Reaction of enzyme-bound 5-deazaflavin with peroxides. Pyrimidine ring contraction via an epoxide intermediate

Reaction of peroxides with 5-deazaflavin bound to glucose oxidase, lactate oxidase, or D-amino acid oxidase results in the formation of 5-deazaflavin 4a, 5-epoxide. The reaction of D-amino acid oxidase with m-chloroperoxybenzoate is an exception since the reagent reacts rapidly with the protein moiety to form m-chlorobenzoate which then binds noncovalently near the unmodified coenzyme. Epoxide bound to glucose oxidase is converted to deazaFAD X X in a reaction similar to that observed previously with oxynitrilase and glycolate oxidase. With lactate oxidase the epoxide is quite stable in the absence of light. With D-amino acid oxidase, denaturation of the protein is accompanied by the release of the epoxide into solution where it decomposes in a manner similar to that observed with model epoxide compounds at neutral pH. Reaction of deazaFAD X X with phosphodiesterase and alkaline phosphatase yields deazariboflavin X X. The same compound has been formed in model studies by exposing 5-deazariboflavin 4a,5-epoxide to alkaline conditions. Structural studies indicate that this reaction involves contraction of the pyrimidine ring to yield 4-ribityl-6,7-dimethyloxazolo[ 4,5-b ]quinolin-2(4H)-one. Model reaction studies are consistent with a mechanism initiated by alkaline hydrolysis of the pyrimidine ring at position 4 followed by two additional steps which proceed at neutral pH. A similar mechanism for the enzyme reactions appears likely since analogous intermediates are detected in the glycolate oxidase and the model reactions. The results suggest that position 4 of the coenzyme in oxynitrilase, glycolate oxidase, and glucose oxidase must be accessible to solvent and that the protein moiety must facilitate the initial hydrolysis of the pyrimidine ring since the enzyme reactions occur at neutral pH. Failure to observe formation of deazaFMN X X with lactate oxidase is attributed, at least in part, to the inaccessibility of the pyrimidine ring to solvent.     

NMR studies on p-hydroxybenzoate hydroxylase from Pseudomonas fluorescens and salicylate hydroxylase from Pseudomonas putida

p-Hydroxybenzoate hydroxylase from Pseudomonas fluorescens and salicylate hydroxylase from Pseudomonas putida have been reconstituted with 13C- and 15N-enriched FAD. The protein preparations were studied by 13C-NMR, 15N-NMR and 31P-NMR techniques in the oxidized and in the two-electron-reduced states. The chemical shift values are compared with those of free flavin in water or chloroform. It is shown that the pi electron distribution in oxidized free p-hydroxybenzoate hydroxylase is comparable to free flavin in water, and it is therefore suggested that the flavin ring is solvent accessible. Addition of substrate has a strong effect on several resonances, e.g. C2 and N5, which indicates that the flavin ring becomes shielded from solvent and also that a conformational change occurs involving the positive pole of an alpha-helix microdipole. In the reduced state, the flavin in p-hydroxybenzoate hydroxylase is bound in the anionic form, i.e. carrying a negative charge at N1. The flavin is bound in a more planar configuration than when free in solution. Upon binding of substrate the resonances of N1, C10a and N10 shift upfield. It is suggested that these upfield shifts are the result of a conformational change similar, but not identical, to the one observed in the oxidized state. The 13C chemical shifts of FAD bound to apo(salicylate hydroxylase) indicate that in the oxidized state the flavin ring is also fairly solvent accessible in the free enzyme. Addition of substrate has a strong effect on the hydrogen bond formed with O4 alpha. It is suggested that this is due to the exclusion of water from the active site by the binding of substrate. In the reduced state, the flavin is anionic. Addition of substrate forces the flavin ring to adopt a more planar configuration, i.e. a sp2-hybridized N5 atom and a slightly sp3-hybridized N10 atom. The NMR results are discussed in relation to the reaction catalyzed by the enzymes.     

