Sedimentation behavior of native and reduced apolipoprotein A-II from human high density lipoproteins

HDL: bridging past and present with a look at the future

Clinical and epidemiological studies have shown that HDLs, a class of plasma lipoproteins, heterogeneous in size and density, have an atheroprotective role attributed, for years, to their capacity to promote the efflux of cholesterol from activated cholesterol-loaded arterial macrophages. Recent studies, however, have recognized that the physical heterogeneity of HDLs is associated with multiple functions that involve both the protein and the lipid components of these particles. ApoA-I, quantitatively the major protein constituent, has an amphipathic structure suited for transport of lipids. It readily interacts with the ATP-binding cassette transporter ABCA1, the SR-B1 scavenger receptor; activates the enzyme lecithin-cholesterol acyl transferase (LCAT), which is critical for HDL maturation. It also has antioxidant and antiinflammatory properties, along with the HDL-associated enzymes paraoxonase, platelet activating factor acetylhydrolase (PAF), and glutathione peroxidase. Regarding the lipid moiety, an atheroprotective role has been recognized for lysosphingolipids, particularly sphingosine-1-phosphate (S1P). All of these atheroprotective functions are lost in the post-translational dependent dysfunctional plasma HDLs of subjects with systemic inflammation, coronary heart disease, diabetes, and chronic renal disease. The emerging notion that particle quality has more predictive power than quantity has stimulated further exploration of the HDL proteome, already revealing unsuspected pro- or antiatherogenic proteins/peptides associated with HDL.

Characterization and mechanistic studies of type II isopentenyl diphosphate:dimethylallyl diphosphate isomerase from Staphylococcus aureus

The recently identified type II isopentenyl diphosphate (IPP):dimethylallyl diphosphate (DMAPP) isomerase (IDI-2) is a flavoenzyme that requires FMN and NAD(P)H for activity. IDI-2 is an essential enzyme for the biosynthesis of isoprenoids in several pathogenic bacteria including Staphylococcus aureus, Streptococcus pneumoniae, and Enterococcus faecalis, and thus is considered as a potential new drug target to battle bacterial infections. One notable feature of the IDI-2 reaction is that there is no net change in redox state between the substrate (IPP) and product (DMAPP), indicating that the FMN cofactor must start and finish each catalytic cycle in the same redox state. Here, we report the characterization and initial mechanistic studies of the S. aureus IDI-2. The steady-state kinetic analyses under aerobic and anaerobic conditions show that FMN must be reduced to be catalytically active and the overall IDI-2 reaction is O2-sensitive. Interestingly, our results demonstrate that NADPH is needed only in catalytic amounts to activate the enzyme for multiple turnovers of IPP to DMAPP. The hydride transfer from NAD(P)H to reduce FMN is determined to be pro-S stereospecific. Photoreduction and oxidation-reduction potential studies reveal that the S. aureus IDI-2 can stabilize significant amounts of the neutral FMN semiquinone. In addition, reconstitution of apo-IDI-2 with 5-deazaFMN resulted in a dead enzyme, whereas reconstitution with 1-deazaFMN led to the full recovery of enzyme activity. Taken together, these studies appear to support a catalytic mechanism in which the reduced flavin coenzyme mediates a single electron transfer to and from the IPP substrate during catalysis.

Aspartate 120 of Escherichia coli methylenetetrahydrofolate reductase: evidence for major roles in folate binding and catalysis and a minor role in flavin reactivity

Escherichia coli methylenetetrahydrofolate reductase (MTHFR) catalyzes the NADH-linked reduction of 5,10-methylenetetrahydrofolate (CH(2)-H(4)folate) to 5-methyltetrahydrofolate (CH(3)-H(4)folate) using flavin adenine dinucleotide (FAD) as cofactor. MTHFR is unusual among flavin oxidoreductases because it contains a conserved, negatively rather than positively charged amino acid (aspartate 120) near the N1-C2=O position of the flavin. At this location, Asp 120 is expected to influence the redox properties of the enzyme-bound FAD. Modeling of the CH(3)-H(4)folate product into the enzyme active site suggests that Asp 120 may also play crucial roles in folate binding and catalysis. We have replaced Asp 120 with Asn, Ser, Ala, Val, and Lys and have characterized the mutant enzymes. Consistent with a loss of negative charge near the flavin, the midpoint potentials of the mutants increased from 17 to 30 mV. A small kinetic effect on the NADH reductive half-reaction was also observed as the mutants exhibited a 1.2-1.5-fold faster reduction rate than the wild-type enzyme. Catalytic efficiency (k(cat)/K(m)) in the CH(2)-H(4)folate oxidative half-reaction was decreased significantly (up to 70000-fold) and in a manner generally consistent with the negative charge density of position 120, supporting a major role for Asp 120 in electrostatic stabilization of the putative 5-iminium cation intermediate during catalysis. Asp 120 is also intimately involved in folate binding as increases in the apparent K(d) of up to 15-fold were obtained for the mutants. Examining the E(red) + CH(2)-H(4)folate reaction at 4 degrees C, we obtained, for the first time, evidence for the rapid formation of a reduced enzyme-folate complex with wild-type MTHFR. The more active Asp120Ala mutant, but not the severely impaired Asp120Lys mutant, demonstrated the species, suggesting a connection between the extent of complex formation and catalytic efficiency.

A study of the spectral and redox properties and covalent flavinylation of the flavoprotein component of p-cresol methylhydroxylase reconstituted with FAD analogues

The spectral and redox properties are described for the wild-type and Y384F mutant forms of the flavoprotein component (PchF) of flavocytochrome, p-cresol methylhydroxylase (PCMH), and cytochrome-free PchF that harbor FAD analogues. The analogues are iso-FAD (8-demethyl-6-methyl-FAD), 6-amino-FAD (6-NH(2)-FAD), 6-bromo-FAD (6-Br-FAD), 8-nor-8-chloro-FAD (8-Cl-FAD), and 5-deaza-5-carba-FAD (5-deaza-FAD). All of the analogues bound noncovalently and stoichiometrically to cytochrome-free apo-PchF, and the resulting holoproteins had high affinity for the cytochrome subunit, PchC. Noncovalently bound FAD, 6-Br-FAD, or 6-NH(2)-FAD can be induced to bind covalently by exposing holo-PchF to PchC. The rate of this process and the redox potential of the noncovalently bound flavin may be correlated. In addition, the redox potential of each FAD analogue was higher when it was covalently bound than when noncovalently bound to PchF. Furthermore, the potential of a covalently bound or noncovalently bound FAD analogue increased on association of the corresponding holo-PchF with PchC, and the activity increased as the flavin's redox potential increased. It was discovered also that 4-hydroxybenzaldehyde, the final p-cresol oxidation product, is an efficient competitive inhibitor for substrate oxidation by PchF since it binds tightly to this protein when the flavin is oxidized, although it binds more loosely to the enzyme with reduced flavin. Finally, the energies of the charge-transfer bands for the interaction of bound flavin analogues with 4-Br-phenol (a substrate mimic) increased as the potential decreases, although a simple global correlation was not seen. This is the case because the energy is also a function of the redox properties of the bound mimic. The implications of these findings to covalent flavinylation and catalysis are discussed.

