Role of aromatic stacking interactions in the modulation of the two-electron reduction potentials of flavin and substrate/product in Megasphaera elsdenii short-chain acyl-coenzyme A dehydrogenase.

The effects of aromatic stacking interactions on the stabilization of reduced flavin adenine dinucleotide (FAD) and substrate/product have been investigated in short-chain acyl-coenzyme A dehydrogenase (SCAD) from Megasphaera elsdenii. Mutations were made at the aromatic residues Phe160 and Tyr366, which flank either face of the noncovalently bound flavin cofactor. The electrochemical properties of the mutants were then measured in the presence and absence of a butyryl-CoA/crotonyl-CoA mixture. Results from these redox studies suggest that the phenylalanine and tyrosine both engage in favorable pi-sigma interactions with the isoalloxazine ring of the flavin to help stabilize formation of the anionic flavin hydroquinone. Disruption of these interactions by replacing either residue with a leucine (F160L and Y366L) causes the midpoint potential for the oxidized/hydroquinone couple (E(ox/hq)) to shift negative by 44-54 mV. The E(ox/hq) value was also found to decrease when aromatic residues containing electron-donating heteroatoms were introduced at the 160 position. Potential shifts of -32 and -43 mV for the F160Y and F160W mutants, respectively, are attributed to increased pi-pi repulsive interactions between the ring systems. This study also provides evidence for thermodynamic regulation of the substrate/product couple in the active site of SCAD. Binding to the wild-type enzyme caused the midpoint potential for the butyryl-CoA/crotonyl-CoA couple (E(BCoA/CCoA)) to shift 14 mV negative, stabilizing the oxidized product. Formation of product was found to be even more favorable in complexes with the F160Y and F160W mutants, suggesting that the electrostatic environment around the flavin plays a role in substrate/product activation.

Role of a cluster of hydrophobic residues near the FAD cofactor in Anabaena PCC 7119 ferredoxin-NADP+ reductase for optimal complex formation and electron transfer to ferredoxin.

In the ferredoxin-NADP(+) reductase (FNR)/ferredoxin (Fd) system, an aromatic amino acid residue on the surface of Anabaena Fd, Phe-65, has been shown to be essential for the electron transfer (ET) reaction. We have investigated further the role of hydrophobic interactions in complex stabilization and ET between these proteins by replacing three hydrophobic residues, Leu-76, Leu-78, and Val-136, situated on the FNR surface in the vicinity of its FAD cofactor. Whereas neither the ability of FNR to accept electrons from NADPH nor its structure appears to be affected by the introduced mutations, different behaviors with Fd are observed. Thus, the ET interaction with Fd is almost completely lost upon introduction of negatively charged side chains. In contrast, only subtle changes are observed upon conservative replacement. Introduction of Ser residues produces relatively sizable alterations of the FAD redox potential, which can explain the modified behavior of these mutants. The introduction of bulky aromatic side chains appears to produce rearrangements of the side chains at the FNR/Fd interaction surface. Thus, subtle changes in the hydrophobic patch influence the rates of ET to and from Fd by altering the binding constants and the FAD redox potentials, indicating that these residues are especially important in the binding and orientation of Fd for efficient ET. These results are consistent with the structure reported for the Anabaena FNR.Fd complex.

Medium-chain acyl-coenzyme A dehydrogenase bound to a product analogue, hexadienoyl-coenzyme A: effects on reduction potential, pK(a), and polarization.

