Structure and properties of the putrescine carbamoyltransferase of Streptococcus faecalis.

Ornithine and putrescine carbamoyltransferases from Streptococcus faecalis ATCC11700 have been purified and their structural properties compared. The molecular weight of native ornithine carbamoyltransferase, measured by molecular sieving, is 250 000. It is composed of six apparently identical subunits with a molecular weight of 39 000, as determined by cross-linking with the bifunctional reagent glutaraldehyde followed by polyacrylamide gel electrophoresis in the presence of sodium dodecylsulfate. Using the same method, putrescine carbamoyltransferase is a trimer of 140 000 consisting of three identical subunits with a molecular weight of 40 000. Ornithine carbamoyltransferase displays a narrow specificity towards its substrate, ornithine. In contrast, putrescine carbamoyltransferase carbamoylates ornithine and several diamines (diaminopropane, diaminohexane, spermine, spermidine, cadaverine) in addition to its preferred substrate, putrescine, but with a considerable lower efficiency than for putrescine. The kinetic mechanism of putrescine carbamoyltransferase has been investigated. Initial velocity studies yield intersecting plots using either putrescine or ornithine as substrate, indicating a sequential mechanism. The patterns of protection of the enzyme by the reactants during heat inactivation as well as the results of product and dead-end inhibition studies provide evidence for a random addition of the substrates. The putrescine inhibition that is induced by phosphate does, however, suggest that a preferred pathway exists in which carbamoylphosphate is the leading substrate. The different kinetic constants have been established. The properties of putrescine carbamoyltransferase are compared to the known properties of other carbamoyltransferases. The evolutionary implications of this comparison are discussed.     

Kinetic mechanism of the type II calmodulin-dependent protein kinase: studies of the forward and reverse reactions and observation of apparent rapid-equilibrium ordered binding

The kinetic reaction mechanism of the type II calmodulin-dependent protein kinase was studied by using its constitutively active kinase domain. Lacking regulatory features, the catalytic domain simplified data collection, analysis, and interpretation. To further facilitate this study, a synthetic peptide was used as the kinase substrate. Initial velocity measurements of the forward reaction were consistent with a sequential mechanism. The patterns of product and dead-end inhibition studies best fit an ordered Bi Bi kinetic mechanism with ATP binding first to the enzyme, followed by binding of the peptide substrate. Initial-rate patterns of the reverse reaction of the kinase suggested a rapid-equilibrium mechanism with obligatory ordered binding of ADP prior to the phosphopeptide substrate; however, this apparent rapid-equilibrium ordered mechanism was contrary to the observed inhibition by the phosphopeptide which is not supposed to bind to the kinase in the absence of ADP. Inspection of product inhibition patterns of the phosphopeptide with both ATP and peptide revealed that an ordered Bi Bi mechanism can show initial-rate patterns of a rapid-equilibrium ordered system when a Michaelis constant for phosphopeptide, Kip, is large relative to the concentration of phosphopeptide used. Thus, the results of this study show an ordered Bi Bi mechanism with nucleotide binding first in both directions of the kinase reaction. All the kinetic constants in the forward and reverse directions and the Keq of the kinase reaction are reported herein. To provide theoretical bases and diagnostic aid for mechanisms that can give rise to typical rapid-equilibrium ordered kinetic patterns, a discussion on various sequential cases is presented in the Appendix.     

Anabolic ornithine carbamoyltransferase of Escherichia coli and catabolic ornithine carbamoyltransferase of Pseudomonas putida. Steady-state kinetic analysis.

The anabolic and catabolic ornithine carbamoyltransferases of Pseudomonas putida display an undirectional catalytic specialization: in citrulline synthesis for the anabolic enzyme, in citrulline phosphorolysis for the catabolic one. The irreversibility of the anabolic enzyme in vitro has been previously explained by its kinetic properties, whereas the irreversibility of the catabolic transferase in vivo was shown to be due to its allosteric behaviour. In this work a steady-state kinetic analysis has been carried out on the catabolic ornithine carbamoyltransferase at pH 6.8 in the presence of the allosteric activator, phosphate. The kinetic mechanism of Escherichia coli ornithine carbamoyltransferase serving as a reference was also determined. For the E. coli enzyme in the reverse direction, the initial velocity patterns converging on the abscissa were obtained with either citrulline or arsenate as variable substrate. The inhibition by the product ornithine was linear competitive with respect to citrulline and linear non-competitive with respect to arsenate. In the forward direction phosphate and its analogs induce an inhibition by ornithine which is partial and competitive with respect to carbamoylphosphate. Together with the results of thermo-inactivation studies in the presence of each reactant, this observation suggests a random kinetic mechanism, but with most of the reaction flux following the path where carbamoylphosphate adds before ornithine, when substrates are present at Km levels. The allosteric catabolic ornithine carbamoyltransferase of Pseudomonas displays qualitatively the same pattern as the E. coli enzyme.     

