binds to MAO B in a dual manner at Glu34 noncovalently and Cys397 covalently. We conclude that Glu34 is critical for the initial non-covalent binding of FAD and is instrumental in delivering FAD to the covalent attachment site at Cys397.

Monoamine oxidase A from human placenta and monoamine oxidase B from bovine liver both have one FAD per subunit

I present the first clear evidence that the protein: FAD ratio in human monoamine oxidase A and bovine monoamine oxidase B has an upper limit of 65 kDa and 57 kDa per FAD, respectively. To now it had been assumed that the protein: FAD ratio was 100-120 kDa to 1 FAD and that there was one FAD per two subunits which were assumed to be of the same size. For the present work the purity of monoamine oxidase A and monoamine oxidase B was improved over that previously achieved. Protein was determined by quantitative amino acid analysis and FAD content was measured by spectrophotometric titration of SDS-denatured enzyme with NaS2O4 standardized against riboflavin. The cause of the previous misassignment of the protein: FAD ratio was judged as having been due to the use of impure enzyme preparations. Knowledge of the correct protein: FAD ratio is important in devising cloning strategies for this enzyme, in understanding its structure, function, mechanism, and in the studies of its biosynthesis.

Interaction of spin-labeled tryptamine with monoamine oxidase: probing the microenvironment of the active site by spin probe-spin label techniques

The spin-labeled substrate, tryptamine, was used as a structural probe of the active site of bovine liver monoamine oxidase B (amine:oxygen oxidoreductase (deaminating) (flavin-containing), EC 1.4.3.4). When the reaction was monitored by electron spin resonance (ESR), line broadening effects indicative of binding with an apparent relation to substrate specificity of the highly purified enzyme were observed. The spectrum indicated that the bound tryptamine was 'partially immobilized' with a dissociation constant of 39 microM and 2.2 mol bound per enzyme dimer. The correlation time, reflecting the environment of the tryptamine binding site, was determined to be 6.2 ns. The topology of the active site was investigated by using dual spin-label methodology in which the spin-labeled substrate, tryptamine, and the 15N-substituted and deuterated maleimide spin label covalently bound to the essential sulfhydryl groups were used. The ESR spectral data suggested that the essential sulfhydryl groups are at least 14 A away from the tryptamine-binding site. The environment surrounding both spin-labeled substrates, tryptamine and [2H,15N]MSL, and the motional properties of the enzyme are discussed.