A continuous fluorometric assay for flavokinase. Properties of flavokinase from Peptostreptococcus elsdenii.

A continuous fluorometric assay that utilizes apoflavodoxin as a trapping agent for riboflavin 5'-phosphate (FMN) has been developed for flavokinase (ATP:riboflavin 5'-phosphotransferase, EC 2.7.1.26). Use of this assay is illustrated in a procedure for the partial purification of flavokinase from the strict anaerobe Peptostreptococcus elsdenii. The purified enzyme catalyzed the formation of 8.3 nmol FMN - min-1 - mg-1 at 37 degrees C and had apparent Km values for riboflavin and ATP of 10 and 4.7 micronM, respectively. ATP could be replaced by ADP (22% of the rate observed with ATP) but not by GTP. The enzyme also phosphorylated 5-deaza- and 8-bromoriboflavin with activities of 15 and 70%, respectively, of that with riboflavin; it was inactive with iso riboflavin and deoxyriboflavin.

Studies on the binding of FMN by apoflavodoxin from Peptostreptococcus elsdenii, pH and NaCl concentration dependence.

1. The pH and ionic strength dependence of the interaction of FMN with apoflavodoxin has been studied by fluorometry in the pH region 2-5, at 22 degrees C. 2. The rate constant of dissociation and the dissociation constant were experimentally determined; the rate constants of association were claculated at a given pH value. These constants depend on the ionic strength. The plots of these constants against the square root of the ionic strength are straight. 3. Our data have been interpreted in terms of the Brönsted theory, which relates chemical reaction rates to ionic strength. The data indicate that the apoenzyme reaches its maximum net positive charge at pH 2.0-2.6. The calculated net charge in this pH region is between 11 and 12 and is in agreement with the theoretical value of 12 as deduced from the primary structure of the protein. The isoelectric point of the holoenzyme is about 4. 4. The rate constant of association extrapolated to zero ionic strength is 3.2-10(5)M-1-s-1 and is pH-independent. 5. The rate constant of dissociation and the dissociation constant extrapolated to zero ionic strength depend on the pH. The results are explained by assuming that there are two protein ionizations with a pK value of 3.4; these ionizing groups are possibly close to the FMN binding site.

A photo-CIDNP study of the active sites of Megasphaera elsdenii and Clostridium MP flavodoxins.

Megasphaera elsdenii and Clostridium MP flavodoxins have been investigated by photo-CIDNP techniques. Using time-resolved spectroscopy and external dyes carrying different charges it was possible to assign unambiguously the resonance lines in the NMR-spectra to tyrosine, tryptophan and methionine residues in the two proteins. The results show that Trp-91 in M.elsdenii and Trp-90 in Cl.MP flavodoxin are strongly immobilized and placed directly above the benzene subnucleus of the prosthetic group. The data further indicate that the active sites of the two flavodoxins are extremely similar.

The effects of pH and semiquinone formation on the oxidation-reduction potentials of flavin mononucleotide. A reappraisal.

Calculation shows that there is poor agreement between frequently cited values for the midpoint redox potentials of the two one-electron steps in the reduction of flavin mononucleotide and equations for the lines that relate these potentials to pH and that use the published pKa values for the three redox states of the flavin [Draper, R. & Ingraham, L.L. (1969) Arch. Biochem. Biophys. 125, 802-808]. Equilibrium data for the first step in the reduction obtained by pulse radiolysis [Anderson, R.F. (1983) Biochim. Biophys. Acta 722, 158-162] show much closer agreement with theory and lead to values for the semiquinone formation constant of flavin mononucleotide that are close to those derived from measurements of the radical concentration using ESR spectroscopy. It is concluded that the data from the second method are more reliable. The redox potentials for flavin mononucleotide at pH 7.0 and 20 degrees C are calculated to be -0.207 V for the overall two-electron reduction (Em), -0.313 V for reduction of the oxidized flavin to the semiquinone (E2) and -0.101 V for the reduction of the semiquinone to the hydroquinone (E1). Information is provided to allow calculation of the three redox potentials at other pH values in the physiological range.

The redox potential of dithionite and SO-2 from equilibrium reactions with flavodoxins, methyl viologen and hydrogen plus hydrogenase.

1. It has been shown that redox equilibria can be formed between dithionite ion (plus SO-2) and (bi)sulphite, and the low-potential electron carriers flavodoxin and methyl viologen. The equilibria were established either by treating the oxidized electron carriers with dithionite, or by treating flavodoxin hydroquinone or methyl viologen semiquinone with (bi)sulphite. Similar redox equilibria were established between dithionite/(bi)sulphite and hydrogen using catalytic amounts of hydrogenase in the presence of a low-potential electron carrier. The effects of pH and temperature on the equilibria were determined. 2. The equilibria were analyzed to determine the redox potential of the dithionite/(bi)sulphite system. In accordance with the results of earlier kinetic studies, it was assumed that the reductant in dithionite solutions is the dissociation product SO-2. The calculated midpoint redox potential E' for the couple SO-2/HSO-3 at pH 7 and 25 degrees C was -0.66 V. The reductant is present largely as the dimer at concentrations of dithionite above about 10nM. Consequently, the midpoint potential, Em, of dithionite solutions becomes less negative as the concentration of dithionite is increased (deltaEm/deltalog S2O2-4 = 29 mV). The theoretical potential of a solution of 1 M S2O2-4 and 2 M (bi)sulphite at pH 7 was calculated to be -0.386V. This value is 59 mV more negative than that determined in 1911 by potentiometry, but considerably more positive than other values in the literature. The effects of pH on the equilibria showed that E' is controlled by the pK of (bi)sulphite at 6.9; the slope deltaE'/deltapH was -59 mV below the pK and -118 mV above the pK. The effects of temperature on the equilibria suggested that Em for dithionite changed by -1.6 mV/degrees C for a rise in temperature between 2 degrees C and 40 degrees C. If sodium dithionite is contaminated with small amounts of (bi)sulphite, its addition in large excess to a low potential electron carrier can cause oxidation of the carrier.

