Kinetic study of a phosphoryl exchange reaction between fructose and fructose 1-phosphate catalyzed by the membrane-bound enzyme II of the phosphoenolpyruvate-fructose 1-phosphotransferase system of Bacillus subtilis.

A phosphoryl exchange reaction between fructose 1-phosphate and fructose was found to be catalyzed by a membrane preparation isolated from Bacillus subtilis. The regulation of the biosynthesis of the activity in the wild type as well as in the regulation mutants fruB closely correlates with that of the membrane-bound enzyme II of the phosphoenolpyruvate fructose 1-phosphotransferase system which is known to mediate the transmembrane vectorial phosphorylation of fructose. The computed analysis of the kinetic data shows that the mechanism of the enzyme II is ping-pong, i.e. that a phosphoryl-enzyme intermediate occurs in the reaction. The apparent dissociation constants of the enzyme II/fructose 1-phosphate complex and of the phosphoryl enzyme II/fructose complex are estimated. The value of the standard free energy of the hydrolysis of the bond between the phosphoryl moiety and the enzyme suggests a covalent bonding. This intermediate is assumed to occur in the physiological functioning of the enzyme which utilizes the phosphocarrier protein HPr as phosphoryl donor. The exchange reaction is competitively inhibited by high fructose concentrations: this indicates that the same site of the enzyme binds fructose and fructose 1-phosphate, this site being accessible to fructose on the external side of the membrane when the enzyme is phosphorylated.     

Steady state and exchange kinetics of pyruvate, phosphate dikinase from Propionibacterium shermanii.

Evidence is presented based on requirements for exchange in the partial reactions, initial velocity and exchange kinetics and product inhibition, that the pyruvate, phosphate dikinase reaction of propionibacteria occurs by a nonclassical Tri Uni Uni Ping Pong mechanism. The mechanism involves a pyrophosphoryl enzyme, a phosphoryl enzyme, and the free enzyme, and three functionally distinct and independent substrate sites. On the first site, there is pyrophosphorylation of the enzyme by ATP with subsequent release of AMP. The pyrophosphoryl moiety then reacts at the second site with Pi yielding the product PPi and the phosphoryl from of the enzyme. At the third site pyruvate is phosphorylated yielding P-enolpyruvate and the free enzyme. The three catalytic sites are proposed to be linked by a histidyl residue which functions as a pyrophosphoyrl- and phosphoryl-carrier between the three sites. This proposal is based on the following observations. (A) The patterns of the double reciprocal plots of the initial velocities were all parallel; (b) product inhibition between each pair of substrates and products of the three partial reactions were competitive, i.e. ATP against AMP, Pi against PPi, and pyruvate against P-enolpyruvate; (c) the other product inhibitions, with one exception, were noncompetitive as required by the nonclassical ping-pong mechanism; (d) ATP or P-enolpyruvate was required for the Pi in equilibrium PPi exchange reaction which is in accord with the participation of a pyrosphosphoryl or phosphoryl form of the enzyme in this exchange; (e) the ATP in equilibrium AMP exchange and pyruvate in equilibrium P-enolpyruvate exchange did not require additional substrates. In addition, the inhibition and participation in the exchange reactions of the alpha,beta and beta,gamma-methylene analogues of ATP and of the methylene analogue of inorganic pyrophosphate were investigated and the results were in accord with the proposed mechanism. The combined evidence provides a well documented example of a three site nonclassical Tri Uni Uni Ping Pong mechanism.     

Phosphorylation of L-type pyruvate kinase by a Ca2+/calmodulin-dependent protein kinase

Rat liver L-type pyruvate kinase was phosphorylated in vitro by a Ca2+/calmodulin-dependent protein kinase purified from rabbit liver. The calmodulin (CaM)-dependent kinase catalyzed incorporation of up to 1.7 mol of 32P/mol of pyruvate kinase subunit; maximum phosphorylation was associated with a 3.0-fold increase in the K0.5 for P-enolpyruvate. This compares to incorporation of 0.7 to 1.0 mol of 32P/mol catalyzed by the cAMP-dependent protein kinase with a 2-fold increase in K0.5 for P-enolpyruvate. When [32P]pyruvate kinase, phosphorylated by the CaM-dependent protein kinase, was subsequently incubated with 5 mM ADP and cAMP-dependent protein kinase (kinase reversal conditions), 50-60% of the 32PO4 was removed from pyruvate kinase, but the K0.5 for P-enolpyruvate decreased only 20-30%. Identification of 32P-amino acids after partial acid hydrolysis showed that the CaM-dependent protein kinase phosphorylated both threonyl and seryl residues (ratio of 1:2, respectively) whereas the cAMP-dependent protein kinase phosphorylated only seryl groups. The two phosphorylation sites were present in the same 3-4-kDa CNBr fragment located near the amino terminus of the enzyme subunit. These results indicate that the CaM-dependent protein kinase catalyzed phosphorylation of L-type pyruvate kinase at two discrete sites. One site is apparently the same serine which is phosphorylated by the cAMP-dependent protein kinase. The second site is a unique threonine residue whose phosphorylation also inactivates pyruvate kinase by elevating the K0.5 for P-enolpyruvate. These results may account for the Ca2+-dependent phosphorylation of pyruvate kinase observed in isolated hepatocytes.     

