The preparation of apo-Cu,Zn superoxide dismutase by ion-exchange chromatography on iminodiacetic acid-sepharose

The superoxide dismutases (EC 1.15.1.1) are a family of enzymes that catalyze the dismutation of superoxide radical anion to dioxygen and hydrogen peroxide. The active site contains a critical metal ion such as manganese, iron, or copper. The copper-containing protein also has one zinc ion bound per subunit. The standard method used to remove the metal ions from Cu,Zn superoxide dismutase has been to exhaustively dialyze the protein against chelating agents at low pH. We have developed a new method where the protein is bound to ion-exchange medium based on iminodiacetic acid immobilized on Sepharose. The bound protein is treated with a buffer containing edta at pH 3.5 to remove metal ions; the buffer is then exchanged for acetate buffer to remove edta, after which the protein is eluted by a salt gradient. An advantage of this method is that a single chromatography step is sufficient to produce apo protein. Results are shown for both human and bovine dimeric Cu,Zn superoxide dismutase and the monomeric Escherichia coli Cu,Zn superoxide dismutase. In every case, the metals were removed efficiently.

Divalent metal derivatives of the hamster dihydroorotase domain

Dihydroorotase (DHOase, EC 3.5.2.3) is a zinc enzyme that catalyzes the reversible cyclization of N-carbamyl-L-aspartate to L-dihydroorotate in the third reaction of the de novo pathway for biosynthesis of pyrimidine nucleotides. The recombinant hamster DHOase domain from the trifunctional protein, CAD, was overexpressed in Escherichia coli and purified. The DHOase domain contained one bound zinc atom at the active site which was removed by dialysis against the chelator, pyridine-2,6-dicarboxylate, at pH 6.0. The apoenzyme was reconstituted with different divalent cations at pH 7.4. Co(II)-, Zn(II)-, Mn(II)-, and Cd(II)-substituted DHOases had enzymic activity, but replacement with Ni(2+), Cu(2+), Mg(2+), or Ca(2+) ions did not restore activity. Atomic absorption spectroscopy showed binding of one Co(II), Zn(II), Mn(II), Cd(II), Ni(II), or Cu(II) to the enzyme, while Mg(II) and Ca(II) were not bound. The maximal enzymic activities of the active, reconstituted DHOases were in the following order: Co(II) --> Zn(II) --> Mn(II) --> Cd(II). These metal substitutions had major effects upon values for V(max); effects upon the corresponding K(m) values were less pronounced. The pK(a) values of the Co(II)-, Mn(II)-, and Cd(II)-substituted enzymes derived from pH-rate profiles are similar to that of Zn(II)-DHOase, indicating that the derived pK(a) value of 6.56 obtained for Zn-DHOase is not due to ionization of an enzyme-metal aquo complex, but probably a histidine residue at the active site. The visible spectrum of Co(II)-substituted DHOase exhibits maxima at 520 and 570 nm with molar extinction coefficients of 195 and 210 M(-1) cm(-1), consistent with pentacoordination of Co(II) at the active site. The spectra at high and low pH are different, suggesting that the environment of the metal binding site is different at these pHs where the reverse and forward reactions, respectively, are favored.

Characterization of point mutations in patients with pyruvate dehydrogenase deficiency: role of methionine-181, proline-188, and arginine-349 in the alpha subunit

