Purification and characterization of EDTA monooxygenase from the EDTA-degrading bacterium BNC1

The synthetic chelating agent EDTA can mobilize radionuclides and heavy metals in the environment. Biodegradation of EDTA should reduce this mobilization. Although several bacteria have been reported to mineralize EDTA, little is known about the biochemistry of EDTA degradation. Understanding the biochemistry will facilitate the removal of EDTA from the environment. EDTA-degrading activities were detected in cell extracts of bacterium BNC1 when flavin mononucleotide (FMN), NADH, and O2 were present. The degradative enzyme system was separated into two different enzymes, EDTA monooxygenase and an FMN reductase. EDTA monooxygenase oxidized EDTA to glyoxylate and ethylenediaminetriacetate (ED3A), with the coconsumption of FMNH2 and O2. The FMN reductase provided EDTA monooxygenase with FMNH2 by reducing FMN with NADH. The FMN reductase was successfully substituted in the assay mixture by other FMN reductases. EDTA monooxygenase was purified to greater than 95% homogeneity and had a single polypeptide with a molecular weight of 45,000. The enzyme oxidized both EDTA complexed with various metal ions and uncomplexed EDTA. The optimal conditions for activity were pH 7.8 and 35 degreesC. Kms were 34.1 microM for uncomplexed EDTA and 8.5 microM for MgEDTA2-; this difference in Km indicates that the enzyme has greater affinity for MgEDTA2-. The enzyme also catalyzed the release of glyoxylate from nitrilotriacetate and diethylenetriaminepentaacetate. EDTA monooxygenase belongs to a small group of FMNH2-utilizing monooxygenases that attack carbon-nitrogen, carbon-sulfur, and carbon-carbon double bonds.     

The Na(+)-translocating NADH:ubiquinone oxidoreductase from the marine bacterium Vibrio alginolyticus contains FAD but not FMN

The Na(+)-translocating NADH:ubiquinone oxidoreductase from Vibrio alginolyticus was extracted from the bacterial membranes and purified by ion exchange chromatographic procedures. The enzyme catalyzed NADH oxidation by suitable electron acceptors, e.g. menadione, and the Na+ and NADH-dependent reduction of ubiquinone-1. Four dominant bands and a number of minor bands were visible on SDS-PAGE that could be part of the enzyme complex. Flavin analyses indicated the presence of FAD but no FMN in the purified enzyme. FAD but no FMN were also present in V. alginolyticus membranes. FAD is therefore a prosthetic group of the Na(+)-translocating NADH:ubiquinone oxidoreductase and FMN is not present in the enzyme. The FAD was copurified with the NADH dehydrogenase. The purified enzyme exhibited an absorption spectrum with a maximum at 450 nm that is typical for a flavoprotein. Upon incubation with NADH this absorption disappeared indicating reduction of the enzyme-bound FAD.     

Effects of abnormal-sterol accumulation on Ustilago maydis plasma membrane H+-ATPase stoichiometry and polypeptide pattern

A flavoprotein with NADH oxidising activity (NADH: acceptor oxidoreductase) was isolated from the soluble fraction of the thermoacidophilic archaea Acidianus ambivalens. The protein is a monomer with a molecular mass of 70 kDa and contains FAD as single cofactor. Its activity as NADH:O2 oxidoreductase is FAD, but not FMN, dependent and yields hydrogen peroxide as the reaction product. The activity decreases with pH in the range 4.5 to 9.8, and increases with the temperature, as tested from 30 degrees to 60 degrees C. As elicited by EPR, the purified enzyme also acts as an NADH:ferredoxin oxidoreductase. These features are discussed in light of the possible involvement of this protein in the metabolism of this archaea.     

Characterization of the overproduced NADH dehydrogenase fragment of the NADH:ubiquinone oxidoreductase (complex I) from Escherichia coli

