Enzymatic activation of chemicals to toxic metabolites

Applying Mechanisms of Chemical Toxicity to Predict Drug Safety

Toxicology can no longer be used only as a science that reacts to problems but must be more proactive in predicting potential human safety issues with new drug candidates. Success in this area must be based on an understanding of the mechanisms of toxicity. This review summarizes and extends some of the concepts of an American Chemical Society ProSpectives meeting on the title subject held in June 2006. One important area is the discernment of the exact nature of the most common problems in drug toxicity. Knowledge of chemical structure alerts and relevant biological pathways are important. Biological activation to reactive products and off-target pharmacology are considered to be major contexts of drug toxicity, although defining exactly what the contributions are is not trivial. Some newer approaches to screening for both have been developed. A goal in predictive toxicology is the use of in vitro methods and database development to make predictions concerning potential modes of toxicity and to stratify drug candidates for further development. Such predictions are desirable for several economic and other reasons but are certainly not routine yet. However, progress has been made using several approaches. Some examples of the application of studies of wide-scale biological responses are now available, with incorporation into development paradigms.

Expression, microsomal and mitochondrial activities of cytochrome P450 enzymes in brain regions from control and phenobarbital-treated rabbits

Expression and monooxygenase activity of various cytochrome P450 (CYP) enzymes along with constitutive androstane (CAR) and the pregnane X (PXR) receptors were investigated in the brain of control and phenobarbital-treated rabbits (80 mg/kg for 4 days). RT-PCR analysis, using specific primers, demonstrated that in control rabbits mRNAs of CYP 2A10, 2B4/5 and 3A6 were expressed, though to a different extent, in the liver, as well as in brain cortex, midbrain, cerebellum, striatum, hippocampus and hypothalamus, whilst CYP2A11 and 4B1 were not expressed in the hypothalamus. CAR was expressed in liver and all the brain regions examined, whereas the PXR was expressed only in liver and cortex. Real time RT-PCR analysis demonstrated that in vivo treatment with phenobarbital, in contrast with what happened in liver, did not induce the expression of CYP 2B4/5 mRNA in cortex, midbrain and cerebellum. NADPH cytochrome c reductase and some other enzymatic activities markers of CYP 2A, 2B, 3A and 4B activities were studied in liver microsomes as well as in microsomes and mitochondria of brain cortex, midbrain and cerebellum of control and phenobarbital-treated rabbits. In contrast to what was observed in liver, phenobarbital treatment did not induce the aforementioned monooxygenase activities in brain. However, we cannot exclude that a longer phenobarbital treatment may lead to a significant induction of CYP activities in brain. These findings indicated that brain CYPs, despite the presence of CAR, were resistant to phenobarbital induction, indicating a possible different regulation of these enzymes between brain and liver.

Limited reactivity of formyl chloride with glutathione and relevance to metabolism and toxicity of dichloromethane

Formyl chloride has been indirectly implicated as an intermediate in the oxidation of CH(2)Cl(2) and proposed to be a product of the oxidation of some other compounds. Formyl chloride was synthesized and added to aqueous solutions, with CO formed as a product. The presence of glutathione (GSH) did not reduce the yield of CO at any of the pH values tested. At pH >or= 9, a small amount of S-formyl GSH was detected (<or =3% of CO formed) and identified by comparison with synthetic material using mass spectrometry. Incubations of CH(2)Cl(2) with human liver microsomes at neutral pH produced mainly CO and only trace protein adducts (detected from (14)CH(2)Cl(2)) and no S-formyl GSH at the level of detection. Neither rat liver cytosol nor purified GSH transferase (rat) 5-5 or (human) T1-1 significantly enhanced the level of S-formyl GSH recovered in incubations with either NADPH-fortified microsomes and CH(2)Cl(2) or synthetic formyl chloride. The oxidation pathway is the principal route of metabolism of CH(2)Cl(2) at low doses in vivo, and previous literature assumes that the formyl chloride product is reactive with GSH and protein. We provide evidence that formyl chloride can react with GSH but that, in contrast to suggestions in the literature, the extent is very limited because of the known high rate of rearrangement to CO in aqueous solution. The very limited reaction of formyl chloride with nucleophiles is consistent with the low toxicity of CH(2)Cl(2), and formyl chloride binding cannot be used as an explanation for discrepancies in pharmacokinetic models [Gargas, M. L., Clewell, H. J., III, and Andersen, M. E. (1986) Toxicol. Appl. Pharmacol. 82, 211-223; Clewell, H. J., III (1995) Toxicology 102, 83-94].

Alternative splicing within the human cytochrome P450 superfamily with an emphasis on the brain: the convolution continues

The human cytochrome P450 (CYP) superfamily of enzymes regulate hepatic phase 1 drug metabolism and subsequently play a significant role in pharmacokinetics, drug discovery and drug development. Alternative splicing of the cytochrome CYP gene transcripts enhances gene diversity and may play a role in transcriptional regulation of certain CYP proteins. Tissue-specific alternative splicing of CYPs is significant for its potential to add greater dimension to differential drug metabolism in hepatic and extrahepatic tissues, such as the brain, and to our understanding of the CYP family. This review provides an overview of tissue-specific splicing patterns, splicing types, regulation and the functional diversities between liver and splice variant CYP proteins and further explores the relevance of tissue-specific alternative splicing of CYPs in the nervous system.

Induction of oxidative stress responses by dioxin and other ligands of the aryl hydrocarbon receptor

TCDD and other polyhalogenated aromatic hydrocarbon ligands of the aryl hydrocarbon receptor (AHR) have been classically considered as non-genotoxic compounds because they fail to be directly mutagenic in either bacteria or most in vitro assay systems. They do so in spite of having repeatedly been linked to oxidative stress and to mutagenic and carcinogenic outcomes. Oxidative stress, on the other hand, has been used as a marker for the toxicity of dioxin and its congeners. We have focused this review on the connection between oxidative stress induction and the toxic effects of fetal and adult dioxin exposure, with emphasis on the large species difference in sensitivity to this agent. We examine the roles that the dioxin-inducible cytochromes P450s play in the cellular and toxicological consequences of dioxin exposure with emphasis on oxidative stress involvement. Many components of the health consequences resulting from dioxin exposure may be attributable to epigenetic mechanisms arising from prolonged reactive oxygen generation.

Comparison of mouse hepatic mitochondrial versus microsomal cytochromes P450 following TCDD treatment

TCDD (2,3,7,8-tetrachlorodibenzo-p-dioxin) induces cytochromes P450 (CYPs) such as CYP1A1 and CYP1A2 via activation of the aromatic hydrocarbon receptor (AHR). Herein we describe the TCDD-dependent enrichment of CYPs in liver microsomes and mitoplasts from C57BL/6J mice. TCDD-induced accumulation of CYP1A1 and CYP1A2 was observed in microsomes and mitoplasts after treatment with 15 microg TCDD/kg/d for 3d. While microsomal CYP1 proteins peaked at 1 week and diminished thereafter, mitoplast CYP1 proteins persisted 8 weeks at high levels. TCDD also induced microsomal CYP2A5, but not microsomal proteins immunoreactive to CYP2C11, CYP3A2 or CYP4A1 antibodies. Nevertheless, each of these proteins increased in mitoplasts following TCDD exposure. These results suggest that TCDD increases mitochondrial CYP immunoreactive proteins under the transcriptional control of the AHR, as well as CYPs that are not under AHR control. We speculate that such mitochondrial CYPs may be involved in the generation, or mitigation, of the well-known TCDD-inducible oxidative stress response.

