Herbal bioactivation, molecular targets and the toxicity relevance

There have been increasing reports on the adverse reactions associated with herbal consumption. For many of these adverse reactions, the underlying biochemical mechanisms are unknown, but bioactivation of herbal compounds to generate reactive intermediates have been implicated. This minireview updates our knowledge on metabolic activation of herbal compounds, molecular targets and the toxicity relevance. A number of studies have documented that some herbal compounds can be converted to toxic or even carcinogenic metabolites by Phase I [e.g. cytochrome P450s (CYPs)] and less frequently by Phase II enzymes. For example, aristolochic acids (AAs) in Aristolochia spp, which undergo reduction of the nitro group by hepatic CYP1A1/2 or peroxidases in extrahepatic tissues to generate highly reactive cyclic nitrenium ions. The latter can react with macromolecules (DNA and protein), resulting in activation of H-ras and myc oncogenes and gene mutation in renal cells and finally carcinogenesis of the kidneys. Teucrin A and teuchamaedryn A, two diterpenoids found in germander (Teuchrium chamaedrys) used as an adjuvant to slimming herbal supplements that caused severe hepatotoxicity, are converted by CYP3A4 to reactive epoxide which reacts with proteins such as CYP3A and epoxide hydrolase and inactivate them. Some naturally occurring alkenylbenzenes (e.g. safrole, methyleugenol and estragole) and flavonoids (e.g. quercetin) can undergo bioactivation by sequential 1-hydroxylation and sulfation, resulting in reactive intermediates capable of forming DNA adducts. Extensive pulegone metabolism generated p-cresol that is a glutathione depletory. The hepatotoxicity of kava is possibly due to intracellular glutathione depletion and/or quinone formation. Moreover, several herbal compounds including capsaicin from chili peppers, dially sulfone in garlic, methysticin and dihydromethysticin in kava, oleuropein in olive oil, and resveratrol found in grape seeds are mechanism-based (suicide) inhibitors of various CYPs. Together with advances of proteomics, metabolomics and toxicogenomics, an integrated systems toxicological approach may provide deep insights into mechanistic aspects of herb-induced toxicities, and contribute to bridging the relationships between herbal bioactivation, protein/DNA adduct formation and the toxicological consequences.     

Metabolic activation of the phenothiazine antipsychotics chlorpromazine and thioridazine to electrophilic iminoquinone species in human liver microsomes and recombinant P450s

The phenothiazine-derived antipsychotics, namely chlorpromazine and thioridazine, have been associated with very rare but severe incidences of hepatotoxicity in patients. While the mechanism of idiosyncratic hepatotoxicity remains unknown, it is possible that metabolic activation and subsequent covalently binding of reactive metabolites to cellular proteins play a causative role. Studies were initiated to determine whether chlorpromazine and thioridazine undergo cytochrome P450 (P450)-mediated bioactivation in human liver microsomes to electrophilic intermediates. LC/MS/MS analysis of incubations containing chlorpromazine or thioridazine in the presence of NADPH and glutathione (GSH) revealed the formation of GSH conjugates derived from the addition of the sulfydryl nucleophile to monohydroxy metabolites of chlorpromazine and thioridazine, respectively. Formation of reactive intermediates of chlorpromazine and thioridazine was primarily mediated by heterologously expressed recombinant CYP2D6, and to a less extent, CYP1A2. The 7-hydroxyl metabolites of chlorpromazine and thioridazine were also detected by tandem mass spectrometry. A tentative pathway states that after initial 7-hydroxylation, a bioactivation sequence involves P450-catalyzed oxidation of the phenothiazine core to an electrophilic quinone imine intermediate, which is subsequently attacked by glutathione yielding the sulfydryl conjugates. The results from the current investigation constitute the first report on the cytochrome P450-catalyzed bioactivation of the phenothiazine antipsychotics chlorpromazine and thioridazine.     

