The role of 4-bromophenol and 4-bromocatechol in bromobenzene covalent binding and toxicity in isolated rat hepatocytes

Identification of Bromophenols' glucuronidation and its induction on UDP- glucuronosyltransferases isoforms

Bromophenols (BPs) are prominent environmental pollutants extensively utilized in aquaculture, pharmaceuticals, and chemical manufacturing. This study aims to identify UDP- glucuronosyltransferases (UGTs) isoforms involved in the metabolic elimination of BPs. Mono-glucuronides of BPs were detected in human liver microsomes (HLMs) incubated with the co-factor uridine-diphosphate glucuronic acid (UDPGA). The glucuronidation metabolism reactions catalyzed by HLMs followed Michaelis-Menten or substrate inhibition kinetics. Recombinant enzymes and inhibition experiments with chemical reagents were employed to phenotype the principal UGT isoforms participating in BP glucuronidation. UGT1A6 emerged as the major enzyme in the glucuronidation of 4-Bromophenol (4-BP), while UGT1A1, UGT1A6, and UGT1A8 were identified as the most essential isoforms for metabolizing 2,4-dibromophenol (2,4-DBP). UGT1A1, UGT1A8, and UGT2B4 were deemed the most critical isoforms in the catalysis of 2,4,6-tribromophenol (2,4,6-TBP) glucuronidation. Species differences were investigated using the liver microsomes of pig (PLM), rat (RLM), monkey (MyLM), and dog (DLM). Additionally, 2,4,6-TBP effects on the expression of UGT1A1 and UGT2B7 in HepG2 cells were evaluated. The results demonstrated potential induction of UGT1A1 and UGT2B7 upon exposure to 2,4,6-TBP at a concentration of 50 μM. Collectively, these findings contribute to elucidating the metabolic elimination and toxicity of BPs.

Different Renal Chronotoxicity of Bromobenzene and Its Intermediate Metabolites in Mice

Bromobenzene (BB) is known to pose a serious threat to human health. We previously demonstrated that BB showed chronotoxicity, that is, daily fluctuations in the severity of hepatotoxicity induced in mice. Although BB showed mild nephrotoxicity, a daily fluctuation was not observed in this toxicity. This might be attributed to the fact that BB-induced chronotoxicity is observed only in the liver and not in the kidneys and that the damage caused by BB is prominent in the liver, masking the daily fluctuation in nephrotoxicity. To confirm these two possibilities, we examined the daily fluctuations in nephrotoxicity due to BB intermediate metabolites that target the kidneys: 3-bromophenol, bromohydroquinone, and 4-bromocatechol. Mice were injected with 3-bromophenol, bromohydroquinone, or 4-bromocatechol intraperitoneally at six different time points in a day (zeitgeber time (ZT): ZT2, ZT6, ZT10, ZT14, ZT18, or ZT22). Mortality was monitored for 7 d post-injection. Mice were more sensitive to the acute toxicity of these metabolites around at ZT14 (dark-phase) exposure than around at ZT2 (light-phase) exposure. Furthermore, mice administered with a non-lethal dose of 4-bromocatechol showed significant increases in the levels of plasma blood urea nitrogen and renal malondialdehyde at ZT14 exposure. Moreover, glutathione peroxidase-4, a ferroptosis indicator, was attenuated at ZT14 exposure. These results indicate the toxicity of BB metabolites was higher during the dark-phase exposure, and demonstrate the reason why the diurnal variation of nephrotoxicity by BB was not observed in our previous report is that renal damage was masked due to severe hepatic damage.

Liver protein targets of hepatotoxic 4-bromophenol metabolites

The hepatotoxicity of bromobenzene (BB) is directly related to the covalent binding of both initially formed epoxide and secondary quinone metabolites to at least 45 different liver proteins. 4-Bromophenol (4BP) is a significant BB metabolite and a precursor to reactive quinone metabolites; yet, when administered exogenously, it has negligible hepatotoxicity as compared to BB. The protein adducts of 4BP were thus labeled as nontoxic [Monks, T. J., Hinson, J. A., and Gillette, J. R. (1982) Life Sci. 30, 841-848]. To help identify which BB-derived adducts might be related to its cytotoxicity, we sought to identify the supposedly nontoxic adducts of 4BP and eliminate them from the BB target protein list. Administration of [(14)C]-4BP to phenobarbital-induced rats resulted in covalent binding of 0.25, 0.33, and 0.42 nmol equiv 4BP/mg protein in the mitochondrial, microsomal, and cytosolic fractions, respectively. These values may be compared to published values of 3-6 nmol/mg protein from a comparable dose of [(14)C]-BB. After subcellular fractionation and 2D electrophoresis, 47 radioactive spots on 2D gels of the mitochondrial, microsomal, and cytosolic fractions were excised, digested, and analyzed by LC-MS/MS. Twenty-nine of these spots contained apparently single proteins, of which 14 were nonredundant. Nine of the 14 are known BB targets. Incubating freshly isolated rat hepatocytes with 4BP (0.1-0.5 mM) produced time- and concentration-dependent increases in lactate dehydrogenase release and changes in cellular morphology. LC-MS/MS analysis of the cell culture medium revealed rapid and extensive sulfation and glucuronidation of 4BP as well as formation of a quinone-derived glutathione conjugate. Studies with 7-hydroxycoumarin, (-)-borneol, or D-(+)-galactosamine showed that inhibiting the glucuronidation/sulfation of 4BP increased the formation of a GSH-bromoquinone adduct, increased covalent binding of 4BP to hepatocyte proteins, and potentiated its cytotoxicity. Taken together, our data demonstrate that protein adduction by 4BP metabolites can be toxicologically consequential and provide a mechanistic explanation for the failure of exogenously administered 4BP to cause hepatotoxicity. Thus, the probable reason for the low toxicity of 4BP in vivo is that rapid conjugation limits its oxidation and covalent binding and thus its toxicity.

