Purification of MAO A and MAO B from Mammalian Tissue Sources.

Procedures are described for the purification of the mitochondrial-bound enzymes human and bovine monoamine oxidases A and B (MAO A and B) from placental and liver tissue sources, respectively. Enzyme purification follows isolation of the mitochondria and preparation of outer membrane particles. The membrane-bound enzymes are solubilized by treatment of membranes with phospholipases and detergent extraction. Functional bovine MAO B is purified by polymer fractionation and differential centrifugation. Functional human MAO A is purified by ion-exchange DEAE-Sepharose chromatography.

Purification of Recombinant Eukaryotic MAO A and MAO B Utilizing the Pichia pastoris Expression System.

Procedures are described for the heterologous expression and purification of the mitochondrial-bound enzymes human and rat monoamine oxidases A and B and zebrafish MAO in the yeast Pichia pastoris. Enzyme expression is under control of a methanol oxidase promoter and similar procedures have been developed for the preparation of membrane particles and detergent solubilization of the functional enzymes. Similarities and differences are described in the procedures for purification of the respective enzymes using standard column chromatographic techniques to provide enzyme yields in the range of 100-300 mg from 1 L of cell culture.

Crystallization of Human Monoamine Oxidase B.

The interest in monoamine oxidases A and B (MAO A and B) is due to their central role in regulating the balance of neurotransmitters, both in the central nervous system and in peripheral organs. As validated drug targets for depression and Parkinson's disease, the elucidation of their crystal structures was an essential step to guide drug design investigations. The development of the heterologous expression system of MAO B in Pichia pastoris and the identification of the detergent, buffer, and precipitant conditions allowed to determine the first crystal structure of human MAO B in 2002. A detailed protocol to obtain reproducible MAO B crystals is described.

Rational Redesign of Monoamine Oxidase A into a Dehydrogenase to Probe ROS in Cardiac Aging.

Cardiac senescence is a typical chronic frailty condition in the elderly population, and cellular aging is often associated with oxidative stress. The mitochondrial-membrane flavoenzyme monoamine oxidase A (MAO A) catalyzes the oxidative deamination of neurotransmitters, and its expression increases in aged hearts. We produced recombinant human MAO A variants at Lys305 that play a key role in O2 reactivity leading to H2O2 production. The K305Q variant is as active as the wild-type enzyme, whereas K305M and K305S have 200-fold and 100-fold lower kcat values and similar Km. Under anaerobic conditions, K305M MAO A was normally reduced by substrate, whereas reoxidation by O2 was much slower but could be accomplished by quinone electron acceptors. When overexpressed in cardiomyoblasts by adenoviral vectors, the K305M variant showed enzymatic turnover similar to that of the wild-type but displayed decreased ROS levels and senescence markers. These results might translate into pharmacological treatments as MAO inhibitors may attenuate cardiomyocytes aging.

Monoamine Oxidases.

Monoamine oxidases A and B (MAO A and B) are mammalian flavoenzymes bound to the outer mitochondrial membrane. They were discovered almost a century ago and they have been the subject of many biochemical, structural and pharmacological investigations due to their central role in neurotransmitter metabolism. Currently, the treatment of Parkinson's disease involves the use of selective MAO B inhibitors such as rasagiline and safinamide. MAO inhibition was shown to exert a general neuroprotective effect as a result of the reduction of oxidative stress produced by these enzymes, which seems to be relevant also in non-neuronal contexts. MAOs were successfully expressed as recombinant proteins in Pichia pastoris, which allowed a thorough biochemical and structural characterization. These enzymes are characterized by a globular water-soluble main body that is anchored to the mitochondrial membrane through a C-terminal α-helix, similar to other bitopic membrane proteins. In both MAO A and MAO B the enzyme active site consists of a hydrophobic cavity lined by residues that are conserved in the two isozymes, except for few details that determine substrate and inhibitor specificity. In particular, human MAO B features a dual-cavity active site whose conformation depends on the size of the bound ligand. This article provides a comprehensive and historical review of MAOs and the state-of-the-art of these enzymes as membrane drug targets.

Biosensor for the characterisation of hMAO B inhibitors and the quantification of selegiline.