Role of nuclear receptor CAR in carbon tetrachloride-induced hepatotoxicity

AIM: To investigate the precise roles of CAR in CCl₄-induced acute hepatotoxicity.

METHODS: To prepare an acute liver injury model, CCl₄- induced was intraperitoneally injected in CAR^+/+ and CAR^-/- mice.

RESULTS: Elevation of serum alanine aminotransferase and extension of centrilobular necrosis were slightly inhibited in CAR^-mice compared to CAR^+/+ mice without PB. Administration of a CAR inducer, PB, revealed that CCl₄-induced liver toxicity was partially inhibited in CAR^-/- mice compared with CAR^+/+ mice. On the other hand, androstanol, an inverse agonist ligand, inhibited hepatotoxicity in CAR^+/+ but not in CAR^-/- mice. Thus, CAR activation caused CCl₄- induced hepatotoxicity while CAR inhibition resulted in partial protection against CCl₄-induced hepatotoxicity.There were no differences in the expression of CYP2E1, the main metabolizing enzyme for CCl₄, between CAR^+/+ and CAR^-/- mice. However, the expression of other CCl₄-metabolizing enzymes, such as CYP2B10 and 3A11, was induced by PB in CAR^+/+ but not in CAR^-/- mice. Although the main pathway of CCl₄-induced acute liver injury is mediated by CYP2E1, CAR modulates its pathway via induction of CYP2B10 and3A11 in the presence of activator or inhibitor.

CONCLUSION: The nuclear receptor CAR modulates CCl₄-induced liver injury via induction of CCl₄-metabolizing enzymes in the presence of an activator. Our results suggest that drugs interacting with nuclear receptors such as PB might play critical roles in drug-induced liver injury or drug-drug interaction even though such drugs themselves are not hepatotoxic.

Monitoring drug-protein interaction

A variety of therapeutic drugs can undergo biotransformation via Phase I and Phase II enzymes to reactive metabolites that have intrinsic chemical reactivity toward proteins and cause potential organ toxicity. A drug-protein adduct is a protein complex that forms when electrophilic drugs or their reactive metabolite(s) covalently bind to a protein molecule. Formation of such drug-protein adducts eliciting cellular damages and immune responses has been a major hypothesis for the mechanism of toxicity caused by numerous drugs. The monitoring of protein-drug adducts is important in the kinetic and mechanistic studies of drug-protein adducts and establishment of dose-toxicity relationships. The determination of drug-protein adducts can also provide supportive evidence for diagnosis of drug-induced diseases associated with protein-drug adduct formation in patients. The plasma is the most commonly used matrix for monitoring drug-protein adducts due to its convenience and safety. Measurement of circulating antibodies against drug-protein adducts may be used as a useful surrogate marker in the monitoring of drug-protein adducts. The determination of plasma protein adducts and/or relevant antibodies following administration of several drugs including acetaminophen, dapsone, diclofenac and halothane has been conducted in clinical settings for characterizing drug toxicity associated with drug-protein adduct formation. The monitoring of drug-protein adducts often involves multi-step laboratory procedure including sample collection and preliminary preparation, separation to isolate or extract the target compound from a mixture, identification and determination. However, the monitoring of drug-protein adducts is often difficult because of short half-lives of the protein adducts, sampling problem and lack of sensitive analytical techniques for the protein adducts. Currently, chromatographic (e.g. high performance liquid chromatography) and immunological methods (e.g. enzyme-linked immunosorbent assay) are two major techniques used to determine protein adducts of drugs in patients. The present review highlights the importance for clinical monitoring of drug-protein adducts, with an emphasis on methodology and with a further discussion of the application of these techniques to individual drugs and their target proteins.

First evidence that cytochrome P450 may catalyze both S-oxidation and epoxidation of thiophene derivatives

Oxidation of 2-phenylthiophene (2PT) by rat liver microsomes, in the presence of NADPH and glutathione (GSH), led to three kinds of metabolites whose structures were established by 1H NMR and mass spectrometry. The first ones were 2PT-S-oxide dimers formed by Diels-Alder type dimerization of 2PT-S-oxide, while the second ones were GSH adducts derived from the 1,4-Michaël-type addition of GSH to 2PT-S-oxide. The third metabolites were GSH adducts resulting from a nucleophilic attack of GSH to the 4,5-epoxide of 2PT. Oxidation of 2PT by recombinant, human cytochrome P4501A1, in the presence of NADPH and GSH, also led to these three kinds of metabolites. These results provide the first evidence that cytochrome P450 may catalyze the oxidation of thiophene compounds with the simultaneous formation of two reactive intermediates, a thiophene-S-oxide and a thiophene epoxide.

Drug bioactivation, covalent binding to target proteins and toxicity relevance

A number of therapeutic drugs with different structures and mechanisms of action have been reported to undergo metabolic activation by Phase I or Phase II drug-metabolizing enzymes. The bioactivation gives rise to reactive metabolites/intermediates, which readily confer covalent binding to various target proteins by nucleophilic substitution and/or Schiff's base mechanism. These drugs include analgesics (e.g., acetaminophen), antibacterial agents (e.g., sulfonamides and macrolide antibiotics), anticancer drugs (e.g., irinotecan), antiepileptic drugs (e.g., carbamazepine), anti-HIV agents (e.g., ritonavir), antipsychotics (e.g., clozapine), cardiovascular drugs (e.g., procainamide and hydralazine), immunosupressants (e.g., cyclosporine A), inhalational anesthetics (e.g., halothane), nonsteroidal anti-inflammatory drugs (NSAIDSs) (e.g., diclofenac), and steroids and their receptor modulators (e.g., estrogens and tamoxifen). Some herbal and dietary constituents are also bioactivated to reactive metabolites capable of binding covalently and inactivating cytochrome P450s (CYPs). A number of important target proteins of drugs have been identified by mass spectrometric techniques and proteomic approaches. The covalent binding and formation of drug-protein adducts are generally considered to be related to drug toxicity, and selective protein covalent binding by drug metabolites may lead to selective organ toxicity. However, the mechanisms involved in the protein adduct-induced toxicity are largely undefined, although it has been suggested that drug-protein adducts may cause toxicity either through impairing physiological functions of the modified proteins or through immune-mediated mechanisms. In addition, mechanism-based inhibition of CYPs may result in toxic drug-drug interactions. The clinical consequences of drug bioactivation and covalent binding to proteins are unpredictable, depending on many factors that are associated with the administered drugs and patients. Further studies using proteomic and genomic approaches with high throughput capacity are needed to identify the protein targets of reactive drug metabolites, and to elucidate the structure-activity relationships of drug's covalent binding to proteins and their clinical outcomes.

Acetaminophen-induced hepatotoxicity: role of metabolic activation, reactive oxygen/nitrogen species, and mitochondrial permeability transition

Large doses of the analgesic acetaminophen cause centrilobular hepatic necrosis in man and in experimental animals. It has been previously shown that acetaminophen is metabolically activated by CYP enzymes to N-acetyl-p-benzoquinone imine. This species is normally detoxified by GSH, but following a toxic dose GSH is depleted and the metabolite covalently binds to a number of different proteins. Covalent binding occurs only to the cells developing necrosis. Recently we showed that these cells also contain nitrated tyrosine residues. Nitrotyrosine is mediated by peroxynitrite, a reactive nitrogen species formed by rapid reaction between nitric oxide and superoxide and is normally detoxified by GSH. Thus, acetaminophen toxicity occurs with increased oxygen/nitrogen stress. This manuscript will review current data on acetaminophen covalent binding, increased oxygen/nitrogen stress, and mitochondrial permeability transition, a toxic mechanism that is both mediated by and leads to increased oxygen/nitrogen stress.