Nucleotide regulation of Escherichia coli glycerol kinase: initial-velocity and substrate binding studies

Substrate binding to Escherichia coli glycerol kinase (EC 2.7.1.30; ATP-glycerol 3-phosphotransferase) was investigated by using both kinetics and binding methods. Initial-velocity studies in both reaction directions show a sequential kinetic mechanism with apparent substrate activation by ATP and substrate inhibition by ADP. In addition, the Michaelis constants differ greatly from the substrate dissociation constants. Results of product inhibition studies and dead-end inhibition studies using 5'-adenylyl imidodiphosphate show the enzyme has a random kinetic mechanism, which is consistent with the observed formation of binary complexes with all the substrates and the glycerol-independent MgATPase activity of the enzyme. Dissociation constants for substrate binding determined by using ligand protection from inactivation by N-ethylmaleimide agree with those estimated from the initial-velocity studies. Determinations of substrate binding stoichiometry by equilibrium dialysis show half-of-the-sites binding for ATP, ADP, and glycerol. Thus, the regulation by nucleotides does not appear to reflect binding at a separate regulatory site. The random kinetic mechanism obviates the need to postulate such a site to explain the formation of binary complexes with the nucleotides. The observed stoichiometry is consistent with a model for the nucleotide regulatory behavior in which the dimer is the enzyme form present in the assay and its subunits display different substrate binding affinities. Several properties of the enzyme are consistent with negative cooperativity as the basis for the difference in affinities. The possible physiological importance of the regulatory behavior with respect to ATP is considered.     

L-Ornithine carbamoyltransferase from Saccharomyces cerevisiae: steady-state kinetic analysis.

Ornithine carbamoyltransferase of Saccharomyces cerevisiae is subjected to an enzymatic regulation of its anabolic activity when it is bound to the inducible catabolic arginase as described earlier. This regulatory ornithine carbamoyltransferase essentially catalyzes the synthesis of citrulline, but the reverse reaction could be demonstrated using arsenate instead of phosphate. Steady-state initial velocity studies of the reverse reaction indicate that the mechanism is consistent with a rapid-equilibrium random model (in which all steps are in equilibrium, except that concerned with the interconversion of the central ternary complexes) involving the formation of enzyme - ornithine - arsenate and enzyme - citrulline - phosphate dead-end complexes. In the forward direction, although the mechanism also appears to be random, the results are in better agreement with a preferred ordered binding of substrates, with carbamoylphosphate adding first. This degenerate form of the random mechanism is discussed.     

Regulation of smooth-muscle myosin-light-chain kinase. Steady-state kinetic studies of the reaction mechanism

The kinetic mechanism of turkey gizzard smooth muscle myosin-light-chain kinase was investigated using the isolated 20-kDa light chain of myosin as substrate. The kinetic and product inhibition patterns of the forward reaction indicated an ordered sequential mechanism in which MgATP bound first, ADP was released last. The order of substrate binding and product release was confirmed independently by competitive, dead-end inhibition patterns obtained using the non-hydrolizable ATP analog adenosine 5'-[beta,gamma-imido]triphosphate. The mechanism was also characterized by a relatively strong product inhibition by ADP and a weak one by phosphorylated 20-kDa light-chain myosin, in addition to a significant inhibition by the latter product via a formation of a dead-end complex. [gamma-32P]ATP in equilibrium with [32P]phosphorylated light chain isotope-exchange data were consistent with the deduced mechanism and with the presence of the latter dead-end complex.     

Anabolic ornithine carbamolytransferase of Pseudomonas. The bases of its functional specialization.