Bioactivation of the tricyclic antidepressant amitriptyline and its metabolite nortriptyline to arene oxide intermediates in human liver microsomes and recombinant P450s

Amitriptyline, the most widely used tricyclic antidepressant, has been associated with very rare but severe incidences of hepatotoxicity in patients. While the mechanism of idiosyncratic hepatotoxicity remains unknown, it is proposed that metabolic activation of amitriptyline and subsequent covalently binding of reactive metabolites to cellular proteins play a causative role. Studies were initiated to determine whether amitriptyline undergoes cytochrome P450 (P450)-mediated bioactivation in human liver microsomes to electrophilic intermediates. LC/MS/MS analysis of incubations containing amitriptyline and NADPH-supplemented microsomes in the presence of glutathione (GSH) revealed the formation of GSH conjugates derived from the addition of the sulfydryl nucleophile to hydrated metabolites of amitriptyline and nortriptyline, the major N-dealkylated metabolite of amitriptyline. Formation of GSH conjugates was primarily catalyzed by heterologously expressed recombinant CYP2D6, CYP3A4, CYP3A5, and to a less extent, CYP1A2. Corresponding dihydrodiol metabolites of amitriptyline and nortriptyline were also detected by tandem mass spectrometry. These findings are consistent with a bioactivation sequence involving initial P450-catalyzed oxidation of the aromatic nucleus in amitriptyline to an electrophilic arene oxide intermediate, which is subsequently attacked by glutathione and water yielding the sulfydryl conjugate and the dihydrodiol metabolite, respectively. The results from the current investigation constitute the first report on the cytochrome P450-catalyzed bioactivation of the antidepressants amitriptyline and nortriptyline. It is proposed that the arene oxide intermediate(s) may represent a rate-limiting step in the initiation of amitriptyline and nortriptyline-mediated hepatotoxicity.     

Biotransformation of tamoxifen in a human endometrial explant culture model

Although long-term tamoxifen therapy is associated with increased risk of endometrial cancer, little is known about the ability of endometrial tissue to biotransform tamoxifen to potentially reactive intermediates, capable of forming DNA adducts. The present study examined whether explant cultures of human endometrium provide a suitable in vitro model to investigate the tissue-specific biotransformation of tamoxifen. Fresh human endometrial tissue, microscopically uninvolved in disease, was cut into 1 x 2-mm uniform explants and incubated with media containing either 25 or 100 microM tamoxifen in a 24-well plate. Metabolites were analyzed by reversed-phase HPLC using postcolumn, online, photochemical activation and fluorescence detection. Three metabolites, namely, alpha-hydroxytamoxifen, 4-hydroxytamoxifen, and N-desmethyltamoxifen were identified in culture medium and tissue lysates. N-desmethyltamoxifen was found to be the major metabolite in both tissue and media extracts of tamoxifen-exposed explants. Incubations of tamoxifen with recombinant human cytochrome P-450s (CYPs) found that CYP2C9 and CYP2D6 produced all three of the above tamoxifen metabolites, while CYP1A1 and CYP3A4 catalyzed the formation of alpha-hydroxytamoxifen and N-desmethyltamoxifen, and CYP1A2 and CYP1B1 only formed the alpha-hydroxy metabolite. CYP2D6 exhibited the greatest activity for the formation of all three tamoxifen metabolites. Western immunoblots of microsomes from human endometrium detected the presence of CYPs 2C9, 3A, 1A1 and 1B1 in fresh endometrium, while CYPs 2D6 and 1A2 were not detected. Immunohistochemical (IHC) analysis also confirmed the presence of CYPs 2C9, 3A and 1B1 in fresh human endometrium and in viable tissue cultured for 24 h with or without tamoxifen. Together, the results support the use of explant cultures of human endometrium as a suitable in vitro model to investigate the biotransformation of tamoxifen in this target tissue. In addition, the results support the role of CYPs 2C9, 3A, 1A1 and 1B1 in the biotransformation of tamoxifen, including the formation of the DNA reactive alpha-hydroxytamoxifen metabolite, in human endometrium.     