Myeloperoxidase-catalyzed oxidation of chloroacetonitrile to cyanide

Chloroacetonitrile (CAN) is a disinfection by-product of chlorination of drinking water. Epidemiological studies indicate that it might present a potential hazard to human health. The present work provides an evidence for CAN activation to cyanide (CN-) by myeloperoxidase (MPO)/hydrogen peroxide (H2O2)/chloride (Cl-) system in vitro. Optimum conditions for the oxidation of CAN to CN- were characterized with respect to pH, temperature and time of incubation as well as CAN, MPO, H2O2 and KCl concentrations in incubation mixtures. The kinetic parameters governing the reaction; maximum velocity (Vmax) and Michaelis-Menten constant (Km) were assessed. Oxidation of CAN to CN- by NaOCl alone was shown. Addition of the MPO inhibitors; sodium azide (NaN3), 4-amino benzoic acid hydrazine (ABAH) or indomethacin to the reaction mixtures resulted in a significant decrease in the rate of CAN oxidation. Inclusion of the antioxidant enzyme catalase (CAT) in the incubation mixtures resulted in a significant decrease in the rate of CAN oxidation and CN- formation. Addition of the sulfhydryl compounds; glutathione (GSH), N-acetyl-L-cysteine (NAC), L-cysteine or D-penicillamine significantly enhanced the rate of CN- release. In conclusion, MPO/H2O2/Cl- system has the ability of oxidizing CAN to CN-. The present results represent a novel pathway for CAN activation and might be important in explaining CAN-induced toxicity.

Herbal bioactivation: the good, the bad and the ugly

It has been well established that the formation of reactive metabolites of drugs is associated with drug toxicity. Similarly, there are accumulating data suggesting the role of the formation of reactive metabolites/intermediates through bioactivation in herbal toxicity and carcinogenicity. It has been hypothesized that the resultant reactive metabolites following herbal bioactivation covalently bind to cellular proteins and DNA, leading to toxicity via multiple mechanisms such as direct cytotoxicity, oncogene activation, and hypersensitivity reactions. This is exemplified by aristolochic acids present in Aristolochia spp, undergoing reduction of the nitro group by hepatic cytochrome P450 (CYP1A1/2) or peroxidases in extrahepatic tissues to reactive cyclic nitrenium ion. The latter was capable of reacting with DNA and proteins, resulting in activation of H-ras oncogene, gene mutation and finally carcinogenesis. Other examples are pulegone present in essential oils from many mint species; and teucrin A, a diterpenoid found in germander (Teuchrium chamaedrys) used as an adjuvant to slimming diets. Extensive pulegone metabolism generated p-cresol that was a glutathione depletory, and the furan ring of the diterpenoids in germander was oxidized by CYP3A4 to reactive epoxide which reacts with proteins such as CYP3A and epoxide hydrolase. On the other hand, some herbal/dietary constituents were shown to form reactive intermediates capable of irreversibly inhibiting various CYPs. The resultant metabolites lead to CYP inactivation by chemical modification of the heme, the apoprotein, or both as a result of covalent binding of modified heme to the apoprotein. Some examples include bergamottin, a furanocoumarin of grapefruit juice; capsaicin from chili peppers; glabridin, an isoflavan from licorice root; isothiocyanates found in all cruciferous vegetables; oleuropein rich in olive oil; dially sulfone found in garlic; and resveratrol, a constituent of red wine. CYPs have been known to metabolize more than 95% therapeutic drugs and activate a number of procarcinogens as well. Therefore, mechanism-based inhibition of CYPs may provide an explanation for some reported herb-drug interactions and chemopreventive activity of herbs. Due to the wide use and easy availability of herbal medicines, there is increasing concern about herbal toxicity. The safety and quality of herbal medicine should be ensured through greater research, pharmacovigilance, greater regulatory control and better communication between patients and health professionals.

Trace Elements and Electrolytes Homeostasis and Their Relation to Antioxidant Enzyme Activity in Brain Hyperexcitability of Epileptic Patients

Epileptogenesis is a big challenge. Various experimental and human studies suggested that the homeostasis of trace elements, electrolytes, membrane lipid peroxidation, and antioxidants is crucial for brain function, and they were directly or indirectly implicated as taking part in the pathophysiology of neuronal excitability, neuronal excitotoxicity, and seizure recurrence and its resistance to treatment with antiepileptic drugs (AEDs). In addition, AEDs can also alter the homeostasis of trace elements, electrolytes, and seriously increase membrane lipid peroxidation at the expense of protective antioxidants, leading to an increase in seizure recurrence and an idiosyncratic drug effect. Differential effects were detected among different AEDs treatments in which carbamazepine (CBZ) was found to be better anticonvulsant for the control of free radical related seizures and the level of trace elements were better regulated with CBZ than with valproate (VPA) and phenytoin (PHT) therapies. It is concluded that adequate trace elements and antioxidants supply is important for brain functions and prevention of neurological diseases and further elucidation of the pathological actions of such substances in the brain should result in new therapeutic approaches. Trace elements and antioxidant might have neuroprotective biological targeted benefits when used in epileptic patients.

Separation and detection methods for covalent drug–protein adducts

Covalent binding of reactive metabolites of drugs to proteins has been a predominant hypothesis for the mechanism of toxicity caused by numerous drugs. The development of efficient and sensitive analytical methods for the separation, identification, quantification of drug-protein adducts have important clinical and toxicological implications. In the last few decades, continuous progress in analytical methodology has been achieved with substantial increase in the number of new, more specific and more sensitive methods for drug-protein adducts. The methods used for drug-protein adduct studies include those for separation and for subsequent detection and identification. Various chromatographic (e.g., affinity chromatography, ion-exchange chromatography, and high-performance liquid chromatography) and electrophoretic techniques [e.g., sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), two-dimensional SDS-PAGE, and capillary electrophoresis], used alone or in combination, offer an opportunity to purify proteins adducted by reactive drug metabolites. Conventionally, mass spectrometric (MS), nuclear magnetic resonance, and immunological and radioisotope methods are used to detect and identify protein targets for reactive drug metabolites. However, these methods are labor-intensive, and have provided very limited sequence information on the target proteins adducted, and thus the identities of the protein targets are usually unknown. Moreover, the antibody-based methods are limited by the availability, quality, and specificity of antibodies to protein adducts, which greatly hindered the identification of specific protein targets of drugs and their clinical applications. Recently, the use of powerful MS technologies (e.g., matrix-assisted laser desorption/ionization time-of-flight) together with analytical proteomics have enabled one to separate, identify unknown protein adducts, and establish the sequence context of specific adducts by offering the opportunity to search for adducts in proteomes containing a large number of proteins with protein adducts and unmodified proteins. The present review highlights the separation and detection technologies for drug-protein adducts, with an emphasis on methodology, advantages and limitations to these techniques. Furthermore, a brief discussion of the application of these techniques to individual drugs and their target proteins will be outlined.

