Multi-frequency high-field EPR studies on metal-substituted xylose isomerase.

The bacterial enzyme D-xylose isomerase (XI) catalyses the conversion of D-xylose to D-xylulose. Each subunit of the homotetrameric protein contains a bimetallic active centre requiring divalent metal ions such as Mg2+, Mn2+ or Co2+ for catalytic activity. We report here on XI in which the metal binding site 1 is specifically loaded with EPR active Mn2+, while binding site 2 is occupied by Co2+ or Cd2+, rendering a catalytically active or inactive species respectively. The Q-band (34 GHz) EPR spectra of these mixed-metal samples (Co2+/Mn2+ and Cd2+/Mn2+ XI) show a clear influence of the metal in site 2 on the Mn2+ EPR parameters. Likewise, a systematic increase of the zero field splitting parameters (zfs) of Mn2+ in site 1 upon incubation with the inhibitor xylitol or substrates for both mixed-metal samples is found. For Co2+/Mn2+ XI complexed with substrate, a drastic line broadening of the central -1/2 <--> +1/2 transition is observed in Q-band EPR, which was not amenable to analysis so far. By means of a multi-frequency approach at frequencies beyond Q-band, the relevant zfs parameters were derived from spectral simulations of EPR spectra measured at 94, 285 and 670 GHz. It is shown that parallel to the increase of the D-value its distribution also grows considerably in going from free Co2+/Mn2+ XI to the species complexed with inhibitor or substrate. For XI with bound substrate, D-values in the range of 70-90 mT and a distribution of about 30 mT were found from simulation trials. The large distribution in zfs values is thought to be correlated to the structural disorder induced by the shift of the metal ion of site 2 into a location necessary for the isomerisation reaction. The results are discussed with respect to high-resolution crystal data.

Xanthine dehydrogenase from Pseudomonas putida 86: specificity, oxidation-reduction potentials of its redox-active centers, and first EPR characterization.

Xanthine dehydrogenase (XDH) from Pseudomonas putida 86, which was induced 65-fold by growth on hypoxanthine, was purified to homogeneity. It catalyzes the oxidation of hypoxanthine, xanthine, purine, and some aromatic aldehydes, using NAD+ as the preferred electron acceptor. In the hypoxanthine:NAD+ assay, the specific activity of purified XDH was 26.7 U (mg protein)(-1). Its activity with ferricyanide and dioxygen was 58% and 4%, respectively, relative to the activity observed with NAD+. XDH from P. putida 86 consists of 91.0 kDa and 46.2 kDa subunits presumably forming an alpha4beta4 structure and contains the same set of redox-active centers as eukaryotic XDHs. After reduction of the enzyme with xanthine, electron paramagnetic resonance (EPR) signals of the neutral FAD semiquinone radical and the Mo(V) rapid signal were observed at 77 K. Resonances from FeSI and FeSII were detected at 15 K. Whereas the observable g factors for FeSII resemble those of other molybdenum hydroxylases, the FeSI center in contrast to most other known FeSI centers has nearly axial symmetry. The EPR features of the redox-active centers of P. putida XDH are very similar to those of eukaryotic XDHs/xanthine oxidases, suggesting that the environment of each center and their functionality are analogous in these enzymes. The midpoint potentials determined for the molybdenum, FeSI and FAD redox couples are close to each other and resemble those of the corresponding centers in eukaryotic XDHs.

Probing magnetic properties of the reduced [2Fe-2S] cluster of the ferredoxin from Arthrospira platensis by 1H ENDOR spectroscopy.