The redox state and the phosphorylation state of the mannitol-specific carrier of the E. coli phosphoenolpyruvate-dependent phosphotransferase system

This review summarizes the recent developments in identifying the activity-linked cysteine as one of the phosphorylation sites on the mannitol-specific EII of the E. coli phosphoenolpyruvate-dependent mannitol transport system. Two phosphorylation sites have been identified, one being the HPr/P-HPr exchange site, the other being the mannitol/mannitol-P exchange site. The activity-linked cysteine and the second phosphorylation site are located in the same 14 residue peptide. Phosphorylation of the second site and phosphoryl group transfer to mannitol do not occur as long as the activity-linked cysteine is oxidized or alkylated.A kinetic scheme has been developed which accounts for the relationships between the redox state, the phosphorylation state and the activity of the carrier. Kinetics of the individual reactions determine whether the enzyme cycles through an oxidized/reduced state during a cycle of phosphorylation/dephosphorylation.Abbreviations DTT Dithiothreitol - glc glucose - mtl mannitol - mtl-P mannitol Phosphate - frc fructose - bgl -glucoside - nag N-acetylglucosamine - PTS Phosphoenolpyruvate-dependent Phosphotransferase System - PEP Phosphoenolpyruvate - P-enolpyruvate Phosphoenolpyruvate     

Kinetic mechanism of phosphoenolpyruvate carboxykinase (GTP) from rat liver cytosol. Product inhibition, isotope exchange at equilibrium, and partial reactions

Initial velocity studies of rat liver cytosolic P-enolpyruvate carboxykinase in the direction of P-enolpyruvate formation gave intersecting double reciprocal plots indicating that the reaction conforms to a sequential reaction pathway. A complete product inhibition study with MnGDP-, P-enolpyruvate, and HCO3- as product inhibitors indicated that all patterns were noncompetitive. Isotope exchange at equilibrium with exchange between the substrate/product pairs GTP/GDP oxalacetate/HCO3-, and oxalacetate/P-enolpyruvate while varying the concentration of substrate/product pairs in fixed constant ratio gave no complete inhibitory patterns as the concentration of the constant ratio pairs approached saturation. The exchange rates between the substrate/product pairs differed by a factor of 40 when compared under the same assay conditions. These results were interpreted in terms of a random reaction mechanism in which true dead-end complexes do not form and in which the rate-limiting step is not the interconversion of the ternary quarternary central complexes. In addition to the formation of P-enolpyruvate from oxalacetate and MnGTP2-, the enzyme catalyzes the decarboxylation of oxalacetate to pyruvate in the absence of MnGTP2-. This reaction occurs only slowly in the absence of GDP and most rapidly in the presence of MnGDP-. When only MnGTP2- and oxalacetate are present, no pyruvate is formed, and oxalacetate is converted stoichiometrically to P-enolpyruvate. The enzyme also catalyzes the exchange of [14C]GDP into GTP in the absence of P-enolpyruvate. This exchange is stimulated by the presence of HCO3-. When enzyme is incubated with MnGTP2- in the presence or absence of HCO3-, there is no hydrolysis to form GDP and P1. The two partial reactions, namely the exchange of [14C]GDP with the E.HCO3.MnGTP or E.MnGTP complex and the formation of pyruvate from the E.oxalacetate.MnGDP complex provide pathways by which the expected dead-end complexes can be converted to enzyme forms which can return to the catalytic or exchange sequence.     

Modulation of the phosphorylation state of rat liver pyruvate kinase by allosteric effectors and insulin.