Human pyruvate dehydrogenase (E1), a heterotetramer (alpha2beta2), is the first component of the pyruvate dehydrogenase complex (PDC). E1 catalyzes the thiamin pyrophosphate (TPP)-dependent decarboxylation of pyruvate and the reductive acetylation of the dihydrolipoamide acetyltransferase component. Site-directed mutagenesis was employed to recreate three point mutations in the alpha subunit identified in E1-deficient patients, M181V, R349H, and P188L (P188A mutant E1 was used because of the very low level of expression of P188L), to investigate the functional roles of these three amino acid residues. P188A mutant E1 was much less thermostable than the wild-type E1. The kcats of M181V and P188A mutant E1s determined in the PDC reaction were 38 and 24% of that of the wild-type enzyme, respectively. The apparent Km for TPP for M181V increased significantly (approx 250-fold when determined in the PDC assay), while the apparent Km for pyruvate increased by only about 3-fold. In contrast, P188A had similar Kms for the coenzyme and the substrate as the wild-type. Km values for R349H were not determined due to the extremely low activity of this mutant (1.2% of the wild-type E1-specific activity measured in the PDC assay). Wild-type E1 displayed a lag phase in the progress curve of the PDC reaction measured in the presence of low TPP concentrations (below 1 microM) only. All mutants had a lag phase that was not eliminated even at very high TPP concentrations, suggesting modifications in the conformation of the active site. Kinetic analysis indicated thiamin 2-thiothiazolone pyrophosphate (ThTTPP) to be an intermediate analog for wild-type human E1. M181V required a higher concentration of ThTTPP for inactivation than the wild-type and P188A E1s. The results of circular dichroism spectropolarimetry in the far UV region indicated that there were no major changes in the secondary structure of M181V, P188A, and R349H E1s. These mutant enzymes exhibited negative dichroic spectra at about 330 nm only in the presence of high TPP concentrations. This study suggests that arginine-349 is critical for E1's activity, methionine-181 is involved in the binding of TPP, and proline-188 is necessary for structural integrity of E1.

Characterization of the membrane quinoprotein glucose dehydrogenase from Escherichia coli and characterization of a site-directed mutant in which histidine-262 has been changed to tyrosine

The requirements for substrate binding in the quinoprotein glucose dehydrogenase (GDH) in the membranes of Escherichia coli are described, together with the changes in activity in a site-directed mutant in which His262 has been altered to a tyrosine residue (H262Y-GDH). The differences in catalytic efficiency between substrates are mainly related to differences in their affinity for the enzyme. Remarkably, it appears that, if a hexose is able to bind in the active site, then it is also oxidized, whereas some pentoses are able to bind (and act as competitive inhibitors), but are not substrates. The activation energies for the oxidation of hexoses and pentoses are almost identical. In a previously published model of the enzyme, His262 is at the entrance to the active site and appears to be important in holding the prosthetic group pyrroloquinoline quinone (PQQ) in place, and it has been suggested that it might play a role in electron transfer from the reduced PQQ to the ubiquinone in the membrane. The H262Y-GDH has a greatly diminished catalytic efficiency for all substrates, which is mainly due to a marked decrease in their affinities for the enzyme, but the rate of electron transfer to oxygen is unaffected. During the processing of the PQQ into the apoenzyme to give active enzyme, its affinity is markedly dependent on the pH, four groups with pK values between pH7 and pH8 being involved. Identical results were obtained with H262Y-GDH, showing that His262 it is not directly involved in this process.

Structural characterization of l-aspartate oxidase and identification of an interdomain loop by limited proteolysis

l-Aspartate oxidase is the first enzyme in the de novo biosynthesis of pyridinic coenzymes in facultative aerobic organisms. The enzyme is FAD dependent and it shares common features with both the oxidase and the fumarate reductase classes of flavoproteins. In this report we focused our attention on the supersecondary structure of the molecule by means of limited proteolysis studies. Moreover the polymerization state of the protein at different pH and the interactions with NAD and its analogues are described. The results suggest that l-aspartate oxidase is a monomer at pH values lower than 4.5 and a dimer at pH values higher than 6.5. The protein is organized in two major domains connected by a flexible loop located in the 120-140 region. The data obtained by limited proteolysis of the holo and the apo form in the presence and in the absence of substrates (fumarate and menadione), inhibitors (succinate) and NAD allows the proposition that both domains are involved in the binding of the flavin coenzyme. Moreover the data reported in this manuscript suggest that NAD inhibits l-aspartate oxidase activity by competing with the flavin for the binding to the enzyme.