The 1H electron nuclear double resonance (ENDOR) spectra in frozen solutions of the reduced [2Fe-2S] cluster in ferredoxin from Arthrospira (Spirulina) platensis have been measured at low temperatures (5-20 K) and simulated using orientational selection methods. The analysis confirmed the existence of a single paramagnetic species with iron valence states II and III connected uniquely to the cluster irons. The experimental ENDOR spectra were fitted to a model including the spin distribution on the centre, the orientation of the g-matrix, and the isotropic and anisotropic hyperfine couplings of the nearest protons in the crystallographically determined structure. In order to partially simulate ENDOR line shapes, a statistical distribution of the corresponding torsion angles between the Fe(III) centre and one of the beta-CH2 protons was introduced. From the analysis, four of the larger hyperfine couplings found were assigned to the cysteine beta-protons near the Fe(III) ion of the cluster, with isotropic hyperfine couplings ranging from 1.6 to 4.1 MHz. The spin distribution on the two iron ions was estimated to be +1.85 for the Fe(III) ion and -0.9 for the Fe(II) ion. The Fe(III) ion was identified as being coordinated to the cysteine ligands Cys49 and Cys79, confirming previous NMR results. The direction of the g-tensor with respect to the cluster was deduced. The g1-g2 plane is parallel to the planes through each iron and its adjacent cysteine sulfurs; the g2-g3 plane is nearly perpendicular to the latter planes and deviates by 25 degrees from the FeSSFe plane. The g1 direction is dominated by the bonding geometry of Fe(II) and does not align with the Fe(II)-Fe(III) vector.

Kinetics and interactions of molybdenum and iron-sulfur centers in bacterial enzymes of the xanthine oxidase family: mechanistic implications.

For isoquinoline 1-oxidoreductase (IsoOr), the reaction mechanism under turnover conditions was studied by EPR spectroscopy using rapid-freeze methods. IsoOr displays several EPR-active Mo(V) species including the "very rapid" component found also in xanthine oxidase (XanOx). For IsoOr, unlike XanOx or quinoline 2-oxidoreductase (QuinOr), this species is stable for about 1 h in the absence of an oxidizing substrate [Canne, C., Stephan, I., Finsterbusch, J., Lingens, F., Kappl, R., Fetzner, S., and Hüttermann, J. (1997) Biochemistry 36, 9780-9790]. Under rapid-freeze conditions in the presence of ferricyanide the very rapid species behaves as a kinetically competent intermediate present only during steady-state turnover. To explain the persistence of the very rapid species in IsoOr in the absence of an added oxidant, extremely slow product dissociation is required. This new finding that oxidative conditions facilitate decay of the very rapid signal for IsoOr supports the mechanism of substrate turnover proposed by Lowe, Richards, and Bray [Lowe, D. J., Richards, R. L., and Bray, R. C. (1997) Biochem. Soc. Trans. 25, 774-778]. Additional stopped-flow data reveal that alternative catalytic cycles occur in IsoOr and show that the product dissociates after transfer of a single oxidizing equivalent from ferricyanide. In rapid-freeze measurements magnetic interactions of the very rapid Mo(V) species and the iron-sulfur center FeSI of IsoOr and QuinOr were observed, proving that FeSI is located close to the molybdopterin cofactor in the two proteins. This finding is used to relate the two different iron-sulfur centers of the aldehyde oxidoreductase structure with the EPR-detectable FeS species of the enzymes.

Flavonol 2,4-dioxygenase from Aspergillus niger DSM 821, a type 2 CuII-containing glycoprotein.

Flavonol 2,4-dioxygenase, which catalyzes the cleavage of quercetin to carbon monoxide and 2-protocatechuoyl-phloroglucinol carboxylic acid, was purified from culture filtrate of Aspergillus niger DSM 821 grown on rutin. It is a glycoprotein (46-54% carbohydrate) with N-linked oligo-mannose type glycan chains. The enzyme was resolved in SDS polyacrylamide gels in a diffuse protein band that corresponded to a molecular mass of 130-170 kDa. When purified flavonol 2,4-dioxygenase was heated, it dissociated into three peptides with apparent molecular masses of 63-67 kDa (L), 53-57 kDa (M), and 31-35 kDa (S), which occurred in a molar ratio of 1:1:1, suggesting a LMS structure. Crosslinking led to a 90-97 kDa species, concomitant with the decrease of staining intensity of the 63-67 kDa (L) and the 31-35 kDa (S) peptides. Analysis by matrix-assisted laser desorption/ionization-time of flight-MS showed peaks at m/z approximately 69 600, m/z approximately 51 700, and m/z approximately 26 500 which are presumed to represent the three peptides of flavonol 2,4-dioxygenase, and a broad peak at m/z approximately 96 300, which might correspond to the LS heterodimer as formed in the crosslinking reaction. Based on the estimated molecular mass of 148 kDa, 1 mol of enzyme contained 1.0-1.6 mol of copper. Ethylxanthate, which specifically reduces CuII to CuI ethylxanthate, is a potent inhibitor of flavonol 2,4-dioxygenase. Metal chelating agents (such as diethyldithiocarbamate, diphenylthiocarbazone) strongly inhibited the enzymatic activity, but inactivation was not accompanied by loss of copper. The EPR spectrum of flavonol 2,4-dioxygenase (as isolated) showed the characteristic parameters of a nonblue type 2 CuII protein. The Cu2+ is assumed to interact with four nitrogen ligands, and the CuII complex has a (distorted) square planar geometry.