The regulation of pyruvate kinase in isolated hepatocytes from fasted rats was studied where the intracellular level of fructose 1,6-bisphosphate was elevated 5-fold by the addition of 5 mM dihydroxyacetone. In this case, flux through pyruvate kinase was increased. The increase in flux correlated with an elevation in fructose bisphosphate levels but not with P-enolpyruvate levels which were unchanged. Pyruvate kinase was activated and its affinity for P-enolpyruvate was increased 7-fold in hepatocyte homogenates. Precipitation of the enzyme from homogenates with ammonium sulfate removed fructose 1,6-bisphosphate and activation was no longer observed. These results indicate that flux through and activity of pyruvate kinase can be controlled by the intracellular level of fructose 1,6-bisphosphate. The effect of elevated fructose 1,6-bisphosphate levels on the ability of glucagon to inactivate pyruvate kinase was also studied where only covalent enzyme modification is observed. Inactivation by maximally effective hormone concentrations was unaffected by elevated levels of fructose 1,6-bisphosphate, but the half-maximally effective concentration was increased from 0.3 to 0.8 nM. Activation of the cyclic AMP-dependent protein kinase by 0.3 nM glucagon was unaffected, but the initial rate of pyruvate kinase inactivation was suppressed. These results suggest that alterations in the level of fructose 1,6-bisphosphate can affect the ability of physiological concentrations of glucagon to inactivate pyruvate kinase by opposing phosphorylation of the enzyme. Consistent with this view was the finding that physiological concentrations of fructose 1,6-bisphosphate inhibited in vitro phosphorylation of purified pyruvate kinase. Inactivation of pyruvate kinase by 0.3 nM glucagon or 1 microM phenylephrine was also suppressed by 10 nM insulin. Insulin did not act by increasing fructose 1,6-bisphosphate levels. The antagonism to glucagon correlated well with the ability of insulin to suppress activation of the cyclic AMP-dependent protein kinase. However, no such correlation was observed with phenylephrine in the absence or presence of insulin. Thus, insulin can enhance pyruvate kinase activity by both cyclic AMP-dependent and independent mechanisms.     

Coupling of GTP hydrolysis by elongation factor G to translocation and factor recycling on the ribosome

The translocation step of elongation entails the coordinated movement of tRNA and mRNA on the ribosome. Translocation is promoted by elongation factor G (EF-G) and accompanied by GTP hydrolysis, which affects both translocation and turnover of EF-G. Both reactions are much slower (50-100-fold) when GTP is replaced with non-hydrolyzable GTP analogues or GDP, indicating that the reaction rates are determined by conformational transitions induced by GTP hydrolysis. Compared to the rate of uncatalyzed, spontaneous translocation, ribosome binding of EF-G with any guanine nucleotide reduces the free energy of activation by about 18 kJ/mol, whereas GTP hydrolysis contributes another 10 kJ/mol. The acceleration by GTP hydrolysis is due to large decrease in activation enthalpy by about 30 kJ/mol, compared to the reaction with GTP analogues or GDP, whereas the activation entropy becomes unfavorable and is lowered by about 20 kJ/mol (37 degrees C). The data suggest that GTP hydrolysis induces, by a conformational change of EF-G, a rapid conformational rearrangement of the ribosome ("unlocking") which determines the rates of both tRNA-mRNA translocation and recycling of the factor.     

Thermodynamics of the pyruvate kinase reaction and the reversal of glycolysis in heart and skeletal muscle

The effect of temperature, pH, and free [Mg(2+)] on the apparent equilibrium constant of pyruvate kinase (phosphoenol transphosphorylase) (EC ) was investigated. The apparent equilibrium constant, K', for the biochemical reaction P-enolpyruvate + ADP = ATP + Pyr was defined as K' = [ATP][Pyr]/[ADP][P-enolpyruvate], where each reactant represents the sum of all the ionic and metal complexed species in M. The K' at pH 7.0, 1.0 mm free Mg(2+) and I of 0.25 m was 3.89 x 10(4) (n = 8) at 25 degrees C. The standard apparent enthalpy (DeltaH' degrees ) for the biochemical reaction was -4.31 kJmol(-1) in the direction of ATP formation. The corresponding standard apparent entropy (DeltaS' degrees ) was +73.4 J K(-1) mol(-1). The DeltaH degrees and DeltaS degrees values for the reference reaction, P-enolpyruvate(3-) + ADP(3-) + H(+) = ATP(4-) + Pyr(1-), were -6.43 kJmol(-1) and +180 J K(-1) mol(-1), respectively (5 to 38 degrees C). We examined further the mass action ratio in rat heart and skeletal muscle at rest and found that the pyruvate kinase reaction in vivo was close to equilibrium i.e. within a factor of about 3 to 6 of K' in the direction of ATP at the same pH, free [Mg(2+)], and T. We conclude that the pyruvate kinase reaction may be reversed under some conditions in vivo, a finding that challenges the long held dogma that the reaction is displaced far from equilibrium.     

