Yeast glutathione reductase. Steady-state kinetic studies of its transhydrogenase activity.

Yeast glutathione reductase catalyzes a pyridine nucleotide transhydrogenase reaction using either NADPH or NADH as the electron donor and thionicotinamideadenine dinucleotide phosphate as the electron acceptor. Competitive substrate inhibition of the transhydrogenase reaction by NADPH (K_i = 11 μM) is observed when NADPH is the electron donor. Competitive substrate inhibition by thionicotinamide-adenine dinucleotide phosphate (K_i = 58 μM) is observed with NADH as the electron donor. The turnover numbers of the two transhydrogenase reactions are similar and are equal to about 1% of the turnover number for the NADPH-dependent reduction of oxidized glutathione catalyzed by the enzyme. The transhydrogenase kinetics are analyzed in terms of a pingpong mechanism. It is concluded that the substrate inhibition results from formation of abortive complexes of NADPH with the reduced form of the enzyme and of thionicotinamide-adenine dinucleotide phosphate with the oxidized form of the enzyme. With NADPH as the electron donor, the apparent Michaelis constant for thionicotinamide-adenine dinucleotide phosphate is sensitive to the ionic composition of the assay medium. The data are interpreted to support the existence of a general pyridine nucleotide-binding site at the active site of the enzyme and separate from the binding site for oxidized glutathione.     

Steady-state kinetic investigation of specific anion effects on the catalytic activity of yeast glutathione reductase

The catalytic activity of yeast glutathione reduetase at pH 7.6 is sensitive to the sodium phosphate buffer concentration and the presence of monovalent sodium salts in the assay medium. Low concentrations of sodium phosphate activate and high concentrations inhibit enzymatic activity. The optimal concentration is at about 0.06 m sodium phosphate. In the presence of 0.06 m sodium phosphate, addition of a variety of monovalent sodium salts results in inhibition of enzymatic activity, the inhibition being competitive with respect to NADPH and noncompetitive with respect to oxidized glutathione. At suboptimal concentrations of sodium phosphate, addition of monovalent sodium salts activates enzymatic activity. In addition, at suboptimal sodium phosphate concentration Lineweaver-Burk plots of initial velocity at constant NADPH concentration with oxidized glutathione as the variable substrate are nonlinear, being concave down. The nonlinear behavior can be eliminated by addition of 0.1 m sodium chloride. It is concluded that there are at least two specific anion binding sites at or near the enzyme active site. The anion inhibition is explained in terms of an ordered sequential mechanism for glutathione reduetase. The anion activation is analyzed in terms of a change of reaction pathway, the reactive enzyme species being dependent upon the oxidized glutathione concentration.     

Human erythrocyte glutathione reductase: pH dependence of kinetic parameters

Human erythrocyte glutathione reductase catalyzes the pyridine nucleotide dependent reduction of oxidized glutathione (GSSG). The pH dependence of the kinetic parameters V and V/K for three reduced pyridine nucleotide substrates, the Ki's for three competitive inhibitors (versus NADPH), and the temperature dependence of the V pH profile have been determined. Below pH 8, V and V/K for NADPH, 2',3'-cyclic-NADPH, and NADH are pH independent. In the basic pH region, both V and V/K for the three substrates are pH dependent. All three of the V profiles decrease with increasing pH as a group with a pKa of approximately 9.2 is titrated. The V/K profiles for NADPH, 2',3'-cyclic-NADPH, and NADH decrease at high pH as a group with a pKa of greater than 9.8, 8.9, and 8.8, respectively, is deprotonated. The Ki's for ATP-ribose and 2',5'-ADP are pH independent below pH 8 but increase in the basic region as a group with a pKa of about 8.8 and 8.5, respectively, is deprotonated. The Ki of AADP is pH independent between pH 6 and 9. These studies suggest that binding interactions between the 2'-phosphate of NADPH and the enzyme are predominately nonionic. The temperature dependence of the pK observed in all V pH profiles allows the calculation of an enthalpy of ionization of 3.2 kcal/mol for this group. The high pK and low enthalpy of ionization suggest that the protonation state of the His-467'-Glu-472' ion pair observed in the structure of human erythrocyte glutathione reductase influences proton-transfer steps occurring in the oxidative half-reaction.     