The proton-pumping NADH:ubiquinone oxidoreductase of Escherichia coli is composed of 14 different subunits and contains one FMN and up to nine iron-sulfur clusters as prosthetic groups. By use of salt treatment, the complex can be split into an NADH dehydrogenase fragment, a connecting fragment and a membrane fragment. The water-soluble NADH dehydrogenase fragment has a molecular mass of approximately 170,000 Da and consists of the subunits NuoE, F, and G. The fragment harbors the FMN and probably six iron-sulfur clusters, four of them being observable by EPR spectroscopy. Here, we report that the fully assembled fragment can be overproduced in E. coli when the genes nuoE, F, and G were simultaneously overexpressed with the genes nuoB, C, and D. Furthermore, riboflavin, sodium sulfide, and ferric ammonium citrate have to be added to the culture medium. The fragment was purified from the cytoplasm by means of ammonium sulfate fractionation and chromatographic steps. The preparation contains one noncovalently bound FMN per molecule. Two binuclear (N1b and N1c) and two tetranuclear (N3 and N4) iron-sulfur clusters were detected by EPR in the NADH reduced preparation with spectral characteristics identical with those of the corresponding clusters in complex I. The preparation fulfills all prerequisites for crystallization of the fragment.     

Search for novel redox groups in mitochondrial NADH:ubiquinone oxidoreductase (complex I) by diode array UV/VIS spectroscopy

The proton-translocating NADH:ubiquinone oxidoreductase of mitochondria (complex I) is a large L-shaped multisubunit complex. The peripheral matrix arm contains one FMN and a number of iron-sulfur (FeS) clusters and is involved in NADH oxidation and electron transfer to the membrane intrinsic arm. There, following a yet unknown mechanism, the redox-driven proton translocation and the ubiquinone reduction take place. Redox groups that would be able to link electron transfer with proton translocation have not been found so far in the membrane arm. We searched for such groups in complex I isolated from Neurospora crassa. Under anaerobic conditions, the preparation was analyzed in different redox states by means of UV/VIS and EPR spectroscopy. Absorption bands in the UV/VIS redox difference spectra were found which cannot be attributed to the FMN or the EPR detectable FeS clusters. The existence of two novel groups is postulated and their possible locations in the electron pathway and their roles in proton translocation are discussed.     

Steady-state kinetic mechanism, stereospecificity, substrate and inhibitor specificity of Enterobacter cloacae nitroreductase

Enterobacter cloacae nitroreductase (NR) is a flavoprotein which catalyzes the pyridine nucleotide-dependent reduction of nitroaromatics. Initial velocity and inhibition studies have been performed which establish unambiguously a ping-pong kinetic mechanism. NADH oxidation proceeds stereospecifically with the transfer of the pro-R hydrogen to the enzyme and the amide moiety of the nicotinamide appears to be the principal mediator of the interaction between NR and NADH. 2,4-Dinitrotoluene is the most efficient oxidizing substrate examined, with a kcat/KM an order of magnitude higher than those of p-nitrobenzoate, FMN, FAD or riboflavin. Dicoumarol is a potent inhibitor competitive vs. NADH with a Ki of 62 nM. Several compounds containing a carboxyl group are also competitive inhibitors vs. NADH. Yonetani-Theorell analysis of dicoumarol and acetate inhibition indicates that their binding is mutually exclusive, which suggests that the two inhibitors bind to the same site on the enzyme. NAD+ does not exhibit product inhibition and in the absence of an electron acceptor, no isotope exchange between NADH and 32P-NAD+ could be detected. NR catalyzes the 4-electron reduction of nitrobenzene to hydroxylaminobenzene with no optically detectable net formation of the putative two-electron intermediate nitrosobenzene.     

Mitochondrial NADH-ubiquinone oxidoreductase (Complex I). Effect of substrates on the fragmentation of subunits by trypsin

It has been shown that treatment of bovine mitochondrial complex I (NADH-ubiquinone oxidoreductase) with NADH or NADPH, but not with NAD or NADP, increases the susceptibility of a number of subunits to tryptic degradation. This increased susceptibility involved subunits that contain electron carriers, such as FMN and iron-sulfur clusters, as well as subunits that lack electron carriers. Results shown elsewhere on changes in the cross-linking pattern of complex I subunits when the enzyme was pretreated with NADH or NADPH (Belogrudov, G., and Hatefi, Y. (1994) Biochemistry 33, 4571-4576) also indicated that complex I undergoes extensive conformation changes when reduced by substrate. Furthermore, we had previously shown that in submitochondrial particles the affinity of complex I for NAD increases by >/=20-fold in electron transfer from succinate to NAD when the particles are energized by ATP hydrolysis. Together, these results suggest that energy coupling in complex I may involve protein conformation changes as a key step. In addition, it has been shown here that treatment of complex I with trypsin in the presence of NADPH, but not NADH or NAD(P), produced from the 39-kDa subunit a 33-kDa degradation product that resisted further hydrolysis. Like the 39-kDa subunit, the 33-kDa product bound to a NADP-agarose affinity column, and could be eluted with a buffer containing NADPH. It is possible that together with the acyl carrier protein of complex I the NADP(H)-binding 39-kDa subunit is involved in intramitochondrial fatty acid synthesis.     