NikD, an unusual amino acid oxidase essential for nikkomycin biosynthesis: structures of closed and open forms at 1.15 and 1.90 A resolution

NikD is an unusual amino-acid-oxidizing enzyme that contains covalently bound FAD, catalyzes a 4-electron oxidation of piperideine-2-carboxylic acid to picolinate, and plays a critical role in the biosynthesis of nikkomycin antibiotics. Crystal structures of closed and open forms of nikD, a two-domain enzyme, have been determined to resolutions of 1.15 and 1.9 A, respectively. The two forms differ by an 11 degrees rotation of the catalytic domain with respect to the FAD-binding domain. The active site is inaccessible to solvent in the closed form; an endogenous ligand, believed to be picolinate, is bound close to and parallel with the flavin ring, an orientation compatible with redox catalysis. The active site is solvent accessible in the open form, but the picolinate ligand is approximately perpendicular to the flavin ring and a tryptophan is stacked above the flavin ring. NikD also contains a mobile cation binding loop.     

Nuclear magnetic resonance studies of the old yellow enzyme. 2. 13C NMR of the enzyme recombined with 13C-labeled flavin mononucleotides

The apoenzyme of NADPH oxidoreductase, 'old yellow enzyme', was reconstituted with selectively 13C-enriched flavin mononucleotides and investigated by 13C NMR spectroscopy. The 13C NMR results confirm the results obtained by 15N NMR spectroscopy and yield additional information about the coenzyme-apoenzyme interaction. A strong deshielding of the C(2) and C(4) atoms of enzyme-bound FMN both in the oxidized and reduced state is observed, which is supposed to be induced by hydrogen-bond formation between the protein and the two carbonyl groups at C(2) and C(4) of the isoalloxazine ring system. The chemical shifts of all 13C resonances of the flavin in the two-electron-reduced state indicate that the N(5) atom is sp3-hybridized. From 31P NMR measurements it is concluded that the FMN phosphate group is not accessible to bulk solvent. The unusual 31P chemical shift of FMN in old yellow enzyme seems to indicate a different binding mode of the FMN phosphate group in this enzyme as compared to the flavodoxins. The 13C and 15N NMR data on the old-yellow-enzyme--phenolate complexes show that the atoms of the phenolate are more deshielded whereas the atoms of the enzyme-bound isoalloxazine ring are more shielded upon complexation. A non-linear correlation exists between the chemical shifts of the N(5) and the N(10) atoms and the pKa value of the phenolate derivative bound to the protein. Since the chemical shifts of N(5), N(10) and C(4a) are influenced most on complexation it is suggested that the phenolate is bound near the pyrazine ring of the isoalloxazine system. 15N NMR studies on the complex between FMN and 2-aminobenzoic acid indicate that the structure of this complex differs from that of the old-yellow-enzyme--phenolate complexes.     

FAD analogues as prosthetic groups of human glutathione reductase. Properties of the modified enzyme species and comparisons with the active site structure

Human glutathione reductase (NADPH + GSSG + H+ in equilibrium with NADP+ + 2 GSH) is a suitable enzyme for correlating spectroscopic properties and chemical reactivities of protein-bound FAD analogues with structural data. FAD, the prosthetic group of the enzyme, was replaced by FAD analogues, which were modified at the positions 8, 1, 2, 4, 5 and 6, respectively, of the isoalloxazine ring. When compared with a value of 100% for native glutathione reductase, the specific activities of most enzyme species ranged from 40% to 17%, in the order of the prosthetic groups 8-mercapto-FAD greater than 8-azido-FAD = 8-F-FAD = 8-C1-FAD greater than 4-thio-FAD = 1-deaza-FAD greater than 2-thio-FAD. The enzymic activities indicate a correct orientation of the bound analogues. The enzyme species containing 5-deaza-FAD and 6-OH-FAD, respectively, had no more glutathione reductase activity than the FAD-free apoenzyme. 5-Deaza-FAD X glutathione reductase was crystallized for X-ray diffraction analysis. Detailed studies were focussed on position 8 of the flavin. 8-Cl-FAD X glutathione reductase and 8-F-FAD X glutathione reductase reacted only poorly with HS- to give 8-mercapto-FAD X glutathione reductase, which suggests that the region around Val61 hinders the halogen anion from leaving the tetrahedral intermediate. Other experiments showed that position 8 is accessible to certain solvent-borne reagents. 8-Mercapto-FAD X glutathione reductase, for instance, reacted readily and stoichiometrically with the thiol reagent methylmethanethiosulfonate. 8-Mercapto-FAD X glutathione reductase does not exhibit a long wavelength charge transfer absorption band upon reduction, as it is the case for the 2-electron-reduced FAD-containing enzyme. This behaviour indicates that the charge transfer interaction between flavin and the thiolate of Cys63 in the native enzyme is not per se essential for catalysis. The absorption spectrum of the blue anionic 8-mercapto-FAD bound to glutathione reductase suggests that the protein concurs to the stabilization of a negative charge in the pyrimidine subnucleus. In light of the protein structure this effect is attributed to the dipole moment of alpha-helix 338-354 which starts out close to the N(1)/C(2)/O(2 alpha) region of the flavin. 1-Deaza-FAD binds as tightly as FAD to the apoenzyme. The resulting holoenzyme was found to be enzymically active but structurally unstable. In this respect 1-deaza-FAD . glutathione reductase mimics the properties of the enzyme species found in inborn glutathione reductase deficiency.(ABSTRACT TRUNCATED AT 400 WORDS)     

