Transient kinetic and deuterium isotope effect studies on the catalytic mechanism of phosphoglycerate dehydrogenase.

The catalytic mechanism of the phosphoglycerate dehydrogenase reaction in both directions was investigated by studying: (a) pre-steady state transients in reduced coenzyme appearance or disappearance or disappearance and in protein fluorescence; (b) deuterium isotope effects on the transients and on the steady state reactions; and (c) the partial reaction between the enzyme-NADH complex and hydroxypyruvate-P. These studies led to the scheme below for the ternary complex interconversion. E1-NADH-hydroxypyruvate-P(1)equilibriumE2-NADH-hydroxypyruvate-P(2)equilibriumE3-NADH-hydroxypyruvate-P + H+(3)equilibriumE3-NAD+-3-phosphoglycerate(4)equilibriumE4-NAD+-3-phosphoglycerate Steps 1,2, and 4 are ternary complex isomerizations. Step 3 is the hydride transfer. Under steady state conditions isomerization 2 is the rate-determining step in the direction of hydroxypyruvate-P reduction at higher pH values. At lower pH values, the hydride transfer step is also partially rate-determining. The rate-determining step in the direction of 3-phosphoglycerate oxidation occurs subsequent to the hydride transfer step at higher pH values. At lower pH values the rate is determined by both isomerization 4 and the hydride transfer step. Isomerizations 1, 2, and 4 were inhibited by serine, an allosteric inhibitor, indicating that the inactive conformation of the enzyme is incapable of performing any of the steps of the ternary complex interconversion. Phosphoglycerate dehydrogenase corresponds to a V-type allosteric enzyme. When the enzyme-NADH complex was mixed with hydroxypyruvate-P at pH 8.5, a rapid quenching of enzymebound NADH fluorescence occurred. This process was studied under pseudo-first order conditions and shown to be the result of hydroxypyruvate-P binding.     

A base change in the catalytic core of the hairpin ribozyme perturbs function but not domain docking

The hairpin ribozyme is a small endonucleolytic RNA motif with potential for targeted RNA inactivation. It optimally cleaves substrates containing the sequence 5'-GU-3' immediately 5' of G. Previously, we have shown that tertiary structure docking of its two domains is an essential step in the reaction pathway of the hairpin ribozyme. Here we show, combining biochemical and fluorescence structure and function probing techniques, that any mutation of the substrate base U leads to a docked RNA fold, yet decreases cleavage activity. The docked mutant complex shares with the wild-type complex a common interdomain distance as measured by time-resolved fluorescence resonance energy transfer (FRET) as well as the same solvent-inaccessible core as detected by hydroxyl-radical protection; hence, the mutant complex appears nativelike. FRET experiments also indicate that mutant docking is kinetically more complex, yet with an equilibrium shifted toward the docked conformation. Using 2-aminopurine as a site-specific fluorescent probe in place of the wild-type U, a local structural rearrangement in the substrate is observed. This substrate straining accompanies global domain docking and involves unstacking of the base and restriction of its conformational dynamics, as detected by time-resolved 2-aminopurine fluorescence spectroscopy. These data appear to invoke a mechanism of functional interference by a single base mutation, in which the ribozyme-substrate complex becomes trapped in a nativelike fold preceding the chemical transition state.     

The mechanism of end product inhibition of serine biosynthesis. V. Mechanism of serim inhibition of phosphoglycerate dehydrogenases.

The reduction of enzyme-bound DPN constitutes a half-reaction of phosphoglycerate dehydrogenase and has been investigated fluorometrically. Serine was found to inhibit the half-reaction to the same extent and with the same degree of cooperation as the steady state reaction. This finding identifies the ternary complex conversion as the point in the reaction sequence at which serine inhibition occurs. Delta H determinations for the half-reaction showed no difference whether serine was or was not present and led to the conclusion that the inhibitory effect of serine could only manifest itself through the delta S term in the expression for the formation of the activated transition state complex. DL-3-P[2-2H]glyceric acid showed no primary isotope effect in the half-reaction. This result excludes hydrogen transfer as the rate-limiting step in the half-reaction and confirms that an isomerization step, affected by serine, exists in the ternary complex conversion scheme. The deuterated 3-P-glyceric acid shows an isotope effect of 2 in the steady state reaction.     

