Cytochrome P-450 heme and the regulation of hepatic heme oxygenase activity

The degradation of cytochrome P-450 heme in the liver has been studied by a new approach. In rats, hepatic heme was labeled by administration of a tracer pulse of [5-¹⁴C]δ-aminolevulinic acid (ALA), and its degradation was analyzed in terms of labeled carbon monoxide (¹⁴CO) excretion, which is a specific degradation product of the labeled heme. Within minutes after administration of [5-¹⁴C]ALA, 14CO was detectable and increased after 2 h to an “early peak,” reflecting the elimination of labeled heme from a rapidly turning over pool in the liver. Beyond the early peak, the rate of ¹⁴CO production decreased in a log-linear manner, consistent with the degradation of heme in stable hepatic hemoproteins. From the rate at which ¹⁴CO production declined during this phase, from the predominant labeling of cytochrome P-450 heme by the administered [5-¹⁴C]ALA and from the known turnover characteristics of this hemoprotein in the liver, it could be inferred that production of ¹⁴CO—between 16 and 30 h after administration of labeled ALA—largely reflected degradation of cytochrome P-450 heme. This approach, which permits serial measurements in a single animal, was used to study the effect on cytochrome P-450 heme of administered heme or endotoxin, both of which are potent stimulators of hepatic heme oxygenase activity. Both of these substances caused marked acceleration of the degradation of cytochrome P-450 heme, the effect occurring over the same dose range as that for stimulation of hepatic heme oxygenase. The findings suggest that stimulation of this enzyme activity in the liver is closely related to the rate of degradation of cytochrome P-450 heme.     

Exogenous heme restores in vivo functional capacity of hepatic cytochrome P-450 destroyed by allylisopropylacetamide.

Administration of allylisopropylacetamide (AIA) produces a dose-related destruction of the heme moiety of the phenobarbital-induced subspecies of hepatic cytochrome P-450. This results in delayed plasma disappearance of the inactivating agent as determined after injection of [¹⁴C]AIA. In phenobarbital-pretreated rats, infusion of heme reversed this AIA-mediated impairment of the plasma disappearance of [¹⁴C]AIA. In the absence of phenobarbital pretreatment, cytochrome P-450 destruction by AIA was minimal and heme infusion failed to enhance plasma disappearance of [¹⁴C]AIA. Since exogenously administered heme is incorporated into hepatic cytochrome P-450 $\text{in vivo}$, these observations suggest that the infused heme restored the functional capacity of the phenobarbital-induced mixed function oxidase system by substituting for the prosthetic heme moiety destroyed by AIA. Heme infusion is a potentially useful therapeutic modality for enhancing drug biotransformation after intoxication with compounds that inactivate cytochrome P-450.     

Effect of ascorbic acid on heme metabolism in hepatic microsomes

Hepatic microsonal cytochrome P-450 levels are significantly decreased (46–68%) in ascorbic acid-deficient guinea pigs. Studies attempting to elucidate the mechanism responsible for decreased cytochrome P-450 demonstrated that ascorbic acid status did not influence the turnover $\text{(}\text{t}\text{1}\text{2}\text{)}$ or the degradation of hepatic cytochrome P-450 heme. Urinary excretion of Δ-aminolevulinic acid (ALA) and coproporphyrin was significantly decreased (30 and 69% respectively) in ascorbic acid-deficient guinea pigs. Injections (ip) of ALA into ascorbic acid-deficient guinea pigs were not effective in returning cytochrome P-450 levels to values found in ascorbic acid-supplemented guinea pigs. In addition, plasma and hepatic iron and blood heme were related directly, while hepatic copper and plasma copper or ceruloplasmin were related inversely, to the ascorbic-acid status of the guinea pig. These data, along with past investigations on heme synthesis in the ascorbic acid-deficient guinea pig, are consistent with mechanisms proposing that ascorbic acid may influence: 1) apocytochrome P-450 synthesis, 2) binding of heme and apo-cytochrome P-450 to form active cytochrome P-450, and/or 3) incorporation of Fe++ into the heme moiety of cytochrome P-450, perhaps via changes in copper metabolism.     

