A Revised Mechanism for Human Cyclooxygenase-2

The mechanism of ω-6 polyunsaturated fatty acid oxidation by wild-type cyclooxygenase 2 and the Y334F variant, lacking a conserved hydrogen bond to the catalytic tyrosyl radical/tyrosine, was examined for the first time under physiologically relevant conditions. The enzymes show apparent bimolecular rate constants and deuterium kinetic isotope effects that increase in proportion to co-substrate concentrations before converging to limiting values. The trends exclude multiple dioxygenase mechanisms as well as the proposal that initial hydrogen atom abstraction from the fatty acid is the first irreversible step in catalysis. Temperature dependent kinetic studies reinforce the novel finding that hydrogen transfer from the reduced catalytic tyrosine to a terminal peroxyl radical is the first irreversible step that controls regio- and stereospecific product formation.     

Experimental and computational investigations of oxygen reactivity in a heme and tyrosyl radical-containing fatty acid α-(di)oxygenase

Rice α-(di)oxygenase mediates the regio- and stereospecific oxidation of fatty acids using a persistent catalytic tyrosyl radical. Experiments conducted in the physiological O(2) concentration range, where initial hydrogen atom abstraction from the fatty acid occurs in a kinetically reversible manner, are described. Our findings indicate that O(2)-trapping of an α-carbon radical is likely to reversibly precede reduction of a 2-(R)-peroxyl radical intermediate in the first irreversible step. A mechanism of concerted proton-coupled electron transfer is proposed on the basis of natural abundance oxygen-18 kinetic isotope effects, deuterium kinetic isotope effects, and calculations at the density functional level of theory, which predict a polarized transition state in which electron transfer is advanced to a greater extent than proton transfer. The approach outlined should be useful for identifying mechanisms of concerted proton-coupled electron transfer in a variety of oxygen-utilizing enzymes.     

Kinetic evidence for the formation of D-alanyl phosphate in the mechanism of D-alanyl-D-alanine ligase

The steady state kinetic mechanism, molecular isotope exchange and the positional isotope exchange (PIX) reactions of D-alanyl-D-alanine ligase from Salmonella typhimurium have been studied. The kinetic mechanism has been determined to be ordered Ter-Ter from initial velocity and product inhibition experiments. The first substrate to bind is ATP followed by the addition of 2 mol of D-alanine. Pi is released, and then D-alanyl-D-alanine and ADP dissociate from the enzyme surface. In the reverse direction D-alanyl-D-alanine exhibits complete substrate inhibition (Ki = 1.15 +/- 0.05 mM) by binding to the enzyme-ATP complex. In the presence of D-alanine, D-alanyl-D-alanine ligase catalyzed the positional exchange of the beta,gamma-bridge oxygen in [gamma-18O4]ATP to a beta-nonbridge position. Two possible alternate dead-end substrate analogs, D-2-chloropropionic acid and isobutyric acid, did not induce a positional isotope exchange in [gamma-18O4]ATP. The positional isotope exchange rate is diminished relative to the net substrate turnover as the concentration of D-alanine is increased. This is consistent with the ordered Ter-Ter mechanism as determined by the steady state kinetic experiments. The ratio of the positional isotope exchange rate relative to the net chemical turnover of substrate (Vex/Vchem) approaches a value of 1.4 as the concentration of D-alanine becomes very small. This ratio is 100 times larger than the ratio of the maximal reverse and forward chemical reaction velocities (V2/V1). This situation is only possible when the reaction mechanism proceeds in two distinct steps and the first step is much faster than the second step. The enzyme was also found to catalyze the molecular isotope exchange of radiolabeled D-alanine with D-alanyl-D-alanine in the presence of phosphate. These results are consistent with the formation of D-alanyl phosphate as a kinetically competent intermediate.     

