Studies on the Mechanism of Microsomal Triphosphopyridine Nucleotide-Cytochrome c Reductase

Esterase, Glutathione S-Transferase and NADPH-Cytochrome P450 Reductase Activity Evaluation in Cacopsylla pyri L. (Hemiptera: Psyllidae) Individual Adults

Cacopsylla pyri (L.) (Hemiptera: Psyllidae) is a key pest of pear orchards in Spain. The large number of insecticide treatments necessary for control may be an important contributor to the emergence of resistance. Laboratory toxicity and biochemical assays are necessary to validate the existence of insecticide resistance and establish the underlying mechanisms. All the methodologies developed to evaluate enzyme activity in C. pyri to date have incorporated "pools" of adults to detect minimum activity ranges. In this study, we determined the optimal working conditions for evaluation of the activities of esterase, glutathione S-transferase and NADPH-cytochrome P450 reductase in individual insects via colorimetric methods using a microplate reader. The main factors affecting enzymatic analysis activity, such as enzyme source and substrate concentration, filter wavelength, buffer pH, reaction time and additives, were evaluated for optimization. Determining the frequency of resistant individuals within a population could be used as an indicator for the evolution of insecticide resistance over time. Two laboratory strains, one of them selected with cypermethrin, and two field populations were analyzed for this purpose. The data obtained revealed high values and great variation in the activity ranges of esterase (EST) in the insecticide-selected population as well as in the field populations validating the applied methodology.

Sensing the Generation of Intracellular Free Electrons Using the Inactive Catalytic Subunit of Cytochrome P450s as a Sink

Cytochrome P450 reductase (CPR) abstracts electrons from Nicotinamide adenine dinucleotide phosphate H (NADPH), transferring them to an active Cytochrome P450 (CYP) site to provide a functional CYP. In the present study, a yeast strain was genetically engineered to delete the endogenous CPR gene. A human CYP expressed in a CPR-null (yRD⁻) strain was inactive. It was queried if Bax—which induces apoptosis in yeast and human cells by generating reactive oxygen species (ROS)—substituted for the absence of CPR. Since Bax-generated ROS stems from an initial release of electrons, is it possible for these released electrons to be captured by an inactive CYP to make it active once again? In this study, yeast cells that did not contain any CPR activity (i.e., because the yeasts’ CPR gene was completely deleted) were used to show that (a) human CYPs produced within CPR-null (yRD-) yeast cells were inactive and (b) low levels of the pro-apoptotic human Bax protein could activate inactive human CYPs within this yeast cells. Surprisingly, Bax activated three inactive CYP proteins, confirming that it could compensate for CPR’s absence within yeast cells. These findings could be useful in research, development of bioassays, bioreactors, biosensors, and disease diagnosis, among others.

Effect of 20-Hydroxyecdysone, a Phytoecdysteroid, on Development, Digestive, and Detoxification Enzyme Activities of Tribolium castaneum (Coleoptera: Tenebrionidae)

Plants present a delimited reservoir of biologically active compounds. Many plants synthesize several compounds of secondary metabolism, such as alkaloids, terpenoids, phenolics, steroids, etc. Such compounds are generally thought to be involved in plant-insect interactions. Phytoecdysteroids are a class of chemicals that plants synthesize; these compounds are analogues of molting hormones produced by insects. In this work, the effect of the 20-hydroxyecdysone, which is a molecule that belongs to the family of phytoecdysteroids, was tested on an insect pest, Tribolium castaneum (Herbst). Firstly, the effect of this molecule on post-embryonic development parameters was tested after ingestion at 300, 600, 900, and 1,200 ppm. Secondly, the effect of the 20-hydroxyecdysone was also tested on the biological parameters (proteins, alpha-amylase, detoxification enzymes). The results of the post-embryonic parameters test showed an important induction of larval mortality and a significant reduction of pupation and adult emergence rates. On the other hand, the test on the biological parameters showed that the 20-hydroxyecdysone caused a significant decrease in the levels of soluble proteins in treated larvae. In addition, the alpha-amylase activity was significantly inhibited by the ingestion of the phytoecdysteroid. And there was also a disruption of detoxification enzymes. The whole of the disturbances recorded in this work prove that phytoecdysteroids are thought to have potential value on T. castaneum control.

Structural and Functional Studies of the Membrane-Binding Domain of NADPH-Cytochrome P450 Oxidoreductase

NADPH-cytochrome P450 oxidoreductase (CYPOR), the essential flavoprotein of the microsomal cytochrome P450 monooxygenase system, is anchored in the phospholipid bilayer by its amino-terminal membrane-binding domain (MBD), which is necessary for efficient electron transfer to cytochrome P450. Although crystallographic and kinetic studies have established the structure of the soluble catalytic domain and the role of conformational motions in the control of electron transfer, the role of the MBD is largely unknown. We examined the role of the MBD in P450 catalysis through studies of amino-terminal deletion mutants and site-directed spin labeling. We show that the MBD spans the membrane and present a model for the orientation of CYPOR on the membrane capable of forming a complex with cytochrome P450. EPR power saturation measurements of CYPOR mutants in liposomes containing a lipid/Ni(II) chelate identified a region of the soluble domain interacting with the membrane. The deletion of more than 29 residues from the N-terminus of CYPOR decreases cytochrome P450 activity concomitant with alterations in electrophoretic mobility and an increased resistance to protease digestion. The altered kinetic properties of these mutants are consistent with electron transfer through random collisions rather than via formation of a stable CYPOR-P450 complex. Purified MBD binds weakly to cytochrome P450, suggesting that other interactions are also required for CYPOR-P450 complex formation. We propose that the MBD and flexible tether region of CYPOR, residues 51-63, play an important role in facilitating the movement of the soluble domain relative to the membrane and in promoting multiple orientations that permit specific interactions of CYPOR with its varied partners.

Anion-Dependent Stimulation of CYP3A4 Monooxygenase

We co-crystallized human cytochrome P450 3A4 (CYP3A4) with progesterone (PRG) under two different conditions, but the resulting complexes contained only one PRG molecule bound to the previously identified peripheral site. A novel feature in one of our structures is a citrate ion, originating from the crystallization solution. The citrate-binding site is located in an area where the N-terminus splits from the protein core and, thus, is suitable for the interaction with the anionic phospholipids of the microsomal membrane. We investigated how citrate affects the function of a soluble CYP3A4 monooxygenase system consisting of equimolar amounts of CYP3A4 and cytochrome P450 reductase (CPR). Citrate was found to affect the properties of both redox partners and stimulated their catalytic activities in a concentration-dependent manner via a complex mechanism. CYP3A4-substrate binding, reduction of CPR with NADPH, and interflavin and interprotein electron transfer were identified as citrate-sensitive steps. Comparative analysis of various negatively charged organic compounds indicated that, in addition to alterations caused by changes in ionic strength, anions modulate the properties of CYP3A4 and CPR through specific anion-protein interactions. Our results help to better understand previous observations and provide new mechanistic insights into CYP3A4 function.

