NADPH:cytochrome P-450(c) reductase: biochemical characterization in rat brain and cultured neurons and evolution of activity during development

Heteromeric complex formation between human cytochrome P450 CYP1A1 and heme oxygenase-1

P450 and heme oxygenase-1 (HO-1) receive their necessary electrons by interaction with the NADPH-cytochrome P450 reductase (POR). As the POR concentration is limiting when compared with P450 and HO-1, they must effectively compete for POR to function. In addition to these functionally required protein-protein interactions, HO-1 forms homomeric complexes, and several P450s have been shown to form complexes with themselves and with other P450s, raising the question, 'How are the HO-1 and P450 systems organized in the endoplasmic reticulum?' Recently, CYP1A2 was shown to associate with HO-1 affecting the function of both proteins. The goal of this study was to determine if CYP1A1 formed complexes with HO-1 in a similar manner. Complex formation among POR, HO-1, and CYP1A1 was measured using bioluminescence resonance energy transfer, with results showing HO-1 and CYP1A1 form a stable complex that was further stabilized in the presence of POR. The POR•CYP1A1 complex was readily disrupted by the addition of HO-1. CYP1A1 also was able to affect the POR•HO-1 complex, although the effect was smaller. This interaction between CYP1A1 and HO-1 also affected function, where the presence of CYP1A1 inhibited HO-1-mediated bilirubin formation by increasing the KmPOR•HO-1 without affecting the Vmaxapp. In like manner, HO-1 inhibited CYP1A1-mediated 7-ethoxyresorufin dealkylation by increasing the KmPOR•CYP1A1. Based on the mathematical simulation, the results could not be explained by a model where CYP1A1 and HO-1 simply compete for POR, and are consistent with the formation of a stable CYP1A1•HO-1 complex that affected the functional characteristics of both moieties.

Lipoxygenase-Mediated N-Demethylation of Imipramine and Related Tricyclic Antidepressants in the Presence of Hydrogen Peroxide

In this study, we examined the ability of soybean lipoxygenase to mediate the N-demethylation of imipramine and related drugs in the presence of hydrogen peroxide. Formaldehyde generation resulting from the N-demethylation of imipramine, a prototype drug, was found to depend on incubation time, and the concentration of the enzyme, imipramine, and hydrogen peroxide. Under optimal assay conditions, Vmax values of 14 to 18 nmol formaldehyde/min/nmol enzyme or 133 to 164 nmol formaldehyde/min/mg protein were observed. An inhibition of formaldehyde and desipramine formation by nordihydroguaiaretic acid confirmed the lipoxygenase involvement. The blockade of the reaction by glutathione, dithiothreitol, butylated hydroxyanisole (BHA), and butylated hydroxytoluene (BHT) indicated the generation of a free radical intermediate from imipramine. Desipramine, trimipramine, clomipramine, and diltiazem, but not amitriptyline and doxepin, were also oxidized, albeit at a lower rate. Collectively, the evidence gathered in this study suggests, for the first time, that tricyclic antidepressant drugs may undergo lipoxygenase-catalyzed N-demethylation.

Drug metabolizing enzyme expression in rat choroid plexus: effects of in vivo xenobiotics treatment

The presence of drug metabolizing enzymes in extrahepatic tissues such as the choroid plexus (CP) suggests that the CP, like the blood-brain barrier, affords a metabolic protection to the brain against xenobiotics. The CP, which is the principal site of formation of the cerebrospinal fluid (CSF), controls the exchange of many endogenous compounds and exogenous molecules between brain tissue and CSF. We present the changes in mRNA expression and enzymatic activities of UDP-glucuronosyltransferase, UGT1A6 isoform and NADPH-cytochrome P450 reductase, after in vitro treatment with xenobiotic molecules known to act in the liver as inducers or inhibitors of these drug metabolizing enzymes. Five study groups of male Sprague-Dawley rats were treated separately with 3-methylcholantrene (3-MC), phenobarbital (PB), dexamethasone (DEX), cyclosporine (CsA) or paraquat (PQ). Choroidal 1-naphthol glucuronidation activities were significantly induced by 3-MC and PQ administration (354 +/- 85 and 257 +/- 49 vs. 115 +/- 24 nmol/h per mg protein, in control group), whereas the other molecules were without effect. Accordingly, UGT1A6 mRNA expression, measured by RT-PCR, was 2.3-fold higher after 3-MC treatment and 2.1-fold higher after PQ administration. By contrast, reductase activities and mRNA expression remained unchanged in the isolated choroids plexus in these experimental conditions. We present for the first time evidences that the choroids plexus express transcripts for both UGT1A6 and NADPH-cytochrome P450 reductase, and their mRNA expression can be differently regulated by exogenous factors. These results emphasize that xenobiotics could modulate the biotransformation of exogenous and/or endogenous compounds in the choroids plexus, and underline the role of UGTs in the maintenance of brain homeostasis.