The active site of purple acid phosphatase from sweet potatoes (Ipomoea batatas) metal content and spectroscopic characterization.

Purple acid phosphatase from sweet potatoes Ipomoea batatas (spPAP) has been purified to homogeneity and characterized using spectroscopic investigations. Matrix-assisted laser desorption/ionization mass spectrometry analysis revealed a molecular mass of approximately 112 kDa. The metal content was determined by X-ray fluorescence using synchrotron radiation. In contrast to previous studies it is shown that spPAP contains a Fe(III)-Zn(II) center in the active site as previously determined for the purple acid phosphatase from red kidney bean (kbPAP). Moreover, an alignment of the amino acid sequences suggests that the residues involved in metal-binding are identical in both plant PAPs. Tyrosine functions as one of the ligands for the chromophoric Fe(III). Low temperature EPR spectra of spPAP show a signal near g = 4.3, characteristic for high-spin Fe(III) in a rhombic environment. The Tyr-Fe(III) charge transfer transition and the EPR signal are both very sensitive to changes in pH. The pH dependency strongly suggests the presence of an ionizable group with a pKa of 4.7, arising from an aquo ligand coordinated to Fe(III). EPR and UV/visible studies of spPAP in the presence of the inhibitors phosphate or arsenate suggest that both anions bind to Fe(III) in the binuclear center replacing the coordinated water or hydroxide ligand necessary for hydrolysis. The conserved histidine residues of spPAP corresponding to His202 and His296 in kbPAP probably interact in catalysis.

A divalent metal site in the small subunit of the manganese-dependent ribonucleotide reductase of Corynebacterium ammoniagenes.

Based on its metallo-cofactor, the manganese-dependent ribonucleotide reductase (Mn-RRase) responsible for delivery of DNA precursors in the Mn-requiring Gram-positive bacterium Corynebacterium (formerly Brevibacterium) ammoniagenes ATCC 6872 is no longer considered as a simple analogue of the aerobic Fe-RRase of Escherichia coli but as the prototype of the class IV enzymes (1). Deliberate dissociation of the Mn-RRase holoenzyme and an improved sample preparation of the dimeric CA2 protein allowed further characterization of the inherent metallo-cofactor by Q-band electron paramagnetic resonance (EPR) spectroscopy. At 40 K, a distinct hyperfine sextet (I = 5/2,55Mn) pattern with a weak zero-field splitting was detected in the CA2 protein prepared from manganese-sufficient cells displaying high RRase activity as expected. This Q-band Mn(II) signal was absent in the apo-CA2 protein obtained from manganese-depleted cells devoid of this enzymatic activity. The presence of a mixed valence manganese cluster in the C. ammoniagenes RRase is excluded since no complex multiline EPR signals were detected in the CA2 protein even at very low (8 K) temperature. The observed Mn(II) spectrum indicates a protein-bound manganese which was modified in the presence of 5.7 mM p-methoxyphenol, but is insensitive toward 10 mM EDTA. Thus, the manganese appeared to be either strictly bound or buried within a hydrophobic pocket of the CA2 protein, inaccessible for EDTA.

Reconstitution and characterization of the polynuclear iron-sulfur cluster in pyruvate formate-lyase-activating enzyme. Molecular properties of the holoenzyme form.