2,4-Hexadienoyl-coenzyme A (HD-CoA) has been used to investigate the redox and ionization properties of medium-chain acyl-CoA dehydrogenase (MCAD) from pig kidney. HD-CoA is a thermodynamically stabilized product analogue that binds tightly to oxidized MCAD (K(dox) = 3.5 +/- 0.1 microM, pH 7.6) and elicits a redox potential shift that is 78% of that observed with the natural substrate/product couple [Lenn, N. D., Stankovich, M. T., and Liu, H. (1990) Biochemistry 29, 3709-3715]. The midpoint potential of the MCAD.HD-CoA complex exhibits a pH dependence that is consistent with the redox-linked ionization of two key glutamic acids as well as the flavin adenine dinucleotide (FAD) cofactor. The estimated ionization constants for Glu376-COOH (pK(a,ox) approximately 9.3) and Glu99-COOH (pK(a,ox) approximately 7.4) in the oxidized MCAD.HD-CoA complex indicate that while binding of the C(6) analogue makes Glu376 a stronger catalytic base (pK(a,ox) approximately 6.5, free MCAD), it has little effect on the pK of Glu99 (pK(a,ox) approximately 7.5, free MCAD) [Mancini-Samuelson, G. J., Kieweg, V., Sabaj, K. M., Ghisla, S., and Stankovich, M. T. (1998) Biochemistry 37, 14605-14612]. This finding is in agreement with the apparent pK of 9.2 determined for Glu376 in the human MCAD.4-thia-octenoyl-CoA complex [Rudik, I., Ghisla, S., and Thorpe, C. (1998) Biochemistry 37, 8437-8445]. The pK(a)s estimated for Glu376 and Glu99 in the reduced pig kidney MCAD.HD-CoA complex, 9.8 and 8.6, respectively, suggest that both of these residues remain protonated in the charge-transfer complex under physiological conditions. Polarization of HD-CoA in the enzyme active site may contribute to the observed pK(a) and redox potential shifts. Consequently, the electronic structures of the product analogue in its free and MCAD-bound forms have been characterized by Raman difference spectroscopy. Binding to either the oxidized or reduced enzyme results in localized pi-electron polarization of the hexadienoyl C(1)=O and C(2)=C(3) bonds. The C(4)=C(5) bond, in contrast, is relatively unaffected by binding. These results suggest that, upon binding to MCAD, HD-CoA is selectively polarized such that partial positive charge develops at the C(3)-H region of the ligand, regardless of the oxidation state of the enzyme.

Redox properties of human medium-chain acyl-CoA dehydrogenase, modulation by charged active-site amino acid residues.

The modulation of the electron-transfer properties of human medium-chain acyl-CoA dehydrogenase (hwtMCADH) has been studied using wild-type and site-directed mutants by determining their midpoint potentials at various pH values and estimating the involved pKs. The mutants used were E376D, in which the negative charge is retained; E376Q, in which one negative charge (pKa approximately 6. 0) is removed from the active center; E99G, in which a different negative charge (pKa approximately 7.3) also is affected; and E376H (pKa approximately 9.3) in which a positive charge is present. Em for hwtMCADH at pH 7.6 is -0.114 V. Results for the site-directed mutants indicate that loss of a negative charge in the active site causes a +0.033 V potential shift. This is consistent with the assumption that electrostatic interactions (as in the case of flavodoxins) and specific charges are important in the modulation of the electron-transfer properties of this class of dehydrogenases. Specifically, these charge interactions appear to correlate with the positive Em shift observed upon binding of substrate/product couple to MCADH [Lenn, N. D., Stankovich, M. T., and Liu, H. (1990) Biochemistry 29, 3709-3715], which coincides with a pK increase of Glu376-COOH from approximately 6 to 8-9 [Rudik, I., Ghisla, S., and Thorpe, C. (1998) Biochemistry 37, 8437-8445]. From the pH dependence of the midpoint potentials of hwtMCADH two mechanistically important ionizations are estimated. The pKa value of approximately 6.0 is assigned to the catalytic base, Glu376-COOH, in the oxidized enzyme based on comparison with the pH behavior of the E376H mutant, it thus coincides with the pK value recently estimated [Vock, P., Engst, S., Eder, M., and Ghisla, S. (1998) Biochemistry 37, 1848-1860]. The pKa of approximately 7.1 is assigned to Glu376-COOH in reduced hwtMCADH. Comparable values for these pKas for Glu376-COOH in pig kidney MCADH are pKox = 6.5 and pKred = 7.9. The Em measured for K304E-MCADH (a major mutant resulting in a deficiency syndrome) is essentially identical to that of hwtMCADH, indicating that the disordered enzyme has an intact active site.

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.

An electrochemical, kinetic, and spectroscopic characterization of [2Fe-2S] vegetative and heterocyst ferredoxins from Anabaena 7120 with mutations in the cluster binding loop.