Aromatic substitution of the FAD-shielding tryptophan reveals its differential role in regulating electron flux in methionine synthase reductase and cytochrome P450 reductase

Methionine synthase reductase (MSR) and cytochrome P450 reductase (CPR) transfer reducing equivalents from NADPH via an FAD and FMN cofactor to a redox partner protein. In both enzymes, hydride transfer from NADPH to FAD requires displacement of a conserved tryptophan that lies coplanar to the FAD isoalloxazine ring. Swapping the tryptophan for a smaller aromatic side chain revealed a distinct role for the residue in regulating MSR and CPR catalysis. MSR W697F and W697Y showed enhanced catalysis, noted by increases in kcat and k(cat)/K(m)(NADPH) for steady-state cytochrome c(3+) reduction and a 10-fold increase in the rate constant (k(obs1)) associated with hydride transfer. Elevated primary kinetic isotope effects on k(obs1) for W697F and W697Y suggest that preceding isotopically insensitive steps like displacement of W697 are less rate determining. MSR W697Y, but not MSR W697F, showed detectable formation of the disemiquinone intermediate, indicating that the polarity of the aromatic side chain influences the rate of interflavin electron transfer. By contrast, the CPR variants (W676F and W676Y) displayed modest decreases in cytochrome c(3+) reduction, a 30- and 3.5-fold decrease in the rate of FAD reduction, accumulation of a FADH2 -NADP(+) charge-transfer complex and dramatically suppressed rates of interflavin electron transfer. We conclude for MSR that hydride transfer is 'gated' by the free energy required to disrupt dispersion forces between the FAD isoalloxazine ring and W697. By contrast, the bulky indole ring of W676 accelerates catalysis in CPR by lowering the energy barrier for displacement of the oxidized nicotinamide ring coplanar with the FAD.

Antioxidant deficit in gills of Pacific oyster (Crassostrea gigas) exposed to chlorodinitrobenzene increases menadione toxicity

Disturbances in antioxidant defenses decrease cellular protection against oxidative stress and jeopardize cellular homeostasis. To knock down the antioxidant defenses of Pacific oyster Crassostrea gigas, animals were pre-treated with 1-chloro-2,4-dinitrobenzene (CDNB) and further challenged with pro-oxidant menadione (MEN). CDNB pre-treatment (10 μM for 18 h) was able to consume cellular thiols in gills, decreasing GSH (53%) and decrease protein thiols (25%). CDNB pre-treatment also disrupted glutathione reductase and thioredoxin reductase activity in the gills, but likewise strongly induced glutathione S-transferase activity (270% increase). Surprisingly, hemocyte viability was greatly affected 24 h after CDNB removal, indicating a possible vulnerability of the oyster immune system to electrophilic attack. New in vivo approaches were established, allowing the identification of higher rates of GSH-CDNB conjugate export to the seawater and enabling the measurement of the organic peroxide consumption rate. CDNB-induced impairment in antioxidant defenses decreased the peroxide removal rate from seawater. After showing that CDNB decreased gill antioxidant defenses and increased DNA damage in hemocytes, oysters were further challenged with 1 mM MEN over 24 h. MEN treatment did not affect thiol homeostasis in gills, while CDNB pre-treated animals recovered GSH and PSH to the control level after 24 h of depuration. Interestingly, MEN intensified GSH and PSH loss and mortality in CDNB-pre-treated animals, showing a clear synergistic effect. The superoxide-generating one-electron reduction of MEN was predominant in gills and may have contributed to MEN toxicity. These results support the idea that antioxidant-depleted animals are more susceptible to oxidative attack, which can compromise survival. Data also corroborate the idea that gills are an important detoxifying organ, able to dispose of organic peroxides, induce phase II enzymes, and efficiently export GSH-CDNB conjugates.

Kinetic and spectroscopic probes of motions and catalysis in the cytochrome P450 reductase family of enzymes

There is a mounting body of evidence to suggest that enzyme motions are linked to function, although the design of informative experiments aiming to evaluate how this motion facilitates reaction chemistry is challenging. For the family of diflavin reductase enzymes, typified by cytochrome P450 reductase, accumulating evidence suggests that electron transfer is somehow coupled to large-scale conformational change and that protein motions gate the electron transfer chemistry. These ideas have emerged from a variety of experimental approaches, including structural biology methods (i.e. X-ray crystallography, electron paramagnetic/NMR spectroscopies and solution X-ray scattering) and advanced spectroscopic techniques that have employed the use of variable pressure kinetic methodologies, together with solvent perturbation studies (i.e. ionic strength, deuteration and viscosity). Here, we offer a personal perspective on the importance of motions to electron transfer in the cytochrome P450 reductase family of enzymes, drawing on the detailed insight that can be obtained by combining these multiple structural and biophysical approaches.

Conformational changes of NADPH-cytochrome P450 oxidoreductase are essential for catalysis and cofactor binding

The crystal structure of NADPH-cytochrome P450 reductase (CYPOR) implies that a large domain movement is essential for electron transfer from NADPH via FAD and FMN to its redox partners. To test this hypothesis, a disulfide bond was engineered between residues Asp(147) and Arg(514) in the FMN and FAD domains, respectively. The cross-linked form of this mutant protein, designated 147CC514, exhibited a significant decrease in the rate of interflavin electron transfer and large (≥90%) decreases in rates of electron transfer to its redox partners, cytochrome c and cytochrome P450 2B4. Reduction of the disulfide bond restored the ability of the mutant to reduce its redox partners, demonstrating that a conformational change is essential for CYPOR function. The crystal structures of the mutant without and with NADP(+) revealed that the two flavin domains are joined by a disulfide linkage and that the relative orientations of the two flavin rings are twisted ∼20° compared with the wild type, decreasing the surface contact area between the two flavin rings. Comparison of the structures without and with NADP(+) shows movement of the Gly(631)-Asn(635) loop. In the NADP(+)-free structure, the loop adopts a conformation that sterically hinders NADP(H) binding. The structure with NADP(+) shows movement of the Gly(631)-Asn(635) loop to a position that permits NADP(H) binding. Furthermore, comparison of these mutant and wild type structures strongly suggests that the Gly(631)-Asn(635) loop movement controls NADPH binding and NADP(+) release; this loop movement in turn facilitates the flavin domain movement, allowing electron transfer from FMN to the CYPOR redox partners.

NADPH-cytochrome P450 oxidoreductase from the chicken (Gallus gallus): sequence characterization, functional expression and kinetic study

Cytochrome P450 monooxygenases have been well known to be responsible for the synthesis of endogenous compounds and the metabolism of exogenous compounds in almost all living organisms, which require NADPH-cytochrome P450 oxidoreductase (POR) as an electron donor to function. In this study, a 2031 bp open reading frame of POR gene was cloned from 35-day-old Roman hen liver, encoding an enzyme of 676 amino acids. Sequence analysis showed that chicken POR shares high homology with other vertebrates PORs and possesses the conserved binding domains of FAD, FMN, and NADPH. The genomic sequences of POR genes from chicken and other four vertebrates have highly conserved exon/intron organization structure. By fusion with bacterial signal peptide, chicken POR gene was functionally expressed in E. coli membrane and showed activities in reduction of cytochrome c and oxidation of NADPH. The Km values for cytochrome c and NADPH were 21.9 ± 2.3 μM and 2.4 ± 0.3 μM respectively. A Ping-Pong mechanism was proposed for chicken POR.

Mosquito NADPH-cytochrome P450 oxidoreductase: kinetics and role of phenylalanine amino acid substitutions at leu86 and leu219 in CYP6AA3-mediated deltamethrin metabolism

The NADPH-cytochrome P450 oxidoreductase (CYPOR) enzyme is a membrane-bound protein and contains both FAD and FMN cofactors. The enzyme transfers two electrons, one at a time, from NADPH to cytochrome P450 enzymes to function in the enzymatic reactions. We previously expressed in Escherichia coli the membrane-bound CYPOR (flAnCYPOR) from Anopheles minimus mosquito. We demonstrated the ability of flAnCYPOR to support the An. minimus CYP6AA3 enzyme activity in deltamethrin degradation in vitro. The present study revealed that the flAnCYPOR purified enzyme, analyzed by a fluorometric method, readily lost its flavin cofactors. When supplemented with exogenous flavin cofactors, the activity of flAnCYPOR-mediated cytochrome c reduction was increased. Mutant enzymes containing phenylalanine substitutions at leucine residues 86 and 219 were constructed and found to increase retention of FMN cofactor in the flAnCYPOR enzymes. Kinetic study by measuring cytochrome c-reducing activity indicated that the wild-type and mutant flAnCYPORs followed a non-classical two-site Ping-Pong mechanism, similar to rat CYPOR. The single mutant (L86F or L219F) and double mutant (L86F/L219F) flAnCYPOR enzymes, upon reconstitution with the An. minimus cytochrome P450 CYP6AA3 and a NADPH-regenerating system, increased CYP6AA3-mediated deltamethrin degradation compared to the wild-type flAnCYPOR enzyme. The increased enzyme activity could illustrate a more efficient electron transfer of AnCYPOR to CYP6AA3 cytochrome P450 enzyme. Addition of extra flavin cofactors could increase CYP6AA3-mediated activity supported by wild-type and mutant flAnCYPOR enzymes. Thus, both leucine to phenylalanine substitutions are essential for flAnCYPOR enzyme in supporting CYP6AA3-mediated metabolism.