Methylenetetrahydrofolate reductase from Escherichia coli: elucidation of the kinetic mechanism by steady-state and rapid-reaction studies

The flavoprotein methylenetetrahydrofolate reductase (MTHFR) from Escherichia coli catalyzes the reduction of 5,10-methylenetetrahydrofolate (CH(2)-H(4)folate) to 5-methyltetrahydrofolate (CH(3)-H(4)folate) using NADH as the source of reducing equivalents. The enzyme also catalyzes the transfer of reducing equivalents from NADH or CH(3)-H(4)folate to menadione, an artificial electron acceptor. Here, we have determined the midpoint potential of the enzyme-bound flavin to be -237 mV. We have examined the individual reductive and oxidative half-reactions constituting the enzyme's activities. In an anaerobic stopped-flow spectrophotometer, we have measured the rate constants of flavin reduction and oxidation occurring in each half-reaction and have compared these with the observed catalytic turnover numbers measured under steady-state conditions. We have shown that, in all cases, the half-reactions proceed at rates sufficiently fast to account for overall turnover, establishing that the enzyme is kinetically competent to catalyze these oxidoreductions by a ping-pong Bi-Bi mechanism. Reoxidation of the reduced flavin by CH(2)-H(4)folate is substantially rate limiting in the physiological NADH-CH(2)-H(4)folate oxidoreductase reaction. In the NADH-menadione oxidoreductase reaction, the reduction of the flavin by NADH is rate limiting as is the reduction of flavin by CH(3)-H(4)folate in the CH(3)-H(4)folate-menadione oxidoreductase reaction. We conclude that studies of individual half-reactions catalyzed by E. coli MTHFR may be used to probe mechanistic questions relevant to the overall oxidoreductase reactions.

Determination of the midpoint potential of the FAD and FMN flavin cofactors and of the 3Fe-4S cluster of glutamate synthase

Glutamate synthase is a complex iron-sulfur flavoprotein that catalyzes the reductive transfer of the L-glutamine amide group to C(2) of 2-oxoglutarate, forming two molecules of L-glutamate. The bacterial enzyme is an alphabeta protomer, which contains one FAD (on the beta subunit, approximately 50 kDa), one FMN (on the alpha subunit, approximately 150 kDa), and three different Fe-S clusters (one 3Fe-4S center on the alpha subunit and two 4Fe-4S clusters at an unknown location). To address the problem of the intramolecular electron pathway, we have measured the midpoint potential values of the flavin cofactors and of the 3Fe-4S cluster of glutamate synthase in the isolated alpha and beta subunits and in the alphabeta holoenzyme. No detectable amounts of flavin semiquinones were observed during reductive titrations of the enzyme, indicating that the midpoint potential value of each flavin(ox)/flavin(sq) couple is, in all cases, significantly more negative than that of the corresponding flavin(sq)/flavin(hq) couple. Association of the two subunits to form the alphabeta protomer does not alter significantly the midpoint potential value of the FMN cofactor and of the 3Fe-4S cluster (approximately -240 and -270 mV, respectively), but it makes that of FAD some 40 mV less negative (approximately -340 mV for the beta subunit and -300 mV for FAD bound to the holoenzyme). Binding of the nonreducible NADP(+) analogue, 3-aminopyridine adenine dinucleotide phosphate, made the measured midpoint potential value of the FAD cofactor approximately 30-40 mV less negative in the isolated beta subunit, but had no effect on the redox properties of the alphabeta holoenzyme. This result correlates with the formation of a stable charge-transfer complex between the reduced flavin and the oxidized pyridine nucleotide in the isolated beta subunit, but not in the alphabeta holoenzyme. Binding of L-methionine sulfone, a glutamine analogue, had no significant effect on the redox properties of the enzyme cofactors. On the contrary, 2-oxoglutarate made the measured midpoint potential value of the 3Fe-4S cluster approximately 20 mV more negative in the isolated alpha subunit, but up to 100 mV less negative in the alphabeta holoenzyme as compared to the values of the corresponding free enzyme forms. These findings are consistent with electron transfer from the entry site (FAD) to the exit site (FMN) through the 3Fe-4S center of the enzyme and the involvement of at least one of the two low-potential 4Fe-4S centers, which are present in the glutamate synthase holoenzyme, but not in the isolated subunits. Furthermore, the data demonstrate a specific role of 2-oxoglutarate in promoting electron transfer from FAD to the 3Fe-4S cluster of the glutamate synthase holoenzyme. The modulatory role of 2-oxoglutarate is indeed consistent with the recently determined three-dimensional structure of the glutamate synthase alpha subunit, in which several polypeptide stretches are suitably positioned to mediate communication between substrate binding sites and the enzyme redox centers (FMN and the 3Fe-4S cluster) to tightly control and coordinate the individual reaction steps [Binda, C., et al. (2000) Structure 8, 1299-1308].

Characterization of the FAD-containing N-methyltryptophan oxidase from Escherichia coli

N-Methyltryptophan oxidase (MTOX) is a flavoenzyme that catalyzes the oxidative demethylation of N-methyl-L-tryptophan and other N-methyl amino acids, including sarcosine, which is a poor substrate. The Escherichia coli gene encoding MTOX (solA) was isolated on the basis of its sequence homology with monomeric sarcosine oxidase, a sarcosine-inducible enzyme found in many bacteria. These studies show that MTOX is expressed as a constitutive enzyme in a wild-type E. coli K-12 strain, providing the first evidence that solA is a functional gene. MTOX expression is enhanced 3-fold by growth on minimal media but not induced by N-methyl-L-tryptophan, L-tryptophan, or 3-indoleacrylate. MTOX forms an anionic flavin semiquinone and a reversible, covalent flavin-sulfite complex (K(d) = 1.7 mM), properties characteristic of flavoprotein oxidases. Rates of formation (k(on) = 5.4 x 10(-3) M(-1) s(-1)) and dissociation (k(off) = 1.3 x 10(-5) s(-1)) of the MTOX-sulfite complex are orders of magnitude slower than observed with most other flavoprotein oxidases. The pK(a) for ionization of oxidized FAD at N(3)H in MTOX (8.36) is two pH units lower than that observed for free FAD. The MTOX active site was probed by characterization of various substrate analogues that act as competitive inhibitors with respect to N-methyl-L-tryptophan. Qualitatively similar perturbations of the MTOX visible absorption spectrum are observed for complexes formed with various aromatic carboxylates, including benzoate, 3-indole-(CH(2))(n)-CO(2)(-) and 2-indole-CO(2)(-). The most stable complex with 3-indole-(CH(2))(n)-CO(2)(-) is formed with 3-indolepropionate (K(d) = 0.79 mM), a derivative with the same side chain length as N-methyl-L-tryptophan. Benzoate binding is enhanced upon protonation of a group in the enzyme-benzoate complex (pK(EL) = 6.87) but blocked by ionization of a group in the free enzyme (pK(E) = 8.41), which is attributed to N(3)H of FAD. Difference spectra observed for the aromatic carboxylate complexes are virtually mirror images of those observed with sarcosine analogues (N,N'-dimethylglycine, N-benzylglycine). Charge-transfer complexes are formed with 3-indoleacrylate, pyrrole-2-carboxylate, and CH(3)XCH(2)CO(2)(-) (X = S, Se, Te).

Monomeric sarcosine oxidase: 1. Flavin reactivity and active site binding determinants