Computational studies of the farnesyltransferase ternary complex part II: the conformational activation of farnesyldiphosphate

Studies aimed at elucidating the reaction mechanism of farnesyltransferase (FTase), which catalyzes the prenylation of many cellular signaling proteins including Ras, has been an active area of research. Much is known regarding substrate binding and the impact of various catalytic site residues on catalysis. However, the molecular level details regarding the conformational rearrangement of farnesyldiphosphate (FPP), which has been proposed via structural analysis and mutagenesis studies to occur prior to the chemical step, is still poorly understood. Following on our previous computational characterization of the resting state of the FTase ternary complex, the thermodynamics of the conformational rearrangement step in the absence of magnesium was investigated for the wild type FTase and the Y300Fbeta mutant complexed with the peptide CVIM. In addition, we also explored the target dependence of the conformational activation step by perturbing isoleucine into a leucine (CVLM). The calculated free energy profiles of the proposed conformational transition confirm the presence of a stable intermediate state, which was identified only when the diphosphate is monoprotonated (FPP2-). The farnesyl group in the computed intermediate state assumes a conformation similar to that of the product complex, particularly for the first two isoprene units. We found that Y300beta can readily form hydrogen bonds with either of the phosphates of FPP. Removing the hydroxyl group on Y300beta does not significantly alter the thermodynamics of the conformational transition, but shifts the location of the intermediate farther away from the nucleophile by 0.5 A, which suggests that Y300beta facilitate the reaction by stabilizing the chemical step. Our results also showed an increased transition barrier height for CVLM (1.5 kcal/mol higher than that of CVIM). Although qualitatively consistent with the findings from the recent kinetic isotope experiments by Fierke and co-workers, the magnitude is not large enough to affect the rate-limiting step.     

Neuronal nitric-oxide synthase mutant (Ser-1412 --> Asp) demonstrates surprising connections between heme reduction, NO complex formation, and catalysis

Rat neuronal NO synthase (nNOS) contains an Akt-dependent phosphorylation motif in its reductase domain. We mutated a target residue in that site (Ser-1412 to Asp) to mimic phosphorylation and then characterized the mutant using conventional and stopped-flow spectroscopies. Compared with wild-type, S1412D nNOS catalyzed faster cytochrome c and ferricyanide reduction but displayed slower steady-state NO synthesis with greater uncoupling of NADPH oxidation. Paradoxically, the mutant had faster heme reduction, faster heme-NO complex formation, and greater heme-NO complex accumulation at steady state. To understand how these behaviors related to flavin and heme reduction rates, we utilized three soybean calmodulins (CaMs) that supported a range of slower flavin and heme reduction rates in mutant and wild-type nNOS. Reductase activity and two catalytic parameters (speed and amount of heme-NO complex formation) related directly to the speed of flavin and heme reduction. In contrast, steady-state NO synthesis increased, reached a plateau, and then fell at the highest rate of heme reduction that was obtained with S1412D nNOS + CaM. Substituting with soybean CaM slowed heme reduction and increased steady-state NO synthesis by the mutant. We conclude the following. 1) The S1412D mutation speeds electron transfer out of the reductase domain. 2) Faster heme reduction speeds intrinsic NO synthesis but diminishes NO release in the steady state. 3) Heme reduction displays an optimum regarding NO release during steady state. The unique behavior of S1412D nNOS reveals the importance of heme reduction rate in controlling steady-state activity and suggests that nNOS already has a near-optimal rate of heme reduction.     