Metabolic activation of the nontricyclic antidepressant trazodone to electrophilic quinone-imine and epoxide intermediates in human liver microsomes and recombinant P4503A4

Therapy with the antidepressant trazodone has been associated with several cases of idiosyncratic hepatotoxicity. While the mechanism of hepatotoxicity remains unknown, it is possible that reactive metabolites of trazodone play a causative role. Studies were initiated to determine whether trazodone undergoes bioactivation in human liver microsomes to electrophilic intermediates. LC/MS/MS analysis of incubations containing trazodone and NADPH-supplemented microsomes or recombinant P4503A4 in the presence of glutathione revealed the formation of conjugates derived from the addition of the sulfydryl nucleophile to mono-hydroxylated- and hydrated-trazodone metabolites. Product ion spectra suggested that mono-hydroxylation and sulfydryl conjugation occurred on the 3-chlorophenyl-ring, whereas hydration and subsequent sulfydryl conjugation had occurred on the triazolopyridinone ring system. These findings are consistent with bioactivation sequences involving: (1) aromatic hydroxylation of the 3-chlorophenyl-ring in trazodone followed by the two-electron oxidation of this metabolite to a reactive quinone-imine intermediate, which reacts with glutathione in a 1,4-Michael fashion and (2) oxidation of the pyridinone ring to an electrophilic epoxide, ring opening of which, by glutathione or water generates the corresponding hydrated-trazodone-thiol conjugate or the stable diol metabolite, respectively. The pathway involving trazodone bioactivation to the quinone-imine has also been observed with many para-hydroxyanilines including the structurally related antidepressant nefazodone. It is proposed that the quinone-imine and/or the epoxide intermediate(s) may represent a rate-limiting step in the initiation of trazodone-mediated hepatotoxicity.     

An investigation of the bioactivation potential and metabolism profile of Zebrafish versus human

The zebrafish model has been increasingly explored as an alternative model for toxicity screening of pharmaceutical drugs. However, little is understood about the bioactivation of drug to reactive metabolite and phase I and II metabolism of chemical in zebrafish as compared with human. The primary aim of our study was to establish the bioactivation potential of zebrafish using acetaminophen as a probe substrate. Our secondary aim was to perform metabolite profiling experiments on testosterone, a CYP3A probe substrate, in zebrafish and compare the metabolite profiles with that of human. The glutathione trapping assay of N-acetyl-p-benzoquinone imine demonstrated that zebrafish generates the same reactive metabolite as humans from the bioactivation of acetaminophen. Zebrafish possesses functional CYP3A4/5-like and UDP-glucuronosyltransferase metabolic activities on testosterone. Differential testosterone metabolism was observed among the two species. In silico docking studies suggested that the zebrafish CYP3A65 was responsible for the bioactivation of acetaminophen and phase I hydroxylation of testosterone. Our findings reinforce the need to further characterize the drug metabolism phenotype of zebrafish before the model can fully achieve its potential as an alternative toxicity screening model in drug research.     

Evidence for trichloroethylene bioactivation and adduct formation in the rat epididymis and efferent ducts

Recent studies indicate that trichloroethylene (TCE) may be a male reproductive toxicant. It is metabolized by conjugation with glutathione and cytochrome p450-dependent oxidation. Reactive metabolites produced along both pathways are capable of forming protein adducts and are thought to be involved in TCE-induced liver and kidney damage. Similarly, in situ bioactivation of TCE and subsequent binding of metabolites may be one mechanism by which TCE acts as a reproductive toxicant. Cysteine-conjugate beta-lyase (beta-lyase) bioactivates the TCE metabolite dichlorovinyl cysteine (DCVC) to a reactive intermediate that is capable of binding cellular macromolecules. In the present study, Western blot analysis indicated that the soluble form of beta-lyase, but not the mitochondrial form, was present in the epididymis and efferent ducts. Both forms of beta-lyase were detected in the kidney. When rats were dosed with DCVC, no protein adducts were detected in the epididymis or efferent ducts, although adducts were present in the proximal tubule of the kidney. Trichloroethylene can also be metabolized and form protein adducts through a cytochrome p450-mediated pathway. Western blot analysis detected the presence of cytochrome p450 2E1 (CYP2E1) in the efferent ducts. Immunoreactive proteins were localized to efferent duct and corpus epididymis epithelia. Metabolism of TCE was demonstrated in vitro using microsomes prepared from untreated rats. Metabolism was inhibited 77% when efferent duct microsomes were preincubated with an antibody to CYP2E1. Dichloroacetyl adducts were detected in epididymal and efferent duct microsomes exposed in vitro to TCE. Results from the present study indicate that the cytochrome p450-dependent formation of reactive intermediates and the subsequent covalent binding of cellular proteins may be involved in the male reproductive toxicity of TCE.     