Site-directed mutagenesis of the conserved threonine (Thr243) of the distal helix of fungal cytochrome P450nor

Cytochrome P450nor (P450nor) is a heme enzyme which catalyzes NO reduction in denitrifying fungi. Threonine 243 (Thr243) of P450nor, which corresponds to the conserved threonine of monooxygenase cytochrome P450s, was replaced by 18 different amino acids via site-directed mutagenesis. The mutation did not seriously affect the optical absorption and the CD spectral properties of the enzyme in several oxidation, ligation, or spin states or the association rate constant for association of NO with the ferric iron, suggesting subtle and local structural changes in the heme environment on Thr243 mutation. However, the NO reduction activity was dramatically altered by Thr243 mutation, depending on the properties of the replaced amino acids. The catalytic activity, as measured by N2O formation and NADH consumption, was considerably retained on substitution of Asn, Ser, and Gly for Thr243, while it was profoundly decreased or lost on substitution with other amino acids. Kinetic analysis of the reaction of the enzymes with NO and NADH indicated that the decrease in the enzymatic activity upon Thr243 mutation mainly results from a decrease in the rate of reduction of the ferric-NO complex with NADH. On the basis of these enzymatic, kinetic, and spectroscopic results, as well as on the basis of the crystal data for native P450nor [Park, S.-Y., et al. (1997) Nat. Struct. Biol. 4, 827-832], the role of the conserved threonine at the 243 position in the NO reduction reaction by P450nor is discussed. We also discuss structural similarities or differences in the vicinity of the conserved threonine between P450nor and other monooxygenase P450s.     

The role of the proton-pumping and alternative respiratory chain NADH:ubiquinone oxidoreductases in overflow catabolism of Aspergillus niger

Mitochondria of fungi contain two respiratory chain enzymes concerned with the oxidation of matrix NADH. These are the proton-pumping NADH:ubiquinone oxidoreductase, also called complex I, which has a high affinity for NADH, and a non-proton-pumping NADH:ubiquinone oxidoreductase, called alternative NADH dehydrogenase, which has a low affinity for NADH. The role of these two enzymes in normal and overflow catabolism has been studied in Aspergillus niger. Three strains were investigated, the wild-type 732, the mutant nuo51 that was generated from the wild-type by disrupting the gene of the (51-kDa) NADH-binding subunit of complex I and the citric acid over-producing strain B60 that looses complex I concomitantly with the onset of the over-production. Under standard growth conditions, respiratory energy transduction in the mutant nuo51 was decreased by 40% compared to the parental wild-type and the strain B60. Respiratory electron transfer in the mutant nuo51, however, meets standard catabolic requirements. The intracellular levels of citric acid cycle intermediates in the mutant nuo51 were the same as in the other two strains. Under growth conditions which lead to uncontrolled catabolic flux through glycolysis, a dramatic catabolic overflow occurred in the mutant nuo51. Intracellular levels of citric acid cycle intermediates increased to 20-fold normal levels. The strain B60, likewise lacking complex I under these conditions, excretes large amounts of citrate to moderate the intracellular catabolic overflow.     

Dopaminergic activity and the discriminative stimulus effects of mu opioids in pigeons: importance of training dose and attenuation by the D3 agonist (+/-)-7-OH-DPAT

