Comparative Toxicity and Metabolism of N-Acyl Homologues of Acetaminophen and Its Isomer 3'-Hydroxyacetanilide.

The hepatotoxicity of acetaminophen (APAP) is generally attributed to the formation of a reactive quinoneimine metabolite (NAPQI) that depletes glutathione and covalently binds to hepatocellular proteins. To explore the importance of the N-acyl group in APAP metabolism and toxicity, we synthesized 12 acyl side chain homologues of acetaminophen (APAP) and its 3'-regioisomer (AMAP), including the respective N-(4-pentynoyl) analogues PYPAP and PYMAP. Rat hepatocytes converted APAP, AMAP, PYPAP, and PYMAP extensively to O-glucuronide and O-sulfate conjugates in varying proportions, whereas glutathione or cysteine conjugates were observed only for APAP and PYPAP. PYPAP and PYMAP also underwent N-deacylation followed by O-sulfation and/or N-acetylation to a modest extent. The overall rates of metabolism in hepatocytes varied approximately 2-fold in the order APAP < AMAP ≈ PYPAP < PYMAP. Rat liver microsomes supplemented with NADPH and GSH converted APAP and PYPAP to their respective glutathione conjugates (formed via a reactive quinoneimine intermediate). With PYPAP only, a hydroxylated GSH conjugate was also observed. Thus, differences in biotransformation among these analogues were modest and mostly quantitative in nature. Cytotoxicity was evaluated in cultured hepatocytes by monitoring cell death using time-lapse photomicrography coupled with Hoechst 33342 and CellTox Green dyes to facilitate counting live cells vs dead cells, respectively. Progress curves for cell death and the areas under those curves showed that toxicity was markedly dependent on compound, concentration, and time. AMAP was essentially equipotent with APAP. Homologating the acyl side chain from C-2 to C-5 led to progressive increases in toxicity up to 80-fold in the para series. In conclusion, whereas N- or ring-substitution on APAP decrease metabolism and toxicity, homologating the N-acyl side chain increases metabolism about 2-fold, preserves the chemical reactivity of quinoneimine metabolites, and increases toxicity by up to 80-fold.

Bioactivation of Trimethoprim to Protein-Reactive Metabolites in Human Liver Microsomes.

The formation of drug-protein adducts via metabolic activation and covalent binding may stimulate an immune response or may result in direct cell toxicity. Protein covalent binding is a potentially pivotal step in the development of idiosyncratic adverse drug reactions (IADRs). Trimethoprim (TMP)-sulfamethoxazole (SMX) is a combination antibiotic that commonly causes IADRs. Recent data suggest that the contribution of the TMP component of TMP-SMX to IADRs may be underappreciated. We previously demonstrated that TMP is bioactivated to chemically reactive intermediates that can be trapped in vitro by N-acetyl cysteine (NAC), and we have detected TMP-NAC adducts (i.e., mercapturic acids) in the urine of patients taking TMP-SMX. However, the occurrence and extent of TMP covalent binding to proteins was unknown. To determine the ability of TMP to form protein adducts, we incubated [(14)C]TMP with human liver microsomes in the presence and absence of NADPH. We observed protein covalent binding that was NADPH dependent and increased with incubation time and concentration of both protein and TMP. The estimated covalent binding was 0.8 nmol Eq TMP/mg protein, which is comparable to the level of covalent binding for several other drugs that have been associated with covalent binding-induced toxicity and/or IADRs. NAC and selective inhibitors of CYP2B6 and CYP3A4 significantly reduced TMP covalent binding. These results demonstrate for the first time that TMP bioactivation can lead directly to protein adduct formation, suggesting that TMP has been overlooked as a potential contributor of TMP-SMX IADRs.

Protein Targets of Isoniazid-Reactive Metabolites in Mouse Liver in Vivo.

