Aryl hydrocarbon (Ah) nonresponsiveness in estrogen receptor-negative MDA-MB-231 cells is associated with expression of a variant arnt protein.

Several studies have reported a correlation between expression of the estrogen receptor (ER) and aryl hydrocarbon (Ah) responsiveness in human breast cancer cell lines. MDA-MB-231 cells are ER-negative and Ah-nonresponsive; however, initial studies showed that 2,3,7,8-tetrachlorodibenzo-p-dioxin induced CYP1A1 mRNA levels (5.8-fold) and chloramphenicol acetyltransferase activity (2.6-fold) in high passage (Hp, >50 passages) cells transiently transfected with an Ah-responsive plasmid. In contrast, no induction responses were observed in low passage (Lp, <20 passages) cells. The Ah responsiveness of Hp compared to Lp MDA-MB-231 cells was associated with a >2-fold increased expression of the Ah receptor in Hp cells. Further analysis revealed that the apparent molecular weight of the Ah receptor mRNA transcript and immunoreactive protein were comparable in Lp MDA-MB-231 and Ah-responsive human HepG2 cells. In contrast, RT-PCR analysis of the Ah receptor nuclear translocator (Arnt) protein showed that HepG2 cells expressed the expected 2.6-kb transcript, whereas a 1.3-kb transcript was the major product in MDA-MB-231 cells. Western blot analysis confirmed that HepG2 cells primarily expressed a 97-kDa wild-type form of Arnt, whereas a dominant 36-kDa variant was expressed in MDA-MB-231 cells. Complete sequence analysis of the variant form of Arnt revealed a major deletion of the C-terminal region of the protein (aa 330 to 789). Like HepG2 cells, the wild-type 2.6-kb transcript was detected in ER-positive (Ah-responsive) MCF-7 cells, whereas the low-molecular-weight variant Arnt was dominant in ER-negative MDA-MB-231, MDA-MB-435, and Adriamycin-resistant MCF-7 cells. These results suggest that expression of this protein may be useful as a prognostic factor in breast cancer.

Protein arylation precedes acetaminophen toxicity in a dynamic organ slice culture of mouse kidney.

Acetaminophen (APAP) is an analgesic and antipyretic agent which may cause hepatotoxicity and nephrotoxicity with overdose in man and laboratory animals. In vivo studies suggest that in situ activation of APAP contributes to the development of nephrotoxicity. Associated with target organ toxicity is selective arylation of proteins, with a 58-kDa acetaminophen binding protein (58-ABP) being the most prominent cytosolic target. In this study a mouse kidney slice model was developed to further evaluate the contribution of in situ activation of APAP to the development of nephrotoxicity and to determine the selectivity of protein arylation. Precision cut kidney slices from male CD-1 mice were incubated with selected concentrations of APAP (0-25 mM) for 2 to 24 hr. APAP caused a dose- and time-dependent decrease in nonprotein sulfhydryls (NPSH), ATP content, and K+ retention. Preceding toxicity was arylation of cytosolic proteins, the most prominent one being the 58-ABP. The association of 58-ABP arylation with APAP toxicity in this mouse kidney slice model is consistent with earlier, in vivo results and demonstrates the importance of in situ activation of APAP for the development of nephrotoxicity. Precision cut renal slices and dynamic organ culture are a good model for further mechanistic studies of APAP-induced renal toxicity.

Protection by clofibrate against acetaminophen hepatotoxicity in male CD-1 mice is associated with an early increase in biliary concentration of acetaminophen-glutathione adducts.

Repeated treatment with clofibrate (CFB) significantly increased hepatic glutathione (GSH) content and also diminished acetaminophen's (APAP) selective protein arylation, GSH depletion, and severity of hepatocellular necrosis. The present work was conducted to evaluate the role of elevated GSH and APAP detoxifying pathways in the amelioration of APAP's toxicity by CFB. Male CD-1 mice received 500 mg CFB/kg, i.p., daily for 10 days. Controls were given corn oil vehicle. They were challenged with 700 mg APAP/kg in 50% propylene glycol/water after an overnight fast. Results indicate that CFB pretreatment had no effect on 24-hr urinary excretion of APAP-glucuronide, sulfate, or GSH-derived conjugates; however, there was 50% less unchanged APAP excreted in urine of CFB-pretreated mice. CFB also did not alter microsomal UDP-glucuronyl transferase activity toward APAP in vitro. However, elimination of APAP from plasma and liver was much greater in CFB-pretreated mice. This was accompanied by elevated biliary APAP-GSH content in CFB-pretreated mice at 2 hr after APAP dosing with diminished levels in bile at 12 hr. The CFB-induced increase in biliary excretion of APAP-GSH may mediate the protection against APAP-induced hepatotoxicity.