The anabolic ornithine carbamoyltransferase of Pseudomonas appears to be extremely specialized. Unlike the other carbamoyltransferases studied, this enzyme catalyzes the phosphorolytic cleavage of citrulline with a very poor efficiency. The main goal of this paper is to understand what, in the catalytic process, causes this directed functional specialization. On the basis of kinetic data and thermodynamic properties of the reaction, it appears that the reaction mechanism is the same as for ornithine carbamoyltransferases from other sources, that is, of the sequential ordered type, where carbamoylphosphate is the first substrate to be bound and phosphate the last product to be released. In addition to this, and here lies the difference with other ornithine carbamoyltransferases, the anabolic transferase of Pseudomonas forms a binary dead-end complex with citrulline, leading to inefficient binding of phosphate and citrulline to the enzyme. Therefore the phosphorolytic cleavage of citrulline is equally inefficient. It should be mentioned that the affinity of the enzyme for citrulline at its catalytic site is low as compared to other transferases.     

Adenosine-5'-phosphosulfate kinase from Escherichia coli K12. Purification, characterization, and identification of a phosphorylated enzyme intermediate

Adenosine-5'-phosphosulfate kinase (ATP:adenylylsulfate 3'-phosphotransferase), the second enzyme in the pathway of sulfate activation, has been purified (approximately 300-fold) to homogeneity from an Escherichia coli K12 strain, which overproduces the enzyme activity (approximately 100-fold). The purified enzyme has a specific activity of 153 mumol of 3'-phosphoadenosine 5'-phosphosulfate (PAPS) formed/min/mg of protein at 25 degrees C. The enzyme is remarkably efficient with a Vmax/Km(APS) of greater than 10(8) M-1 s-1, indicating that at physiologically low substrate concentrations the reaction is essentially diffusion limited. Upon incubation with MgATP a phosphorylated enzyme is formed; the isolated phosphorylated enzyme can transfer its phosphoryl group to adenosine 5'-phosphosulfate (APS) to form PAPS or to ADP to form ATP. The phosphorylated enzyme exists as a dimer of identical 21-kilodalton subunits, while the dephosphorylated form primarily exists as a tetramer. Divalent cations are required for activity with Mg(II), Mn(II), Co(II), and Cd(II) activating. Studies of the divalent metal-dependent stereoselectivity for the alpha- and beta-phosphorothioate derivatives of ATP indicate metal coordination to at least the alpha-phosphoryl group of the nucleotide. Steady state kinetic studies of the reverse reaction indicate a sequential mechanism, with a rapid equilibrium ordered binding of MgADP before PAPS. In the forward direction APS is a potent substrate inhibitor, competitive with ATP, complicating kinetic studies. The primary kinetic mechanism in the forward direction is sequential. Product inhibition studies at high concentrations of APS suggest an ordered kinetic mechanism with MgATP binding before APS. At submicromolar concentrations of APS, product inhibition by both MgADP and PAPS is more complex and is not consistent with a solely ordered sequential mechanism. The formation of a phosphorylated enzyme capable of transferring its phosphoryl group to APS or to MgADP suggests that a ping-pong pathway in which the rate of MgADP dissociation is comparable to the rate of APS binding might contribute at very low concentrations of APS. The substrate inhibition by APS is consistent with APS binding to the enzyme, to form a dead-end E.APS complex.     

Mechanism of ketol acid reductoisomerase--steady-state analysis and metal ion requirement

Ketol acid reductoisomerase is an enzyme of the branched-chain amino acid biosynthetic pathway. It catalyzes two separate reactions: an acetoin rearrangement and a reduction. This paper reports on the purification of the enzyme from a recombinant Escherichia coli and on the steady-state kinetics of the enzyme. The kinetics of the reaction were determined for the forward and reverse reaction by using the appropriate chiral substrates. At saturating metal ion concentrations the mechanism follows an ordered pathway where NADPH binds before acetolactate. The product of the rearrangement of acetolactate, 3-hydroxy-3-methyl-2-oxobutyrate, is shown to be kinetically competent as an intermediate in the enzyme-catalyzed reaction. Starting with acetolactate, Mg2+ is the only divalent metal ion that will support enzyme catalysis. For the reduction of 3-hydroxy-3-methyl-2-oxobutyrate, Mn2+ is catalytically active. Product and dead-end inhibition studies indicate that the binding of metal ion and NADPH occurs randomly. In the forward reaction direction, the deuterium kinetic isotope effect on V/K is 1.07 when acetolactate is the substrate and 1.39 when 3-hydroxy-3-methyl-2-oxobutyrate is the substrate.     