Isoniazid (INH) has been a first-line drug for the treatment of tuberculosis for more than 40 years. INH is well-tolerated by most patients, but some patients develop hepatitis that can be severe in rare cases or after overdose. The mechanisms underlying the hepatotoxicity of INH are not known, but covalent binding of reactive metabolites is known to occur in animals and is suspected in human cases. A major unresolved question is the identity of the liver proteins that are modified by INH metabolites. Treating mice with INH leads to accumulation of isonicotinoyl-lysine residues on numerous proteins in the hepatic S9 fraction. Analysis of this fraction by SDS-PAGE followed by tryptic digestion of bands and LC-MS/MS revealed a single adducted peptide derived from d-dopachrome decarboxylase. When a tryptic digest of whole S9 was applied to anti-INH antibody immobilized on beads, only 12 peptides were retained, 5 of which clearly contained isonicotinoyl-lysine adducts and could be confidently assigned to 5 liver proteins. In another experiment, undigested S9 fractions from INA-treated and untreated (UT) mice were adsorbed in parallel on anti-INA beads and the retained proteins were digested and analyzed by LC-MS/MS. The INA-S9 digest showed 1 adducted peptide that was associated with a unique protein whose identity was corroborated by numerous nonadducted peptides in the digest and 13 other proteins identified only by multiple nonadducted peptides. None of these 14 proteins was associated with any peptides present in the UT-S9 fraction. Overall, we identified 7 mouse liver proteins that became adducted by INH metabolites in vivo. Of these 7 INH target proteins, only 2 have been previously reported as targets of any reactive metabolite in vivo.

Bioinformatic analysis of 302 reactive metabolite target proteins. Which ones are important for cell death?

Many low molecular weight compounds undergo biotransformation to chemically reactive metabolites (CRMs) that covalently modify cellular proteins. However, the mechanisms by which this covalent binding leads to cytotoxicity are not understood. Prior analyses of lists of target proteins sorted by functional categories or hit frequency have not proven informative. In an attempt to move beyond covalent binding, we hypothesized that xenobiotic posttranslational modification of proteins might disrupt important protein-protein interactions (PPIs) and thereby direct cells from homeostasis into cell death pathways. To test this hypothesis, we analyzed a list of 302 proteins (66% rat, 26% mouse, 5% human) known to be targeted by 41 different cytotoxic CRMs. Human orthologs of rodent proteins were found by blast sequence alignment, and their interacting partners were found using the Human Protein Reference Database. The combined set of target orthologs and partners was sorted into KEGG pathways and Gene Ontology categories. Those most highly ranked based on sorting statistics and toxicological relevance were heavily involved with intracellular signaling pathways, protein folding, unfolded protein response, and regulation of apoptosis. Detailed examination revealed that many of the categories were flagged primarily by partner proteins rather than target proteins and that a majority of these partners interacted with just a small number of proteins in the CRM target set. A similar analysis performed without the partner proteins flagged very few categories as significant. These results support the hypothesis that disruption of important PPIs may be a major mechanism contributing to CRM-induced acute cytotoxicity.

Protein targets of thioacetamide metabolites in rat hepatocytes.

Thioacetamide (TA) has long been known as a hepatotoxicant whose bioactivation requires S-oxidation to thioacetamide S-oxide (TASO) and then to the very reactive S,S-dioxide (TASO2). The latter can tautomerize to form acylating species capable of covalently modifying cellular nucleophiles including phosphatidylethanolamine (PE) lipids and protein lysine side chains. Isolated hepatocytes efficiently oxidize TA to TASO but experience little covalent binding or cytotoxicity because TA is a very potent inhibitor of the oxidation of TASO to TASO2. However, hepatocytes treated with TASO show extensive covalent binding to both lipids and proteins accompanied by extensive cytotoxicity. In this work, we treated rat hepatocytes with [(14)C]-TASO and submitted the mitochondrial, microsomal, and cytosolic fractions to 2DGE, which revealed a total of 321 radioactive protein spots. To facilitate the identification of target proteins and adducted peptides, we also treated cells with a mixture of TASO/[(13)C2D3]-TASO. Using a combination of 1DGE- and 2DGE-based proteomic approaches, we identified 187 modified peptides (174 acetylated, 50 acetimidoylated, and 37 in both forms) from a total of 88 nonredundant target proteins. Among the latter, 57 are also known targets of at least one other hepatotoxin. The formation of both amide- and amidine-type adducts to protein lysine side chains is in contrast to the exclusive formation of amidine-type adducts with PE phospholipids. Thiobenzamide (TB) undergoes the same two-step oxidative bioactivation as TA, and it also gives rise to both amide and amidine adducts on protein lysine side chains but only amidine adducts to PE lipids. Despite their similarity in functional group chemical reactivity, only 38 of 62 known TB target proteins are found among the 88 known targets of TASO. The potential roles of protein modification by TASO in triggering cytotoxicity are discussed in terms of enzyme inhibition, protein folding, and chaperone function, and the emerging role of protein acetylation in intracellular signaling and the regulation of biochemical pathways.