Studies of the mechanism of the delta 5-3-ketosteroid isomerase reaction by substrate, solvent, and combined kinetic deuterium isotope effects on wild-type and mutant enzymes

delta 5-3-Ketosteroid isomerase (EC 5.3.3.1) catalyzes the isomerization of delta 5-3-ketosteroids to delta 4-3-ketosteroids by a conservative tautomeric transfer of the 4 beta-proton to the 6 beta-position using Tyr-14 as a general acid and Asp-38 as a general base [Kuliopulos, A., Mildvan, A. S., Shortle, D., & Talalay, P. (1989) Biochemistry 28, 149]. On deuteration of the 4 beta-position (97.0%) of the substrate, kcat(H)/kcat(4 beta-D) is 6.1 in H2O and 6.3 in D2O. The solvent isotope effect, kcat(H2O)/kcat(D2O), is 1.6 for both the 4 beta-H and 4 beta-D substrates. Mutation of Tyr-55 to Phe lowers kcat 4.3-fold; kcat(H)/kcat/4 beta-D) is 5.3 in H2O and 5.9 in D2O, and kcat(H2O)/kcat(D2O) with the 4 beta-H and 4 beta-D substrates is 1.5 and 1.7, respectively, indicating concerted general acid-base catalysis in either the enolization or the ketonization step of both the wild-type and the Tyr-55----Phe (Y55F) mutant enzymes. An additional slow step occurs with the Y55F mutant. Smaller isotope effects on Km are used to estimate individual rate constants in the kinetic schemes of both enzymes. On deuteration of the 4 alpha-position (88.6%) of the substrate, the secondary isotope effect on kcat/Km corrected for composition is 1.11 +/- 0.02 with the wild-type enzyme and 1.12 +/- 0.02 with the Y55F mutant. These effects decrease to 1.06 +/- 0.01 and 1.07 +/- 0.01, respectively, when the 4 beta-position is also deuterated, thereby establishing these to be kinetic (rather than equilibrium) secondary isotope effects and to involve a proton-tunneling contribution. Deuteration of the 6-position of the substrate (92.0%) produces no kinetic isotope effects on kcat/Km with either the wild-type (1.00 +/- 0.01) or the Y55F mutant (1.01 +/- 0.01) enzyme. Since a change in hybridization from sp3 to sp2 occurs at C-4 only during enolization of the substrate and a change in hybridization at C-6 from sp2 to sp3 occurs only during reketonization of the dienol intermediate, enolization of the substrate constitutes the concerted rate-limiting step. Concerted enolization is consistent with the right angle or antarafacial orientations of Tyr-14 and Asp-38 with respect to the enzyme-bound substrate and with the additive effects on kcat of mutation of these catalytic residues [Kuliopulos, A., Talalay, P., & Mildvan, A. S. (1990) Biophys. J. 57, 39a].     

Prostaglandin H synthase: Resolved and unresolved mechanistic issues

The cyclooxygenase and peroxidase activities of prostaglandin H synthase (PGHS)-1 and -2 have complex kinetics, with the cyclooxygenase exhibiting feedback activation by product peroxide and irreversible self-inactivation, and the peroxidase undergoing an independent self-inactivation process. The mechanistic bases for these complex, non-linear steady-state kinetics have been gradually elucidated by a combination of structure/function, spectroscopic and transient kinetic analyses. It is now apparent that most aspects of PGHS-1 and -2 catalysis can be accounted for by a branched chain radical mechanism involving a classic heme-based peroxidase cycle and a radical-based cyclooxygenase cycle. The two cycles are linked by the Tyr385 radical, which originates from an oxidized peroxidase intermediate and begins the cyclooxygenase cycle by abstracting a hydrogen atom from the fatty acid substrate. Peroxidase cycle intermediates have been well characterized, and peroxidase self-inactivation has been kinetically linked to a damaging side reaction involving the oxyferryl heme oxidant in an intermediate that also contains the Tyr385 radical. The cyclooxygenase cycle intermediates are poorly characterized, with the exception of the Tyr385 radical and the initial arachidonate radical, which has a pentadiene structure involving C11-C15 of the fatty acid. Oxygen isotope effect studies suggest that formation of the arachidonate radical is reversible, a conclusion consistent with electron paramagnetic resonance spectroscopic observations, radical trapping by NO, and thermodynamic calculations, although moderate isotope selectivity was found for the H-abstraction step as well. Reaction with peroxide also produces an alternate radical at Tyr504 that is linked to cyclooxygenase activation efficiency and may serve as a reservoir of oxidizing equivalent. The interconversions among radicals on Tyr385, on Tyr504, and on arachidonate, and their relationships to regulation and inactivation of the cyclooxygenase, are still under active investigation for both PGHS isozymes.     