Monomeric sarcosine oxidase (MSOX) is an inducible bacterial flavoenzyme that catalyzes the oxidative demethylation of sarcosine (N-methylglycine) and contains covalently bound FAD [8alpha-(S-cysteinyl)FAD]. This paper describes the spectroscopic and thermodynamic properties of MSOX as well as the X-ray crystallographic characterization of three new enzyme.inhibitor complexes. MSOX stabilizes the anionic form of the oxidized flavin (pK(a) = 8.3 versus 10.4 with free FAD), forms a thermodynamically stable flavin radical, and stabilizes the anionic form of the radical (pK(a) < 6 versus pK(a) = 8.3 with free FAD). MSOX forms a covalent flavin.sulfite complex, but there appears to be a significant kinetic barrier against complex formation. Active site binding determinants were probed in thermodynamic studies with various substrate analogues whose binding was found to perturb the flavin absorption spectrum and inhibit MSOX activity. The carboxyl group of sarcosine is essential for binding since none is observed with simple amines. The amino group of sarcosine is not essential, but binding affinity depends on the nature of the substitution (CH(3)XCH(2)CO(2)(-), X = CH(2) < O < S < Se < Te), an effect which has been attributed to differences in the strength of donor-pi interactions. MSOX probably binds the zwitterionic form of sarcosine, as judged by the spectrally similar complexes formed with dimethylthioacetate [(CH(3))(2)S(+)CH(2)CO(2)(-)] and dimethylglycine (K(d) = 20.5 and 17.4 mM, respectively) and by the crystal structure of the latter. The methyl group of sarcosine is not essential but does contribute to binding affinity. The methyl group contribution varied from -3.79 to -0.65 kcal/mol with CH(3)XCH(2)CO(2)(-) depending on the nature of the heteroatom (NH(2)(+) > O > S) and appeared to be inversely correlated with heteroatom electron density. Charge-transfer complexes are formed with MSOX and CH(3)XCH(2)CO(2)(-) when X = S, Se, or Te. An excellent linear correlation is observed between the energy of the charge transfer bands and the one-electron reduction potentials of the ligands. The presence of a sulfur, selenium, or telurium atom identically positioned with respect to the flavin ring is confirmed by X-ray crystallography, although the increased atomic radius of S < Se < Te appears to simultaneously favor an alternate binding position for the heavier atoms. Although L-proline is a poor substrate, aromatic heterocyclic carboxylates containing a five-membered ring and various heteroatoms (X = NH, O, S) are good ligands (K(d, X=NH) = 1.37 mM) and form charge-transfer complexes with MSOX. The energy of the charge-transfer bands (S > O >> NH) is linearly correlated with the one-electron ionization potentials of the corresponding heterocyclic rings.

Modulation of the redox potential of the [Fe(SCys)(4)] site in rubredoxin by the orientation of a peptide dipole

Rubredoxins (Rds) may be separated into two classes based upon the correlation of their reduction potentials with the identity of residue 44; those with Ala44 have reduction potentials that are approximately 50 mV higher than those with Val44. The smaller side chain volume occupied by Ala44 relative to that occupied by Val44 has been proposed to explain the increase in the reduction potential, based upon changes in the Gly43-Ala44 peptide bond orientation and the distance to the [Fe(SCys)(4)] center in the Pyrococcus furiosus (Pf) Rd crystal structure compared to those of Gly43-Val44 in the Clostridium pasteurianum (Cp) Rd crystal structure. As an experimental test of this hypothesis, single-site Val44 <--> Ala44 exchange mutants, [V44A]Cp and [A44V]Pf Rds, have been cloned and expressed. Reduction potentials of these residue 44 variants and pertinent features of the X-ray crystal structure of [V44A]Cp Rd are reported. Relative to those of wild-type Cp and Pf Rds, the V44A mutation in Cp Rd results in an 86 mV increase in midpoint reduction potential and the [A44V] mutation in Pf Rd results in a 95 mV decrease in midpoint reduction potential, respectively. In the crystal structure of [V44A]Cp Rd, the peptide bond between residues 43 and 44 is approximately 0.3 A closer to the Fe center and the hydrogen bond distance between the residue 44 peptide nitrogen and the Cys42 gamma-sulfur decreases by 0.32 A compared to the analogous distances in the wild-type Cp Rd crystal structure. The results described herein support the prediction that the identity of residue 44 alone determines whether a Rd reduction potential of about -50 or 0 mV is observed.

pH-dependent spectroscopic changes associated with the hydroquinone of FMN in flavodoxins

Photoreduction with a 5-deazaflavin as the catalyst was used to convert flavodoxins from Desulfovibrio vulgaris, Megasphaera elsdenii, Anabaena PCC 7119, and Azotobacter vinelandii to their hydroquinone forms. The optical spectra of the fully reduced flavodoxins were found to vary with pH in the pH range of 5.0-8.5. The changes correspond to apparent pKa values of 6.5 and 5.8 for flavodoxins from D. vulgaris and M. elsdenii, respectively, values that are similar to the apparent pKa values reported earlier from the effects of pH on the redox potential for the semiquinone-hydroquinone couples of these two proteins (7 and 5.8, respectively). The changes in the spectra resemble those occurring with the free two-electron-reduced flavin for which the pKa is 6.7, but they are red-shifted compared with those of the free flavin. The optical changes occurring with flavodoxins from D. vulgaris and A. vinelandii flavodoxins are larger than those of free reduced FMN. The absorbance of the free and bound flavin increases in the region of 370-390 nm (Delta epsilon = 1-1.8 mM-1 cm-1) with increases of pH. Qualitatively similar pH-dependent changes occur when FMN in D. vulgaris flavodoxin is replaced by iso-FMN, and in the following mutants of D. vulgaris flavodoxin in which the residues mutated are close to the isoalloxazine of the bound flavin: D95A, D95E, D95A/D127A, W60A, Y98S, W60M/Y98W, S96R, and G61A. The 13C NMR spectrum of reduced D. vulgaris [2,4a-13C2]FMN flavodoxin shows two peaks. The peak due to C(4a) is unaffected by pH, but the peak due to C(2) broadens with decreasing pH; the apparent pKa for the change is 6.2. It is concluded that a decrease in pH induces a change in the electronic structure of the reduced flavin due to a change in the ionization state of the flavin, a change in the polarization of the flavin environment, a change in the hydrogen-bonding network around the flavin, and/or possibly a change in the bend along the N(5)-N(10) axis of the flavin. A change in the ionization state of the flavin is the simplest explanation, with the site of protonation differing from that of free FMNH-. The pH effect is unlikely to result from protonation of D95 or D127, the negatively charged amino acids closest to the flavin of D. vulgaris flavodoxin, because the optical changes observed with alanine mutants at these positions are similar to those occurring with the wild-type protein.

Egg white sulfhydryl oxidase: kinetic mechanism of the catalysis of disulfide bond formation

The flavin-dependent sulfhydryl oxidase from chicken egg white catalyzes the oxidation of sulfhydryl groups to disulfides with reduction of oxygen to hydrogen peroxide. The oxidase contains FAD and a redox-active cystine bridge and accepts a total of 4 electrons per active site. Dithiothreitol (DTT; the best low molecular weight substrate known) reduces the enzyme disulfide bridge with a limiting rate of 502/s at 4 degrees C, pH 7.5, yielding a thiolate-to-flavin charge-transfer complex. Further reduction to EH4 is limited by the slow internal transfer of reducing equivalents from enzyme dithiol to oxidized flavin (3.3/s). In the oxidative half of catalysis, oxygen rapidly converts EH4 to EH2, but Eox appearance is limited by the slow internal redox equilibration. During overall turnover with DTT, the thiolate-to-flavin charge-transfer complex accumulates with an apparent extinction coefficient of 4.9 mM-1 cm-1 at 560 nm. In contrast, glutathione (GSH) is a much slower reductant of the oxidase to the EH2 level and shows a kcat/Km 100-fold smaller than DTT. Full reduction of EH2 by GSH shows a limiting rate of 3.6/s at 4 degrees C comparable to that seen with DTT. Reduced RNase is an excellent substrate of the enzyme, with kcat/Km per thiol some 1000- and 10-fold better than GSH and DTT, respectively. Enzyme-monitored steady-state turnover shows that RNase is a facile reductant of the oxidase to the EH2 state. This work demonstrates the basic similarity in the mechanism of turnover between all of these three substrates. A physiological role for sulfhydryl oxidase in the formation of disulfide bonds in secreted proteins is discussed.