Construction and evaluation of the kinetic scheme associated with dihydrofolate reductase from Escherichia coli

A kinetic scheme is presented for Escherichia coli dihydrofolate reductase that predicts steady-state kinetic parameters and full time course kinetics under a variety of substrate concentrations and pHs. This scheme was derived from measuring association and dissociation rate constants and pre-steady-state transients by using stopped-flow fluorescence and absorbance spectroscopy. The binding kinetics suggest that during steady-state turnover product dissociation follows a specific, preferred pathway in which tetrahydrofolate (H4F) dissociation occurs after NADPH replaces NADP+ in the ternary complex. This step, H4F dissociation from the E X NADPH X H4F ternary complex, is proposed to be the rate-limiting step for steady-state turnover at low pH because koff = VM. The rate constant for hydride transfer from NADPH to dihydrofolate (H2F), measured by pre-steady-state transients, has a deuterium isotope effect of 3 and is rapid, khyd = 950 s-1, essentially irreversible, Keq = 1700, and pH dependent, pKa = 6.5, reflecting ionization of a single group in the active site. This scheme accounts for the apparent pKa = 8.4 observed in the steady state as due to a change in the rate-determining step from product release at low pH to hydride transfer above pH 8.4. This kinetic scheme is a necessary background to analyze the effects of single amino acid substitutions on individual rate constants.     

Conformational dynamics of two histidine-binding proteins of Salmonella typhimurium.

The Salmonella typhimurium periplasmic histidine-binding J-protein is one of four proteins encoded by the histidine transport operon. Mutant J-protein hisJ5625 binds L-histidine, but does not transport it. The tertiary structure and conformational dynamics of native and mutant J-protein have been compared using steady state fluorescence, fluorescence polarization, and fluorescence energy transfer measurements. The two proteins have different three-dimensional structures and exhibit different responses to histidine binding. Ligand-induced conformational changes were demonstrated in both J-proteins using fluorescence energy transfer (distant reporter method) between the single tryptophan residue per mole of protein and a fluorescein-labeled methionine residue. However, the conformational change of the mutant protein is qualitatively and quantitatively different from that of the wild-type protein. Moreover, the microenvironment of the tryptophan and its distance from the labeled methionine (44A for the wild type, 60A for the mutant J-protein) are different in the two proteins. In conclusion, these results indicate that the specific conformational change induced in the wild type J-protein is a necessary requirement for the transport of L-histidine.     

A substrate-induced conformation change in the reaction of alkaline phosphatase from Escherichia coli

1. Benzyl phosphonates were prepared and their potentialities as chromophoric reagents for the exploration of the substrate-binding site of Escherichia coli alkaline phosphatase were investigated. 4-Nitrobenzylphosphonate is a competitive inhibitor of the enzyme. 2-Hydroxy-5-nitrobenzylphosphonate changes its spectrum on binding to the enzyme. This spectral change is reversed when the phosphonate is displaced from the enzyme by substrate. 2. The kinetics of the reaction of 2-hydroxy-5-nitrophenylphosphonate were studied by the stopped-flow and the temperature-jump techniques. It was found that the combination of the phosphonate with the enzyme occurred in two successive and reversible steps: enzyme-phosphonate complex-formation followed by rearrangement of the complex. The spectral change is associated with the rearrangement. At pH8 in 1m-sodium chloride at 22 degrees the rate constant is 167sec.(-1) for the rearrangement of the initially formed binary complex and is 18sec.(-1) for the reverse process. 3. It has previously been proposed that the reactions of phosphatase with its substrates include a distinct step between enzyme-substrate combination and chemical catalysis. The rate constant involved could be predicted but not measured from experiments with substrates. The value for the rate constant measured from the rate of the enzyme-phosphonate rearrangement is in excellent agreement with the predicted value. A model for the reaction mechanism is proposed that includes a conformation change in response to phosphate ester binding before phosphate transfer from substrate to enzyme.     

Conversion of the proximal histidine ligand to glutamine restores activity to an inactive mutant of cytochrome c peroxidase.

Using site-directed mutagenesis, a double mutant in yeast cytochrome c peroxidase (CCP) has been constructed where the proximal ligand, His175, has been converted to glutamine and the neighboring Trp191 has been converted to phenylalanine. The refined 2.4-A crystal structure of the double mutant shows that the Gln175 side chain is within coordination distance of the heme iron atom and that Phe191 occupies the same position as Trp191 in the native enzyme with very little rearrangement outside the immediate vicinity of the mutations. Consistent with earlier work, we find that the single mutant, His175-->Gln, is fully active under steady state assay conditions and that as reported earlier (Mauro et al., 1988), the Trp191-->Phe mutant exhibits only < 0.05% activity. However, the double mutant, His175-->Gln/Phe191-->Phe, exhibits 20% wild type activity. Since it is known that the Trp191-->Phe mutant is inactive because it can no longer transfer electrons from ferrocytochrome c, changing the nature of the proximal ligand is able to restore this activity. These results raise interesting questions regarding the mechanism of interprotein electron transfer reactions.     