Bioactivation of xenobiotics by prostaglandin H synthase

Prostaglandin H synthase (PHS) catalyzes the oxidation of arachidonic acid to prostaglandin H2 in reactions which utilize two activities, a cyclooxygenase and a peroxidase. These enzymatic activities generate enzyme- and substrate-derived free radical intermediates which can oxidize xenobiotics to biologically reactive intermediates. As a consequence, in the presence of arachidonic acid or a peroxide source, PHS can bioactivate many chemical carcinogens to their ultimate mutagenic and carcinogenic forms. In general, PHS-dependent bioactivation is most important in extrahepatic tissues with low monooxygenase activity such as the urinary bladder, renal medulla, skin and lung. Mutagenicity assays are useful in the detection of compounds which are converted to genotoxic metabolites during PHS oxidation. In addition, the oxidation of xenobiotics by PHS often form metabolites or adducts to cellular macromolecules which are specific for peroxidase- or peroxyl radical-dependent reactions. These specific metabolites and/or adducts have served as biological markers of xenobiotic bioactivation by PHS in certain tissues. Evidence is presented which supports a role for PHS in the bioactivation of several polycyclic aromatic hydrocarbons and aromatic amines, two classes of carcinogens which induce extrahepatic neoplasia. It should be emphasized that the toxicities induced by PHS-dependent bioactivation of xenobiotics are not limited to carcinogenicity. Examples are given which demonstrate a role for PHS in pulmonary toxicity, teratogenicity, nephrotoxicity and myelotoxicity.     

Pulegone mediated hepatotoxicity: evidence for covalent binding of R(+)-[14C]pulegone to microsomal proteins in vitro

Incubation of R(+)-[14C]pulegone with rat liver microsomes in the presence of NADPH resulted in covalent binding of radioactive material to macromolecules. Covalent binding was much higher in phenobarbital-treated microsomes as compared to 3-methylcholanthrene treated or control microsomes. The Km and Vmax of covalent binding was 0.4 mM and 1.7 nmol min-1 mg-1, respectively. Covalent binding was drastically inhibited (93%) in the presence of piperonyl butoxide. Antibodies to phenobarbital-induced cytochrome P-450 and NADPH-cytochrome P-450 reductase inhibited covalent binding to an extent of 72% and 47%, respectively. Cysteine and semicarbazide also inhibited NADPH dependent binding of radiolabel from R(+)-[14C]pulegone to microsomal proteins. The results suggest the involvement of liver microsomal cytochrome P-450 in the bioactivation of R(+)-pulegone to reactive metabolite(s) which might be responsible for covalent binding to macromolecules resulting in toxicity.     

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     

Selective protection of curcumin against carbon tetrachloride-induced inactivation of hepatic cytochrome P450 isozymes in rats

We investigated the effects of curcumin, a major antioxidant constituent of turmeric, on hepatic cytochrome P450 (CYP) activity in rats. Wistar rats received curcumin-containing diets (0.05, 0.5 and 5 g/kg diet) with or without injection of carbon tetrachloride (CCl(4)). The hepatic CYP content and activities of six CYP isozymes remained unchanged by curcumin treatment, except for the group treated with the extremely high dose (5 g/kg). This suggested that daily dose of curcumin does not cause CYP-mediated interaction with co-administered drugs. Chronic CCl(4) injection drastically decreased CYP activity, especially CYP2E1 activity, which is involved in the bioactivation of CCl(4), thereby producing reactive free radicals. Treatment with curcumin at 0.5 g/kg alleviated the CCl(4)-induced inactivation of CYPs 1A, 2B, 2C and 3A isozymes, except for CYP2E1. The lack of effect of curcumin on CYP2E1 damage might be related to suicidal radical production by CYP2E1 on the same enzyme. It is speculated that curcumin inhibited CCl(4)-induced secondary hepatic CYPs damage through its antioxidant properties. Our results demonstrated that CYP isozyme inactivation in rat liver caused by CCl(4) was inhibited by curcumin. Dietary intake of curcumin may protect against CCl(4)-induced hepatic CYP inactivation via its antioxidant properties, without inducing hepatic CYPs.     