Dissection of proteolytic 18O labeling: endoprotease-catalyzed 16O-to-18O exchange of truncated peptide substrates

Proteolytic labeling in H2(18)O has been recently revived as a versatile method for proteomics research. To understand the molecular basis of the labeling process, we have dissected the process into two separate events: cleavage of the peptide amide bonds and exchange of the terminal carboxyl oxygens. It was demonstrated that both carboxyl oxygens can be catalytically labeled, independent of the cleavage step. Reaction kinetics of the tryptic 16O-to-18O exchange of YGGFMR, YGGFMK, and the tryptic digest of apomyoglobin were studied by matrix-assisted laser desorption/ionization Fourier transform ion cyclotron resonance mass spectrometry. A larger KM for the Lys-peptide (4400 +/- 700 microM), when compared to that of the Arg-peptide (KM 1300 +/- 300 microM), was mainly responsible for the slower reaction with YGGFMK (kcat/KM 0.64 +/- 0.14 microM(-1)min(-1)) compared to YGGFMR (kcat/KM 2.6 +/- 0.9 microM(-1)min(-1)). Multiplexed kinetic studies showed that endoprotease-catalyzed oxygen exchange is a general phenomenon, allowing homogeneous 18O2-coding of a variety of peptides. It was demonstrated for the first time that chymotrypsin 18O2-codes peptides during proteolysis. On the basis of the analyses reported here, we propose that proteolytic 18O labeling can be advantageously decoupled from protein digestion, and endoproteases can be used in a separate step to 18O2-code peptides for comparative studies after proteolysis has taken place.     

Enzyme-bound pentadienyl and peroxyl radicals in purple lipoxygenase

Samples of purple lipoxygenase prepared by addition of either 13-hydroperoxy-9,11-octadecadienoic acid or linoleic acid and oxygen to ferric lipoxygenase contain pentadienyl and/or peroxyl radicals. The radicals are identified by the g values and hyperfine splitting parameters of natural abundance and isotopically enriched samples. The line shapes of their EPR spectra suggest the radicals are conformationally constrained when compared to spectra of the same radicals generated in frozen linoleic acid. Further, the EPR spectra are unusually difficult to saturate. The radicals are stable in buffered aqueous solution at 4 degrees C for several minutes. All of this implies that these species are bound to the enzyme, possibly in proximity to the iron. Only peroxyl radical is seen when the purple enzyme is generated with either hydroperoxide or linoleic acid in O2-saturated solutions. Addition of natural abundance hydroperoxide under 17O-enriched O2 leads to the 17O-enriched peroxyl radical, while the opposite labeling results in the natural abundance peroxyl radical, demonstrating the exchange of oxygen. Both radicals are detected in samples of purple lipoxygenase prepared with either linoleic acid or hydroperoxide under air. Addition of the hydroperoxide in the absence of oxygen favors the pentadienyl radical. We propose that addition of either linoleic acid or hydroperoxide to ferric lipoxygenase leads to multiple mechanistically connected enzyme complexes, including those with (hydro)peroxide, peroxide, peroxyl radical, pentadienyl radical, and linoleic acid bound. This hypothesis is essentially identical with the proposed radical mechanism of oxygenation of polyunsaturated fatty acids by lipoxygenase.     

Combined effects of two mutations of catalytic residues on the ketosteroid isomerase reaction

delta 5-3-Ketosteroid isomerase (EC 5.3.3.1) catalyzes the isomerization of delta 5-3-ketosteroids to delta 4-3-ketosteroids by a conservative tautomeric transfer of the 4 beta-proton to the 6 beta-position with Tyr-14 as a general acid and Asp-38 as a general base [Kuliopulos, A., Mildvan, A. S., Shortle, D., & Talalay, P. (1989) Biochemistry 28, 149-159]. Primary, secondary, and combined deuterium kinetic isotope effects establish concerted substrate enolization to be the rate-limiting step with the wild-type enzyme [Xue, L., Talalay, P., & Mildvan, A. S. (1990) Biochemistry 29, 7491-7500]. The product of the fractional kcat values resulting from the Y14F mutation (10(-4.7)) and the D38N mutation (10(-5.6)) is comparable (10(-10.3)) to that of the double mutant Y14F + D38N (less than or equal to 10(-10.4)) which is completely inactive. Hence, the combined effects are either additive or synergistic. Quantitatively, similar effects of the two mutations on kcat/KM are found in the double mutant. Despite its inactivity, the Y14F + D38N double mutant forms crystals indistinguishable in form from those of the wild-type enzyme, tightly binds steroid substrates and substrate analogues, and immobilizes a spin-labeled steroid in an orientation indistinguishable from that found in the wild-type enzyme, indicating that the double mutant is otherwise largely intact. It is concluded that the total enzymatic activity of ketosteroid isomerase probably results from the independent and concerted functioning of Tyr-14 and Asp-38 in the rate-limiting enolization step, in accord with the perpendicular or antarafacial orientation of these two residues with respect to the enzyme-bound substrate. Synergistic effects of mutating two residues on kcat and on kcat/KM of enzyme-catalyzed multistep reactions are shown, theoretically, to occur when both residues act independently in the same step, and simple additivity occurs when this step is rate-limiting. Other conditions for additivity of the effects of mutations of kcat and kcat/KM are theoretically explored.     