Porcine recombinant dihydropyrimidine dehydrogenase: comparison of the spectroscopic and catalytic properties of the wild-type and C671A mutant enzymes

Dihydropyrimidine dehydrogenase catalyzes, in the rate-limiting step of the pyrimidine degradation pathway, the NADPH-dependent reduction of uracil and thymine to dihydrouracil and dihydrothymine, respectively. The porcine enzyme is a homodimeric iron-sulfur flavoprotein (2 x 111 kDa). C671, the residue postulated to be in the uracil binding site and to act as the catalytically essential acidic residue of the enzyme oxidative half-reaction, was replaced by an alanyl residue. The mutant enzyme was overproduced in Escherichia coli DH5alpha cells, purified to homogeneity, and characterized in comparison with the wild-type species. An extinction coefficient of 74 mM-1 cm-1 was determined at 450 nm for the wild-type and mutant enzymes. Chemical analyses of the flavin, iron, and acid-labile sulfur content of the enzyme subunits revealed similar stoichiometries for wild-type and C671A dihydropyrimidine dehydrogenases. One FAD and one FMN per enzyme subunit were found. Approximately 16 iron atoms and 16 acid-labile sulfur atoms were found per wild-type and mutant enzyme subunit. The C671A dihydropyrimidine dehydrogenase mutant exhibited approximately 1% of the activity of the wild-type enzyme, thus preventing its steady-state kinetic analysis. Therefore, the ability of the C671A mutant and, for comparison, of the wild-type enzyme species to interact with reaction substrates, products, or their analogues were studied by absorption spectroscopy. Both enzyme forms did not react with sulfite. The wild-type and mutant enzymes were very similar to each other with respect to the spectral changes induced by binding of the reaction product NADP+ or of its nonreducible analogue 3-aminopyridine dinucleotide phosphate. Uracil also induced qualitatively and quantitatively similar absorbance changes in the visible region of the absorbance spectrum of the two enzyme forms. However, the calculated Kd of the enzyme-uracil complex was significantly higher for the C671A mutant (9.1 +/- 0.7 microM) than for the wild-type dihydropyrimidine dehydrogenase (0.7 +/- 0.09 microM). In line with these observations, the two enzyme forms behaved in a similar way when titrated anaerobically with a NADPH solution. Addition of an up to 10-fold excess of NADPH to both dihydropyrimidine dehydrogenase forms led to absorbance changes consistent with reduction of approximately 0.5 flavin per subunit, with no indication of reduction of the enzyme iron-sulfur clusters. Absorbance changes consistent with reduction of both enzyme flavins were obtained by removing NADP+ with a NADPH-regenerating system. On the contrary, the two enzyme species differed significantly with respect to their reactivity with dihydrouracil. Addition of dihydrouracil to the wild-type enzyme species, under anaerobic conditions, led to absorbance changes that could be interpreted to result from both partial flavin reduction and the formation of a complex between the enzyme and (dihydro)uracil. In contrast, only spectral changes consistent with formation of a complex between the oxidized enzyme and dihydrouracil were observed when a C671A mutant enzyme solution was titrated with this compound. Furthermore, enzyme-monitored turnover experiments were carried out anaerobically in the presence of a limiting amount of NADPH and excess uracil with the two enzyme forms in a stopped-flow apparatus. These experiments directly demonstrated that the substitution of an alanyl residue for C671 in dihydropyrimidine dehydrogenase specifically prevents enzyme-catalyzed reduction of uracil. Finally, sequence analysis of dihydropyrimidine dehydrogenase revealed that it exhibits a modular structure; the N-terminal region, similar to the beta subunit of bacterial glutamate synthases, is proposed to be responsible for NADPH binding and oxidation with reduction of the FAD cofactor of dihydropyrimidine dehydrogenase. The central region, similar to the FMN subunit of dihydroorotate dehydrogenases, is likely to harbor the site o

The mechanism of adenosylmethionine-dependent activation of methionine synthase: a rapid kinetic analysis of intermediates in reductive methylation of Cob(II)alamin enzyme

Cobalamin-dependent methionine synthase catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine, generating tetrahydrofolate and methionine. During this primary turnover cycle, the enzyme alternates between the active methylcobalamin and cob(I)alamin forms of the enzyme. Formation of the cob(II)alamin prosthetic group by oxidation of cob(I)alamin or photolysis of methylcobalamin renders the enzyme inactive. Methionine synthase from E. coli catalyzes its own reactivation by a reductive methylation that involves electron transfer from reduced flavodoxin and methyl transfer from AdoMet. This process has been proposed to involve formation of a transient cob(I)alamin intermediate that is then trapped by methyl transfer from AdoMet. During aerobic growth of E. coli, electrons for this process are ultimately derived from NADPH, and electron transfer does not generate a detectable level of cob(I)alamin due to the large potential difference between the NADPH/NADP+ couple and the cob(I)alamin/cob(II)alamin couple. In this paper, we show that even in the presence of the strong reductant flavodoxin hydroquinone, cob(I)alamin is not observed as a significant intermediate. We demonstrate, however, that this is due to a rate-limiting reorganization of the cobalt ligand environment from five-coordinate to four-coordinate cob(II)alamin. Mutation of aspartate 757 to glutamate results in a cob(II)alamin enzyme that is approximately 70% four-coordinate, and reductive methylation of this enzyme using flavodoxin hydroquinone as the electron donor proceeds through a kinetically competent cob(I)alamin intermediate. Furthermore, wild-type cob(I)alamin enzyme produced by chemical reduction reacts with AdoMet in a kinetically competent reaction. We provide evidence that methyl transfer from AdoMet to cob(I)alamin enzyme results initially in formation of a five-coordinate methylcobalamin enzyme that slowly decays to the active six-coordinate methylcobalamin enzyme. We propose a kinetic scheme for reductive methylation of wild-type cob(II)alamin enzyme by adenosylmethionine and flavodoxin hydroquinone in which slow conformational changes mask the relatively fast electron and methyl transfer steps.

Reaction of the NAD(P)H:flavin oxidoreductase from Escherichia coli with NADPH and riboflavin: identification of intermediates

Flavin reductase catalyzes the reduction of free flavins by NAD(P)H. As isolated, Escherichia coli flavin reductase does not contain any flavin prosthetic group but accommodates both the reduced pyridine nucleotide and the flavin substrate in a ternary complex prior to oxidoreduction. The reduction of riboflavin by NADPH catalyzed by flavin reductase has been studied by static and rapid kinetics absorption spectroscopies. Static absorption spectroscopy experiments revealed that, in the presence of riboflavin and reduced pyridine nucleotide, flavin reductase stabilizes, although to a small extent, a charge-transfer complex of NADP+ and reduced riboflavin. In addition, reduction of riboflavin was found to be essentially irreversible. Rapid kinetics absorption spectroscopy studies demonstrated the occurrence of two intermediates with long-wavelength absorption during the catalytic cycle. Such intermediate species exhibit spectroscopic properties similar to those of charge-transfer complexes of oxidized flavin and NAD(P)H, and reduced flavin and NAD(P)+, respectively, which have been identified as intermediates during the reaction of flavoenzymes of the ferredoxin-NADP+ reductase family. Thus, a minimal kinetic scheme for the reaction of flavin reductase with NADPH and riboflavin can be proposed. After formation of the Michaelis complex of flavin reductase with NADPH and riboflavin, a first intermediate, identified as a charge-transfer complex of NADPH and riboflavin, is formed. It is followed by a second charge-transfer intermediate of enzyme-bound NADP+ and reduced riboflavin. The latter decays, yielding the Michaelis complex of flavin reductase with NADP+ and reduced riboflavin, which then dissociates to complete the reaction. These results support the initial hypothesis of a structural similarity between flavin reductase and the enzymes of the ferredoxin-NADP+ reductase family and extend it at a functional level.