Residues within the cluster binding loops of plant-type [2Fe-2S] ferredoxins are highly conserved and serve to structurally stabilize this unique region of the protein. We have investigated the influence of these residues on the thermodynamic reduction potentials and rate constants of electron transfer to ferredoxin:NADP+ reductase (FNR) by characterizing various single and multiple site-specific mutants of both the vegetative (VFd) and the heterocyst (HFd) [2Fe-2S] ferredoxins from Anabaena. Incorporation of residues from one isoform into the polypeptide backbone of the other created hybrid mutants whose reduction potentials either were not significantly altered or were shifted, but did not reconcile the 33-mV potential difference between VFd and HFd. The reduction potential of VFd appears relatively insensitive to mutations in the binding loop, excepting nonconservative variations at position 78 (T78A/I) which resulted in approximately 40- to 50-mV positive shifts compared to wild type. These perturbations may be linked to the role of the T78 side chain in stabilizing an ordered water channel between the iron-sulfur cluster and the surface of the wild-type protein. While no thermodynamic barrier to electron transfer to FNR is created by these potential shifts, the electron-transfer reactivities of mutants T78A/I (as well as T48A which has a wild-type-like potential) are reduced to approximately 55-75% that of wild type. These studies suggest that residues 48 and 78 are involved in the pathway of electron transfer between VFd and FNR and/or that mutations at these positions induce a unique, but unproductive orientation of the two proteins within the protein-protein complex.

Structure-function relationships in Anabaena ferredoxin: correlations between X-ray crystal structures, reduction potentials, and rate constants of electron transfer to ferredoxin:NADP+ reductase for site-specific ferredoxin mutants.

A combination of structural, thermodynamic, and transient kinetic data on wild-type and mutant Anabaena vegetative cell ferredoxins has been used to investigate the nature of the protein-protein interactions leading to electron transfer from reduced ferredoxin to oxidized ferredoxin:NADP+ reductase (FNR). We have determined the reduction potentials of wild-type vegetative ferredoxin, heterocyst ferredoxin, and 12 site-specific mutants at seven surface residues of vegetative ferredoxin, as well as the one- and two-electron reduction potentials of FNR, both alone and in complexes with wild-type and three mutant ferredoxins. X-ray crystallographic structure determinations have been carried out for six of the ferredoxin mutants. None of the mutants showed significant structural changes in the immediate vicinity of the [2Fe-2S] cluster, despite large decreases in electron-transfer reactivity (for E94K and S47A) and sizable increases in reduction potential (80 mV for E94K and 47 mV for S47A). Furthermore, the relatively small changes in Calpha backbone atom positions which were observed in these mutants do not correlate with the kinetic and thermodynamic properties. In sharp contrast to the S47A mutant, S47T retains electron-transfer activity, and its reduction potential is 100 mV more negative than that of the S47A mutant, implicating the importance of the hydrogen bond which exists between the side chain hydroxyl group of S47 and the side chain carboxyl oxygen of E94. Other ferredoxin mutations that alter both reduction potential and electron-transfer reactivity are E94Q, F65A, and F65I, whereas D62K, D68K, Q70K, E94D, and F65Y have reduction potentials and electron-transfer reactivity that are similar to those of wild-type ferredoxin. In electrostatic complexes with recombinant FNR, three of the kinetically impaired ferredoxin mutants, as did wild-type ferredoxin, induced large (approximately 40 mV) positive shifts in the reduction potential of the flavoprotein, thereby making electron transfer thermodynamically feasible. On the basis of these observations, we conclude that nonconservative mutations of three critical residues (S47, F65, and E94) on the surface of ferredoxin have large parallel effects on both the reduction potential and the electron-transfer reactivity of the [2Fe-2S] cluster and that the reduction potential changes are not the principal factor governing electron-transfer reactivity. Rather, the kinetic properties are most likely controlled by the specific orientations of the proteins within the transient electron-transfer complex.

Roles of the methane monooxygenase reductase component in the regulation of catalysis.

