Assembly of redox centers in the trimethylamine dehydrogenase of bacterium W3A1. Properties of the wild-type enzyme and a C30A mutant expressed from a cloned gene in Escherichia coli

What's in a covalent bond? On the role and formation of covalently bound flavin cofactors

Many enzymes use one or more cofactors, such as biotin, heme, or flavin. These cofactors may be bound to the enzyme in a noncovalent or covalent manner. Although most flavoproteins contain a noncovalently bound flavin cofactor (FMN or FAD), a large number have these cofactors covalently linked to the polypeptide chain. Most covalent flavin-protein linkages involve a single cofactor attachment via a histidyl, tyrosyl, cysteinyl or threonyl linkage. However, some flavoproteins contain a flavin that is tethered to two amino acids. In the last decade, many studies have focused on elucidating the mechanism(s) of covalent flavin incorporation (flavinylation) and the possible role(s) of covalent protein-flavin bonds. These endeavors have revealed that covalent flavinylation is a post-translational and self-catalytic process. This review presents an overview of the known types of covalent flavin bonds and the proposed mechanisms and roles of covalent flavinylation.

Probing the dynamic interface between trimethylamine dehydrogenase (TMADH) and electron transferring flavoprotein (ETF) in the TMADH-2ETF complex: role of the Arg-alpha237 (ETF) and Tyr-442 (TMADH) residue pair

We have used multiple solution state techniques and crystallographic analysis to investigate the importance of a putative transient interaction formed between Arg-alpha237 in electron transferring flavoprotein (ETF) and Tyr-442 in trimethylamine dehydrogenase (TMADH) in complex assembly, electron transfer, and structural imprinting of ETF by TMADH. We have isolated four mutant forms of ETF altered in the identity of the residue at position 237 (alphaR237A, alphaR237K, alphaR237C, and alphaR237E) and with each form studied electron transfer from TMADH to ETF, investigated the reduction potentials of the bound ETF cofactor, and analyzed complex formation. We show that mutation of Arg-alpha237 substantially destabilizes the semiquinone couple of the bound FAD and impedes electron transfer from TMADH to ETF. Crystallographic structures of the mutant ETF proteins indicate that mutation does not perturb the overall structure of ETF, but leads to disruption of an electrostatic network at an ETF domain boundary that likely affects the dynamic properties of ETF in the crystal and in solution. We show that Arg-alpha237 is required for TMADH to structurally imprint the as-purified semiquinone form of wild-type ETF and that the ability of TMADH to facilitate this structural reorganization is lost following (i) redox cycling of ETF, or simple conversion to the oxidized form, and (ii) mutagenesis of Arg-alpha237. We discuss this result in light of recent apparent conflict in the literature relating to the structural imprinting of wild-type ETF. Our studies support a mechanism of electron transfer by conformational sampling as advanced from our previous analysis of the crystal structure of the TMADH-2ETF complex [Leys, D. , Basran, J. , Sutcliffe, M. J., and Scrutton, N. S. (2003) Nature Struct. Biol. 10, 219-225] and point to a key role for the Tyr-442 (TMADH) and Arg-alpha237 (ETF) residue pair in transiently stabilizing productive electron transfer configurations. Our work also points to the importance of Arg-alpha237 in controlling the thermodynamics of electron transfer, the dynamics of ETF, and the protection of reducing equivalents following disassembly of the TMADH-2ETF complex.

Production of completely flavinylated histamine dehydrogenase, unique covalently bound flavin, and iron-sulfur cluster-containing enzyme of nocardioides simplex in Escherichia coli, and its properties

The hmd gene of histamine dehydrogenase from Nocardioides simplex was overexpressed in Escherichia coli, and the resulting enzyme was purified to homogeneity. The purified recombinant enzyme is almost identical with the native enzyme in view of molecular weight and specific activity, and is stoichiometrically assembled with the three cofactors 6-S-cysteinyl FMN, 4Fe-4S cluster, and ADP.

Histamine dehydrogenase from Rhizobium sp.: gene cloning, expression in Escherichia coli, characterization and application to histamine determination

The gene encoding histamine dehydrogenase in Rhizobium sp. 4--9 has been cloned and overexpressed in Escherichia coli. The coding region of the gene was 2,079 bp and encoded a protein of 693 amino acids with a calculated molecular mass of 76,732 Da. This histamine dehydrogenase was related to histamine dehydrogenase from Nocardioides simplex (54.5% identical), trimethylamine dehydrogenase from Methylophilus methylotrophus (39.3% identical) and dimethylamine dehydrogenase from Hyphomicrobium X (38.1% identical), which have a covalent 6-S-cysteinyl flavin mononucleotide and a [4Fe--4S] cluster as redox cofactors. Sequence alignment and a UV-visible absorption spectrum supported the presence of these cofactors in this histamine dehydrogenase. The investigation of the enzymatic properties suggested that this enzyme exhibited the most excellent substrate specificity toward histamine among all amine oxidases or dehydrogenases found to date. The recombinant enzyme was able to be used for the colorimetric determination of histamine, which gave a linear calibration curve and identical data with conventional methods.

Biosynthesis of covalently bound flavin: isolation and in vitro flavinylation of the monomeric sarcosine oxidase apoprotein

The covalently bound FAD in native monomeric sarcosine oxidase (MSOX) is attached to the protein by a thioether bond between the 8alpha-methyl group of the flavin and Cys315. Large amounts of soluble apoenzyme are produced by controlled expression in a riboflavin-dependent Escherichia coli strain. A time-dependent increase in catalytic activity is observed upon incubation of apoMSOX with FAD, accompanied by the covalent incorporation of FAD to approximately 80% of the level observed with the native enzyme. The spectral and catalytic properties of the reconstituted enzyme are otherwise indistinguishable from those of native MSOX. The reconstitution reaction exhibits apparent second-order kinetics (k = 139 M(-)(1) min(-)(1) at 23 degrees C) and is accompanied by the formation of a stoichiometric amount of hydrogen peroxide. A time-dependent reduction of FAD is observed when the reconstitution reaction is conducted under anaerobic conditions. The results provide definitive evidence for autoflavinylation in a reaction that proceeds via a reduced flavin intermediate and requires only apoMSOX and FAD. Flavinylation of apoMSOX is not observed with 5-deazaFAD or 1-deazaFAD, an outcome attributed to a decrease in the acidity of the 8alpha-methyl group protons. Covalent flavin attachment is observed with 8-nor-8-chloroFAD in an aromatic nucleophilic displacement reaction that proceeds via a quininoid intermediate but not a reduced flavin intermediate. The reconstituted enzyme contains a modified cysteine-flavin linkage (8-nor-8-S-cysteinyl) as compared with native MSOX (8alpha-S-cysteinyl), a difference that may account for its approximately 10-fold lower catalytic activity.