Role of the charged groups of glutathione disulfide in the catalysis of glutathione reductase: crystallographic and kinetic studies with synthetic analogues

Six analogues of glutathione disulfide were synthesized. All of them involved the abolishment of charges, either by amidation of carboxylates or by removal of amino groups. Four of these analogues could be bound to crystalline oxidized glutathione reductase, and their binding modes could be established by X-ray analyses at 2.4-A resolution. All six analogues were catalytically processed; the kinetic parameters were determined. The two analogues that did not bind in the crystals had by far the poorest catalytic efficiencies. Kinetic parameters together with X-ray data show the influence of each charged group on binding and catalytic rate. Data analysis indicates that the enzyme avoids processing of incorrect substrates in two ways: First, it reduces their binding strengths and/or enforces displacement of catalytically important substrate parts. Furthermore, it forms a fragile cluster of bound substrate and catalytically competent residues, which is unbalanced by incorrect parts of the substrate such that catalysis is prevented. A scouting microcalorimetric study using glutathione disulfide yielded a binding enthalpy of -103 (+/- 10) kJ/mol at 25 degrees C and a heat capacity change of -8 (+/- 1) kJ.mol-1.K-1. The study showed that it is feasible to measure these parameters as a function of substrate modification.     

Comparative studies of glutathione reductase and lipoamide dehydrogenase

1. Glutathione reductase and lipoamide dehydrogenase are structurally and mechanistically related flavoenzymes catalyzing various one and two electron transfer reactions between NAD(P)H and substrates with different structures. 2. The two enzymes differ in their coenzyme and functional specificities. Lipoamide dehydrogenase shows higher coenzyme preference while glutathione reductase displays greater functional specificity. 3. Binding preference of the two flavoenzymes for nicotinamide coenzymes is demonstrated by 31P-NMR spectroscopy. 4. The presence of arginines in glutathione reductase which is inactivated by phenyl glyoxal, is likely to be responsible for the NADPH-activity of glutathione reductase. 5. The substrate binding sites of the two enzymes are similar, though their functional details differ. 6. The active-site histidine of glutathione reductase functions primarily as the proton donor during catalysis. While the active-site histidine of lipoamide dehydrogenase stabilizes the thiolate anion intermediate and relays a proton in the catalytic process.     

Docking and molecular dynamics studies at trypanothione reductase and glutathione reductase active sites

A theoretical docking study on the active sites of trypanothione reductase (TR) and glutathione reductase (GR) with the corresponding natural substrates, trypanothione disulfide (T[S]2) and glutathione disulfide (GSSG), is reported. Molecular dynamics simulations were carried out in order to check the robustness of the docking results. The energetic results are in agreement with previous experimental findings and show the crossed complexes have lower stabilization energies than the natural ones. To test DOCK3.5, four nitro furanic compounds, previously designed as potentially active anti-chagasic molecules, were docked at the GR and TR active sites with the DOCK3.5 procedure. A good correlation was found between differential inhibitory activity and relative interaction energy (affinity). The results provide a validation test for the use of DOCK3.5 in connection with the design of anti-chagasic drugs.     

Interaction of a glutathione S-conjugate with glutathione reductase. Kinetic and X-ray crystallographic studies

S-Conjugates of glutathione influence the glutathione/glutathione disulfide (GSH/GSSG) status of hepatocytes in at least two ways, namely by inhibition of GSSG transport into the bile [Akerboom et al. (1982) FEBS Lett. 140, 73-76] and by inhibition of the enzyme GSSG reductase (EC 1.6.4.2). The interaction of GSSG reductase with a well-studied conjugate, namely S-(2,4-dinitrophenyl)-glutathione and its electrophilic precursor 1-chloro-2,4-dinitrobenzene are described. For short exposures both compounds are reversible inhibitors of the enzyme, the Ki values being 30 microM and 22 microM respectively. After prolonged incubation, 1-chloro-2,4-dinitrobenzene blocks GSSG reductase irreversibly, which emphasizes the need for rapid conjugate formation in situ. As shown by X-ray crystallography the major binding site of S-(2,4-dinitrophenyl)-glutathione in GSSG reductase overlaps the binding site of the substrate, glutathione disulfide. However, the glutathione moiety of the conjugate does not bind in the same manner as either of the glutathiones in the disulfide.     

Switching kinetic mechanism and putative proton donor by directed mutagenesis of glutathione reductase

By directed mutagenesis of the cloned Escherichia coli gor gene encoding the flavoprotein glutathione reductase, Tyr-177 (the residue corresponding to Tyr-197 in the NADPH-binding pocket of the homologous human enzyme) was changed to phenylalanine (Y177F), serine (Y177S), and glycine (Y177G). The catalytic activity of the Y177F mutant was very similar to that of the wild-type enzyme, but that of the Y177S and Y177G mutants was substantially diminished. However, all three mutants retained the ability to protect the reduced flavin from adventitious oxidation, indicating that Tyr-177 does not act as a simple "lid" on the NADPH-binding pocket and that the protection of the reduced enzyme must be due largely to burial of the isoalloxazine ring in the protein. The wild-type enzyme and Y177F mutant displayed ping-pong kinetics, but the Y177S and Y177G mutants appeared to have switched to an ordered sequential mechanism. This could be explained by supposing that the enzyme normally functions by a hybrid kinetic mechanism and that the Y177S and Y177G mutations diverted flux from the ping-pong loop favored by the wild-type enzyme to an ordered sequential loop. The necessary change in the partitioning of the common E-NADPH intermediate could be caused by a slowing of the formation of the EH2 intermediate on the ping-pong loop, or by the observed concomitant fall in the Km for glutathione favoring flux through the ordered sequential loop. In another experiment, His-439, thought to act as a proton donor/acceptor in the glutathione-binding pocket, was mutated to a glutamine residue.(ABSTRACT TRUNCATED AT 250 WORDS)     

