Characterization of N-(2,6-dimethylphenyl)hydroxylamine adducts of 2'-deoxyguanosine under weakly basic conditions.

Aromatic amines are a class of chemical carcinogens that are activated by cytochrome P450 enzymes to form arylhydroxylamines that are conjugated to form N-acetoxyarylamines or N-sulfonyloxyarylamines. These conjugates undergo N-O bond cleavage to become reactive nitrenium ions that may form DNA adducts. Numerous studies in the past using N-acetoxyarylamines to investigate DNA adduct formation were conducted, however, less is known in regard to DNA adduct formation directly from arylhydroxylamines - especially under conditions that mimic the physiological conditions of cells such as weakly basic conditions. In this study, 2'-deoxyguanosine (dG) was exposed to N-(2,6-dimethylphenyl)hydroxylamine (2,6-DMPHA) and N-phenylhydroxylamine (PHA) at pH 7.4 without enzymes and analyzed by liquid chromatography high resolution mass spectrometry (LC-HRMS). 2,6-DMPHA exposure resulted in the production of relatively low amounts of adducts however the identities of at least six different adducts that were formed through reactions with carbon, nitrogen and oxygen of 2'-deoxyguanosine were proposed based upon different analytical approaches including HRMS CID fragmentation and NMR analyses. Contrastively, PHA exposure under identical conditions resulted in one adduct at the C8 position. It was concluded from these results and results of theoretical calculations that nitrenium ions produced from 2,6-DMPHA were relatively more stable resulting in longer nitrenium ion lifetimes which ultimately led to greater potential for 2,6-DMPHA nitrenium ions to react with multiple sites on dG.

Formation of Bulky DNA Adducts by Non-Enzymatic Production of 1,2-Naphthoquinone-Epoxide from 1,2-Naphthoquinone under Physiological Conditions.

Quinones may be formed metabolically or abiotically from environmental pollutants and polycyclic aromatic hydrocarbons (PAHs); many are recognized as toxicological intermediates that cause a variety of deleterious cellular effects including mutagenicity. The PAH-o-quinone, 1,2-naphthoquinone (1,2-NQ), may exert its genotoxic effects through interactions with cellular nucleophiles such as DNA, however, the mechanisms of 1,2-NQ adduct formation are still under investigation. With the aim to further understand these mechanisms, the chemical structures of adducts formed from the reaction of 2'-deoxyguanosine (dG) with 1,2-NQ under physiological conditions were investigated by liquid chromatography electrospray ionization tandem mass spectrometry and 1H NMR analyses. Results showed that 1,2-NQ underwent non-enzymatic oxidation to form a 1,2-NQ-epoxide which in turn formed at least four bulky adducts with dG, and these adducts were more likely to be formed under physiological conditions. A mechanism was proposed whereby hydration of 1,2-NQ to form unstable naphthohydroquinones and 2-hydroxy-1,4-naphthoquinone resulted in formation of hydrogen peroxide that oxidized 1,2-NQ. These results suggest that the genotoxicity of 1,2-NQ may not only be caused through oxidative DNA damage and adduct formation through Michael addition but also through non-enzymatic oxidative transformation of 1,2-NQ itself to form an intermediate PAH-epoxide which covalently binds to DNA.

Usefulness of in vitro combination assays of mitochondrial dysfunction and apoptosis for the estimation of potential risk of idiosyncratic drug induced liver injury.

Drug-induced liver injury (DILI) is one of the serious and frequent drug-related adverse events. This adverse event is a main reason for regulatory action pertaining to drugs, including restrictions in clinical indications and withdrawal from clinical trials or the marketplace. Idiosyncratic DILI especially has become a major clinical concern because of its unpredictable nature, frequent hospitalization, need for liver transplantation and high mortality. The estimation of the potential for compounds to induce idiosyncratic DILI is very difficult in non-clinical studies because the precise mechanism of idiosyncratic DILI is still unknown. Recently, many in vitro assays which indicate a possibility of the prediction of the idiosyncratic DILI have been reported. Among these, some in vitro assays focus on the effects of compounds on mitochondrial function and the apoptotic effects of compounds on human hepatocytes. In this study, we measured oxygen consumption rate (OCR) and caspase-3/7 activity as an endpoint of mitochondrial dysfunction and apoptosis, respectively, with human hepatocytes after treatment with compounds causing idiosyncratic DILI (troglitazone, leflunomide, ranitidine and diclofenac). Troglitazone and leflunomide decreased the OCR but did not affect caspase-3/7 activity. Ranitidine increased caspase-3/7 activity but did not affect the OCR. Diclofenac decreased the OCR and increased caspase-3/7 activity. Acetaminophen and ethanol, which are also hepatotoxicants but do not induce idiosyncratic DILI, did not affect the OCR or caspase-3/7 activity. These results indicate that a combination assay of mitochondrial dysfunction and apoptosis is useful for the estimation of potential risk of compounds to induce idiosyncratic DILI.

Enhancement of acetaminophen-induced chronic hepatotoxicity in restricted fed rats: a nonclinical approach to acetaminophen-induced chronic hepatotoxicity in susceptible patients.