Active monomeric and dimeric forms of Pseudomonas putida glyoxalase I: evidence for 3D domain swapping

3D domain swapping of proteins involves the interconversion of a monomer containing a single domain-domain interface and a 2-fold symmetrical dimer containing two equivalent intermolecular interfaces. Human glyoxalase I has the structure of a domain-swapped dimer [Cameron, A. D., Olin, B., Ridderström, M., Mannervik, B., and Jones, T. A. (1997) EMBO J. 16, 3386-3395] but Pseudomonas putida glyoxalase I has been reported to be monomeric [Rhee, H.-I., Murata, K., and Kimura, A. (1986) Biochem. Biophys. Res. Commun. 141, 993-999]. We show here that recombinant P. putida glyoxalase I is an active dimer (kcat approximately 500 +/- 100 s-1; KM approximately 0.4 +/- 0.2 mM) with two zinc ions per dimer. The zinc is required for structure and function. However, treatment of the dimer with glutathione yields an active monomer (kcat approximately 115 +/- 40 s-1; KM approximately 1.4 +/- 0.4 mM) containing a single zinc ion. The monomer is metastable and slowly reverts to the active dimer in the absence of glutathione. Thus, glyoxalase I appears to be a novel example of a single protein able to exist in two alternative domain-swapped forms. It is unique among domain-swapped proteins in that the active site and an essential metal binding site are apparently disassembled and reassembled by the process of domain swapping. Furthermore, it is the only example to date in which 3D domain swapping can be regulated by a small organic ligand.

Evidence for an induced-fit mechanism operating in pi class glutathione transferases

Three-dimensional structures of the apo form of human pi class glutathione transferase have been determined by X-ray crystallography. The structures suggest the enzyme recognizes its substrate, glutathione, by an induced-fit mechanism. Compared to complexed forms of the enzyme, the environment around the catalytic residue, Tyr 7, remains unchanged in the apoenzyme. This observation supports the view that Tyr 7 does not act as a general base in the reaction mechanism. The observed cooperativity of the dimeric enzyme may be due to the movements of a helix that forms one wall of the active site and, in particular, to movements of a tyrosine residue that is located in the subunit interface.

Reconstitution of membrane-integrated quinoprotein glucose dehydrogenase apoenzyme with PQQ and the holoenzyme's mechanism of action

Membrane-integrated quinoprotein glucose dehydrogenase from Acinetobacter calcoaceticus was produced by heterologous expression of the gene for it in an Escherichia coli recombinant strain. The apoenzyme (lacking the cofactor pyrroloquinoline quinone, PQQ) was solubilized with Triton X-100 and purified to homogeneity. Reconstitution of the apoenzyme to full activity in the assay was achieved with a stoichiometric amount of PQQ in the presence of Mg2+. Just as for other PQQ-containing dehydrogenases where Ca2+ fulfills this role, Mg2+ anchors PQQ to the mGDH protein and activates the bound cofactor. This occurs in a precise way since high anomer specificity was found for the enzyme toward the sugars tested. Although the steady-state-type kinetics were as expected for a dye-linked dehydrogenase (ping-pong) and the PQQ in it was present in oxidized form, addition of glucose to the holoenzyme resulted in a very slow but continuous production of gluconolactone; i.e., the reaction did not stop after one turnover, with O2 apparently acting as an (albeit poor) electron acceptor by reoxidizing PQQH2 in the enzyme. The surprisingly low reactivity with glucose, in the absence of dye, as compared to the activity observed in the steady-state assay appeared to be due to formation of an anomalous enzyme form, mGDH. Formation of normal holoenzyme, mGDH, reducing added glucose immediately to gluconolactone (in one turnover), was achieved by treating mGDH with sulfite, by reconstituting apoenzyme with PQQ in the presence of sulfite, or by applying assay conditions to mGDH (addition of PMS/DCPIP). As compared to other quinoprotein dehydrogenases, mGDH appears to be unique with respect to the mode of PQQ-binding, as expressed by the special conditions for reconstitution and the absorption spectra of the bound cofactor, and the reactivity of the reduced enzyme toward O2. The primary cause for this seems not to be related to a different preference for the activating bivalent metal ion but to the special way of binding of PQQ to mGDH.