An EPR study of the peroxyl radicals induced by hydrogen peroxide in the haem proteins

The reaction of hydrogen peroxide H(2)O(2) with horse heart metmyoglobin (HH metMb), sperm whale metmyoglobin (SW metMb) and human metHb (metHbA) was studied at pH 6-8 by low temperature (10 K) EPR spectroscopy with the emphasis on the peroxyl radicals formed during the reaction. The same type of peroxyl radical was found in both myoglobin systems, as was concluded from close similarities in the spectroscopic properties of the radicals and in their kinetic dependences. This is consistent with previous reports of the peroxyl radical being localised on the Trp14 of SW and HH myoglobins. There are two types of peroxyl radical found in the metHbA/H(2)O(2) system, one (ROO-I) having spectral parameters, kinetic and pH dependences similar to those of the peroxyl radical found in both myoglobin systems. The other peroxyl radical (ROO-II) found in metHbA treated with H(2)O(2) has slightly different, though distinguishable, spectral parameters and a significantly different kinetic dependence as compared to those of the peroxyl radical common for all three proteins studied (ROO-I). The concentration of ROO-I radical formed in the three proteins on addition of H(2)O(2) correlates with the effectiveness of incorporating molecular oxygen into styrene oxide reported before for these three proteins. It is shown that a different distance from Trp14 to haem iron in the three proteins might be the structural basis for the different yield of the peroxyl radical and the different efficiency of incorporation of molecular oxygen into styrene. The site of the peroxyl radical found only in metHbA (ROO-II) is speculated to be the Trp37 residue of the beta-subunit of HbA.     

Lipid peroxyl radical intermediates in the peroxidation of polyunsaturated fatty acids by lipoxygenase. Direct electron spin resonance investigations

Lipid peroxyl radicals resulting from the peroxidation of polyunsaturated fatty acids by soybean lipoxygenase were directly detected by the method of rapid mixing, continuous-flow electron spin resonance spectroscopy. When air-saturated borate buffer (pH 9.0) containing linoleic acid or arachidonate acid was mixed with lipoxygenase, fatty acid-derived peroxyl free radicals were readily detected; these radicals have a characteristic g-value of 2.014. An organic free radical (g = 2.004) was also detected; this may be the carbon-centered fatty acid free radical that is the precursor of the peroxyl free radical. The ESR spectrum of this species was not resolved, so the identification of this free radical was not possible. Fatty acids without at least two double bonds (e.g. stearic acid and oleic acid) did not give the corresponding peroxyl free radicals, suggesting that the formation of bisallylic carbon-centered radicals precedes peroxyl radical formation. The 3.8-G doublet feature of the fatty acid peroxyl spectrum was proven (by selective deuteration) to be a hyperfine coupling due to a gamma-hydrogen that originated as a vinylic hydrogen of arachidonate. Arachidonate peroxyl radical formation was shown to be dependent on the substrate, active lipoxygenase, and molecular oxygen. Antioxidants are known to protect polyunsaturated fatty acids from peroxidation by scavenging peroxyl radicals and thus breaking the free radical chain reaction. Therefore, the peroxyl signal intensity from micellar arachidonate solutions was monitored as a function of the antioxidant concentration. The reaction of the peroxyl free radical with Trolox C was shown to be 10 times slower than that with vitamin E. The vitamin E and Trolox C phenoxyl radicals that resulted from scavenging the peroxyl radical were also detected.     