Properties of rabbit liver glutathione reductase reconstituted with FAD analogs

The FAD binding site of rabbit liver glutathione reductase has been explored by reconstitution of the apoprotein with several FAD analogs modified in the isoalloxazine ring. The apoglutathione reductase binds the p-quinoid form of 8-mercapto-FAD, suggesting that the protein stabilizes a negative charge in the -N1-C2 = O position of the pyrimidine subnucleus. The main absorption peak in the visible spectrum of the 8-mercapto-FAD-enzyme is at 585 nm; treatment of the reconstituted protein with reducing agents of disulfide groups induces a reversible hypochromic shift of 20 nm of the peak. Thus, in 8-mercapto-FAD-glutathione reductase, the oxidation-reduction state of the active center disulfide can be monitored. The chemical reactivity toward methylmethanethiosulfonate and iodoacetamide of the 8-mercapto-FAD-enzyme shows that the flavin position 8 is freely accessible to solvent. However, position 2 is buried within the protein molecule as judged from the lack of reactivity of the 2-thio-FAD-enzyme with methylmethanethiosulfonate. Hydrogen peroxide reacts slowly with both 2-thio-FAD-enzyme and native glutathione reductase, yielding inactive enzyme with a modified spectrum; the prosthetic group is still protein bound. Differences in the active site of the rabbit liver enzyme compared to the human erythrocyte glutathione reductase are evidenced by use of FAD analogs: the peaks of reconstituted liver enzymes are shifted about 10 nm toward longer wavelengths.     

Resonance Raman study on the flavin in the purple intermediates of D-amino acid oxidase

Resonance Raman (RR) spectra were measured for the purple intermediates of D-amino acid oxidase reconstituted with isotopically labelled FAD's, i.e., [4a-13C]-, [4,10a-13C2]-, [2-13C]-, [5-15N]-, and [1,3-15N2]flavin adenine dinucleotides, and compared with those with the native enzyme. The RR lines around 1605 cm-1 with D-alanine or D-proline as a substrate and at 1548 cm-1 with D-alanine undergo isotopic shifts upon [4a-13C]- and [4,10a-13C2]-labelling. These lines are assigned to the vibrational modes associated with C(10a) = C(4a) - C(4) = O moiety of reduced flavin, providing the first assignment of RR lines of reduced flavin and conclusive evidence that reduced flavin is involved in this intermediate.     

Purification and some properties of cholesterol oxidase from Schizophyllum commune with covalently bound flavin.

