KEGG:D02011 - FACTA Search

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Query: KEGG:D02011 (FAD)
5,530 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The 13C- and 15N-NMR spectra of porcine kidney medium-chain acyl-CoA dehydrogenase (MCAD) reconstituted with 13C- and 15N-enriched FADs were measured. The positions of selective enrichment were C(2), C(4), C(4 alpha), C(10 alpha), N(1), N(3), and N(5) of the isoalloxazine nucleus of FAD. The NMR signals of the labeled atoms were observed as broad but distinct peaks in each NMR spectrum. The chemical shift values of the 2-, 4-, 4 alpha-, and 10 alpha-13C for the oxidized form of MCAD were 159.5, 166.8, 141.1, and 155.5 ppm, respectively, relative to the methyl resonance of 3-(trimethylsilyl)propionic acid-d4, while those of 1-, 3-, and 5-15N for the oxidized form were 183.6, 161.1, and 334.7 ppm, relative to liquid ammonia, respectively. The upfield shift of 2-13C of MCAD relative to that of FMN in the aqueous medium and its downfield shift relative to that of tetraacetylriboflavin in an apolar medium imply that a weaker hydrogen bond exists between C(2) = O and apoMCAD or a water molecule than that of free FMN with a water molecule. That the 4-13C resonance was observed downfield-shifted relative to that of free FMN in aqueous solution suggests a strong hydrogen bond between C(4) = O and apoMCAD. The chemical shift for 4 alpha-13C in oxidized MCAD is considerably downfield-shifted from that of FMN or any other flavoprotein observed thus far, indicating a unique environment around this position in MCAD. The 1-15N resonance of MCAD was most upfield-shifted among the flavoproteins observed.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:13C- and 15N-NMR studies on medium-chain acyl-CoA dehydrogenase reconstituted with 13C- and 15N-enriched flavin adenine dinucleotide. 845 67

Crystal structures of the wild type human medium-chain acyl-CoA dehydrogenase (MCADH) and a double mutant in which its active center base-arrangement has been altered to that of long chain acyl-CoA dehydrogenase (LCADH), Glu376Gly/Thr255Glu, have been determined by X-ray crystallography at 2.75 and 2.4 A resolution, respectively. The catalytic base responsible for the alpha-proton abstraction from the thioester substrate is Glu376 in MCADH, while that in LCADH is Glu255 (MCADH numbering), located over 100 residues away in its primary amino acid sequence. The structures of the mutant complexed with C8-, C12, and C14-CoA have also been determined. The human enzyme structure is essentially the same as that of the pig enzyme. The structure of the mutant is unchanged upon ligand binding except for the conformations of a few side chains in the active site cavity. The substrate with chain length longer than C12 binds to the enzyme in multiple conformations at its omega-end. Glu255 has two conformations, "active" and "resting" forms, with the latter apparently stabilized by forming a hydrogen bond with Glu99. Both the direction in which Glu255 approaches the C alpha atom of the substrate and the distance between the Glu255 carboxylate and the C alpha atom are different from those of Glu376; these factors are responsible for the intrinsic differences in the kinetic properties as well as the substrate specificity. Solvent accessible space at the "midsection" of the active site cavity, where the C alpha-C beta bond of the thioester substrate and the isoalloxazine ring of the FAD are located, is larger in the mutant than in the wild type enzyme, implying greater O2 accessibility in the mutant which might account for the higher oxygen reactivity.
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PMID:Crystal structures of the wild type and the Glu376Gly/Thr255Glu mutant of human medium-chain acyl-CoA dehydrogenase: influence of the location of the catalytic base on substrate specificity. 882 76