Inhibition of rat brain microsomal cytochrome P450-dependent dealkylation activities by an oxidative stress

There is increasing evidence that an oxidative stress not only alters cellular lipids and nucleic acids, but also numerous proteins. This oxidation results in alterations of some cellular functions, either by reversible modifications allowing a post-transcriptional regulation of enzyme activities or receptor affinities, or by irreversible modifications of the protein, triggering its inactivation and destruction. In the present work, we examined the effects of an experimental oxidative stress on rat brain microsomal cytochrome P450-dependent dealkylation activities. For that purpose, superoxide anions were produced either by the NADPH-dependent redox cycling of a quinine, menadione, or by the addition of apomorphine, which produces by autoxidation both superoxide anions and apomorphine-derived quinones. The inhibition of brain cytochrome P450-dependent alkoxyresorufin O-dealkylase activities was dependent on both menadione or apomorphine concentrations. Simultaneously, an increase of microsomal carbonyl groups was recorded. Immunoblotting characterization of brain microsomal oxidized protein was carried out, using antibodies raised against 2,4-dinitrophenylhydrazine as a reagent of protein carbonyl groups, and a revelation by a chemiluminescence method. We observed an increase in cerebral CYP1A protein oxidation, related to menadione concentration, suggesting that oxidation of cytochrome P450 protein may result in its catalytic inactivation.

Xenobiotic-mediated production of superoxide by primary cultures of rat cerebral endothelial cells, astrocytes, and neurones

Previous works of our group demonstrated that xenobiotic metabolism by brain microsomes or cultured cerebral cells may promote the formation of reactive oxygen species. In order to characterise the risk of oxidative stress to both the central nervous system and the blood-brain barrier, we measured in the present work the release of superoxide in the culture medium of rat cerebrovascular endothelial cells during the metabolism of menadione, anthraquinone, diquat or nitrofurazone. Assays were run in the same experimental conditions on primary cultures of rat neurones and astrocytes. Quinone metabolism efficiently produced superoxide, but the production of radicals during the metabolism of diquat or nitrofurazone was very low, as a probable result of their reduced transport inside the cells. In all cell types assayed, superoxide production was time- and concentration-dependent, and cultured astrocytes always produced the highest amounts of radicals. Superoxide formation by microsomes prepared from the cultured cells was decreased by immunoinhibition of NADPH-cytochrome P450 reductase or by its irreversible inhibition by diphenyliodonium chloride, suggesting the involvement of this flavoprotein in radical production. Cerebrovascular endothelial cells cultured on collagen-coated filters produced equivalent amounts of superoxide both at their luminal side and through the artificial basement membrane, suggesting that in vivo, endothelial superoxide production may endanger adjacent astrocytes and neurones.

Demonstration of a coupled metabolism-efflux process at the choroid plexus as a mechanism of brain protection toward xenobiotics

