Energetic consequences of accommodating a bulkier ligand at the active site of medium chain acyl-CoA dehydrogenase by creating a complementary enzyme site cavity

The substitution of the C=O by the C=S group in 2-azaoctanoyl-CoA increases the volume of the ligand by 11 A(3), and the excision of a methylene group from Glu-376, via Glu-376 --> Asp (E376D) mutation in medium chain acyl-CoA dehydrogenase (MCAD), creates a complementary cavity of 18 A(3) dimension, just opposite to the ligand's carbonyl group. We investigated whether the newly created cavity would facilitate accommodation of the bulkier (C=O --> C=S substituted) ligand within the active site of the enzyme. To ascertain this, we determined the binding affinity and kinetics of association and dissociation of 2-azaoctanoyl-CoA and the C=O --> C=S substituted ligand, 2-azadithiooctanoyl-CoA, involving the wild-type and Glu-376 --> Asp mutant enzymes. The experimental data revealed that the binding of 2-azadithiooctanoyl-CoA to the wild-type enzyme was energetically unfavorable as compared to 2-azaoctanoyl-CoA. However, such an energetic constraint was alleviated for the binding of the former ligand to the E376D mutant enzyme site. A detailed account of the free energy and enthalpic profiles for the binding of 2-azaoctanoyl-CoA and 2-azadithiooctanoyl-CoA to the wild-type and Glu-376 --> Asp mutant enzymes throws light on the flexibility of the enzyme site cavity in stabilizing the ground and transition states of the enzyme-ligand complexes.     

Interaction of acyl coenzyme A substrates and analogues with pig kidney medium-chain acyl-coA dehydrogenase

Several alkylthio coenzyme A (CoA) derivatives (from ethyl- to hexadecyl-SCoA) have been synthesized to probe the substrate binding site in the flavoprotein medium-chain acyl-CoA dehydrogenase from pig kidney. All bind to apparently equivalent sites with a stoichiometry of four per tetramer. A plot of log Kd vs: hydrocarbon chain length is linear from 2 to 16 carbons with a free energy of binding of 390 cal/methylene group. These data suggest an acyl-binding site of moderate hydrophobicity and imply that the observed substrate specificity of the medium-chain dehydrogenase is not achieved simply by the length of the hydrocarbon binding pocket. Extrapolation of the graph to zero chain length predicts a Kd of 1 mM for the CoA moiety. The difference between this value and the experimentally determined value of 206 microM may be attributed to a contribution from the ionization of the sulfhydryl group in CoASH. The interaction of several eight-carbon intermediates of beta-oxidation (trans-2- and trans-3-octenoyl-CoA and L-3-hydroxy- and 3-ketooctanoyl-CoA) with the dehydrogenase has also been studied. All but the L-3-OH derivative bind tightly to the enzyme (with Kd values in the 50-90 nM range) and are very effective inhibitors of the dehydrogenation of octanoyl-CoA. The trans-3-enoyl analogue produces an immediate, intense, long-wavelength band (lambda max = 820 nm), which probably represents a charge-transfer interaction between the delocalized alpha-carbanion donor and oxidized flavin as the acceptor. The L-3-OH analogue is a reductant of the flavin, yielding 3-ketooctanoyl-CoA.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanistic investigation of medium-chain fatty acyl-CoA dehydrogenase utilizing 3-indolepropionyl/acryloyl-CoA as chromophoric substrate analogues.

