Uncoupled human flavin-containing monooxygenase 3 releases superoxide radical in addition to hydrogen peroxide.

Human flavin-containing monooxygenase 3 (hFMO3) is a drug-metabolizing enzyme capable of performing N- or S-oxidation using the C4a-hydroperoxy intermediate. In this work, we employ both wild type hFMO3 as well as an active site polymorphic variant (N61S) to unravel the uncoupling reactions in the catalytic cycle of this enzyme. We demonstrate that in addition to H2O2 this enzyme also produces superoxide anion radicals as its uncoupling products. The level of uncoupling was found to vary between 50 and 70% (WT) and 90-98% (N61S) for incubations with NADPH and benzydamine over a period of 5 or 20 min, respectively. For the first time, we were able to follow the production of the superoxide radical in hFMO3, which was found to account for 13-18% of the total uncoupling of this human enzyme. Moreover, measurements in the presence or absence of the substrate show that the substrate lowers the level of uncoupling only related to the H2O2 and not the superoxide radical. This is consistent with the entry point of the substrate in this enzyme's catalytic cycle. These findings highlight the importance of the involvement of hFMO3 in the production of radicals in the endoplasmic reticulum, as well as the relevance of single-nucleotide polymorphism leading to deleterious effects of oxidative stress.

Drug metabolite synthesis by immobilized human FMO3 and whole cell catalysts.

BACKGROUND: Sufficient reference standards of drug metabolites are required in the drug discovery and development process. However, such drug standards are often expensive or not commercially available. Chemical synthesis of drug metabolite is often difficulty due to the highly regio- and stereo-chemically demanding. The present work aims to construct stable and efficient biocatalysts for the generation of drug metabolites in vitro. RESULT: In this work, using benzydamine as a model drug, two easy-to-perform approaches (whole cell catalysis and enzyme immobilization) were investigated for the synthesis of FMO3-generated drug metabolites. The whole cell catalysis was carried out by using cell suspensions of E. coli JM109 harboring FMO3 and E. coli BL21 harboring GDH (glucose dehydrogenase), giving 1.2 g/L benzydamine N-oxide within 9 h under the optimized conditions. While for another approach, two HisTrap HP columns respectively carrying His6-GDH and His6-FMO3 were connected in series used for the biocatalysis. In this case, 0.47 g/L benzydamine N-oxide was generated within 2.5 h under the optimized conditions. In addition, FMO3 immobilization at the C-terminal (membrane anchor region) significantly improved its enzymatic thermostability by more than 10 times. Moreover, the high efficiency of these two biocatalytic approaches was also confirmed by the N-oxidation of tamoxifen. CONCLUSIONS: The results presented in this work provides new possibilities for the drug-metabolizing enzymes-mediated biocatalysis.

Binding of methimazole and NADP(H) to human FMO3: In vitro and in silico studies.

Human flavin-containing monooxygenase isoform 3 (hFMO3) is an important hepatic drug-metabolizing enzyme, catalyzing the monooxygenation of nucleophilic heteroatom-containing xenobiotics. Based on the structure of bacterial FMO, it is proposed that a conserved asparagine is involved in both NADP(H) and substrate binding. In order to explore the role of this amino acid in hFMO3, two mutants were constructed. In the case of N61Q, increasing the steric hindrance above the flavin N5-C4a causes poor NADP(H) binding, destabilizing the catalytic FAD intermediate, whereas the introduction of a negatively charged residue, N61D, interferes mainly with catalytic intermediate formation and its stability. To better understand the substrate-enzyme interaction, in vitro as well as in silico experiments were carried out with methimazole as substrate. Methimazole is a high-affinity substrate of hFMO3 and can competitively suppress the metabolism of other compounds. Our results demonstrate that methimazole Pi-stacks above the isoalloxazine ring of FAD in hFMO3, in a similar way to indole binding to the bacterial FMO. However, for hFMO3 indole is found to act as a non-substrate competitive inhibitor. Finally, understanding the binding mode of methimazole and indole could be advantageous for development of hFMO3 inhibitors, currently investigated as a possible treatment strategy for atherosclerosis.

Inactivation mechanism of N61S mutant of human FMO3 towards trimethylamine.