The intense charge transfer complex between the enolate of 3-thia-octanoyl-CoA and the oxidized flavin of the medium-chain acyl-CoA dehydrogenase is discharged by the ferricenium ion with irreversible inactivation of the enzyme. Charge transfer complex formation is a necessary, but insufficient, condition for oxidative inactivation: the 3-oxa-octanoyl-CoA complex is also inactivated, whereas the comparable trans-3-octenoyl-CoA species is not. Complete inactivation of the dehydrogenase with 3-thia-octanoyl-CoA requires 1 molecule of thioester and apparently 3 molecules of ferricenium hexafluorophosphate. Experiments with 8-Cl-FAD substituted enzyme and the crystal structure of enzyme.ligand complexes argue that ferricenium ion-mediated oxidation proceeds through the flavin prosthetic group. Synthesis of [2-14C]-3-thia-octanoyl-CoA, followed by isolation of radiolabeled peptide from the modified medium-chain dehydrogenase, showed that inactivation results in labeling the catalytic base, GLU376. Oxidative modification is accompanied by the release of CoASH. A mechanism for inactivation is proposed involving generation of a sulfonium salt which efficiently captures the carboxylate nucleophile.
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PMID:Oxidative inactivation of a charge transfer complex in the medium-chain acyl-CoA dehydrogenase. 884 70

Two forms of rat peroxisomal acyl-CoA oxidase (ACO-I and -II) interact with the substrate analogs, 3-ketoacyl-CoAs, forming a complex characterized by the so-called charge-transfer (CT) band around 575 nm in the absorption spectra. The CT band of ACO-I exhibited a broad dependency on the acyl chain-length from C4 to C16, whereas that of ACO-II showed increased intensity with a longer acyl chain to reach a maximum with a chain-length of C12. These chain-length dependencies of the CT bands were compared with those of the enzymatic activities reported previously [Setoyama et al. (1995) Biochem. Biophys. Res. Commun. 217, 482-487]. The differences in spectroscopic and enzymatic properties between ACO-I and -II suggest that the amino acid stretch corresponding to the third exon in the ACO sequence affects the binding of the ligand and substrate, since the difference in the primary structure between ACO-I and -II lies in the short amino acid stretch corresponding to the third of the total of 14 exons. On the other hand, resonance Raman spectra of the complexes of ACO-I and -II with 3-ketoacyl-CoAs excited in the CT band showed similar features. The two prominent FAD bands II and III, associated with the C(4a)=N(5) moiety of FAD, were observed at 1,577 and 1,545 cm(-1), respectively. In contrast, the bands at 1,615 and 1,493 cm(-1) in the ACO-I x 3-keto-C8-CoA complex were assigned to the stretching modes of C=O at positions 3 and 1 of the ligand, respectively, by using the isotopically labeled ligands. Both C=O stretching bands were shifted to lower wave numbers upon complex formation with ACO-I, implying that the C=O bond involves the single bond (C-O-) character in the active site cavity. The downshift of the C(1)=O stretching band was larger than that of the C(3)=O stretching band. Therefore, the ligand lies in the active site as the anionic form with a major contribution from C(1)-O-. These observations demonstrate that the CT band around 575 nm arises from the charge-transfer interaction between the oxidized FAD and the enolate transformed after the elimination of the a-proton. The band II of FAD in the complexes reveals a significant decrease in the frequency in comparison with the complexes of medium-chain acyl-CoA dehydrogenase (MCAD) with 3-ketoacyl-CoA. This observation suggests a difference between ACO and MCAD in the hydrogen-bonding network associated with enzyme-bound FAD.
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PMID:Spectroscopic studies of rat liver acyl-CoA oxidase with reference to recognition and activation of substrate. 935 89

Mature medium chain acyl-CoA dehydrogenase isolated from pig kidney (pkMCADH) and originating from mitochondria carries a phosphate group as demonstrated by 31P-NMR-spectroscopy and chemical analysis. Two broad resonances at -6.3 and -8 ppm are observed and are assigned to the pyrophosphate group of the cofactor FAD. A third, narrow resonance at 4.65 ppm indicates the presence of a phosphomonoester residue. Chemical analysis of intact pkMCADH shows the presence of 3 +/- 0.3 phosphates, those of FAD and of an additional covalently attached phosphate. With recombinant, human wild type MCADH expressed in and purified from E. coli only the two FAD phosphates (2 +/- 0.35) are found. Similarly, pkMCADH which has been converted to the apoenzyme and reconstituted to holoenzyme also contains 2 +/- 0.4 phosphates. The covalently bound phosphate can be hydrolyzed by phosphatase and subsequently removed by dialysis. The phosphate group has no detectable effect on the catalytic activity of the MCADH measured with artificial and natural electron acceptors such as pig electron transferring flavoprotein. However, phosphorylation has a marked effect on protein solubility which is +5-fold lower for the dephosphorylated protein.
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PMID:Medium-chain acyl CoA dehydrogenase: evidence for phosphorylation. 942 98