A novel human monoamine oxidase B (hMAO B) based biosensor for inhibitory measurements was developed. It allows both the characterisation of the type of enzyme inhibition and the sensitive and simple determination of inhibitors like selegiline hydrochloride. The sensor consists of a screen printed carbon working electrode modified with 20% manganese dioxide (MnO2) and the enzyme hMAO B, which was immobilised on the electrode via a dialysis membrane (regenerated cellulose, molecular weight cut-off 14000). Inhibition of hMAO B is evaluated by adding different concentrations of the inhibitor selegiline hydrochloride to the enzyme and applying a defined amount of the hMAO B substrate phenylethylamine (PEA). The enzymatically formed H2O2 is amperometrically detected at 0.4V vs. Ag/AgCl in a flow injection analysis (FIA) system. With 100µM PEA the sensor showed a linear correlation between peak height and inhibitor concentration in a range of 0.51-3.25µg/mL selegiline hydrochloride. LOD and LOQ were determined to be 0.15 and 0.51µg/mL, respectively. The sensor showed a repeatability of 3.7% and an intermediate precision of 8.1%. The inhibition-based biosensor was successfully employed to quantify selegiline hydrochloride in pharmaceutical samples. Kinetic studies via Lineweaver-Burk plot and enzyme quantity vs. current plot revealed that the inhibition is irreversible.

Monoamine Oxidases, Oxidative Stress, and Altered Mitochondrial Dynamics in Cardiac Ageing.

The advances in healthcare over the past several decades have resulted in populations now living longer. With this increase in longevity, a wider prevalence of cardiovascular diseases is more common and known to be a major factor in rising healthcare costs. A wealth of scientific evidence has implicated cell senescence as an important component in the etiology of these age-dependent pathologies. A number of studies indicate that an excess of reactive oxygen species (ROS) contributes to trigger and accelerate the cardiac senescence processes, and a new role of monoamine oxidases, MAO-A and MAO-B, is emerging in this context. These mitochondrial enzymes regulate the level of catecholamines and serotonin by catalyzing their oxidative deamination in the heart. MAOs' expression substantially increases with ageing (6-fold MAO-A in the heart and 4-fold MAO-B in neuronal tissue), and their involvement in cardiac diseases is supposedly related to the formation of ROS, via the hydrogen peroxide produced during the substrate degradation. Here, we will review the most recent advances in this field and describe why MAOs could be effective targets in order to prevent age-associated cardiovascular disease.

Why p-OMe- and p-Cl-ß-Methylphenethylamines Display Distinct Activities upon MAO-B Binding.

Despite their structural and chemical commonalities, p-chloro-ß-methylphenethylamine and p-methoxy-ß-methylphenethylamine display distinct inhibitory and substrate activities upon MAO-B binding. Density Functional Theory (DFT) quantum chemical calculations reveal that ß-methylation and para-substitution underpin the observed activities sustained by calculated transition state energy barriers, attained conformations and key differences in their interactions in the enzyme's substrate binding site. Although both compounds meet substrate requirements, it is clear that ß-methylation along with the physicochemical features of the para-substituents on the aromatic ring determine the activity of these compounds upon binding to the MAO B-isoform. While data for a larger set of compounds might lend generality to our conclusions, our experimental and theoretical results strongly suggest that the contrasting activities displayed depend on the conformations adopted by these compounds when they bind to the enzyme.

Design and synthesis of novel chalcones as potent selective monoamine oxidase-B inhibitors.

A novel series of substituted chalcones were designed and synthesized to be evaluated as selective human MAO-B inhibitors. A combination of either methylsulfonyl or trifluoromethyl substituents on the aromatic ketone moiety with a benzodioxol ring on the other end of the chalcone scaffold was investigated. The compounds were tested for their inhibitory activities on both human MAO-A and B. All compounds appeared to be selective MAO-B inhibitors with Ki values in the micromolar to submicromolar range. Molecular modeling studies have been performed to get insight into the binding mode of the synthesized compounds to human MAO-B active site.

Reversible and irreversible small molecule inhibitors of monoamine oxidase B (MAO-B) investigated by biophysical techniques.