The reductase component (MMOR) of the soluble methane monooxygenase isolated from Methylosinus trichosporium OB3b catalyzes transfer of 2e- from NADH to the hydroxylase component (MMOH) where oxygen activation and substrate oxidation occur. It is shown here that MMOR can also exert regulatory effects on catalysis by binding to MMOH or to the binary complex of MMOH and component B (MMOB), another regulatory protein. MMOR alters the oxidation-reduction potentials of the dinuclear iron cluster at the active site of MMOH. Although little change is observed in the potential for the first electron transfer to the cluster (E(1)0' = 76 mV), the E(2)0' potential value for the second electron transfer is increased from 21 to 125 mV. This shift provides a larger driving force for electron transfer from MMOR and favors transfer of two rather than one electron as required by catalysis. Similar positive shifts in potential are observed even in the presence of MMOB which has been shown to cause a 132 mV negative shift in the midpoint potential of MMOH in the absence of MMOR. MMOR is also shown to decrease the rate of reaction between the fully reduced MMOH-MMOB and O2 approximately 20-fold at 4 degrees C. However, the time course of the key catalytic cycle intermediate that can react with substates, compound Q, is unaffected. This implies a compensating faster decay of one or more of the intermediates that occur between diferrous MMOH and compound Q in the reaction cycle, thereby limiting potential nonproductive autodecay of these intermediates. Accordingly, an increase in single turnover product yield is observed in the presence of MMOR. Interestingly, MMOR can cause the redox potential increases, changes in rates, and the increase in product yield when present at only 10% of the concentration of MMOH active sites. Substrate binding is shown to induce negligible changes in the redox potentials. Two alternative regulatory schemes are presented based on (i) thermodynamic coupling of component binding and redox changes or (ii) dynamic interconversion of two states of MMOH promoted by MMOR.

Iron-sulfur cluster cysteine-to-serine mutants of Anabaena -2Fe-2S- ferredoxin exhibit unexpected redox properties and are competent in electron transfer to ferredoxin:NADP+ reductase.

The reduction potentials and the rate constants for electron transfer (et) to ferredoxin:NADP+ reductase (FNR) are reported for site-directed mutants of the [2Fe-2S] vegetative cell ferredoxin (Fd) from Anabaena PCC 7120, each of which has a cluster ligating cysteine residue mutated to serine (C41S, C46S, and C49S). The X-ray crystal structure of the C49S mutant has also been determined. The UV-visible optical and CD spectra of the mutants differ from each other and from wild-type (wt) Fd. This is a consequence of oxygen replacing one of the ligating cysteine sulfur atoms, thus altering the ligand --> Fe charge transfer transition energies and the chiro-optical properties of the chromophore. Each mutant is able to rapidly accept an electron from deazariboflavin semiquinone (dRfH.) and to transfer an electron from its reduced form to oxidized FNR although all are somewhat less reactive (30-50%) toward FNR and are appreciably less stable in solution than is wt Fd. Whereas the reduction potential of C46S (-381 mV) is not significantly altered from that of wt Fd (-384 mV), the potential of the C49S mutant (-329 mV) is shifted positively by 55 mV, demonstrating that the cluster potential is sensitive to mutations made at the ferric iron in reduced [2Fe-2S] Fds with localized valences. Despite the decrease in thermodynamic driving force for et from C49S to FNR, the et rate constant is similar to that measured for C46S. Thus, the et reactivity of the mutants does not correlate with altered reduction potentials. The et rate constants of the mutants also do not correlate with the apparent binding constants of the intermediate (Fdred:FNRox) complexes or with the ability of the prosthetic group to be reduced by dRfH.. Furthermore, the X-ray crystal structure of the C49S mutant is virtually identical to that of wt Fd. We conclude from these data that cysteine sulfur d-orbitals are not essential for et into or out of the iron atoms of the cluster and that the decreased et reactivity of these Fd mutants toward FNR may be due to small changes in the mutual orientation of the proteins within the intermediate complex and/or alterations in the electronic structure of the [2Fe-2S] cluster.

Studies of the redox properties of CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase (E1) and CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase reductase (E3): two important enzymes involved in the biosynthesis of ascarylose.