The glycyl radical (Gly-734) contained in the active form of pyruvate formate-lyase (PFL) of Escherichia coli is generated by the S-adenosylmethionine-dependent pyruvate formate-lyase-activating enzyme (PFL activase). A 5'-deoxyadenosyl radical intermediate produced by the activase has been suggested as the species that abstracts the pro-S hydrogen of the glycine 734 residue in PFL (Frey, M., Rothe, M., Wagner, A. F. V., and Knappe, J. (1994) J. Biol. Chem. 269, 12432-12437). To enable mechanistic investigations of this system we have worked out a convenient large scale preparation of functionally competent PFL activase from its apoform. The previously inferred metallic cofactor was identified as redox-interconvertible polynuclear iron-sulfur cluster, most probably of the [4Fe-4S] type, according to UV-visible and EPR spectroscopic information. Cys --> Ser replacements by site-directed mutagenesis determined Cys-29, Cys-33, and Cys-36 to be essential to yield active holoenzyme. Gel filtration chromatography showed a monomeric structure (28 kDa) for both the apoenzyme and holoenzyme form. The iron-sulfur cluster complement proved to be a prerequisite for effective binding of adenosylmethionine, which induces a characteristic shift of the EPR signal shape of the reduced enzyme form ([4Fe-4S]+) from axial to rhombic symmetry.

Comparative EPR and redox studies of three prokaryotic enzymes of the xanthine oxidase family: quinoline 2-oxidoreductase, quinaldine 4-oxidase, and isoquinoline 1-oxidoreductase.

For three prokaryotic enzymes of the xanthine oxidase family, namely quinoline 2-oxidoreductase, quinaldine 4-oxidase, and isoquinoline 1-oxidoreductase, the electron transfer centers were investigated by electron paramagnetic resonance. The enzymes are containing a molybdenum-molybdopterin cytosine dinucleotide cofactor, two distinct [2Fe-2S] clusters and, apart from isoquinoline 1-oxidoreductase, a flavin adenine dinucleotide. The latter cofactor yields two different organic radical signals in quinoline 2-oxidoreductase and quinaldine 4-oxidase, typical for the neutral and anionic form, respectively. A "rapid" Mo(V) species is present in all enzymes with small differences in magnetic parameters. From spectra simulation of 95Mo-substituted quinoline 2-oxidoreductase, a deviation of 25 degrees between the maximal g and 95Mo-hyperfine tensor component was derived. The very rapid Mo(V) species was detected in small amounts upon reduction with substrates in quinoline 2-oxidoreductase and quinaldine 4-oxidase, but showed a different kinetic behavior with considerable EPR intensities in isoquinoline 1-oxidoreductase. The FeSI and FeSII centers produced different signals in all three enzymes and, in case of isoquinoline 1-oxidoreductase, revealed a dipolar interaction, from which a maximum distance of 15 A between FeSI and FeSII was estimated. The midpoint potentials of the FeS centers were surprisingly different and determined for FeSI/FeSII with -155/-195 mV in quinoline 2-oxidoreductase, -250/-70 mV in quinaldine 4-oxidase, and +65/+10 mV in isoquinoline 1-oxidoreductase. The slopes of the fitting curves for the Nernst equation are indicative for nonideal behavior. Only in quinoline 2-oxidoreductase, an averaged midpoint potential of the molybdenum redox pairs of about -390 mV could be determined. Both of the other enzymes did not produce Mo(V) signals in redox titration experiments, probably because of direct reduction of Mo(VI) to Mo(IV) in the presence of dithionite.

Electron paramagnetic resonance of D-xylose isomerase: evidence for metal ion movement induced by binding of cyclic substrates and inhibitors.