Brain homeostasis depends on the composition of both brain interstitial fluid and CSF. Whereas the former is largely controlled by the blood-brain barrier, the latter is regulated by a highly specialized blood-CSF interface, the choroid plexus epithelium, which acts either by controlling the influx of blood-borne compounds, or by clearing deleterious molecules and metabolites from CSF. To investigate mechanisms of brain protection at the choroid plexus, the blood-CSF barrier was reconstituted in vitro by culturing epithelial cells isolated from newborn rat choroid plexuses of either the fourth or the lateral ventricle. The cells grown in primary culture on semipermeable membranes established a pure polarized monolayer displaying structural and functional barrier features, (tight junctions, high electric resistance, low permeability to paracellular markers) and maintaining tissue-specific markers (transthyretin) and specific transporters for micronutriments (amino acids, nucleosides). In particular, the high enzymatic drug metabolism capacity of choroid plexus was preserved in the in vitro blood-CSF interface. Using this model, we demonstrated that choroid plexuses can act as an absolute blood-CSF barrier toward 1-naphthol, a cytotoxic, lipophilic model compound, by a coupled metabolism-efflux mechanism. This compound was metabolized in situ via uridine diphosphate glururonosyltransferase-catalyzed conjugation, and the cellular efflux of the glucurono-conjugate was mediated by a transporter predominantly located at the basolateral, i.e., blood-facing membrane. The transport process was temperature-dependent, probenecid-sensitive, and recognized other glucuronides. Efflux of 1-naphthol metabolite was inhibited by intracellular glutathione S-conjugates. This metabolism-polarized efflux process adds a new facet to the understanding of the protective functions of choroid plexuses.

Metabolic activation of dopamine o-quinones to o-semiquinones by NADPH cytochrome P450 reductase may play an important role in oxidative stress and apoptotic effects

In this study, it is shown that considerable evidence for the possible pathway by which dopamine o-quinone, o-quinone and aminochrome can be activated metabolically by NADPH cytochrome P450 reductase to high reactive semiquinones. These findings were discussed from a mechanistic standpoint as well as in terms of potential physiological implications of dopamine o-quinones and o-semiquinones' concerted action in oxidative stress and apoptotic events.

Drug metabolizing enzyme activities and superoxide formation in primary and immortalized rat brain endothelial cells

The activities of several enzymes involved in drug metabolism, NADPH-cytochrome P450 reductase, cytochrome P450 isoforms CYP1A and CYP2B, and uridine diphosphate glucuronosyltransferase (UGT) have been measured in primary cultures of rat cerebrovascular endothelial cells and in the immortalized rat brain endothelial cell line RBE4. These drug metabolizing activities were similar in the microsomes prepared from both cell types, even after 20 passages for RBE4 cells. These results were confirmed by Western immunoblotting analysis, using polyclonal antibodies raised against rat liver enzymes. The superoxide production observed during NADPH-cytochrome P450 reductase-dependent monoelectronic reduction of four xenobiotics, menadione, anthraquinone, nitrofurazone and diquat, was also investigated in these cultured cells at confluence. The rates of radical production were concentration-dependent. The superoxide formation induced by quinone metabolism was comparable in both cell cultures, and high amounts of superoxide radicals were produced even after 20 passages of RBE4 cells. On the other hand, nitrofurazone and diquat metabolism produced weak amounts of superoxide radicals in both cell types. Taken together, these results suggest that RBE4 cell line seems to constitute a valuable in vitro model for studies on the activity of some enzymatic systems involved in drug metabolism at the blood-brain barrier and the functional consequences of their activity.

Developmental expression of heme oxygenase-1 (HSP32) in rat brain: an immunocytochemical study

Heme oxygenase (HO) is a microsomal enzyme that oxidatively cleaves heme molecules to produce bile pigments, iron and carbon monoxide. In normal adult rat brain, HO-2 is the most abundant isozyme whereas HO-1 is present at very low levels except in select cell populations. Because its promoter region has NF-kB and AP-1 sites, heat-shock and heme-responsive elements, the HO-1 isozyme can be induced by a variety of stimuli. Since the expression and activity of several transcription factors such as NF-kB, Fos/Jun, and CREB show specific changes during development, we postulated that HO-1 expression may show similar developmental regulation. Using immunocytochemistry and Western blotting, this study demonstrates the development changes of HO-1 protein expression in normal brain from rats at postnatal day 7 (P7), P14, P21, and adult. Brain HO-1 immunoreactivity was highest at P7 in most brain regions including the white matter in areas of myelinogenesis, cerebral cortex, hippocampus, thalamus and hypothalamus and, in the blood vessel endothelial cells throughout the brain. In most regions, the adult pattern was reached by P21 with HO-1 protein localized almost exclusively to the dentate regions of hippocampus, some thalamic and hypothalamic nuclei, with little or no staining of endothelium, white matter and cortex. In a few select areas such as the substantia nigra, globus pallidus, ventromedial hypothalamic nucleus and the lateral preoptic nuclei area, little or no cellular HO-1 staining was observed at P7 whereas increased staining was found with maturation and adulthood. These results show that HO-1 protein expression is regulated in different cell types of specific regions of the rat brain during development.