Studies of the biosynthesis of ascarylose, a 3,6-dideoxyhexose found in the lipopolysaccharide of Yersinia pseudotuberculosis V, have shown that the C-3 deoxygenation is a process consisting of two enzymatic steps. The first enzyme involved in this transformation is CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase (E1), which is a pyridoxamine 5'-phosphate dependent iron-sulfur protein. The second catalyst, CDP-6-deoxy-L-threo-D-glycero-4-hexulose-3-dehydrase reductase, formally called CDP-6-deoxy-delta(3,4)-glucoseen reductase (E3), is an NADH dependent plant type [2Fe-2S] containing flavoenzyme. To better understand the electron transfer carried out by these two enzymes, the potentials of the E1 and E3 redox cofactors were determined spectroelectrochemically. At pH 7.5, the midpoint potential of the E3 FAD was found to be -212 mV, with the FADox/FADsq couple (E1o') and the FADsq/FADhq couple (E2o') calculated to be -231 and -192 mV, respectively. However, the E1o' and E2o' of the FAD in E3(apoFeS) at pH 7.5 were estimated to be -215 and -240 mV, respectively, which are quite different from those of the holo-E3, suggesting a significant effect of the iron-sulfur center on the redox properties of the flavin coenzyme. Our data also showed that the midpoint potential of the E3 iron-sulfur is -257 mV and that of the E1 [2Fe-2S] center is -209 mV. These values indicated a thermodynamic barrier to the proposed electron transfer of NADH->FAD=>E3[2Fe-2S]->E1[2Fe-2S] at pH 7.5. Regulation of electron transfer by several mechanisms is possible and experiments were performed to examine ways of overcoming the unfavorable electron transfer energetics in the E1/E3 system. It was found that both binding of E3 with NAD+ and complex formation between E3 and E1 showed no effect on the midpoint potentials of the E3 FAD and iron-sulfur center. Interestingly, the midpoint potential of the E3 FAD shifts dramatically to -273 mV (E1o' approximately -345 mV and E2o' approximately -200 mV) at pH 8.4, with very little semiquinone stabilization (< 5%). The potential of the E3 [2Fe-2S] center at pH 8.4 was also found to undergo a negative shift to -279 mV, and that of the E1 iron sulfur center remained essentially the same at -206 mV. These data indicated that the redox properties of this system may be regulated by pH and the electron transfer between the E3 redox centers may be prototropically controlled. These results also demonstrated that E3 is unique among this class of enzymes.

Electron transfer properties of the R2 protein of ribonucleotide reductase from Escherichia coli.

The enzyme ribonucleotide reductase from Escherichia coli consists of two proteins, R1 and R2. The active R2 protein contains two dinuclear iron centers and the catalytically essential tyrosyl radical. We have explored the redox properties of the tyrosyl radical and estimate an apparent redox potential of +1000 +/- 100 mV (vs SHE) on the basis of the behavior of numerous mediators. The inability of most of these mediators to equilibrate with the tyrosyl radical supports the notion that the radical exists in an extremely protected hydrophobic pocket that prevents most radical scavengers from interacting with the radical, resulting in its unusual stability. The formal midpoint potential of the diiron clusters of the R2 protein was determined to be -115 +/- 2 mV at pH 7.6 and 4 degrees C. This reduction is a two-electron transfer process, making the R2 protein the first of the nonheme diiron proteins not to stabilize a mixed valence intermediate at ambient temperature. The formal midpoint potential of the dinuclear iron centers is pH dependent, exhibiting a 30 mV/pH unit variance, which indicates that one proton is accepted from the solvent per two electrons transferred to the dinuclear iron center upon reduction. The midpoint potential of the site-directed mutant Y122F R2 protein was also investigated under the same conditions, and this midpoint potential was determined to be -178 mV, providing the first direct evidence that the presence of the Y122 residue modulates the redox properties of the diiron clusters. The redox potentials of both the wild type and Y122F proteins experience cathodic shifts when measured in the presence of azide or the R1 protein. For the latter, the midpoint potentials were determined to be -226 mV for the wild type protein and -281 mV for the Y122F mutant protein, representing a negative shift of over 100 mV for both proteins. These results indicate that the presence of the Y122 residue does not influence the effect of R1 binding, that the R1 protein preferentially binds the oxidized form of R2, and that the binding of R1 acts as a regulatory control mechanism to prevent unnecessary turnover of the dinuclear iron centers.