Characteristics of energy-linked proton translocation in liposome reconstituted bovine cytochrome bc1 complex. Influence of the protonmotive force on the H+/e- stoichiometry.

A study is presented on the H+/e- stoichiometry for proton translocation by the isolated cytochrome bc1 complex under level-flow and steady-state conditions. An experimental procedure was used which allows the determination of pure vectorial proton translocation in both conditions in a single experiment. The results obtained indicate an H+/e- ratio of 1 at level-flow and 0.3 at steady-state. The ratios appear to be independent of the rate of electron transfer through the complex. Making use of pyranine-entrapped bc1 vesicles, a respiration-dependent steady-state delta pH value of 0.4 was determined in the presence of valinomycin. This value could be either decreased by subsaturating concentrations of the uncoupler carbonyl cyanide m-chlorophenylhydrazone (CCCP) or increased by introducing bovine serum albumin in the assay mixture. The steady-state H+/e- ratio appeared to be in linear inverse correlation with the delta pH. This indicates that delta pH exerts a control on the proton pump of the bc1 complex at the steady state. The effect of valinomycin-mediated potassium-diffusion potential on electron-transfer and proton-translocation activities is also shown. The experiments presented show that the H+/e- ratio is unaffected, both at level flow and steady state, by an imposed diffusion potential up to around 100 mV. At higher potential values the level-flow H+/e- ratio slightly decreased. Measurements as a function of imposed membrane potential of the rate of electron transfer at level flow and of the rate of the pre-steady-state reduction of b and c1 cytochromes in the complex indicate activation of electron transfer at potential values of 40-50 mV. This activation appears, however, to involve a rate-limiting step which remains normally coupled to proton translocation.     

Clustering of peptide-loaded MHC class I molecules for endoplasmic reticulum export imaged by fluorescence resonance energy transfer

Fluorescence resonance energy transfer between cyan fluorescent protein- and yellow fluorescent protein-tagged MHC class I molecules reports on their spatial organization during assembly and export from the endoplasmic reticulum (ER). A fraction of MHC class I molecules is clustered in the ER at steady state. Contrary to expectations from biochemical models, this fraction is not bound to the TAP. Instead, it appears that MHC class I molecules cluster after peptide loading. This clustering points toward a novel step involved in the selective export of peptide-loaded MHC class I molecules from the ER. Consistent with this model, we detected clusters of wild-type HLA-A2 molecules and of mutant A2-T134K molecules that cannot bind TAP, but HLA-A2 did not detectably cluster with A2-T134K at steady state. Lactacystin treatment disrupted the HLA-A2 clusters, but had no effect on the A2-T134K clusters. However, when cells were fed peptides with high affinity for HLA-A2, mixed clusters containing both HLA-A2 and A2-T134K were detected.     

Disruption of the bacteriophage T4 Mre11 dimer interface reveals a two-state mechanism for exonuclease activity

The Mre11-Rad50 (MR) complex is a central player in DNA repair and is implicated in the processing of DNA ends caused by double strand breaks. Recent crystal structures of the MR complex suggest that several conformational rearrangements occur during its ATP hydrolysis cycle. A comparison of the Mre11 dimer interface from these structures suggests that the interface is dynamic in nature and may adopt several different arrangements. To probe the functional significance of the Mre11 dimer interface, we have generated and characterized a dimer disruption Mre11 mutant (L101D-Mre11). Although L101D-Mre11 binds to Rad50 and dsDNA with affinity comparable with the wild-type enzyme, it does not activate the ATP hydrolysis activity of Rad50, suggesting that the allosteric communication between Mre11 and Rad50 has been interrupted. Additionally, the dsDNA exonuclease activity of the L101D-MR complex has been reduced by 10-fold under conditions where processive exonuclease activity is required. However, we unexpectedly found that under steady state conditions, the nuclease activity of the L101D-MR complex is significantly greater than that of the wild-type complex. Based on steady state and single-turnover nuclease assays, we have assigned the rate-determining step of the steady state nuclease reaction to be the productive assembly of the complex at the dsDNA end. Together, our data suggest that the Mre11 dimer interface adopts at least two different states during the exonuclease reaction.     