S-phosphocysteine and phosphohistidine are intermediates in the phosphoenolpyruvate-dependent mannitol transport catalyzed by Escherichia coli EIIMtl

During a cycle of mannitol transport and phosphorylation, the phosphoryl group originating on P-enolpyruvate is transferred, consecutively, to two sites on the Escherichia coli mannitol-specific carrier (EIIMtl) before being placed on mannitol [Pas et al. (1988) Biochemistry (in press)]. The peptides constituting the two EIIMtl phosphorylation sites have been isolated and identified after labeling with [32P]-P-enolpyruvate. The first site is localized in peptide Leu 541-Lys 560. The hydrolysis characteristics of the phosphorylated peptide indicate that a histidine residue is phosphorylated. The second site is located in peptide Ile 380-Met 393, which contains the activity-linked cysteine (384) [Pas & Robillard (1988) Biochemistry (in press)]. The hydrolysis characteristics of the phosphopeptide indicate that Cys 384 is the site of phosphorylation.     

Magnetic resonance studies of the interaction of Co2+ and phosphoenolpyruvate with pyruvate kinase.

Co2+, which activates rabbit muscle pyruvate kinase, competes with Mn2+ for the active site of the enzyme with a KD of 46 muM. Co2+ binds to phosphoenolpyruvate with a KD of 4.1 mM. The structures of the binary Co2+/P-enolpyruvate, and quaternary pyruvate kinase/Co2+/K+/P-enolpyruvate complexes were studied using EPR and the effects of Co2+ on the longitudinal (T1) and transverse (T2) relaxation times of the protons of water and P-enolpyruvate and the phosphorus of P-enolpyruvate. The EPR spectra of all complexes at 6 K, disappear above 40 K and reveal principal g values between 2 and 7 indicating high spin Co2+. For free Co2+ and for the binary Co2+/P-enolpyruvate complex, the T1 of water protons was independent of frequency in the range 8, 15, 24.3, 100, and 220 MHz. Assuming coordination numbers (q) of 6 and 5 for free Co2+ and Co2+/P-enolpyruvate, respectively, correlation times (tauc) of 1.3 times 10(-13) and 1.7 times 10(-13) s, were calculated. The distances from Co2+ and phosphorus and to the cis and trans protons in the binary Co2+/P-enolpyruvate complex calculated from their T1 values were 2.7 A, 4.1 A, AND 5.3 A, respectively, indicating an inner sphere phosphoryl complex. Consistent with direct phosphoryl coordination, a large Co2+ to phosphorus hyperfine contact coupling constant (A/h) of 5 times 10(5) Hz was determined by the frequency dependence of the T2 of phosphorus at 25.1, 40.5, and 101.5 MHz. For both enzyme complexes, the dipolar correlation time tauc was 2 times 10(-12) s and the number of rapidly exchanging water ligands (q) was 0.6 as determined from the frequency dependence of the T1 of water protons. In the quaternary enzyme/Co2+/K+/P-enolyruvate complex this tauc value was consistent with the frequency dependence of the T1 of the phosphorus of enzyme-bound P-enolpyruvate at 25.1 and 40.5 MHz. Distances from enzyme-bound C02+ to the phosphorus and protons of P-enolpyruvate, from their T1 values, were 5.0 A and 8 to 10 A, respectively, indicating a predominantly (greater than or equal to 98%) second spere complex and less than 2% inner sphere complex. Consistent with a second sphere complex on the enzyme, an A/h value of less than 10(3) Hz was determined from the frequency dependence of the T2 of phosphorus. In all complexes the exchange reates were found to be faster than the paramagnetic relaxation rates and the hyperfine contact interaction was found to be small compared to the dipolar interaction. The results thus indicate that the interaction of C02+ with P-enolpyruvate is greatly decreased upon binding to the active site of pyruvate kinase.     

Hepatic pyruvate kinase. Regulation by glucagon, cyclic adenosine 3'-5'-monophosphate, and insulin in the perfused rat liver.