Enzymatic reaction of hydrogen peroxide-dependent peroxygenase cytochrome P450s: kinetic deuterium isotope effects and analyses by resonance Raman spectroscopy

Cytochromes P450SP(alpha) (CYP152B1) and P450BS(beta) (CYP152A1), which are isolated from Sphingomonas paucimobilis and Bacillus subtilis, respectively, belong to the P450 superfamily, but catalyze hydroxylation reactions, in which an oxygen atom from H2O2 is efficiently introduced into fatty acids (e.g., myristic acid). P450SP(alpha) produces the alpha-hydroxylated (alpha-OH) products at 100%, while P450BS(beta) produces alpha- and beta-hydroxylated (beta-OH) products at 33 and 67%, respectively. Using deuterium-substituted fatty acids ([2,2-d2]-myristic acid and d27-myristic acid) as a substrate, the peroxygenase reactions of the two bacterial P450s were investigated. In the P450SP(alpha) reaction, we observed an intermolecular noncompetitive kinetic isotope effect on Vmax (DV = 4.1) when [2,2-d2]-myristic acid was used, suggesting that an isotopically sensitive step involving the alpha-hydrogen of the fatty acid is present in the catalytic cycle. On the other hand, D(V/K) was masked, in sharp contrast to the features of usual monooxygenases P450. The characteristic kinetic features can be interpreted in terms of the faster product formation than the substrate dissociation. A similar kinetic isotope effect was observed [DV = 4.9, D(V/K) approximately 1] for the P450BS(beta) reaction, when d27-myristic acid was used as a substrate, indicating that the reaction mechanism is the same for both peroxygenases. The resonance Raman spectral data of P450BS(beta) in the ferric and ferrous-CO forms in the presence and absence of myristic acid demonstrated that the catalytic pocket of the enzyme is polar, so that the location of the carboxylate of the substrate close to the sixth ligand of the heme could be allowed. On the basis of these results on the kinetic isotope effects and spectroscopy, we discuss the possible mechanisms of the alpha- and beta-hydroxylation of fatty acids catalyzed by peroxygenases P450SP(alpha) and P450BS(beta).     

Kinetics of enzyme acylation and deacylation in the penicillin acylase-catalyzed synthesis of beta-lactam antibiotics.

Penicillin acylase catalyses the hydrolysis and synthesis of semisynthetic beta-lactam antibiotics via formation of a covalent acyl-enzyme intermediate. The kinetic and mechanistic aspects of these reactions were studied. Stopped-flow experiments with the penicillin and ampicillin analogues 2-nitro-5-phenylacetoxy-benzoic acid (NIPAOB) and d-2-nitro-5-[(phenylglycyl)amino]-benzoic acid (NIPGB) showed that the rate-limiting step in the conversion of penicillin G and ampicillin is the formation of the acyl-enzyme. The phenylacetyl- and phenylglycyl-enzymes are hydrolysed with rate constants of at least 1000 s-1 and 75 s-1, respectively. A normal solvent deuterium kinetic isotope effect (KIE) of 2 on the hydrolysis of 2-nitro-5-[(phenylacetyl)amino]-benzoic acid (NIPAB), NIPGB and NIPAOB indicated that the formation of the acyl-enzyme proceeds via a general acid-base mechanism. In agreement with such a mechanism, the proton inventory of the kcat for NIPAB showed that one proton, with a fractionation factor of 0.5, is transferred in the transition state of the rate-limiting step. The overall KIE of 2 for the kcat of NIPAOB resulted from an inverse isotope effect at low concentrations of D2O, which is overridden by a large normal isotope effect at large molar fractions of D2O. Rate measurements in the presence of glycerol indicated that the inverse isotope effect originated from the higher viscosity of D2O compared to H2O. Deacylation of the acyl-enzyme was studied by nucleophile competition and inhibition experiments. The beta-lactam compound 7-aminodesacetoxycephalosporanic acid (7-ADCA) was a better nucleophile than 6-aminopenicillanic acid, caused by a higher affinity of the enzyme for 7-ADCA and complete suppression of hydrolysis of the acyl-enzyme upon binding of 7-ADCA. By combining the results of the steady-state, presteady state and nucleophile binding experiments, values for the relevant kinetic constants for the synthesis and hydrolysis of beta-lactam antibiotics were obtained.     