Calpain released from dying hepatocytes mediates progression of acute liver injury induced by model hepatotoxicants

Liver injury is known to progress even after the hepatotoxicant is long gone and the mechanisms of progressive injury are not understood. We tested the hypothesis that hydrolytic enzymes such as calpain, released from dying hepatocytes, destroy the surrounding cells causing progression of injury. Calpain inhibitor, N-CBZ-VAL-PHE-methyl ester (CBZ), administered 1 h after a toxic but nonlethal dose of CCl(4) (2 ml/kg, ip) to male Sprague Dawley rats substantially mitigated the progression of liver injury (6 to 48 h) and also led to 75% protection against CCl(4)-induced lethality following a lethal dose (LD75) of CCl(4) (3 ml/kg). Calpain leakage in plasma and in the perinecrotic areas increased until 48 h and decreased from 72 h onward paralleling progression and regression of liver injury, respectively, after CCl(4) treatment. Mitigation of progressive injury was accompanied by substantially low calpain in perinecrotic areas and in plasma after CBZ treatment. Normal hepatocytes incubated with the plasma collected from CCl(4)-treated rats (collected at 12 h when most of the CCl(4) is eliminated) resulted in extensive cell death prevented by CBZ. Cell-impermeable calpain inhibitor E64 also protected against progression of CCl(4)-induced liver injury, thereby confirming the role of released calpain in progression of liver injury. Following CCl(4) treatment, calpain-specific breakdown of alpha-fodrin increased, while it was negligible in rats receiving CBZ after CCl(4). Hepatocyte cell death in incubations containing calpain was completely prevented by CBZ. Eighty percent of Swiss Webster mice receiving a lethal dose (LD80) of acetaminophen (600 mg/kg, ip) survived if CBZ was administered 1 h after acetaminophen, suggesting that calpain-mediated progression of liver injury is neither species nor chemical specific. These findings suggest the role of calpain in progression of liver injury.

Pitfalls of enzyme-based molecular anticancer dietary manipulations: food for thought

Dietary approaches to cancer chemoprevention increasingly have focused on single nutrients or phytochemicals to stimulate one or another enzymatic metabolizing system. These procedures, which aim to boost carcinogen detoxification or inhibit carcinogen bioactivation, fail to take into account the multiple and paradoxical biological outcomes of enzyme modulators that make their effects unpredictable. Here, we critically examine the scientific and medical evidence for the idea that the physiological roles of specific enzymes may be manipulated by regular, long-term administration of isolated nutrients and other chemicals derived from food plants. Instead, we argue that consumption of healthful diets is most likely to reduce mutagenesis and cancer risk, and that research efforts and dietary recommendations should be redirected away from single nutrients to emphasize the improvement of dietary patterns as a principal strategy for public health policy.

Ecotoxicological risks associated with land treatment of petrochemical wastes. II. Effects on hepatic phase I and phase II detoxification enzymes in cotton rats

The purpose of this study was to evaluate possible exposure and resultant hepatic effects of petrochemical waste on cotton rats (Sigmodon hispidus) living on landfarmed sites. Male and female cotton rats were collected in summer, fall, and winter from four landfarm sites and four ecologically similar reference sites. Hepatic methoxyresorufin O-deethylase (MROD) activity was significantly induced in male and female rats collected from landfarms compared to rats collected from reference sites. In contrast, changes in ethoxyresorufin O-deethylase (EROD) activity were inconsistent due to season, sex, and treatment variation. A significant decrease in EROD and MROD activity was found in cotton rats held for 48 h prior to sacrifice compared to rats euthanized on the day of capture. These results indicate that when using hepatic EROD and MROD activities as biochemical markers of exposure to aryl hydrocarbon receptor agonists, animals should be euthanized as quickly as possible after capture. The cotton rats collected from one landfarm unit exhibited a pattern of consistent elevation of EROD, MROD, and pent-oxyresorufin O-deethylase (PROD) activity. This unit also had a pattern of elevated CYP1A2 protein expression determined by Western blotting. There were no consistent alterations from contaminant exposure on hepatic glutathione S-transferase (GST) activity, glutathione levels, or CYP1A1 protein. Hepatic EROD and MROD activities varied considerably between seasons and sex of rats. In conclusion, consistent induction of hepatic EROD and MROD activities in cotton rats was found in three out of four sampled landfarm sites compared to the rats collected from the reference sites, indicating exposure to contaminants-likely polyaromatic hydrocarbons.

Differential metabolism of alprazolam by liver and brain cytochrome (P4503A) to pharmacologically active metabolite

Cytochrome P450 (P450) is a superfamily of enzymes which mediates metabolism of xenobiotics including drugs. Alprazolam, an anti-anxiety agent, is metabolized in rat and human liver by P4503A1 and P4503A4 respectively, to 4-hydroxy alprazolam (4-OHALP, pharmacologically less active) and alpha-hydroxy alprazolam (alpha-OHALP, pharmacologically more active). We examined P450 mediated metabolism of alprazolam by rat and human brain microsomes and observed that the relative amount of alpha-OHALP formed in brain was higher than liver. This biotransformation was mediated by a P450 isoform belonging to P4503A subfamily, which is constitutively expressed in neuronal cells in rat and human brain. The formation of larger amounts of alpha-OHALP in neurons points to local modulation of pharmacological activity in brain, at the site of action of the anti-anxiety drug. Since hydroxy metabolites of alprazolam are hydrophilic and not easily cleared through blood-CSF barrier, alpha-OHALP would potentially have a longer half-life in brain.

Cytochrome P450 oxidations in the generation of reactive electrophiles: epoxidation and related reactions

Much of the interest in the cytochrome P450 (P450) enzymes has been because of oxidation of chemicals to reactive products. The epoxides (oxiranes) have been a major topic of interest with olefins and aryl compounds. Epoxides vary considerably in their reactivity, with t(1/2) varying from 1s to several hours. The stability and reactivity influences not only the overall damage to biological systems but also the site of injury. Transformations of some xenobiotic chemicals may involve products other than epoxides. Chemicals considered here include olefins, aromatic hydrocarbons, heterocycles, vinyl halides, ethyl carbamate, vinyl nitrosamines, and aflatoxin B(1). These compounds either are unsaturated or are transformed to unsaturated products. The epoxides and other products provide a view of the landscape of P450-generated reactive products and the myriad of chemistry involved in the metabolism of drugs and protoxicants. Understanding the chemical nature of reactive products is necessary to develop rational strategies for intervention.

Mitochondrial reactive oxygen production is dependent on the aromatic hydrocarbon receptor

2,3,7,8-Tetrachlorodibenzo-p-dioxin (dioxin; TCDD) is a pervasive environmental contaminant that induces hepatic and extrahepatic oxidative stress. We have previously shown that dioxin increases mitochondrial respiration-dependent reactive oxygen production. In the present study we examined the dependence of mitochondrial reactive oxygen production on the aromatic hydrocarbon receptor (AHR), cytochrome P450 1A1 (CYP1A1), and cytochrome P450 1A2 (CYP1A2), proteins believed to be important in dioxin-induced liver toxicity. Congenic Ahr(-/-), Cyp1a1(-/-) and Cyp1a2(-/-) knockout mice, and C57BL/6J inbred mice as their Ahr/Cyp1a1/Cyp1a2(+/+) wild-type (wt) counterparts, were injected intraperitoneally with dioxin (15 microg/kg body weight) or corn-oil vehicle on 3 consecutive days. Liver mitochondria were examined 1 week following the first treatment. The level of mitochondrial H(2)O(2) production in vehicle-treated Ahr(-/-) mice was one fifth that found in vehicle-treated wt mice. Whereas dioxin caused a rise in succinate-stimulated mitochondrial H(2)O(2) production in the wt, Cyp1a1(-/-), and Cyp1a2(-/-) mice, this increase did not occur with the Ahr(-/-) knockout. The lack of H(2)O(2) production in Ahr(-/-) mice was not due to low levels of Mn(2+)-superoxide dismutase (SOD2) as shown by Western immunoblot analysis, nor was it due to high levels of mitochondrial glutathione peroxidase (GPX1) activity. Dioxin decreased mitochondrial aconitase (an enzyme inactivated by superoxide) by 44% in wt mice, by 26% in Cyp1a2(-/-) mice, and by 24% in Cyp1a1(-/-) mice; no change was observed in Ahr(-/-) mice. Dioxin treatment increased mitochondrial glutathione levels in the wt, Cyp1a1(-/-), and Cyp1a2(-/-) mice, but not in Ahr(-/-) mice. These results suggest that both constitutive and dioxin-induced mitochondrial reactive oxygen production is associated with a function of the AHR, and these effects are independent of either CYP1A1 or CYP1A2.