Comparing the electronic properties and docking calculations of heme derivatives on CYP2B4

Cytochrome P-450 is a group of enzymes involved in the biotransformation of many substances, including drugs. These enzymes possess a heme group (1) that when it is properly modified induces several important physicochemical changes that affect their enzymatic activity. In this work, the five structurally modified heme derivatives 2–6 and the native heme 1 were docked on CYP2B4, (an isoform of P450), in order to determine whether such modifications alter their binding form and binding affinity for CYP2B4 apoprotein. In addition, docking calculations were used to evaluate the affinity of CYP2B4 apoprotein-heme complexes for aniline (A) and N-methyl-aniline (NMA). Results showing the CYP2B4 heme 4- and heme 6-apoprotein complexes to be most energetically stable indicate that either hindrance effects or electronic properties are the most important factors with respect to the binding of heme derivatives at the heme-binding site. Furthermore, although all heme-apoprotein complexes demonstrated high affinity for both A and NMA, the CYP2B4 apoprotein-5 complex had higher affinity for A, and the heme 6 complex had higher affinity for NMA. Finally, surface electronic properties (SEP) were calculated in order to explain why certain arginine residues of CYP2B4 apoprotein interact with polarizable functionalities, such as ester groups or sp ² carbons, present in some heme derivates. The main physicochemical parameter involved in the recognition process of the heme derivatives, the CYP2B4 apoprotein and A or NMA, are reported. Figure Scheme of steps to be followed for obtaining five new CYP2B4 apoprotein-heme complexes by docking     

Global incorporation of norleucine in place of methionine in cytochrome P450 BM-3 heme domain increases peroxygenase activity

In this study we have replaced all 13 methionine residues in the cytochrome P450 BM-3 heme domain (463 amino acids) with the isosteric methionine analog norleucine. This experiment has provided a means of testing the functional limits of globally incorporating into an enzyme an unnatural amino acid in place of its natural analog, and also an efficient way to test whether inactivation during peroxide-driven P450 catalysis involves methionine oxidation. Although there was no increase in the stability of the P450 under standard reaction conditions (in 10 mM hydrogen peroxide), complete substitution with norleucine resulted in nearly two-fold-increased peroxygenase activity. Thermostability was significantly reduced. The fact that the enzyme can tolerate such extensive amino acid replacement suggests that we can engineer enzymes with unique chemical properties via incorporation of unnatural amino acids while retaining or improving catalytic properties. This system also provides a platform for directing enzyme evolution using an extended set of protein building blocks.     

The intrinsic axial ligand effect on propene oxidation by horseradish peroxidase versus cytochrome P450 enzymes

The axial ligand effect on reactivity of heme enzymes is explored by means of density functional theoretical calculations of the oxidation reactions of propene by a model compound I species of horseradish peroxidase (HRP). The results are assessed vis-à-vis those of cytochrome P450 compound I. It is shown that the two enzymatic species perform C=C epoxidation and C–H hydroxylation in a multistate reactivity scenario with Fe^III and Fe^IV electromeric situations and two different spin states, doublet and quartet. However, while the HRP species preferentially keeps the iron in a low oxidation state (Fe^III), the cytochrome P450 species prefers the higher oxidation state (Fe^IV). It is found that HRP compound I has somewhat lower barriers than those obtained by the cytochrome P450 species. Furthermore, in agreement with experimental observations and studies on model systems, HRP prefers C=C epoxidation, whereas cytochrome P450 prefers C–H hydroxylation. Thus, had the compound I species of HRP been by itself, it would have been an epoxidizing agent, and at least as reactive as cytochrome P450. In the enzyme, HRP is much less reactive than cytochrome P450, presumably because HRP reactivity is limited by the access of the substrate to compound I.Electronic Supplementary Material Supplementary material is available for this article at .The paper is dedicated to D. K. Bohme on the occasion of his forthcoming 65th birthday.     

