EC:1.3.99.3 - FACTA Search

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Query: EC:1.3.99.3 (acyl-CoA dehydrogenase)
1,425 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Chicken embryos in eggs laid by hens that are genetically unable to deposit riboflavin into their eggs die on or about the 13th day of incubation. We show that these riboflavin-deficient embryos grow normally until the day of death and that their heart rate is normal to within an hour of death. The embryos have symptoms of impaired fatty acid oxidation, including decreased activity of FAD-dependent medium-chain acyl CoA dehydrogenase in liver and heart along with a significant accumulation of intermediates of fatty acid oxidation (C10, C12, and C14 acids). Unlike riboflavin-deficient mammals, the embryos do not accumulate dicarboxylic acids derived from omega-oxidation of fatty acids. Blood glucose is near normal on day 10 but declines to undetectable levels by the time of death. Allantoic fluid from the riboflavin-deficient embryos of 11 days or older contains more lactate than 3-hydroxybutyrate, while in normal embryos the reverse is true. No appreciable amounts of glycine-conjugated acids were found. We conclude that the major and perhaps primary pathological effect of riboflavin deficiency in chicken embryos is the impairment of fatty acid beta-oxidation, and that the subsequent depletion of limited carbohydrate reserves leads to sudden death.
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PMID:Riboflavin-deficient chicken embryos: hypoglycemia without dicarboxylic aciduria. 759 88

In a previous paper, we demonstrated that the reductive half-reaction of medium-chain fatty acyl-CoA dehydrogenase (MCAD), utilizing octanoyl-CoA as physiological substrate, generates two (kinetically distinct) forms of the reduced enzyme (MCAD-FADH2) - octenoyl-CoA charge-transfer complexes [Kumar, N.R., & Srivastava, D.K. (1994) Biochemistry 33, 8833-8841]. We present evidence that octenoyl-CoA dissociates from the second (most stable) charge-transfer complex (referred to as CT2) via two alternative ("facile" and "restricted") pathways. The dissociation of octenoyl-CoA via the facile pathway involves the reversal of the overall reductive half-reaction of the enzyme, generating MCAD-FAD - octanoyl-CoA as the Michaelis complex, followed by dissociation of the latter complex into MCAD-FAD + octanoyl-CoA. Hence, via this pathway, octenoyl-CoA is released from the enzyme site in the form of octanoyl-CoA. In contrast, the restricted pathway involves a direct (albeit slow) dissociation of octenoyl-CoA from CT2 to yield MCAD-FADH2 + octenoyl-CoA. The kinetic profile for the dissociation of octenoyl-CoA via the restricted pathway matches the rate of oxidation of the reduced flavin (within CT2) by O2. This suggests that the oxidase activity of the enzyme remains suppressed as long as the reduced enzyme predominates in the form of the charge-transfer complex(es). The oxidase activity of the enzyme emerges concomitantly with the conversion of CT2 to the MCAD-FADH2 - octenoyl-CoA Michaelis complex. The energetic basis for the dissociation of octenoyl-CoA via the facile and restricted pathways and the mechanism of suppression of the oxidase activity of the enzyme are discussed.
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PMID:Facile and restricted pathways for the dissociation of octenoyl-CoA from the medium-chain fatty acyl-CoA dehydrogenase (MCAD)-FADH2-octenoyl-CoA charge-transfer complex: energetics and mechanism of suppression of the enzyme's oxidase activity. 762 13

We studied the role of FAD in the intramitochondrial folding and assembly of medium-chain acyl-CoA dehydrogenase (MCAD), a homotetrameric mitochondrial enzyme containing a molecule of non-covalently bound FAD/monomer. In the MCAD molecule, FAD is buried in a crevice containing the active center. We have previously shown that upon import into mitochondria, newly processed MCAD is first incorporated into a high molecular weight (hMr) complex and that the hMr complex mainly consisted of MCAD-heat-shock protein 60 (hsp60) complex (Saijo, T., Welch, W.J., and Tanaka, K (1994) J. Biol. Chem. 269, 4401-4408). In the present study, we incubated in vitro synthesized precursor MCAD with mitochondria isolated from normal and riboflavin-deficient rat liver for 10-60 min and fractionated the solubilized mitochondria using gel filtration. The amount of MCAD in the hMr complex was larger and that of tetramer was smaller in riboflavin-deficient mitochondria than in control at any time point. In addition, riboflavin-deficient mitochondria were solubilized after 10-min import in a buffer containing ATP and were chased in the presence of FAD, FMN, or NAD+ or without any addition. The mitochondrial proteins were analyzed using gel filtration or immunoprecipitated with anti-hsp60 antibody. After 60-min chase in the presence of FAD, the majority of MCAD in the complex with hsp60 was transferred to tetramer, whereas no such transfer occurred after the chase in the absence of FAD. When chase was done in the presence of FMN, a significant amount of MCAD was transferred from the complex with hsp60 to tetramer, but the transfer was not as efficient as in the presence of FAD. The chase in the presence of NAD+ resulted in no transfer. These data suggest that isoalloxazine ring of FAD plays a critical role, exerting nucleating effect, in the hsp60-assisted folding of MCAD subunit into an assembly competent conformation, probably assisting the formation of the core.
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PMID:Isoalloxazine ring of FAD is required for the formation of the core in the Hsp60-assisted folding of medium chain acyl-CoA dehydrogenase subunit into the assembly competent conformation in mitochondria. 782 28