A reversible interconversion of two kinetically distinct forms of hepatic pyruvate kinase regulated by glucagon and insulin is demonstrated in the perfused rat liver. The regulation does not involve the total enzyme content of the liver, but rather results in a modulation of the substrate dependence. The forms of pyruvate kinase in liver homogenates are distinguished by measurements of the ratio of the enzyme activity at a subsaturating concentration of P-enolpyruvate (1.3 mM) to the activity at a saturating concentration of this substrate (6.6 mM). A low ratio form of pyruvate kinase (ratio between 0.1 and 0.2) is obtained from livers perfused with 10(-7) M glucagon or 0.1 mM adenosine 3':5'-monophosphate (cyclic AMP). A high ratio form of the enzyme is obtained from livers perfused with no hormone (ratio = 0.35 to 0.45). The regulation of pyruvate kinase by glucagon and cyclic AMP occurs within 2 min following the hormone addition to the liver. Insulin (22 milliunits/ml) counteracts the inhibition of pyruvate kinase caused by 5 X 10(-11) M glucagon, but has only a slight influence on the enzyme properties in the absence of the hyperglycemic hormone. The low ratio form of pyruvate kinase obtained from livers perfused with glucagon or cyclic AMP is unstable in liver extracts and will revert to a high ratio form within 10 min at 37 degrees or within a few hours at 0 degrees. Pyruvate kinase is quantitatively precipitated from liver supernatants with 2.5 M ammonium sulfate. This precipitation stabilizes the enzyme and preserves the kinetically distinguishable forms. The kinetic properties of the two forms of rat hepatic pyruvate kinase are examined using ammonium sulfate precipitates from the perfused rat liver. At pH 7.5 the high ratio form of the enzyme has [S]0.5 = 1.6 +/- 0.2 mM P-enolpyruvate (n = 8). The low ratio form of enzyme from livers perfused with glucagon or cyclic AMP has [S]0.5 = 2.5 +/- 0.4 mM P-enolpyruvate (n = 8). The modification of pyruvate kinase induced by glucagon does not alter the dependence of the enzyme activity on ADP (Km is approximately 0.5 mM ADP for both forms of the enzyme). Both forms are allosterically modulated by fructose 1,6-bisphosphate, L-alanine, and ATP. The changes in the kinetic properties of hepatic pyruvate kinase which follow treating the perfused rat liver with glucagon or cyclic AMP are consistent with the changes observed in the enzyme properties upon phosphorylation in vitro by a clyclic AMP-stimulated protein kinase (Ljungstr?m, O., Hjelmquist, G. and Engstr?m, L. (1974) Biochim. Biophys. Acta 358, 289--298). However, other factors also influence the enzyme activity in a similar manner and it remains to be demonstrated that the regulation of hepatic pyruvate kinase by glucagon and cyclic AMP in vivo involes a phosphorylation.     

Dipole-dipole interaction stabilizes the transition state of apurinic/apyrimidinic endonuclease--abasic site interaction

Human apurinic/apyrimidinic (AP) endonuclease (hAPE) initiates the repair of an abasic site (AP site). To gain insight into the mechanisms of damage recognition of hAPE, we conducted surface plasmon resonance spectroscopy to study the thermodynamics and kinetics of its interaction with substrate DNA containing an abasic site (AP DNA). The affinity of hAPE binding toward DNA increased as much as 6-fold after replacing a single adenine (equilibrium dissociation constant, K(D), 5.3 nm) with an AP site (K(D), 0.87 nm). The enzyme-substrate complex formation appears to be thermodynamically stabilized and favored by a large change in Gibbs free energy, DeltaG degrees (-50 kJ/mol). The latter is supported by a high negative change in enthalpy, DeltaH degrees (-43 kJ/mol) and also positive change in entropy, DeltaS degrees (24 J/(K mol)), and thus the binding process is spontaneous at all temperatures. Analysis of kinetic parameters reveals small enthalpy of activation for association, DeltaH degrees++(ass) (-17 kJ/mol), and activation energy for association (E(a), -14 kJ/mol) when compared with the enthalpy of activation for dissociation, DeltaH degrees++(diss) (26 kJ/mol), and activation energy in the reverse direction (E(d), 28 kJ/mol). Furthermore, varying concentration of KCl showed an increase in binding affinity at low concentration but complete abrogation of the binding at higher concentration, implying the importance of hydrophobic, but predominantly ionic, forces in the Michaelis-Menten complex formation. Thus, low activation energy and the enthalpy of activation, which are perhaps a result of dipole-dipole interactions, play critical roles in AP site binding of APE.     

Equilibrium constants under physiological conditions for the reactions of choline kinase and the hydrolysis of phosphorylcholine to choline and inorganic phosphate.