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.

Covalent modification of lipids and proteins in rat hepatocytes and in vitro by thioacetamide metabolites.

Thioacetamide (TA) is a well-known hepatotoxin in rats. Acute doses cause centrilobular necrosis and hyperbilirubinemia while chronic administration leads to biliary hyperplasia and cholangiocarcinoma. Its acute toxicity requires its oxidation to a stable S-oxide (TASO) that is oxidized further to a highly reactive S,S-dioxide (TASO(2)). To explore possible parallels among the metabolism, covalent binding, and toxicity of TA and thiobenzamide (TB), we exposed freshly isolated rat hepatocytes to [(14)C]-TASO or [(13)C(2)D(3)]-TASO. TLC analysis of the cellular lipids showed a single major spot of radioactivity that mass spectral analysis showed to consist of N-acetimidoyl PE lipids having the same side chain composition as the PE fraction from untreated cells; no carbons or hydrogens from TASO were incorporated into the fatty acyl chains. Many cellular proteins contained N-acetyl- or N-acetimidoyl lysine residues in a 3:1 ratio (details to be reported separately). We also oxidized TASO with hydrogen peroxide in the presence of dipalmitoyl phosphatidylenthanolamine (DPPE) or lysozyme. Lysozyme was covalently modified at five of its six lysine side chains; only acetamide-type adducts were formed. DPPE in liposomes also gave only amide-type adducts, even when the reaction was carried out in tetrahydrofuran with only 10% water added. The exclusive formation of N-acetimidoyl PE in hepatocytes means that the concentration or activity of water must be extremely low in the region where TASO(2) is formed, whereas at least some of the TASO(2) can hydrolyze to acetylsulfinic acid before it reacts with cellular proteins. The requirement for two sequential oxidations to produce a reactive metabolite is unusual, but it is even more unusual that a reactive metabolite would react with water to form a new compound that retains a high degree of chemical reactivity toward biological nucleophiles. The possible contribution of lipid modification to the hepatotoxicity of TA/TASO remains to be determined.

Identification of protein targets of reactive metabolites of tienilic acid in human hepatocytes.