Electron donation in Photosystem II

The electron transfer resulting from illumination and dark storage of PS II has been studied using EPR signals from several electron carriers. The recombination of D⁺ (Signal II) and Q⁻_A formed by illumination occurred during dark storage at 77 K and was used to deplete reaction centres of D⁺. The donor D was then shown to be oxidized in the dark by the S₂ state of the oxygen-evolving complex. A slow change which occurred during dark storage of PS II samples was detected using the power saturation characteristics of D. We interpret this effect on D to be an indirect result of a rearrangement of the manganese complex during long-term dark adaptation. A role for D in the stability, protection and perhaps initial manganese binding of the oxygen-evolving complex is suggested.     

Nonconserved residues Ala287 and Ser290 of the Cryptosporidium hominis thymidylate synthase domain facilitate its rapid rate of catalysis

Cryptosporidium hominis TS-DHFR exhibits an unusually high rate of catalysis at the TS domain, at least 10-fold greater than those of other TS enzymes. Using site-directed mutagenesis, we have mutated residues Ala287 and Ser290 in the folate-binding helix to phenylalanine and glycine, respectively, the corresponding residues in human and most other TS enzymes. Our results show that the mutant A287F, the mutant S290G, and the double mutant all have reduced affinities for methylene tetrahydrofolate and reduced rates of reaction at the TS domain. Interestingly, the S290G mutant enzyme had the lowest TS activity, with a catalytic efficiency approximately 200-fold lower than that of the wild type (WT). The rate of conformational change of the S290G mutant is approximately 80 times slower than that of WT, resulting in a change in the rate-limiting step from hydride transfer to covalent ternary complex formation. We have determined the crystal structure of ligand-bound S290G mutant enzyme, which shows that the primary effect of the mutation is an increase in the distance between the TS ligands. The kinetic and crystal structure data presented here provide the first evidence explaining the unusually fast TS rate in C. hominis.     

Electron transfer to photosystem 1 from spinach plastocyanin mutated in the small acidic patch: ionic strength dependence of kinetics and comparison of mechanistic models

A set of plastocyanin (Pc) mutants, probing the small acidic patch (Glu59, Glu60, and Asp61) and a nearby residue, Gln88, has been constructed to provide further insight into the electron transfer process between Pc and photosystem 1. The negatively charged residues were changed into their neutral counterparts or to a positive lysine. All mutant proteins exhibited electron transfer kinetics qualitatively similar to those of the wild type protein over a wide range of Pc concentrations. The kinetics were slightly faster for the Gln88Lys mutant, while they were significantly slower for the Glu59Lys mutant. The data were analyzed with two different models: one involving a conformational change of the Pc-photosystem 1 complex that precedes the electron transfer step (assumed to be irreversible) [Bottin, H., and Mathis, P. (1985) Biochemistry 24, 6453-6460] and another where no conformational change occurs, the electron transfer step is reversible, and dissociation of products is explicitly taken into account [Drepper, F., Hippler, M., Nitschke, W., and Haehnel, W. (1996) Biochemistry 35, 1282-1295]. Both models can account for the observed kinetics in the limits of low and high Pc concentrations. To discriminate between the models, the effects of added magnesium ions on the kinetics were investigated. At a high Pc concentration (0.7 mM), the ionic strength dependence was found to be consistent with the model involving a conformational change but not with the model where the electron transfer is reversible. One residue in the small acidic patch, Glu60, seems to be responsible for the major part of the ionic strength dependence of the kinetics.     

Serine activation is the rate limiting step of tRNASer aminoacylation by yeast seryl tRNA synthetase.