Chlorophyll fluorescence measurements were performed on osmotically lysed potato chloroplasts in order to characterize the reactions involved in the dark reduction of photosynthetic inter-system chain electron carriers. Addition of NADH or NADPH to lysed chloroplasts increased the chlorophyll fluorescence level measured in the presence of a non-actinic light until reaching Fmax, thus indicating an increase in the redox state of the plastoquinone (PQ) pool. The fluorescence increase was more pronounced when the experiment was carried out under anaerobic conditions and was about 50% higher when NADH rather than NADPH was used as an electron donor. The NAD(P)H-PQ oxidoreductase reaction was inhibited by diphenylene iodonium, N-ethylmaleimide and dicoumarol, but insensitive to rotenone, antimycin A and piericidin A. By comparing the substrate specificity and the inhibitor sensitivity of this reaction to the properties of spinach ferredoxin-NADP+-reductase (FNR), we infer that FNR is not involved in the NAD(P)H-PQ oxidoreductase activity and conclude to the participation of rotenone-insensitive NAD(P)H-PQ oxidoreductase. By measuring light-dependent oxygen uptake in the presence of DCMU, methyl viologen and NADH or NADPH as an electron donors, the electron flow rate through the NAD(P)H-PQ oxidoreductase is estimated to about 160 nmol O2 min-1 mg-1 chlorophyll. The nature of this enzyme is discussed in relation to the existence of a thylakoidal NADH dehydrogenase complex encoded by plastidial ndh genes. Copyright 1998 Elsevier Science B.V.     

Neither human immunodeficiency virus-1 (HIV-1) nor HIV-2 infects most-primitive human hematopoietic stem cells as assessed in long-term bone marrow cultures

Phenylglyoxylate (benzoylformate) is an intermediate in the anoxic metabolism of phenylalanine and phenylacetate. It is formed by alpha-oxidation of phenylacetyl-CoA. Phenylglyoxylate is oxidatively decarboxylated by phenylglyoxylate-oxidoreductase to benzoyl-CoA, a central intermediate of anaerobic aromatic metabolism. The phenylglyoxylate oxidizing enzyme activity in the denitrifying bacterium Azoarcus evansii was induced during anaerobic growth with phenylalanine, phenylacetate and phenylglyoxylate, but not with benzoate. The new enzyme phenylglyoxylate:acceptor oxidoreductase was purified and studied. The oxygen-sensitive enzyme reduced both NAD+ and viologen dyes. It was composed of five subunits of approximately 50, 48, 43, 24, and 11.5 kDa; the native mass as determined by gel filtration was 370 kDa, suggesting an alpha2 beta2 gamma2 delta2 epsilon2 composition. Phenylglyoxylate:acceptor oxidoreductase exhibited an ultraviolet/visible spectrum characteristic for an iron-sulfur protein and contained 35 +/- 4 mol Fe, 36 +/- 4 mol acid-labile sulfur, and 1.1 +/- 0.2 mol FAD/mol. The enzyme was specific for phenylglyoxylate (Km 45 microM) and coenzyme A (Km 55 microM); 2-oxoisovalerate was oxidized with 15% of the rate. The turnover number with benzyl viologen at 37 degrees C was 46 s(-1) at the optimal pH of 8. The enzyme catalyzed a NAD(P)H:viologen dye transhydrogenation reaction, NAD(H) being the preferred coenzyme. It also catalyzed an isotope exchange between CO2 and the carboxyl group of the substrate. The data are consistent with the following hypothesis. The enzyme complex consists of a core enzyme of four subunits with the composition alpha2 beta2 gamma2 delta2, as reported for archaeal 2-oxoacid:ferredoxin oxidoreductases; this complex is able to reduce viologen dyes. The holoenzyme contains in addition an epsilon2 unit that catalyzes the transfer of electrons from a small ferredoxin-like subunit of the core complex to NAD+; this unit also catalyzes the transhydrogenase reaction, carries FAD and resembles ferredoxin:NAD(P)+-oxidoreductase.     

Cloning and characterization of the genes encoding nitrilotriacetate monooxygenase of Chelatobacter heintzii ATCC 29600

A 6.2-kb DNA fragment containing the genes for the nitrilotriacetate (NTA) monooxygenase of Chelatobacter heintzii ATCC 29600 was cloned and characterized by DNA sequencing and expression studies. The nucleotide sequence contained three major open reading frames (ORFs). Two of the ORFs, which were oriented divergently with an intergenic region of 307 bp, could be assigned to the NTA monooxygenase components A and B. The predicted N-terminal amino acid sequences of these ORFs were identical with those determined for the purified components. We therefore named these genes ntaA (for component A of NTA monooxygenase) and ntaB (for component B). The ntaA and ntaB genes could be expressed in Escherichia coli DH5alpha, and the gene products were visualized after Western blotting (immunoblotting) and incubation with polyclonal antibodies against component A or B. By mixing overproduced NtaB from E. coli and purified component A from C. heintzii ATCC 29600, reconstitution of a functional NTA monooxygenase complex was possible. The deduced gene product of ntaA showed only significant homology to SoxA (involved in dibenzothiophene degradation) and to SnaA (involved in pristamycin synthesis); that of ntaB shared weak homologies in one domain with other NADH:flavine mononucleotide oxidoreductases. These homologies provide no conclusive answer as to the possible evolutionary origin of the NTA monooxygenase. The deduced gene product of the third ORF (ORF1) had homology in the N-terminal region with the GntR class of bacterial regulator proteins and therefore may encode a regulator protein, possibly involved in regulation of ntaA and ntaB expression.     