Catalytic properties of the archaeal S-adenosylmethionine decarboxylase from Methanococcus jannaschii

S-Adenosylmethionine decarboxylase (AdoMetDC) is a pyruvoyl cofactor-dependent enzyme that participates in polyamine biosynthesis. AdoMetDC from the Archaea Methanococcus jannaschii is a prototype for a recently discovered class that is not homologous to the eucaryotic enzymes or to a distinct group of microbial enzymes. M. jannaschii AdoMetDC has a Km of 95 microm and the turnover number (kcat) of 0.0075 s(-1) at pH 7.5 and 22 degrees C. The turnover number increased approximately 38-fold at a more physiological temperature of 80 degrees C. AdoMetDC was inactivated by treatment with the imine reductant NaCNBH3 only in the presence of substrate. Mass spectrometry of the inactivated protein showed modification solely of the pyruvoyl-containing subunit, with a mass increase corresponding to reduction of a Schiff base adduct with decarboxylated AdoMet. The presteady state time course of the AdoMetDC reaction revealed a burst of product formation; thus, a step after CO2 formation is rate-limiting in turnover. Comparable D2O kinetic isotope effects of were seen on the first turnover (1.9) and on kcat/Km (1.6); there was not a significant D2O isotope effect on kcat, suggesting that product release is rate-limiting in turnover. The pH dependence of the steady state rate showed participation of acid and basic groups with pK values of 5.3 and 8.2 for kcat and 6.5 and 8.3 for kcat/Km, respectively. The competitive inhibitor methylglyoxal bis(guanylhydrazone) binds at a single site per (alphabeta) heterodimer. UV spectroscopic studies show that methylglyoxal bis(guanylhydrazone) binds as the dication with a 23 microm dissociation constant. Studies with substrate analogs show a high specificity for AdoMet.     

Secondary isotope effects and structure-reactivity correlations in the dopamine beta-monooxygenase reaction: evidence for a chemical mechanism

The chemical mechanism of hydroxylation, catalyzed by dopamine beta-monooxygenase, has been explored with a combination of secondary kinetic isotope effects and structure-reactivity correlations. Measurement of primary and secondary isotope effects on Vmax/Km under conditions where the intrinsic primary hydrogen isotope effect is known allows calculation of the corresponding intrinsic secondary isotope effect. By this method we have obtained an alpha-deuterium isotope effect, Dk alpha = 1.19 +/- 0.06, with dopamine as substrate. The beta-deuterium isotope effect is indistinguishable from one. The large magnitude of Dk alpha, together with our previous determination of a near maximal primary deuterium isotope effect of 9.4-11, clearly indicates the occurrence of a stepwise process for C-H bond cleavage and C-O bond formation and hence the presence of a substrate-derived intermediate. To probe the nature of this intermediate, a structure-reactivity study was performed by using a series of para-substituted phenylethylamines. Deuterium isotope effects on Vmax and Vmax/Km parameters were determined for all of the substrates, allowing calculation of the rate constants for C-H bond cleavage and product dissociation and dissociation constants for amine and O2 loss from the enzyme-substrate ternary complex. Multiple regression analysis yielded an electronic effect of p = -1.5 for the C-H bond cleavage step, eliminating the possibility of a carbanion intermediate. A negative p value is consistent with formation of either a radical or a carbocation; however, a significantly better correlation is obtained with sigma p rather than sigma p+, implying formation of a radical intermediate via a polarized transition state. Additional effects determined from the regression analyses include steric effects on rate constants for substrate hydroxylation and product release and on KDamine, consistent with a sterically restricted binding site, and a positive electronic effect of p = 1.4 on product dissociation, ascribed to a loss of product from an enzyme-bound Cu(II)-alkoxide complex. These results lead us to propose a mechanism in which O-O homolysis [from a putative Cu(II)-OOH species] and C-H homolysis (from substrate) occur in a concerted fashion, circumventing the formation of a discrete, high energy oxygen species such as hydroxyl radical. The substrate and peroxide-derived radical intermediates thus formed undergo a recombination, kinetically limited by displacement of an intervening water molecule, to give the postulated Cu(II)-alkoxide product complex.     

An internal equilibrium preorganizes the enzyme-substrate complex for hydride tunneling in choline oxidase