Cholesterol oxidase [EC 1.1.3.6] from Schizophyllum commune was purified by an affinity chromatography using 3-O-succinylcholesterol-ethylenediamine (3-cholesteryl-3-[2-aminoethylamido]propionate) Sepharose gels. The resulting preparation was homogeneous as judged by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis. The molecular weight of the enzyme was estimated to be 53,000 by SDS-gel electrophoresis and 46,000 by sedimentation equilibrium. The enzyme contained 483 amino acid residues as calculated on the basis of the molecular weight of 53,000. The enzyme consumed 60 mumol of O2/min per mg of protein with 1.3 mM cholesterol at 37 degrees C. The enzyme showed the highest activity with cholesterol; 3 beta-hydroxysteroids, such as dehydroepiandrosterone, pregnenolone, and lanosterol, were also oxidized at slower rates. Ergosterol was not oxidized by the enzyme. The Km for cholesterol was 0.33 mM and the optimal pH was 5.0. The enzyme is a flavoprotein which shows a visible absorption spectrum having peaks at 353 nm and 455 nm in 0.1 M acetate buffer, pH 4.0. The spectrum was characterized by the hypsochromic shift of the second absorption peak of the bound flavin. The bound flavin was reduced on anaerobic addition of a model substrate, dehydroepiandrosterone. Neither acid not heat treatment released the flavin coenzyme from the enzyme protein. The flavin of the enzyme could be easily released from the enzyme protein in acid-soluble form as flavin peptides when the enzyme protein was digested with trypsin plus chymotrypsin. The mobilities of the aminoacyl flavin after hydrolysis of the flavin peptides on thin layer chromatography and high voltage electrophoresis differed from those of free FAD, FMN, and riboflavin. A pKa value of 5.1 was obtained from pH-dependent fluorescence quenching process of the aminoacyl flavin. AMP was detected by hydrolysis of the flavin peptides with nucleotide pyrophosphatase. The results indicate strongly that cholesterol oxidase from Schizophyllum commune contains FAD as the prothetic group, which is covalently linked to the enzyme protein. The properties of the bound FAD were comparable to those of N (1)-histidyl FAD.     

Protein dynamics control proton transfers to the substrate on the His72Asn mutant of p-hydroxybenzoate hydroxylase

p-Hydroxybenzoate hydroxylase (PHBH) hydroxylates activated benzoates using NADPH as a reductant and O(2) as an oxygenating substrate. Because the flavin, when reduced, will quickly react with oxygen in either the presence or absence of a phenolic substrate, it is important to regulate flavin reduction to prevent the uncontrolled reaction of NADPH and oxygen to form H(2)O(2). Reduction is controlled by the protonation state of the aromatic substrate p-hydroxybenzoate (pOHB), which when ionized to the phenolate facilitates the movement of flavin between two conformations, termed "in" and "out". When the hydrogen bond network that provides communication between the substrate and solvent is disrupted by changing its terminal residue, His72, to Asn, protons from solution no longer equilibrate rapidly with pOHB bound to the active site [Palfey, B. A., Moran, G. R., Entsch, B., Ballou, D. P., and Massey, V. (1999) Biochemistry 38, 1153-1158]. Thus, one population of the His72Asn enzyme reduces rapidly and has the phenolate form of pOHB bound at the active site and the flavin in the out conformation. The remaining population of the His72Asn enzyme reduces slowly and has the phenolic form of pOHB bound and the flavin in the in conformation. We have investigated the mechanisms of proton transfer between solvent and pOHB bound to the His72Asn form of the enzyme by double-mixing and single-mixing stopped-flow experiments. We find that, depending on the initial ionization state of bound pOHB and the new pH of the solution, the ionization/protonation of pOHB proceeds through the direct reaction of hydronium or hydroxide with the enzyme-ligand complex and leads to the conversion of one flavin conformation to the other. Our kinetic data indicate that the enzyme with the flavin in the in conformation reacts in two steps. Inspection of crystal structures suggests that the hydroxide ion would react at the re-face of the flavin, and its reaction with pOHB is limited by the movement of Pro293, a conserved residue in similar flavoprotein hydroxylases. We hypothesize that this type of breathing mode by the protein may have been used to compensate for the lack of an efficient proton-transfer network in ancestral hydroxylases, permitting useful catalysis prior to the emergence of specialized proton-transfer mechanisms.     

A resonance Raman study on a reaction intermediate of Pseudomonas L-phenylalanine oxidase (deaminating and decarboxylating).