The CoA derivative 3-indolepropionyl-CoA (IPCoA) serves as a competent pseudosubstrate for the medium-chain fatty acyl-CoA dehydrogenase (MCAD)-catalyzed reaction. The reaction product trans-3-indoleacryloyl-CoA (IACoA) exhibits a characteristic UV-vis absorption spectrum with lambda max = 367 nm and epsilon 367 = 26,500 M-1 cm-1. The chromophoric nature of IACoA allows us to measure the direct conversion of substrate to product (at 367 nm) without recourse to absorption signals for either the enzyme-bound flavin or the coupling electron acceptors, as well as probe the enzyme site environment. The interaction of IACoA with medium chain fatty acyl-CoA dehydrogenase (MCAD)-FAD is characterized by resultant (spectra of the mixture minus the individual components) absorption peaks at 490, 417, and 355 nm. These absorption peaks increase in magnitude as the pH of the buffer media decreases. Transient kinetic analysis for the interaction of MCAD-FAD with IACoA suggests that the formation of the enzyme-IACoA complex proceeds in two steps. The first (fast) step involves the formation of an E-IACoA collision complex, which [formula: see text] is isomerized (concomitant with changes in the protein structure) to an E*-IACoA complex in the second (slow) step. We have studied the effect of pH on Kc, k2, and k-2. While Kc shows practically no dependence on pH (within a 2-fold variation between pH 6.0 and 9.5), k2 and k-2 show a strong dependence on pH. Both k2 and k-2 exhibit a sigmoidal dependence on the pH of the buffer media, with pKa's of 7.53 and 8.30, respectively. In accordance with the model presented herein, the pKa of 7.53 represents an enzyme site group which is involved in the interaction with IACoA within the E-IACoA collision complex. This pKa is perturbed to 8.30 upon isomerization of the collision complex. The pH-dependent changes in k2 and k-2 are such that the equilibrium distribution between E-IACoA and E*-IACoA is favored to the latter complex (by about 20-fold) at lower pH than at higher pH. A cumulative account of the spectral, kinetic, and thermodynamic properties of the enzyme-IACoA complexes has allowed us delineate the microscopic pathway by which the E-IACoA isomerization (presumably via protein conformational changes) is coupled to the proton equilibration steps.     

Octopus photoreceptor membranes. Surface charge density and pK of the Schiff base of the pigments.

The chromophore of octopus rhodopsin is 11-cis retinal, linked via a protonated Schiff base to the protein backbone. Its stable photoproduct, metarhodopsin, has all-trans retinal as its chromphore. The Schiff base of acid metarhodopsin (lambda max = 510 nm) is protonated, whereas that of alkaline metarhodopsin (lambda max = 376 nm) is unprotonated. Metarhodopsin in photoreceptor membranes was titrated and the apparent pK of the Schiff base was measured at different ionic strengths. From these salt-dependent pKs the surface charge density of the octopus photoreceptor membranes and the intrinsic Schiff base pK of metarhodopsin were obtained. The surface charge density is sigma = -1.6 +/- 0.1 electronic charges per 1,000 A2. Comparison of the measured surface charge density with values from octopus rhodopsin model structures suggests that the measured value is for the extracellular surface and so the Schiff base in metarhodopsin is freely accessible to protons from the extracellular side of the membrane. The intrinsic Schiff base pK of metarhodopsin is 8.44 +/- 0.12, whereas that of rhodopsin is found to be 10.65 +/- 0.10 in 4.0 M KCl. These pK values are significantly higher than the pK value around 7.0 for a retinal Schiff base in a polar solvent; we suggest that a plausible mechanism to increase the pK of the retinal pigments is the preorganization of their chromophore-binding sites. The preorganized site stabilizes the protonated Schiff base with respect to the unprotonated one. The difference in the pK for the octopus rhodopsin compared with metarhodopsin is attributed to the relative freedom of the latter's chromophore-binding site to rearrange itself after deprotonation of the Schiff base.     

Mechanism-based inactivation of human glutaryl-CoA dehydrogenase by 2-pentynoyl-CoA: rationale for enhanced reactivity