Decavanadate interacts with microsomal NADH oxidation system and enhances cytochrome c reduction

Oxidation of NADH with accompanying oxygen consumption (NADH:O(2) = 1:1) was observed in the combined presence of metavanadate (MV), decavanadate (DV) and microsomes. Oxygen consumption was negligible in the absence of MV, but NADH was oxidized and DV was reduced to a form of vanadyl-V(IV), colored blue like vanadyl sulfate but differed from it in having a 23-fold higher absorbance at 700 nm. DV can interact with the NADH oxidation system of microsomes as an electron acceptor, in addition to the known ferricyanide and cytochrome c. DV enhances rate of cytochrome c reduction significantly at microM concentrations. These studies indicate potential of DV as a redox intermediate.

NADPH-cytochrome P450 oxidoreductase from the mosquito Anopheles minimus: kinetic studies and the influence of Leu86 and Leu219 on cofactor binding and protein stability

NADPH-cytochrome c oxidoreductase from the mosquito Anopheles minimus lacking the first 55 amino acid residues was expressed in Escherichia coli. The purified enzyme loses FMN, leading to an unstable protein and subsequent aggregation. To understand the basis for the instability, we constructed single and triple mutants of L86F, L219F, and P456A, with the first two residues in the FMN domain and the third in the FAD domain. The triple mutant was purified in high yield with stoichiometries of 0.97 FMN and 0.55 FAD. Deficiency in FAD content was overcome by addition of exogenous FAD to the enzyme. Both wild-type and the triple mutant follow a two-site Ping-Pong mechanism with similar kinetic constants arguing against any global structural changes. Analysis of the single mutants indicates that the proline to alanine substitution has no impact, but that both leucine to phenylalanine substitutions are essential for FMN binding and maximum stability of the enzyme.

The journey from NADPH-cytochrome P450 oxidoreductase to nitric oxide synthases

This mini-review will reflect the perspective of its author on two fields of research, which have merged as the result of the insights of investigators whose work has influenced both areas immeasurably. It cannot be overlooked, however, that the research activities of many during a period of over five decades have produced the chemical and biological bases for the exciting discoveries now encompassing the cytochromes P450 and their redox partners, and the three isoforms of nitric oxide synthase as they function in their respective biological milieux. Following the remarkable discovery that, indeed, molecular oxygen can be adducted to organic molecules by enzymatic systems and that such processes require a supply of reducing equivalents, it is the purpose of this review to provide a chart, with some of its detours, of the road that followed in the pursuit of interesting biological phenomena involving these two major oxygenation systems. It is not intended to be a balanced review and apologies must be offered in advance to those whose contributions may be overlooked or simply were not directly germane to the development of the author's journey.

Recruitment of governing elements for electron transfer in the nitric oxide synthase family

At least three building blocks are responsible for the molecular basis of the modulation of electron transfer in nitric oxide synthase (NOS) isoforms: the calmodulin-binding sequence, the C-terminal extension, and the autoregulatory loop in the reductase domain. We have attempted to impart the control conferred by the C termini of NOS to cytochrome P450 oxidoreductase (CYPOR), which contains none of these regulatory elements. The effect of these C termini on the properties of CYPOR sheds light on the possible evolutionary origin of NOS and addresses the recruitment of new peptides on the development of new functions for CYPOR. The C termini of NOSs modulate flavoprotein-mediated electron transfer to various electron acceptors. The reduction of the artificial electron acceptors cytochrome c, 2,6-dichlorophenolindophenol, and ferricyanide was inhibited by the addition of any of these C termini to CYPOR, whereas the reduction of molecular O(2) was increased. This suggests a shift in the rate-limiting step, indicating that the NOS C termini interrupt electron flux between flavin mononucleotide (FMN) and flavin adenine dinucleotide (FAD) and/or the electron acceptors. The modulation of CYPOR by the addition of the NOS C termini is also supported by flavin reoxidation and fluorescence-quenching studies and antibody recognition of the C-terminal extension. These experiments support the origin of the NOS enzymes from modules consisting of a heme domain and CYPOR or ferredoxin-NADP(+) reductase- and flavodoxin-like subdomains that constitute CYPOR, followed by further recruitment of smaller modulating elements into the flavin-binding domains.

Electron transfer by diflavin reductases

Diflavin reductases are enzymes which emerged as a gene fusion of ferredoxin (flavodoxin) reductase and flavodoxin. The enzymes of this family tightly bind two flavin cofactors, FAD and FMN, and catalyze transfer of the reducing equivalents from the two-electron donor NADPH to a variety of one-electron acceptors. Cytochrome P450 reductase (P450R), a flavoprotein subunit of sulfite reductase (SiR), and flavoprotein domains of naturally occurring flavocytochrome fusion enzymes like nitric oxide synthases (NOS) and the fatty acid hydroxylase from Bacillus megaterium are some of the enzymes of this family. In this review the results of the last decade of research are summarized, and some earlier results are reevaluated as well. The kinetic mechanism of cytochrome c reduction is analyzed in light of other results on flavoprotein interactions with nucleotides and cytochromes. The roles of the binding sites of the isoalloxazine rings of the flavin cofactors and conformational changes of the protein in electron transfer are discussed. It is proposed that minor conformational changes during catalysis can potentiate properties of the redox centers during the catalytic turnover. A function of the aromatic residue that shields the isoalloxazine ring of the FAD is also proposed.

Menadione enhances oxyradical formation in earthworm extracts: vulnerability of earthworms to quinone toxicity

NAD(P)H-cytochrome c reductase activities have been determined in the earthworms, L. rubellus and A. chlorotica, extracts. Menadione (0.35 mM, maximum concentration tested) was found to stimulate the rates of NADPH- and NADH-dependent cytochrome c reduction by three- and twofold, respectively. Superoxide dismutase (SOD) inhibited completely this menadione-mediated stimulation, suggesting that *O2- is involved in the redox cycling of menadione. However, SOD had no effect on the basal activity (activity in the absence of quinone) in the case of NADH-dependent cytochrome c reduction, whereas it partially inhibited the basal activity of NADPH-cytochrome c reduction. This indicates direct electron transfer in the former case and the formation of superoxide anion in the latter. DT-diaphorase, measured as the dicumarol-inhibitable part of menadione reductase activity, was not detectable in the earthworms' extracts. In contrast, it was found that DT-diaphorase represents about 70% of the menadione reductase activities in the freshwater mussel, Dreissena polymorpha. The results of this work suggest that earthworms, compared with mussels, could be more vulnerable to oxidative stress from quinones due to lack, or very low level of DT-diaphorase, an enzyme considered to play a significant role in the detoxification of quinones. On the contrary, mussels have efficient DT-diaphorase, which catalyzes two-electron reduction of menadione directly to hydroquinone, thus circumventing the formation of semiquinone.