Reconstitution of the holoenzyme form of Escherichia coli porphobilinogen deaminase from apoenzyme with porphobilinogen and preuroporphyrinogen: a study using circular dichroism spectroscopy

Porphobilinogen deaminase (PBG-D), an early enzyme of the tetrapyrrole biosynthetic pathway, catalyzes the formation of a tetrapyrrole chain, preuroporphyrinogen, from four molecules of porphobilinogen (PBG). The PBG-D apoenzyme is responsible for the autocatalytic synthesis and covalent attachment of a dipyrromethane cofactor at its active site. In this paper an efficient method for the purification of Escherichia coli PBG-D apoenzyme using an affinity chromatography resin is reported. Circular dichroism (CD) spectra of apoenzyme and holoenzyme were recorded and significant differences in both the backbone and aromatic region of the spectra were observed. The differences in the spectra allowed the reconstitution of holoenzyme from purified apoenzyme with PBG and preuroporphyrinogen in solution to be monitored separately by CD. Apoenzyme incubated with preuroporhyrinogen gave a CD spectrum that was much more like the CD spectrum of holoenzyme than apoenzyme incubated with PBG. The results showed clearly that the cofactor was generated much more rapidly from preuroporphyrinogen than from PBG. Changes in the CD spectrum associated with the aromatic side-chain region, in particular the contribution assigned to phenylalanine-62, were found to correlate well with the activity of the reconstituted enzyme. Phenylalanine-62 is located in close proximity to the cofactor and acts as a sensitive probe to active-site changes. The stability of the holoenzyme and apoenzyme were compared with respect to both heat and susceptibility to proteolysis. The results were consistent with a model for the apoenzyme in which, in the absence of the cofactor, the three domains of the protein are held less rigidly together, thereby making the protein more susceptible to heat denaturation and proteolysis. The CD spectrum of the holoenzyme was found to be similar at both pH 5.1 and 7.4, suggesting that the crystal structure, determined at pH 5.1, is likely to be similar at physiological pH values.

The N-glycosylation sites of soybean seed coat peroxidase

Tryptic digestion of apo-soybean peroxidase (apo-SBP), with and without acetamidation, chromatographic separation of the tryptic fragments and MALDI-TOF analysis of the major components, both before and after digestion with glycopeptidase A, demonstrated the presence of six carbohydrate groups on five peptides. Five of the glycopeptides can be mapped with confidence to the peptides containing Asn16, Asn90, Asn104, Asn169, and Asn174. The sixth N-glycosylation site is not known and does not appear to be Asn145. It may be present on the N-terminus of SBP, which has not been sequenced.

Construction of a catalytically active iron superoxide dismutase by rational protein design

The rational protein design algorithm DEZYMER was used to introduce the active site of nonheme iron superoxide dismutase (SOD) into the hydrophobic interior of the host protein, Escherichia coli thioredoxin (Trx), a protein that does not naturally contain a transition metal-binding site. Reconstitution of the designed protein, Trx-SOD, showed the incorporation of one high-affinity metal-binding site. The electronic spectra of the holoprotein and its N3- and F- adducts are analogous to those previously reported for native {Fe3+}SOD. Activity assays showed that {Fe3+}Trx-SOD is capable of catalyzing the dismutation of the superoxide anion; comparative studies with the unrelated wild-type E. coli iron SOD indicated that {Fe3+}Trx-SOD catalyzes the dismutation reaction at a rate on the order of 10(5) M-1s -1. The ability to design catalytically competent metalloenzymes allows for the systematic investigation of fundamental mechanistic questions concerning catalysis at transition metal centers.