6-S-cysteinyl flavin mononucleotide-containing histamine dehydrogenase from Nocardioides simplex: molecular cloning, sequencing, overexpression, and characterization of redox centers of enzyme

Histamine dehydrogenase from Nocardioides simplex is a homodimeric enzyme and catalyzes oxidative deamination of histamine. The gene encoding this enzyme has been sequenced and cloned by polymerase chain reactions and overexpressed in Escherichia coli. The sequence of the complete open reading frame, 2073 bp coding for a protein of 690 amino acids, was determined on both strands. The amino acid sequence of histamine dehydrogenase is closely related to those of trimethylamine dehydrogenase and dimethylamine dehydrogenase containing an unusual covalently bound flavin mononucleotide, 6-S-cysteinyl-flavin mononucleotide, and one 4Fe-4S cluster as redox active cofactors in each subunit of the homodimer. The presence of the identical redox cofactors in histamine dehydrogenase has been confirmed by sequence alignment analysis, mass spectral analysis, UV-vis and EPR spectroscopy, and chemical analysis of iron and acid-labile sulfur. These results suggest that the structure of histamine dehydrogenase in the vicinity of the two redox centers is almost identical to that of trimethylamine dehydrogenase as a whole. The structure modeling study, however, demonstrated that a putative substrate-binding cavity in histamine dehydrogenase is quite distinct from that of trimethylamine dehydrogenase.

A mechanism for substrate-Induced formation of 6-hydroxyflavin mononucleotide catalyzed by C30A trimethylamine dehydrogenase

Experiments are described to determine the origin of the 6-hydroxyl group of 6-hydroxyFMN produced by the substrate-induced transformation of FMN in the C30A mutant of trimethylamine dehydrogenase. The conversion of FMN to 6-hydroxyFMN is carried out in the presence of H(2)(18)O and 18O(2), and the results clearly show that the 6-hydroxyl group is derived from molecular oxygen and not from water.

Deflavination and reconstitution of flavoproteins

Flavoproteins are ubiquitous redox proteins that are involved in many biological processes. In the majority of flavoproteins, the flavin cofactor is tightly but noncovalently bound. Reversible dissociation of flavoproteins into apoprotein and flavin prosthetic group yields valuable insights in flavoprotein folding, function and mechanism. Replacement of the natural cofactor with artificial flavins has proved to be especially useful for the determination of the solvent accessibility, polarity, reaction stereochemistry and dynamic behaviour of flavoprotein active sites. In this review we summarize the advances made in the field of flavoprotein deflavination and reconstitution. Several sophisticated chromatographic procedures to either deflavinate or reconstitute the flavoprotein on a large scale are discussed. In a subset of flavoproteins, the flavin cofactor is covalently attached to the polypeptide chain. Studies from riboflavin-deficient expression systems and site-directed mutagenesis suggest that the flavinylation reaction is a post-translational, rather than a cotranslational, process. These genetic approaches have also provided insight into the mechanism of covalent flavinylation and the rationale for this atypical protein modification.

Optimizing the Michaelis complex of trimethylamine dehydrogenase: identification of interactions that perturb the ionization of substrate and facilitate catalysis with trimethylamine base

Recent evidence from isotope studies supports the view that catalysis by trimethylamine dehydrogenase (TMADH) proceeds from a Michaelis complex involving trimethylamine base and not, as thought previously, trimethylammonium cation. In native TMADH reduction of the flavin by substrate (perdeuterated trimethylamine) is influenced by two ionizations in the Michaelis complex with pK(a) values of 6.5 and 8.4; maximal activity is realized in the alkaline region. The latter ionization has been attributed to residue His-172 and, more recently, the former to the ionization of substrate itself. In the Michaelis complex, the ionization of substrate (pK(a) approximately 6.5 for perdeuterated substrate) is perturbed by approximately -3.3 to -3.6 pH units compared with that of free trimethylamine (pK(a) = 9.8) and free perdeuterated trimethylamine (pK(a) = 10.1), respectively, thus stabilizing trimethylamine base by approximately 2 kJ mol(-1). We show, by targeted mutagenesis and stopped-flow studies that this reduction of the pK(a) is a consequence of electronic interaction with residues Tyr-60 and His-172, thus these two residues are key for optimizing catalysis in the physiological pH range. We also show that residue Tyr-174, the remaining ionizable group in the active site that we have not targeted previously by mutagenesis, is not implicated in the pH dependence of flavin reduction. Formation of a Michaelis complex with trimethylamine base is consistent with a mechanism of amine oxidation that we advanced in our previous computational and kinetic studies which involves nucleophilic attack by the substrate nitrogen atom on the electrophilic C4a atom of the flavin isoalloxazine ring. Stabilization of trimethylamine base in the Michaelis complex over that in free solution is key to optimizing catalysis at physiological pH in TMADH, and may be of general importance in the mechanism of other amine dehydrogenases that require the unprotonated form of the substrate for catalysis.