Characterization of hydride transfer to flavin adenine dinucleotide in neuronal nitric oxide synthase reductase domain: geometric relationship between the nicotinamide and isoalloxazine rings

Based on the similarity in both structure and function of the reductase domain of neuronal nitric oxide synthase (nNOSred) to that of NADPH-cytochrome P450 reductase (CPR), we determined whether the characteristics of hydride transfer from NADPH to flavin adenine dinucleotide (FAD) were similar for both proteins. Secondly, we questioned whether hydride transfer from NADPH to either nNOSred or holo-nNOS was rate limiting for reactions catalyzed by these two proteins. Utilizing 500 MHz proton NMR and deuterated substrate, we determined that the stereospecificity of hydride transfer from NADPH and the conformation of the nicotinamide ring around the glycosidic bond were similar between CPR and nNOSred. Specifically, nNOSred abstracts the A-side hydrogen from NADPH, and the nicotinamide ring is in the anti conformation. We determined that the rate of hydride transfer to FAD appears to become partially rate limiting only for exceptionally good electron acceptors such as cytochrome c. Hydride transfer is not rate limiting for NO. production under any conditions used in this study. Interestingly, the deuterium isotope effect was decreased in the cytochrome c reductase assay with both nNOS and nNOSred when the assays were conducted in high ionic strength buffer, suggesting an increase in the rate of hydride transfer to FAD. These results are in stark contrast to results obtained with CPR (D. S. Sem and C. B. Kasper, 1995, Biochemistry 34, 3391-3398) whereby hydride transfer is partially rate limiting at high, but not at low, ionic strength. The seemingly opposite results in deuterium isotope effect observed with CPR and nNOSred, under conditions of high and low ionic strength, suggest differences in structure and/or regulation of these important flavoproteins.

Roles of oxygen radical production and lipid peroxidation in the cytotoxicity of cephaloridine on cultured renal epithelial cells (LLC-PK1)

To clarify the mechanism of cephalosporin nephrotoxicity, the cytotoxic effects of cephaloridine (CER), a nephrotoxic cephalosporin antibiotic, on the pig kidney proximal tubular epithelial cell line (LLC-PK1) were studied in culture. CER increased the content of hydrogen peroxide and decreased the activity of catalase in the treated cells, followed by an increase in the content of lipid peroxide and decreases in both glutathione peroxidase activity and in the non-protein sulfhydryl content. The levels of NADPH-dependent hydrogen peroxide and superoxide anion production by microsomes prepared from LLC-PK1 cells, and by NADPH-cytochrome P-450 reductase purified from the rat renal cortex were significantly increased by paraquat. The production of these molecules was antagonized by p-chloromer-curibenzoate, an inhibitor of NADPH-cytochrome P-450 reductase. On the other hand, CER did not significantly affect the production of hydrogen peroxide or superoxide anions. These results suggested that the cytotoxic effect of CER on cultured LLC-PK1 cells was due to the increases in hydrogen peroxide and lipid peroxide levels and not microsomal oxygen radical production, and that the mechanism of this cytotoxicity is very different from that of paraquat which induces microsomal oxygen radical production.

One-electron reduction of quinones by the neuronal nitric-oxide synthase reductase domain

Flavin electron transferases can catalyze one- or two-electron reduction of quinones including bioreductive antitumor quinones. The recombinant neuronal nitric oxide synthase (nNOS) reductase domain, which contains the FAD-FMN prosthetic group pair and calmodulin-binding site, catalyzed aerobic NADPH-oxidation in the presence of the model quinone compound menadione (MD), including antitumor mitomycin C (Mit C) and adriamycin (Adr). Calcium/calmodulin (Ca2+/CaM) stimulated the NADPH oxidation of these quinones. The MD-mediated NADPH oxidation was inhibited in the presence of NAD(P)H:quinone oxidoreductase (QR), but Mit C- and Adr-mediated NADPH oxidations were not. In anaerobic conditions, cytochrome b5 as a scavenger for the menasemiquinone radical (MD*-) was stoichiometrically reduced by the nNOS reductase domain in the presence of MD, but not of QR. These results indicate that the nNOS reductase domain can catalyze a only one-electron reduction of bivalent quinones. In the presence or absence of Ca2+/CaM, the semiquinone radical species were major intermediates observed during the oxidation of the reduced enzyme by MD, but the fully reduced flavin species did not significantly accumulate under these conditions. Air-stable semiquinone did not react rapidly with MD, but the fully reduced species of both flavins, FAD and FMN, could donate one electron to MD. The intramolecular electron transfer between the two flavins is the rate-limiting step in the catalytic cycle [H. Matsuda, T. Iyanagi, Biochim. Biophys. Acta 1473 (1999) 345-355). These data suggest that the enzyme functions between the 1e- <==> 3e- level during one-electron reduction of MD, and that the rates of quinone reductions are stimulated by a rapid electron exchange between the two flavins in the presence of Ca2+/CaM.

Calmodulin activates intramolecular electron transfer between the two flavins of neuronal nitric oxide synthase flavin domain

The neuronal NO synthase (nNOS) flavin domain, which has similar redox properties to those of NADPH-cytochrome P450 reductase (P450R), contains binding sites for calmodulin, FAD, FMN, and NADPH. The aim of this study is to elucidate the mechanism of activation of the flavin domain by calcium/calmodulin (Ca(2+)/CaM). In this study, we used the recombinant nNOS flavin domains, which include or delete the calmodulin (CaM)-binding site. The air-stable semiquinone of the nNOS flavin domains showed similar redox properties to the corresponding FAD-FMNH(&z.ccirf;) of P450R. In the absence or presence of Ca(2+)/CaM, the rates of reduction of an FAD-FMN pair by NADPH have been investigated at different wavelengths, 457, 504 and 590 nm by using a stopped-flow technique and a rapid scan spectrophotometry. The reduction of the oxidized enzyme (FAD-FMN) by NADPH proceeds by both one-electron equivalent and two-electron equivalent mechanisms, and the formation of semiquinone (increase of absorbance at 590 nm) was significantly increased in the presence of Ca(2+)/CaM. The air-stable semiquinone form of the enzyme was also rapidly reduced by NADPH. The results suggest that an intramolecular one-electron transfer between the two flavins is activated by the binding of Ca(2+)/CaM. The F(1)H(2), which is the fully reduced form of the air-stable semiquinone, can donate one electron to the electron acceptor, cytochrome c. The proposed mechanism of activation by Ca(2+)/CaM complex is discussed on the basis of that provided by P450R.

Mechanism of cytochrome P450 reductase from the house fly: evidence for an FMN semiquinone as electron donor

The interaction of recombinant house fly (Musca domestica) P450 reductase with NADPH and the role of the FMN semiquinone in reducing cytochrome c have been investigated. House fly P450 reductase can rapidly oxidize only one molecule of NADPH, whereas the rate of oxidation of a second molecule of NADPH is too slow to account for the observed rates of catalysis. This demonstrates that house fly P450 reductase does not require a priming reaction with NADPH for catalysis. Kinetics of cytochrome c reduction and EPR spectroscopy revealed that the enzyme forms two types of neutral FMN semiquinone. One serves as the catalytic intermediate of cytochrome c reduction, and another one is an 'airstable' semiquinone, which reduces cytochrome c 3000 times more slowly. The results show that the reduction state of the house fly P450 reductase during catalysis cycles in a 0-2-1-0 sequence.