2-Pentynoyl-CoA inactivates glutaryl-CoA dehydrogenase at a rate that considerably exceeds the rates of inactivation of short chain and medium chain acyl-CoA dehydrogenases by this inhibitor and related 2-alkynoyl-CoAs. To determine the rate of inactivation by 2-pentynoyl-CoA, we investigated the inactivation in the presence of a non-oxidizable analog, 3-thiaglutaryl-CoA, which competes for the binding site. The enhanced rate of inactivation does not reflect an alteration in specificity for the acyl group, nor does it reflect the covalent modification of a residue other than the active site glutamate. In addition to determining the inactivation of catalytic activity a spectral intermediate was detected by stopped-flow spectrophotometry, and the rate constants of formation and decay of this charge transfer complex (lambdamax approximately 790 nm) were determined by global analysis. Although the rate-limiting step in the inactivation of the other acyl-CoA dehydrogenases can involve the abstraction of a proton at C-4, this is not the case with glutaryl-CoA dehydrogenase. Glutaryl-CoA dehydrogenase is also differentiated from other acyl-CoA dehydrogenases in that the catalytic base must access both C-2 and C-4 in the normal catalytic pathway. Access to C-4 is not obligatory for the other dehydrogenases. Analysis of the distance from the closest carboxylate oxygen of the glutamate base catalyst to C-4 of a bound acyl-CoA ligand for medium chain, short chain, and isovaleryl-CoA dehydrogenases suggests that the increased rate of inactivation reflects the carboxylate oxygen to ligand C-4 distance in the binary complexes. This distance for wild type glutaryl-CoA dehydrogenase is not known. Comparison of the rate constants of inactivation and formation of a spectral species between wild type glutaryl-CoA dehydrogenase and a E370D mutant are consistent with the idea that this distance in glutaryl-CoA dehydrogenase contributes to the enhanced rate of inactivation and the 1,3-prototropic shift catalyzed by the enzyme.     

Iron-bleomycin interactions with oxygen and oxygen analogues. Effects on spectra and drug activity.

Despite extensive structural dissimilarities, iron . bleomycin complexes and heme-containing oxygenases display remarkable similarities in binding oxygen antagonists and in spectral properties deriving from bound iron. Fe(II)-bleomycin reversibly forms a complex with either CO or isocyanide (lambda max = 384 and 497 nm, respectively), either of which interfere with its oxygen-dependent cleavage of DNA. A similar but paramagnetic complex forms with NO (lambda max = 470 nm; AN = 24 G). In contrast, cyanide enhances bleomycin activity against DNA. Complexes of bleomycin and FE(III), formed either by direct association or by autoxidation of the Fe(II) . bleomycin complex, exhibit indistinguishable EPR and visible spectra, which change characteristically with pH. At neutral pH, Fe(III) . bleomycin is a low spin complex (g = 2.45, 2.18, 1.89; lambda max = 365, 384 nm) and, at low pH, it is a high spin rhombic complex (geff = 9.4, 4.3; lambda max = 430 nm). These complexes are interconvertible (pK 4.3). Fe(II) . bleomycin oxidation, although reversible by spectral criteria, is accompanied by drug inactivation unless DNA is present.     

Spectral properties of bacterial nitric-oxide reductase: resolution of pH-dependent forms of the active site heme b3

Bacterial nitric-oxide reductase catalyzes the two electron reduction of nitric oxide to nitrous oxide. In the oxidized form the active site non-heme Fe(B) and high spin heme b(3) are mu-oxo bridged. The heme b(3) has a ligand-to-metal charge transfer band centered at 595 nm, which is insensitive to pH over the range of 6.0-8.5. Partial reduction of nitric-oxide reductase yields a three electron-reduced state where only the heme b(3) remains oxidized. This results in a shift of the heme b(3) charge transfer band lambda(max) to longer wavelengths. At pH 6.0 the charge transfer band lambda(max) is 605 nm, whereas at pH 8.5 it is 635 nm. At pH 6.5 and 7.5 the nitric-oxide reductase ferric heme b(3) population is a mixture of both 605- and 635-nm forms. Magnetic circular dichroism spectroscopy suggests that at all pH values examined the proximal ligand to the ferric heme b(3) in the three electron-reduced form is histidine. At pH 8.5 the distal ligand is hydroxide, whereas at pH 6.0, when the enzyme is most active, it is water.     

Role of histidine 42 in ascorbate peroxidase. Kinetic analysis of the H42A and H42E variants.