Oxidase activity of the acyl-CoA dehydrogenases

The medium chain acyl-CoA dehydrogenase catalyzes the flavin-dependent oxidation of a variety of acyl-CoA thioesters with the transfer of reducing equivalents to electron-transferring flavoprotein. The binding of normal substrates profoundly suppresses the reactivity of the reduced enzyme toward molecular oxygen, whereas the oxidase reaction becomes significant using thioesters such as indolepropionyl-CoA (IP-CoA) and 4-(dimethylamino)-3-phenylpropionyl-CoA (DP-CoA). Steady-state and stopped-flow studies with IP-CoA led to a kinetic model of the oxidase reaction in which only the free reduced enzyme reacts with oxygen (Johnson, J. K., Kumar, N. R., and Srivastava, D. K. (1994) Biochemistry 33, 4738-4744). We have tested their proposal with IP-CoA and DP-CoA. The dependence of the oxidase reaction on oxygen concentration is biphasic with a major low affinity phase incompatible with a model predicting a simple Km for oxygen of 3 microM. If only free reduced enzyme reacts with oxygen, increasing IP-CoA would show strong substrate inhibition because it binds tightly to the reduced enzyme. Experimentally, IP-CoA shows simple saturation kinetics. The Glu376-Gln mutant of the medium chain dehydrogenase allows the oxygen reactivity of complexes of the reduced enzyme with IP-CoA and the corresponding product indoleacryloyl-CoA (IA-CoA) to be characterized without the subsequent redox equilibration that complicates analysis of the oxidase kinetics of the native enzyme. In sum, these data suggest that when bulky, nonphysiological substrates are employed, multiple reduced enzyme species react with molecular oxygen. The relatively high oxidase activity of the short chain acyl-CoA dehydrogenase from the obligate anaerobe Megasphaera elsdenii was studied by rapid reaction kinetics of wild-type and the Glu367-Gln mutant using butyryl-, crotonyl-, and 2-aza-butyryl-CoA thioesters. In marked contrast to those of the mammalian dehydrogenase, complexes of the reduced bacterial enzyme with these ligands react with molecular oxygen at rates similar to those of the free protein. Evolutionary and mechanistic aspects of the suppression of oxygen reactivity in the acyl-CoA dehydrogenases are discussed.

Reductive and oxidative half-reactions of morphinone reductase from Pseudomonas putida M10: a kinetic and thermodynamic analysis

The reaction of morphinone reductase (MR) with the physiological reductant NADH and the oxidizing substrate codeinone has been studied by multiple and single wavelength stopped-flow spectroscopy. Reduction of the enzyme with NADH proceeds in two kinetically resolvable steps. In the first step, the oxidized enzyme forms a charge-transfer intermediate with NADH. The charge-transfer complex is characterized by an increase in absorbance at long wavelength (540 to 650 nm), and its rate of formation is dependent on substrate concentration and is controlled by a second-order rate constant of 4. 8 x 10(5) M-1 s-1 at pH 7.0 and 5 degrees C. In the second step, the enzyme-bound flavin is reduced to the dihydroflavin form. The rate of flavin reduction (23.4 s-1 at pH 7.0 and 5 degrees C) is independent of substrate concentration and is observed as a monophasic decrease in absorbance at 462 nm. The oxidative half-reaction proceeds in three kinetically resolvable steps. The first is due to the formation of a reduced enzyme-codeinone charge-transfer complex and is observed at long wavelength (about 650 nm). The rate of charge-transfer complex formation is dependent on codeinone concentration and is controlled by a second-order rate constant of 11.5 x 10(3) M-1 s-1 at pH 7.0 and 5 degrees C. The second step represents flavin reoxidation and is observed at 462 (absorption increase) and 650 nm (absorption decrease) and progresses with a rate (about 45 s-1) which is independent of codeinone concentration. The third step is observed as a further small increase in absorbance at 462 nm and proceeds with a rate of about 2.5 s-1. This step most likely represents hydrocodone release from the oxidized enzyme. Analysis of the temperature dependence of the reductive half-reaction has enabled calculation of the entropic and enthalpic contributions for charge-transfer formation, charge-transfer decay (yielding free enzyme and substrate), and electron transfer to the enzyme-bound FMN, and the construction of a partial energy profile for the reaction catalyzed by MR. The reaction scheme and redox properties of MR are compared with those described previously for the closely related flavoprotein, old yellow enzyme. Although common features are identified, there are notable differences in the kinetic and redox properties of the two enzymes.

S-Adenosylmethionine-dependent reduction of lysine 2,3-aminomutase and observation of the catalytically functional iron-sulfur centers by electron paramagnetic resonance

Lysine 2,3-aminomutase catalyzes the interconversion of l-alpha-lysine and l-beta-lysine. The enzyme contains an iron-sulfur cluster with unusual properties, and it requires pyridoxal-5'-phosphate (PLP) and S-adenosylmethionine (AdoMet) for activity. The reaction proceeds by a substrate radical rearrangement mechanism, in which the external aldimine formed between PLP and lysine is initially converted into a lysyl-radical intermediate by hydrogen abstraction from C3. The present research concerns the mechanism by which a hydrogen-abstracting species is generated at the active site of lysine 2,3-aminomutase. Earlier tritium tracer experiments have implicated the 5'-deoxyadenosyl moiety of AdoMet in this process. AdoMet is here shown to interact with the iron-sulfur cluster at the active site of Clostridial lysine 2,3-aminomutase. Reduction of the iron-sulfur cluster from its EPR-silent form [4Fe-4S]2+ to the fully reduced form [4Fe-4S]1+ requires the presence of either AdoMet or S-adenosylhomocysteine (SAH) and a strong reducing agent such as dithionite or deazariboflavin and light. The reduced forms are provisionally designated E-[4Fe-4S]1+/AdoMet and E-[4Fe-4S]1+/SAH, and they display similar low-temperature EPR spectra centered at gav = 1.91. The reduced form E-[4Fe-4S]1+/AdoMet is fully active in the absence of any added reducing agent, whereas the form E-[4Fe-4S]1+/SAH is not active. It is postulated that the active form E-[4Fe-4S]1+/AdoMet is in equilibrium with a low concentration of a radical-initiating form that contains the 5'-deoxyadenosyl radical. Initiation of the radical rearrangement mechanism is postulated to take place by action of the 5'-deoxyadenosyl radical in abstracting a hydrogen atom from carbon-3 of lysine, which is bound as its external aldiminine with PLP. This process accounts for the results of tritium tracer experiments, it explains the radical rearrangement mechanism, and it rationalizes the roles of AdoMet and the [4Fe-4S] cluster in the reaction.

The recombinant alpha subunit of glutamate synthase: spectroscopic and catalytic properties

As part of our studies of Azospirillum brasilense glutamate synthase, a complex iron-sulfur flavoprotein, we have overproduced the two enzyme subunits separately in Escherichia coli. The beta subunit (53.2 kDa) was demonstrated to contain the site of NADPH oxidation of glutamate synthase and the FAD cofactor, which was identified as Flavin 1 of glutamate synthase, the flavin located at the site of NADPH oxidation. We now report the overproduction of the glutamate synthase alpha subunit (162 kDa), which is purified to homogeneity in a stable form. This subunit contains FMN as the flavin cofactor which exhibits the properties of Flavin 2 of glutamate synthase: reactivity with sulfite to yield a flavin-N(5)-sulfite addition product (Kd = 2.6 +/- 0.22 mM), lack of reactivity with NADPH, reduction by L-glutamate, and reoxidation by 2-oxoglutarate and glutamine. Thus, FMN is the flavin located at the site of reduction of the iminoglutarate formed on the addition of glutamine amide group to the C(2) carbon of 2-oxoglutarate. The glutamate synthase alpha subunit contains the [3Fe-4S] cluster of glutamate synthase, as shown by low-temperature EPR spectroscopy experiments. The glutamate synthase alpha subunit catalyzes the synthesis of glutamate from L-glutamine and 2-oxoglutarate, provided that a reducing system (dithionite and methyl viologen) is present. The FMN moiety but not the [3Fe-4S] cluster of the subunit appears to participate in this reaction. Furthermore, the isolated alpha subunit of glutamate synthase exhibits a glutaminase activity, which is absent in the glutamate synthase holoenzyme. These findings support a model for glutamate synthase according to which the enzymes prepared from various sources share a common glutamate synthase function (the alpha subunit of the bacterial enzyme, or its homologous polypeptide forming the ferredoxin-dependent plant enzyme) but differ for the chosen electron donor. The pyridine nucleotide-dependent forms of the enzyme have recruited a FAD-dependent oxidoreductase (the bacterial beta subunit) to mediate electron transfer from the NAD(P)H substrate to the glutamate synthase polypeptide. However, it appears that the presence of the enzyme beta subunit and/or of the additional iron-sulfur clusters (Centers II and III) of the bacterial glutamate synthase is required for communication between Center I (the [3Fe-4S] center) and the FMN moiety within the alpha subunit, and for ensuring coupling of glutamine hydrolysis to the transfer of the released ammonia molecule to 2-oxoglutarate in the holoenzyme.