Resonance Raman (RR) spectra of purple intermediates of L-phenylalanine oxidase (PAO) with non-labeled and isotopically labeled phenylalanines as substrates, i.e., [1-13C], [2-13C], [ring-U-13C6], and [15N]phenylalanines, were measured with excitation at 632.8 nm within the broad absorption band around 540 nm. The spectra obtained resemble those of purple intermediates of D-amino acid oxidase (DAO). The isotope effects on the 1,665 cm-1 band with [15N] or [2-13C]phenylalanine indicate that the band is due to the C = N stretching mode of an imino acid derived from phenylalanine, i.e., alpha-imino-beta-phenylpropionate. The intense band at 1,389 cm-1 is contributed to by the CO2- symmetric stretching and C-CO2- stretching modes of alpha-imino-beta-phenylpropionate. The 1,602 cm-1 band, which does not shift upon isotopic substitution of phenylalanine, corresponds to the 1,605 cm-1 band of DAO purple intermediates and was assigned to a vibrational mode associated with the C(10a) = C(4a) - C(4) = O moiety of reduced flavin. These results confirm that PAO purple intermediates consist of the reduced enzyme and an imino acid derived from a substrate, and suggest that the plane defined by C(10a) = C(4a) - C(4) = O of reduced flavin and the plane containing H2+N = C - CO2- of an imino acid are arranged in close contact to each other, generating a charge-transfer interaction.     

Structure of the oxidized long-chain flavodoxin from Anabaena 7120 at 2 A resolution.

The structure of the long-chain flavodoxin from the photosynthetic cyanobacterium Anabaena 7120 has been determined at 2 A resolution by the molecular replacement method using the atomic coordinates of the long-chain flavodoxin from Anacystis nidulans. The structure of a third long-chain flavodoxin from Chondrus crispus has recently been reported. Crystals of oxidized A. 7120 flavodoxin belong to the monoclinic space group P2(1) with a = 48.0, b = 32.0, c = 51.6 A, and beta = 92 degrees, and one molecule in the asymmetric unit. The 2 A intensity data were collected with oscillation films at the CHESS synchrotron source and processed to yield 9,795 independent intensities with Rmerg of 0.07. Of these, 8,493 reflections had I > 2 sigma and were used in the analysis. The model obtained by molecular replacement was initially refined by simulated annealing using the XPLOR program. Repeated refitting into omit maps and several rounds of conjugate gradient refinement led to an R-value of 0.185 for a model containing atoms for protein residues 2-169, flavin mononucleotide (FMN), and 104 solvent molecules. The FMN shows many interactions with the protein with the isoalloxazine ring, ribityl sugar, and the 5'-phosphate. The flavin ring has its pyrimidine end buried into the protein, and the functional dimethyl benzene edge is accessible to solvent. The FMN interactions in all three long-chain structures are similar except for the O4' of the ribityl chain, which interacts with the hydroxyl group of Thr 88 side chain in A. 7120, while with a water molecule in the other two. The phosphate group interacts with the atoms of the 9-15 loop as well as with NE1 of Trp 57. The N5 atom of flavin interacts with the amide NH of Ile 59 in A. 7120, whereas in A. nidulans it interacts with the amide NH of Val 59 in a similar manner. In C. crispus flavodoxin, N5 forms a hydrogen bond with the side chain hydroxyl group of the equivalent Thr 58. The hydrogen bond distances to the backbone NH groups in the first two flavodoxins are 3.6 A and 3.5 A, respectively, whereas in the third flavodoxin the distance is 3.1 A, close to the normal value. Even though the hydrogen bond distances are long in the first two cases, still they might have significant energy because their microenvironment in the protein is not accessible to solvent.(ABSTRACT TRUNCATED AT 400 WORDS)     

Structure of the sodium borohydride-reduced N-(cyclopropyl)glycine adduct of the flavoenzyme monomeric sarcosine oxidase