S-2-Br-hexanoyl-CoA and the branched chain isomer S-2-Br-4-methyl-pentanoyl-CoA are affinity labels of the medium-chain acyl-CoA dehydrogenase from pig kidney. The straight chain thioester is both a substrate and an irreversible inhibitor of the dehydrogenase. Inactivation of the enzyme is biphasic and is half-complete in 4 min at pH 6.5, 25 degrees C. Although S-2-Br-hexanoyl-CoA can partially reduce the FAD prosthetic group of the dehydrogenase, inactivation results from attachment of one molecular of inhibitor per subunit of the oxidized enzyme. The branched chain analogue is a very weak substrate of the dehydrogenase (0.1% that of octanoyl-CoA), but is almost as effective an inhibitor of the dehydrogenase. Incubation experiments with [14C]S-2-Br-methyl-pentanoyl-CoA followed by the isolation of radiolabeled peptide show that modification of the active site base, GLU376, is responsible for enzyme inactivation. The data are compatible with a simple nucleophilic attack of the carboxylate base on the C-2 atom of these 2-Br-analogues.
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PMID:S-2-bromo-acyl-CoA analogues are affinity labels for the medium-chain acyl-CoA dehydrogenase from pig kidney. 789 66

Of the different chain length fatty acyl-CoA substrates, octanoyl-CoA has been known as one of the most efficient (and physiological) substrates for the medium-chain fatty acyl-CoA dehydrogenase (MCAD)-catalyzed reaction. The reaction of MCAD-FAD with octanoyl-CoA ([MCAD-FAD] << [octanoyl-CoA]), measured via the stopped-flow technique, at 5 degrees C was characterized by a biphasic decrease and increase in absorptions at 450 and 545 nm, respectively. The average values of the fast (1/tau 1) and slow (1/tau 2) relaxation rate constants, derived from the data at these wavelengths, were found to be 319.7 +/- 33.5 and 28.8 +/- 12.5 s-1, respectively, and both of these relaxation rate constants remained invariant between 8 and 200 microM concentrations of octanoyl-CoA. Under identical experimental conditions, we measured time courses for the interaction of MCAD-FAD with octenoyl-CoA ([MCAD-FAD] << [octenoyl-CoA]) by monitoring the absorption changes at 299, 394, and 440 nm. The binding profile was consistent with a biphasic decrease (at 440 nm) and increase (at 299 and 394 nm) in absorbance, with similar magnitudes of fast [1/tau 1 (average) = 382.3 +/- 39.8 s-1] and slow [1/tau 2 (average) = 14.3 +/- 7.4 s-1] relaxation rate constants. The observed relaxation rate constants were, once again, found to be invariant with changes in the octenoyl-CoA concentration from 40 to 150 microM.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Reductive half-reaction of medium-chain fatty acyl-CoA dehydrogenase utilizing octanoyl-CoA/octenoyl-CoA as a physiological substrate/product pair: similarity in the microscopic pathways of octanoyl-CoA oxidation and octenoyl-CoA binding. 803 75