Candida albicans NADPH-P450 reductase: Expression, purification, and characterization of recombinant protein

Candida albicans is responsible for serious fungal infections in humans. Analysis of its genome identified NCP1 gene coding for a putative NADPH-P450 reductase (NPR) enzyme. This enzyme appears to supply reducing equivalents to cytochrome P450 or heme oxygenase enzymes for fungal survival and virulence. In this study, we report the characterization of the functional features of NADPH-P450 reductase from C. albicans. The recombinant C. albicans NPR protein harboring a 6×(His)-tag was expressed heterologously in Escherichia coli, and was purified. Purified C. albicans NPR has an absorption maximum at 453 nm, indicating the feature of an oxidized flavin cofactor, which was decreased by the addition of NADPH. It also evidenced NADPH-dependent cytochrome c or nitroblue tetrazolium reducing activity. This purified reductase protein was successfully able to substitute for purified mammalian NPR in the reconstitution of the human P450 1A2-catalyzed O-deethylation of 7-ethoxyresorufin. These results indicate that purified C. albicans NPR is an orthologous reductase protein that supports cytochrome P450 or heme oxygenase enzymes in C. albicans.     

Site-Directed Mutagenesis of Cytochrome P450scc (CYP11A1). Effect of Lysine Residue Substitution on Its Structural and Functional Properties

Our previous chemical modification and cross-linking studies identified some positively charged amino acid residues of cytochrome P450scc that may be important for its interaction with adrenodoxin and for its functional activity. The present study was undertaken to further evaluate the role of these residues in the interaction of cytochrome P450scc with adrenodoxin using site-directed mutagenesis. Six cytochrome P450scc mutants containing replacements of the surface-exposed positively charged residues (Lys103Gln, Lys110Gln, Lys145Gln, Lys394Gln, Lys403Gln, and Lys405Gln) were expressed in E. coli cells, purified as a substrate-bound high-spin form, and characterized as compared to the wild-type protein. The replacement of the surface Lys residues does not dramatically change the protein folding or the heme pocket environment as judged from limited proteolysis and spectral studies of the cytochrome P450 mutants. The replacement of Lys in the N-terminal sequence of P450scc does not dramatically affect the activity of the heme protein. However, mutant Lys405Gln revealed rather dramatic loss of cholesterol side-chain cleavage activity, efficiency of enzymatic reduction in a reconstituted system, and apparent dissociation constant for adrenodoxin binding. The present results, together with previous findings, suggest that the changes in functional activity of mutant Lys405Gln may reflect the direct participation of this amino acid residue in the electrostatic interaction of cytochrome P450scc with its physiological partner, adrenodoxin.     

The P450cam G248E mutant covalently binds its prosthetic heme group

Previous studies on mammalian peroxidases and cytochrome P450 family 4 enzymes have shown that a carboxylic group positioned close to a methyl group of the prosthetic heme is required for the formation of a covalent link between a protein carboxylic acid side chain and the heme. To determine whether there are additional requirements for covalent bond formation in the P450 enzymes, a glutamic acid or an aspartic acid has been introduced into P450(cam) close to the heme 5-methyl group. Spectroscopic and kinetic studies of the resulting G248E and G248D mutants suggest that the carboxylate group coordinates with the heme iron atom, as reported for a comparable P450(BM3) mutant [Girvan, H. M., Marshall, K. R., Lawson, R. J., Leys, D., Joyce, M. G., Clarkson, J., Smith, W. E., Cheesman, M. R., and Munro, A. W. (2004) J. Biol. Chem. 279, 23274-23286]. The two P450(cam) mutants have low catalytic activity, but in contrast to the P450(BM3) mutant, incubation of the G248E (but not G248D) mutant with camphor, putidaredoxin, putidaredoxin reductase, and NADH results in partial covalent binding of the heme to the protein. No covalent attachment is observed in the absence of camphor or any of the other reaction components. Pronase digestion of the G248E P450(cam) mutant after covalent attachment of the heme releases 5-hydroxyheme, establishing that the heme is covalently attached through its 5-methyl group as predicted by in silico modeling. The results establish that a properly positioned carboxyl group is the sole requirement for autocatalytic formation of a heme-protein link in P450 enzymes, but also show that efficient covalent binding requires placement of the carboxyl close to the methyl but in a manner that prevents strong coordination to the iron atom.     