Tienilic acid (TA) is a uricosuric diuretic that was withdrawn from the market only months after its introduction because of reports of serious incidents of drug-induced liver injury including some fatalities. Its hepatotoxicity is considered to be primarily immunoallergic in nature. Like other thiophene compounds, TA undergoes biotransformation to a S-oxide metabolite which then reacts covalently with cellular proteins. To identify protein targets of TA metabolites, we incubated [(14)C]-TA with human hepatocytes, separated cellular proteins by 2D gel electrophoresis, and analyzed proteins in 36 radioactive spots by tryptic digestion followed by LC-MS/MS. Thirty-one spots contained at least one identifiable protein. Sixteen spots contained only one of 14 nonredundant proteins which were thus considered to be targets of TA metabolites. Six of the 14 were also found in other radioactive spots that contained from 1 to 3 additional proteins. Eight of the 14 had not been reported to be targets for any reactive metabolite other than TA. The other 15 spots each contained from 2 to 4 identifiable proteins, many of which are known targets of other chemically reactive metabolites, but since adducted peptides were not observed, the identity of the adducted protein(s) in these spots is ambiguous. Interestingly, all the radioactive spots corresponded to proteins of low abundance, while many highly abundant proteins in the mixture showed no radioactivity. Furthermore, of approximately 16 previously reported protein targets of TA in rat liver ( Methogo, R., Dansette, P., and Klarskov, K. ( 2007 ) Int. J. Mass Spectrom. , 268 , 284 -295 ), only one (fumarylacetoacetase) is among the 14 targets identified in this work. One reason for this difference may be statistical, given that each study identified a small number of targets from among thousands present in hepatocytes. Another may be the species difference (i.e., rat vs human), and still another may be the method of detection of adducted proteins (i.e., Western blot vs C-14). Knowledge of human target proteins is very limited. Of more than 350 known protein targets of reactive metabolites, only 42 are known from humans, and only 21 of these are known to be targets for more than one chemical. Nevertheless, the demonstration that human target proteins can be identified using isolated hepatocytes in vitro should enable the question of species differences to be addressed more fully in the future.

Bioinformatic analysis of xenobiotic reactive metabolite target proteins and their interacting partners.

BACKGROUND: Protein covalent binding by reactive metabolites of drugs, chemicals and natural products can lead to acute cytotoxicity. Recent rapid progress in reactive metabolite target protein identification has shown that adduction is surprisingly selective and inspired the hope that analysis of target proteins might reveal protein factors that differentiate target- vs. non-target proteins and illuminate mechanisms connecting covalent binding to cytotoxicity. RESULTS: Sorting 171 known reactive metabolite target proteins revealed a number of GO categories and KEGG pathways to be significantly enriched in targets, but in most cases the classes were too large, and the "percent coverage" too small, to allow meaningful conclusions about mechanisms of toxicity. However, a similar analysis of the directlyinteracting partners of 28 common targets of multiple reactive metabolites revealed highly significant enrichments in terms likely to be highly relevant to cytotoxicity (e.g., MAP kinase pathways, apoptosis, response to unfolded protein). Machine learning was used to rank the contribution of 211 computed protein features to determining protein susceptibility to adduction. Protein lysine (but not cysteine) content and protein instability index (i.e., rate of turnover in vivo) were among the features most important to determining susceptibility. CONCLUSION: As yet there is no good explanation for why some low-abundance proteins become heavily adducted while some abundant proteins become only lightly adducted in vivo. Analyzing the directly interacting partners of target proteins appears to yield greater insight into mechanisms of toxicity than analyzing target proteins per se. The insights provided can readily be formulated as hypotheses to test in future experimental studies.

Filling and mining the reactive metabolite target protein database.

The post-translational modification of proteins is a well-known endogenous mechanism for regulating protein function and activity. Cellular proteins are also susceptible to post-translational modification by xenobiotic agents that possess, or whose metabolites possess, significant electrophilic character. Such non-physiological modifications to endogenous proteins are sometimes benign, but in other cases they are strongly associated with, and are presumed to cause, lethal cytotoxic consequences via necrosis and/or apoptosis. The Reactive Metabolite Target Protein Database (TPDB) is a searchable, freely web-accessible (http://tpdb.medchem.ku.edu:8080/protein_database/) resource that attempts to provide a comprehensive, up-to-date listing of known reactive metabolite target proteins. In this report we characterize the TPDB by reviewing briefly how the information it contains came to be known. We also compare its information to that provided by other types of "-omics" studies relevant to toxicology, and we illustrate how bioinformatic analysis of target proteins may help to elucidate mechanisms of cytotoxic responses to reactive metabolites.

Protein targets of reactive metabolites of thiobenzamide in rat liver in vivo.