Induction of cellular oxidative stress by aryl hydrocarbon receptor activation

The aryl hydrocarbon receptor (AHR) has long been associated with the induction of a battery of genes involved in the metabolism of foreign and endogenous compounds. Depending on experimental conditions, AHR can mediate either activation or amelioration of chemical toxicity. For the past decade, evidence has mounted that AHR is associated with a cellular oxidative stress response that must be considered when evaluating the mechanism of action of xenobiotics capable of activating AHR, or capable of metabolic activation by enzymes encoded by genes under control of AHR. In this review, we have evaluated the diverse mechanisms by which AHR generates an oxidative stress response, including inflammation, antioxidant and prooxidant enzymes and cytochrome P450. A review of the regulation of Ahr transcription and functional polymorphisms especially related to oxidative stress is also included. We have carefully avoided placing a value judgment on the degree of toxicity produced by such a response, in view of the realization that an oxidative response is involved in many normal physiological processes. Since the interface between physiological, adaptive and toxicological responses elicited by the AHR-mediated oxidative stress response is not clearly defined, it behooves the researcher to evaluate both toxicological and physiological features of the response.

Rate and capacity of hepatic microsomal ring-hydroxylation of phenol to hydroquinone and catechol in rainbow trout (Oncorhynchus mykiss)

Rainbow trout (Oncorhynchus mykiss) liver microsomes were used to study the rate of ring-hydroxylation of phenol at 11 and 25 degrees C by directly measuring the production of two potentially toxic metabolites, hydroquinone (HQ) and catechol (CAT). An HPLC method with integrated ultraviolet and electrochemical detection was used for metabolite identification and quantification at low (pmol) formation rates found in fish. The Michaelis-Menten saturation kinetics for the production of HQ and CAT over a range of phenol concentrations were determined at trout physiological pH. The apparent Km's for the production of HQ and CAT at 11 degrees C were 14+/-1 and 10+/-1 mM, respectively, with Vmax's of 552+/-71 and 161+/-15 pmol/min per mg protein. The kinetic parameters for HQ and CAT at 25 degrees C were 22+/-1 and 32+/-3 mM (Km) and 1752+/-175 and 940+/-73 pmol/min per mg protein (Vmax), respectively. The calculated increase in metabolic rate per 10 degrees C temperature rise (Q(10)) was 2.28 for HQ and 3.53 for CAT production. These experiments assess the potential for metabolic bioactivation in fish through direct quantification of putative reactive metabolites at the low, but toxicologically significant, chemical concentrations found in aquatic organisms. This work initiates a series of studies to compare activation pathway, rate, and capacity across fish species, providing a basis for development of biologically-based dose response models in diverse species.

The effect of paclitaxel on gene expression and activity of arylamine N-acetyltransferase and DNA-2-aminofluorene adduct formation in human leukemia HL-60 cells

N-Acetylation is recognized as the first step in arylamine metabolism. The enzyme responsible for N-acetylation is called arylamine N-acetyltransferase (NAT),which uses acetyl coenzyme A as the acetyl group donor. Paclitaxel has been shown to exhibit antineoplastic and anticancer activity. In this study, paclitaxel was selected to determine the inhibition of arylamine N-acetyltransferase activity, gene expression (NAT mRNA) and DNA-2-aminofluorene adduct formation in human leukemia HL-60 cell line. Paclitaxel (0.01-l microM) did decrease the level of NAT mRNA in a dose-dependent manner. The results demonstrated that paclitaxel inhibited NAT activity and DNA-2-aminofluorene adduct formation in human leukemia HL-60 cells in a dose-dependent manner. Using standard steady-state kinetic analysis, it was demonstrated that paclitaxel was a possible uncompetitive inhibitor to NAT activity in cytosols based on the decrease in apparent values of K(m) and V(max). This report is the first demonstration that paclitaxel affected human leukemia HL-60 cells NAT activity and DNA-2-aminofluorene adduct formation.

Sex differences in the metabolism of (+)- and (-)-limonene enantiomers to carveol and perillyl alcohol derivatives by cytochrome p450 enzymes in rat liver microsomes

(+)-Limonene is reported to cause nephropathy in male rats, but not in female rats and other species of animals including mice, rabbits, guinea pigs, and dogs. Male rats contain high levels of alpha2u-globulin in kidneys, and it has been shown that limonene and/or its metabolites are able to bind noncovalently to alpha2u-globulin, resulting in an accumulation of protein droplets in the renal tubules. In this study, we investigated whether (+)- and (-)-limonene enantiomers are differentially metabolized by liver microsomes of male and female rats. (+)- and (-)-limonene enantiomers were found to be oxidized to their respective trans-carveol (6-hydroxylation) and perillyl alcohol (7-hydroxylation) derivatives in greater amounts by liver microsomes of male rats than those of female rats. The limonene hydroxylation activities were not detected in liver microsomes of rat fetuses and were increased developmentally after birth, only in male rats. Treatment of male rats with phenobarbital significantly increased liver microsomal 6-hydroxylation activities with both enantiomers whereas beta-naphthoflavone, isosafrole, and pregnenolone 16alpha-carbonitrile did not cause such effects. Anti-P450 2C9 which cross-reacts with rat P450 2C11 inhibited limonene hydroxylations catalyzed by liver microsomes of untreated male rats, and it was also found that anti-P450 2B1 suppressed the activities catalyzed by liver microsomes of phenobarbital-treated rats. Possible roles of P450 2C11 and P450 2B1 in the limonene hydroxylation activities were supported by the experiments with purified rat liver P450s in reconstitution systems and with recombinant rat P450s in Trichoplusia ni. Our present results showing that there are sex-related differences in the oxidative metabolism of limonene enantiomers by liver microsomes may provide useful information on the basis of limonene-induced toxicities in different animal species.

Biotransformation of organophosphorus compounds

This study reviews current understanding of mechanisms of biotransformation of organophosphorus compounds (OPC). The first part of this article covers chemical aspects of biotransformation describing reactions that lead to activation or detoxication of OPC. The second part explains biochemical mechanisms of biotransformation describing the role of enzymes that are involved in this process. Among them are the enzymes that take part in metabolic activation of OPC such as cytochrome P450 system, NADPH-cytochrome P450 reductase and flavin-containing monooxygenases. Among enzymes participating in detoxication of OPC, the role of phosphoric triester hydrolases, carboxylesterases and glutathione redox system is explained. This article also deals with other aspects of detoxication of OPC such as protein binding and the role of tissue depots for these compounds.

Common and uncommon cytochrome P450 reactions related to metabolism and chemical toxicity

Cytochrome P450 (P450) enzymes catalyze a variety of reactions and convert chemicals to potentially reactive products as well as make compounds less toxic. Most of the P450 reactions are oxidations. The majority of these can be rationalized in the context of an FeO(3+) intermediate and odd electron abstraction/rebound mechanisms; however, other iron-oxygen complexes are possible and alternate chemistries can be considered. Another issue regarding P450-catalyzed reactions is the delineation of rate-limiting steps in the catalytic cycle and the contribution to reaction selectivity. In addition to the rather classical oxidations, P450s also catalyze less generally discussed reactions including reduction, desaturation, ester cleavage, ring expansion, ring formation, aldehyde scission, dehydration, ipso attack, one-electron oxidation, coupling reactions, rearrangement of fatty acid and prostaglandin hydroperoxides, and phospholipase activity. Most of these reactions are rationalized in the context of high-valent iron-oxygen intermediates and Fe(2+) reductions, but others are not and may involve acid-base catalysis. Some of these transformations are involved in the bioactivation and detoxication of xenobiotic chemicals.