Effect of transition-state analogues on the redox properties of medium-chain acyl-CoA dehydrogenase.

The binding of substrate/product or transition-state intermediates modifies the properties of medium-chain fatty acyl-CoA dehydrogenase (MCAD) by causing the redox potential to shift positive and the oxygen reactivity to slow by 3000-fold. Two ligands, identified as being the most effective in slowing oxygen reactivity, were 2-azaoctanoyl-CoA and 3-thiaoctanoyl-CoA [Wang, R., & Thorpe, C. (1991) Biochemistry 30, 7895-7901]. We have measured the potential shifts caused by the binding of both ligands to determine which is most similar to the potential shift caused by substrate/product mixture, the assumption being that the best transition-state structural intermediate would give the potential shift most similar to that of substrate/product [Lenn, N.D., Stankovich, M.T., & Liu, H. (1990) Biochemistry 29, 10594-10602]. Both ligands shifted the potential positive, but the shift caused by 2-azaoctanoyl-CoA was 65% that of substrate/product, while 3-thiaoctanoyl-CoA was only 20% of that value. This positive shift is proposed to be caused by a resonance form stabilized by the interaction of the catalytically essential carbonyl of the acyl-CoA with two hydrogen bonds from the enzyme, which induces a partial negative charge on the carbonyl and a partial positive charge on carbon 2 of the ligand and carbon 3 of the substrate/product couple. The X-ray structure shows that carbons 2 and 3 of the substrate/product overlap the diazadiene portion of the flavin ring [Kim, J.-J. P., Wang, M., & Paschke, R. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 7523-7527].(ABSTRACT TRUNCATED AT 250 WORDS)

Three-dimensional structure of butyryl-CoA dehydrogenase from Megasphaera elsdenii.

The crystal structure of butyryl-CoA dehydrogenase (BCAD) from Megasphaera elsdenii complexed with acetoacetyl-CoA has been solved at 2.5 A resolution. The enzyme crystallizes in the P422 space group with cell dimensions a = b = 107.76 A and c = 153.67 A. BCAD is a bacterial analog of short chain acyl-CoA dehydrogenase from mammalian mitochondria. Mammalian acyl-CoA dehydrogenases are flavin adenine dinucleotide (FAD)-containing enzymes that catalyze the first step in the beta-oxidation of fatty acids. Although specific for substrate chain lengths, they exhibit high sequence homology. The structure of BCAD was solved by the molecular replacement method using the atomic coordinates of pig liver medium chain acyl-CoA dehydrogenase (MCAD). The structure was refined to an R-factor of 19.3%. The overall polypeptide fold of BCAD is similar to that of MCAD. E367 in BCAD is at the same position and in a similar conformation as the catalytic base in MCAD, E376. The main enzymatic differences between BCAD and MCAD are their substrate specificities and the significant oxygen reactivity exhibited by BCAD but not by MCAD. The substrate binding cavity of BCAD is relatively shallow compared to that of MCAD, as consequences of both a single amino acid insertion and differences in the side chains of the helices that make the binding site. The si-face of the FAD in BCAD is more exposed to solvent than that in MCAD. Therefore solvation can stabilize the superoxide anion and considerably increase the rate of oxidation of reduced flavin in the bacterial enzyme.

Oxidation-reduction properties of short-chain acyl-CoA dehydrogenase: effects of substrate analogs.