The observed equilibrium constants (Kobs) of the P-choline hydrolysis reaction have been determined under physiological conditions of temperature (38 degrees) and ionic strength (0.25 M) and physiological ranges of pH and free [Mg2+]. Using sigma and square brackets to indicate total concentrations: (see article.) The value of Kobs has been found to be relatively insensitive to variations in pH and free [Mg2+]. At pH 7.0 and taking the standard state of liquid water to have unit activity ([H2O] = 1), Kobs = 26.6 M at free [Mg2+] = 0 [epsilon G0obs = -2.03 kcal/mol(-8.48 kJ/mol)], 26.8 M at free [Mg2+] = 10(-3) M, and 28.4 M at free [Mg2+] = 10(-2) M. At pH 8.0, Kobs = 18.8 M at free [Mg2+] = 0, 19.2 M at free [Mg2+] = 10(-3), and 22.2 M at free [Mg2+] = 10(-2) M. These values apply only to situations where choline and Pi concentrations are both relatively low (such as the conditions found in most tissues). At higher concentrations of phosphate and choline, the value of Kobs becomes significantly increased since HPO42- complexes choline weakly (association constant = 3.3 M-1). The value of K at 38 degrees and I = 0.25 M is calculated to be 16.4 +/- 0.3 M [epsilonG0 = 1.73 kcal/mol (-7.23 kJ/mol)]. The K for the P-choline hydrolysis reaction has been combined with the K for the ATP hydrolysis reaction determined previously under physiological conditions to calculate a value of 4.95 X 10(-3 M [deltaG0 j.28 kcal/mol (13.7 kJ/mol] for the K of the choline kinase reaction (EC 2.7.1.32), an important step in phospholipid metabolism: (see article.) Likewise, values for Kobs for the choline kinase reaction at 38 degrees, pH 7.0, and I = 0.25 M have been calculated to be 5.76 X 10(4) [deltaG0OBS = -6.77 KCAL/MOL (-28.3 KJ/mol)] at [Mg2+] = 0; 1.24 X 10(4) [deltaG0obs = -5.82 kcal/mol (-24.4 kJ/mol)] at [Mg2+] = 10(-3) M and 8.05 X 10(3) [delta G0obs = -5.56 kcal/mol (-23.3 kJ/mol)] at [Mg2+ = 10(-2) M. Attempts to determine the Kobs of the choline kinase reaction directly were unsuccessful because of the high value of the constant. The results indicate that in contrast to the high deltaG0obs for the hydrolysis of the ester bond of acetylcholine, the deltaG0obs for the hydrolysis of the ester bond of P-choline is quite low, among the lowest known for phosphate ester bonds of biological interest.     

Kinetic and thermodynamic study of cloned thermostable endo-1,4-β-xylanase from Thermotoga petrophila in mesophilic host

The 1,044 bp endo-1,4-β-xylanase gene of a hyperthermophilic Eubacterium, "Thermotoga petrophila RKU 1" (T. petrophila) was amplified, from the genomic DNA of donor bacterium, cloned and expressed in mesophilic host E. coli strain BL21 Codon plus. The extracellular target protein was purified by heat treatment followed by anion and cation exchange column chromatography. The purified enzyme appeared as a single band, corresponding to molecular mass of 40 kDa, upon SDS-PAGE. The pH and temperature profile showed that enzyme was maximally active at 6.0 and 95 °C, respectively against birchwood xylan as a substrate (2,600 U/mg). The enzyme also exhibited marked activity towards beech wood xylan (1,655 U/mg). However minor activity against CMC (61 U/mg) and β-Glucan barley (21 U/mg) was observed. No activity against Avicel, Starch, Laminarin and Whatman filter paper 42 was observed. The K(m), V(max) and K (cat) of the recombinant enzyme were found to be 3.5 mg ml(-1), 2778 μmol mg(-1)min(-1) and 2,137,346.15 s(-1), respectively against birchwood xylan as a substrate. The recombinant enzyme was found very stable and exhibited half life (t(?)) of 54.5 min even at temperature as high as 96 °C, with enthalpy of denaturation (ΔH*(D)), free energy of denaturation (ΔG*(D)) and entropy of denaturation (ΔS*(D)) of 513.23 kJ mol(-1), 104.42 kJ mol(-1) and 1.10 kJ mol(-1)K(-1), respectively at 96 °C. Further the enthalpy (ΔH*), Gibbs free energy (ΔG*) and entropy (ΔS*) for birchwood xylan hydrolysis by recombinant endo-1,4-β-xylanase were calculated at 95 °C as 62.45 kJ mol(-1), 46.18 kJ mol(-1) and 44.2 J mol(-1) K(-1), respectively.     