The interactions of substrates and inhibitors with the Mn2+ ions in the binuclear active center of D-xylose isomerase (XylI) were investigated by EPR spectroscopy at X- and Q-band frequencies. The metal binding site 1 (A site) was specifically occupied with Mn2+ ions by blocking the high-affinity metal binding site 2 (B-site) either with Co2+ ions, resulting in a catalytically active enzyme, or with Cd2+ or Pb2+ ions yielding an inactive enzyme species. Incubation of both the Co2+/Mn2+- and the Cd2+/Mn2+-XylI with the acyclic inhibitor xylitol revealed EPR spectra with well-resolved hyperfine patterns, but with increased zero field splitting (zfs) parameter D compared to the spectra without inhibitor. D was estimated by spectral simulation of the central --1/2<-->1/2 fine structure transition. D values of 33 and 50 mT were obtained for the Co2+/Mn2+-XylI and the Cd2+/Mn2+-XylI samples, respectively. These results indicate direct interaction of the xylitol with the Mn2+ in the A-site. More drastic changes are observed with the substrates D-xylose and D-glucose and with the cyclic inhibitors 5-thio-alpha-D-glucose and 2-desoxy-D-glucose. For Cd2+/Mn2+-XylI, the EPR spectra with substrates and cyclic inhibitors are similar to each other but different from the spectra with the acylic inhibitor xylitol. They exhibit well-resolved line patterns with a relative large zero field splitting, which was estimated to be in the range of D = 65-85 mT in the various complexes. Binding of substrates or of cyclic inhibitors to the Co2+/ Mn2+-XylI yields EPR spectra without resolved hyperfine interactions, indicative of dipolar interaction between the two paramagnetic metal ions. This can be explained with a decrease in the metal-metal distance. Furthermore, the EPR data strongly suggest that the corresponding metal ion movement is induced by binding of the cyclic conformation of either substrates or cyclic inhibitors and not by binding of the extended form of the sugars.

Quinoline oxidoreductase from Pseudomonas putida 86: an improved purification procedure and electron paramagnetic resonance spectroscopy.

Quinoline oxidoreductase, an iron-sulfur molybdenum flavoprotein containing flavin adenine dinucleotide and molybdopterin cytosine dinucleotide, was purified from Pseudomonas putida 86 to homogeneity. The various electron-transfer centers of the purified enzyme were examined by electron paramagnetic resonance spectroscopy. Quinoline deuterated at position 2 was prepared by deuterodecarboxylation of 2-quinolinecarboxylic acid. Quinoline added to the enzyme elicited the Mo(V) "rapid" type Q signal arising from the complex of enzyme and substrate, whereas in oxidized quinoline oxidoreductase a Mo(V) "resting" signal was observed. EPR spectroscopy at helium temperatures below 70 K revealed the existence of two types of iron-sulfur centers, Fe-S I and Fe-S II. An organic free radical appeared upon reduction with sodium dithionite. Inactivation of the enzyme by cyanide led to the inactive desulfo quinoline oxidoreductase, which yielded another Mo(V) signal designated "slow" type Q upon reduction with dithionite. Desulfo quinoline oxidoreductase was partially reactivated by incubation with sulfide.

X- and Q-band EPR studies on the two Mn(2+)-substituted metal-binding sites of D-xylose isomerase.

The two metal-binding sites (A and B)/subunit of the homotetrameric D-xylose isomerase (Xyl isomerase) from Streptomyces rubiginosus have been studied with Mn(2+)-EPR spectroscopy at X-band and Q-band frequencies and with electronic spectroscopy. Displacement studies in the visible absorbance range showed that Mn2+ have a higher affinity for the B site. With the low-affinity A site unoccupied, the coordination sphere of Mn2+ in the B site is quite distorted giving rise to a highly anisotropic X-band EPR spectrum. Simulation of the Q-band spectrum reveals a zero field splitting (zfs) D of about 45-48 mT and a rhombicity parameter E/D between 0.2 and 0.3. Occupation of both binding sites with Mn2+ induces a significant shift towards a higher symmetry in the coordination sphere of the B site resulting in similar zfs parameters for both binding sites. The change in A-site environment caused by B-site occupation was analysed in mixed Xyl isomerase derivatives, in which the B site is loaded with Co2+, Cd2+ or Pb2+ and the A site with Mn2+. In the Co2+/Mn2+ Xyl isomerase the Mn2+ has a relatively symmetric ligand environment with small zfs parameters (D = 12 mT, E/D < 0.15). Substituting Co2+ with Cd2+ or Pb2+ in the B site leads to a drastic increase in the zfs parameters of Mn2+ in the A site. The distortions are directly linked to the ionic radii of the ions bound to the B site and may be mediated by the carboxylate group of Glu216 that bridges the metal-binding sites. The EPR spectra also reflect the catalytic activity of the mixed metal samples. With the larger Cd2+ or Pb2+ in the B site, which are strongly influencing the stereochemistry of the A site, the catalytic activity is lost, whereas Co2+ and Mn2+ render the enzyme in an active state, so that the mutual influence on catalysis depends on the complex geometry of both metal-binding sites.