The covalent FAD of monoamine oxidase: structural and functional role and mechanism of the flavinylation reaction

The family of flavoenzymes in which the flavin coenzyme redox cofactor is covalently attached to the protein through an amino acid side chain is covered in this review. Flavin-protein covalent linkages have been shown to exist through each of five known linkages: (a) 8alpha-N(3)-histidyl, (b) 8alpha-N(1)-histidyl, (c) 8alpha-S-cysteinyl, (d) 8alpha-O-tyrosyl, or (e) 6-S-cysteinyl with the flavin existing at either the flavin mononucleotide or flavin adenine dinucleotide (FAD) levels. This class of enzymes is widely distributed in diverse biological systems and catalyzes a variety of enzymatic reactions. Current knowledge on the mechanism of covalent flavin attachment is discussed based on studies on the 8alpha-S-cysteinylFAD of monoamine oxidases A and B, as well as studies on other flavoenzymes. The evidence supports an autocatalytic quinone-methide mechanism of protein flavinylation. Proposals to explain the structural and mechanistic advantages of a covalent flavin linkage in flavoenzymes are presented. It is concluded that multiple factors are involved and include: (a) stabilization of the apoenzyme structure, (b) steric alignment of the cofactor in the active site to facilitate catalysis, and (c) modulation of the redox potential of the covalent flavin through electronic effects of 8alpha-substitution.

Inactivation of C30A trimethylamine dehydrogenase by N-cyclopropyl-alpha-methylbenzylamine, 1-phenylcyclopropylamine, and phenylhydrazine

Trimethylamine dehydrogenase (TMADH) from the bacterium Methylophilus methylotrophus (sp. W(3)A(1)) and its C30A mutant were inactivated with three known inactivators of monoamine oxidase, namely, phenylhydrazine, N-cyclopropyl-alpha-methylbenzylamine, and 1-phenylcyclopropylamine. All three compounds irreversibly inactivated both the wild-type and C30A mutant enzymes, although phenylhydrazine was 10 times more potent than N-cyclopropyl-alpha-methylbenzylamine, which was much more potent than 1-phenylcyclopropylamine. The change in the UV--visible absorption spectra upon modification indicated that the flavin was modified. In the case of the C30A mutant, the absence of a covalent attachment of the flavin to the polypeptide has permitted LC-electrospray mass spectrometry of the reaction product to be undertaken, demonstrating new mass peaks corresponding to various chemically modified forms of the flavin cofactor. In the case of N-cyclopropyl-alpha-methylbenzylamine, masses corresponding to hydroxy-FMN and hydroxyriboflavin were detected. 1-Phenylcyclopropylamine inactivation of the C30A mutant produced three modified flavins, as evidenced by the electrospray mass spectrum: hydroxy-FMN, FMN plus C(6)H(5)COCH(2)CH(2), and hydroxy-FMN plus C(6)H(5)COCH(2)CH(2). Phenylhydrazine inactivation of the C30A mutant gave at least seven different modified flavins: hydroxyriboflavin, hydroxy-FMN, two apparently isomeric compounds corresponding to hydroxy-FMN plus one phenyl group, two apparently isomeric compounds corresponding to FMN plus one phenyl group, and FMN plus two phenyl groups. Covalent flavin adduct formation appears to be the only modification because dialysis of the inactive enzyme followed by reconstitution with FMN restores the enzyme activity to that of a noninactivated control.

Organization of the multiple coenzymes and subunits and role of the covalent flavin link in the complex heterotetrameric sarcosine oxidase

Heterotetrameric (alphabetagammadelta) sarcosine oxidase from Corynebacterium sp. P-1 (cTSOX) contains noncovalently bound FAD and NAD(+) and covalently bound FMN, attached to beta(His173). The beta(His173Asn) mutant is expressed as a catalytically inactive, labile heterotetramer. The beta and delta subunits are lost during mutant enzyme purification, which yields a stable alphagamma complex. Addition of stabilizing agents prevents loss of the delta but not the beta subunit. The covalent flavin link is clearly a critical structural element and essential for TSOX activity or preventing FMN loss. The alpha subunit was expressed by itself and purified by affinity chromatography. The alpha and beta subunits each contain an NH(2)-terminal ADP-binding motif that could serve as part of the binding site for NAD(+) or FAD. The alpha subunit and the alphagamma complex were each found to contain 1 mol of NAD(+) but no FAD. Since NAD(+) binds to alpha, FAD probably binds to beta. The latter could not be directly demonstrated since it was not possible to express beta by itself. However, FAD in TSOX from Pseudomonas maltophilia (pTSOX) exhibits properties similar to those observed for the covalently bound FAD in monomeric sarcosine oxidase and N-methyltryptophan oxidase, enzymes that exhibit sequence homology with beta. A highly conserved glycine in the ADP-binding motif of the alpha(Gly139) or beta(Gly30) subunit was mutated in an attempt to generate NAD(+)- or FAD-free cTSOX, respectively. The alpha(Gly139Ala) mutant is expressed only at low temperature (t(optimum) = 15 degrees C), but the purified enzyme exhibited properties indistinguishable from the wild-type enzyme. The much larger barrier to NAD(+) binding in the case of the alpha(Gly139Val) mutant could not be overcome even by growth at 3 degrees C, suggesting that NAD(+) binding is required for TSOX expression. The beta(Gly30Ala) mutant exhibited subunit expression levels similar to those of the wild-type enzyme, but the mutation blocked subunit assembly and covalent attachment of FMN, suggesting that both processes require a conformational change in beta that is induced upon FAD binding. About half of the covalent FMN in recombinant preparations of cTSOX or pTSOX is present as a reversible covalent 4a-adduct with a cysteine residue. Adduct formation is not prevented by mutating any of the three cysteine residues in the beta subunit of cTSOX to Ser or Ala. Since FMN is attached via its 8-methyl group to the beta subunit, the FMN ring must be located at the interface between beta and another subunit that contains the reactive cysteine residue.