Monomeric sarcosine oxidase (MSOX) is a flavoprotein that contains covalently bound FAD [8a-(S-cysteinyl)FAD] and catalyzes the oxidation of sarcosine (N-methylglycine) and other secondary amino acids, such as l-proline. Our previous studies showed that N-(cyclopropyl)glycine (CPG) acts as a mechanism-based inactivator of MSOX [Zhao, G., et al. (2000) Biochemistry 39, 14341-14347]. The reaction results in the formation of a modified reduced flavin that can be further reduced and stabilized by treatment with sodium borohydride. The borohydride-reduced CPG-modified enzyme exhibits a mass increase of 63 +/- 2 Da as compared with native MSOX. The crystal structure of the modified enzyme, solved at 1.85 A resolution, shows that FAD is the only site of modification. The modified FAD contains a fused five-membered ring, linking the C(4a) and N(5) atoms of the flavin ring, with an additional oxygen atom bound to the carbon atom attached to N(5) and a tetrahedral carbon atom at flavin C(4) with a hydroxyl group attached to C(4). On the basis of the crystal structure of the borohydride-stabilized adduct, we conclude that the labile CPG-modified flavin is a 4a,5-dihydroflavin derivative with a substituent derived from the cleavage of the cyclopropyl ring in CPG. The results are consistent with CPG-mediated inactivation in a reaction initiated by single electron transfer from the amine function in CPG to FAD in MSOX, followed by collapse of the radical pair to yield a covalently modified 4a,5-dihydroflavin.     

Rates of oxygen and hydrogen exchange as indicators of TPQ cofactor orientation in amine oxidases.

This study presents the first detailed examination by resonance Raman (RR) spectroscopy of the rates of solvent exchange for the C5 and C3 positions of the TPQ cofactor in several wild-type copper-containing amine oxidases and mutants of the amine oxidase from Hansenula polymorpha (HPAO). On the basis of crystal structure analysis and differing rates of C5 [double bond] O and C3 [bond] H exchange within the enzyme systems, but equally rapid rates of C5 [double bond] O and C3 [bond] H exchange in a TPQ model compound, it is proposed that these data can be used to determine the TPQ cofactor orientation within the active site of the resting enzyme. A rapid rate of C5 [double bond] O exchange (t(1/2) < 30 min) and a slow (t(1/2) = 6 h) to nonexistent rate of C3 [bond] H exchange was observed for wild-type HPAO, the amine oxidase from Arthrobacter globiformis, pea seedling amine oxidase at pH 7.1, and the E406Q mutant of HPAO. This pattern is ascribed to a productive TPQ orientation, with the C5 [double bond] O near the substrate-binding site and the C3 [bond] H near the Cu. In contrast, a slow rate of C5 [double bond] O exchange (t(1/2) = 1.6-3.3 h) coupled with a fast rate of C3 [bond] H exchange (t(1/2) < 30 min) was observed for the D319E and D319N catalytic base mutants of HPAO and for PSAO at pH 4.6 (t(1/2) = 4.5 h for C5 [double bond] O exchange). This pattern identifies a flipped orientation, involving 180 degrees rotation about the C alpha-C beta bond, which locates the C3 [bond] H near the substrate-binding site and the C5 double bond] O near the Cu. Finally, fast rates of both C5 [double bond] O and C3 [bond] H exchange (t(1/2) < 30 min) were observed for the amine oxidase from Escherichia coli and the N404A mutant of HPAO, suggesting a mobile cofactor, with multiple TPQ orientations between productive and flipped. These results demonstrate that opposing sides of the TPQ ring possess different degrees of solvent accessibility and that the rates of C5 [double bond] O and C3 [bond] H exchange can be used to predict the TPQ cofactor orientation in the resting forms of these enzymes.     

Reactions of anthranilate hydroxylase with salicylate, a nonhydroxylated substrate analogue. Steady state and rapid reaction kinetics

Steady state and rapid reaction kinetics of the flavoprotein anthranilate hydroxylase (EC 1.14.12.2) have been examined with the nonhydroxylated substrate analogue, salicylate. Since the reaction with salicylate does not involve events in which aromatic substrate is oxygenated, it provides a simpler model for studying the hysteresis exhibited by this enzyme. It is shown that the first turnover of the enzyme is slower than subsequent turnovers owing in part to slow initial binding reactions of salicylate with the enzyme. The reductive half-reaction of the first turnover is also slow since rapid reduction of the enzyme flavin requires bound aromatic substrate. The oxidative half-reaction involves reaction of the reduced enzyme-salicylate complex with oxygen to form a flavin C4a-hydroperoxide, which then decays to oxidized flavoenzyme and H2O2. Several lines of evidence indicate that salicylate remains bound to the enzyme at the end of the catalytic cycle so that in turnovers subsequent to the first, the slow steps involving salicylate binding are avoided.     