Activity and kinetic characteristics of glutathione reductase in vitro in reverse micellar waterpool

The enzyme activity of glutathione reductase (NAD(P)H:oxidized-glutathione oxidoreductase, EC 1.6.4.2) incorporated in CTAB/H2O/CHCl3-isooctane (1:1, v/v) reverse micelles has been investigated. Enzyme follows the Michaelis-Menten kinetics within a specified concentration range. Effects of pH, waterpool (W0), and surfactant concentration on the activity of glutathione reductase have been studied in detail. Optimum pH for the maximum enzyme activity was found to be dependent on the size of the waterpool. Further, a substrate inhibition was observed when concentration of one of the substrates was present in large excess over the other substrate. Km values for the substrate, oxidized glutathione (GSSG) and NADPH in CTAB/H2O/CHCl3-isooctane (1:1, v/v) were determined at W0 values of 14.4, 20.0, 25.5 and 29.7, at pH 8.0. These values are close to those obtained in aqueous solution, whereas the kcat values vary with W0 values of 8.8 to 32.3. Studies on the storage stability in the reverse micelle at W0 29.7 and pH 8.0 showed that glutathione reductase retained about 80% of its activity even after a month. The enzyme showed a higher stability at high waterpool. Oxidized glutathione (GSSG) provides protection to glutathione reductase against denaturation on storage in reverse micellar solution. Apparently, the enzyme is able to acquire a suitable native conformation at waterpool 29.7 and pH 8.0 and thereby exhibits an activity and stability inside the micellar cavity that are almost equivalent to that in aqueous solution.     

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.     

Chloroplast glutathione reductase

Glutathione reductase (EC 1.6.4.2) activity is present in spinach (Spinacia oleracea L.) chloroplasts. The pH dependence and substrate concentration for half-maximal rate are reported and a possible role in chloroplasts is proposed.     

Steady-state kinetic behaviour of functioning-dependent structures

A fundamental problem in biochemistry is that of the nature of the coordination between and within metabolic and signalling pathways. It is conceivable that this coordination might be assured by what we term functioning-dependent structures (FDSs), namely those assemblies of proteins that associate with one another when performing tasks and that disassociate when no longer performing them. To investigate a role in coordination for FDSs, we have studied numerically the steady-state kinetics of a model system of two sequential monomeric enzymes, E(1) and E(2). Our calculations show that such FDSs can display kinetic properties that the individual enzymes cannot. These include the full range of basic input/output characteristics found in electronic circuits such as linearity, invariance, pulsing and switching. Hence, FDSs can generate kinetics that might regulate and coordinate metabolism and signalling. Finally, we suggest that the occurrence of terms representative of the assembly and disassembly of FDSs in the classical expression of the density of entropy production are characteristic of living systems.     

Steady-state kinetic mechanism of PDK1

PDK1 catalyzes phosphorylation of Thr in the conserved activation loop region of a number of its downstream AGC kinase family members. In addition to the consensus sequence at the site of phosphorylation, a number of PDK1 substrates contain a PIF sequence (PDK1-interacting fragment), which binds and activates the kinase domain of PDK1 (PDK1(deltaPH)). To gain further insight to PIF-dependent catalysis, steady-state kinetic and inhibition studies were performed for His6-PDK1(deltaPH)-catalyzed phosphorylation of PDK1-Tide (Tide), which contains an extended "PIF" sequence C-terminal to the consensus sequence for PDK1 phosphorylation. In two-substrate kinetics, a large degree of negative binding synergism was observed to occur on formation of the active ternary complex (alphaKd(ATP) = 40 microM and alphaKd(Tide) = 80 microM) from individual transitory binary complexes (Kd(ATP) = 0.6 microM and Kd(Tide) = 1 microM). On varying ATP concentrations, the ADP product and the (T/E)-PDK1-Tide product analog (p'Tide) behaved as competitive and noncompetitive inhibitors, respectively; on varying Tide concentrations, ADP and p'Tide behaved as noncompetitive and competitive inhibitors, respectively. Also, negative binding synergism was associated with formation of dead-end inhibited ternary complexes. Time progress curves in pre-steady-state studies under "saturating" or kcat conditions showed (i) no burst or lag phenomena, (ii) no change in reaction velocity when adenosine 5'-O-(thiotriphosphate) was used as a phosphate donor, and (iii) no change in reaction velocity on increasing relative microviscosity (0 < or = eta/eta0 < or = 3). Taken together, PDK1-catalyzed trans-phosphorylation of PDK1-Tide approximates a Rapid Equilibrium Random Bi Bi system, where motions in the central ternary complex are largely rate-determining.     