To examine the role of the distal His42 residue in the catalytic mechanism of pea cytosolic ascorbate peroxidase, two site-directed variants were prepared in which His42 was replaced with alanine (H42A) or glutamic acid (H42E). Electronic spectra of the ferric derivatives of H42A and H42E (pH 7.0, mu = 0.10 m, 25.0 degrees C) revealed wavelength maxima [lambda(max) (nm): 397, 509, approximately equal to 540(sh), 644 (H42A); 404, 516, approximately equal to 538(sh), 639 (H42E)] consistent with a predominantly five-co-ordinate high-spin iron. The specific activity of H42E for oxidation of L-ascorbate (8.2 +/- 0.3 U.mg(-1)) was approximately equal to 30-fold lower than that of the recombinant wild-type enzyme (rAPX); the H42A variant was essentially inactive but activity could be partially recovered by addition of exogenous imidazoles. The spectra of the Compound I intermediates of H42A [lambda(max) (nm) = 403, 534, 575(sh), 645] and H42E [lambda(max) (nm) = 404, 530, 573(sh), 654] were similar to those of rAPX. Pre-steady-state data for formation of Compound I for H42A and H42E were consistent with a mechanism involving accumulation of a transient enzyme intermediate (K(d)) followed by conversion of this intermediate into Compound I (k'(1)). Values for k'(1) and K(d) were, respectively, 4.3 +/- 0.2 s(-1) and 30 +/- 2.0 mM (H42A) and 28 +/- 1.0 s(-1) and 0.09 +/- 0.01 mM (H42E). Photodiode array experiments for H42A revealed wavelength maxima for this intermediate at 401 nm, 522 nm and 643 nm, consistent with the formation of a transient [H42A-H(2)O(2)] species. Rate constants for Compound I formation for H42A were independent of pH, but for rAPX and H42E were pH-dependent [pKa = 4.9 +/- 0.1 (rAPX) and pK(a) = 6.7 +/- 0.2 (H42E)]. The results provide: (a) evidence that His42 is critical for Compound I formation in APX; (b) confirmation that titration of His42 controls Compound I formation and an assignment of the pK(a) for this group; (c) mechanistic and spectroscopic evidence for an intermediate before Compound I formation; (d) evidence that a glutamic acid residue at position 42 can act as the acid-base catalyst in ascorbate peroxidase.     

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.     

Carboxymethylated liver alcohol dehydrogenase: kinetic and thermodynamic characterization of reactions with substrates and inhibitors

Liver alcohol dehydrogenase (LADH) carboxymethylated at Cys-46 (CMLADH) forms two different ternary complexes with 4-trans-(N,N-dimethylamino)cinnamaldehyde (DACA). The complex with reduced nicotinamide adenine dinucleotide (NADH) is characterized by a 38-nm red shift of the long-wavelength pi, pi* transition to 436 nm, while the complex with oxidized nicotinamide adenine dinucleotide (NAD+) is characterized by a 60-nm red shift to 458 nm. CMLADH also forms a ternary complex with NAD+ and the Z isomer of 4-trans-(N,N-dimethylamino)cinnamaldoxime in which the absorption of the oxime (lambda max = 354 nm) is red shifted 80 nm to 434 nm. Pyrazole and 4-methylpyrazole are weak competitive inhibitors of ligand binding to the substrate site of native LADH. These inhibitors were found to form ternary complexes with CMLADH and NADH which are more stable than the corresponding complexes with the native enzyme. The transient reductions of the aldehydes DACA and p-nitrobenzaldehyde (NBZA) were studied under single-turnover conditions. Carboxymethylation decreases the DACA reduction rate 80-fold and renders the process essentially independent of pH over the region 5-9, whereas this process depends on a pKa of 6.0 in the native enzyme. At pH 7.0, the rate constant for NBZA reduction also is decreased at least 80-fold to a value of 7.7 +/- 0.3 s-1. Since primary kinetic isotope effects are observed when NADH is substituted with (4R)-4-deuterio-NADH (kH/kD = 3.0 for DACA and kH/kD = 2.3 for NBZA), the rate-limiting step for both aldehydes involves hydride transfer. The altered pH dependence is concluded to be due to an increase in the pK value of the zinc-coordinated DACA-alcohol in the ternary complex with NAD+ by more than 3 units. This perturbation is brought about by the close proximity of the negatively charged carboxymethyl carboxylate.     

Dual photoactive species in Glu46Asp and Glu46Ala mutants of photoactive yellow protein: a pH-driven color transition.