In a previous communication, we demonstrated that the medium-chain fatty acyl CoA dehydrogenase (MCAD) catalyzed conversion of 3-indolepropionyl CoA (IPCoA) to trans-3-indoleacryloyl CoA (IACoA) proceeds via the formation of an intermediary species X that possesses the electronic properties of reduced flavin and highly conjugated CoA product. Since the steady-state turnover of the enzyme-catalyzed dehydrogenation reaction precisely matches with the rate of formation of X [Johnson, J. K., & Srivastava, D. K. (1993) Biochemistry 32, 8004-8013], the latter species appeared to be the likely site for the transfer of electrons to external electron acceptors (e.g., ferricenium hexafluorophosphate, FcPF6). To probe the microscopic pathway for the oxidative half-reaction, we employed a sequential mixing stopped-flow technique utilizing IPCoA as the enzyme substrate and FcPF6 as the electron acceptor. The time-dependent changes in absorption at 450, 415, and 367 nm were measured upon mixing FcPF6 with previously mixed and aged solutions of MCAD-FAD+IPCoA in the stopped-flow syringes. The kinetic traces show an increase (1/tau 1) followed by a decrease (1/tau 2) in absorption at 450 and 415 nm, and a lag (corresponding to the time regime of 1 u 1) followed by an increase in absorption (1/tau 2) at 367 nm. The relaxation rate constants (1/tau's) thus measured remain unaffected, with variations in the aging time; however, the amplitudes of these phases increase up to the aging time of 5 s, after which the amplitudes attain maxima. For an aging time of 5 s, 1/tau 1 and 1/tau 2 show a linear and a hyperbolic dependence on the FcPF6 concentration, respectively. These, coupled with the complementary studies involving butyryl CoA as a nonchromophoric substrate for this enzyme, lead us to propose the following sequence of events during the MCAD-catalyzed oxidative half-reaction: (1) The enzyme-catalyzed oxidative half-reaction proceeds via the formation of a collision complex between X and FcPF6 during the fast (1/tau 1) relaxation phase. (2) The reduced flavin moiety of X is oxidized via (rapid) transfer of electrons to FcPF6 within the collision complex, without formation of a detectable (metastable) flavin semiquinone intermediate. (3) The transfer of electrons is accompanied by changes in the electronic structures of both the flavin and IACoA moieties within the enzyme-IACoA complex. The electronic structure of this newly formed complex is exactly the same as that formed upon isomerization of the MCAD-FAD-IACoA complex [Johnson, J. K., Wang, Z. X., & Srivastava, D. K. (1992) Biochemistry 31, 10564-10575].(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Microscopic pathway for the medium-chain fatty acyl CoA dehydrogenase catalyzed oxidative half-reaction: changes in the electronic structures of flavin and CoA derivatives during catalysis. 821 25

Mammalian electron-transferring flavoprotein (ETF) has been reported to consist of two non-identical subunits and one FAD. The present paper shows that ETF purified from pig kidney contains one more molecule, an AMP. ETF was denatured by guanidine hydrochloride and ultrafiltered for the purpose of removing proteins. The filtrate was analyzed by reverse-phase chromatography. Two peaks appeared on the chromatogram: they were identified as FAD and AMP, and their molar amounts were identical, indicating that ETF contains one AMP molecule. ApoETF, which was prepared by KBr treatment of ETF, also contains one AMP molecule. ApoETF, which was prepared by KBr treatment of ETF, also contain one AMP molecule. These results clearly demonstrate that ETF has an AMP-binding site in addition to the FAD-binding site. AMP-free apoETF was prepared by guanidine treatment of ETF. Mixing AMP-free apoETF, FAD, and AMP produced reconstituted ETF, which showed the same properties as native ETF. Mixing AMP-free apoETF and FAD produced AMP-free ETF, regardless of the coexistence of ATP or ADP: the AMP-binding site cannot bind FAD, ADP, or ATP. The enzymatic activity of the AMP-free ETF for electron transfer from substrate-reduced medium-chain acyl-CoA dehydrogenase to 2,6-dichlorophenolindophenol was identical to that of native ETF. This indicates that the AMP contained in holoETF has no apparent influence on this enzymatic activity. A role of AMP recognized in this study is that AMP facilitates the formation of holoETF from AMP-free apoETF, FAD, and AMP.
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PMID:Electron-transferring flavoprotein has an AMP-binding site in addition to the FAD-binding site. 826 2

We have investigated the medium-chain fatty acyl-CoA dehydrogenase (MCAD)-catalyzed reaction via rapid-scanning stopped-flow (RSSF) UV/vis spectroscopy, combined with the single-wavelength stopped-flow technique, utilizing 3-indolepropionyl-CoA (IPCoA) and trans-3-indoleacryloyl-CoA (IACoA) as chromophoric pseudosubstrates. The RSSF spectral data reveal that formation of an intermediary species with an absorbance maximum at 400 nm and a broad charge-transfer band around 600 nm accompanies the reduction of MCAD-FAD by IPCoA. In the presence of high concentrations of enzyme ([MCAD] >> [IPCoA]) the intermediary spectral band at 400 nm remains unperturbed, whereas in the presence of low concentrations of enzyme ([MCAD] << [IPCoA]) it slowly shifts to an absorption band with an absorbance maximum at 370 nm. Appearance and disappearance of this intermediary species coincides with the appearance and disappearance of the charge-transfer band. Single-wavelength stopped-flow studies, performed under similar high and low enzyme conditions, were consistent with one (1/tau 1) and two (1/tau 1 > 1/tau 2) relaxation rate constants, respectively. These findings, combined with relaxation studies performed in the reverse directions as well as substrate and product binding studies with the oxidized and reduced forms of the enzyme, have allowed us to conclude the following: (1) the intermediary species possesses the properties of reduced flavin and highly conjugated reaction product IACoA (absorbance maximum = 400 nm); (2) this intermediary species collapses into an MCAD-FADH2-IACoA complex (absorbance maximum = 370 nm) in the presence of excessive concentrations of IPCoA; the collapse is being driven by the competitive binding of IPCoA with the reduced form of the enzyme; (3) the 400-nm absorption band and the charge-transfer band are given by the same intermediary species formed during the enzyme-catalyzed reaction pathway. The role of protein conformational changes in modulating the substrate/product structures during the MCAD-catalyzed reaction is discussed.
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PMID:Detection and identification of a chromophoric intermediate during the medium-chain fatty acyl-CoA dehydrogenase-catalyzed reaction via rapid-scanning UV/visible spectroscopy. 826 94