The superoxide production mediated by the redox cycling of xenobiotics in rat brain microsomes is dependent on their reduction potential

Several exogenous molecules undergo enzymatic one-electron reduction leading to radicals which can rapidly react with molecular oxygen to form superoxide anions. We have previously shown that under aerobic conditions a significant superoxide anion production occurred during the NADPH-dependent one-electron reduction of some drugs and xenobiotics by rat brain preparations. We report here for several compounds a fairly good correlation between the reduction potentials (Epc vs. SCE) which ranged between - 230 and - 700 mV in aqueous medium (pH 7.4) or between -700 mV and -1100 mV in the aprotic solvent N,N-dimethylformamide, and the rate of superoxide anion production during their metabolism by rat brain microsomes. The data obtained suggest that the redox potential of most of the molecules assayed was related to their ability to undergo one-electron reduction mediated by flavoenzymes in the rat brain. The main range of reduction potentials corresponding to a large superoxide anion production suggests that the redox cycling of these chemicals was mediated by NADPH-cytochrome P-450 reductase. Therefore the measurement of reduction potentials of drugs and xenobiotics able to reach the brain, and chemically related to quinones, nitroaromatics, nitroheterocyclics and iminiums, may provide information both on their electron affinity and the possibility of one-electron transfer in vivo, and thus on their possible neurotoxicity due to the production of oxygenated free radicals.

Messenger RNAs encoding steroidogenic enzymes are expressed in rodent brain

Using the reverse transcription polymerase chain reaction, mRNAs encoding steroidogenic P450s as well as NADPH-cytochrome P450 reductase (P450 reductase), adrenodoxin and the transcription factor steroidogenic factor 1 (SF-1) were all detected in rodent brain, but their distribution between brain regions varied. Adrenodoxin and P450 reductase were detected in all regions, suggesting the presence of both mitochondrial and microsomal P450s throughout the brain. Messenger RNAs encoding P450scc (CYP11A1) and P45017 alpha (CYP17) were also detected in all brain regions, this being the first report of CYP17 in the brain. P450c21 (CYP21) was detected only in the brain stem. P45011 beta (CYP11B1) and P450aldo (CYP11B2) are expressed in rat brain, but not in mouse brain; CYP11B1 primarily in the cerebrum, whereas CYP11B2 was detected in all brain regions. In both species, highest levels of aromatase P450 (CYP19) mRNA were detected in the cerebrum. SF-1 expression was restricted to the cerebrum minus cortex. Thus, although SF-1 is required for high level expression of the steroidogenic enzymes in adrenals and gonads, other factors may influence the expression of these genes in the brain. If the mRNAs detected by RT-PCR are indeed translated into functional enzymes, these studies suggest that different brain regions have different capacities for local steroid hormone production and metabolism. This raises the technical challenge of locating the specific sites of synthesis as well as the function of such locally produced ligands.

Superoxide anion production during monoelectronic reduction of xenobiotics by preparations of rat brain cortex, microvessels, and choroid plexus

Brain microsomes may produce reactive metabolites during the reductive metabolism of some xenobiotics including drugs. These reactive species can, in turn, react with molecular oxygen to form superoxide radicals (O2.-). We measured the rates of superoxide production by homogenates obtained from three cerebral structures, cortex plus cerebellum, choroid plexus, and microvessels. The molecules assayed were related to quinone, nitroheterocycle, and iminium chemical families. The results we obtained showed a significant correlation between the rate of superoxide anion production and the apparent kinetic parameters (log Km/Vmax) of NADPH-cytochrome P450 reductase activity for these molecules, suggesting the involvement of this enzyme in xenobiotic-induced superoxide production.