Photoactive yellow protein (PYP) is a blue light sensor present in the purple photosynthetic bacterium Ectothiorhodospira halophila, which undergoes a cyclic series of absorbance changes upon illumination at its lambda(max) of 446 nm. The anionic p-hydroxycinnamoyl chromophore of PYP is covalently bound as a thiol ester to Cys69, buried in a hydrophobic pocket, and hydrogen-bonded via its phenolate oxygen to Glu46 and Tyr42. The chromophore becomes protonated in the photobleached state (I(2)) after it undergoes trans-cis isomerization, which results in breaking of the H-bond between Glu46 and the chromophore and partial exposure of the phenolic ring to the solvent. In previous mutagenesis studies of a Glu46Gln mutant, we have shown that a key factor in controlling the color and photocycle kinetics of PYP is this H-bonding system. To further investigate this, we have now characterized Glu46Asp and Glu46Ala mutants. The ground-state absorption spectrum of the Glu46Asp mutant shows a pH-dependent equilibrium (pK = 8.6) between two species: a protonated (acidic) form (lambda(max) = 345 nm), and a slightly blue-shifted deprotonated (basic) form (lambda(max) = 444 nm). Both of these species are photoactive. A similar transition was also observed for the Glu46Ala mutant (pK = 7.9), resulting in two photoactive red-shifted forms: a basic species (lambda(max) = 465 nm) and a protonated species (lambda(max) = 365 nm). We attribute these spectral transitions to protonation/deprotonation of the phenolate oxygen of the chromophore. This is demonstrated by FT Raman spectra. Dark recovery kinetics (return to the unphotolyzed state) were found to vary appreciably between these various photoactive species. These spectral and kinetic properties indicate that the hydrogen bond between Glu46 and the chromophore hydroxyl group is a dominant factor in controlling the pK values of the chromophore and the glutamate carboxyl.     

The reductive half-reaction in Acyl-CoA dehydrogenase from pig kidney: studies with thiaoctanoyl-CoA and oxaoctanoyl-CoA analogues

Thia- and oxaoctanoyl-CoA derivatives (substituted at the C-3 and C-4 positions) have been synthesized to prove the reductive half-reaction in the medium-chain acyl-CoA dehydrogenase from pig kidney. 3-Thiaoctanoyl-CoA binds to this flavoenzyme, forming an intense, stable, long-wavelength band (at 804 nm; extinction coefficient = 8.7 mM-1 cm-1 at pH 7.6). The intensity of this band increases about 20% from pH 6.0 to pH 8.8. This long-wavelength species probably represents a charge-transfer complex between bound acyl enolate as the donor and oxidized flavin adenine dinucleotide as the acceptor. Thus, the enzyme catalyzes alpha-proton exchange, and no long-wavelength bands are seen with 3-thiaoctyl-CoA (where the carbonyl moiety is replaced by a methylene group). 3-Oxaoctanoyl-CoA binds comparatively weakly to the dehydrogenase, with a long-wavelength band at 780 nm which is both less intense and less stable than the corresponding thia analogue. These data suggest that the enzyme can accomplish alpha-proton abstraction from certain weakly acidic acyl-CoA derivatives, without concerted transfer of a hydride equivalent to the flavin. 4-Thiaoctanoyl-CoA is dehydrogenated in the standard assay 1.5-fold faster than octanoyl-CoA. Titrations of the medium-chain dehydrogenase with the 4-thia derivative resemble those obtained with octanoyl-CoA, except for the contribution of the strongly absorbing 4-thia-trans-2-octenoyl-CoA product. The corresponding 4-oxa analogue is a much poorer substrate (10% of the rate shown by octanoyl-CoA) but again effects substantially complete reduction of the flavin chromophore in the dehydrogenase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Evidence that cysteine 298 is in the active site of tryptophan indole-lyase

Escherichia coli tryptophan indole-lyase (tryptophanase) mutants, with cysteine residues 294 and 298 selectively replaced by serines, have been prepared by site-directed mutagenesis. Both mutant enzymes are highly active for beta-elimination reactions measured with both L-tryptophan and S-(o-nitrophenyl)-L-cysteine. The Cys-294----Ser mutant enzyme is virtually identical to the wild type with respect to pyridoxal phosphate binding (KCO = 2 microM), cofactor absorption spectrum (lambda max = 420 and 337 nm) and pH dependence (pK alpha = 7.3), pH profile for catalysis, and rate of bromopyruvic acid inactivation. In contrast, the Cys-298----Ser mutant enzyme exhibits a reduced affinity for pyridoxal phosphate (KCO = 6 microM), a shift in the cofactor absorption spectrum to 414 nm and an altered pK alpha = 8.5, an alkaline shift in the pH profile for catalysis, and resistance to inactivation of the apoenzyme by bromopyruvic acid. The C298S mutant enzyme (wherein cysteine 298 is altered to serine) also undergoes an isomerization to an unreactive state upon storage at 4 degrees C. These results demonstrate that the sulfhydryl groups of Cys-294 and Cys-298 are catalytically nonessential. However, these data suggest that Cys-298 is located within or very near the active site of the enzyme and is the reactive cysteine residue previously observed by others.     