Properties of immobilized flavodoxin from Peptostreptococcus elsdenii. An affinity ligand for the purification of riboflavin 5'-phosphate (FMN) and its analogues.

The small flavoprotein, flavodoxin, isolated from Peptostreptococcus elsdenii, has been covalently coupled to CNBr-activated Sepharose 4B. The immobilized protein replaces ferredoxin as an electron carrier in hydrogen production from dithionite or pyruvate in the presence of ferredoxin-free extracts of P. elsdenii; compared with soluble flavodoxin, its activities in these systems are 13% and 3.5% respectively. Acid treatment reversibly dissociates FMN from the immobilized protein. The dissociation constant of the complex with FMN, determined by fluorimetric titration, is 1.5 (+/- 0.4) nM, and is therefore very little different from that of soluble flavodoxin. Like soluble apoflavodoxin, the immobilized apoprotein is highly specific for flavins with an N-10 side-chain of 5 carbon atoms and a C-5' phosphate group. Approximately half of the flavin impurity in commercial preparations of FMN (12-15% of the total flavin), and similar impurity in synthetic analogues of FMN, is not separated by conventional purification procedures, but it is readily and conveniently removed by affinity chromatography with apoflavodoxin as the immobilized ligand. The immobilized protein is stable for long periods; its capacity for FMN decreases by only 20% after 15 cycles of flavin dissociation and reassociation during several months.

Identification and properties of 8-hydroxyflavin--adenine dinucleotide in electron-transferring flavoprotein from Peptostreptococcus elsdenii.

1. A new flavin prosthetic group has been isolated in pure form from the electron-transferring flavoprotein of Peptostreptococcus elsdenni. Its structure has been established as the FAD derivative of 7-methyl-8-hydroxyisoalloxazine: (see article). Proof of this structure has been obtained by chemical syntehsis of 7-methyl-8-hydroxyisoalloxazine models, and by stepwise degradation of the native compound to 7-methy-8-hydroxyalloxazine. The orange chromophore is characterized by a strong absorption band with a maximum at 472 nm (xi = 41 000 M-1 CM-1) and a pK at 4.8 due to the ionisation of the C(8)-OH group. 2. The properties of a series of functionally substituted derivatives of 8-hydroxy flavins and lumichromes have been investigated to provide a basis for interpreting the effects of pH on the spectroscopic properties of the 8-hydroxy derivatives of FAD and FMN. 3. The 8-hydroxy derivative of FAD is bound by apo-D-amino acid oxidase; the complex shows no catalytic activity. The 8-hydroxy derivative of FMN is bound by apoflavodoxin to give a complex which has catalytic activity similar to that of native flavodoxin. The complex is reversibly reduced by dithionite, first to a relatively stable semiquinone and further to the dihydroflavin form.

Cloning, overexpression, and characterization of peroxiredoxin and NADH peroxiredoxin reductase from Thermus aquaticus.

The genes for peroxiredoxin (Prx) and NADH:peroxiredoxin oxidoreductase (PrxR) have been cloned from the thermophilic bacterium Thermus aquaticus. prx is located upstream from prxR, the two genes being separated by 13 bases. The amino acid sequences show that Prx is related to two-cysteine peroxiredoxins from a range of organisms and that PrxR resembles NADH-dependent flavoenzymes that catalyze the reduction of peroxiredoxins in mesophilic bacteria. The sequence of PrxR also resembles those of thioredoxin reductases (TrxR) from thermophiles but with an N-terminal extension of about 200 residues. PrxR has motifs for two redox-active disulfides, one in the FAD-binding site, as occurs in TrxR, and the other in the N-terminal extension. The molecular masses of the monomers of Prx and PrxR are 21.0 and 54.9 kDa, respectively; both enzymes exist as multimers. The recombinant flavoenzyme requires 3 mol equivalents of dithionite for full reduction, as is consistent with 1 FAD and 2 disulfides per monomer. PrxR and Prx together catalyze the anaerobic reduction of hydrogen peroxide. The activity of Prx is much less than has been observed with homologous proteins. Prx appears to be inactivated by cumene hydroperoxide. PrxR itself has low peroxidase activity.

The hydrogen-tritium exchange activity of Megasphaera elsdenii hydrogenase.

The hydrogenase of Megasphaera elsdenii was purified to a specific activity of 350 units/mg. The hydrogen-tritium exchange assay of Hallahan et al. [Hallahan, D.L., Fernandez, V. M., Hatchikian, E. C. and Hall, D. O. (1986) Biochimie (Paris) 68, 49-54] was adapted to allow its use in the study of the M. elsdenii hydrogenase preparation. Under the assay conditions routinely employed, the enzyme's exchange activity was inhibited by Tris/HCl and MgCl2; it was stimulated by ethylene glycol. Maximal activity in this standard assay occurred at pH 7.1. The effect of the concentration of molecular hydrogen (1H2 plus 3H1H) on the exchange activity was studied. The resulting double-reciprocal plot was linear; its slope and its intercepts on the ordinate and abscissa were pH-dependent. The rate equations for a number of models of the exchange activity were derived. Each model gave rise to a linear double-reciprocal plot at constant pH, but none could explain fully the observed effects of varying pH. The experimental data corresponded most closely to the predictions of models in which protons were treated both as substrates and as regulators of the enzyme's activity.