Differential coupling through Val-344 and Tyr-442 of trimethylamine dehydrogenase in electron transfer reactions with ferricenium ions and electron transferring flavoprotein

Modeling studies of the trimethylamine dehydrogenase-electron transferring flavoprotein (TMADH-ETF) electron transfer complex have suggested potential roles for Val-344 and Tyr-442, found on the surface of TMADH, in electronic coupling between the 4Fe-4S center of TMADH and the FAD of ETF. The importance of these residues in electron transfer, both to ETF and to the artificial electron acceptor, ferricenium (Fc(+)), has been studied by site-directed mutagenesis and stopped-flow spectroscopy. Reduction of the 6-(S)-cysteinyl FMN in TMADH is not affected by mutation of either Tyr-442 or Val-344 to a variety of alternate side chains, although there are modest changes in the rate of internal electron transfer from the 6-(S)-cysteinyl FMN to the 4Fe-4S center. The kinetics of electron transfer from the 4Fe-4S center to Fc(+) are sensitive to mutations at position 344. The introduction of smaller side chains (Ala-344, Cys-344, and Gly-344) leads to enhanced rates of electron transfer, and likely reflects shortened electron transfer "pathways" from the 4Fe-4S center to Fc(+). The introduction of larger side chains (Ile-344 and Tyr-344) reduces substantially the rate of electron transfer to Fc(+). Electron transfer to ETF is not affected, to any large extent, by mutation of Val-344. In contrast, mutation of Tyr-442 to Phe, Leu, Cys, and Gly leads to major reductions in the rate of electron transfer to ETF, but not to Fc(+). The data indicate that electron transfer to Fc(+) is via the shortest pathway from the 4Fe-4S center of TMADH to the surface of the enzyme. Val-344 is located at the end of this pathway at the bottom of a small groove on the surface of TMADH, and Fc(+) can penetrate this groove to facilitate good electronic coupling with the 4Fe-4S center. With ETF as an electron acceptor, the observed rate of electron transfer is substantially reduced on mutation of Tyr-442, but not Val-344. We conclude that the flavin of ETF does not penetrate fully the groove on the surface of TMADH, and that electron transfer from the 4Fe-4S center to ETF may involve a longer pathway involving Tyr-442. Mutation of Tyr-442 likely disrupts electron transfer by perturbing the interaction geometry of TMADH and ETF in the productive electron transfer complex, leading to less efficient coupling between the redox centers.

Influence of FAD structure on its binding and activity with the C406A mutant of recombinant human liver monoamine oxidase A

The FAD binding site of human liver monoamine oxidase A (MAO A) has been investigated by mutagenesis of the amino acid site of covalent FAD attachment (Cys-406) to an alanyl residue. Expression of the C406A mutant in Saccharomyces cerevisiae results in the formation of an active enzyme, as found previously with the rat liver enzyme. The activity of this mutant enzyme is labile to solubilization, thus requiring all experiments to be done with membrane preparations. C406A MAO A was expressed in a rib 5(-) strain of S. cerevisiae in the presence of 16 different riboflavin analogues. Inactive apoC406A MAO A is formed by induction of the enzyme in the absence of riboflavin. FAD but not FMN or riboflavin restores catalytic activity with an apparent K(d) of 62 +/- 5 nm. The results from both in vivo and in vitro reconstitution experiments show increased activity levels (up to approximately 7-fold higher) with those analogues exhibiting higher oxidation-reduction potentials than normal flavin and decreased activity levels with analogues exhibiting lower potentials. Analogues with substituents on the pyrimidine ring bind to C406A MAO A more weakly than normal FAD, suggesting specific interactions with the N(3) and N(1) positions. Analogues with substituents in the 7 and 8 positions bind to C406A MAO A with affinities comparable with that of normal FAD. These results are discussed in regard to functional significance of 8alpha-covalent binding of flavins to proteins.

Structural and biochemical characterization of recombinant wild type and a C30A mutant of trimethylamine dehydrogenase from methylophilus methylotrophus (sp. W(3)A(1))

Trimethylamine dehydrogenase (TMADH) is an iron-sulfur flavoprotein that catalyzes the oxidative demethylation of trimethylamine to form dimethylamine and formaldehyde. It contains a unique flavin, in the form of a 6-S-cysteinyl FMN, which is bent by approximately 25 degrees along the N5-N10 axis of the flavin isoalloxazine ring. This unusual conformation is thought to modulate the properties of the flavin to facilitate catalysis, and has been postulated to be the result of covalent linkage to Cys-30 at the flavin C6 atom. We report here the crystal structures of recombinant wild-type and the C30A mutant TMADH enzymes, both determined at 2.2 A resolution. Combined crystallographic and NMR studies reveal the presence of inorganic phosphate in the FMN binding site in the deflavo fraction of both recombinant wild-type and C30A proteins. The presence of tightly bound inorganic phosphate in the recombinant enzymes explains the inability to reconstitute the deflavo forms of the recombinant wild-type and C30A enzymes that are generated in vivo. The active site structure and flavin conformation in C30A TMADH are identical to those in recombinant and native TMADH, thus revealing that, contrary to expectation, the 6-S-cysteinyl FMN link is not responsible for the 25 degrees butterfly bending along the N5-N10 axis of the flavin in TMADH. Computational quantum chemistry studies strongly support the proposed role of the butterfly bend in modulating the redox properties of the flavin. Solution studies reveal major differences in the kinetic behavior of the wild-type and C30A proteins. Computational studies reveal a hitherto, unrecognized, contribution made by the S(gamma) atom of Cys-30 to substrate binding, and a role for Cys-30 in the optimal geometrical alignment of substrate with the 6-S-cysteinyl FMN in the enzyme active site.