A range of 4-thiaacyl-CoA derivatives has been synthesized to study the bioactivation of cytotoxic fatty acids by the mitochondrial medium-chain acyl-CoA dehydrogenase and the peroxisomal acyl-CoA oxidase. Both enzymes catalyze alpha-proton abstraction from normal acyl-CoA substrates with elimination of a beta-hydride equivalent to the FAD prosthetic group. In competition with this oxidation reaction, 4-thiaacyl-CoA thioesters undergo dehydrogenase-catalyzed beta-elimination, providing that the corresponding thiolates are sufficiently good leaving groups and can be accommodated by the active site of the enzyme. Thus, the dehydrogenase catalyzes the elimination of 2-mercaptobenzothiazole and 4-nitrothiophenolate from 4-(2-benzothiazole)-4-thiabutanoyl-CoA and 4-(4-nitrophenyl)-4-thiabutanoyl-CoA, respectively. However, the 2,4-dinitrophenyl-analogue appears too bulky and the unsubstituted thiophenyl-derivative is insufficiently activated for significant elimination. Molecular modeling shows that steric interference from the flavin ring dictates a syn rather than an anti elimination. Acryloyl-CoA, the other product of 4-thiaacyl-CoA elimination reactions, is not a significant inactivator of the medium-chain dehydrogenase. In contrast, the irreversible inactivation observed during beta-elimination using 5,6-dichloro-4-thia-5-hexenoyl-CoA (DCTH-CoA), 5,6-dichloro-7,7,7-trifluoro-4-thia-5-heptenoyl-CoA (DCTFTH-CoA), and 6-chloro-5,5,6-trifluoro-4-thiahexanoyl-CoA (CTFTH-CoA) is caused by release of cytotoxic thiolate products within the active site of the dehydrogenase. The double bond between C5 and C6 found in the vinylic analogues DCTH- and DCTFTH-CoA is not essential for enzyme inactivation, although CTFTH-CoA is a weaker inhibitor of the dehydrogenase. Mechanism-based inactivation with CTFTH-CoA requires elimination, is unaffected by exogenous nucleophiles, and is strongly protected by octanoyl-CoA. The peroxisomal acyl-CoA oxidase efficiently oxidizes 4-thiaacyl-CoA analogues, but is only rapidly inactivated by DCTFTH-CoA. The variable ratio of elimination to oxidation observed for DCTH-, DCTFTH-, and CTFTH-CoA may influence the metabolism of the corresponding cytotoxic alkanoic acids in vivo.
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PMID:Elimination reactions in the medium-chain acyl-CoA dehydrogenase: bioactivation of cytotoxic 4-thiaalkanoic acids. 947 67