Forging the links between metabolism and carcinogenesis

Metabolism plays important roles in chemical carcinogenesis, both good and bad. The process of carcinogen metabolism was first recognized in the first half of the twentieth century and developed extensively in the latter half. The activation of chemicals to reactive electrophiles that become covalently bound to DNA and protein was demonstrated by Miller and Miller [Cancer 47 (1981) 2327]. Today many of the DNA adducts formed by chemical carcinogens are known, and extensive information is available about pathways leading to the electrophilic intermediates. Some concepts about the stability and reactivity of electrophiles derived from carcinogens have changed over the years. Early work in the field demonstrated the ability of chemicals to modulate the metabolism of carcinogens, a phenomenon now described as enzyme induction. The cytochrome P450 enzymes play a prominent role in the metabolism of carcinogens, both in bioactivation and detoxication. The conjugating enzymes can also play both beneficial and detrimental roles. As an example of a case in which several enzymes affect the metabolism and carcinogenicity of a chemical, aflatoxin B1 (AFB1) research has revealed insight into the myriad of reaction chemistry that can occur even with a 1s half-life for a reactive electrophile. Further areas of investigation involve the consequences of enzyme variability in humans and include areas such as genomics, epidemiology, and chemoprevention.

Tumourigenic studies on deltamethrin in Swiss albino mice

Deltamethrin, an alpha-cyano type II synthetic pyrethroid insecticide is used to control a wide range of insects on a variety of crops. Deltamethrin is reported to cause many adverse effects on non-target species. Deltamethrin is reported to cause DNA damage and micronuclei induction in human lymphocytes. It is highly toxic for other organisms such as aquatic invertebrates, fish and Daphnia. About the tumorigenic risk (both tumour initiating and promoting) associated with deltamethrin exposure, very few reports are available in literature. In the present set of investigations, deltamethrin has been evaluated for its tumorigenic and co-carcinogenic (tumour initiating and tumour promoting) potential following long term dermal exposure in Swiss albino mice. The results revealed that deltamethrin has only tumour initiating potential in both the sexes of Swiss albino mice, initiated with deltamethrin and promoted by standard tumour promoter, 12-O-tetra decanoyl phorbol-13-acetate (TPA). In the single dose initiated mice (deltamethrin 4 mg/kg body weight, once only), 44% males and 43% females developed benign skin tumours. A much higher incidence of tumorigenesis was recorded in multiple dose initiated animals (deltamethrin 4 mg/kg body weight, three times per week for 3 weeks), where 71% male and 75% female mice developed tumours at the site of application of deltamethrin. Deltamethrin exposure failed to show any tumour promoting and complete tumorigenic potential at all the three tested dose levels.

Characterization of T cell responses to fragrances

Fragrances are worldwide a major cause of allergic contact dermatitis (ACD), a delayed-type hypersensitivity reaction mediated by T lymphocytes. We investigated T cell responses to fragrances using peripheral blood mononuclear cells (PBMC) and T cells from skin lesions of fragrance-allergic patients. The components of a fragrance mixture (eugenol, isoeugenol, geraniol, oak moss, alpha-amyl cinnamic aldehyde, cinnamic aldehyde, cinnamic alcohol, and hydroxycitronellal) that is commonly used in the patch test were studied in vitro in the lymphocyte transformation test (LTT). PBMC from fragrance-allergic patients (n = 32) showed significant stimulations to all eight fragrances. The calculated stimulation indices (SI) varied between 2.1 and 21.8. The influence of metabolic enzymes on T cell stimulation was studied for two fragrances. Interestingly, stimulation of eugenol and isoeugenol was increased in the presence of antigen-modified human liver microsomes (CYP450) or recombinant CYP1A1 in five of seven cases. Furthermore, we established 18 T cell clones (TCC) from a skin lesion reacting specifically to eugenol. FACS analysis revealed that the majority (n = 15, 83%) of TCC were CD3(+), CD4(+), and HLA-DR(+). Seventeen percent (n = 3) of the clones were CD8(+). TCC (n = 4) released significant amounts of IL-2 and IFN-gamma but no IL-4 and IL-5. In addition, CD4(+) TCC (n = 3) showed antigen-induced cytotoxic activities against autologous B cells. In summary, we demonstrated for the first time that fragrance-specific CD4(+) and CD8(+) T lymphocytes are present in fragrance-allergic individuals. In addition, our results suggest that CYPs can be involved in the formation of the nominative antigen.

Allelic variants of human cytochrome P450 1A1 (CYP1A1): effect of T461N and I462V substitutions on steroid hydroxylase specificity

Steroid hydroxylation specificities were determined for the wild-type and the two allelic variants of the polymorphic human cytochrome P450 1A1 (CYP1A1) that were associated with amino acid exchanges near the active site of the enzyme. All three variants were expressed in insect cells using recombinant baculoviruses. Each variant protein was spectrally and enzymatically active, as judged by the ability of the prepared microsomes to catalyse O-dealkylation of ethoxyresorufin and pentoxyresorufin in cumene hydroperoxide-mediated reactions. With progesterone and testosterone as substrate, all variants of CYP1A1 exhibited high, but different steroid hydroxylation activities (8-40 pmol hydroxysteroid/min/pmol CYP1A1, i.e. approximately 800-4000 pmol/min/mg microsomal protein). All three variants exclusively catalysed 6beta-hydroxylation of both steroids. In addition, towards progesterone as substrate, all variants also catalysed 16alpha-hydroxylations with approximately half of the rate of 6beta-hydroxylation activity. With progesterone as substrate for hydroxylation in 6beta position, CYP1A1 T461N had the lowest catalytic efficiency (Vmax/Km) followed by the CYP1A1 I462V variant and the wild-type enzyme. For 16alpha-hydroxylation of progesterone, the catalytic efficiencies of the three variants are not statistically significantly different. With testosterone as substrate the CYP1A1 1462V variant catalysed 6beta-hydroxylation with an efficiency considered not significantly different compared to the wild-type, although both the apparent Km and Vmax were significantly decreased. In contrast, the CYP1A1 T461N variant exhibited significantly decreased catalytic efficiencies compared to both the 1462V variant and the wild-type enzyme. These results indicate that all three naturally occurring allelic variants of human CYP1A1 hydroxylate steroid hormones with varying efficiencies in a stereo- and regioselective manner, whereby the CYP1A1 T461N variant exhibited the lowest catalytic efficiency.

Ethoxyresorufin-O-deethylase (EROD) activity in fish as a biomarker of chemical exposure

This review compiles and evaluates existing scientific information on the use, limitations, and procedural considerations for EROD activity (a catalytic measurement of cytochrome P4501A induction) as a biomarker in fish. A multitude of chemicals induce EROD activity in a variety of fish species, the most potent inducers being structural analogs of 2,3,7,8-tetracholordibenzo-p-dioxin. Although certain chemicals may inhibit EROD induction/activity, this interference is generally not a drawback to the use of EROD induction as a biomarker. The various methods of EROD analysis currently in use yield comparable results, particularly when data are expressed as relative rates of EROD activity. EROD induction in fish is well characterized, the most important modifying factors being fish species, reproductive status and age, all of which can be controlled through proper study design. Good candidate species for biomonitoring should have a wide range between basal and induced EROD activity (e.g., common carp, channel catfish, and mummichog). EROD activity has proven value as a biomarker in a number of field investigations of bleached kraft mill and industrial effluents, contaminated sediments, and chemical spills. Research on mechanisms of CYP1A-induced toxicity suggests that EROD activity may not only indicate chemical exposure, but also may also precede effects at various levels of biological organization. A current research need is the development of chemical exposure-response relationships for EROD activity in fish. In addition, routine reporting in the literature of EROD activity in standard positive and negative control material will enhance confidence in comparing results from different studies using this biomarker.