Kinetic mechanism of cytochrome P450 reductase from the house fly (Musca domestica)

Recombinant house fly (Musca domestica) cytochrome P450 reductase has been purified by anion exchange and affinity chromatography. Steady-state kinetics of cytochrome c reductase activity revealed a random Bi-Bi mechanism with formation of a ternary P450 reductase-NADPH-electron acceptor complex as catalytic intermediate. NADP(H) binding is essential for fast hydride ion transfer to FAD, as well as for electron transfer from FMN to cytochrome c. Reduced cytochrome c had no effect on the enzyme activity, while NADP+ and 2'-AMP inhibited P450 reductase competitively with respect to NADPH and noncompetitively with respect to cytochrome c. The affinity of the P450 reductase to NADPH is 10 times higher than to NADP+ (Kd of 0.31 and 3.3 microM, respectively). Such an affinity change during catalysis could account for a +30 mV shift of the redox potential of FAD. Cys560 was substituted for Tyr by site-directed mutagenesis. This mutation decreased enzyme affinity to NADPH 35-fold by decreasing the bimolecular rate constant of nucleotide binding with no detectable effect on the kinetic mechanism. The affinity of the C560Y mutant enzyme to NADP+ decreased 9-fold compared to the wild-type enzyme, while the affinity to 2'-AMP was not significantly affected, suggesting that Cys560 is located in the nicotinamide binding site of the active, full-size enzyme in solution.

Mechanistic studies on the reductive half-reaction of NADPH-cytochrome P450 oxidoreductase

Site-directed mutagenesis has been employed to study the mechanism of hydride transfer from NADPH to NADPH-cytochrome P450 oxidoreductase. Specifically, Ser457, Asp675, and Cys630 have been selected because of their proximity to the isoalloxazine ring of FAD. Substitution of Asp675 with asparagine or valine decreased cytochrome c reductase activities 17- and 677-fold, respectively, while the C630A substitution decreased enzymatic activity 49-fold. Earlier studies had shown that the S457A mutation decreased cytochrome c reductase activity 90-fold and also lowered the redox potential of the FAD semiquinone (Shen, A., and Kasper, C. B. (1996) Biochemistry 35, 9451-9459). The S457A/D675N and S457A/D675N/C630A mutants produced roughly multiplicative decreases in cytochrome c reductase activity (774- and 22000-fold, respectively) with corresponding decreases in the rates of flavin reduction. For each mutation, increases were observed in the magnitudes of the primary deuterium isotope effects with NADPD, consistent with decreased rates of hydride transfer from NADPH to FAD and an increase in the relative rate limitation of hydride transfer. Asp675 substitutions lowered the redox potential of the FAD semiquinone. In addition, the C630A substitution shifted the pKa of an ionizable group previously identified as necessary for catalysis (Sem, D. S., and Kasper, C. B. (1993) Biochemistry 32, 11539-11547) from 6.9 to 7.8. These results are consistent with a model in which Ser457, Asp675, and Cys630 stabilize the transition state for hydride transfer. Ser457 and Asp675 interact to stabilize both the transition state and the FAD semiquinone, while Cys630 interacts with the nicotinamide ring and the fully reduced FAD, functioning as a proton donor/acceptor to FAD.

Inhibition of NADPH-cytochrome P450 reductase and glyceryl trinitrate biotransformation by diphenyleneiodonium sulfate

We reported previously that the flavoprotein inhibitor diphenyleneiodonium sulfate (DPI) irreversibly inhibited the metabolic activation of glyceryl trinitrate (GTN) in isolated aorta, possibly through inhibition of vascular NADPH-cytochrome P450 reductase (CPR). We report that the content of CPR represents 0.03 to 0.1% of aortic microsomal protein and that DPI caused a concentration- and time-dependent inhibition of purified cDNA-expressed rat liver CPR and of aortic and hepatic microsomal NADPH-cytochrome c reductase activity. Purified CPR incubated with NADPH and GTN under anaerobic, but not aerobic conditions formed the GTN metabolites glyceryl-1,3-dinitrate (1,3-GDN) and glyceryl-1,2-dinitrate (1,2-GDN). GTN biotransformation by purified CPR and by aortic and hepatic microsomes was inhibited > 90% after treatment with DPI and NADPH. DPI treatment also inhibited the production of activators of guanylyl cyclase formed by hepatic microsomes. We also tested the effect of DPI on the hemodynamic-pharmacokinetic properties of GTN in conscious rats. Pretreatment with DPI (2 mg/kg) significantly inhibited the blood pressure lowering effect of GTN and inhibited the initial appearance of 1,2-GDN (1-5 min) and the clearance of 1,3-GDN. These data suggest that the rapid initial formation of 1,2-GDN is related to mechanism-based GTN biotransformation and to enzyme systems sensitive to DPI inhibition. We conclude that vascular CPR is a site of action for the inhibition by DPI of the metabolic activation of GTN, and that vascular CPR is a novel site of GTN biotransformation that should be considered when investigating the mechanism of GTN action in vascular tissue.

Effect of DIMBOA on growth and digestive physiology of Sesamia nonagrioides (Lepidoptera: noctuidae) larvae

The hydroxamic acid 2,4-dihydroxy-7-methoxy-1,4-benzoxazin-3-one (DIMBOA) was assessed for its effect on growth and digestive physiology of larvae of the stalk corn borer Sesamia nonagrioides Lef. Nutritional indices and activities of some digestive and detoxification enzymes were determined for larvae feeding on a DIMBOA-containing diet for the first two days of the third instar (short-term feeding assays), and from neonates to third instar (long-term feeding assays). DIMBOA reduced the relative growth rate and the efficiency of conversion of ingested food without affecting the relative consumption rate in long-term feeding assays, but it had no effect in short-term assays. Moreover, elastase-like activity was significantly increased by DIMBOA in short-term feeding assays, whereas microsomal oxidase activity was increased and esterase activity was reduced in long-term feeding assays. In vitro, DIMBOA inhibited the activities of carboxypeptidases, aminopeptidase, glutathione S-transferase and esterase, but it had no effect on trypsin, chymotrypsin and elastase. The implications of the altered levels of proteases and detoxification enzyme activities on the digestive physiology of larvae feeding on DIMBOA-containing diets are discussed.

p32 protein, a splicing factor 2-associated protein, is localized in mitochondrial matrix and is functionally important in maintaining oxidative phosphorylation

Human p32, originally cloned as a splicing factor 2-associated protein, has been reported to interact with a variety of molecules including human immunodeficiency virus Tat and complement 1q (C1q). p32 protein is supposed to be in the nucleus and on the plasma membrane for the association with human immunodeficiency virus Tat and C1q, respectively. None of the interactions, however, is proven to have a physiological role. To investigate the physiological function of p32, we determined the intracellular localization of p32. The fractionation of cells, fluorescent immunocytochemistry, and electron microscopic immunostaining show that p32 is exclusively localized in the mitochondrial matrix. We cloned a Saccharomyces cerevisiae homologue of human p32 gene, referred to yeast p30 gene. The yeast p30 protein is also localized in the mitochondrial matrix. The disruption of the p30 gene caused the growth retardation of yeast cells in a glycerol medium but not in a glucose medium, i.e. the impairment of the mitochondrial ATP synthesis. The growth impairment was restored by the introduction of the human p32 cDNA, indicating that p30 is a functional yeast counterpart of human p32. Taken together, both p32 and p30 reside in mitochondrial matrix and play an important role in maintaining mitochondrial oxidative phosphorylation.