A unique reaction in a common pathway: mechanism and function of chorismate synthase in the shikimate pathway

Chorismate synthase, the seventh enzyme in the shikimate pathway, catalyzes the transformation of 5-enolpyruvylshikimate 3-phosphate to chorismate which is the last common precursor in the biosynthesis of numerous aromatic compounds in bacteria, fungi and plants. The enzyme has an absolute requirement for reduced FMN as a cofactor, although the 1,4-anti elimination of phosphate and the C(6proR)-hydrogen does not involve a net redox change. The role of the reduced FMN in catalysis has long been elusive. However, recent detailed kinetic and bioorganic approaches have fundamentally advanced our understanding of the mechanism of action, suggesting an initial electron transfer from tightly bound reduced flavin to the substrate, a process which results in C-O bond cleavage. Studies on chorismate synthases from bacteria, fungi and plants revealed that in these organisms the reduced FMN cofactor is made available in different ways to chorismate synthase: chorismate synthases in fungi--in contrast to those in bacteria and plants--carry a second enzymatic activity which enables them to reduce FMN at the expense of NADPH. Yet, as shown by the analysis of the corresponding genes, all chorismate synthases are derived from a common ancestor. However, several issues revolving around the origin of reduced FMN, as well as the possible regulation of the enzyme activity by means of the availability of reduced FMN, remain poorly understood. This review summarizes recent developments in the biochemical and genetic arena and identifies future aims in this field.     

Differential redox and electron-transfer properties of purified yeast, plant and human NADPH-cytochrome P-450 reductases highly modulate cytochrome P-450 activities

Saccharomyces, human and two Arabidopsis (ATR1 and ATR2) NADPH-P-450 reductases were expressed in yeast, purified to homogeneity and used to raise antibodies. Among the P-450-reductases, ATR2 contrasted by its very low FMN affinity and required a thiol-reducing agent for efficient cofactor binding to the FMN-depleted enzyme. Analysis of reductase kinetic properties using artificial acceptors and different salt conditions suggested marked differences between reductases in their FAD and FMN environments and confirmed the unusual properties of the ATR2 FMN-binding domain. Courses of flavin reductions by NADPH were analysed by rapid kinetic studies. The human enzyme was characterized by a FAD reduction rate sixfold to tenfold slower than values for the three other reductases. Following the fast phase of reduction, expected accumulation of flavin semiquinone was observed for the human and ATR1 but not for ATR2 and the yeast reductases. Consistently, redox potential for the FMN semiquinone/reduced couple in the yeast enzyme was found to be more positive than the value for the FMN oxidized/semiquinone couple. This situation was reminiscent of similar inversion observed in bacterial P-450 BM3 reductase. Affinities of reductases for rabbit P-450 2B4 and supported monooxygenase activities in reconstituted systems highly depended on the reductase source. The human enzyme exhibited the highest affinity but supported the lowest kcat whereas the yeast reductase gave the best kcat but with the lowest affinity. ATR1 exhibited both high affinity and efficiency. No simple relation was found between reductase activities with artificial and natural (P-450) acceptors. Thus marked differences in kinetic and redox parameters between reductases dramatically affect their respective abilities to to support P-450 functions.     