Alcohol-mediated effects on the level of cytochrome P-450 and heme biosynthesis in cultured rat hepatocytes

Interaction of alcohol and drugs in the liver appears to involve common microsomal oxidative enzymes which utilize cytochrome P-450. Since alcohol augments the toxicity of a variety of drugs, the regulation of the P-450 hemoprotein, a primary component in hepatic drug metabolizing systems, may play a vital role in this phenomenon. We utilize an adult rat liver culture system as a model to explore the action of levels of alcohol below that which is necessary to produce intoxication in humans. The addition of 16 mM ethanol (70 mg/dl) to these hepatocytes results in a 49.5% decrease in cytochrome P-450 activity after 24 h, and a 3-fold increase in the activity of δ-aminolevulinate synthase, the rate-limiting enzyme in hepatic heme biosynthesis. Furthermore, ethanol treatment also causes a transient decrease in the level of intracellular heme. However, the diminished level of total heme does not appear to act as a repressor for δ-aminolevulinate synthase, since it occurs after the initial stimulation of the enzyme by ethanol.     

Covalent attachment of the heme prosthetic group in the CYP4F cytochrome P450 family

We demonstrated earlier that the heme in cytochrome P450 enzymes of the CYP4A family is covalently attached to the protein through an I-helix glutamic acid residue [Hoch, U., and Ortiz de Montellano, P. R. (2001) J. Biol. Chem. 276, 11339-11346]. As the critical glutamic acid residue is conserved in many members of the CYP4F class of cytochrome P450 enzymes, we investigated covalent heme binding in this family of enzymes. Chromatographic analysis indicates that the heme is covalently bound in CYP4F1 and CYP4F4, which have the required glutamic acid residue, but not in CYP4F5 and CYP4F6, which do not. Catalytic turnover of CYP4F4 with NADPH-cytochrome P450 reductase shows that the heme is covalently bound through an autocatalytic process. Analysis of the prosthetic group in the CYP4F5 G330E mutant, into which the glutamic acid has been reintroduced, shows that the heme is partially covalently bound and partially converted to noncovalently bound 5-hydroxymethylheme. The modified heme presumably arises by trapping of a 5-methyl carbocation intermediate by a water molecule. CYP4F proteins thus autocatalytically bind their heme groups covalently in a process that requires a glutamic acid both to generate a reactive (cationic) form of the heme methyl and to trap it to give the ester bond.     

Covalently linked heme in cytochrome p4504a fatty acid hydroxylases

Three independent experimental methods, liquid chromatography, denaturing gel electrophoresis with heme staining, and mass spectrometry, establish that the CYP4A class of enzymes has a covalently bound heme group even though the heme is not cross-linked to the protein in other P450 enzymes. Covalent binding has been demonstrated for CYP4A1, -4A2, -4A3, -4A8, and -4A11 heterologously expressed in Escherichia coli. However, the covalent link is also present in CYP4A1 isolated from rat liver and is not an artifact of heterologous expression. The extent of heme covalent binding in the proteins as isolated varies and is substoichiometric. In CYP4A3, the heme is attached to the protein via an ester link to glutamic acid residue 318, which is on the I-helix, and is predicted to be within the active site. This is the first demonstration that a class of cytochrome P450 enzymes covalently binds their prosthetic heme group.     