Covalent flavinylation is essential for efficient redox catalysis in vanillyl-alcohol oxidase

By mutating the target residue of covalent flavinylation in vanillyl-alcohol oxidase, the functional role of the histidyl-FAD bond was studied. Three His(422) mutants (H422A, H422T, and H422C) were purified, which all contained tightly but noncovalently bound FAD. Steady state kinetics revealed that the mutants have retained enzyme activity, although the turnover rates have decreased by 1 order of magnitude. Stopped-flow analysis showed that the H422A mutant is still able to form a stable binary complex of reduced enzyme and a quinone methide product intermediate, a crucial step during vanillyl-alcohol oxidase-mediated catalysis. The only significant change in the catalytic cycle of the H422A mutant is a marked decrease in reduction rate. Redox potentials of both wild type and H422A vanillyl-alcohol oxidase have been determined. During reduction of H422A, a large portion of the neutral flavin semiquinone is observed. Using suitable reference dyes, the redox potentials for the two one-electron couples have been determined: -17 and -113 mV. Reduction of wild type enzyme did not result in any formation of flavin semiquinone and revealed a remarkably high redox potential of +55 mV. The marked decrease in redox potential caused by the missing covalent histidyl-FAD bond is reflected in the reduced rate of substrate-mediated flavin reduction limiting the turnover rate. Elucidation of the crystal structure of the H422A mutant established that deletion of the histidyl-FAD bond did not result in any significant structural changes. These results clearly indicate that covalent interaction of the isoalloxazine ring with the protein moiety can markedly increase the redox potential of the flavin cofactor, thereby facilitating redox catalysis. Thus, formation of a histidyl-FAD bond in specific flavoenzymes might have evolved as a way to contribute to the enhancement of their oxidative power.

Redox cycles in trimethylamine dehydrogenase and mechanism of substrate inhibition

The steady-state reaction of trimethylamine dehydrogenase (TMADH) with the artificial electron acceptor ferricenium hexafluorophosphate (Fc(+)) has been studied by stopped-flow spectroscopy, with particular reference to the mechanism of inhibition by trimethylamine (TMA). Previous studies have suggested that the presence of alternate redox cycles is responsible for the inhibition of activity seen in the high-substrate regime. Here, we demonstrate that partitioning between these redox cycles (termed the 0/2 and 1/3 cycles on the basis of the number of reducing equivalents present in the oxidized/reduced enzyme encountered in each cycle) is dependent on both TMA and electron acceptor concentration. The use of Fc(+) as electron acceptor has enabled a study of the major redox forms of TMADH present during steady-state turnover at different concentrations of substrate. Reduction of Fc(+) is found to occur via the 4Fe-4S center of TMADH and not the 6-S-cysteinyl flavin mononucleotide: the direction of electron flow is thus analogous to the route of electron transfer to the physiological electron acceptor, an electron-transferring flavoprotein (ETF). In steady-state reactions with Fc(+) as electron acceptor, partitioning between the 0/2 and 1/3 redox cycles is dependent on the concentration of the electron acceptor. In the high-concentration regime, inhibition is less pronounced, consistent with the predicted effects on the proposed branching kinetic scheme. Photodiode array analysis of the absorption spectrum of TMADH during steady-state turnover at high TMA concentrations reveals that one-electron reduced TMADH-possessing the anionic flavin semiquinone-is the predominant species. Conversely, at low concentrations of TMA, the enzyme is predominantly in the oxidized form during steady-state turnover. The data, together with evidence derived from enzyme-monitored turnover experiments performed at different concentrations of TMA, establish the operation of the branched kinetic scheme in steady-state reactions. With dimethylbutylamine (DMButA) as substrate, the partitioning between the 0/2 and 1/3 redox cycles is poised more toward the 0/2 cycle at all DMButA concentrations studied-an observation that is consistent with the inability of DMButA to act as an effective inhibitor of TMADH.

The role of Tyr-169 of trimethylamine dehydrogenase in substrate oxidation and magnetic interaction between FMN cofactor and the 4Fe/4S center

Tyr-169 in trimethylamine dehydrogenase is one component of a triad also comprising residues His-172 and Asp-267. Its role in catalysis and in mediating the magnetic interaction between FMN cofactor and the 4Fe/4S center have been investigated by stopped-flow and EPR spectroscopy of a Tyr-169 to Phe (Y169F) mutant of the enzyme. Tyr-169 is shown to play an important role in catalysis (mutation to phenylalanine reduces the limiting rate constant for bleaching of the active site flavin by about 100-fold) but does not serve as a general base in the course of catalysis. In addition, we are able to resolve two kinetically influential ionizations involved in both the reaction of free enzyme with free substrate (as reflected in klim/Kd), and in the breakdown of the Eox.S complex (as reflected in klim). In EPR studies of the Y169F mutant, it is found that the ability of the Y169F enzyme to form the spin-interacting state between flavin semiquinone and reduced 4Fe/4S center characteristic of wild-type enzyme is significantly compromised. The present results are consistent with Tyr-169 representing the ionizable group of pKa approximately 9.5, previously identified in pH-jump studies of electron transfer, whose deprotonation must occur for the spin-interacting state to be established.

Monomeric sarcosine oxidase: structure of a covalently flavinylated amine oxidizing enzyme

BACKGROUND

Monomeric sarcosine oxidases (MSOXs) are among the simplest members of a recently recognized family of eukaryotic and prokaryotic enzymes that catalyze similar oxidative reactions with various secondary or tertiary amino acids and contain covalently bound flavins. Other members of this family include heterotetrameric sarcosine oxidase, N-methyltryptophan oxidase and pipecolate oxidase. Mammalian sarcosine dehydrogenase and dimethylglycine dehydrogenase may be more distantly related family members.

RESULTS

The X-ray crystal structure of MSOX from Bacillus sp. B-0618, expressed in Escherichia coli, has been solved at 2.0 A resolution by multiwavelength anomalous dispersion (MAD) from crystals of the selenomethionine-substituted enzyme. Fourteen selenium sites, belonging to two MSOX molecules in the asymmetric unit, were used for MAD phasing and to define the local twofold symmetry axis for electron-density averaging. The structures of the native enzyme and of two enzyme-inhibitor complexes were also determined.

CONCLUSIONS

MSOX is a two-domain protein with an overall topology most similar to that of D-amino acid oxidase, with which it shares 14% sequence identity. The flavin ring is located in a very basic environment, making contact with sidechains of arginine, lysine, histidine and the N-terminal end of a helix dipole. The flavin is covalently attached through an 8alpha-S-cysteinyl linkage to Cys315 of the catalytic domain. Covalent attachment is probably self-catalyzed through interactions with the positive sidechains and the helix dipole. Substrate binding is probably stabilized by hydrogen bonds between the substrate carboxylate and two basic sidechains, Arg52 and Lys348, located above the re face of the flavin ring.