Redox potentials of short-chain acyl-CoA dehydrogenase from the anaerobe, Megasphaera elsdenii, have been determined by means of uv-visible spectroelectrochemistry in the presence of substrate analogs. During redox titrations in the presence of 2-azabutyryl-CoA, up to 85% anionic FAD semiquinone was stabilized with a molar absorbance at 387 nm of 19 mM-1 cm-1. Despite a slow reduction of short-chain acyl-CoA dehydrogenase by 2-azabutyryl-CoA (< 2% reduction/h), a dissociation constant of 0.7 microM was measured and redox potentials, E1(0') and E2(0'), of -0.07 and -0.17 V, respectively, were determined at pH 7.0 for the first and second electrons in reduction of the FAD of short-chain acyl-CoA dehydrogenase. The analog, 2-azoctanoyl-CoA, did not reduce short-chain acyl-CoA dehydrogenase, bound with a dissociation constant of 2 microM, stabilized up to 47% anionic FAD semiquinone, and gave values of -0.08 and -0.11 V for E1(0') and E2(0') at pH 6.9. In contrast to 2-aza-acyl-CoA, the thioethers, butyl-CoA, octyl-CoA, and allyl-CoA, and the thioester, acetyl-CoA, did not bind strongly (Kd > or = 50 microM) and caused no significant change in the redox properties of short-chain acyl-CoA dehydrogenase. The two-electron redox potential, Em, remained at -0.08 V at pH 7.0 and there was no stabilization of FAD semiquinone in the presence of these analogs. These results show that no single feature of substrate structure, the thioester carbonyl, the presence of 2,3-unsaturation, or a fatty alkyl chain of appropriate length, can account for the 0.06-V positive change in redox potential which is observed in the presence of the substrate couple, crotonyl-CoA/butyryl-CoA (M. T. Stankovich and S. Soltysik (1987) Biochemistry 26 2627-2632). As outlined above, 2-azabutyryl-CoA or 2-azaoctanoyl-CoA did cause marked changes in the redox properties of short-chain acyl-CoA dehydrogenase, but the preferential stabilization of FAD semiquinone and negative change in Em distinguish the effects of 2-azaacyl-CoA from those of the substrate couple.

Product binding modulates the thermodynamic properties of a Megasphaera elsdenii short-chain acyl-CoA dehydrogenase active-site mutant.

Previous work has shown that the redox properties of Megasphaera elsdenii short-chain acyl-CoA dehydrogenase (SCAD) are specifically modulated upon the binding of the substrate/product couple, allowing the reaction to proceed thermodynamically [Stankovich, M.T., & Soltysik, S. (1987) Biochemistry 26, 2627-2632]. The focus of this study on the Glu367Gln SCAD mutant protein is to gain an understanding of this phenomenon. The active-site mutant Glu367Gln SCAD inactivates the reductive and oxidative pathways and allows the effects of substrate (butyryl-CoA) and product (crotonyl-CoA) binding on the redox properties of the Glu367Gln SCAD mutant protein to be determined separately. Red anionic semiquinone was found to be thermodynamically stabilized in coulometric/potentiometric reductions of both butyryl-CoA- and crotonyl-CoA-complexed Glu367Gln SCAD. Reduction potential measurements showed that butyryl-CoA binding has little effect on the reduction potential of Glu367Gln SCAD. Crotonyl-CoA complexation, however, shifted the reduction potential of the Glu367Gln SCAD mutant protein by 30 mV in the positive direction. This modulation is similar to the 60-mV positive shift observed in native M. elsdenii SCAD upon complexation with the substrate/product couple [Stankovich, M.T., & Soltysik, S. (1987) Biochemistry 26, 2627-2632]. Thus, product binding and not substrate binding, thermodynamically regulates M. elsdenii SCAD. We propose that this observation is best explained by assuming that the product resembles an intermediate in the catalytic mechanism that is responsible for facilitating isopotential electron transfer from the substrate to the enzyme.

Oxidation-reduction potentials of the methane monooxygenase hydroxylase component from Methylosinus trichosporium OB3b.