Three-dimensional structure of the flavoenzyme acyl-CoA oxidase-II from rat liver, the peroxisomal counterpart of mitochondrial acyl-CoA dehydrogenase

Acyl-CoA oxidase (ACO) catalyzes the first and rate-determining step of the peroxisomal beta-oxidation of fatty acids. The crystal structure of ACO-II, which is one of two forms of rat liver ACO (ACO-I and ACO-II), has been solved and refined to an R-factor of 20.6% at 2.2-A resolution. The enzyme is a homodimer, and the polypeptide chain of the subunit is folded into the N-terminal alpha-domain, beta-domain, and C-terminal alpha-domain. The X-ray analysis showed that the overall folding of ACO-II less C-terminal 221 residues is similar to that of medium-chain acyl-CoA dehydrogenase (MCAD). However, the N-terminal alpha- and beta-domains rotate by 13 with respect to the C-terminal alpha-domain compared with those in MCAD to give a long and large crevice that accommodates the cofactor FAD and the substrate acyl-CoA. FAD is bound to the crevice between the beta- and C-terminal domains with its adenosine diphosphate portion interacting extensively with the other subunit of the molecule. The flavin ring of FAD resides at the active site with its si-face attached to the beta-domain, and is surrounded by active-site residues in a mode similar to that found in MCAD. However, the residues have weak interactions with the flavin ring due to the loss of some of the important hydrogen bonds with the flavin ring found in MCAD. The catalytic residue Glu421 in the C-terminal alpha-domain seems to be too far away from the flavin ring to abstract the alpha-proton of the substrate acyl-CoA, suggesting that the C-terminal domain moves to close the active site upon substrate binding. The pyrimidine moiety of flavin is exposed to the solvent and can readily be attacked by molecular oxygen, while that in MCAD is protected from the solvent. The crevice for binding the fatty acyl chain is 28 A long and 6 A wide, large enough to accommodate the C23 acyl chain.     

Studies on the biosynthesis of coenzyme F420 in methanogenic bacteria

Coenzyme F₄₂₀ is a 8-hydroxy-5-deazaflavin present in methanogenic bacteria. We have investigated whether the pyrimidine ring of the deazaflavin originates from guanine as in flavin biosynthesis, in which the pyrimidine ring of guanine is conserved. For this purpose the incorporation of [2-¹⁴C]guanine and of [8-¹⁴C]guanine into F₄₂₀ by growing cultures of Methanobacterium thermoautotrophicum was studied. Only in the case of [2-¹⁴C]guanine did F₄₂₀ become labeled. The specific radioactivity of the deazaflavin and of guanine isolated from nucleic acids of [2-¹⁴C]guanine grown cells were identical. This finding suggests that the pyrimidine ring of the deazaflavin and of flavins are synthesized by the same pathway.F₄₂₀ did not become labeled when M. thermoautotrophicum was grown in the presence of methyl-[¹⁴C] methionine, [U-¹⁴C]phenylalanine or [U-¹⁴C]tyrosine. This excludes that C-5 of the deazaflavin is derived from the methyl group of methionine and that the benzene ring comes from phenylalanine or tyrosine.     

Observations on the biosynthesis of thiamine in yeast

1. Methods are described for the isolation of radioactively pure thiamine from yeast and its degradation on a small scale to its cyclic components. 2. A degradation of the pyrimidine ring and a thin-layer method for the separation of thiamine, its derivatives and pyrimidine and thiazole residues are described. 3. [(14)C]Formate is more effectively incorporated into the pyrimidine residue than into the thiazole residue, whereas the reverse is true with l-[Me-(14)C]methionine. 4. Experiments with [Me-(14)C,(35)S]methionine demonstrate that methionine provides an intact unit for the biosynthesis of the thiazole ring. 5. [6-(14)C]Orotic acid is insignificantly incorporated into the pyrimidine residue of thiamine. 6. Experiments with [1-(14)C]- and [2-(14)C]-acetate indicate that it is incorporated as a unit into the thiazole residue, but that only C-2 is incorporated into the pyrimidine residue. 7. l-[U-(14)C]Alanine is also effectively incorporated into the thiazole residue. 8. These results are discussed in relation to possible pathways of biosynthesis of the two ring components of the thiamine molecule.     