Slow inhibition of almond beta-glucosidase by azasugars: determination of activation energies for slow binding

The thermodynamic and activation energies of the slow inhibition of almond beta-glucosidase with a series of azasugars were determined. The inhibitors studied were isofagomine ((3R,4R,5R)-3,4-dihydroxy-5-hydroxymethylpiperidine, 1), isogalactofagomine ((3R,4S,5R)-3,4-dihydroxy-5-hydroxymethylpiperidine, 2), (-)-1-azafagomine ((3R,4R,5R)-4,5-dihydroxy-3-hydroxymethylhexahydropyridazine, 3), 3-amino-3-deoxy-1-azafagomine (4) and 1-deoxynojirimycin (5). It was found that the binding of 1 to the enzyme has an activation enthalpy of 56.1 kJ/mol and an activation entropy of 25.8 J/molK. The dissociation of the enzyme-1 complex had an activation enthalpy of -2.5 kJ/mol and an activation entropy of -297 J/molK. It is suggested that the activation enthalpy of association is due to the breaking of bonds to water, while the large negative activation entropy of dissociation is due at least in part to the resolvation of the enzyme with water molecules. For the association of 1 DeltaH(0) is 58.6 kJ/mol and DeltaS(0) is 323.8 J/molK. Inhibitor 3 has an activation enthalpy of 39.3 kJ/mol and an activation entropy of -17.9 J/molK for binding to the enzyme, and an activation enthalpy of 40.8 kJ/mol and an activation entropy of -141.0 J/molK for dissociation of the enzyme-inhibitor complex. For the association of 3 DeltaH(0) is -1.5 kJ/mol and DeltaS(0) is 123.1 J/molK. Inhibitor 5 is not a slow inhibitor, but its DeltaH(0) and DeltaS(0) of association are -30 kJ/mol and -13.1 J/molK. The large difference in DeltaS(0) of association of the different inhibitors suggests that the anomeric nitrogen atom of inhibitors 1-4 is involved in an interaction that results in a large entropy increase.     

Phosphoenolpyruvate-dependent fructose phosphotransferase system of Rhodopseudomonas sphaeroides: purification and physicochemical and immunochemical characterization of a membrane-associated enzyme I

The phosphotransferase system (PTS) of the phototrophic bacterium Rhodopseudomonas sphaeroides consists of a component located in the cytoplasmic membrane and a membrane-associated enzyme called "soluble factor" (SF) [Saier, M. H., Feucht, B. U., & Roseman, S. (1971) J. Biol. Chem. 246, 7819--7821]. SF has been partially purified by a combination of hydrophobic interaction and ion-exchange and gel-permeation chromatography. SF is similar to Escherichia coli enzyme I in its molecular characteristics and enzymatic properties. It has a molecular weight of 85 000 and readily dimerizes. Phosphoenolpyruvate and Mg2+ stabilize the dimer. The enzyme catalyzes the conversion of phosphoenolpyruvate into pyruvate and becomes phosphorylated in the process. The phosphoryl group is subsequently transferred to fructose in the presence of R. sphaeroides membranes. SF substitutes for E. coli enzyme I in fructose or glucose phosphorylation with E. coli enzyme II and HPr. The activities of SF with the R. sphaeroides PTS and the E. coli PTS reside on structurally distinct molecules as shown by their response to limited proteolytic digestion and by immunochemical studies. The activity of SF with the E. coli PTS arises during the isolation procedure and is most likely due to the removal of HPr-like protein from SF.     

Thermodynamics of hexokinase catalyzed reactions. II. Measurement and calculation of enthalpies of reaction as a function of magnesium ion concentration.

Enthalpies of phosphorylation of glucose by adenosine 5'-triphosphate have been measured as a function of concentrations of magnesium chloride in TRIS/TRIS-HCl buffer in the pH range 8.64 to 8.98. These measurements are compared with the results of calculations of these enthalpies that use a coupled equilibrium formalism with equilibrium data and enthalpy values selected from the literature. The experimental results span the range of magnesium ion concentrations 1 X 10(-6) to 0.3 mol alpha-1 and show a total variation in the enthalpy of reaction of almost 10 kJ mol-1, with the most exothermic reaction occurring at a magnesium ion concentration of 6.0 X 10(-4) mol alpha-1. The calculated enthalpies of reaction, except for the magnesium ion concentration range 4 X 10(-6) to 5 X 10(-4) mol alpha-1, are, within estimated uncertainty intervals (0.8 to 10.2 kJ mol-1), in agreement with the measured values.     