Fosfomycin resistance protein (FosA) is a manganese metalloglutathione transferase related to glyoxalase I and the extradiol dioxygenases

The enzyme conferring resistance to the antibiotic fosfomycin [(1R,2S)-1,2-epoxypropylphosphonic acid] originally reported by Suarez and co-workers [Area, P., Hardisson, C., & Suarez, J. E. (1990) Antimicrob. Agents Chemother. 34, 844-848] is demonstrated in this study to be a metalloglutathione transferase. The apoenzyme is a dimer of 16 kDa subunits. Electron paramagnetic resonance spectroscopy and water proton nuclear magnetic resonance longitudinal relaxation rates suggest that each subunit contains a mononuclear Mn2+ center that interacts strongly with the substrate fosfomycin (Kd = 17 microM) more weakly with the product (Kd = 1.1 mM) and very weakly or not at all with GSH. Inhomogeneous broadening of the EPR signals of enzyme-bound Mn2+ in the presence of H2(17)O indicates that three of the coordination sites on the metal are occupied by water. Sequence alignments, three-dimensional structures, and mechanistic considerations suggest that FosA is related to at least two other metalloenzymes, glyoxalase I and the Mn2+- or Fe2+-containing extradiol dioxygenases. The mechanistic imperative driving the evolution of this previously unidentified superfamily of metalloenzymes is proposed to be bidentate coordination of a substrate or intermediate to the metal center in the enzyme-catalyzed reactions.

Unique isozymes of superoxide dismutase in Streptomyces griseus

Two unique isozymes of superoxide dismutase (EC 1.15.1.1) were purified to apparent homogeneity from Streptomyces griseus by a purification procedure consisting of ammonium sulfate precipitation and chromatographies on DEAE Sephacel, Sephacryl S-200, and DEAE 5PW. Superoxide dismutase I was composed of four identical subunits of 13.0 kDa. The absorption spectrum of superoxide dismutase I exhibited absorption bands at 276 and 378 nm and a broad shoulder at 530 nm. The g values of electron paramagnetic resonance spectrum of superoxide dismutase I were g1 = 2.304, g2 = 2.248, and g3 = 2.012 and the resonance centered at g3 = 2.012 was split into triplet, indicating nickel-containing superoxide dismutase. Superoxide dismutase I contained 0.89 g-atom of nickel per mole of 13.0-kDa subunit. Superoxide dismutase II was composed of four identical subunits of 22.0 kDa. The absorption spectrum of superoxide dismutase II showed the featureless absorption band in the range of 300-500 nm. The g values of electron paramagnetic resonance spectrum of superoxide dismutase II were gz = 4.762, gx = 4.072, and gy = 3.742, indicating iron-containing superoxide dismutase. Superoxide dismutase II uniquely contains 0.40 g-atom of iron per mole of monomer as well as 0.43 g-atom of zinc per mole of monomer. The immunological cross-reactivity between two isozymes was not found. Nickel-containing superoxide dismutase was widely distributed within the genus Streptomyces; however, iron- and zinc-containing superoxide dismutase was not found in S. albus and S. longisporoflavus, on the basis of the immunological cross-reactivity.

On the holoenzyme reconstitution process in native and truncated Rhodotorula gracilis D-amino acid oxidase

After developing a rapid gel filtration method to prepare pure and stable apoenzyme forms of D-amino acid oxidase from the yeast Rhodotorula gracilis, we carried out comparative kinetic studies on the reconstitution to holoenzyme (with FAD) of the intact (40 kDa) and proteolyzed (38.3 kDa) apoenzyme forms of this oxidase. Changes in catalytic activity and flavin and protein fluorescence revealed that in both cases reconstitution was biphasic. The proteolyzed enzyme was catalytically competent, but unlike the intact form was unable to dimerize following formation of the apoprotein-FAD complex. We present evidence that reconstitution of holoenzyme from apoenzyme plus FAD does not involve dimerization, and that dimerization is not necessary for expression of DAAO activity. We propose that both apoenzyme forms share a common reconstitution mechanism, which includes a step of conformational interconversion of an enzymatically active intermediate to the final holoenzyme.