Domain-domain interaction in cytochrome P450BM-3

The influence of ionic strength on the interactions between individually expressed functional domains of cytochrome P450BM-3 and the domains in the holoenzyme has been analyzed by spectrophotometric and fluorometric techniques. High ionic strength facilitated electron transfer from NADPH to the FMN moiety of the reductase domain (BMR) of P450BM-3 and did not affect the first electron transfer from FMN to the heme in the holoenzyme. The cytochrome c reductase activity of the holoenzyme was higher than that of BMR within the range of ionic strength tested. Two electron reduced FMN, ie incapable of transferring electrons to the heme iron of P450BM-3, was found to be capable of reducing cytochrome c. Fluorometric studies of the domains of P450BM-3 revealed that: 1) fluorescence of FAD is completely quenched in the FAD-binding domain; 2) BMR gives the highest quantum yield which is 2.5 times higher than that of the FMN-binding domain alone; 3) the heme domain (BMP) quenches a half and three-fourths of the fluorescence of the FMN in the linked BMP/FMN-binding domain and in the holoenzyme, respectively; 4) maximal quenching of the flavin fluorescence in the mixtures containing different combinations of the functional domains of P450BM-3 was observed at high ionic strength. The results indicate that the flavins in P450BM-3 are not in close proximity. Moreover, the presence of the FAD domain causes structural changes in the FMN domain resulting in an increase in the polarity of the FMN environment in BMR and may promote the interaction between FMN- and heme-binding domains in P450BM-3. Such domain interaction may facilitate the delivery of electrons from the FMN semiquinone to the heme and prevent the formation of the inactive two electron reduced species of the FMN. Thus, the high turnover number of P450BM-3 and tight coupling of the monooxygenation reaction are provided not only by the mechanism of reduction of the heme by the reductase but also by domain-domain interaction.

NADPH-P-450 reductase: structural and functional comparisons of the eukaryotic and prokaryotic isoforms

The comparison of the properties of microsomal NADPH-P-450 reductase and the flavoprotein domain of P-450BM-3 (BMR) has revealed a significant difference in the mechanism of reduction of the hemoprotein P-450 by these flavoproteins. Microsomal NADPH-P-450 reductase transfers electrons to the hemoprotein by shuttling between hydroquinone and semiquinone forms of the FMN delivering one electron per cycle. Since the microsomal NADPH-P450 reductase has evolved as a component of multi-enzyme system, this type of mechanism may permit regulation of the steps of the P-450 reaction via variation in the affinity of the reductase for different P-450s, interaction with cytochrome b5, etc. In contrast, in the soluble, bacterial flavocytochrome P-450BM-3, the reductase domain has evolved together with a single unique heme domain. This enzyme was found to utilize the fastest and simplest way to reduce the heme iron, with the FMN moiety of BMR shuttling between the semiquinone and oxidized states. This mechanism of reduction provides the highest turnover number of any P-450 and tight coupling of the monooxygenation reaction. While there are clear differences in the intermediates involved in the reduction of P-450s by these two enzymes, the domain structure and presumably the mode of interaction between the reductase and P-450s has been maintained over evolutionary time.

Kinetic mechanism for the model reaction of NADPH-cytochrome P450 oxidoreductase with cytochrome c

The kinetic mechanism of NADPH-cytochrome P450 oxidoreductase (P450R) has been determined for the model reaction with cytochrome c3+. Although initial velocity studies show parallel patterns, consistent with a classical (one-site) ping-pong mechanism that precludes the formation of a ternary NADPH-P450R-cytochrome c3+ complex, product and dead-end inhibition results suggest a nonclassical (two-site) ping-pong mechanism [Northrop, D. B. (1969) J. Biol. Chem. 244, 5808-5819]. This mechanism is a hybrid of the random sequential (ternary complex) and ping-pong mechanisms, since ternary complexes can form as well as intermediate, modified forms of the enzyme that can be present in the absence of any bound substrate. The complete rate equation is derived for this mechanism, and values for Vmax, (V/K)NADPH, (V/K)cytc, and the corresponding Michaelis constants are presented in terms of microscopic rate constants along with the expected product inhibition patterns (Appendix). Inhibition by NADP+ is competitive versus NADPH and uncompetitive versus cytochrome c3+, while inhibition by cytochrome c2+ is competitive versus cytochrome c3+ and noncompetitive versus NADPH. These inhibition patterns are consistent with the proposed two-site mechanism. This mechanism would give the same initial velocity patterns as the classical one-site ping-pong mechanism, but it allows for the formation of a ternary complex, with NADPH and cytochrome c3+ reacting independently at two separate sites on P450R. The D(V/K)NADPH isotope effect is not affected by cytochrome c3+ concentration, consistent with our assumption (in deriving the rate equation) that binding at the two sites is independent. At the high ionic strength used in this study (850 mM), the mechanism is two-site ping-pong, with the electron acceptor site itself reacting with cytochrome c3+ in a tetra uni ping-pong manner.

Enzyme-substrate binding interactions of NADPH-cytochrome P-450 oxidoreductase characterized with pH and alternate substrate/inhibitor studies

The pH dependence of the kinetic parameters for the reaction catalyzed by NADPH-cytochrome P-450 oxidoreductase (P-450R) has been determined, using various substrates and inhibitors. All Vmax and (V/K) profiles show pKas of 6.2-7.3, for an acidic group that is preferentially unprotonated for catalysis, and of 8.1-9.6, for a basic group that is preferentially protonated for catalysis. The presence of the wrong ionization state for both of these groups is tolerated more at lower ionic strength (300 mM) than at higher ionic strength (850 mM). Ionization of the basic group has a more pronounced effect on binding of substrate (cytochrome c or dichloroindophenol) than on catalysis, since ionization has only a 2-fold effect on Vmax with cytochrome c, and only a 5-fold effect on Vmax with dichloroindophenol, while (V/K) for both substrates continues to drop at high pH with no sign of reaching a plateau. Therefore, this basic group affects predominantly substrate binding and, to a lesser extent, catalysis. It is most likely located on the surface of the protein at the cytochrome c/dichloroindophenol binding site, near the FMN prosthetic group. The NADP+ pKi profile shows a pKa of 5.95 for the 2'-phosphate of NADP+, which is bound to P-450R as the dianion, and a pKa of 9.53 for an enzyme group that must be protonated in order to bind NADP+.(ABSTRACT TRUNCATED AT 250 WORDS)

Reductive metabolism of diaziquone (AZQ) in the S9 fraction of MCF-7 cells. II. Enhancement of the alkylating activity of AZQ by NAD(P)H: quinone-acceptor oxidoreductase (DT-diaphorase)

The alkylating activity of reduced diaziquone was studied by the nitrobenzylpyridine (NBP) assay and was compared to those of the parent compound and aziridine-containing N,N',N"-triethylenethiophosphoramide (Thio-TEPA). Diaziquone (AZQ) was reduced enzymatically by 2e- using S9 cell fraction from MCF-7 cells which is rich in NAA(P)H:quinone-acceptor oxidoreductase (DT-diaphorase) (QAO) activity. One electron enzymatic reduction was performed with NADPH-cytochrome c reductase. The alkylating activity of AZQ increased 3-fold when reduced by 2e-. This increase was inhibited by dicumarol, an inhibitor of QAO. In contrast, the alkylating activity of AZQ did not increase beyond that of the parent compound when reduced by 1e- using purified NADPH-cytochrome c reductase. Similar results were obtained when AZQ was reduced chemically with borohydride (2e-) and with NADPH (1e-). Anaerobic incubations of AZQ with the S9 fraction of MCF-7 cells (2e- reduction) resulted in an increase in NBP alkylation over its aerobic counterpart (1.8-fold) while maintaining the near 3-fold increase in alkylation over untreated AZQ. In contrast, AZQ incubations with NADPH-cytochrome c reductase (1e- reduction) under the same conditions did not result in an NBP alkylation increase over untreated AZQ. These results indicate that AZQ hydroquinone is most likely the responsible species for the observed alkylation of this antitumor agent to DNA and other nucleophiles. The results also suggest that NAD(P)H:quinone-acceptor oxidoreductase is a very important enzyme in the bioactivation of AZQ.