The medium chain acyl-CoA dehydrogenase catalyzes the FAD-dependent oxidation of a variety of acyl-CoA substrates to the corresponding trans-2-enoyl-CoA thioesters. This work identifies 3-methyleneoctanoyl-CoA and 3-methyl-trans-2-octenoyl-CoA as representatives of a new class of mechanism-based inhibitor of the dehydrogenase. One equivalent of either compound generates an inactive reduced flavin species with low absorption at 450 nm and a shoulder at 320 nm suggestive of an N-5 adduct. Reduction is rapid with the 3-methylene analogue (10/s at 1 degree C), but comparatively slow for 3-methyl-trans-2-octenoyl-CoA (1.1 x 10(-4)/s, under the same conditions). The reduced species is very stable, but the adduct can be slowly displaced with a large excess of octanoyl-CoA. The reduced adduct resists oxidation by the facile one-electron oxidant of the dehydrogenase, ferricenium hexafluorophosphate. Evidence that both isomeric inhibitors generate the same reduced flavin species includes an essentially identical visible spectrum, the same kinetics of displacement using octanoyl-CoA, and the same mixture of products on HPLC after denaturation of the treated enzyme with trichloroacetic acid, methanol, or by boiling. Experiments with the corresponding shorter analogues of these inhibitors, 3-methylenebutanoyl-CoA and 3-methyl-2-butenoyl-CoA confirm and extend these findings. These reduced adducts are less stable, allowing the dehydrogenase to catalyze the interconversion of the unconjugated 3-methylenebutanoyl-CoA to the more stable conjugated 3-methyl-2-butenoyl-CoA thioester (Keq ca. 150). These data suggest that alpha-proton abstraction from the 3-methylene derivatives or gamma-proton removal from the 3-methyl-2-enoyl analogues generates a common carbanionic intermediate which attacks oxidized flavin. As would be expected, the unconjugated 3-methylene derivatives are more effective inhibitors of the dehydrogenase than the thermodynamically more stable 3-methylenoyl analogues.
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PMID:3-Methyleneoctanoyl-CoA and 3-methyl-trans-2-octenoyl-CoA: two new mechanism-based inhibitors of medium chain acyl-CoA dehydrogenase from pig kidney. 829 7

The three-dimensional structure of medium-chain acyl-CoA dehydrogenase from pig mitochondria in the native form and that of a complex of the enzyme and a substrate (product) have been solved and refined by x-ray crystallographic methods at 2.4-A resolution to R factors of 0.172 and 0.173, respectively. The overall polypeptide folding and the quaternary structure of the tetramer are essentially unchanged upon binding of the ligand, octanoyl (octenoyl)-CoA. The ligand binds to the enzyme at the rectus (re) face of the FAD in the crevice between the two alpha-helix domains and the beta-sheet domain of the enzyme. The fatty acyl chain of the thioester substrate is buried inside of the polypeptide and the 3'-AMP moiety is close to the surface of the tetrameric enzyme molecule. The alkyl chain displaces the tightly bound water molecules found in the native enzyme and the carbonyl oxygen of the thioester interacts with the ribityl 2'-hydroxyl group of the FAD and the main-chain carbonyl oxygen of Glu-376. The C alpha--C beta of the fatty acyl moiety lies between the flavin and the gamma-carboxylate of Glu-376, supporting the role of Glu-376 as the base that abstracts the alpha proton in the alpha--beta dehydrogenation reaction catalyzed by the enzyme. Trp-166 and Met-165 are located at the sinister (si) side of the flavin ring at the surface of the enzyme, suggesting that they might be involved in the interactions with electron transferring flavoprotein. Lys-304, the prevalent mutation site found in patients with medium-chain acyl-CoA dehydrogenase deficiency, is located approximately 20 A away from the active site of the enzyme.
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PMID:Crystal structures of medium-chain acyl-CoA dehydrogenase from pig liver mitochondria with and without substrate. 835 49

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