Localization of drug-metabolizing enzyme activities to blood-brain interfaces and circumventricular organs

The brain, with the exception of the choroid plexuses and circumventricular organs, is partially protected from the invasion of blood-borne chemicals by the specific morphological properties of the cerebral micro-vessels, namely, the tight junctions of the blood-brain barrier. Recently, several enzymes that are primarily involved in hepatic drug metabolism have been shown to exist in the brain, albeit at relatively low specific activities. In the present study, the hypothesis that these enzymes are located primarily at blood-brain interfaces, where they form an "enzymatic barrier," is tested. By using microdissection techniques or a gradient-centrifugation isolation procedure, the activities of seven drug-metabolizing enzymes in isolated microvessels, choroid plexuses, meningeal membranes, and tissue from three circumventricular organs (the neural lobe of the hypophysis, pineal gland, and median eminence) were assayed. With two exceptions, the activities of these enzymes were higher in the three circumventricular organs and cerebral microvessel than in the cortex. Very high membrane-bound epoxide hydrolase and UDP-glucuronosyltransferase activities (approaching those in liver) and somewhat high 7-benzoxyresorufin-O-dealkylase and NADPH-cytochrome P-450 reductase activities were determined in the choroid plexuses. The pia-arachnoid membranes, but not the dura matter, displayed drug-metabolizing enzyme activities, notably that of epoxide hydrolase. The drug-metabolizing enzymes located at these nonparenchymal sites may function to protect brain tissue from harmful compounds.

Subcellular localization of cytochrome P450, and activities of several enzymes responsible for drug metabolism in the human brain

We studied the subcellular distribution of cytochrome P450 and related monooxygenase activities in six regions of human brains removed at autopsy. The content of total cytochrome P450 was found to be at least nine times higher in the mitochondrial fraction than in the microsomes in all the regions studied. However, cytochrome P450-dependent enzymatic activities which are representative of different isoforms metabolizing exogenous molecules exhibited a microsomal prevalence, a situation previously observed in rat brain. The other drug-metabolizing enzymes catalysing functionalization and conjugation reactions, presented the following characteristics in human brain: (i) a low activity of NADPH-cytochrome P450 reductase, which also catalyses the reduction of some xenobiotics; (ii) a high specific activity of the membrane-bound epoxide hydrolase; (iii) among the enzymes catalysing conjugation reactions, 1-naphthol-UDP-glucuronosyltransferase activity was barely or not detectable, whereas the mean glutathione-S-transferase activity was 15 times higher than the activity measured in rat brain. The presence of several drug-metabolizing enzyme activities in human brain microvessels, and particularly the high activity of epoxide hydrolase, suggests a participation of these enzymes in the metabolic blood-brain barrier.

Effect of ageing on tissue levels of amino acids involved in the nitric oxide pathway in rat brain

Nitric oxide (NO) and citrulline are produced from L-arginine by the action of NO synthase after activation of excitatory amino acid receptors. In addition to its role in neurodegeneration, there is convincing evidence that NO is also involved in long-term potentiation, a cellular analog of learning and memory in the mammalian nervous system. In the present study, concentrations of L-arginine, citrulline, aspartic acid and glutamic acid were determined in various brain regions of young and old rats. The aim was to examine whether changes in brain concentrations of these amino acids might be indicative of a possible decrease in NO production with ageing, in relation with the well-established decline of cognitive function. Brain aspartic acid, citrulline and L-arginine concentrations were found to be lower in old rats compared to young animals, although the decrease did not always reach statistical significance. In contrast, no change in glutamic acid levels was found. In all brain structures of young and old rats, concentrations of L-arginine were higher than the concentration for NO synthase to function at maximum velocity in the rat brain. Therefore, the decrease in citrulline concentrations found in some brain regions of old rats might be seen, at least partly, as a reflection of a lower production of NO with ageing, although further work is clearly needed to ascertain a decrease in rat brain NO synthase activity with age.