Catalytic oxidation of 2,4,5-trihydroxyphenylalanine by tyrosinase: identification and evolution of intermediates.

The oxidation of 3,4-dihydroxyphenylalanine (dopa) by O2 catalyzed by tyrosinase yields 4-(2-carboxy-2-aminoethyl)-1,2-benzoquinone, with its amino group protonated (o-dopaquinone-H+). This evolves non-enzymatically through two branches (cyclization and/or hydroxylation), whose respective operations are determined by pH. The hydroxylation branch of o-dopaquinone-H+ only operates significantly at pH < or = 5.0 and involves the accumulation of 2,4,5-trihydroxyphenylalanine (topa), which has been detected by high-performance liquid chromatography (HPLC). This last compound is also a substrate of tyrosinase. The oxidation of topa by both tyrosinase and periodate yields 5-(2-carboxy-2-aminoethyl)-4-hydroxy-1,2-benzoquinone, with its amino group protonated (o-topaquinone-H+), which is red (RTQH) (lambda max 272-485 nm) at pH 7.0 and yellow (TTQH) (lambda max 265-390 nm) at pH 3.0. This is based on pKa 4.5 of the 2-OH group of the benzene ring of o-topaquinone-H+, as derived from spectrophotometric and HPLC assays. At physiological pH, RTQH undergoes deprotonation of the ammonium group of the side chain to yields RTQ, which cyclize into 2-carboxy-2,3-dihydroxyindolen-5,6-quinone (dopachrome), with a 1:1 stoichiometry and first-order kinetics. The evolution of RTQH has been analyzed by spectrophotometry, HPLC, cyclic voltammetry and constant potential electrolytic assays. From HPLC assays, the value of the first-order constant for the evolution of RTQH at pH 7.0 (kRTQHapp 4.83 x 10(-5) s-1), as well as of the rate constant for the cyclization step of RTQ (kRTQc 2.53 x 10(-3) s-1) were determined.     

Acyl-CoA dehydrogenases. A mechanistic overview.

Acyl-CoA dehydrogenases constitute a family of flavoproteins that catalyze the alpha,beta-dehydrogenation of fatty acid acyl-CoA conjugates. While they differ widely in their specificity, they share the same basic chemical mechanism of alpha,beta-dehydrogenation. Medium chain acyl-CoA dehydrogenase is probably the best-studied member of the class and serves as a model for the study of catalytic mechanisms. Based on medium chain acyl-CoA dehydrogenase we discuss the main factors that bring about catalysis, promote specificity and determine the selective transfer of electrons to electron transferring flavoprotein. The mechanism of alpha,beta-dehydrogenation is viewed as a process in which the substrate alphaC-H and betaC-H bonds are ruptured concertedly, the first hydrogen being removed by the active center base Glu376-COO- as an H+, the second being transferred as a hydride to the flavin N(5) position. Hereby the pKa of the substrate alphaC-H is lowered from > 20 to approximately 8 by the effect of specific hydrogen bonds. Concomitantly, the pKa of Glu376-COO- is also raised to 8-9 due to the decrease in polarity brought about by substrate binding. The kinetic sequence of medium chain acyl-CoA dehydrogenase is rather complex and involves several intermediates. A prominent one is the molecular complex of reduced enzyme with the enoyl-CoA product that is characterized by an intense charge transfer absorption and serves as the point of transfer of electrons to the electron transferring flavoprotein. These views are also discussed in the context of the accompanying paper on the three-dimensional properties of acyl-CoA dehydrogenases.     