Redox potentials and quinone reductase activity of L-aspartate oxidase from Escherichia coli

l-Aspartate oxidase (EC 1.4.3.16) is a flavoprotein that catalyzes the first step in the de novobiosynthetic pathway to pyridine nucleotides both under aerobic and under anaerobic conditions. Despite the physiological importance of this biosynthesis particularly in facultative aerobic organisms, such as Escherichia coli, little is known about the electron acceptor of reduced L-aspartate oxidase in the absence of oxygen. In this report, evidence is presented which suggests that in vitro quinones can play such a role. L-Aspartate oxidase binds menadione and 2, 3-dimethoxy-5-methyl-p-benzoquinone with Kd values of 11.5 and 2.4 microM, respectively. A new L-aspartate:quinone oxidoreductase activity is described in the presence and in the absence of phospholipids, and its possible physiological relevance is discussed. Moreover, considering the striking sequence similarity between L-aspartate oxidase and the highly conserved family of succinate-fumarate oxidoreductases, the redox properties of L-aspartate oxidase were investigated in detail. A value of -216 mV was calculated for the midpoint potential of the couple FAD/FADH2 bound to the enzyme. This result perfectly explains why L-aspartate oxidase may be considered as a very particular fumarate reductase unable to use succinate as the electron donor.

Cobalamin-dependent methionine synthase from Escherichia coli: involvement of zinc in homocysteine activation

Methionine synthase (MetH) is a modular protein with at least four distinct regions; amino acids 2-353 comprise a region responsible for binding and activation of homocysteine, amino acids 345-649 are thought to be involved in the binding and activation of methyltetrahydrofolate, amino acids 650-896 are responsible for binding of the prosthetic group methylcobalamin, and amino acids 897-1227 are involved in binding adensylmethionine and are required for reductive activation of enzyme in the cob(II)alamin form. Previous studies have shown that mutations of Cys310 or Cys311 to either alanine or serine result in loss of all detectable catalytic activity. These mutant proteins retain the ability to catalyze methyl transfer from methyltetrahydrofolate to exogenous cob(I)alamin, but have lost the ability to transfer methyl groups from exogenous methylcobalamin to homocysteine [Goulding, C. W., Postigo, D., and Matthews, R. G. (1997) Biochemistry 36, 8082-8091]. We now demonstrate that both MetH holoenzyme and a truncated MetH(2-649) protein, which lacks a cobalamin prosthetic group, contain 0.9 equiv of zinc, while the Cys310Ser and Cys311Ser mutant proteins contain less than 0.05 equiv of zinc. Addition of l-homocysteine to MetH(2-649) is accompanied by release of 1 equiv of protons/mol of protein, while addition of l-homocysteine to the Cys310Ser and Cys311Ser mutant truncated proteins does not result in proton release. The Cys310Ala and Cys311Ala mutant methylcobalamin holoenzymes have completely lost the ability to transfer the methyl group from methylcobalamin to homocysteine, suggesting that zinc is required for this reaction. Further evidence that zinc is required for catalytic activity comes from experiments in which the zinc is removed from MetH(2-1227). Removal of zinc from methylated wild-type holoenzyme by treatment with methyl methanethiolsulfonate and then with dithiothreitol and EDTA results in loss of the ability of the protein to catalyze methyl transfer from methyltetrahydrofolate to homocysteine. Reconstitution of the zinc-depleted holoenzyme results in incorporation of 0.4 equiv of zinc/mol of protein and partial restoration of the ability of the protein to catalyze homocysteine methylation.

Flavin mononucleotide-binding domain of the flavoprotein component of the sulfite reductase from Escherichia coli

The flavoprotein component (SiR-FP) of the sulfite reductase from Escherichia coli is an octamer containing one FAD and one FMN as cofactors per polypeptide chain. We have constructed an expression vector containing the DNA fragment encoding for the FMN-binding domain of SiR-FP. The overexpressed protein (SiR-FP23) was purified as a partially flavin-depleted polymer. It could incorporate FMN exclusively upon flavin reconstitution to reach a maximum flavin content of 1.2 per polypeptide chain. Moreover, the protein could stabilize a neutral air-stable semiquinone radical over a wide range of pHs. During photoreduction, the flavin radical accumulated first, followed by the fully reduced state. The redox potentials, determined at room temperature [E'1 (FMNH./FMN) = -130 +/- 10 mV and E'2 (FMNH2/FMNH.) = -335 +/- 10 mV], were very close to those previously reported for Salmonella typhimurium SiR-FP [Ostrowski, J., Barber, M. J., Rueger, D. C., Miller, B. E., Siegel, L. M., & Kredich, N. M. (1989) J. Biol. Chem. 264, 15796-15808]. Both the radical and fully reduced forms of SiR-FP23 were able to transfer their electrons to cytochrome c quantitatively. Altogether, the results presented herein demonstrate that the N-terminal end of E. coli SiR-FP forms the FMN-binding domain. It folds independently, thus retaining the chemical properties of the bound FMN, and provides a good model of the FAD-depleted form of native SiR-FP. Moreover, the FMN prosthetic group in SiR-FP23 and native SiR-FP is compared to that of cytochrome P450 reductase and bacterial cytochrome P450, which also contain one FAD and one FMN per polypeptide chain.

Thermodynamics and reduction kinetics properties of 2-methyl-3-hydroxypyridine-5-carboxylic acid oxygenase

The investigation by absorbance and fluorescence rapid reaction spectrophotometry of the binding of the substrate MHPC (2-methyl-3-hydroxypyridine-5-carboxylic acid) or the substrate analog 5HN (5-hydroxynicotinic acid) to the flavoprotein MHPCO (2-methyl-3-hydroxypyridine-5-carboxylic acid oxygenase) shows that the binding proceeds in two steps. An enzyme-substrate complex initially formed is followed by a ligand-induced isomerization. This binding process is required for efficient reduction of the enzyme-bound flavin, as evidenced by the fact that MHPCO-substrate complexes can be reduced by NADH much faster than the enzyme alone. Since redox potential values of MHPCO and MHPCO-substrate complexes are the same, steric factors, such as the relative orientation of MHPC to the enzyme-bound flavin, are important for efficient hydride transfer to occur.

Kinetic characterization of wild-type and S229A mutant MurB: evidence for the role of Ser 229 as a general acid

X-ray derived structural data predicted that serine 229 was positioned to act as a proton donor to the developing C2 carbanion during the reduction of enolpyruvyl-UDP-N-acetylglucosamine catalyzed by the bacterial peptidoglycan biosynthetic flavoenzyme MurB. To investigate this effect, a mutant where serine 229 was replaced by alanine was constructed and purified. Kinetic analysis of the two half-reactions for the mutant enzyme revealed a 9-fold decrease in the reduction of EFlox by NADPH and a dramatic 10(7)-fold decrease in the reoxidation of EFlred with the enolpyruvyl substrate. In addition, studies of S229A with the substrate analog, (E)-enolbutyryl-UDP-N-acetylglucosamine, showed a striking bias of the partitioning toward formation of the (Z) geometric isomer as opposed to formation of the reduced product UDP-methylmuramic acid, which was the predominant product in wild-type MurB. These studies provide evidence for the proposed role of this active-site serine as a general acid catalyst.