The kinetic mechanism of phage T4 DNA-[N6-adenine]-methyltransferase

Kinetic analysis of methyl group transfer from S-adenosyl-L-methionine (SAM) to the GATC recognition site catalyzed by the phage T4 DNA-[N6-adenine]-methyltransferase (MTase) [EC 2.1.1.72] showed that the reverse reaction is at least 500 times slower than the direct one. The overall pattern of product inhibition corresponds to an ordered steady-state mechanism following the sequence SAM decreases DNA decreases metDNA increases SAH increases (S-adenosyl-L-homocysteine). Pronounced inhibition was observed at high concentrations of the 20-meric substrate duplex, which may be attributed to formation of a dead-end complex MTase-SAH-DNA. In contrast, high SAM concentrations proportionally accelerated the reaction. Thus, the reaction may include a stage whereby the binding of SAM and the release of SAH are united into one concerted event. Computer fitting of alternative kinetic schemes to the aggregate of experimental data revealed that the most plausible mechanism involves isomerization of the enzyme.     

AMP nucleosidase: kinetic mechanism and thermodynamics

The kinetic mechanism of AMP nucleosidase (EC 3.2.2.4; AMP + H2O----adenine + ribose 5-phosphate) from Azotobacter vinelandii is rapid-equilibrium random by initial rate studies of the forward and reverse reactions in the presence of MgATP, the allosteric activator. Inactivation-protection studies have established the binding of adenine to AMP nucleosidase in the absence of ribose 5-phosphate. Product inhibition by adenine suggests a dead-end complex of enzyme, AMP, and adenine. Methanol does not act as a nucleophile to replace H2O in the reaction, and products do not exchange into substrate during AMP hydrolysis. Thus, the reactive complex has the properties of concerted hydrolysis by an enzyme-directed water molecule rather than by formation of a covalent intermediate with ribose 5-phosphate. The Vmax in the forward reaction (AMP hydrolysis) is 300-fold greater than that in the reverse reaction. The Keq for AMP hydrolysis has been experimentally determined to be 170 M and is in reasonable agreement with Keq values of 77 and 36 M calculated from Haldane relationships. The equilibrium for enzyme-bound substrate and products strongly favors the enzyme-product ternary complex ([enzyme-adenine ribose 5-phosphate]/[enzyme-AMP] = 480). The temperature dependence of the kinetic constants gave Arrhenius plots with a distinct break between 20 and 25 degrees C. Above 25 degrees C, AMP binding demonstrates a strong entropic effect consistent with increased order in the Michaelis complex. Below 20 degrees C, binding is tighter and the entropic component is lost, indicating distinct enzyme conformations above and below 25 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)     

Arginyl-tRNA synthetase from Escherichia coli K12. Purification, properties, and sequence of substrate addition.

Arginyl-tRNA synthetase from Escherichia coli K12 has been purified more than 1000-fold with a recovery of 17%. The enzyme consists of a single polypeptide chain of about 60 000 molecular weight and has only one cysteine residue which is essential for enzymatic activity. Transfer ribonucleic acid completely protects the enzyme against inactivation by p-hydroxymercuriben zoate. The enzyme catalyzes the esterification of 5000 nmol of arginine to transfer ribonucleic acid in 1 min/mg of protein at 37 degrees C and pH 7.4. One mole of ATP is consumed for each mole of arginyl-tRNA formed. The sequence of substrate binding has been investigated by using initial velocity experiments and dead-end and product inhibition studies. The kinetic patterns are consistent with a random addition of substrates with all steps in rapid equilibrium except for the interconversion of the cental quaternary complexes. The dissociation constants of the different enzyme-substrate complexes and of the complexes with the dead-end inhibitors homoarginine and 8-azido-ATP have been calculated on this basis. Binding of ATP to the enzyme is influenced by tRNA and vice versa.     

Recombinant human glucose-6-phosphate dehydrogenase. Evidence for a rapid-equilibrium random-order mechanism.