Beyond the proton abstracting role of Glu-376 in medium-chain acyl-CoA dehydrogenase: influence of Glu-376-->Gln substitution on ligand binding and catalysis

The active site residue, Glu-376, of medium-chain acyl-CoA dehydrogenase (MCAD) has been known to abstract the alpha-proton from acyl-CoA substrates during the course of the reductive half-reaction. The site-specific mutation of Glu-376-->Gln(E376Q) slows down the octanoyl-CoA-dependent reductive half-reaction of the enzyme by about 5 orders of magnitude due to impairment in the proton-transfer step. To test whether the carboxyl group of Glu-376 exclusively serves as the active site base (for abstracting the alpha-proton) during the enzyme catalysis, we undertook a detailed kinetic investigation of the enzyme-ligand interaction and enzyme catalysis, utilizing octanoyl-CoA/octenoyl-CoA as a physiological substrate/product pair and the wild-type and E376Q mutant enzymes as the catalysts. The transient kinetic data revealed that the E376Q mutation not only impaired the rate of octanoyl-CoA-dependent reduction of the enzyme-bound FAD, but also impaired the association and dissociation rates for the binding of the reaction product, octenoyl-CoA. Besides, the E376Q mutation correspondingly impaired the kinetic profiles for the quenching of the intrinsic protein fluorescence during the course of the above diverse (i.e., "chemistry" versus "physical interaction") processes. A cumulative account of the experimental data led to the suggestion that the carboxyl group of Glu-376 of MCAD is intimately involved in modulating the microscopic environment (protein conformation) of the enzyme's active site during the course of ligand binding and catalysis. Arguments are presented that the electrostatic interactions among Glu-376, FAD, and CoA-ligands are responsible for structuring the enzyme's active site cavity in the ground and transition states of the enzyme during the above physicochemical processes.     

Reversible denaturation of Aequorea green-fluorescent protein: physical separation and characterization of the renatured protein

The green-fluorescent protein (GFP) that functions as a bioluminescence energy transfer acceptor in the jellyfish Aequorea has been renatured with up to 90% yield following acid, base, or guanidine denaturation. Renaturation, following pH neutralization or simple dilution of guanidine, proceeds with a half-recovery time of less than 5 min as measured by the return of visible fluorescence. Residual unrenatured protein has been quantitatively removed by chromatography on Sephadex G-75. The chromatographed, renatured GFP has corrected fluorescence excitation and emission spectra identical with those of the native protein at pH 7.0 (excitation lambda max = 398 nm; emission lambda max = 508 nm) and also at pH 12.2 (excitation lambda max = 476 nm; emission lambda max = 505 nm). With its peak position red-shifted 78 nm at pH 12.2, the Aequorea GFP excitation spectrum more closely resembles the excitation spectra of Renilla (sea pansy) and Phialidium (hydromedusan) GFPs at neutral pH. Visible absorption spectra of the native and renatured Aequorea green-fluorescent proteins at pH 7.0 are also identical, suggesting that the chromophore binding site has returned to its native state. Small differences in far-UV absorption and circular dichroism spectra, however, indicate that the renatured protein has not fully regained its native secondary structure.     

Differences between the electric fields of the catalytic sites of papain and actinidin detected by using the thiol-located nitrobenzofurazan label as a spectroscopic reporter group.

The catalytic-site thiol groups of papain (EC 3.4.22.2) and actinidin (EC 3.4.22.14) were each labelled with the nitrobenzofurazan (Nbf) chromophore by reaction with 4-chloro-7-nitrobenzofurazan at pH 4.4. The electronic-absorption spectra of both labelled enzymes were determined in aqueous solution, in the pH ranges approx. 2-5 for S-Nbf-papain and approx. 3.3-8 for S-Nbf-actinidin, and for the latter also in 6 M-guanidinium chloride. The spectrum of S-Nbf-papain is characterized by lambda max. = 402 nm at pH 5 and by lambda max. = 422 nm at pH 2.18. The pH-dependent shift in lambda max. accompanies a pH-dependent change in A 430, the nature of which is consistent with its dependence on a single ionizing group with pKa 3.7. The spectrum of S-Nbf-actinidin is pH-independent in the pH range approx. 3.3-8 and is characterized by lambda max. = 413 nm. This absorption maximum shifts to 425 nm in 6M-guanidinium chloride. These results are discussed and related to those reported previously from studies on papain and actinidin with various reactivity probes. Despite the close similarity in the catalytic sites of papain and actinidin deduced from X-ray-diffraction studies, the considerable differences in their reactivity characteristics are mirrored by differences in their electric fields detected by the Nbf spectroscopic label. The microenvironment in the catalytic site of actinidin appears to favour the existence of ions significantly more than in the corresponding region in papain.     