4-Hydroxybutyryl-CoA dehydratase from Clostridium aminobutyricum: characterization of FAD and iron-sulfur clusters involved in an overall non-redox reaction

4-Hydroxybutyryl-CoA dehydratase catalyzes the reversible dehydration of 4-hydroxybutyryl-CoA to crotonyl-CoA, which involves cleavage of an unactivated beta-C-H bond. The enzyme also catalyzes the apparently irreversible isomerization of vinylacetyl-CoA to crotonyl-CoA. Addition of crotonyl-CoA to the dehydratase, which contains FAD as well as non-heme iron and acid labile sulfur, led to a decrease of the flavin absorbance at 438 nm and an increase in the region from 500 to 800 nm. The protein-bound FAD was easily reduced to the semiquinone (redox equilibration within seconds) and only slowly to the hydroquinone (redox equilibration minutes to hours): the redox potentials were not unusual for flavoproteins (Eox/sq = -140 +/- 15 mV and Esq/red = -240 +/- 15 mV; pH 7.0, 25 degrees C). There was no equilibration of electrons between the flavin and the Fe-S cluster, which was difficult to reduce. After extensive photoreduction, an EPR signal indicative of a [4Fe-4S]+ cluster was detected (g-values: 2.037, 1.895, 1.844). Upon exposure to air at 0 degrees C, the enzyme lost dehydration activity completely within 40 min, but isomerase activity dropped to about 40% of the initial value and persisted for more than a day. The properties of the protein-bound FAD are consistent with a mechanism involving transient one-electron oxidation of the substrate to activate the the beta-C-H bond. The putative [4Fe-4S]2+ cluster could serve a structural role and/or as Lewis acid facilitating the leaving of the hydroxyl group.

High- and low-temperature unfolding of human high-density apolipoprotein A-2

Human plasma apolipoprotein A-2 (apoA-2) is the second major protein of the high-density lipoproteins that mediate the transport and metabolism of cholesterol. Using CD spectroscopy and differential scanning calorimetry, we demonstrate that the structure of lipid-free apoA-2 in neutral low-salt solutions is most stable at approximately 25 degrees C and unfolds reversibly both upon heating and cooling from 25 degrees C. High-temperature unfolding of apoA-2, monitored by far-UV CD, extends from 25-85 degrees C with midpoint Th = 56 +/- 2 degrees C and vant Hoff's enthalpy delta H(Th) = 17 +/- 2 kcal/mol that is substantially lower than the expected enthalpy of melting of the alpha-helical structure. This suggests low-cooperativity apoA-2 unfolding. The apparent free energy of apoA-2 stabilization inferred from the CD analysis of the thermal unfolding, delta G(app)(25 degrees) = 0.82 +/- 0.15 kcal/mol, agrees with the value determined from chemical denaturation. Enhanced low-temperature stability of apoA-2 observed upon increase in Na2HPO4 concentration from 0.3 mM to 50 mM or addition of 10% glycerol may be linked to reduced water activity. The close proximity of the heat and cold unfolding transitions, that is consistent with low delta G(app)(25 degrees), indicates that lipid-free apoA-2 has a substantial hydrophobic core but is only marginally stable under near-physiological solvent conditions. This suggests that in vivo apoA-2 transfer is unlikely to proceed via the lipid-free state. Low delta H(Th) and low apparent delta Cp approximately 0.52 kcal/mol.K inferred from the far-UV CD analysis of apoA-2 unfolding, and absence of tertiary packing interactions involving Tyr groups suggested by near-UV CD, are consistent with a molten globular-like state of lipid-free apoA-2.

Kinetics of the reductive half-reaction of the iron-sulfur flavoenzyme CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase reductase

The conversion of CDP-4-keto-6-deoxy-D-glucose to CDP-4-keto-3,6-dideoxy-D-glucose is a key step in biosynthesis of ascarylose, the terminal dideoxyhexose of the O-antigen tetrasaccharide of the lipopolysaccharide from Yersinia pseudotuberculosis V. This transformation is catalyzed by two enzymes: CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase (E1), which contains a pyridoxamine and a [2Fe-2S] center, and an NADH-dependent CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase reductase (E3), which contains both an FAD and a [2Fe-2S] center. E1 reacts to form a Schiff base with CDP-4-keto-6-deoxy-D-glucose and catalyzes the elimination of the hydroxyl at position 3 of the glucose moiety, resulting in the formation of a covalently bound CDP-6-deoxy-delta(3,4)-glucoseen intermediate. E3 transfers electrons from NADH to E1, which uses these to reduce the delta(3,4)-glucoseen bond to produce CDP-4-keto-3,6-dideoxy-D-glucose. In this work, we have investigated the reductive half-reaction of E3 using both single wavelength and diode array stopped flow absorbance spectroscopy. We find that NADH binds to both oxidized (Kd = 52.5 +/- 2 microM) and two-electron-reduced (Kd = 12.1 +/- 1 microM) forms of E3. Hydride transfer from NADH to the FAD moiety occurs at 107.5 +/- 3 s-1 and exhibits a 10-fold deuterium isotope effect when (4R)-[2H]NADH is substituted for NADH. Following the hydride transfer reaction, NAD+ is released at 42.5 +/- 1 s-1 and electron transfer from the reduced FAD to the [2Fe-2S] center occurs rapidly. The extent of the intramolecular electron transfer reaction is pH-dependent with a pKa of 7.3 +/- 0.1, which may represent the ionization state of the N-1 position of the FAD hydroquinone of E3. Finally, E3 is converted to the three-electron-reduced state in a slow disproportionation reaction that consumes NADH: The [2Fe-2S] center of E3 was selectively disassembled by titration with mersalyl to give E3(apoFeS). The properties of this form of the enzyme are compared to those of the holoenzyme. Similarities and differences of the reductive half-reactions of E3 and related iron-sulfur flavoenzymes are discussed.

Complete coordination of the four Fe-S centers of the beta subunit from Escherichia coli nitrate reductase. Physiological, biochemical, and EPR characterization of site-directed mutants lacking the highest or lowest potential [4Fe-4S] clusters

The beta subunit of the nitrate reductase A from Escherichia coli contains four groups of cysteine residues (I-IV) which are thought to bind the four iron-sulfur centers (1-4) of the enzyme. The fourth Cys residue of each group was replaced by Ala by site-directed mutagenesis, which led to the C26A, C196A, C227A, and C263A mutants. Physiological and biochemical effects of the mutations were investigated on both the membrane-bound and the soluble forms of the enzyme. In addition, detailed redox titrations of the mutants were monitored by EPR spectroscopy. The C196A and C227A mutations resulted in the full loss of the four Fe-S clusters and of the Mo-cofactor, leading to inactive enzymes. In contrast, the C26A and C263A mutants retained significant nitrate reductase activities. The EPR analysis showed that the highest redox potential [4Fe-4S] cluster (center 1) was selectively removed by the C263A mutation and that the C26A replacement likely eliminated the lowest potential [4Fe-4S] cluster (center 4). In both mutants, the three remaining Fe-S clusters kept the same spectral and redox properties as in the wild type enzyme. These results enabled the determination of the Cys ligands of center 1 to be completed and led to a proposed model for the coordination of the four Fe-S centers by the four Cys groups of the beta subunit. In this model, the four clusters are organized in two pairs, (center 1, center 4) and (center 2, center 3), which is in good agreement with the magnitude of intercenter magnetic interactions observed by EPR and with the stability of the different mutants. The possible implications on the intramolecular electron transfer pathway are discussed.