Thiobenzamide (TB) is a potent hepatotoxin in rats, causing dose-dependent hyperbilirubinemia, steatosis, and centrolobular necrosis. These effects arise subsequent to and appear to result from the covalent binding of the iminosulfinic acid metabolite of TB to cellular proteins and phosphatidylethanolamine lipids [ Ji et al. ( 2007) Chem. Res. Toxicol. 20, 701- 708 ]. To better understand the relationship between the protein covalent binding and the toxicity of TB, we investigated the chemistry of the adduction process and the identity of the target proteins. Cytosolic and microsomal proteins isolated from the livers of rats treated with a hepatotoxic dose of [ carboxyl- (14)C]TB contained high levels of covalently bound radioactivity (25.6 and 36.8 nmol equiv/mg protein, respectively). These proteins were fractionated by two-dimensional gel electrophoresis, and radioactive spots (154 cytosolic and 118 microsomal) were located by phosphorimaging. Corresponding spots from animals treated with a 1:1 mixture of TB and TB- d 5 were similarly separated, the spots were excised, and the proteins were digested in gel with trypsin. Peptide mass mapping identified 42 cytosolic and 24 microsomal proteins, many of which appeared in more than one spot on the gel; however, only a few spots contained more than one identifiable protein. Eighty-six peptides carrying either a benzoyl or a benzimidoyl adduct on a lysine side chain were clearly recognized by their d 0/ d 5 isotopic signature (sometimes both in the same digest). Because model studies showed that benzoyl adducts do not arise by hydrolysis of benzimidoyl adducts, it was proposed that TB undergoes S-oxidation twice to form iminosulfinic acid 4 [PhC(NH)SO 2H], which either benzimidoylates a lysine side chain or undergoes hydrolysis to 9 [PhC(O)SO 2H] and then benzoylates a lysine side chain. The proteins modified by TB metabolites serve a range of biological functions and form a set that overlaps partly with the sets of proteins known to be modified by several other metabolically activated hepatotoxins. The relationship of the adduction of these target proteins to the cytotoxicity of reactive metabolites is discussed in terms of three currently popular mechanisms of toxicity: inhibition of enzymes important to the maintenance of cellular energy and homeostasis, the unfolded protein response, and interference with kinase-based signaling pathways that affect cell survival.

Covalent modification of microsomal lipids by thiobenzamide metabolites in vivo.

Thiobenzamide (TB) is hepatotoxic in rats causing centrolobular necrosis, steatosis, cholestasis, and hyperbilirubinemia. It serves as a model compound for a number of thiocarbonyl compounds that undergo oxidative bioactivation to chemically reactive metabolites. The hepatotoxicity of TB is strongly dependent on the electronic character of substituents in the meta- and para-positions, with Hammett rho values ranging from -4 to -2. On the other hand, ortho substituents that hinder nucleophilic addition to the benzylic carbon of S-oxidized TB metabolites abrogate the toxicity and protein covalent binding of TB. This strong linkage between the chemistry of TB and its metabolites and their toxicity suggests that this model is a good one for probing the overall mechanism of chemically induced biological responses. While investigating the protein covalent binding of TB metabolites, we noticed an unusually large amount of radioactivity associated with the lipid fraction of rat liver microsomes. Thin-layer chromatography showed that most of the radioactivity was contained in a single spot more polar than the neutral lipids but less polar than the phospholipid fractions. Mass spectral analyses aided by the use of synthetic standards identified the material as N-benzimidoyl derivatives of typical microsomal phosphatidylethanolamine (PE) lipids. Quantitative analysis indicated that up to 25% of total microsomal PE became modified within 5 h after a hepatotoxic dose of TB. Further studies will be required to determine the contribution of lipid modification to the hepatotoxicity of TB.

The reactive metabolite target protein database (TPDB)--a web-accessible resource.