Resonance Raman spectroscopy of pyridoxal Schiff bases

Resonance Raman (RR) spectra are reported for amino acid and amine adducts of pyridoxal 5'-phosphate (PLP) and 5'-deoxypyridoxal (5'-dPL) in aqueous solution. For the valine adducts, a detailed study has been carried out on solutions at pH and pD 5, 9, and 13, values at which the pyridine and imine protons are successively ionized, and on the adducts formed from 15N-valine, alpha-deuterovaline, and N-methyl-PLP. Good quality spectra were obtained, despite the strong fluorescence of pyridoxal Schiff bases, by adding KI as a quencher, and by exciting the molecules on the blue side of their absorption bands: 406.7 nm (cw Kr+ laser) for the pH 5 and 9 species (lambda max = 409 and 414 nm), and 354.7 nm (pulsed YAG laser, third harmonic) for the pH 13 species (lambda max = 360 nm). A prominent band at 1646 cm-1 is assigned to the imine C=N stretch via its 13 cm-1 15N shift. A 12 cm-1 down-shift of the band in D2O confirms that the Schiff base linkage is protonated at pH 9. Deprotonation at pH 13 shifts VC = N from 1646 to 1629 cm-1, values typical of conjugated Schiff bases. The strongest band in the spectrum, at 1338 cm-1, shifts to 1347 cm-1 upon pyridine protonation at pH 5, and is assigned to a ring mode with a large component of phenolate C-O stretch. A shoulder on its low-frequency side is assigned to the C4-C4' stretch. Large enhancements of these modes can be understood qualitatively in terms of the dominant resonance structures contributing to the ground and resonant excited states. A number of weaker bands are observed, and assigned to pyridine ring modes. These modes gain significantly in intensity, while the exocyclic modes diminish, when the spectra are excited at 266 nm (YAG laser, fourth harmonic) in resonance with ring-localized electronic transitions.     

Purification and physical-chemical properties of methanobactin: a chalkophore from Methylosinus trichosporium OB3b

Methanobactin is an extracellular, copper-binding chromopeptide from the methane-oxidizing bacterium, Methylosinus trichosporium OB3b, believed to be involved in copper detoxification, sequestration, and uptake. Although small (1217.2 Da), methanobactin possesses a complex three-dimensional macrocyclic structure with several unusual moieties. The molecule binds one copper and has the N-2-isopropylester-(4-thionyl-5-hydroxyimidazolate)-Gly(1)-Ser(2)-Cys(3)-Tyr(4)-pyrrolidine-(4-hydroxy-5-thionylimidazolate)-Ser(5)-Cys(6)-Met(7) sequence [Kim, H. J., et al. (2004) Science 305, 1612-1615]. We report methods for purifying methanobactin from M. trichosporium OB3b and present initial evidence of its physiological function. MALDI-TOF MS was used to systematically monitor samples for optimizing purification conditions, and for detecting and analyzing specific metal-methanobactin complexes. Purification was performed by first stabilizing the extracted compound with copper followed by separation using reversed-phase HPLC in neutral pH buffers. Purified methanobactin exhibited UV-visible maxima at 342 nm, a shoulder at 388 nm, and a broad peak at 282 nm. These features were lost upon CuCl(2) titration with appearance of new features at 335, 356, 290, and 255 nm. Furthermore, methanobactin contains two fluorescent moieties, which exhibit broad emissions at 440-460 nm (lambda(max)(ex) at 388 nm) and 390-430 nm (lambda(max)(ex) = 342 nm), respectively. Finally, methanobactin eliminates the growth lag in M. trichosporium OB3b and substantially increases growth rates when cultures are exposed to elevated copper levels.