Glycerol-induced development of catalytically active conformation of Crotalus adamanteus L-amino acid oxidase in vitro

The reconstitutable apoprotein of Crotalus adamanteus L-amino acid oxidase was prepared using hydrophobic interaction chromatography. After reconstitution with flavin adenine dinucleotide, the resulting protein was inactive, with a perturbed conformation of the flavin binding site. Subsequently, a series of cosolvent-dependent compact intermediates was identified. The nearly complete activation of the reconstituted apoprotein and the restoration of its native flavin binding site was achieved in the presence of 50% glycerol. We provide evidence that in addition to a merely stabilizing effect of glycerol on native proteins, glycerol can also have a restorative effect on their compact equilibrium intermediates, and we suggest the hydrophobic effect as a dominating force in this in vitro-assisted restorative process.

Heterologous expression and characterization of soybean cytosolic ascorbate peroxidase

Ascorbate peroxidase is a widespread plant enzyme that catalyzes the removal of potentially harmful H2O2. This enzyme is particularly important in legume root nodules due to their high potential for generating activated forms of oxygen. A cDNA clone of soybean nodule ascorbate peroxidase was used to construct an expression system in Escherichia coli. The recombinant protein had an N-terminal tag of six consecutive histidine residues to allow for purification by Ni(2+)-agarose affinity chromatography. Large amounts of recombinant peroxidase (about 27% of total soluble protein) were produced but most of the peroxidase was present in the apo-form (without heme). Addition of delta-aminolevulinic acid to the growth media resulted in an increase in production of holoprotein. Apoprotein was easily converted to the holo-form by in vitro reconstitution with hemin. The reconstituted protein was catalytically, spectrally, and immunologically indistinguishable from native ascorbate peroxidase.

Studies on the structural and functional aspects of Rhodotorula gracilis D-amino acid oxidase by limited trypsinolysis

The structure-function relationships of purified Rhodotorula gracilis D-amino acid oxidase (in its holo-, apo- and holo-enzyme-benzoate complex forms) was analysed by digestion with trypsin. In all cases trypsin cleaves this 80 kDa dimeric enzyme at the C-terminal region, since the peptide bonds sensitive to proteinase attack are clustered in this region. Digestion of native enzyme with trypsin produced a nicked and truncated form of 38.3 kDa containing two polypeptides of 34 and 5 kDa starting from Met1 and Ala319 respectively, and with detachment of the Thr306-Arg318 and Glu365-Leu368 peptides. Our results show that this 'core', folded into a compact structure, is catalytically competent. The acquisition of this nicked form was marked by a shift from a dimeric to a monomeric active enzyme, a result never previously obtained. The deleted sequences, Thr306-Arg318 and Glu365-Leu368, are essential for the monomer-monomer interaction, and, in particular, the region encompassing Thr306-Arg318 should play an essential role in the dimerization process. interestingly, the Ser308-Lys321 sequence present in the lost peptide corresponds to a sequence not present in other known D-amino acid oxidases [Faotto, Pollegioni, Ceciliani, Ronchi and Pilone (1995) Biotechnol. Lett. 17, 193-198]. A role of the cleaved-off region for the thermostabilization of the enzyme is also discussed.