Induction of hepatic heme oxygenase activity by bromobenzene

Hepatic heme oxygenase, an enzyme which converts heme to carbon monoxide and bile pigment in vitro, is inducible by heme but also by large “toxic” doses of such nonheme substances as hormones, endotoxin, and heavy metal ions. When we gave rats a single hepatotoxic dose of allyl alcohol, ethionine, acetaminophen, furosemide, or endotoxin, hepatic heme oxygenase activity rose modestly (two- to fivefold) after 20 h. In contrast, administration of bromobenzene (5 mmol/kg) induced heme oxygenase in the liver an average of 15-fold after 20 h but was without effect on the enzyme in the kidney or spleen. The change in heme oxygenase was accompanied by a loss in cytochrome P-450 concentration and, in rats labeled with 5-δ-amino[¹⁴C]levulinic acid, an increased rate of degradation of hepatic [¹⁴C]heme to ¹⁴CO. Induction of heme oxygenase by bromobenzene was blocked by cycloheximide, an inhibitor of protein synthesis, but not by actinomycin D, an inhibitor of RNA synthesis. This suggests that bromobenzene stimulates de novo enzyme synthesis at the step of translation. Subtoxic doses of bromobenzene (less than 1 mmol/kg) gave proportionately greater induction of heme oxygenase. Furthermore, induction of the enzyme remained unaffected when bromobenzene hepatotoxicity was blocked by pretreatment of rats with SKF-525A, 3-methylcholanthrene, or cysteine (which supplements liver sulfhydryl content), or when hepatotoxicity was enhanced by pretreatment with phenobarbital or with diethylmaleate (which depletes hepatic glutathione). These data suggest that with induction of heme oxygenase by bromobenzene, neither liver cell necrosis nor alteration in hepatic sulfhydryl metabolism is indispensible. The latter characteristic differs from induction of the enzyme by metal ions in which depletion of sulfhydryl-containing constituents has been thought to be essential. We conclude that bromobenzene is a novel inducer of heme oxygenase activity in the liver, differing from other nonheme substances in potency and specificity for the liver, and in utilizing mechanism(s) which require neither production of hepatotoxicity, depletion of hepatic glutathione, nor sensitivity to actinomycin D.     

Sites of covalent attachment of CYP4 enzymes to heme: evidence for microheterogeneity of P450 heme orientation

Typical cytochrome P450s secure the heme prosthetic group with a cysteine thiolate ligand bound to the iron, electrostatic interactions with the heme propionate carboxylates, and hydrophobic interactions with the heme periphery. In addition to these interactions, CYP4B1 covalently binds heme through a monoester link furnished, in part, by a conserved I-helix acid, Glu310. Chromatography, mass spectrometry, and NMR have now been utilized to identify the site of attachment on the heme. Native CYP4B1 covalently binds heme solely at the C-5 methyl position. Unexpectedly, recombinant CYP4B1 from insect cells and Escherichia coli also bound their heme covalently at the C-8 methyl position. Structural heterogeneity may be common among recombinant CYP4 proteins because CYP4A3 exhibited this duality. Attempts to evaluate functional heterogeneity were complicated by the complexity of the system. The phenomenon of covalent heme binding to P450 provides a novel method for assessing microheterogeneity in heme orientation and raises questions about the fidelity of heme incorporation in recombinant systems.     

Spectroscopic features of cytochrome P450 reaction intermediates

Cytochromes P450 constitute a broad class of heme monooxygenase enzymes with more than 11,500 isozymes which have been identified in organisms from all biological kingdoms [1]. These enzymes are responsible for catalyzing dozens chemical oxidative transformations such as hydroxylation, epoxidation, N-demethylation, etc., with very broad range of substrates [2] and [3]. Historically these enzymes received their name from ‘pigment 450’ due to the unusual position of the Soret band in UV–vis absorption spectra of the reduced CO-saturated state [4] and [5]. Despite detailed biochemical characterization of many isozymes, as well as later discoveries of other ‘P450-like heme enzymes’ such as nitric oxide synthase and chloroperoxidase, the phenomenological term ‘cytochrome P450’ is still commonly used as indicating an essential spectroscopic feature of the functionally active protein which is now known to be due to the presence of a thiolate ligand to the heme iron [6]. Heme proteins with an imidazole ligand such as myoglobin and hemoglobin as well as an inactive form of P450 are characterized by Soret maxima at 420 nm [7]. This historical perspective highlights the importance of spectroscopic methods for biochemical studies in general, and especially for heme enzymes, where the presence of the heme iron and porphyrin macrocycle provides rich variety of specific spectroscopic markers available for monitoring chemical transformations and transitions between active intermediates of catalytic cycle.     