P450BM-3: reduction by NADPH and sodium dithionite

Microsomal P450s catalyze the monooxygenation of a large variety of hydrophobic compounds, including drugs, steroids, carcinogens, and fatty acids. The interaction of microsomal P450s with their electron transfer partner, NADPH-P450 reductase, during the transfer of electrons from NADPH to P450, for oxygen activation, may be important in regulating this enzyme system. Highly purified Bacillus megaterium P450BM-3 is catalytically self-sufficient and contains both the reductase and P450 domains on a single polypeptide chain of approximately 120,000 Da. The two domains of P450BM-3 appear to be analogous in their function and homologous in their sequence to the microsomal P450 system components. FAD, FMN, and heme residues are present in equimolar amounts in purified P450BM-3 and, therefore, this protein could potentially accept five electron equivalents per mole of enzyme during a reductive titration. The titration of P450BM-3 with sodium dithionite under a carbon monoxide atmosphere was complete with the addition of the expected five electron equivalents. The intermediate spectra indicate that the heme iron is reduced first, followed by the flavin residues. Titration of the protein with the physiological reductant, NADPH, also required approximately five electron equivalents when the reaction was performed under an atmosphere of carbon monoxide. Under an atmosphere of argon and in the absence of carbon monoxide, one of the flavin groups was reduced prior to the reduction of the heme group. The titration behavior of P450BM-3 with NADPH was surprising because no spectral changes characteristic of flavin semiquinone intermediates were observed. The results of the titration with NADPH can only be explained if (a) there was "rapid" intermolecular electron transfer between P450BM-3 molecules, (b) there is no kinetic barrier to the reduction of P450 by the one-electron-reduced form of the reductase, and (c) the "air-stable semiquinone" form of the reductase does not accumulate in this complex multidomain enzyme.

The reductive metabolism of diaziquone (AZQ) in the S9 fraction of MCF-7 cells: free radical formation and NAD(P)H: quinone-acceptor oxidoreductase (DT-diaphorase) activity

The S9 fraction of MCF-7 human breast carcinoma cells has NAD(P)H (quinone-acceptor) oxidoreductase activity as measured by the reduction of dichlorophenol-indophenol (DCPIP). This reduction is dependent on the activators Tween-20 and bovine serum albumin and it is inhibitable by dicumarol. The S9 fraction also has cytochrome c reductase activity which is approximately 29 times less than the two-electron reduction activity of NAD(P)H (quinone-acceptor) oxidoreductase. Diaziquone (AZQ) is a substrate for this NAD(P)H oxidoreductase active S9 fraction as judged by its enzymatic reduction detected spectrophotometrically and by electron spin resonance spectroscopy. Two-electron mediated enzymatic reduction of AZQ was evidenced by the formation of the colorless dihydroquinone (AZQH2) which could be followed at 340 nm. The production of the dihydroquinone was inhibitable by dicumarol implicating NAD(P)H oxidoreductase in its formation. Under aerobic conditions, electron spin resonance spectroscopy showed evidence for the production of AZQ semiquinone (AZQH) and oxygen radicals. Under anaerobic conditions no oxygen radicals were observed, but the semiquinone was stable for hours. These results are also inhibitable by dicumarol and suggest a two-step one-electron oxidation process of the dihydroquinone. The production of semiquinone and oxygen radicals as detected by electron spin resonance spectroscopy was more sensitive to dicumarol when NADPH was used as cofactor (68% inhibition of OH and 65% inhibition of AZQH) than when NADH was used (28% inhibition of OH and 5% inhibition of AZQH). This suggests that NADH flavin reductases play a more important role in the one-electron reduction pathway of AZQ in MCF-7 S9 fraction than NADPH reductases. The reduction of AZQ by NAD(P)H (quinone-acceptor) oxidoreductase may play an important role in the bioreductive alkylating properties of AZQ.

The pentose phosphate pathway in skeletal muscle under patho-physiological conditions. A combined histochemical and biochemical study

Over the last 30 years, research into the neuromuscular apparatus, has expanded greatly. Multidisciplinary investigations have rapidly advanced our understanding both of diseases and of the basic neuromuscular mechanisms. The mode of pathological reaction of the neuromuscular apparatus is now quite well understood. The most notable aspect of the reaction of the injured neuromuscular apparatus is the remarkably stereotyped character of the resulting pathological changes as demonstrated by a wide variety of harmful causes, producing surprisingly similar effects. The findings of our combined histochemical and biochemical investigations presented in this monograph, are in complete harmony with the stereotyped character of the pathological changes. For example, it is particularly striking that many affected muscle fibres of patients with muscular dystrophies, congenital myopathies, inflammatory myopathies, metabolic myopathies, endocrine myopathies, or with diseases of the lower motor neuron, display an enhanced activity of both oxidative enzymes of the pentose phosphate pathway. Likewise, we found that experimental animals with disordered skeletal muscles, provoked by different types of agents or treatments, reveal the same marked rise in activity of GPDH and PGDH in the muscle fibres, with a positive correlation between the activity of both enzymes. Other findings of our investigations point to a positive correlation between the activity of GPDH and PGDH on the one hand and that of the non-oxidative enzymes of the pentose phosphate pathway, the enzymes TA, TK, RPI and RPE on the other hand. The rise in activity of PGDH and, in particular, of GPDH is regulated by two different mechanisms. The first represents a rapid control mechanism based on the stimulation of both oxidative enzymes of the pentose phosphate pathway by NADP+ and on their inhibition by NADPH. The other mechanism represents a long-term effect directed at the synthesis of the enzymes. It is this type of mechanism which is responsible for the rise in activity of GPDH and PGDH we observed. The findings obtained with the applied enzyme histochemical techniques clearly demonstrated that the rise in activity of both enzymes is not homogeneously distributed in the disordered skeletal muscles of man and experimental animals. For that reason, in order to obtain reliable quantitative information about enzyme activities in the muscle fibres themselves, the application of biochemical assays on a micro-scale was indispensable. The biochemical assay of enzyme activities was performed on histologically and histochemically selected dissected muscle specimens.(ABSTRACT TRUNCATED AT 400 WORDS)

A 31P-nuclear-magnetic-resonance study of NADPH-cytochrome-P-450 reductase and of the Azotobacter flavodoxin/ferredoxin-NADP+ reductase complex

31P-nuclear-magnetic-resonance spectroscopy has been employed to probe the structure of the detergent-solubilized form of liver microsomal NADPH--cytochrome-P-450 reductase. In addition to the resonances due to the FMN and FAD coenzymes, additional phosphorus resonances are observed and are assigned to the tightly bound adenosine 2'-phosphate (2'-AMP) and to phospholipids. The phospholipid content was found to vary with the preparation; however, the 2'-AMP resonance was observed in all preparations tested. In agreement with published results [Otvos et al. (1986) Biochemistry 25, 7220-7228] for the protease-solubilized enzyme, the addition of Mn(II) to the oxidized enzyme did not result in any observable line-broadening of the FMN and FAD phosphorus resonances. The phospholipid resonances, however, were extensively broadened and the line width of the phosphorus resonance assigned to the bound 2'-AMP was broadened by approximately 70 Hz. The data show that only the phosphorus moieties of the phospholipids and the 2'-AMP, but not the flavin coenzymes are exposed to the bulk solvent. Removal of the FMN moiety from the enzyme substantially alters the 31P-NMR spectrum as compared with the native enzyme. The 2'-AMP is removed from the enzyme during the FMN-depletion procedure and the pyrophosphate resonances of the bound FAD are significantly altered. Reconstitution of the FMN-depleted protein with FMN results in the restoration of the coenzyme spectral properties. Reduction of FMN to its air-stable paramagnetic semiquinone form results in broadening of the FMN and 2'-AMP resonances in the detergent-solubilized enzyme. In agreement with previous results. FMN semiquinone formation had little or no effect on the line width of the FMN phosphorus resonance for the proteolytically solubilized enzyme. 31P-NMR experiments with Azotobacter flavodoxin semiquinone, both in its free form and in a complex with spinach ferredoxin-NADP+ reductase, mimic the differential paramagnetic effects of the flavin semiquinone on the line width of the FMN phosphorus resonance, observed by comparison of the detergent-solubilized and protease-solubilized forms of the reductase. The data demonstrate that assignment of the site of flavin semiquinone formation to a particular flavin coenzyme may not always be possible by 31P-NMR experiments in multi-flavin containing enzymes.