BACKGROUND: The toxic effects of many simple organic compounds stem from their biotransformation to chemically reactive metabolites which bind covalently to cellular proteins. To understand the mechanisms of cytotoxic responses it may be important to know which proteins become adducted and whether some may be common targets of multiple toxins. The literature of this field is widely scattered but expanding rapidly, suggesting the need for a comprehensive, searchable database of reactive metabolite target proteins. DESCRIPTION: The Reactive Metabolite Target Protein Database (TPDB) is a comprehensive, curated, searchable, documented compilation of publicly available information on the protein targets of reactive metabolites of 18 well-studied chemicals and drugs of known toxicity. TPDB software enables i) string searches for author names and proteins names/synonyms, ii) more complex searches by selecting chemical compound, animal species, target tissue and protein names/synonyms from pull-down menus, and iii) commonality searches over multiple chemicals. Tabulated search results provide information, references and links to other databases. CONCLUSION: The TPDB is a unique on-line compilation of information on the covalent modification of cellular proteins by reactive metabolites of chemicals and drugs. Its comprehensiveness and searchability should facilitate the elucidation of mechanisms of reactive metabolite toxicity. The database is freely available at http://tpdb.medchem.ku.edu/tpdb.html.

A proteomic analysis of bromobenzene reactive metabolite targets in rat liver cytosol in vivo.

Metabolic activation and protein covalent binding are early and apparently obligatory events in the cytotoxicity of many simple organic chemicals including drugs and natural products. Although much has been learned about the chemistry of reactive metabolite formation and reactivity toward protein nucleophiles, progress in identifying specific protein targets for reactive metabolites of various protoxins has been much slower. We previously reported nine microsomal and three cytosolic proteins as targets for reactive metabolites of bromobenzene in rat liver. These results, and contemporary work by others, indicate that protein covalent binding is not totally random in cells. Moreover, as protein targets for other protoxins were identified, little commonality of target proteins became apparent. In the present work, we used two-dimensional gel electrophoresis to separate liver cytosolic proteins from rats treated with 14C-bromobenzene; 110 of the 836 observed spots contained measurable radioactivity that varied over a 600-fold range of adduct density. Of these 110 spots, in-gel digestion coupled with mass spectrometry identified apparently single proteins in 57 spots. A few other spots clearly contained more than one identifiable protein, and in several cases, the same protein was identified in several spots having different apparent molecular masses and/or pI. Altogether, 33 unique new protein targets for bromobenzene metabolites were identified and compared to those known for acetaminophen, naphthalene, butylated hydroxytoluene, benzene, thiobenzamide, and halothane via a target protein database available at http://tpdb.medchem.ku.edu:8080/protein_database/. With increasing numbers of target proteins becoming known, more commonality in targeting by reactive metabolites from diverse chemical agents may be seen. Such commonality may help to separate toxicologically significant covalent binding events from a background of covalent binding that is toxicologically inconsequential.

Site-specific arylation of rat glutathione s-transferase A1 and A2 by bromobenzene metabolites in vivo.

The hepatotoxicity of bromobenzene (BB) derives from its reactive metabolites (epoxides and quinones), which arylate cellular proteins. Application of proteomic methods to liver proteins from rats treated with a hepatotoxic dose of [14C]-BB has identified more than 40 target proteins, but no adducted peptides have yet been observed. Because such proteins are known to contain bromophenyl- and bromodihydroxyphenyl derivatives of cysteine, histidine, and lysine, the failure to observe modified peptides has been attributed to the low level of total covalent binding and to the "dilution" effect of multiple metabolites reacting at multiple sites on multiple proteins. In this work glutathione S-transferase (GST), a well-known and abundant BB-target protein, was isolated from liver cytosol of rats treated with 14C-BB by use of a glutathione (GSH)-agarose affinity column and further resolved by reverse-phase high-performance liquid chromatography (HPLC) into subunits M1, M2, A1, A2 and A3. The subunits were identified by a combination of sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE), whole-molecule mass spectrometry, and peptide mass mapping and found to contain radioactivity corresponding to 0.01-0.05 adduct per molecule of protein. Examination of tryptic digests of these subunits by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) and electrospray ionization mass spectrometry (ESI-MS) failed to reveal any apparent adducted peptides despite observed sequence coverages up to 87%. However, use of HPLC-linear ion-trap quadrupole Fourier transform mass spectrometry (LTQ-FTMS) to search for predicted modified tryptic peptides revealed peaks corresponding, with a high degree of mass accuracy, to a bromobenzoquinone adduct of peptide 89-119 in both GSTA1 and A2. The identity of these adducts and their location at Cys-111 was confirmed by tandem mass spectrometry (MS-MS). No evidence for the presence of any putative BB-adducts in GST M1, M2, or A3 was obtained. This work highlights the challenges involved in the unambiguous identification of reactive metabolite adducts formed in vivo.