Inhibition of glutathione disulfide reductase by glutathione

Rat-liver glutathione disulfide reductase is significantly inhibited by physiological concentrations of the product, glutathione. GSH is a noncompetitive inhibitor against GSSG and an uncompetitive inhibitor against NADPH at saturating concentrations of the fixed substrate. In both cases, the inhibition by GSH is parabolic, consistent with the requirement for 2 eq. of GSH in the reverse reaction. The inhibition of GSSG reduction by physiological levels of the product, GSH, would result in a significantly more oxidizing intracellular environment than would be realized in the absence of inhibition. Considering inhibition by the high intracellular concentration of GSH, the steady-state concentration of GSSG required to maintain a basal glutathione peroxidase flux of 300 nmol/min/g in rat liver is estimated at 8-9 microM, about 1000-fold higher than the concentration of GSSG predicted from the equilibrium constant for glutathione reductase. The kinetic properties of glutathione reductase also provide a rationale for the increased glutathione (GSSG) efflux observed when cells are exposed to oxidative stress. The resulting decrease in intracellular GSH relieves the noncompetitive inhibition of glutathione reductase and results in an increased capacity (Vmax) and decreased Km for GSSG.     

Steady-state kinetic studies of the metal ion-dependent decarboxylation of oxalacetate catalyzed by pyruvate kinase

Steady-state kinetic studies with differing divalent metals ions have been carried out on the pyruvate kinase-catalyzed, divalent cation-dependent decarboxylation of oxalacetate to probe the role of the divalent metal ion in this reaction. With either Mn2+ or Co2+, initial velocity patterns show that the divalent metal ion is bound to the enzyme in a rapid equilibrium prior to the addition of oxalacetate. Further, there is no change in the initial velocity patterns or the kinetic parameters in the presence or absence of K+, indicating that K+ is not required for oxalacetate decarboxylation. Dead-end inhibition of the decarboxylation reaction by the physiological substrate phosphoenolpyruvate indicates that phosphoenolpyruvate binds only to the enzyme-metal ion complex and not to free enzyme. The pKi values for both Mn2+ and Co2+ decrease below a pK of 7.0, and increase above a pK of 8.9. Since these pK values are the same for both ions, both of the observed pK values must be attributable to enzymatic residues. The pK of 7.0 is presumably that of a ligand to the metal ion, while the pK of 8.9 is probably that of the lysine involved in enolization of pyruvate in the normal physiological reaction. However, with Co2+ as divalent cation, the V for oxalacetate decreases above a pK of 8.0, the V/K decreases above two pK values averaging 7.8, and the pKi for oxalate decreases above a single pK of 7.3. These data indicate that metal-coordinated water is displaced during the binding of substrates or inhibitors and the other pK value observed in both V and V/K pH profiles (pK of 8.3 with Co2+ and 9.2 with Mg2+) is an enzymatic residue whose deprotonation disrupts the charge distribution in the active site and decreases activity.     

Steady-state kinetic mechanism of recombinant avocado ACC oxidase: initial velocity and inhibitor studies

The gaseous plant hormone ethylene modulates a wide range of biological processes, including fruit ripening. It is synthesized by the ascorbate-dependent oxidation of 1-aminocyclopropyl-1-carboxylate (ACC), a reaction catalyzed by ACC oxidase. Recombinant avocado (Persea americana) ACC oxidase was expressed in Escherichia coli and purified in milligram quantities, resulting in high levels of ACC oxidase protein and enzyme activity. An optimized assay for the purified enzyme was developed that takes into account the inherent complexities of the assay system. Fe(II) and ascorbic acid form a binary complex that is not the true substrate for the reaction and enhances the degree of ascorbic acid substrate inhibition. The K(d) value for Fe(II) (40 nM, free species) and the K(m)'s for ascorbic acid (2.1 mM), ACC (62 microM), and O(2) (4 microM) were determined. Fe(II) and ACC exhibit substrate inhibition, and a second metal binding site is suggested. Initial velocity measurements and inhibitor studies were used to resolve the kinetic mechanism through the final substrate binding step. Fe(II) binding is followed by either ascorbate or ACC binding, with ascorbate being preferred. This is followed by the ordered addition of molecular oxygen and the last substrate, leading to the formation of the catalytically competent complex. Both Fe(II) and O(2) are in thermodynamic equilibrium with their enzyme forms. The binding of a second molecule of ascorbic acid or ACC leads to significant substrate inhibition. ACC and ascorbate analogues were used to confirm the kinetic mechanism and to identify important determinants of substrate binding.