Resonance Raman studies of catecholate and phenolate complexes of recombinant human tyrosine hydroxylase

Human tyrosine hydroxylase isoform 1 (hTH1) was expressed in Escherichia coli, purified as the apoenzyme, and reconstituted with iron. The resonance Raman spectra of hTH1 complexed with dopamine, noradrenaline, tyramine, and catechol have been studied and compared to those obtained for TH isolated from bovine adrenal glands or rat phaeochromocytoma tissue. A TH-phenolate complex is reported for the first time. Using dopamine selectively 18O-labeled in the 3-position or both 3- and 4-hydroxy positions, we have been able to assign unambiguously the origin of the low-frequency vibration bands: the band at 631 cm-1 involves the oxygen in the 4-position; the band at 592 cm-1 involves the oxygen in the 3-position, and the band around 528 cm-1 is shifted by both, suggesting a chelated mode vibration. A small shift of the 1275 cm-1 band and no shift of the 1320 cm-1 band were observed, showing that those two bands involve essentially ring vibrations of the catecholate moiety, rather than the C--O stretching vibration as previously suggested. The spectrum of the catechol-d6-hTH1 complex confirms this assignment. The resonance Raman spectra of the 54Fe, 56Fe, or 57Fe isotope-containing enzymes complexed with dopamine are virtually identical, showing that the component of the iron in the approximately 600 cm-1 vibrations is too small to be observed. These results provide a better understanding of the Raman properties of iron-catecholate complexes in this enzyme, as well as in other metalloproteins and model compounds.

Purification and characterization of the imidazoleglycerol-phosphate dehydratase of Saccharomyces cerevisiae from recombinant Escherichia coli

The HIS3+ gene of Saccharomyces cerevisiae was overexpressed in Escherichia coli and the recombinant imidazoleglycerol-phosphate dehydratase (IGPD) purified to homogeneity. Laser-desorption and electrospray m.s. indicated a molecular ion within 2 units of that expected (23833.3) on the basis of the protein sequence, with about half of the polypeptide lacking the N-terminal formylmethionine residue. IGPD initially purified as an apoprotein was catalytically inactive and mainly a trimer of M(r) 70,000. Addition of Mn2+ (but not Mg2+) caused this to assemble to an active (40 units/mg) enzyme (Mn-IGPD) comprising of 24 subunits (M(r) 573,000) and containing 1.35 +/- 0.1 Mn atoms/polypeptide subunit. An enzyme with an identical activity and metal content was also obtained when the fermenter growth medium of recombinant Escherichia coli was supplemented with MnCl2, and IGPD was purified through as Mn-IGPD rather than as the apoenzyme and assembled in vitro. Inhibition by EDTA indicated that the intrinsic Mn2+ was essential for activity. The retention of activity over time after dilution to very low concentrations of enzyme (< 20 nM) indicated that the metal remained in tight association with the protein. A novel continuous assay method was developed to facilitate the kinetic characterization of Mn-IGPD. At pH 7.0, the Km for IGP was 0.10 +/- 0.02 mM and the Ki value for inhibition by 1,2,4-triazole, 0.12 +/- 0.02 mM. In contrast with other reports, thiols had no influence on catalytic activity. The activity of Mn-IGPD varied with enzyme concentration in such a way as to suggest that it dissociates to a less active form at very low concentrations. Significant inhibition by the product, imidazole acetol phosphate, was inferred from the shape of the progress curve. Titration with, the potent competitive inhibitor, 2-hydroxy-3-(1,2,4-triazol-1-yl)propyl phosphonate indicated that Mn-IGPD contained 0.9 +/- 0.1 catalytic sites/protomer. The activity nearly doubled in the presence of high concentrations of Mn2+; the apparent Ks for stimulation was 20 microM. The basis of this effect was obscure, since there was no corresponding increase in the titre of active sites. Neither was there a discernable shift in the values of Km or Ki (above), although exogenous Mn2+ did reduce the optimum pH for kcat, from 7.2 to 6.8. On the basis of a single site/subunit, the maximum rate of catalytic turnover at 30 degrees C was 32 s-1.