Reversible transfer of heme between different molecular species of microsome-bound cytochrome P-450 in rat liver

Incorporation of newly synthesized heme into microsome-bound cytochrome P-450 in rat liver was not affected by cycloheximide administration to the animals, indicating that the heme incorporation into cytochrome P-450 is not tightly coupled with the synthesis of the apo-cytochrome. When the heme of microsomal cytochrome P-450 had been labeled in vivo with delta-[14C]aminolevulinic acid, and then the animals were treated with phenobarbital (PB) or 3-methylcholanthrene (MC), PB-induced or MC-induced form of cytochrome P-450 was found to contain labeled heme derived from preexistent cytochrome P-450. These observations indicated that the heme of microsome-bound cytochrome P-450 is not tightly associated with the protein portion, and exchanges reversibly between different molecular species of cytochrome P-450 in vivo.     

Site-Directed Mutagenesis of Cytochrome b5 for Studies of Its Interaction with Cytochrome P450

We have shown earlier that microsomal cytochrome b ₅ can form a specific complex with mitochondrial cytochrome P450 (cytochrome P450scc). The formation of the complex between these two heme proteins was proved spectrophotometrically, by affinity chromatography on immobilized cytochrome b ₅, and by measuring the cholesterol side-chain cleavage activity of cytochrome P450scc in a reconstituted system in the presence of cytochrome b ₅. To further study the mechanism of interaction of these heme proteins and evaluate the role of negatively charged amino acid residues Glu42, Glu48, and Asp65 of cytochrome b ₅, which are located at the site responsible for interaction with electron transfer partners, we used sitedirected mutagenesis to replace residues Glu42 and Glu48 with lysine and residue Asp65 with alanine. The resulting mutant forms of cytochrome b ₅ were expressed in E. coli, and full-length and truncated forms (shortened from the C-terminal sequence due to cleavage of 40 amino acid residues) of these cytochrome b ₅ mutants were purified. Addition of the truncated forms of cytochrome b ₅ (which do not contain the hydrophobic C-terminal sequence responsible for interaction with the membrane) to the reconstituted system containing cytochrome P450scc caused practically no stimulation of catalytic activity, indicating an important role of the hydrophobic fragment of cytochrome b ₅ in its interaction with cytochrome P450scc. However, full-length cytochrome b ₅ and the full-length Glu48Lys and Asp65Ala mutant forms of cytochrome b ₅ stimulated the cholesterol side-chain cleavage reaction catalyzed by cytochrome P450scc by 100%, suggesting that residues Glu48 and Asp65 of cytochrome b ₅ are not directly involved in its interaction with cytochrome P450scc. The replacement of Glu42 for lysine, however, made the Glu42Lys mutant form of cytochrome b ₅ about 40% less effective in stimulation of the cholesterol side-chain cleavage activity of cytochrome P450scc, indicating that residue Glu42 of cytochrome b ₅ is involved in electrostatic interactions with cytochrome P450scc. Residues Glu42 and Glu48 of cytochrome b ₅ appear to participate in electrostatic interaction with microsomal type cytochrome P450.     