Methane monooxygenase (MMO) isolated from Methylosinus trichosporium OB3b consists of hydroxylase (MMOH), reductase (MMOR), and "B" (MMOB) protein components. MMOH contains two oxygen-bridged dinuclear iron clusters that are the sites of O2 activation and hydrocarbon oxidation. Each cluster can be stabilized in diferric [Fe(III).Fc(III)], mixed-valence [Fe(II).Fe(III)], and diferrous [Fe(II).Fe(II)] redox states. We have correlated the EPR spin quantitation of the S = 1/2 mixed-valence state with the system electrode potential to determine both formal redox potential values for MMOH at 4 degrees C: E1 degrees' = +76 +/- 15 mV and E2 degrees' = +21 +/- 15 mV (Em = +48 mV, 61% maximum mixed-valence state). Complementary Mössbauer studies of 57Fe-enriched MMOH allowed all three redox states to be quantitated simultaneously in individual samples and revealed that the distribution of redox states was in accord with the measured potential values. EPR spectra of partially reduced MMOH showed that the apparent midpoint potential values of MMOH-MMOR, MMOH-MMOR-MMOB, and MMOH-MMOR-MMOB-substrate complexes were slightly more positive than that of MMOH alone. In contrast, the MMOH-MMOB complex appeared to have a substantially more negative redox potential. The formal redox potential values of the latter complex were determined to be E1 degrees' = -52 +/- 15 mV and E2 degrees' = -115 +/- 15 mV, respectively, at 4 degrees C (Em = -84 mV, 65% maximum mixed-valence state). This negative 132-mV shift in the midpoint potential of MMOH coupled to MMOB binding suggests that MMOB binds approximately 10(4) more strongly to the diferric state of MMOH than to the diferrous state. Since the potential shift is strongly negative, and since a nearly constant separation between the two formal potential values of MMOH is maintained when MMOB binds, the role of the MMOB-MMOH complex must not be to thermodynamically stabilize the formation of the diferrous cluster which is the form that reacts with O2 during catalysis. However, MMOB binding may provide kinetic stabilization of the diferrous state and/or modulation of the interaction of MMOH with O2 and hydrocarbon substrates. Such roles may be effected through cyclic association and dissociation of the MMOB-MMOH complex as MMOH oscillates between redox states during catalysis, thereby dynamically altering the affinity of this complex.

Characterization of wild-type and an active-site mutant in Escherichia coli of short-chain acyl-CoA dehydrogenase from Megasphaera elsdenii.

The objective of this work is to determine the molecular mechanism and regulation of short-chain acyl-CoA dehydrogenase (SCAD) from Megasphaera elsdenii. To achieve this, the gene coding for SCAD from M. elsdenii was cloned and sequenced. Site-directed mutagenesis was then used to identify an amino acid residue that is required for the proposed mechanism. To clone the gene, the amino acid sequence of the 50 N-terminal residues of SCAD from M. elsdenii was determined. This sequence information was utilized to synthesize two sets of mixed oligonucleotide primers which were then used to generate a 120-bp specific probe from M. elsdenii DNA by the polymerase chain reaction (PCR) method. The 120-bp probe was used to screen a M. elsdenii genomic DNA library cloned into Escherichia coli. The gene encoding M. elsdenii SCAD was identified from this library, sequenced, and expressed. The cloned SCAD gene contained an open reading frame which revealed a high degree of sequence identity with an open reading frame protein sequence of the human SCAD and the rat medium-chain acyl-CoA dehydrogenase (MCAD) (44% and 36% identical residues in paired comparisons for human SCAD and rat MCAD, respectively). Recombinant SCAD expressed from a pUC119 vector accounted for 35% of the cytosolic protein in the Escherichia coli crude extract. The expressed protein had similar activity, redox potential properties, and nearly identical amino acid composition to native M. elsdenii SCAD. In addition, a site-directed Glu367 Gln mutant of SCAD expressed from a pUC119 vector was shown to have minimal reductive and oxidative pathway activity with butyryl-CoA and crotonyl-CoA, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)

Influence of two substrate analogues on thermodynamic properties of medium-chain acyl-CoA dehydrogenase.

The objective of this work was to identify the key structural functionalities of substrate or product that modulate the thermodynamic properties of medium-chain acyl-CoA dehydrogenase (MCAD). In order to achieve this, two classes of substrate analogues, acetyl-CoA and thioether-CoAs, were complexed with MCAD and their effects on the redox properties of MCAD were measured. A pH dependence study of the redox potential of uncomplexed MCAD allowed us to compare redox properties between complexed and uncomplexed MCAD and to calculate the dissociation constants of the analogues to the three redox states of MCAD. The results from this work indicate that these analogues are not influencing the thermodynamic behavior of MCAD in the same way as natural substrate. Thus, we propose that the following two key structural features of the binding ligand are necessary for mimicking the thermodynamic effects natural substrate has on MCAD: a thioester carbonyl on carbon 1 and a fatty acyl-CoA chain length around 8 carbon units. Furthermore, with the advent of structural knowledge, insights into the interactions of these structural features with MCAD and their influence on MCAD's highly regulated dehydrogenation mechanism are discussed.