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.

Metabolism of stavudine-5'-[p-bromophenyl methoxyalaninyl phosphate], stampidine, in mice, dogs, and cats

We examined the pharmacokinetics and metabolism of the experimental nucleoside reverse transcriptase inhibitor compound stampidine in mice, dogs, and cats. Also reported is the identification of p-bromophenyl sulfate (p-Br-Ph-S) as a major in vivo phase II metabolite of stampidine. Liver cytosol was shown to take part in the hydrolysis of stampidine to form alaninyl-STV-monophosphate (Ala-STV-MP), 2',3'-didehydro-3'-deoxythymidine (STV), and p-bromophenol; p-bromophenol was further sulfonated by sulfotransferase to form p-Br-Ph-S. Notably, plasma concentrations of stampidine >4 logs higher than its IC(50) value can be achieved in both dogs and cats after its p.o administration at a 100-mg/kg dose level. In dogs as well as cats, stampidine was metabolized to yield micromolar concentrations of the active metabolites ala-STV-MP and STV, which is similar to the metabolism of stampidine in mice. These findings encourage the further development of this new antiviral agent for possible clinical use in human immunodeficiency virus-infected patients.

Reactive intermediates and their toxicological significance

Many chemicals that cause toxicity do so via metabolism to biologically reactive metabolites. However, the nature of the interaction between such reactive metabolites and various cellular components, and the mechanism(s) by which these interactions eventually lead to cell death are poorly understood. The relative importance of macromolecular alkylation (covalent binding), lipid peroxidation, alterations in thiol, calcium and energy homeostasis are discussed with reference to specific toxicants. It is concluded that the cytotoxic effects of reactive metabolites are a consequence of simultaneous and/or sequential alterations in several cellular processes. Further studies are required to determine the relationship between these alterations and cell death.

Antagonism of bromobenzene-induced hepatotoxicity by phentolamine: evidence for a metabolism-independent intervention

A previous study has revealed that phentolamine markedly antagonizes the bromobenzene-induced hepatotoxicity and lethality in B6C3F1 mice. One potential mechanism by which phentolamine may diminish the bromobenzene-induced hepatotoxicity is by a direct or indirect interference with the metabolism of bromobenzene to toxic metabolites. In the present study, phentolamine cotreatment failed to alter the elimination of bromobenzene from serum or the distribution of bromobenzene to liver. This suggests that phentolamine cotreatment does not indirectly interfere with bromobenzene bioactivation secondary to changes in bromobenzene absorption, distribution, or elimination. Further, a phentolamine concentration 10- to 20-fold greater than those measured in vivo failed to alter the in vitro metabolism of bromobenzene to its ortho- and para-phenolic metabolites. It is believed that para-bromophenol represents the rearrangement product of the hepatotoxic 3,4-epoxide and that ortho-bromophenol is a product of the nonhepatotoxic 2,3-epoxide pathway. Thus, it appears that phentolamine does not antagonize bromobenzene-induced hepatotoxicity by inhibiting the formation of hepatotoxic intermediates, nor by enhancing metabolism via the nonhepatotoxic pathway. On the basis of these studies, we conclude that phentolamine antagonism of bromobenzene-induced hepatotoxicity occurs through a mechanism independent of bromobenzene bioactivation.

In vitro cytotoxicity of allyl alcohol and bromobenzene in a novel organ culture system

Two well-known hepatotoxicants, allyl alcohol (AA) and bromobenzene (BB), were studied using an in vitro system of cultured liver slices from control and phenobarbital-treated rats, respectively. Dose- and time-dependent increases in media lactate dehydrogenase (LDH), and decreases in slice K+ content and in protein synthesis were observed in rat liver slices incubated with either compound at concentrations between 0.1 and 1 mM over a period of 6 hr. The histopathological changes which occurred in the intoxicated slices appeared to parallel these biochemical changes. Additionally, the toxicity of either BB or AA, evaluated at 4 hr, was inhibited when slices were preincubated for 30 min with beta-ethyl-2,2-diphenylvalerate hydrochloride (SKF 525-A) (0.1 mM) or pyrazole (1.0 mM), respectively. In this in vitro incubation system the cytotoxicity of xenobiotics can be studied under conditions where the multicellular hepatic lobular architecture is partially maintained, and alterations in biochemical and functional processes may be correlated to pathological changes.