Alpha-hydroxylation of lignoceroyl-CoA in rat brain microsomes: involvement of NADPH-cytochrome c reductase and topical distribution

1. The enzymatic mechanism of the alpha-hydroxylation of lignoceroyl-CoA, an intermediate in the synthesis of hydroxyceramide, was studied. In the presence of NADPH, sphingosine and microsomes from 20-day-old rat brain, 14C from [1-14C]lignoceroyl-CoA was incorporated into hydroxyceramide. 2. The alpha-hydroxylation of lignoceroyl-CoA in rat brain microsomes was strongly inhibited by a rabbit anti-immunoglobulin G which was prepared against rat liver microsomal NADPH-cytochrome c reductase. However, anti-immunoglobulin G against cytochrome b5 did not inhibit the alpha-hydroxylase activity. 3. The alpha-hydroxylation activity was more sensitive to trypsin treatment than was NADPH-cytochrome c reductase in rat brain microsomes. This indicates that either alpha-hydroxylase itself or an unknown factor essential in alpha-hydroxylation is highly exposed to the surface of brain microsomes.

Kinetic study of the enzyme NADPH cytochrome-C (P-450) reductase: non-Michaelian behaviour

1. Contrary to what has been accepted until now, the enzyme exhibits non-Michaelian kinetics both against NADPH and against cytochrome-c as substrates; deviations were detected that have led to the proposition of a rate equation of minimum degree 2:2. 2. A general mechanism is proposed that includes, apart from the binding of the enzyme to NADPH, the formation of an enzyme-cytochrome-c complex, both routes leading to the formation of a ternary-complex NADPH-enzyme-acceptor. 3. From the latter, a series of intermediate steps finally leads to the release of the enzyme in conditions to start a new catalytic cycle. 4. Application of the King-Altman method to this mechanism yields a kinetic equation of degree 2:2 with respect to the cytochrome-c and NADPH, in accordance with our experimental results.

Comparison of highly purified sheep liver and lung NADPH-cytochrome P-450 reductases by the analysis of kinetic and catalytic properties

1. Reductase was purified to electrophoretic homogeneity from sheep liver and lung microsomes. The specific activity of both enzymes ranged from 55 to 66 mumol cytochrome c reduced/min/mg protein. 2. Liver and lung reductases appeared to have similar kinetic and spectral properties. Km (NADPH) and Km (cytochrome c) values were calculated to be 14.3 +/- 1.23 microM and 22.2 +/- 2.78 microM for liver and 11.1 +/- 0.70 microM and 20.0 +/- 2.15 microM for lung reductase, respectively. Kinetic studies showed that cytochrome c can bind the oxidized form of the enzyme as well as its reduced form and both reductases operated through a ping-pong type mechanism. 3. These reductases cannot be distinguished on the basis of monomer molecular weights (Mr 78,000) except that the liver reductase was found to be more susceptible to proteolytic attack. 4. Both reductases supported aniline 4-hydroxylation and ethylmorphine N-demethylation reactions to the same extent in the reconstituted systems. However, sheep lung reductase appeared only 36.5 and 14.8% as effective in catalyzing benzo[a]pyrene reaction as an equivalent amount of reductase from liver in the presence of liver cytochrome P-450 and 3MC-treated rat liver cytochrome P-448, respectively.

The one-electron reduction of uroporphyrin I by rat hepatic microsomes

Uroporphyrin I, which accumulates in body tissues of congenital erythropoietic porphyria patients, can undergo an enzymatic one-electron reduction to the porphyrin anion radical when a suitable reducing cofactor is present. We have demonstrated, in the absence of light, that anaerobic microsomal incubations containing NADPH and uroporphyrin I give an electron spin resonance spectrum consistent with the enzymatic formation of a porphyrin anion free radical. This radical undergoes a second-order decay (k2 approximately 10(5) M-1 s-1) due to nonenzymatic disproportionation of the radical. Aerobic microsomal incubations were also investigated for the reduction of oxygen to superoxide by monitoring oxygen consumption and the spin-trapping of superoxide. These experiments demonstrate that electron transfer from the porphyrin radical to molecular oxygen does occur, but due to the slow formation of the radical anion, no oxygen consumption above the basal level could be detected in the microsomal incubations. The photoreduction of uroporphyrin I in aerobic and anaerobic incubations was also investigated.

Alpha-hydroxylation of lignoceroyl-CoA by a cyanide-sensitive oxygenase in rat brain microsomes

The enzymatic mechanism of alpha-hydroxylation of lignoceroyl-CoA, an intermediate in the synthesis of hydroxyceramide, was studied. In the presence of NADPH, sphingosine and microsomes from 20-day-old rat brain, 14C from [1-14C]lignoceroyl-CoA was incorporated into hydroxyceramide. Activity was linear with time (up to 40 min) and with protein (up to 0.8 mg). The apparent Km for lignoceroyl-CoA was about 10 microM. NADPH was a more efficient electron donor than NADH. Oxygen was required for activity, which increased linearly up to 20% O2. In 5 and 10% oxygen, the reaction was inhibited by 0.1 mM cyanide and by electron transfer chain inhibitors, cytochrome c, ferricyanide, menadione, and p-chloromercuriphenyl sulphonate; CO and SKF-525A had no effect. Moreover none of the inhibitors affected the formation of hydroxyceramide. Lignoceroyl-CoA alpha-hydroxylase appears to be an oxygenase requiring NADPH and oxygen, which involves cyanide-sensitive enzyme.

Localization of the free radical on the flavin mononucleotide of the air-stable semiquinone state of NADPH-cytochrome P-450 reductase using 31P NMR spectroscopy

Microsomal NADPH-cytochrome P-450 reductase is the only mammalian flavoprotein known to contain both FAD and FMN as prosthetic groups. The discovery of the air-stable semiquinone [Masters, B. S. S., Kamin, H., Gibson, Q. H., & Williams, C. H., Jr. (1965) J. Biol. Chem. 240, 921-931] and its identification as a one-electron-reduced state [Iyanagi, T., & Mason, H. S. (1973) Biochemistry 12, 2297-2308] have engendered a number of studies to elucidate its unique catalytic mechanism. In this paper, 31P NMR spectroscopy is utilized to probe the localization of the free radical in this air-stable semiquinone form and to ascertain the environments of the FAD and FMN prosthetic groups as affected by the paramagnetic ion Mn(II). Consistent with conclusions drawn from studies utilizing FMN-free reductase [Vermilion, J. L., & Coon, M. J. (1978) J. Biol. Chem. 253, 8812-8819], the free radical was shown to reside on the FMN moiety by the broadening of its characteristic resonance in the 31P NMR spectrum. In addition, the effect of the paramagnetic ion Mn(II) was determined on the four resonances attributable to FAD and FMN and the additional ones contributed by NADP+ resulting from the oxidation of the physiological reductant NADPH. The addition of Mn(II) had little effect on the line widths of the FMN and FAD signals but resulted in an increase in their intensities due to a decrease in T1 relaxation times.(ABSTRACT TRUNCATED AT 250 WORDS)