Cloning and over-expression of human glucose 6-phosphate dehydrogenase (Glc6P dehydrogenase) has for the first time allowed a detailed kinetic study of a preparation that is genetically homogeneous and in which all the protein molecules are of identical age. The steady-state kinetics of the recombinant enzyme, studied by fluorimetric initial-rate measurements, gave converging linear Lineweaver-Burk plots as expected for a ternary-complex mechanism. Patterns of product and dead-end inhibition indicated that the enzyme can bind NADP+ and Glc6P separately to form binary complexes, suggesting a random-order mechanism. The Kd value for the binding of NADP+ measured by titration of protein fluorescence is 8.0 microm, close to the value of 6.8 microm calculated from the kinetic data on the assumption of a rapid-equilibrium random-order mechanism. Strong evidence for this mechanism and against either of the compulsory-order possibilities is provided by repeating the kinetic analysis with each of the natural substrates replaced in turn by structural analogues. A full kinetic analysis was carried out with deaminoNADP+ and with deoxyglucose 6-phosphate as the alternative substrates. In each case the calculated dissociation constant upon switching a substrate in a random-order mechanism (e.g. that for NADP+ upon changing the sugar phosphate) was indeed constant within experimental error as expected. The calculated rate constants for binding of the leading substrate in a compulsory-order mechanism, however, did not remain constant when the putative second substrate was changed. Previous workers, using enzyme from pooled blood, have variously proposed either compulsory-order or random-order mechanisms. Our study appears to provide unambiguous evidence for the latter pattern of substrate binding.     

Evolutionary optimization of the catalytic efficiency of enzymes.

1. The rate equation for a generalized Michaelian type of enzymic reaction mechanism has been analyzed in order to establish how the mechanism should be kinetically designed in order to optimize the catalytic efficiency of the enzyme for a given average magnitude of true and apparent first-order rate constants in the mechanism at given concentrations of enzyme, substrate and product. 2. As long as on-velocity constants for substrate and product binding to the enzyme have not reached the limiting value for a diffusion-controlled association process, the optimal state of enzyme operation will be characterized by forward (true and apparent) first-order rate constants of equal magnitude and reverse rate constants of equal magnitude. The drop in free energy driving the catalysed reaction will occur to an equal extent for each reaction step in the mechanism. All internal equilibrium constants will be of equal magnitude and reflect only the closeness of the catalysed reaction to equilibrium conditions. 3. When magnitudes of on-velocity constants for substrate and product binding have reached their upper limits, the optimal kinetic design of the reaction mechanism becomes more complex and has to be established by numerical methods. Numerical solutions, calculated for triosephosphate isomerase, indicate that this particular enzyme may or may not be considered to exhibit close to maximal efficiency, depending on what value is assigned to the upper limit for a ligand association rate constant. 4. Arguments are presented to show that no useful information on the evolutionary optimization of the catalytic efficiency of enzymes can be obtained by previously taken approaches that are based on the application of linear free-energy relationships for rate and equilibrium constants in the reaction mechanism.     

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.     

Polyol-pathway enzymes of human brain. Partial purification and properties of sorbitol dehydrogenase.

Sorbitol dehydrogenase was isolated from human brain and purified 690-fold, giving a final specific activity of 11.1 units/mg of protein. The enzyme preparation was nearly homogeneous, but was unstable at most temperatures. It exhibited a broad pH optimum of 7.5-9.0 in the forward reaction (i.e. sorbitol leads to fructose), and of 7.0 in the reverse reaction (i.e. fructose leads to sorbitol). Substrate-specificity studies demonstrated that the enzyme had the capability to oxidize a wide range of polyols and that the enzyme had a higher affinity for substrates in the forward reaction than in the reverse reaction, e.g. Km for sorbitol was 0.45 mM, and that for fructose was 480 mM. However, the Vmax. was 10 times greater in the reverse reaction. At high concentrations of fructose (500 mM) the enzyme exhibited substrate inhibition in the reverse reaction. The enzyme mechanism was sequential, as determined by the kinetic patterns arising from varying the substrate concentrations. In addition, both fructose and NADH protected the enzyme against thermal inactivation. These findings, together with product-inhibition data, suggested that the mechanism is random rapid equilibrium with two dead-end complexes.     

Uridine phosphorylase from Escherichia coli B.: kinetic studies on the mechanism of catalysis

Using a highly purified enzyme preparation of uridine phosphorylase from Escherichia coli B, we have performed detailed kinetic studies which include initial-velocity and product-inhibition experiments in the forward and reverse directions of the reaction. These studies indicate a rapid-equilibrium random mechanism for this enzyme with the formation of an enzyme . uracil phosphate abortive complex. Lack of formation of the enzyme . uridine . ribose-1-phosphate abortive complex suggests that the ribosyl moiety of the two ligands compete for the same binding site. The random mechanism is different from the ordered addition of substrates found for uridine phosphorylase from other sources. All the kinetic constants in the forward and reverse directions and the Keq of reaction for E. coli uridine phosphorylase are reported herein.     