Comparative thermodynamic analysis of DNA--protein interactions using surface plasmon resonance and fluorescence correlation spectroscopy

We report a kinetic and thermodynamic analysis of interactions between ssDNA and replication protein A (RPA) using surface plasmon resonance (SPR) and fluorescence correlation spectroscopy (FCS) at variable temperature. The two methods yield different values for the Gibbs free energy but nearly the same value for the reaction enthalpy of ssDNA-RPA complex formation. The Gibbs free energy was determined by SPR and FCS to be -62.6 and -54.7 kJ/mol, respectively. The values for the reaction enthalpy are -64.4 and -66.5 kJ/mol. It is concluded that the difference in Gibbs free energy measured by the two methods is due to different reaction entropies. The entropic contribution to the free energy at 25 degrees C is -1.8 kJ/mol for SPR and -11.8 kJ/mol for FCS. In SPR, the reaction is restricted to two dimensions because of immobilization of the DNA molecules to the sensor surface. In contrast, FCS is able to follow complex formation without spatial restrictions. In consequence, the reaction entropy determined from SPR experiments is lower than for FCS experiments.     

Phosphorylation and inactivation of the pyruvate dehydrogenase from the anaerobic parasitic nematode, Ascaris suum. Stoichiometry and amino acid sequence around the phosphorylation sites

Tryptic digestion of the fully phosphorylated Ascaris suum pyruvate dehydrogenase complex yielded a single tetradecapeptide containing 2 phosphorylated serine residues. Its amino acid sequence was Tyr-Ser-Gly-His-Ser(P)-Met-Ser-Asp-Pro-Gly-Thr-Ser(P)-Tyr-Arg and was very similar to one of the tryptic phosphopeptides isolated from mammalian and yeast pyruvate dehydrogenases. At partial phosphorylation, three peptides were isolated which corresponded to the monophosphorylated (sites 1 and 2) and diphosphorylated tetradecapeptides. In contrast to results reported from mammalian complexes, phosphorylation of the ascarid complex paralleled inactivation, and no additional phosphorylation occurred after inactivation was complete. Complete inactivation of the complex was associated with the incorporation of 1.7-1.9 mol of phosphoryl groups/mol of alpha-pyruvate dehydrogenase subunit, and the strict preference of the pyruvate dehydrogenase kinase for site 1 was not observed. Whereas site 1 was initially phosphorylated more rapidly than site 2, at 50% inactivation, 41% of the incorporated phosphoryl groups were incorporated into site 2. In addition, substantial amounts of peptide monophosphorylated at site 2 also accumulated, suggesting that prior phosphorylation at site 1 was not necessary for phosphorylation at site 2. Phosphorylation also caused a marked decrease in the mobility of the alpha-pyruvate dehydrogenase subunit on sodium dodecyl sulfate-polyacrylamide gels and the apparent separation of mono- and diphosphorylated forms of the enzyme. The significance of these observations in the regulation of the unique anaerobic mitochondrial metabolism of A. suum is discussed.     

Calorimetric study on human erythrocyte glycolysis. Heat production in various metabolic conditions.

The heat production of human erythrocytes was measured on a flow microcalorimeter with simultaneous analyses of lactate and other metabolites. The heat production connected with the lactate formation was about 17 kcal (71 kJ) per mol lactate formed which corresponded to the sum of heat production due to the formation of lactate from glucose and the heat production due to neutralization. The heat production rate increased as the pH of the suspension increased, corresponding to the increase in lactate formation. Glycolytic inhibitors such as fluoride and monoiodoacetate caused a decrease in the rate of heat production, whereas arsenate induced a large transient increase in heat production associated with a transient increase in lactate formation. Decrease in pyruvate concentration was usually associated with increase in heat production, although the decreased pyruvate concentration was coupled with formation of 2,3-bisphosphoglycerate. When inosine, dihydroxyacetone or D-glyceraldehyde was used as a substrate, an increase in the heat production rate was observed. Addition of methylene blue caused an oxygen uptake which was accompanied by a remarkable increase in heat production rate corresponding to about 160 kcal (670 kJ) per mol oxygen consumed. The value for heat production in red cells in the above-mentioned metabolic conditions was considered in relation to earlier known data on free energy and enthalpy changes of the different metabolic steps in the glycolytic pathway.