Covalent attachment of flavin adenine dinucleotide (FAD) and flavin mononucleotide (FMN) to enzymes: the current state of affairs

The first identified covalent flavoprotein, a component of mammalian succinate dehydrogenase, was reported 42 years ago. Since that time, more than 20 covalent flavoenzymes have been described, each possessing one of five modes of FAD or FMN linkage to protein. Despite the early identification of covalent flavoproteins, the mechanisms of covalent bond formation and the roles of the covalent links are only recently being appreciated. The main focus of this review is, therefore, one of mechanism and function, in addition to surveying the types of linkage observed and the methods employed for their identification. Case studies are presented for a variety of covalent flavoenzymes, from which general findings are beginning to emerge.

Involvement of a flavin iminoquinone methide in the formation of 6-hydroxyflavin mononucleotide in trimethylamine dehydrogenase: a rationale for the existence of 8alpha-methyl and C6-linked covalent flavoproteins

In trimethylamine dehydrogenase, substrate is bound in the active site via cation-pi bonding to three aromatic residues (Tyr-60, Trp-264, and Trp-355). Mutation of one of these residues (Trp-355 --> Leu, mutant W355L) influences the chemistry of the flavin mononucleotide in the active site, enabling derivatization to 6-hydroxy-FMN. The W355L mutant is purified as a mixture of deflavo, natural 6-S-cysteinyl-FMN, and inactive 6-hydroxy-FMN forms, and the enzyme is severely compromised in its ability to oxidatively demethylate trimethylamine. Analysis of samples of the native and recombinant wild-type trimethylamine dehydrogenases also revealed the presence of 6-hydroxy-FMN, but at much reduced levels compared with that of the W355L enzyme. Unlike that for a C30A mutant of trimethylamine dehydrogenase, addition of substrate to the W355L trimethylamine dehydrogenase is not required for the production of 6-hydroxy-FMN. A mechanism is proposed for the 6-hydroxylation of FMN in trimethylamine dehydrogenase that involves an electrophilic flavin iminoquinone methide. The proposed mechanism involving the flavin iminoquinone methide could apply to the flavinylation of trimethylamine dehydrogenase at the C6 position but also to the flavinylation of enzymes via the 8alpha position, thus providing a rationale for the evolution of covalent flavoproteins in general. Covalent linkage at C6 or the 8alpha-methyl prevents 6-hydroxylation by direct modification at the C6 atom or by preventing formation of the flavin iminoquinone methide, respectively.

Selective modification of alkylammonium ion specificity in trimethylamine dehydrogenase by the rational engineering of cation-pi bonding

In trimethylamine dehydrogenase (TMADH), substrate is bound in the active site by organic cation-pi bonding mediated by residues Tyr-60, Trp-264, and Trp-355. In the closely related dimethylamine dehydrogenase (DMADH), modeling suggests that a mixture of cation-pi bonding and conventional hydrogen bonding is responsible for binding dimethylamine. The active sites of both enzymes are highly conserved, but three changes in amino acid identity (residues Tyr-60 --> Gln, Ser-74 --> Thr, and Trp-105 --> Phe, TMADH numbering) were identified as probable determinants for tertiary --> secondary alkylammonium ion specificity. In an attempt to switch the substrate specificity of TMADH so that the enzyme operates more efficiently with dimethylamine, three mutant proteins of TMADH were isolated. The mutant forms contained either a single mutation (Y60Q), double mutation (Y60Q x S74T) or triple mutation (Y60Q x S74T x W105F). A kinetic analysis in the steady state with trimethylamine and dimethylamine as substrate indicated that the specificity of the triple mutant was switched approximately 90,000-fold in favor of dimethylamine. The major component of this switch in specificity is a selective impairment of the catalytic efficiency of the enzyme with trimethylamine. Rapid-scanning and single wavelength stopped-flow spectroscopic studies revealed that the major effects of the mutations are on the rate of flavin reduction and the dissociation constant for substrate when trimethylamine is used as substrate. With dimethylamine as substrate, the rate constants for flavin reduction and the dissociation constants for substrate are not substantially affected in the mutant enzymes compared with wild-type TMADH. The results indicate a selective modification of the substrate-binding site in TMADH (that impairs catalysis with trimethylamine but not with dimethylamine) is responsible for the switch in substrate specificity displayed by the mutant enzymes.

An ultracentrifugal approach to quantitative characterization of the molecular assembly of a physiological electron-transfer complex: the interaction of electron-transferring flavoprotein with trimethylamine dehydrogenase

The interaction between two physiological redox partners, trimethylamine dehydrogenase and electron-transferring flavoprotein, has been characterized quantitatively by analytical ultracentrifugation at 4 degrees C. Analysis of sedimentation-equilibrium distributions obtained at 15 000 rpm for mixtures in 10 mM potassium phosphate, pH 7.5, by means of the psi function [Wills, P. R., Jacobsen, M. P. & Winzor, D. J. (1996) Biopolymers 38, 119-130] has yielded an intrinsic dissociation constant of 3-7 microM for the interaction of electron-transferring flavoprotein with two equivalent and independent sites on the homodimeric enzyme. This investigation indicates the potential of sedimentation equilibrium for the quantitative characterization of interactions between dissimilar macromolecules.