Clinical evaluation of failure to thrive in older people

Deoxyhypusine synthase catalyzes the NAD+-dependent formation of deoxyhypusine in the eIF-5A precursor protein by transferring the 4-aminobutyl moiety of spermidine. This enzyme has recently been shown to be essential for cell viability and growth of yeast [Sasaki, K., Abid, M.R., and Miyazaki, M. (1996) FEBS Lett. 384, 151 154]. We have purified and characterized the enzyme from the yeast Saccharomyces carlsbergensis. The yeast and recombinant enzymes had a specific activity of 1.21 to 1.26 pmol per min per pmol of protein, and recognized both the eIF-5A precursor proteins almost equally as judged from their similar K(m) and V(max) values. Size exclusion chromatography and SDS-PAGE indicated that the active form of the enzyme is a homotetramer consisting of 43-kDa subunits. The enzyme showed a strict specificity for its substrates, NAD+, spermidine and eIF-5A precursor protein. Among all the substrates tested, only NAD+ showed a protective effect against heat inactivation of the enzyme suggesting that NAD+ initiates some conformational change in the enzyme. NADH exhibited a strong non-competitive inhibition (product inhibition). Unexpectedly, FAD, FMN, and riboflavin showed a moderate competitive inhibition. The competitive inhibition by diamines was maximal with compounds resembling spermidine in carbon chain length. 1,3-Diaminopropane inhibited the enzyme strongly in a competitive manner (product inhibition). On the other hand, putrescine did not inhibit the enzyme or act as a substrate. A polyclonal antibody raised against the yeast recombinant enzyme specifically inhibited deoxyhypusine synthase activity. The cross-reactivity (by Western blotting) of this antibody with the crude extracts varied depending on the source, indicating species specificity.     

Regulation of multicatalytic enzyme activity by insulin and the insulin-degrading enzyme

The insulin-degrading enzyme (IDE) plays an important role in the cellular metabolism of insulin. Recent studies have also suggested a regulatory role for this protein in controlling the activity of cytoplasmic protein complexes, including the proteasome [multicatalytic proteinase (MCP)] and the glucocorticoid and androgen receptors. Binding of IDE to these complexes increases their activity, whereas the addition of substrates for IDE inhibits activity. This provides a potential mechanism of action for internalized insulin and other IDE substrates in the control of protein turnover. To examine further the interactions, partially purified IDE-MCP complex was treated with EDTA or EGTA, and activity was measured in the absence and presence of various divalent cations (Ca2+, Mn2+, Co2+, and Zn2+) and insulin. EDTA treatment reduced MCP activity and eliminated the effect of insulin on the complex. Divalent cations partially or completely restored MCP activity, but did not restore the effect of insulin. EGTA treatment had a lesser effect on MCP activity, but abolished insulin inhibition of activity. Divalent cations restored the insulin effect. Inhibitors of IDE also blocked the insulin effect on MCP activity, as did treatment with SDS. These findings suggest that conformational changes in the complex may play a role in the insulin control of MCP activity.     

Roles of the methane monooxygenase reductase component in the regulation of catalysis

The reductase component (MMOR) of the soluble methane monooxygenase isolated from Methylosinus trichosporium OB3b catalyzes transfer of 2e- from NADH to the hydroxylase component (MMOH) where oxygen activation and substrate oxidation occur. It is shown here that MMOR can also exert regulatory effects on catalysis by binding to MMOH or to the binary complex of MMOH and component B (MMOB), another regulatory protein. MMOR alters the oxidation-reduction potentials of the dinuclear iron cluster at the active site of MMOH. Although little change is observed in the potential for the first electron transfer to the cluster (E(1)0' = 76 mV), the E(2)0' potential value for the second electron transfer is increased from 21 to 125 mV. This shift provides a larger driving force for electron transfer from MMOR and favors transfer of two rather than one electron as required by catalysis. Similar positive shifts in potential are observed even in the presence of MMOB which has been shown to cause a 132 mV negative shift in the midpoint potential of MMOH in the absence of MMOR. MMOR is also shown to decrease the rate of reaction between the fully reduced MMOH-MMOB and O2 approximately 20-fold at 4 degrees C. However, the time course of the key catalytic cycle intermediate that can react with substates, compound Q, is unaffected. This implies a compensating faster decay of one or more of the intermediates that occur between diferrous MMOH and compound Q in the reaction cycle, thereby limiting potential nonproductive autodecay of these intermediates. Accordingly, an increase in single turnover product yield is observed in the presence of MMOR. Interestingly, MMOR can cause the redox potential increases, changes in rates, and the increase in product yield when present at only 10% of the concentration of MMOH active sites. Substrate binding is shown to induce negligible changes in the redox potentials. Two alternative regulatory schemes are presented based on (i) thermodynamic coupling of component binding and redox changes or (ii) dynamic interconversion of two states of MMOH promoted by MMOR.     