Effect of liquorice and glycyrrhizin on rat liver carcinogen metabolizing enzymes

We investigated the effect of single or repeated intake of conspicuous amounts of licorice root extract (LE, 3138 or 6276 mg/kg body weight (bw) per os) or its natural constituent glycyrrhizin (G, 240 or 480 mg/kg bw per os) on Sprague-Dawley rat liver monooxygenases. Whereas a single LE or G dose was unable to affect CYP superfamily, four daily doses induced CYP3A, CYP1A2 and to varying extents CYP2B1-linked monooxygenases. A boosting effect on testosterone 6beta- (CYP3A1/2, CYP1A1/2), 7alpha- (CYP1A1/2, CYP2A1), 16alpha- (CYP2B1, CYP2C11), 2alpha- (CYP2C11) and 2beta- (CYP3A1, CYP1A1) -dependent oxidases as well as on androst-4-ene-3,17-dione- (CYP3A1/2) -supported monooxygenases were also achieved. Harmful outcomes associated to CYP changes (e.g. cotoxicity, cocarcinogenicity and promotion) may be of concern.

The many consequences of chemical- and genetic-based modulation of drug metabolizing enzyme activities

The induction or inhibition of the metabolizing enzyme activities by a great deal of substances (including drugs) influence their toxicological or pharmacological outcomes as well as that of other xenobiotics or drugs to which human is simultaneously exposed. The dual bioactivating/detoxificating nature of both phase I and phase II enzymes poses such modulation as an unavoidable unhealthy phenomenon. Therefore, the proposed strategies in preventive medicine which foresee boosting or depressing enzymatic effects such as those in the field of cancer chemoprevention, should be carefully reconsidered before their credibility would be compromised. As the phenotypic features, genetic polymorphisms leading to the occurrence of high or low metabolizers in the population, each at high risk to certain forms of toxicity, behave as a sort of "constitutive" enzymatic modulation. Thus, considering the double-edged sword nature (detoxi-toxicant) of these catalysts towards ubiquitous environmental pollutants, the search for individual susceptibility by means of the genotypic analysis represents a very intriguing problem. However, the knowledge of the "overall" metabolic fingerprint associated to the phenotypic analysis in a single person could offer an interesting way to (partially) control human risk by making suitable (well aimed) modifications of determined life-styles (e.g. stop smoking or drinking) or particular dietetic practices (e.g. stop eating high cooked meat or fish) as well as selecting personalised drug adjustments by physicians either in terms of dosage or fitting drug.

Renal metabolism of acrylonitrile to cyanide: in vitro studies

Acrylonitrile (VCN) is a widely used industrial chemical. The present work examines the mechanism of its renal toxicity. In renal centrifugal fractions from Sprague-Dawley rats, the metabolism of VCN to cyanide (CN(-)) was highest in the microsomal fraction and required a NADPH-generating system in the presence of magnesium ions for maximum activity. This biotransformation of VCN to CN(-)was characterised with respect to time (15 min), microsomal protein concentration (3 mg ml(-1)), pH (7.5) and temperature (37 degrees C). The V(max)of the reaction was 118.2 pmol CN(-)mg(-1)protein min(-1)and K(m)was 160.2 micromol VCN. Activation of VCN to CN(-)was markedly increased in microsomes obtained from phenobarbital (PB), ethanol, 4-methylpyrazole and 3-methylcholanthrene-treated rats by 161.5, 89.6, 71.0 and 50.2%, respectively. Addition of SKF 525-A (5x10(-4)m) or benzimidazole (2 m m) to the incubation mixtures significantly inhibited VCN metabolism by 66.6 and 78.8%, respectively. VCN metabolism to CN(-)was enhanced significantly by the addition of 10 m m of glutathione (GSH), l -cysteine, d -penicillamine, cysteamine or 2-mercaptoethanol to 389.5, 886.5, 611. 1, 145.5 and 384.0% of control, respectively. These findings indicate that VCN is metabolised in the kidney via cytochrome P-450-dependent mixed function oxidase system. 1999 Academic Press.

Pyrrolizidine alkaloids in human diet

Pyrrolizidine alkaloids are the leading plant toxins associated with disease in humans and animals. Upon ingestion, metabolic activation in liver converts the parent compounds into highly reactive electrophiles capable of reacting with cellular macromolecules forming adducts which may initiate acute or chronic toxicity. The pyrrolizidine alkaloids present a serious health risk to human populations that may be exposed to them through contamination of foodstuffs or when plants containing them are consumed as medicinal herbs. Some pyrrolizidine alkaloids (PA) adducts are persistent in animal tissue and the metabolites may be re-released and cause damage long after the initial period of ingestion. PAs are also known to act as teratogens and abortifacients. Chronic ingestion of plants containing PAs has also led to cancer in experimental animals and metabolites of several PAs have been shown to be mutagenic in the Salmonella typhimurium/mammalian microsome system. However, no clinical association has yet been found between human cancer and exposure to PAs. Based on the extensive reports on the outcome of human exposure available in the literature, we conclude that while humans face the risk of veno-occlusive disease and childhood cirrhosis PAs are not carcinogenic to humans.

Regulation of gene expression by reactive oxygen

Reactive oxygen intermediates are produced in all aerobic organisms during respiration and exist in the cell in a balance with biochemical antioxidants. Excess reactive oxygen resulting from exposure to environmental oxidants, toxicants, and heavy metals perturbs cellular redox balance and disrupts normal biological functions. The resulting imbalance may be detrimental to the organism and contribute to the pathogenesis of disease and aging. To counteract the oxidant effects and to restore a state of redox balance, cells must reset critical homeostatic parameters. Changes associated with oxidative damage and with restoration of cellular homeostasis often lead to activation or silencing of genes encoding regulatory transcription factors, antioxidant defense enzymes, and structural proteins. In this review, we examine the sources and generation of free radicals and oxidative stress in biological systems and the mechanisms used by reactive oxygen to modulate signal transduction cascades and redirect gene expression.

Tandem mass spectrometry linked fraction collection for the isolation of drug metabolites from biological matrices

An automated mass spectrometric linked fraction collection system is described which enables on-line examination of isolated components based on molecular-ion and product-ion information. This system has been used successfully to specifically isolate drug-related material from complex biological fluids to aid structural identification. Metabolites have been isolated with sufficient purity to allow unequivocal characterisation by 1H nuclear magnetic resonance spectroscopy. This system has the advantage that isolation of the components of interest is not triggered by a simple contact closure. Therefore fraction collection is not biased by limitations in either the detector (e.g. insufficient sensitivity) or the analyst (e.g. programmed collection of predicted metabolites only). Furthermore, all isolated components are readily available post fractionation for additional screening.