An exposed tyrosine on the surface of trimethylamine dehydrogenase facilitates electron transfer to electron transferring flavoprotein: kinetics of transfer in wild-type and mutant complexes

In wild-type trimethylamine dehydrogenase, tyrosine-442 is located at the center of a concave region on the surface of the enzyme that is proposed to form the docking site for the physiological redox acceptor, electron transferring flavoprotein. The intrinsic rate constant for electron transfer in the reoxidation of one-electron dithionite-reduced wild-type trimethylamine dehydrogenase (modified with phenylhydrazine) by electron transferring flavoprotein was investigated by stopped-flow spectroscopy. Analysis of the temperature dependence of the reaction rate by electron transfer theory yielded values for the reorganizational energy of 1.4 eV and the electronic coupling matrix element of 0.82 cm-1. The role played by residue Tyr-442 in facilitating reduction of ETF by TMADH was investigated by isolating three mutant forms of the enzyme in which Tyr-442 was exchanged for a phenylalanine, leucine, or glycine residue. Rates of electron transfer from these mutants of TMADH to ETF were investigated by stopped-flow spectroscopy. At 25 degrees C, modest reductions in rate were observed for the Y442F (1.4-fold) and Y442L (2.2-fold) mutant complexes, but a substantial decrease in rate (30.5-fold) and an elevated dissociation constant for the complex were seen for the Y442G mutant enzyme. Inspection of the crystal structure of wild-type TMADH reveals that Tyr-442 is positioned along one side of a small cavity on the surface of the enzyme: Val 344, located at the bottom of this cavity, is the closest surface residue to the 4Fe-4S center of TMADH and is likely to be positioned on a major electron transfer pathway to ETF. The reduced electron transfer rates in the mutant complexes are probably brought about by decreases in electronic coupling between the electron transfer donor and acceptor within the complex, either directly or indirectly due to unfavorable change in the orientation of the two proteins with respect to one another.

Covalent attachment of FAD derivatives to a fusion protein consisting of 6-hydroxy-D-nicotine oxidase and a mitochondrial presequence. Folding, enzyme activity, and import of the modified protein into yeast mitochondria

Autoflavinylation of 6-hydroxy-D-nicotine oxidase (6-HDNO) was successfully employed to modify the protein covalently with FAD derivatives. The model compounds N6-(2-aminoethyl)-FAD and N6-(6-carboxyhexyl)-FAD were spontaneously bound to a fusion protein consisting of the mitochondrial targeting sequence of Neurospora crassa F0-ATPase subunit 9 (Su9) attached to 6-HDNO. When translated in the rabbit reticulocyte lysate, Su9-6-HDNO was in the trypsin-sensitive apoenzyme form; when translated in the presence of flavins it adopted a trypsin-resistant conformation characteristic of the 6-HDNO holoenzyme. With flavin derivatives, Su9-6-HDNO exhibited approximately 50% of the 6-HDNO activity observed with FAD. The covalently modified Su9-6-HDNO was imported into Saccharomyces cerevisiae mitochondria with an efficiency equal to that of the apoenzyme. Apparently the increase in size and charge of the FAD moiety did not hamper translocation across the mitochondrial membranes. Yeast mutant ssc1-2 mitochondria deficient in mtHsp70 unfoldase activity imported the flavinylated Su9-6-HDNO protein. In mutant ssc1-3 mitochondria deficient in both mtHsp70 unfoldase and translocase activity Su9-6-HDNO was trapped as translocation intermediate; the Su9 presequence was passed to the matrix where it was proteolytically cleaved by the mitochondrial processing peptidase; (MPP); the translocation-arrested 6-HDNO moiety adopted a trypsin-sensitive conformation. Our results indicate that unfolding of the FAD-stabilized flavin-binding domain of 6-HDNO in passage through the mitochondrial general insertion pore does not require the activity of mtHsp70.

Reaction of the C30A mutant of trimethylamine dehydrogenase with diethylmethylamine

The role played by the 6-S-cysteinyl-FMN bond of trimethylamine dehydrogenase in the reductive half-reaction of the enzyme has been studied by following the reaction of the slow substrate diethylmethylamine with a C30A mutant of the enzyme lacking the covalent flavin attachment to the polypeptide. Removal of the 6-S-cysteinyl-FMN bond diminishes the limiting rate for the first of the three observed kinetic phases of the reaction by a factor of 6, but has no effect on the rate constants for the two subsequent kinetic phases. The flavin in the C30A enzyme recovered from the reaction of the C30A enzyme with excess substrate is found to have been converted to the 6-hydroxy derivative, rendering the enzyme inactive. The noncovalently bound FMN of the C30A mutant enzyme is also converted to 6-hydroxy-FMN and rendered inactive upon reduction with excess trimethylamine, but not by reduction with dithionite, even at high pH or in the presence of the effector tetramethylammonium chloride. These results suggest that one significant role of the 6-S-cysteinyl-FMN bond is to prevent the inactivation of the enzyme during catalysis. A reaction mechanism is proposed whereby OH- attacks C-6 of a flavin-substrate covalent adduct in the course of steady-state turnover to form 6-hydroxy-FMN.

Biogenesis of the covalently flavinylated mitochondrial enzyme dimethylglycine dehydrogenase

Rat dimethylglycine dehydrogenase (Me2GlyDH) was used as model protein to study the biogenesis of a covalently flavinylated mitochondrial enzyme. Here we show that: 1) enzymatically active holoenzyme correlated with trypsin resistance of the protein; 2) folding of the reticulocyte lysate-translated protein into the trypsin-resistant, holoenzyme form was a slow process that was stimulated by the presence of the flavin cofactor and was more efficient at 15 degrees C than at 30 degrees C; 3) the mitochondrial presequence reduced the extent but did not prevent holoenzyme formation; 4) covalent attachment of FAD to the Me2GlyDH apoenzyme proceeded spontaneously and did not require a mitochondrial protein factor; 5) in vitro only the precursor, but not the mature form, of the protein was imported into isolated rat liver mitochondria; in vivo, in stably transfected HepG2 cells, both the precursor and the mature form were imported into the organelle; 6) holoenzyme formation in the cytoplasm did not prevent the translocation of the proteins into the mitochondria in vivo; and 7) lack of vitamin B2 in the tissue culture medium resulted in a reduced recovery of the precursor and the mature form of Me2GlyDH from cell mitochondria, suggesting a decreased efficiency of mitochondrial protein import.