Use of isotopic signatures for mass spectral detection of protein adduction by chemically reactive metabolites of bromobenzene: studies with model proteins.

The cytotoxicity of many small organic compounds often apparently derives from their metabolic activation and covalent binding to cellular proteins. It is therefore of considerable interest to be able to determine, for a given protoxin, which metabolites modify which proteins at which sites. Our laboratory has identified more than 45 target proteins for bromobenzene metabolites in liver by peptide mass mapping after two-dimensional electrophoresis. Through all of this work, we have never observed a bromine-containing peptide. We therefore generated model adducted proteins by carbodiimide coupling of Nalpha-acetyl-Ntau-(p-bromophenyl)-L-histidine (1) and Nalpha-acetyl-Nepsilon-(p-bromophenyl)-L-lysine (2) to bovine pancreatic ribonuclease A. For the adducts, RNase-(1)n and RNase-(2)n, mass spectrometry indicated that n = 0-2 and 0-6, respectively. RNase-(2)n was submitted to in-gel and in-solution digestion with trypsin, and the digests were analyzed by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) and liquid chromatgraphy electrospray ionization MS (LC/ESI-MS) and tandem MS (MS/MS). Sequence coverages observed ranged from 67% with only three modified lysines observed using in-gel digestion and MALDI-TOF analysis, to 100% coverage with all 10 lysines observed in both modified and unmodified form using in-solution digestion and LC/ESI-MS. In the mass spectra of all modified peptides up to 2000 Da, the bromine isotope pattern was obvious by visual inspection; for peptides up to 3600 Da, the isotopic signature could be recognized by visual comparison to simulated spectra. The presence of Br-containing adducts was confirmed by MS/MS analysis of selected peptides. The selection of peaks for MS/MS analysis was significantly facilitated by visual recognition of the bromine isotope pattern, even at signal-to-noise ratios of 10 (or lower in favorable cases). These results indicate that stable isotope labeling may have considerable potential for detecting and locating protein adducts of reactive metabolites.

1H high-resolution magic-angle spinning (HR-MAS) NMR analysis of ligand density on resins using a resin internal standard.

We recently attempted to generate an affinity chromatography adsorbent to purify cytochrome P450 4A1 by coupling 11-(1'-imidazolyl)-3,6,9-trioxaundecanoic acid to Toyopearl AF-Amino 650 M resin. Variations in ligand density for several resin batches were quantified by high-resolution magic-angle spinning (HR-MAS) NMR spectroscopy using a novel resin internal standard. The uniquely designed ImQ internal resin standard yields its signature resonance in a transparent region of the analyte spectrum making suppression of the polymer background unnecessary. This method enabled us to target a reasonable ligand density for enzyme purification and provides an advantageous alternative to quantitation against soluble standards or protonated solvent.

Synthesis of N tau-arylhistidine derivatives via direct N-arylation.

N(tau)-Aryl-histidine derivatives were synthesized using a modified one-step Cu-catalyzed coupling of aryl halides and N-acetylhistidine methyl ester. The latter is much less reactive than imidazole toward aryl halides. p-Chloroiodobenzene coupled with iodine displacement only, whereas m- and p-bromoiodobenzene both gave mixtures of bromo- and iodophenyl products.

Formation of cyclopropanone during cytochrome P450-catalyzed N-dealkylation of a cyclopropylamine.