The pitfall of detoxifying enzymes

One of the major mechanism of chemical protection against mutagenesis, carcinogenesis and other forms of toxicity is the induction of phase-II metabolizing enzymes such as UDP-glucuronosyl transferases, glutathione S-transferases and NAD(P)H quinone reductase, or inhibition of typical phase-I reactions. The use of selective inducers of conjugating enzymes or inhibitors of CYP- and FAD-dependent monooxygenases revealed the possibility of reducing the expression of certain forms of malignancy. However, the use of some anti-initiating entities devised to reduce tumor initiation, seems to receive invalidated justification. Indeed, considering the double edge-sword nature (activating or detoxifying) of drug metabolizing enzymes as well as the myriad of xenobiotics to which human is exposed, any attempt to modulate such catalysts by dietary components (including drugs) could lead to an increased cancer risk. Paradoxically, it has been recently proposed the use of metabolizing liver preparations, isolated from phase-II induced rodents, as a novel bioactivating model in the field of genetic toxicology. Exogenous microsomal (S9) fraction prepared from 2-(3)-tert-butyl-4-hydroxyanisole (BHA) (monofunctional post-oxidative inducer) treated mice are able to increase the DNA binding and genotoxic response of pre-mutagens. On the whole, the use of enzyme modulators in cancer chemoprevention, for their ability to simultaneously reduce or increase pre-carcinogen bioactivation, should be carefully reconsidered.

Role of cytochrome P-450 in quinalphos toxicity: effect on hepatic and brain antioxidant enzymes in rats

Quinalphos (QP), an organophosphate pesticide, is used in controlling the pests of a variety of crops. To understand the mechanism of the metabolic basis of the toxicity of QP it was thought pertinent to study the role of cytochrome P-450 (P450) and antioxidant enzyme systems. Albino rats treated orally with QP (0.52 and 1.04 mg/kg body weight) for 60 days showed a significant decrease in body, brain and liver weights. Hepatic P450 content and its dependent monooxygenases, namely aryl hydrocarbon hydroxylase (AHH) and ethoxyresorufin-O-deethylase (ERD), were induced to 1.8-2.5-fold, while neuronal AHH was induced to 1.8-fold following QP treatment (1.04 mg/kg) to animals. The hepatic antioxidant defence system, comprising catalase, glutathione (GSH) reductase, superoxide dismutase (SOD) and GSH peroxidase, was also significantly increased in QP-treated animals, while in the brain only catalase was increased and GSH reductase decreased. There was no significant change in hepatic GSH content and lipid peroxide levels in QP treated animals at any dose group in comparison with the control group. Pretreatment of rats with phenobarbitone (PB) or 3-methylcholanthrene (MC) (P450 inducers) prevented mortality caused by the LD50 dose of QP, whereas pretreatment with cobalt chloride (a P450 inhibitor) enhanced the mortality rate to 100% within 3 days. From the above study it can be inferred that the toxicity of QP may be due to the parent compound or its metabolite(s) produced prior to P450 oxidation and that the induction of P450 system by QP may be a defence mechanism.

Isolation of a novel metabolizing system enriched in phase-II enzymes for short-term genotoxicity bioassays

Murine S9 liver fractions isolated from mice fed 7.5 g kg-1 2(3)-tert-Butyl-4-hydroxyanisole (BHA) for 3 weeks were tested to determine: (a) the profile of both phase-I and phase-II xenobiotic metabolizing enzymes; (b) their ability to induce in vitro covalent binding of some precarcinogens to calf thymus DNA; and (c) their activation in a standard genetic toxicology assay. With regard to phase-I pathway, the S9 fraction expressed various cytochrome P-450-(CYP) (classes 1A1, 1A2, 2B1, 2E1, and 3A)-dependent biotransformation enzymes at levels comparable with those present in murine control liver. For post-oxidative enzymes, the S9 expressed high levels of glutathione S-transferases (up to 12-fold increase), glutathione S-epoxide-transferase (up to 2.6-fold), UDP-glucuronosyl transferase (up to 5.3-fold) and epoxide hydrolase (up to 2.6-fold) activities, as compared to untreated mice. The in vitro DNA binding of the precarcinogenic agents [14C]-1,4-dichlorobenzene, [14C]-1,2-dichlorobenzene and [14C]-1,4-dibromobenzene, mediated by BHA-induced cytosol and/or microsomal preparation, showed an increase in specific activity comparable to that observed with phase-I (PB/beta NF) induced S9. In some instances, covalent binding was even more elevated using the BHA-induced systems as compared with traditional S9 fractions. For example, cytosol derived from BHA-administered mice was able to induce a significant binding to calf thymus DNA up to 26.2-fold increase for [14C]-1,4-dichlorobenzene, while cytosol from PB/beta NF was not. A high mutagenic response on diploid D7 strain of Saccharomyces cerevisiae as exemplified by a marked induction of mitotic gene conversion and point (reverse) mutation confirmed that BHA-derived S9 fractions activate precarcinogens to final genotoxins. Because a number of chemicals are activated by either oxidative or post-oxidative enzymes, the use of metabolizing biosystems, with an enhanced phase-II pathway, together with classical S9 fractions, can improve the sensitivity of the assay in detecting unknown genotoxins.

Cancer chemoprevention: some complications and limitations

Chemopreventive strategies are very attractive and have earned serious consideration as a potential means of controlling cancer incidence. However, the use of some anti-initiating entities (enzyme inducers or inhibitors) devised to reduce tumor initiation is controversial. Indeed, considering the double-edged-sword (activating or detoxifying) nature of drug metabolizing enzymes, any attempt to modulate such catalysts by dietary components (including drugs) may lead to cancer risk.

Oxidation kinetics of ethanol by human cytochrome P450 2E1. Rate-limiting product release accounts for effects of isotopic hydrogen substitution and cytochrome b5 on steady-state kinetics

A number of cytochrome P450 (P450) 2E1 substrates are known to show kinetic deuterium isotope effects of approximately 5 on Km (DK = DKm/HKm), but not on kcat, in rat liver microsomes (e.g. N-nitrosodimethylamine, ethanol, and CH2Cl2). We observed DKm values of 3-5 for recombinant human P450 2E1-catalyzed ethanol oxidation. Replacing NADPH and O2 with the oxygen surrogate cumene hydroperoxide yielded similar results. Ferric P450 2E1 reduction was fast (k >1000 min-1) even in the absence of substrate. These results indicate that the basis for the increase in Km is in the latter portion of the catalytic cycle. The intrinsic isotope effect (Dk) for ethanol oxidation was determined (competitively) to be 3.8, indicating that C-H bond cleavage is isotopically sensitive. Pre-steady-state studies showed a burst of product formation (k = 410 min-1), with the burst amplitude corresponding to the P450 concentration. Deuteration of ethanol resulted in an isotope effect of 3.2 on the rate of the burst. We conclude that product release is rate-limiting in the oxidation of ethanol to acetaldehyde by P450 2E1. The steady-state kinetics can be described by a paradigm in which the kcat approximates the rate of product release, and Km is an expression in which the denominator is dominated by the rate of C-H bond breaking.

Tyrosine hydroxylase: mechanisms of oxygen radical formation

A new mechanism of oxygen radical formation in dopaminergic neurons is proposed, based on the oxidative mechanism of tyrosine hydroxylase. The cofactor (6R,6S)-5,6,7,8-tetrahydrobiopterin can rearrange in solution which allows an autoxidation reaction producing O2.-, H2O2 and HO.. The combination of tyrosine hydroxylase and the cofactor produces more oxygen radicals than does the autoxidation of the cofactor. This production of oxygen radicals could be damaging to dopaminergic neurons. In the presence of tyrosine, the enzyme produces less radicals than it does in the absence of tyrosine. Mechanisms are proposed for the generation of reactive oxygen species during the autoxidation of the cofactor and during enzymatic catalysis. The generation, by tyrosine hydroxylase, of very small amounts of oxygen radicals over the period of 65 years could contribute to the oxidative stress that causes Parkinson's disease.