EPR-spectroscopy of reduced oxyferrous-P450cam.

X-irradiation of the ternary complex of P450:substrate:O2 at 77 K produces a reduced intermediate by electron addition to the Fe:O2 complex which can be studied by EPR-spectroscopy. The EPR spectrum of the new species exhibits rhombic symmetry with g-factors of 2.27, 2.17 and 1.95, respectively. Increasing the temperature of the sample to 190 K results in loss of intensity of the intermediate signals. X-irradiation of oxymyo- and oxyhemoglobin produces similar EPR signals indicating that the added electron is resident on the Fe:O2 compleX (Kappl, R., et al. (1985) Biochim. Biophys. Acta 870, 20-30).

Visible, EPR and electron nuclear double-resonance spectroscopic studies on the two metal-binding sites of oxovanadium (IV)-substituted D-xylose isomerase.

The two metal-binding sites of the D-xylose isomerase from Streptomyces rubiginosus were studied using VO2+ as a sensor for the ligand environment. Titration of the tetrameric enzyme with VO2+, followed by EPR spectroscopy and inhibition studies, show that the first four VO2+ equivalents occupy, in analogy to Co2+, Cd2+ and Pb2+, the binding site B. The visible absorption data and the EPR parameters indicate that a nitrogen ligand is involved in the ligand sphere of the high-affinity B site. The low-affinity A site could be studied selectively by blocking the B site with visible and EPR-silent Cd2+. The visible data and EPR parameters for this site are consistent with a ligand environment composed of oxygen donors without nitrogen ligation. The nitrogen coordination in the high-affinity site could be demonstrated by electron nuclear double-resonance (ENDOR) studies of the 4VO2+ enzyme, and was assigned to a histidine ligand. The 14N resonances are interpreted in terms of a quartet with a coupling value of 13.2 MHz. 1H-ENDOR coupling of 1.7 MHz, exchangeable in D2O, has been assigned to the N-H proton of the histidine. Additional proton ENDOR couplings, which are not exchangeable, are due to protons bound to the carbon atoms of the histidine. For the low-affinity binding site, a nitrogen coordination could be definitely excluded by the ENDOR measurements. Exchangeable 1H-ENDOR couplings observed in this sample were assigned to H2O ligands in the vicinity of VO2+. The results closely relate to what is known from X-ray structure. However, the relative affinities for the two binding sites seem not to be the same for different bivalent cations. In mixed metal samples with four VO2+ and four Co2+ equivalents, the VO2+ is distributed between both binding sites. Small changes in the complex geometry of the A site, indicated by different EPR features, seem to occur if the B site is occupied by Co2+ or by Cd2+.

An ENDOR study of human and bovine erythrocyte superoxide dismutase: 1H and 14N interactions.

Hyperfine interactions (1H and 14N) with the paramagnetic Cu(II)-site obtained from frozen solutions of human and bovine erythrocyte superoxide dismutase (superoxide:superoxide oxidoreductase, EC 1.15.1.1) as well as from their derivatives produced by anion binding (N3-, CN-) and by depletion of the Zn(II) site were studied using electron nuclear double resonance (ENDOR) spectroscopy at about 15 K. Both interactions were found to be identical in human and bovine erythrocyte superoxide dismutase. In all compounds, an anisotropic, exchangeable 1H interaction with a nearly constant coupling value (approximately 3 MHz along g perpendicular ) was observed which is due to either histidine NH- or water protons. Other proton interactions were tentatively assigned to H beta 1 of His-44, H delta 2 of His-46 and to H beta 2 of His-44. Depletion of the Zn(II) site did not alter appreciably the pattern of the proton interactions. The 14N couplings of the native specimen indicated equivalent coordination, whereas Zn(II) depletion and CN- addition were found to produce either some or drastic inequivalences, respectively. For N3- addition to either the native or the Zn(II)-depleted sample only minor effects on the respective 14N coupling pattern were observed.