Mutations in the B12-binding region of methionine synthase: how the protein controls methylcobalamin reactivity

Vitamin B12-dependent methionine synthase catalyzes the transfer of a methyl group from methyltetrahydrofolate to homocysteine via the enzyme-bound cofactor methylcobalamin. To carry out this reaction, the enzyme must alternately stabilize six-coordinate methylcobalamin and four-coordinate cob(I)alamin oxidation states. The lower axial ligand to the cobalt in free methylcobalamin is the dimethylbenzimidazole nucleotide substituent of the corrin ring; when methylcobalamin binds to methionine synthase, the ligand is replaced by histidine 759, which in turn is linked by hydrogen bonds to aspartate 757 and thence to serine 810. We have proposed that these residues control the reactivity of the enzyme-bound cofactor both by increasing the coordination strength of the imidazole ligand and by allowing stabilization of cob(I)alamin via protonation of the His-Asp-Ser triad. In this paper we report results of mutation studies focusing on these catalytic residues. We have used visible absorbance spectroscopy and electron paramagnetic resonance spectroscopy to probe the coordination state of the cofactor and have used stopped-flow kinetic measurements to explore the reactivity of each mutant. We show that mutation of histidine 759 blocks turnover, while mutations of aspartate 757 or serine 810 decrease the reactivity of the methylcobalamin cofactor. In contrast, we show that mutations of these same residues increase the rate of AdoMet-dependent reactivation of cob(II)alamin enzyme. We propose that the reaction with AdoMet proceeds via a different transition state than the reactions with homocysteine and methyltetrahydrofolate. These results provide a glimpse at how a protein can control the reactivity of methylcobalamin.

Interaction of apolipoprotein AII with the putative high-density lipoprotein receptor

There is strong evidence to indicate that binding of HDL by cells is due to recognition of apoproteins residing on the surface of the lipoprotein by the putative HDL receptor(s). Although both of the major HDL apoproteins, AI and AII, are recognized by the putative receptor, the nature of the binding interaction and the domains of the apoproteins involved are largely unknown. Previous data from this laboratory led to the proposal of a model to explain how HDL particles containing AII interacted with the HDL receptor in a different manner as compared to HDL particles which contain apoAI but not apoAII [Vadiveloo, P. K., & Fidge, N. H. (1992) Biochem. J. 284, 145-151]. The model predicted that each chain of the apoAII homodimer contained a binding domain capable of interacting with the HDL receptor. This model was tested in the current study by preparing apoAII monomers, complexing them with phospholipid, and determining the ability of these complexes to bind to putative HDL receptors in rat liver plasma membranes (RLPM) and bovine aortic endothelial cell membranes (BAECM) by ligand blotting. The data showed that these complexes were bound by HB1 and HB2 from RLPM, and to the 110-kDa HDL binding protein from BAECM, providing critical evidence to support the model. Further investigation into the binding interaction revealed that apoAII complexed with phospholipid (apoAII-PC) bound more than delipidated apoAII, which bound more than delipidated apoAII monomers. Thus, optimum binding required the presence of lipid.(ABSTRACT TRUNCATED AT 250 WORDS)

Isolation and structural characterization of the bovine tyrosine hydroxylase gene

A bovine tyrosine hydroxylase (TH) cDNA probe was used to screen a charon 30 genomic library. Screening of approximately 1 million recombinant phage resulted in the identification of one clone, lambda B1, containing the entire bovine TH gene. Results derived from restriction endonuclease mapping and sequence analysis reveal that the bovine gene contains 13 exons spanning approximately 7 kb of genomic DNA. Determination of the transcription initiation site indicates that the TH gene has a 5' untranslated region of 27 bp. A TATA-box sequence is located between positions-29 and -24 from the transcription initiation site and a cyclic AMP regulatory element (CRE) between-45 and -38. Although the TH gene appears to be glucocorticoid responsive in vitro, no regions bearing identity to the consensus sequence for the glucocorticoid regulatory element (GRE) were detected within approximately 1.5 kb of 5' flanking sequence. A cross-species comparison of the 5' flanking sequences of the bovine, rat, and human TH genes reveals strong sequence and positional conservation of seven sequence elements. An analysis of the nucleotide sequence within these elements reveals similarity to the consensus sequences reported for known cis-acting regulatory elements and transcription factor binding sites, suggesting that they may play a role in the regulation of TH gene expression.

Self-association of human apolipoproteins A-I and A-II and interactions of apolipoprotein A-I with bile salts: quasi-elastic light scattering studies

We employed quasi-elastic light scattering (QLS) to systematically study the aqueous self-association of human apolipoproteins A-I and A-II (apo A-I and apo A-II) and the interactions of apo A-I with common taurine-conjugated bile salts. Self-association of apo A-I was promoted by increases in apolipoprotein concentration (0.09-2.2 mg/mL) and ionic strength (0.15-2.0 M NaCl), inhibited by increases in temperature (5-50 degrees C) and guanidine hydrochloride concentration (0-2.0 M), and unaffected by hydrostatic pressures up to 500 atm. The mean hydrodynamic radius (Rh) of apo A-I micelles ranged from 38 A to a maximum asymptotic value of 68 A. We examined several possible models of apo A-I self-association; the model that best fitted the Rh values assumed that apo A-I monomers first interacted at low concentrations to form dimers, which then further associated to form ring-shaped limiting octamers. Comparison of the temperature-dependent and ionic strength dependent free energy changes for the formation of octamers from apo A-I dimers suggested that hydrophobic forces strongly favored self-association and that electrostatic repulsive forces were only weakly counteractive. Apo A-II self-association was also promoted by increases in apolipoprotein concentration (0.2-1.8 mg/mL) and inhibited by increases in guanidine hydrochloride concentration (0-1.0 M) but was unaffected by variations in temperature (10-37 degrees C): the largest Rh values observed were consistent with limiting tetramers. As demonstrated by equilibrium dialysis, bile salts in concentrations below their critical micellar concentrations (cmc) bound to apo A-I micelles but had no effect upon apo A-I self-association, as inferred from constant Rh values. When bile salt concentrations exceeded their aqueous cmc values, a dissociation of apo A-I micelles resulted with the formation of mixed bile salt/apo A-I micelles. These studies support the concepts that apo A-I and apo A-II form small dimeric micelles at low concentrations that grow sharply to reach limiting sizes over a narrow concentration range. The influences of bile salt concentration and species upon these micelles have relevance to the plasma transport of bile salts in high-density lipoproteins and to the physical-chemical state of apo A-I and apo A-II molecules in native biles.

Physical properties of lipid-protein complexes formed by the interaction of dimyristoylphosphatidylcholine and human high-density apolipoprotein A-II

Apolipoprotein A-II (apoA-II) from human plasma high-density lipoproteins associates with dimyristoylphosphatidylcholine (DMPC) to give complexes whose structure is determined by the temperature at which the reaction is conducted. The temperature dependence is related to the gel leads to liquid crystalline transition temperature, Tc, of DMPC which occurs at 23.9 degrees C. At T less than Tc (20 degrees C), T = Tc, and T greater than Tc (30 degrees C), three different complexes can be isolated. At 20 degrees C, at 75:1 (molar ratio of lipid to protein) complex is formed. This complex has a molecular weight (Mt) of 343 000, a Stokes radius, Rs, of 65 A, and a partial specific volume (v) of 0.914 mL/g. At 24 degrees C, two different complexes may be formed. One is similar to the one formed at 20 degrees C and the other is a complex with a DMPC:apoA-II ratio of 241:1; the corresponding physical constants for the latter complex are Mr = 1580 000, Rs = 120 A, and v = 0.948 mL/g. This complex is asymmetric, having a frictional coefficient f/f0 = 1.20. AT 30 degrees C, a 45:1 complex was formed; for this complex, Mr = 229 000, Rs = 57 A, and v = 0.892 mL/g. Electron microscopy reveals that the negatively stained complexes are arranged in rouleaux having subunits with average dimensions of 175 x 60, 250 x 62, and 50 x 55 A for the 45:1, 75:1, and 240:1 complexes, respectively. The multiple lipid-protein species formed by apoA-II and DMPC suggest the possible existence of more than one macromolecular spices of lipid and apoA-II in the plasma.