Human flavin-containing monooxygenase 3 (hFMO3) catalyses the oxygenation of a wide variety of compounds including drugs as well as dietary compounds. It is the major hepatic enzyme involved in the production of the N-oxide of trimethylamine (TMAO) and clinical studies have uncovered a striking correlation between plasma TMAO concentration and cardiovascular disease. Certain mutations within the hFMO3 gene cause defective trimethylamine (TMA) N-oxygenation leading to trimethylaminuria (TMAU) also known as fish-odour syndrome. In this paper, the inactivation mechanism of a TMAU-causing polymorphic variant, N61S, is investigated. Transient kinetic experiments show that this variant has a > 170-fold lower NADPH binding affinity than the wild type. Thermodynamic and spectroscopic experiments reveal that the poor NADP+ binding affinity accelerates the C4a-hydroperoxyFAD intermediate decay, responsible for an unfavourable oxygen transfer to the substrate. Steady-state kinetic experiments show significantly decreased N61S catalytic activity towards other substrates; methimazole, benzydamine and tamoxifen. The in vitro data are corroborated by in silico data where compared to the wild type enzyme, a hydrogen bond required for the stabilisation of the flavin intermediate is lacking. Taken together, the data presented reveal the molecular basis for the loss of function observed in N61S mutant.

Human flavin-containing monooxygenase 3: Structural mapping of gene polymorphisms and insights into molecular basis of drug binding.

Human hepatic flavin-containing monooxygenase 3 (hFMO3) catalyses the monooxygenation of carbon-bound reactive heteroatoms and plays an important role in the metabolism of drugs and xenobiotics. Although numerous hFMO3 allelic variants have been identified in patients and their biochemical properties well-characterised in vitro, the molecular mechanisms underlying loss-of-function mutations have still not been elucidated due to lack of detailed structural information of hFMO3. Therefore, in this work a 3D structural model of hFMO3 was generated by homology modeling, evaluated by a variety of different bioinformatics tools, refined by molecular dynamics simulations and further assessed based on in vitro biochemical data. The molecular dynamics simulation results highlighted 4 flexible regions of the protein with some of them overlapping the data from trypsin digest. This was followed by structural mapping of 12 critical polymorphic variants and molecular docking experiments with five different known substrates/drugs of hFMO3 namely, benzydamine, sulindac sulfide, tozasertib, methimazole and trimethylamine. Localisation of these mutations on the hFMO3 model provided a structural explanation for their observed biological effects and docked models of hFMO3-drug complexes gave insights into their binding mechanism demonstrating that nitrogen- and sulfur-containing substrates interact with the isoalloxazine ring through Pi-Cation interaction and Pi-Sulfur interactions, respectively. Finally, the data presented give insights into the drug binding mechanism of hFMO3 which could be valuable not only for screening of new chemical entities but more significantly for designing of novel inhibitors of this important Phase I drug metabolising enzyme.

Site-directed mutagenesis studies of the aromatic residues at the active site of a lipase from Malassezia globosa.

The lipase from Malassezia globosa (SMG1) has specific activity on mono- and diacylglycerol but not on triacylglycerol. The structural analysis of SMG1 structure shows that two bulky aromatic residues, W116 and W229, lie at the entrance of the active site. To study the functions of these two residues in the substrate recognition and the catalytic reaction, they were mutated to a series of amino acids. Subsequently, biochemical properties of these mutants were investigated. Although the activities decrease, W229L and W116A show a significant shift in substrate preference. W229L has an increased preference for short-chain substrates whereas W116A has preference for long-chain substrates. Besides, the half-lives of W116A and W116H at 45 °C are 346.6 min and 115.5 min respectively, which improve significantly compared to that of native enzyme. Moreover, the optimum substrate of W116A, W116F and W229F mutants shifted from p-nitrophenyl caprylate to p-nitrophenyl myristate. These findings not only shed light onto the lipase structure/function relationship but also lay the framework for the potential industrial applications.

Molecular basis for substrate selectivity of a mono- and diacylglycerol lipase from Malassezia globosa.

The lipase from Malassezia globosa (SMG1) was identified to be strictly specific for mono- and diacylglycerol but not triacylglycerol. The crystal structures of SMG1 were solved in the closed conformation, but they failed to provide direct evidence of factors responsible for this unique selectivity. To address this problem, we constructed a structure in the open, active conformation and modeled a diacylglycerol analogue into the active site. Molecular dynamics simulations were performed on this enzyme-analogue complex to relax steric clashes. This bound diacylglycerol analogue unambiguously identified the position of two pockets which accommodated two alkyl chains of substrate. The structure of SMG1-analogue complex revealed that Leu103 and Phe278 divided the catalytic pocket into two separated moieties, an exposed groove and a narrow tunnel. Analysis of the binding model suggested that the unique selectivity of this lipase mainly resulted from the shape and size of this narrow tunnel, in which there was no space for the settlement of the third chain of triacylglycerol. These results expand our understanding on the mechanism underlying substrate selectivity of enzyme, and could pave the way for site-directed mutagenesis experiments to improve the enzyme for application.