Monoamine oxidase B (MAO-B) plays a key role in the metabolism of dopamine, a neurotransmitter critical for the maintenance of cognitive function. Consequently, MAO-B is an important therapeutic target for disorders characterized by a decline in dopaminergic neurotransmission, including Parkinson's disease (PD). An emerging strategy in drug discovery is to utilize the biophysical approaches of thermal shift and isothermal titration calorimetry (ITC) to gain insight into binding modality and identify thermodynamically privileged chemical scaffolds. Described here is the development of such approaches for reversible and irreversible small molecule inhibitors of MAO-B. Investigation of soluble recombinant MAO-B revealed mechanism-based differences in the thermal shift and binding thermodynamic profiles of MAO-B inhibitors. Irreversible inhibitors demonstrated biphasic protein melt curves, large enthalpically favorable and entropically unfavorable binding, in contrast to reversible compounds, which were characterized by a dose-dependent increase in thermal stability and enthalpically-driven binding. The biophysical approaches described here aim to facilitate the discovery of next-generation MAO-B inhibitors.

Hydrogen peroxide produced by mitochondrial monoamine oxidase catalysis: biological implications.

The biological roles of mitochondrial-produced reactive oxygen species continue to receive intensive investigation since one of the products (H2O2) has important cellular signaling roles as well as contributing to apoptotic responses. In general, the source of mitochondrial reactive oxygen species is thought to be the superoxide anion produced from Complex I and Complex III components of the electron transport chain. Superoxide anion readily dismutates to H2O2 with subsequent transformation to the hydroxyl radical by Fenton chemistry. An overlooked source of H2O2 in the mitochondrion is its production as a catalytic reaction product from the outer membrane enzymes: monoamine oxidases A and B. The literature is reviewed to document identified degenerative reactions attributed to H2O2 produced by MAO A and by MAO B catalysis. Available information on the topologies of these enzymes in the mitochondrial outer membrane is also discussed with relevance to H2O2 production and involvement in cell signaling functions as well as degenerative effects.

Truncated FAD synthetase for direct biocatalytic conversion of riboflavin and analogs to their corresponding flavin mononucleotides.

The preparation of flavin mononucleotide (FMN) and FMN analogs from their corresponding riboflavin precursors is traditionally performed in a two-step procedure. After initial enzymatic conversion of riboflavin to flavin adenine dinucleotide (FAD) by a bifunctional FAD synthetase, the adenyl moiety of FAD is hydrolyzed with snake venom phosphodiesterase to yield FMN. To simplify the protocol, we have engineered the FAD synthetase from Corynebacterium ammoniagenes by deleting its N-terminal adenylation domain. The newly created biocatalyst is stable and efficient for direct and quantitative phosphorylation of riboflavin and riboflavin analogs to their corresponding FMN cofactors at preparative-scale.

Beyond the Protein Matrix: Probing Cofactor Variants in a Baeyer-Villiger Oxygenation Reaction.

A general question in biochemistry is the interplay between the chemical properties of cofactors and the surrounding protein matrix. Here, the functions of NADP+ and FAD are explored by investigation of a representative monooxygenase reconstituted with chemically-modified cofactor analogues. Like pieces of a jigsaw puzzle, the enzyme active site juxtaposes the flavin and nicotinamide rings, harnessing their H-bonding and steric properties to finely construct an oxygen-reacting center that restrains the flavin-peroxide intermediate in a catalytically-competent orientation. Strikingly, the regio- and stereoselectivities of the reaction are essentially unaffected by cofactor modifications. These observations indicate a remarkable robustness of this complex multi-cofactor active site, which has implications for enzyme design based on cofactor engineering approaches.

Precursor of ether phospholipids is synthesized by a flavoenzyme through covalent catalysis.

The precursor of the essential ether phospholipids is synthesized by a peroxisomal enzyme that uses a flavin cofactor to catalyze a reaction that does not alter the redox state of the substrates. The enzyme crystal structure reveals a V-shaped active site with a narrow constriction in front of the prosthetic group. Mutations causing inborn ether phospholipid deficiency, a very severe genetic disease, target residues that are part of the catalytic center. Biochemical analysis using substrate and flavin analogs, absorbance spectroscopy, mutagenesis, and mass spectrometry provide compelling evidence supporting an unusual mechanism of covalent catalysis. The flavin functions as a chemical trap that promotes exchange of an acyl with an alkyl group, generating the characteristic ether bond. Structural comparisons show that the covalent versus noncovalent mechanistic distinction in flavoenzyme catalysis and evolution relies on subtle factors rather than on gross modifications of the cofactor environment.