Structural biology of heme monooxygenases

Over the past few years the number of crystal structures available for heme monooxygenases has substantially increased. Those most closely related to one another are cytochrome P450, nitric oxide synthase, and heme oxygenase. The present mini-review provides a summary of some recently published work on how crystallography and solution studies have provided new insights on function and especially the oxygen activation process. It now appears that in all three monooxygenases highly ordered solvent in the active site serves as direct proton donors to the iron-linked dioxygen; a requirement for splitting the O-O bond. This is in sharp contrast to the related peroxidase family of enzymes where strategically positioned amino acid side chains serve the function of shuttling protons. The P450cam-oxy-complex as well as various mutants in a complex with either oxygen or carbon monoxide have enabled a fairly detailed picture to be developed on the role of specific amino acids and conformational changes in both electron transfer and oxygen activation.     

High pressure, a tool for exploring heme protein active sites

High pressure is an interesting and suitable parameter in the study of the dynamics and stability of proteins. The effects of pressure on proteins delineates its volumic (deltaV degrees ) and energetic (deltaG degrees ) parameters. An enormous amount of effort has been invested by several laboratories in developing basic theory and high pressure techniques that allow the determination of barotropic parameters. Cytochrome P450s, one of the largest super families of heme proteins, are good models for high pressure studies. Two distinct pressure-induced spin transitions of the heme iron in the active site and a P450 to P420 inactivation process have been characterized. The obtained reaction volumes of these two processes for a series of analog-bound cytochrome P450s are compared. We have shown that both the spin volume and the inactivation volume are dependent on the substrate analogs which are known to modulate the polarity and hydration of the heme pocket. Several linear correlations were found between these reaction volumes and the physico-chemical properties of the heme protein such as the polarity-induced exposure of tyrosines, the hydration of the cytochrome CYP101 heme pocket, and the mobility and binding of the substrates indicate that they constitute the main contribution to the complex thermodynamic reaction volume parameters. This interpretation allows us to conclude that cytochrome CYP101, CYP2B4 and CYP102 possess a similar mechanism of substrate binding. Interestingly the barotropic behaviors of monomeric cytochrome P450s are quite different from those of oligomeric and hetorooligomeric cytochrome P450s. The interactions of heterooligomeric subunits influence the stability of individual cytochrome P450s and the asymmetric organization of subunits which can control and modulate the activity and the recognition with NADPH-cytochrome P450 reductase.     

Role of heme in phenobarbital induction of cytochromes P450 and 5-aminolevulinate synthase in cultured rat hepatocytes maintained on an extracellular matrix

When hepatocytes are cultured on matrigel, a reconstituted basement membrane matrix, mRNAs for cytochrome P450 class IIB1/2 and class III genes can be induced by treatment with phenobarbital. We took advantage of this new system to critically evaluate the role of heme as a regulator of these cytochromes P450 and of 5-aminolevulinate synthase (ALA-S), the rate-limiting enzyme in heme biosynthesis. Phenobarbital treatment of rat cultures increased the total amount of cytochrome P450, activities catalyzed by IIB1/2 (benzyloxy- and pentoxyresorufin O-dealkylases) and ALA-S activity, and ALA-S mRNA. Treatments with phenobarbital combined with succinyl acetone, an inhibitor of heme biosynthesis at the step of 5-aminolevulinate dehydrase, blocked the induction of the proteins for cytochrome P450IIB1/2 and cytochrome P450IIIAI, as indicated by spectral, immunological, and enzymatic assays. However, at the same time, succinyl acetone cotreatment failed to inhibit the induction of the mRNAs for cytochrome P450IIB1/2 and cytochrome P450IIIA. Lack of effect on the cytochrome P450 mRNAs was selective inasmuch as treatment with phenobarbital combined with succinyl acetone synergistically increased both ALA-S activity and ALA-S mRNA, presumably by blocking formation of heme, the feedback repressor of ALA-S. Indeed, the increase in ALA-S mRNA caused by the combined treatment was abolished by adding heme itself to the cultures. In contrast to earlier concepts, we conclude that in the intact hepatocyte, phenobarbital-induced cytochrome P450 induction is independent of changes in heme synthesis.