Complete kinetic mechanism of homoisocitrate dehydrogenase from Saccharomyces cerevisiae

The kinetic mechanism of homoisocitrate dehydrogenase from Saccharomyces cerevisiae was determined using initial velocity studies in the absence and presence of product and dead end inhibitors in both reaction directions. Data suggest a steady state random kinetic mechanism. The dissociation constant of the Mg-homoisocitrate complex (MgHIc) was estimated to be 11 +/- 2 mM as measured using Mg2+ as a shift reagent. Initial velocity data indicate the MgHIc complex is the reactant in the direction of oxidative decarboxylation, while in the reverse reaction direction, the enzyme likely binds uncomplexed Mg2+ and alpha-ketoadipate. Curvature is observed in the double-reciprocal plots for product inhibition by NADH and the dead-end inhibition by 3-acetylpyridine adenine dinucleotide phosphate when MgHIc is the varied substrate. At low concentrations of MgHIc, the inhibition by both nucleotides is competitive, but as the MgHIc concentration increases, the inhibition changes to uncompetitive, consistent with a steady state random mechanism with preferred binding of MgHIc before NAD. Release of product is preferred and ordered with respect to CO2, alpha-ketoadipate, and NADH. Isocitrate is a slow substrate with a rate (V/E(t)) 216-fold slower than that measured with HIc. In contrast to HIc, the uncomplexed form of isocitrate and Mg2+ bind to the enzyme. The kinetic mechanism in the direction of oxidative decarboxylation of isocitrate, on the basis of initial velocity studies in the absence and presence of dead-end inhibitors, suggests random addition of NAD and isocitrate with Mg2+ binding before isocitrate in rapid equilibrium, and the mechanism approximates rapid equilibrium random. The Keq for the overall reaction measured directly using the change in NADH as a probe is 0.45 M.     

Random-order ternary complex reaction mechanism of serine acetyltransferase from Escherichia coli

Although serine acetyltransferase (SAT) from Escherichia coli is homologous with a number of bacterial enzymes that catalyze O-acetyl transfer by a sequential (ternary complex) mechanism, it has been suggested, from experiments with the nearly identical enzyme from Salmonella typhimurium, that the reaction could proceed via an acetyl-enzyme intermediate. To resolve the matter, the E. coli gene for SAT was overexpressed and the enzyme purified 13-fold to homogeneity. The results of a steady-state kinetic analysis of the forward reaction are diagnostic for a ternary complex mechanism, and the response of SAT to dead-end inhibitors indicates a random order for the addition of substrates. The linearity of primary double-reciprocal plots, in the presence and absence of dead-end inhibitors, argues that interconversion of ternary complexes is not significantly faster than kcat, whereas substrate inhibition by serine suggests that breakdown of the SAT.CoA binary complex is rate-determining. The results of equilibrium isotope exchange experiments, for both half-reactions, rule out a "ping-pong" mechanism involving an acetyl-enzyme intermediate, and a pre-steady-state kinetic analysis of the turnover of AcCoA supports such a conclusion. Kinetic data for the reverse reaction (acetylation of CoA by O-acetylserine) are also consistent with a steady-state random-order mechanism, wherein both the breakdown of the SAT*serine complex and the interconversion of ternary complexes are partially rate-determining.     

Purification and properties of L-lysine-alpha-ketoglutarate reductase from human placenta.

l-Lysine-α-ketoglutarate reductase has been extensively purified from human placenta. The enzyme is active in the formation of saccharopine from l-lysine and α-ketoglutarate and possesses a stringent substrate specificity. Steady-state product inhibition studies indicate the possibility of either of two basic reaction mechanisms. The first is an ordered reaction mechanism in which α-ketoglutarate, l-lysine, and NADPH bind to the enzyme followed by the release of NADP and saccharopine. The second mechanism involves an initial binding of NADPH. This is followed by either the ordered addition of α-ketoglutarate and l-lysine with the occurrence of an E-NADPH-saccharopine dead-end complex or by the random addition of α-ketoglutarate and l-lysine with the formation of an E-NADPH-sac-charopine-l-lysine dead-end complex. No inhibition of the forward reaction or stimulation of the reverse reaction by the addition of ammonium sulfate was found; other investigators, working with other mammalian tissue have reported such effects. A molecular weight estimate of 480,000 for both l-lysine-α-ketoglutarate reductase and saccharopine dehydrogenase was obtained on gel filtration. No indication of separation of the two activites was obtained throughout the purification procedure, and the presence of detergents had no effect on the sedimentation rate in the ultracentrifuge or on the migration rate in gel filtration.