Homology modeling of the three membrane proteins of the dhurrin metabolon: catalytic sites, membrane surface association and protein-protein interactions

Formation of metabolons (macromolecular enzyme complexes) facilitates the channelling of substrates in biosynthetic pathways. Metabolon formation is a dynamic process in which transient structures mediated by weak protein-protein interactions are formed. In Sorghum, the cyanogenic glucoside dhurrin is derived from l-tyrosine in a pathway involving the two cytochromes P450 (CYPs) CYP79A1 and CYP71E1, a glucosyltransferase (UGT85B1), and the redox partner NADPH-dependent cytochrome P450 reductase (CPR). Experimental evidence suggests that the enzymes of this pathway form a metabolon. Homology modeling of the three membrane bound proteins was carried out using the Sybyl software and available relevant crystal structures. Residues involved in tight positioning of the substrates and intermediates in the active sites of CYP79A1 and CYP71E1 were identified. In both CYPs, hydrophobic surface domains close to the N-terminal trans-membrane anchor and between the F′ and G helices were identified as involved in membrane anchoring. The proximal surface of both CYPs showed positively charged patches complementary to a negatively charged bulge on CPR carrying the FMN domain. A patch of surface exposed, positively charged amino acid residues positioned on the opposite face of the membrane anchor was identified in CYP71E1 and might be involved in binding UGT85B1 via a hypervariable negatively charged loop in this protein.     

Bioactivation of coumarin in rat olfactory mucosal microsomes: Detection of protein covalent binding and identification of reactive intermediates through analysis of glutathione adducts

The presence of high levels, as well as tissue-specific forms, of cytochrome P450 enzymes in mammalian olfactory mucosa (OM) has important implications in the bioactivation and toxicity of xenobiotics entering the tissue. Previous studies have shown that coumarin, a known olfactory toxicant in rats, is bioactivated by OM microsomal P450s to a number of products, presumably via coumarin-3,4-epoxide and other epoxide intermediates. The aim of the current study was to obtain direct evidence for the formation of such reactive intermediates in rat OM through the detection of protein covalent binding and glutathione (GSH) adduct formation. Protein covalent binding experiments with [¹⁴C]coumarin (10 μM) displayed a 7–9-fold higher NADPH-dependent radioactivity binding in rat OM microsomes (2.5 nmol/mg/30 min) compared to those in rat and human liver microsomes; the binding value in rat OM microsomes was substantially but not completely reduced by the addition of GSH (5 mM). LC/MS analyses detected a number of GSH adducts in GSH-supplemented coumarin metabolism reaction in rat OM microsomes; 3-glutathionyl coumarin was found to be the major one, indicating 3,4-epoxidation as the main bioactivation pathway. Additional GSH adducts were identified, presumably forming via the same pathway or epoxidation on the benzene moiety. Our findings provide direct evidence for the formation of multiple coumarin reactive intermediates in rat OM, leading to protein covalent binding and GSH conjugation.     

Cytochrome-P450 phosphorylation as a functional switch

Xenobiotic metabolizing cytochromes P450 (CYP) were shown to be phosphorylated in vitro (using purified protein kinases together with purified CYPs), in intact cells (in V79 cells after transfection of cDNAs coding for individual CYPs, in diagnostic mutants, in hepatocytes), and in whole organisms (rats). CYP phosphorylation is highly isoenzyme selective in that only some CYPs are phosphorylated. Protein kinase A (PKA) was identified as a major catalyst for the phosphorylation of CYPs. The PKA recognition motif Arg-Arg-X-Ser is present in several members of the CYP2 family, but is used by only some of them, most notably by CYP2B1/2B2 and CYP2E1. For CYP2B1 it was shown that a substantial portion but not the entire pool of CYP2B1 molecules is phosphorylated and that the phosphorylated portion is catalytically fully inactive. Phosphorylation of CYPs is a very fast process (visible at the earliest time point experimentally investigated after introduction of phosphorylation-supporting measures, which was 2.5min) and the phosphorylated protein is immediately inactive (i.e., the time curves of phosphorylation and inactivation are superimposable). Thus in contrast to the slower process controlling CYP activities by enzyme induction, CYP phosphorylation controls CYP function like a switch. The physical entity of the switch was identified by site-directed mutation as the phosphoryl acceptor Ser in the PKA recognition motif, which is Ser(138) in CYPs 2B (rat CYP2B1 and rabbit CYP2B4) and its homologous Ser(139) in CYP2E1. The function of this switch was demonstrated for the drastic changes in the control of the genotoxic metabolites of mutagenic carcinogens as well as for the control of effectiveness versus unwanted toxicity of cytostatic cancer drugs.     