The hydride transfer reaction catalyzed by choline oxidase under irreversible regime, i.e., at saturating oxygen, was shown in a recent study to occur quantum mechanically within a highly preorganized active site, with the reactive configuration for hydride tunneling being minimally affected by environmental vibrations of the reaction coordinate other than those affecting the distance between the alpha-carbon of the choline alkoxide substrate and the N(5) atom of the enzyme-bound flavin cofactor [Fan, F., and Gadda, G. (2005) J. Am. Chem. Soc. 127, 17954-17961]. In this study, we have determined the effects of pH and temperature on the substrate kinetic isotope effects with 1,2-[2H4]choline as substrate for choline oxidase at 0.2 mM oxygen to gain insights on the mechanism of hydride transfer under reversible catalytic regime. The data presented indicated that the kinetic complexity arising from the net flux through the reverse of the hydride transfer step changed with temperature, with the hydride transfer reaction becoming more reversible with increasing temperatures. After this kinetic complexity was accounted for, analyses of the kcat/Km and D(kcat/Km) values determined at 0.2 mM according to the Eyring and Arrhenius formalisms suggested that the quantum mechanical nature of the hydride transfer reaction is, not surprisingly, maintained during enzymatic catalysis under reversible regime. A comparison of the thermodynamic and kinetic parameters of the hydride transfer reaction under reversible and irreversible catalytic regimes showed that the enthalpies of activation (DeltaH++) were significantly larger in the reversible catalytic regime. This reflects the presence of an enthalpically unfavorable internal equilibrium of the enzyme-substrate Michaelis complex occurring prior to, and independently from, CH bond cleavage. Such an internal equilibrium is required to preorganize the enzyme-substrate complex for efficient quantum mechanical tunneling of the hydride ion from the substrate alpha-carbon to the flavin N(5) atom.     

Observation of a chloride-dependent intermediate during catalysis by angiotensin converting enzyme using radiationless energy transfer

Stopped-flow radiationless energy-transfer kinetics have been used to examine the effects of chloride on the hydrolysis of Dns-Lys-Phe-Ala-Arg by angiotensin converting enzyme. The kinetic constants for hydrolysis at pH 7.5 and 22 degrees C in the presence of 300 mM sodium chloride were KM = 28 microM and kcat = 110 s-1, and in its absence, KM = 240 microM and kcat = 68 s-1. The apparent binding constant for chloride was 4 mM, and the extent of chloride activation in terms of kcat/KM was 14-fold. The effects of chloride on the pre-steady-state were examined at 2 degrees C. In the presence of chloride, two distinct enzyme-substrate complexes were observed, suggesting multiple steps in substrate binding. The initial complex was formed during the mixing period (kobsd greater than 200 s-1) while the second complex was formed much more slowly (kobsd = 40 s-1 when [S] = 5 microM and [NaCl] = 150 mM). Strikingly, in the absence of chloride, only a single, rapidly formed enzyme-substrate complex was observed. These results are consistent with a nonessential activator kinetic mechanism in which the slow step reflects conversion of an initially formed complex, (E X Cl- X S)1, to a more tightly bound complex, (E X Cl- X S)2.     

Perhydroxyl radical (HOO.) initiated lipid peroxidation. The role of fatty acid hydroperoxides

It is demonstrated that the perhydroxyl radical (HOO., the conjugate acid of superoxide (O2-], initiates fatty acid peroxidation (a model for biological lipid peroxidation) by two parallel pathways: fatty acid hydroperoxide (LOOH)-independent and LOOH-dependent. Previous workers (Gebicki, J. M., and Bielski, B. H. J. (1981) J. Am. Chem. Soc. 103, 7020-7025) demonstrated that HOO., generated by pulse radiolysis, initiates peroxidation in ethanol/water fatty acid dispersions by abstraction of the bis-allylic hydrogen atom from a polyunsaturated fatty acid. Addition of O2 to the fatty acid radicals forms peroxyl radicals (LOO.s), the chain-propagating species of lipid peroxidation. In this work it is demonstrated that HOO., generated either chemically (KO2) or enzymatically (xanthine oxidase), is a good initiator of fatty acid peroxidation in linoleic acid ethanol/water dispersions; O2- serves only as the source of HOO., and HOO. initiation can be observed at physiologically relevant pH values. In contrast to the previous results, the initiating effectiveness of HOO. is related directly to the initial concentrations of LOOHs in the lipids to be peroxidized. This defines a LOOH-dependent mechanism for fatty acid peroxidation initiation by HOO., which parallels the previously established LOOH-independent pathway. Since the LOOH-dependent pathway is much more facile than the LOOH-independent pathway, LOOH is the kinetically preferred site of HOO. attack in these systems. Experiments comparing HOO./LOOH-dependent fatty acid peroxidation with transition metal- and peroxyl radical-initiated peroxidation rule out the participation of the latter two species as initiators, which defines the HOO./LOOH initiation system as mechanistically unique. LOOH product studies are consistent with either a direct or indirect hydrogen atom transfer between LOOH and HOO. to yield LOO.s, which propagate peroxidation. The LOOH-dependent pathway of HOO.-initiated fatty acid peroxidation may be relevant to mechanisms of lipid peroxidation initiation in vivo.     