Hydrogen peroxide elimination from C4a-hydroperoxyflavin in a flavoprotein oxidase occurs through a single proton transfer from flavin N5 to a peroxide leaving group

C4a-hydroperoxyflavin is found commonly in the reactions of flavin-dependent monooxygenases, in which it plays a key role as an intermediate that incorporates an oxygen atom into substrates. Only recently has evidence for its involvement in the reactions of flavoprotein oxidases been reported. Previous studies of pyranose 2-oxidase (P2O), an enzyme catalyzing the oxidation of pyranoses using oxygen as an electron acceptor to generate oxidized sugars and hydrogen peroxide (H(2)O(2)), have shown that C4a-hydroperoxyflavin forms in P2O reactions before it eliminates H(2)O(2) as a product (Sucharitakul, J., Prongjit, M., Haltrich, D., and Chaiyen, P. (2008) Biochemistry 47, 8485-8490). In this report, the solvent kinetic isotope effects (SKIE) on the reaction of reduced P2O with oxygen were investigated using transient kinetics. Our results showed that D(2)O has a negligible effect on the formation of C4a-hydroperoxyflavin. The ensuing step of H(2)O(2) elimination from C4a-hydroperoxyflavin was shown to be modulated by an SKIE of 2.8 ± 0.2, and a proton inventory analysis of this step indicates a linear plot. These data suggest that a single-proton transfer process causes SKIE at the H(2)O(2) elimination step. Double and single mixing stopped-flow experiments performed in H(2)O buffer revealed that reduced flavin specifically labeled with deuterium at the flavin N5 position generated kinetic isotope effects similar to those found with experiments performed with the enzyme pre-equilibrated in D(2)O buffer. This suggests that the proton at the flavin N5 position is responsible for the SKIE and is the proton-in-flight that is transferred during the transition state. The mechanism of H(2)O(2) elimination from C4a-hydroperoxyflavin is consistent with a single proton transfer from the flavin N5 to the peroxide leaving group, possibly via the formation of an intramolecular hydrogen bridge.     

EPR, ENDOR, and TRIPLE resonance spectroscopy on the neutral flavin radical in Escherichia coli DNA photolyase

Ultraviolet radiation promotes the formation of a cyclobutane ring between adjacent pyrimidine residues on the same DNA strand to form a pyrimidine dimer. Such dimers may be restored to their monomeric forms through the action of a light-absorbing enzyme named DNA photolyase. The redox-active cofactor involved in the light-induced electron transfer reactions of DNA repair and enzyme photoactivation is a noncovalently bound FAD. In this paper, the FAD cofactor of Escherichia coli DNA photolyase was characterized as the neutral flavin semiquinone by EPR spectroscopy at 9.68 and 94.5 GHz. From the high-frequency/high-field EPR spectrum, the principal values of the axially symmetric g-matrix of FADH(*) were extracted. Both EPR spectra show an emerging hyperfine splitting of 0.85 mT that could be assigned to the isotropic hyperfine coupling constant (hfc) of the proton at N(5). To obtain more information about the electron spin density distribution ENDOR and TRIPLE resonance spectroscopies were applied. All major proton hfc's could be measured and unambiguously assigned to molecular positions at the isoalloxazin moiety of FAD. The isotropic hfc's of the protons at C(8alpha) and C(6) are among the smallest values reported for protein-bound neutral flavin semiquinones so far, suggesting a highly restricted delocalization of the unpaired electron spin on the isoalloxazin moiety. Two further hfc's have been detected and assigned to the inequivalent protons at C(1'). Some conclusions about the geometrical arrangement of the ribityl side chain with respect to the isoalloxazin ring could be drawn: Assuming tetrahedral angles at C(1') the dihedral angle between the C(1')-C(2') bond and the 2p(z)() orbital at N(10) has been estimated to be 170.4 degrees +/- 1 degrees.