Structural basis for benzothiazinone-mediated killing of Mycobacterium tuberculosis.

The benzothiazinone BTZ043 is a tuberculosis drug candidate with nanomolar whole-cell activity. BTZ043 targets the DprE1 catalytic component of the essential enzyme decaprenylphosphoryl-ß-D-ribofuranose-2'-epimerase, thus blocking biosynthesis of arabinans, vital components of mycobacterial cell walls. Crystal structures of DprE1, in its native form and in a complex with BTZ043, reveal formation of a semimercaptal adduct between the drug and an active-site cysteine, as well as contacts to a neighboring catalytic lysine residue. Kinetic studies confirm that BTZ043 is a mechanism-based, covalent inhibitor. This explains the exquisite potency of BTZ043, which, when fluorescently labeled, localizes DprE1 at the poles of growing bacteria. Menaquinone can reoxidize the flavin adenine dinucleotide cofactor in DprE1 and may be the natural electron acceptor for this reaction in the mycobacterium. Our structural and kinetic analysis provides both insight into a critical epimerization reaction and a platform for structure-based design of improved inhibitors.

Lights and shadows on monoamine oxidase inhibition in neuroprotective pharmacological therapies.

Playing a pivotal role in the metabolism of neurotransmitters in the central nervous system, the mitochondrial enzymes monoamine oxidases A and B (MAO A and B) have been for long studied as drug targets for neurodegenerative and neurological diseases. MAO inhibitors (MAOIs) are clinically used to treat Parkinson's disease and depression by blocking the degradation of neuroactive catecholamines and providing a symptomatic relief in the patients. More recent is the idea that the neuroprotective effect of MAOIs may result from the prevention of oxidative stress produced by the MAO reaction rather than being simply related to the inhibition of neurotransmitters degradation. Tranylcypromine and phenelzine are among the first developed MAOI drugs and have been used for years to treat depression. Their usage is now limited to cases of refractory depression because of their negative side effects, which are due to both the lack of MAO A/MAO B selectivity and the inhibition of other enzymes such as the drug-metabolizing cytochromes P450. Although the multi-target action of these MAOIs determines negative implications, the most newly developed compounds have improved properties not only for their specificity relatively to MAO A/MAO B selectivity but also because they function through multiple mechanisms that produce beneficial effects. In particular, safinamide, a MAO B selective inhibitor in clinical trials for Parkinson's disease, is neuroprotective by blocking the voltage-dependent Na+ and Ca2+ channels and the Ca2+-mediated glutamate release processes. Rasagiline is a drug used in combination with L-dopa in the treatment of parkinsonian patients and the metabolic products of its degradation exert neuroprotective effects. Moreover, rasagiline scaffold is used to design analogs by addition of pharmacophores that act on other neurological targets. This multi-target approach may prove successful in order to find new and more effective therapies for the complexity of neurodegenerative diseases.

Structural properties of human monoamine oxidases A and B.

The structural elucidations of human monoamine oxidases A and B (MAO-A and -B) have provided novel insights into their similarities and differences. Although the enzymes exhibit ∼70% sequence identities, highly conserved chain folds, and are structurally identical in their flavin adenine dinucleotide (FAD)-binding sites, they differ considerably in the structures of their active sites opposite the flavin cofactor. MAO-A has a monopartite cavity of ∼550 ų, and MAO-B exhibits a bipartite cavity structure with an entrance cavity of 290 ų and a substrate cavity of ∼400 ų. Ile199 functions as a conformational "gate" separating the two cavities. Both enzymes are anchored to the outer mitochondrial membrane via C-terminal helical tails. Loop structures are found at the entrances to their active sites at the membrane surface. Although the crystal structure of human MAO-A is monomeric while MAO-B is dimeric, both enzymes are dimeric in their membrane-bound forms. Dimerization may be important for the favorable orientation of the resultant protein dipole moment toward the anionic membrane surface.

The 'gating' residues Ile199 and Tyr326 in human monoamine oxidase B function in substrate and inhibitor recognition.