Using the quenched flow technique the mechanism of seryl tRNA synthetase action has been investigated with respect to the presteady state kinetics of individual steps. Under conditions where the strong binding sites of the enzyme are nearly saturated and the steady state turnover number is about 1 s-1, rate constants of four different processes have been determined: steps connected with substrate associations are relatively slow (12 s-1 for the entire process); activation of serine is the rate determining step (about 1.2 s-1 in presence of tRNASer); whereas the transfer of serine onto tRNASer (35 s-1) and the dissociation of seryl tRNASer (70 s-1) are fast. Similar kinetic parameter seem to hold also for the steady state reactions. This conclusion is based on a detailed study of the substrate, product, and Mg2+ concentration dependence of the transfer reaction. The results also indicate that a second serine binding site is operative. Since the transfer of serine from a preformed adenylate complex onto tRNASer is fast, seryl adenylate seems to be a kinetically competent intermediate of the aminoacylation reaction although, of course, alternative mechanisms cannot be excluded.     

Rational design of a lipase to accommodate catalysis of Baeyer–Villiger oxidation with hydrogen peroxide

The mechanism and potential energy surface for the Baeyer-Villiger oxidation of acetone with hydrogen peroxide catalyzed by a Ser105-Ala mutant of Candida antarctica Lipase B has been determined using ab initio and density functional theories. Initial substrate binding has been studied using an automated docking procedure and molecular dynamics simulations. Substrates were found to bind to the active site of the mutant. The activation energy for the first step of the reaction, the nucleophilic attack of hydrogen peroxide on the carbonyl carbon of hydrogen peroxide, was calculated to be 4.4 kcal x mol(-1) at the B3LYP/6-31+G* level. The second step, involving the migration of the alkyl group, was found to be the rate-determining step with a computed activation energy of 19.9 kcal x mol(-1) relative the reactant complex. Both steps were found to be lowered considerably in the reaction catalyzed by the mutated lipase, compared to the uncatalyzed reaction. The first step was lowered by 36.0 kcal x mol(-1) and the second step by 19.5 kcal x mol(-1). The second step of the reaction, the rearrangement step, has a high barrier of 27.7 kcal x mol(-1) relative to the Criegee intermediate. This could lead to an accumulation of the intermediate. It is not clear whether this result is an artifact of the computational procedure, or an indication that further mutations of the active site are required. Figure Second TS (18TS) in the Baeyer-Villiger oxidation in a mutant of CALB. Distances in A     

Role of Thr(66) in porcine NADH-cytochrome b5 reductase in catalysis and control of the rate-limiting step in electron transfer

Site-directed mutagenesis of Thr(66) in porcine liver NADH-cytochrome b(5) reductase demonstrated that this residue modulates the semiquinone form of FAD and the rate-limiting step in the catalytic sequence of electron transfer. The absorption spectrum of the T66V mutant showed a typical neutral blue semiquinone intermediate during turnover in the electron transfer from NADH to ferricyanide but showed an anionic red semiquinone form during anaerobic photoreduction. The apparent k(cat) values of this mutant were approximately 10% of that of the wild type enzyme (WT). These data suggest that the T66V mutation stabilizes the neutral blue semiquinone and that the conversion of the neutral blue to the anionic red semiquinone form is the rate-limiting step. In the WT, the value of the rate constant of FAD reduction (k(red)) was consistent with the k(cat) values, and the oxidized enzyme-NADH complex was observed during the turnover with ferricyanide. This indicates that the reduction of FAD by NADH in the WT-NADH complex is the rate-limiting step. In the T66A mutant, the k(red) value was larger than the k(cat) values, but the k(red) value in the presence of NAD(+) was consistent with the k(cat) values. The spectral shape of this mutant observed during turnover was similar to that during the reduction with NADH in the presence of NAD(+). These data suggest that the oxidized T66A-NADH-NAD(+) ternary complex is a major intermediate in the turnover and that the release of NAD(+) from this complex is the rate-limiting step. These results substantiate the important role of Thr(66) in the one-electron transfer reaction catalyzed by this enzyme. On the basis of these data, we present a new kinetic scheme to explain the mechanism of electron transfer from NADH to one-electron acceptors including cytochrome b(5).