The mechanism by which acyl-CoA dehydrogenases initiate catalysis was studied by using p-substituted phenylacetyl-CoAs (substituents-NO2, -CN, and CH3CO-), 3S-C8-, and 3'-dephospho-3S-C8CoA. These analogues lack a beta C-H and cannot undergo alpha,beta-dehydrogenation. Instead they deprotonate at alpha C-H at pH > or = 14 to form delocalized carbanions having strong absorbancies in the near UV-visible spectrum. The pKas of the corresponding phenylacetone analogues were determined as approximately 13.6 (-NO2), approximately 14.5 (-CN), and approximately 14.6 (CH3CO-). Upon binding to human wild-type medium-chain acyl-CoA dehydrogenase (MCADH), all analogues undergo alpha C-H deprotonation. While the extent of deprotonation varies, the anionic products from charge-transfer complexes with the oxidized flavin. From the pH dependence of the dissociation constants (Kd) of p-NO2-phenylacetyl-CoA (4NPA-CoA), 3S-C8-CoA, and 3'-dephospho-3S-C8CoA, four pKas at approximately 5, approximately 6, approximately 7.3, and approximately 8 were identified. They were assigned to the following ionizations: (a) pKa approximately 5, ligand (L-H) in the MCADH approximately ligand complex; (b) pKa approximately 6, Glu376-COOH in uncomplexed MCADH; (c) pKa approximately 7.3, Glu99-COOH in uncomplexed MCADH (Glu99 is a residue that flanks the bottom of the active-center cavity; this pK is absent in the mutant Glu99Gly-MCADH); and (d) pK approximately 8, Glu99-COOH in the MCADH approximately 4NPA-CoA complex. The pKa approximately 6 (b) is not significantly affected in the MCADH approximately 4NPA-CoA complex, but it is increased by > or = 1 pK unit in that with 3S-C8CoA and further in the presence of C8-CoA, the best substrate. The alpha C-H pKas of 4NPA-CoA, of 3S-C8-CoA, and of 3'-dephospho-3S-C8CoA in the complex with MCADH are approximately 5, approximately 5, and approximately 6. Compared to those of the free species these pKa values are therefore lowered by 8 to > or = 11 pH units (50 to > or = 65 kJ mol-1) and are close to the pKa of Glu376-COOH in the complex with substrate/ligand. This effect is ascribed mainly to the hydrogen-bond interactions of the thioester carbonyl group with the ribityl-2'-OH of FAD and Glu376-NH. It is concluded that the pKa shifts induced with normal substrates such as n-octanoyl-CoA are still higher and of the order of 9-13 pK units. With 4NPA-CoA and MCADH, alpha C-H abstraction is fast (kapp approximately 55 s-1 at pH 7.5 and 25 degrees C, deuterium isotope effect approximately 1.34). However, it does not proceed to completion since it constitutes an approach to equilibrium with a finite rate for reprotonation in the pH range 6-9.5. The extent of deprotonation and the respective rates are pH-dependent and reflect apparent pKas of approximately 5 and approximately 7.3, which correspond to those determined in static experiments.
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PMID:Substrate activation by acyl-CoA dehydrogenases: transition-state stabilization and pKs of involved functional groups. 948 10

Oxidation of thioester substrates in the medium-chain acyl-CoA dehydrogenase involves alpha-proton abstraction by the catalytic base, Glu376, with transfer of a beta-hydride equivalent to the flavin prosthetic group. Polarization of bound acyl-CoA derivatives by the recombinant human liver enzyme has been studied with 4-thia-trans-2-enoyl-CoA analogues. Polarization is maximal at low pH, with an apparent pK of 9.2 for complexes with the C8 analogue, and progressively lower pK values as the length of the chain increases. This pH effect reflects ionization of the catalytic base, since polarization of a variety of enoyl-CoA analogues by the Glu376Gln mutant is pH independent. Binding of these ligands is accompanied by uptake of about 1 proton with the wild-type enzyme, but only about 0.1 proton with the Glu376Gln mutant. Rapid reaction studies show that proton uptake with the wild-type enzyme occurs at the same rate as polarization of the enoyl-CoA thioester, but is much slower than the initial ligand binding step. Studies with 6-OH-FAD-substituted enzyme show that this isomerization reaction also influences the flavin prosthetic group inducing deprotonation to the green anionic form. The failure of the bound thioether analogue, octyl-SCoA, to elicit pK shifts to flavin and Glu376 shows the importance of the thioester carbonyl oxygen in modulating key properties of the medium-chain enzyme. The role of thioester-mediated desolvation within the active site of the acyl-CoA dehydrogenases is discussed.
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PMID:Protonic equilibria in the reductive half-reaction of the medium-chain acyl-CoA dehydrogenase. 962 95