Induction of CYP1A1, CYP1A2, CYP1B1, increased oxidative stress and inflammation in the lung and liver tissues of rats exposed to incense smoke

Incense smoke is increasingly being recognized as a potential environmental contaminant and is linked to malignant and non-malignant respiratory diseases. The detoxification of environmental contaminants including polycyclic aromatic hydrocarbons (PAHs) involves the induction of cytochrome P-450 family enzymes (CYPs) by PAHs. However, the detoxification of PAHs also results in the generation of reactive and unstable intermediary metabolites which are implicated in the oxidative stress, DNA damage, and inflammation. It is unclear whether CYPs are similarly induced by incense smoke, which incidentally contains substantial amounts of PAHs. Here, we examined the impact of long-term incense smoke exposure on the induction of CYPs in male Wister Albino rats. Incense smoke exposure significantly induced the expression of CYP1A1, CYP1A2, and CYP1B1 mRNAs in both lung and liver tissues. The extent of CYP1A1 and CYP1B1 induction was significantly higher in the liver compared to that in the lung, while that of CYP1A2 was greater in the lung than in liver. Incense smoke exposure also increased malondialdehyde and reduced glutathione levels in lung and liver tissues, and the catalase activity in the liver tissues to significant levels. Furthermore incense smoke exposure led to a marked increase in TNF-α and IL-4 levels. The data demonstrate for the first time the capacity of incense smoke to induce CYP1 family enzymes in the target and non-target tissues. Induction of CYPs increased oxidative stress and inflammation appear to be intimately linked to promote the carcinogenesis and health complications in people chronically exposed to incense smoke.     

The in vivo turnover of rat liver microsomal epoxide hydrolase and both the apoprotein and heme moieties of specific cytochrome P-450 isozymes

The in vivo turnover rates of liver microsomal epoxide hydrolase and both the heme and apoprotein moieties of cytochromes P-450a, P-450b + P-450e, and P-450c have been determined by following the decay in specific radioactivity from 2 to 96 h after simultaneous injections of NaH14CO3 and 3H-labeled delta-aminolevulinic acid to Aroclor 1254-treated rats. Total liver microsomal protein was characterized by an apparent biphasic exponential decay in specific radioactivity, with half-lives of 5-9 and 82 h for the fast- and slow-phase components, respectively. Most (approximately 90%) of the rapidly turning over microsomal protein fraction was immunologically distinct from membrane-associated serum protein, and thus appeared to represent integral membrane proteins. The existence of two distinct populations of cytochrome P-450a was suggested by the apparent biphasic turnover of both the heme and apoprotein moieties of the holoenzyme. The half-lives of the apoprotein were estimated to be 12 and 52 h for the fast- and slow-phase components, respectively, and 7 and 34 h for the heme moiety. The turnover of cytochromes P-450b + P-450e was identical to that of cytochrome P-450c, with half-lives of 37 and 28 h for the apoprotein and heme moieties, respectively. In all cases, the shorter half-lives of the heme component compared to the protein component were statistically significant. In contrast to the cytochrome P-450 isozymes, epoxide hydrolase (t1/2 = 132 h) turned over slower than the "average" microsomal protein (t1/2 = 82 h). The differential rates of degradation of these major integral membrane proteins during both the rapid and slow phases of total microsomal protein turnover argue against the concepts of unit membrane degradation and unidirectional membrane flow of liver endoplasmic reticulum.