Acetaminophen (APAP) is a commonly used and effective analgesic and antipyretic agent. However, some patients encounter hepatotoxicity after repeated APAP dosing at therapeutic doses. In the present study, we focused on the nutritional state as one of the risk factors of APAP-induced chronic hepatotoxicity in humans and investigated the contribution of undernourishment to susceptibility to APAP-induced chronic hepatotoxicity using an animal model mimicking undernourished patients. Rats were divided into 2 groups: the ad libitum fed (ALF) and the restricted fed (RF) rats and were assigned to 3 groups (n = 8/group) for each feeding condition. The animals were given APAP at 0, 300 and 500mg/kg for 99 days under each feeding condition. Plasma and urinary glutathione-related metabolites and liver function parameters were measured during the dosing period and hepatic glutathione levels were measured at the end of the dosing period. In the APAP-treated ALF rats hepatic glutathione levels were increased and hepatic function parameters were not changed, but in the APAP-treated RF rats hepatic glutathione levels were decreased at 500mg/kg and hepatic function parameters were increased at 300 and 500mg/kg. Moreover the urinary endogenous metabolite profile after long-term treatment with APAP in the ALF and RF rats was similar to that in human non-responders and responders to APAP-induced chronic hepatotoxicity, respectively. In conclusion, the RF rats were more sensitive to APAP-induced chronic hepatotoxicity than the ALF rats and were considered to be a useful model to estimate the contribution of the nutritional state of patients to APAP-induced chronic hepatotoxicity.

Effects of spaced feeding on gene expression of hepatic transaminase and gluconeogenic enzymes in rats.

Blood alanine aminotransferase (ALT) and aspartate aminotransferase (AST) activities are widely used as sensitive markers of liver toxicity. However, these activities are also recognized to be altered by hormonal and nutritional modifications. We investigated the relationships between the activity and gene expression of the hepatic transaminases and the state of hepatic amino acid/glucose/fatty acid metabolism in the ad libitum fed (ALF) and spaced-fed (SF) rats. Acceleration of hepatic gluconeogenesis and fatty acid oxidation was noted in the SF rats. Expression of hepatic clock gene was also altered in the SF rats. Hepatic transaminase activities in the SF rats were higher than those in the ALF rats. These alterations were due to increases in the synthesis of hepatic ALT and AST proteins. In conclusion, the increased transaminase protein synthesis in the liver of the SF rats was considered to be related to the acceleration of hepatic gluconeogenesis under the conditions of spaced feeding.

Relationships between plasma and tissue transaminase activities in rats maintained under different feeding conditions.

In order to verify the nutritional aspect of alterations of the plasma and tissue transaminase activities, rats were fed 4 hr per day for 35 days (the spaced-fed (SF) rats) and the time course of the alterations in plasma and tissue transaminase activity was compared with those in the ad libitum fed (ALF) rats. Plasma transaminase activities were stable throughout the experiment period in the ALF rats. In the SF rats there were alterations in the plasma alanine aminotransferase (ALT) activities, the direction of which was different between the early phase and late phase of the experiment period; plasma ALT activities decreased in the early phase and gradually increased in the late phase. Plasma aspartate aminotransferase (AST) activities were stable in the SF rats throughout the experiment period as well as the ALF rats. The decreases in plasma ALT activities in the early phase were considered to be related to decreases in ALT activities in the small intestinal mucosa (SI mucosa). On the other hand, the increases in plasma ALT activities in the late phase were considered to be related to increases in ALT activities in the liver. Multiple regression analyses (MRAs) revealed that plasma ALT activities in the SF rats could be estimated by the ALT activities in the SI mucosa and liver. From these results, the alterations of the plasma ALT activities in the SF rats could be explained by those in the SI mucosa and liver under the conditions in our study.

Effects of fenofibrate on plasma and hepatic transaminase activities and hepatic transaminase gene expression in rats.

Serum alanine aminotransferase (ALT) and aspartate aminotransferase (AST) levels are widely used as sensitive markers of possible tissue damage, particularly liver toxicity. Lipid-lowering drugs, such as fibrates, slightly increase serum transaminase levels in humans, but there is little evidence that the phenomenon is related to drug-induced liver injury (DILI). Some in vitro studies have indicated that the elevations of serum transaminase activities after treatment of humans with fenofibrate, one of the fibrates, are related to increased transaminase synthesis in the hepatocytes rather than to transaminase leakage from the hepatocytes associated with cell lysis. In this study, male F344/DuCrlCrlj (Fischer) rats were treated once with fenofibrate at a dose level of 400 mg/kg and the relationships between the pharmacological effects, blood and hepatic transaminase activities and the gene expression of the transaminases in the liver were investigated. Fenofibrate treatment slightly increased plasma transaminase activities in rats with the findings directly related to the pharmacological action of the drug. The increases were in parallel with increases in hepatic transaminase activities associated with increases in the transaminase genes in the liver and were not considered to be a consequence of hepatotoxicity from the drug. The modification in transaminase gene expression is likely to be secondary to the pharmacological action of fenofibrate. The evidence obtained in our study underlines the importance of gene regulation as a possible alternative mechanism for increased blood transaminase activities.