The major structural difference between human monoamine oxidases A (MAO A) and B (MAO B) is that MAO A has a monopartite substrate cavity of ~550 Å(3) volume and MAO B contains a dipartite cavity structure with volumes of ~290 Å(3) (entrance cavity) and ~400 Å(3) (substrate cavity). Ile199 and Tyr326 side chains separate these two cavities in MAO B. To probe the function of these gating residues, Ile199Ala and Ile199Ala-Tyr326Ala mutant forms of MAO B were investigated. Structural data on the Ile199Ala MAO B mutant show no alterations in active site geometries compared with wild-type enzyme while the Ile199Ala-Tyr326Ala MAO B mutant exhibits alterations in residues 100-103 which are part of the loop gating the entrance to the active site. Both mutant enzymes exhibit catalytic properties with increased amine K(M) but unaltered k(cat) values. The altered K(M) values on mutation are attributed to the influence of the cavity structure in the binding and subsequent deprotonation of the amine substrate. Both mutant enzymes exhibit weaker binding affinities relative to wild-type enzyme for small reversible inhibitors. Ile199Ala MAO B exhibits an increase in binding affinity for reversible MAO B specific inhibitors which bridge both cavities. The Ile199Ala-Tyr326Ala double mutant exhibits inhibitor binding properties more similar to those of MAO A than to MAO B. These results demonstrate that the bipartite cavity structure in MAO B plays an important role in substrate and inhibitor recognition to distinguish its specificities from those of MAO A and provide insights into specific reversible inhibitor design for these membrane-bound enzymes.

²H kinetic isotope effects and pH dependence of catalysis as mechanistic probes of rat monoamine oxidase A: comparisons with the human enzyme.

Monoamine oxidase A (MAO A) is a mitochondrial outer membrane-bound flavoenzyme important in the regulation of serotonin and dopamine levels. Because the rat is extensively used as an animal model in drug studies, it is important to understand how rat MAO A behaves in comparison with the more extensively studied human enzyme. For many reversible inhibitors, rat MAO A exhibits K(i) values similar to those of human MAO A. The pH profile of k(cat) for rat MAO A shows a pK(a) of 8.2 ± 0.1 for the benzylamine ES complex and pK(a) values of 7.5 ± 0.1 and 7.6 ± 0.1 for the ES complexes with p-CF(3)-(1)H- and p-CF(3)-(2)H-benzylamine, respectively. In contrast to the human enzyme, the rat enzyme exhibits a single pK(a) value (8.3 ± 0.1) with k(cat)/K(m) for benzylamine versus pH and pK(a) values of 7.8 ± 0.1 and 8.1 ± 0.2 for the ascending limbs, respectively, of k(cat)/K(m) versus pH profiles for p-CF(3)-(1)H- and p-CF(3)-(2)H-benzylamine and 9.3 ± 0.1 and 9.1 ± 0.2 for the descending limbs, respectively. The oxidation of para-substituted benzylamine substrate analogues by rat MAO A has large deuterium kinetic isotope effects on k(cat) and on k(cat)/K(m). These effects are pH-independent and range from 7 to 14, demonstrating a rate-limiting α-C-H bond cleavage step in catalysis. Quantitative structure-activity correlations of log k(cat) with the electronic substituent parameter (σ) at pH 7.5 and 9.0 show a dominant contribution with positive ρ values (1.2-1.3) and a pH-independent negative contribution from the steric term. Quantitative structure-activity relationship analysis of the binding affinities of the para-substituted benzylamine analogues for rat MAO A shows an increased van der Waals volume (V(w)) increases the affinity of the deprotonated amine for the enzyme. These results demonstrate that rat MAO A exhibits functional properties similar but not identical with those of the human enzyme and provide additional support for C-H bond cleavage via a polar nucleophilic mechanism.

Nitrogen kinetic isotope effects for the monoamine oxidase B-catalyzed oxidation of benzylamine and (1,1-(2)H2)benzylamine: nitrogen rehybridization and CH bond cleavage are not concerted.

Nitrogen kinetic isotope effects for the oxidation of benzylamine and (1,1-(2)H(2))benzylamine by recombinant human monoamine oxidase B show that cleavage of the CH bond is not concerted with rehybridization of the nitrogen atom.