The cytochrome subunit is necessary for covalent FAD attachment to the flavoprotein subunit of p-cresol methylhydroxylase

When p-cresol methylhydroxylase (PCMH) is expressed in its natural host Pseudomonas putida, or when the genes of the alpha and beta subunits of the enzyme are expressed together in the heterologous host Escherichia coli, flavin-adenine dinucleotide (FAD) is covalently attached to Tyr384 of the alpha subunit and the correct alpha 2 beta 2 form of the enzyme is assembled. The apoflavoprotein has been expressed in E. coli in the absence of the beta cytochrome c subunit and purified. While noncovalent FAD binding to apoflavoprotein in the absence of the cytochrome subunit could not be directly demonstrated, circumstantial evidence suggests that this indeed occurs. Covalent flavinylation requires one molecule each of FAD and cytochrome for each flavoprotein subunit. The flavinylation process leads to the 2-electron-reduced form of covalently bound FAD, and the resulting alpha 2 beta 2 enzyme is identical to wild-type PCMH. This work presents clear evidence that covalent flavinylation occurs by a self-catalytic mechanism; an external enzyme or chaperon is not required, nor is prior chemical activation of FAD or of the protein. This work is the first to define the basic chemistry of covalent flavinylation of an enzyme to produce the normal, active species, and confirms a long standing, postulated chemical mechanism of this process. It also demonstrates, for the first time, the absolute requirement for a partner subunit in the post-translational modification of a protein. It is proposed that the covalent FAD bond to Tyr384 and the phenolic portion of this Tyr are part of the essential electron transfer path from FAD to heme.

The primary structure of Hyphomicrobium X dimethylamine dehydrogenase. Relationship to trimethylamine dehydrogenase and implications for substrate recognition

The gene encoding dimethylamine dehydrogenase from Hyphomicrobium X has been cloned and over-expressed in Escherichia coli. Using the chemically determined protein sequence, primers were designed to amplify DNA fragments encoding the proximal and distal parts of the gene. These fragments were used to synthesise two probes and the dmd gene was cloned as part of two BamHI fragments isolated from digested genomic DNA. The sequence of the complete open reading frame was determined on both strands and contained 2211 bp coding for a protein of 736 amino acids, including the N-terminal methionine residue that is removed when expressed in the native host. The molecular mass of the processed apoprotein predicted from the DNA sequence is 82,523 Da. Dimethylamine dehydrogenase is closely related to the trimethylamine dehydrogenase of Methylophilus methylotrophus W3A1 (63.5% identical) and other class I FMN-binding beta 8 alpha 8 barrel flavoproteins. Residues in the active site of trimethylamine dehydrogenase that are known, or implicated, to be important in catalysis are conserved in dimethylamine dehydrogenase. Sequence alignment of dimethylamine and trimethylamine dehydrogenases suggests that the specificity for secondary and tertiary amines resides in a single amino acid substitution in a substrate-binding aromatic bowl located in the active site of the enzymes.

The flavinylation reaction of trimethylamine dehydrogenase. Analysis by directed mutagenesis and electrospray mass spectrometry

The flavinylation reaction products of wild-type and mutant forms of trimethylamine dehydrogenases purified from Methylophilus methylotrophus (bacterium W3A1) and Escherichia coli were studied by electrospray mass spectrometry (ESMS). The ESMS analyses demonstrated for the first time that wild-type enzyme expressed in M. methylotrophus is predominantly in the holoenzyme form, although a small proportion is present as the deflavo enzyme. ESMS demonstrated that the deflavo forms of the recombinant wild-type and mutant enzymes are not post-translationally modified and therefore prevented from assembling with flavin mononucleotide (FMN) because of previously unrecognized modifications. The data suggest that the higher proportion of deflavo enzyme observed for the recombinant wild-type enzyme is a consequence of the higher expression levels in E. coli. Mutagenesis of the putative flavinylation base (His-29 to Gln-29) did not prevent flavinylation, but the relative proportion of flavinylated product was substantially less than that seen for the recombinant wild-type enzyme. No flavinylation products were observed for a double mutant (His-29 to Cys-29; Cys-30 to His-30), in which the positions of the putative flavinylation base and cysteine nucleophile were exchanged. Taken together, the data indicate that the assembly of trimethylamine dehydrogenase with FMN occurs during the folding of the enzyme, and in the fully folded form, deflavo enzyme is unable to recognize FMN. Results of site-directed mutagenesis experiments in the FMN-binding site suggest that following mutation the affinity for FMN during the folding process is reduced. Consequently, in the folded mutant enzymes, less flavin is trapped in the active site, and reduced levels of flavinylated product are obtained.

On the lack of coordination between protein folding and flavin insertion in Escherichia coli for flavocytochrome b2 mutant forms Y254L and D282N

Wild-type flavocytochrome b2 (L-lactate dehydrogenase) from Saccharomyces cerevisiae, as well as a number of its point mutants, can be expressed to a reasonable level as recombinant proteins in Escherichia coli (20-25 mg per liter culture) with a full complement of prosthetic groups. At the same expression level, active-site mutants Y254L and D282N, on the other hand, were obtained with an FMN/heme ratio significantly less than unity, which could not be raised by addition of free FMN. Evidence is provided that the flavin deficit is due to incomplete prosthetic group incorporation during biosynthesis. Flavin-free and holo-forms for both mutants could be separated on a Blue-Trisacryl M column. The far-UV CD spectra of the two forms of each mutant protein were very similar to one another and to that of the wild-type enzyme, suggesting the existence of only local conformational differences between the active holo-enzymes and the nonreconstitutable flavin-free forms. Selective proteolysis with chymotrypsin attacked the same bond for the two mutant holo-enzymes as in the wild-type one, in the protease-sensitive loop. In contrast, for the flavin-free forms of both mutants, cleavage occurred at more than a single bond. Identification of the cleaved bonds suggested that the structural differences between the mutant flavin-free and holo-forms are located mostly at the C-terminal end of the barrel, which carries the prosthetic group and the active site. Altogether, these findings suggest that the two mutations induce an alteration of the protein-folding process during biosynthesis in E. coli; as a result, the synchrony between folding and flavin insertion is lost. Finally, a preliminary kinetic characterization of the mutant holo-forms showed the Km value for lactate to be little affected; kcat values fell by a factor of about 70 for the D282N mutant and of more than 500 for the Y254L mutant, compared to the wild-type enzyme.