Contribution of quantitative lectin histochemistry to characterizing well-differentiated, dedifferentiated and poorly differentiated liposarcomas

The antioxidative effect of CuZnSOD, which catalyzes the dismutation of superoxide anion (O2-), provides a defense against the oxygen toxicity. The object of the study is to evaluate the erythrocytes superoxide dismutase (SOD) activity in two groups of persons (Group I, healthy blood donors; Group II, lung cancer patients), using the spectrophotometric assay of NADH oxidation and the indirect method. The effect of trace elements, such as Al3-, Cr3+, Fe3+, Hg2+, NI2+, and Pb2+ (producing free radicals oxygen and present in pollution and smoke) is also evaluated. The results show the decrease of SOD activity in lung cancer patients with respect to healthy individuals. Likewise, in those patients the enzymatic activity is bigger in early stage (I,II) with respect to advanced one (III) (p < 0.05). The lesser activity when the samples are incubated with Ni or Pb point out that these metals play a role in neoplasm development. In short, the oxidant-antioxidant balance is altered in lung cancer patients.     

Effects of metal ions on the substrate-specificity and activity of proton-pumping nicotinamide nucleotide transhydrogenase from Escherichia coli

Nicotinamide nucleotide transhydrogenase catalyzes the reversible reduction of NADP+ by NADH and a concomitant proton translocation. It was demonstrated (Glavas, N.A. and Bragg, P.D. (1995) Biochim. Biophys. Acta 1231, 297-303) that the Escherichia coli transhydrogenase also catalyzed a reduction of the NAD-analogue 3-acetylpyridine-NAD+ (AcPyAD+) by NADH at low pH and in the absence of (added) NADP(H) and high salt concentrations The mechanism of this reaction has as yet not been explained. In the present study, the E. coli transhydrogenase was purified by affinity chromatography through the NADP(H)-site, rendering the pure enzyme free of NADP(H). Using this preparation it was confirmed that the enzyme readily catalyzes the above reaction. Inhibitors specific for the NADP(H)-site, e.g., palmitoyl-Coenzyme A and adenosine-2'-monophosphate-5'-diphosphoribose, strongly inhibited the reduction of AcPyAD+ by NADH, whereas an inhibitor of the NAD(H)-site, adenosine 5'-diphosphoribose, was less inhibitory. This suggests that a lack of metal ions or other ions at low pH induces an unspecific interaction of the NADP(H)-site with AcPyAD+ or NADH, presumably NADH, producing a cyclic reduction of AcPyAD+ by NADH via NAD(H) bound in the NADP(H) site. A stimulation of reduction of AcPyAD+ by NADPH by Mg2+ present during reconstitution of transhydrogenase in phospholipid vesicles was observed, but it is presently unclear whether this effect is related to that seen with the detergent-dispersed enzyme.     

cDNA sequence and chromosomal localization of the remaining three human nuclear encoded iron sulphur protein (IP) subunits of complex I: the human IP fraction is completed

NADH:ubiquinone oxidoreductase (complex I) of the mitochondrial respiratory chain can be fragmented in a flavoprotein (FP), iron-sulfur protein (IP), and hydrophobic protein (HP) subfraction. The IP subfraction is hypothesized to be significant, since it contains important prosthetic groups highly conserved among species. We cloned the cDNA of three remaining human NADH:ubiquinone oxidoreductase subunits of this IP fraction: the NDUFS2 (49 kDa), NDUFS3 (30 kDa), and NDUFS6 (13 kDa) subunits. All presented cDNAs include the complete open reading frame (ORF), which consist of 1392, 795, and 375 base pairs, coding for 463, 264, and 124 amino acids, respectively. The latter show 96, 90, and 83% homology with the corresponding bovine translation products. The 3' untranslated regions (UTR) are complete in all three cDNAs. Polymerase chain reaction performed with DNA isolated from somatic human-rodent cell hybrids containing defined human chromosomes as template gave a human-specific signal which mapped the NDUFS2 and NDUFS3 subunits to chromosomes 1 and 11, respectively. In the case of the NDUFS6 subunit a pseudogene may be present since signals were seen in the lanes containing chromosomes 5 and 6. The NDUFS2 contains a highly conserved protein kinase C phosphorylation site and the NDUFS3 subunit contains a highly conserved casein kinase II phosphorylation site which make them strong candidates for future mutation detection studies in enzymatic complex I-deficient patients.