A simple method for determination of stereospecificity of aminotransferases for C-4' hydrogen transfer of the coenzyme

A simple method was established for determination of the stereospecificity of C-4' hydrogen transfer of the coenzymes (pyridoxal and pyridoxamine). The method is based on the findings that aspartate aminotransferase of pig heart and D-amino acid aminotransferase of Bacillus sp. YM-1 catalyze the abstraction of the pro-S and pro-R proton at C-4' of pyridoxamine, respectively. Pyridoxal is a poor coenzyme, but readily released from the enzyme. It reacts in 3H2O with a substrate amino acid and an apo-aminotransferase whose stereospecificity for C-4' hydrogen transfer is to be determined. The resultant pyridoxamine which is tritiated at C-4' is incubated with an apo form of aspartate aminotransferase or D-amino acid aminotransferase and a substrate, alpha-keto acid. The stereospecificity for the C-4' hydrogen transfer examined is determined by measurement of radioactivity retained in the pyridoxal formed. We showed by means of this method that C-4' hydrogen transfer of coenzyme occurs on the si face of the external Schiff base in the transamination reactions of two aspartate aminotransferases of Bacillus sp. YM-2 and Escherichia coli, and aromatic amino acid aminotransferase of E. coli.

Conformation and interaction of phenylalanine with the divalent cation at the active site of human recombinant tyrosine hydroxylase as determined by proton NMR

Recombinant human tyrosine hydroxylase has been purified as a metal-free apoenzyme (apo-hTH1) which tightly binds one Fe2+, Co2+, or Zn2+ per subunit with activation only by Fe2+ and competitive inhibition by the other cations. L-tyrosine and L-phenylalanine are alternative substrates for this enzyme, giving similar Vmax values, although the KM value for phenylalanine is about 8-fold greater than for tyrosine. Apo-hTH1 enhances the paramagnetic effects of Co2+ on 1/T1 and 1/T2 values of the protons of enzyme-bound phenylalanine both in the presence and in the absence of the oxidized form of the cofactor L-erythro-7,8-dihydrobiopterin (BH2), which was used as an inactive analog of the natural cofactor (6R)-1-erythro-tetrahydrobiopterin (BH4). No effects of hTH1-Zn2+ on 1/T1 or 1/T2 are found. From paramagnetic effects of hTH1-Co2+ on 1/T1 of phenylalanine protons at 250 and 600 MHz, in the presence of BH2, a correlation time (tau c) of 1.8 +/- 0.1 ps was found. Using this tau c value, and assuming that only one proton of the pairs H3,H5, and H2,H6 is experiencing the total paramagnetic effect (asymmetric limiting case), distances from enzyme-bound Co2+ to phenylalanine (+/- 1.2 A) of 6.1 A (H3 or H5), 6.3 A (H2 or H6), 7.0 A (H4), 7.3 A (H alpha), > or = 7.4 A (H beta-pro-S), and > or = 7.6 A (H beta-pro-R) were calculated. The distances to H3 or H5 and to H2 or H6 are slightly increased to 6.8 and 7.0 A, respectively, if each proton of both degenerate pairs equally experiences the paramagnetic effect of Co2+ (symmetric limiting case). These distances place the aromatic ring of phenylalanine in the second coordination sphere of the metal, which would permit an Fe-bound oxy or peroxy species to approach molecular contact with C3/C4, suggesting a direct role of Fe2+ in the hydroxylation reaction. The same correlation time and similar distances were found in the absence of BH2 with H4 of phenylalanine slightly closer to the metal. In the ternary hTH1-Zn(2+).BH2.phenylalanine complex, eight interproton distances in the enzyme-bound phenylalanine were determined by NOESY spectra at 600 MHz at 35-, 50-, and 75-ms mixing times. The conformation of enzyme-bound phenylalanine, consistent with the six Co(2+)-proton distances and the eight interproton distances, is partially extended with torsional angles chi 1 = 97 degrees +/- 3 degrees and chi 2 = -78 degrees +/- 2 degrees.