Brain cytochrome P450 and testosterone metabolism by rat brain subcellular fractions: presence of cytochrome P450 3A immunoreactive protein in rat brain mitochondria

The hydroxylation of testosterone by rat brain subcellular fractions has been studied using an HPLC method with an enhanced resolution for the separation of testosterone and its monohydroxy derivatives. Although the analysis time is longer than that reported for earlier methods, a baseline separation was obtained between all hydroxytestosterones, excepting 6 alpha-hydroxytestosterone and 15 beta-hydroxytestosterone, which were separated using a second chromatography system. This separation was important as rat brain microsomes metabolized testosterone to 15 alpha-, 6 beta-, 15 beta-, 16 beta-, 2 beta-, 1 beta-hydroxytestosterone and androstenedione. Testosterone metabolism was found to be linear with time and protein concentration. The rat brain mitochondrial fraction metabolized testosterone to androstenedione. Small amounts of immunoreactive bands comigrating with purified cytochromes P450j, P450b, and P450p were detected by Western blot analysis in rat brain microsomes, while only an immunoreactive protein related to cytochrome P450p was found in the mitochondrial fractions. Immunoinhibition studies showed that BEA33, a monoclonal antibody to cytochrome P450b and simultaneously recognizing cytochromes P450e and P450a, was able to inhibit the metabolism of testosterone to the 1 beta-, 15 alpha-, 2 beta-, and 6 alpha-hydroxylated metabolites, whereas polyclonal anti-cytochrome P450p did not inhibit the formation of the 6 beta-hydroxytestosterone by rat brain microsomes. The metabolism of testosterone by rat brain microsomal or mitochondrial fractions was refractory to induction by 3-methylcholanthrene or pregnenolone-16 alpha-carbonitrile. Thus, in the brain multiple isozymes of cytochrome P450 are constitutively expressed in different subcellular fractions, which suggests that brain cytochrome P450 may play an important role in the metabolism of endogenous compounds. The significance and role of cytochrome P450p-related protein in the rat brain mitochondrial fraction are yet to be determined.

Reconstitution of the brain mixed function oxidase system: purification of NADPH-cytochrome P450 reductase and partial purification of cytochrome P450 from whole rat brain

NADPH-cytochrome P450 reductase was purified to apparent homogeneity and cytochrome P450 partially purified from whole rat brain. Purified reductase from brain was identical to liver P450 reductase by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and western blot techniques. Kinetic studies using cerebral P450 reductase reveal Km values in close agreement with those determined with enzyme purified from rat liver. Moreover, the brain P450 reductase was able to function successfully in a reconstituted microsomal system with partially purified brain cytochrome P450 and with purified hepatic P450c (P450IA1) as measured by 7-ethoxycoumarin and 7-ethoxyresorufin O-deethylation. Our results indicate that the reductase and P450 components may interact to form a competent drug metabolism system in brain tissue.

Evidence for drug metabolism as a source of reactive species in the brain

Several pathways for reactive species formation involving xenobiotic metabolism exist in the brain. They include oxidative activation by different enzymatic systems like cytochrome P-450 and monoamine oxidases, and superoxide radical production issued from reductive xenobiotic metabolism. They may contribute to cellular impairment observed in various physiopathological situations.

Enzyme mediated superoxide radical formation initiated by exogenous molecules in rat brain preparations

The ability of brain tissue preparation to generate superoxide from xenobiotic interactions has been investigated. We showed that a significant superoxide production occurred with different molecules known to undergo a single electron reductive pathway of metabolism, both in a homogenate derived from neuronal and glial cells and in isolated cerebral microvessels which form the blood-brain barrier. Determination of the nucleotide cofactors requirement and data obtained with different subcellular fractions indicated that this production was largely associated with the microsomal fraction in a NADPH-dependent pathway and was probably mediated by NADPH-cytochrome P450 (c) reductase. A significant xenobiotic-mediated production of superoxide also occurred in mitochondria under in vitro conditions. Thus the evidence of reductive pathways of xenobiotic metabolism and the generation of oxygenated free radicals observed are of neurotoxicological significance.

Drug metabolizing enzymes in the brain and cerebral microvessels

Several families of brain parenchyma and microvessel endothelial cell enzymes can metabolize substrates of exogenous origin. This xenobiotic metabolism includes functionalization and conjugation reactions and results in detoxication, but also possibly in the formation of pharmacologically active or neurotoxic products. The brain is partially protected from chemical insults by the physical barrier formed by the cerebral microvasculature of endothelial cells, which prevents the influx of hydrophilic molecules. These cells provide also, as a result of their drug-metabolizing enzyme activities, a metabolic barrier against penetrating lipophilic substances. The involvement of these enzymatic activities in neurotoxic events, probably responsible for neuronal dysfunctioning and/or death, neurodegenerative diseases and normal aging, is discussed.