We investigated the influence of Glu-376-->Asp (E376D) mutation on the UV/visible spectral, thermodynamic, and kinetic properties for the interaction of structurally different types of CoA-ligands (viz., octenoyl-CoA, acetoacetyl-CoA, and indoleacryloyl-CoA) to human liver medium-chain acyl-CoA dehydrogenase (MCAD). Whereas the E376D mutation had minimal/negligible effect on the above properties for the binding of octenoyl-CoA to the enzyme, it had pronounced effects (albeit in opposite directions) for the binding of acetoacetyl-CoA and indoleacryloyl-CoA to the enzyme. In the case of acetoacetyl-CoA, the spectrum of the enzyme-ligand complex (in the charge-transfer region; lambdamax = 545 nm) was 1.8-fold more pronounced, and the DeltaH degrees value for the binding of acetoacetyl-CoA to the enzyme was 5.6 kcal/mol more favorable with wild-type as compared to the E376D mutant enzyme. The kinetic data revealed that the above effects were related to an increase in the dissociation "off-rate" of acetoacetyl-CoA from the enzyme-acetoacetyl-CoA complex. In contrast, in the case of IACoA, the resultant UV/visible spectrum of the enzyme-IACoA complex (lambdamax = 416 nm) was 2.7-fold less pronounced, and the DeltaH degrees value of the enzyme-IACoA complex was 6.4 kcal/mol less favorable with the wild-type than the E376D mutant enzyme. The latter effects were supported by the fact that the above mutation impaired the dissociation "off-rate" of IACoA from the enzyme-IACoA complex by 5.7-fold. Molecular model building studies revealed that the discriminatory influence of the E376D mutation on the spectral, thermodynamic, and kinetic properties of the enzyme-ligand complexes is due to ligand-specific changes in the spatial relationship between the FAD and CoA-ligands at the enzyme site. Arguments are presented that the "void" created by excision of a methylene group from Glu-376 (upon Glu-376-->Asp mutation) is adjusted differently upon interaction with structurally different types of CoA-ligands.
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PMID:Discriminatory influence of Glu-376-->Asp mutation in medium-chain acyl-CoA dehydrogenase on the binding of selected CoA-ligands: spectroscopic, thermodynamic, kinetic, and model building studies. 962 96

The mechanism underlying the recognition and activation of the substrate for medium-chain acyl-CoA dehydrogenase (MCAD) was spectroscopically investigated using 3-thiaacyl-CoAs as substrate analogs. The complex of MCAD with 3-thiaoctanoyl-CoA (3-thia-C8-CoA) exhibited a charge-transfer (CT) band with a molar extinction coefficient of epsilon808 = 9.1 mM-1.cm-1. With increasing 3-thiaacyl-chain length, the CT-band intensity of the complex decreased concomitantly with changes in the FAD absorption at 416 and 482 nm, and no CT band was detected in complexes with chain-lengths longer than C15. Detailed analysis of the absorption spectra suggested that the complexed states represent a two-state equilibrium between the CT-inducing form and the CT-non-inducing form. 13C-NMR measurements with 13C-labeled ligand clarified that 3-thia-C8-CoA is complexed to MCAD in an anionic form with signals detected at 163.7 and 101.2 ppm for 13C(1) and 13C(2), respectively. In the MCAD complex with 13C(1)-labeled 3-thia-C12-CoA, two signals for the bound ligand were observed at 163.7 and 198.3 ppm, and assigned to the anionic and neutral forms, respectively. Only the neutral form signal was measured at 200.6 ppm in the complex with 13C(1)-labeled 3-thia-C17-CoA. These results indicate that the CT band can be explained in terms of an internal equilibrium between anionic (CT-inducing) and neutral (CT-non-inducing) forms of the bound ligand. Resonance Raman spectra of the MCAD.3-thia-C8-CoA complex, with excitation at the CT band, showed enhanced bands, among which the 854- and 1,368-cm-1 bands were assigned to the S-C(2) stretching mode of the ligand and to flavin band VII, respectively. Since the enhanced bands were observed at the same wave numbers in complexes with C8, C12, and C14-ligands, it appears that the CT-inducing form shares a common alignment relative to oxidized flavin irrespective of differences in the acyl-chain length. However, with longer ligands, the degree of resonance enhancement of the Raman bands decreased in parallel with the CT-band intensity; this is compatible with the increase in the CT-non-inducing form in complexes with longer ligands. Furthermore, the pH dependence of the CT band gave an apparent pKa = 5.6-5.7 for ligands with chain-lengths of C8-C12. The NMR measurements revealed that, like chain-length dependence, the pH dependence can be explained by a two-state equilibrium derived from the protonation/deprotonation of the CT-inducing form of the bound ligand. On the basis of these results we have established a novel model to explain the mechanism of recognition and activation of the substrates/ligands by MCAD.
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PMID:Mechanism for the recognition and activation of substrate in medium-chain acyl-CoA dehydrogenase. 999 Jan 25

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