Mycobacterium tuberculosis beta-ketoacyl-acyl carrier protein (ACP) reductase: kinetic and chemical mechanisms

Beta-ketoacyl-acyl carrier protein (ACP) reductase from Mycobacterium tuberculosis (MabA) is responsible for the second step of the type-II fatty acid elongation system of bacteria, plants, and apicomplexan organisms, catalyzing the NADPH-dependent reduction of beta-ketoacyl-ACP to generate beta-hydroxyacyl-ACP and NADP(+). In the present work, the mabA-encoded MabA has been cloned, expressed, and purified to homogeneity. Initial velocity studies, product inhibition, and primary deuterium kinetic isotope effects suggested a steady-state random bi-bi kinetic mechanism for the MabA-catalyzed reaction. The magnitudes of the primary deuterium kinetic isotope effect indicated that the C(4)-proS hydrogen is transferred from the pyridine nucleotide and that this transfer contributes modestly to the rate-limiting step of the reaction. The pH-rate profiles demonstrated groups with pK values of 6.9 and 8.0, important for binding of NADPH, and with pK values of 8.8 and 9.6, important for binding of AcAcCoA and for catalysis, respectively. Temperature studies were employed to determine the activation energy of the reaction. Solvent kinetic isotope effects and proton inventory analysis established that a single proton is transferred in a partially rate-limiting step and that the mechanism of carbonyl reduction is probably concerted. The observation of an inverse (D)2(O)V/K and an increase in (D)2(O)V when [4S-(2)H]NADPH was the varied substrate obscured the distinction between stepwise and concerted mechanisms; however, the latter was further supported by the pH dependence of the primary deuterium kinetic isotope effect. Kinetic and chemical mechanisms for the MabA-catalyzed reaction are proposed on the basis of the experimental data.     

Steady-state kinetic mechanism of Ras farnesyl:protein transferase.

The steady-state kinetic mechanism of bovine brain farnesyl:protein transferase (FPTase) has been determined using a series of initial velocity studies, including both dead-end substrate and product inhibitor experiments. Reciprocal plots of the initial velocity data intersected on the 1/[s] axis, indicating that a ternary complex forms (sequential mechanism) and suggesting that the binding of one substrate does not affect the binding of the other. The order of substrate addition was probed by determining the patterns of dead-end substrate and product inhibition. Two nonhydrolyzable analogues of farnesyl diphosphate, (alpha-hydroxyfarnesyl)phosphonic acid (1) and [[(farnesylmethyl)hydroxyphosphinyl]methyl]phosphonic acid (2), were both shown to be competitive inhibitors of farnesyl diphosphate and noncompetitive inhibitors of Ras-CVLS. Four nonsubstrate tetrapeptides, CV[D-L]S, CVLS-NH2, N-acetyl-L-penicillamine-VIM, and CIFM, were all shown to be noncompetitive inhibitors of farnesyl diphosphate and competitive inhibitors of Ras-CVLS. These data are consistent with random order of substrate addition. Product inhibition patterns corroborated the results found with the dead-end substrate inhibitors. We conclude that bovine brain FPTase proceeds through a random order sequential mechanism. Determination of steady-state parameters for several physiological Ras-CaaX variants showed that amino acid changes affected the values of KM, but not those of kcat, suggesting that the catalytic efficiencies (kcat/KM) of Ras-CaaX substrates depend largely upon their relative binding affinity for FPTase.     

Enzymatic formation of long-chain polyketide pyrones by plant type III polyketide synthases

Recombinant chalcone synthase (CHS) from Scutellaria baicalensis and stilbene synthase (STS) from Arachis hypogaea accepted CoA esters of long-chain fatty acid (CHS up to the C12 ester, while STS up to the C14 ester) as a starter substrate, and carried out sequential condensations with malonyl-CoA, leading to formation of triketide and tetraketide alpha-pyrones. Interestingly, the C6, C8, and C10 esters were kinetically favored by the enzymes over the physiological starter substrate; the kcat/KM values were 1.2- to 1.9-fold higher than that of p-coumaroyl-CoA. The catalytic diversities of the enzymes provided further mechanistic insights into the type III PKS reactions, and suggested involvement of the CHS-superfamily enzymes in the biosynthesis of long-chain alkyl polyphenols such as urushiol and ginkgolic acid in plants.