The role of single electron transfer (SET) in P450-catalyzed N-dealkylation reactions has been studied using the probe substrates N-cyclopropyl-N-methylaniline (2a) and N-(1'-methylcyclopropyl)-N-methylaniline (2b). In earlier work, we showed that SET oxidation of 2a by horseadish peroxidase leads exclusively to products arising via fragmentation of the cyclopropane ring [Shaffer, C. L.; Morton, M. D.; Hanzlik, R. P. J. Am. Chem. Soc. 2001, 123, 8502-8508]. In the present study, we found that liver microsomes from phenobarbital pretreated rats (which contain CYP2B1 as the predominant isozyme) oxidize [1'-(13)C, 1'-(14)C]-2a efficiently (80% consumption in 90 min). Disappearance of 2a follows first-order kinetics throughout, indicating a lack of P450 inactivation by 2a. HPLC examination of incubation mixtures revealed three UV-absorbing metabolites: N-methylaniline (4), N-cyclopropylaniline (6a), and a metabolite (M1) tentatively identified as p-hydroxy-2a, in a 2:5:2 mole ratio, respectively. 2,4-Dinitrophenylhydrazine trapping indicated formation of formaldehyde equimolar with 6a; 3-hydroxypropionaldehyde and acrolein were not detected. Examination of incubations of 2a by (13)C NMR revealed four (13)C-enriched signals, three of which were identified by comparison to authentic standards as N-cyclopropylaniline (6a, 33.6 ppm), cyclopropanone hydrate (11, 79.2 ppm), and propionic acid (12, 179.9 ppm); the fourth signal (42.2 ppm) was tentatively determined to be p-hydroxy-2a. Incubation of 2a with purified reconstituted CYP2B1 also afforded 4, 6a, and M1 in a 2:5:2 mole ratio (by HPLC), indicating that all metabolites are formed at a single active site. Incubation of 2b with PB microsomes resulted in p-hydroxylation and N-demethylation only; no loss or ring-opening of the cyclopropyl group occurred. These results effectively rule out the participation of a SET mechanism in the P450-catalyzed N-dealkylation of cyclopropylamines 2a and 2b, and argue strongly for the N-dealkylation of 2a via a carbinolamine intermediate formed by a conventional C-hydroxylation mechanism.

Identification of seven proteins in the endoplasmic reticulum as targets for reactive metabolites of bromobenzene.

The hepatotoxicity of bromobenzene is strongly correlated with the covalent binding of chemically reactive metabolites to cellular proteins, but up to now relatively few hepatic protein targets of these reactive metabolites have been identified. To identify additional hepatic protein targets we injected an hepatotoxic dose of [14C]bromobenzene to phenobarbital-pretreated male Sprague-Dawley rats ip. After 4 h, their livers were removed and homogenized, and the homogenates fractionated by differential ultracentrifugation. The highest specific radiolabeling (6.1 nmol equiv 14C/mg of protein) was observed in a particulate fraction (P25) sedimented at 25000g from a 6000g supernatant fraction. Proteins in this fraction were separated by two-dimensional electrophoresis and, after transblotting, analyzed for radioactivity by phosphorimaging. More than 20 radiolabeled protein spots were observed in the blots. For 17 of these spots, peptide mass maps were obtained using in-gel digestion with trypsin, followed by MALDI-TOF mass spectrometric analysis of the resulting peptide mixtures. By searching genomic databases, the 17 sets of MS-derived peptide masses were found to match predicted tryptic fragments of just 7 proteins. Spots 1-4 matched with 78 kDa glucose regulated protein (GRP78), protein disulfide isomerase isozyme A1 (PDIA1), endoplasmic reticulum protein ERp29, and PDIA6, respectively. Spots 5 and 6, 7-11, and 12-17 presented as apparent "charge trains" of spots, each of which gave peptide mixtures closely similar to those of other spots within the train. The proteins present in these sets of spots were identified as transthyretin, serum albumin precursor and PDIA3, respectively. The possible relationship of the adduction of these proteins to the toxicological outcome is discussed.