Evidence suggesting the 58-kDa acetaminophen binding protein is a preferential target for acetaminophen electrophile.

Acetaminophen is an analgesic and antipyretic which causes liver toxicity in humans and experimental animals with overdose. Acetaminophen (APAP) covalent binding to a cytosolic protein of approximately 58 kDa (58-ABP) has been associated with target organ toxicity. Since hepatic content of 58-ABP varies, studies were conducted to determine if this influences APAP binding to other target proteins. In the liver, the amount of 58-ABP varied with individual male CD-1 mice, but in kidneys of the same mice there was no such variability in 58-ABP content. All male A/J mice tested had comparatively little detectable 58-ABP in liver cytosol. Similarly, female CD-1 mice had low 58-ABP content compared to males; however, administration of testosterone propionate to females significantly increased 58-ABP content in liver cytosol. At 4 hr after challenge of mice from the above-described groups with 600 mg APAP/kg, cytosolic covalent binding to proteins was determined by Western blot analysis with anti-APAP antibody. The Western blots were then stripped of antibody and blocking agents and reprobed with antibody prepared against purified 58-ABP (anti-58-ABP). In the liver, the level of APAP bound to the 58-ABP target corresponded with 58-ABP content. In cases where 58-ABP was poorly expressed, APAP adducts to other protein targets were more prominently detected. In the kidneys of the male CD-1 mice 58-ABP arylation by APAP varied little among animals, reflecting the relatively consistent levels of renal 58-ABP. These data suggest that binding to the 58-ABP may spare other potential targets of APAP electrophile attach and support a role of the 58-ABP as a preferred target of APAP electrophile in cytosol.

Gender-related differences in susceptibility to acetaminophen-induced protein arylation and nephrotoxicity in the CD-1 mouse.

Acetaminophen (APAP) is a commonly used analgesic and antipyretic agent which, in high doses, causes liver and kidney necrosis in man and animals. Damage in both target organs is greatly dependent upon biotransformation. However, in the CD1 mouse only males exhibit cytochrome P450-dependent nephrotoxicity and selective protein covalent binding. The lack of renal toxicity in female mice may reflect the androgen dependence of renal CYP2E1. To study this, female mice were pretreated with testosterone propionate and then challenged 6 days later with APAP. Groups of control males and females were similarly challenged with APAP for comparison. All groups exhibited hepatotoxicity after APAP with similar glutathione (GSH) depletion, covalent binding, centrilobular necrosis, and elevation of plasma sorbitol dehydrogenase activity. By contrast, APAP-induced nephrotoxicity occurred only in males and in the females pretreated with testosterone. No nephrotoxicity was evident in APAP-challenged control females. The selective pattern of hepatic and renal protein arylation previously reported for male mice was similarly observed in testosterone-pretreated female mice. Western blot analysis of microsomes showed that testosterone increased renal CYP2E1 levels without altering hepatic CYP2E1. Testosterone pretreatment, in vivo, also resulted in increased activation of APAP in vitro in kidney microsomes with no effect on the in vitro activation of APAP in liver microsomes. These data suggest that APAP-mediated GSH depletion, covalent binding, and toxicity in the kidneys of testosterone-pretreated females results from increased APAP activation by the testosterone-induced renal CYP2E1. This further suggests that renal, rather than hepatic, biotransformation of APAP to a toxic electrophile is central to APAP-induced nephrotoxicity in the mouse.

Clofibrate pretreatment diminishes acetaminophen's selective covalent binding and hepatotoxicity.

Peroxisome proliferators have been shown to diminish acetaminophen (APAP) hepatotoxicity (Biochem. Pharmacol. 43, 1395, 1992). To investigate the mechanistic basis for this protection CD-1 male mice were given corn oil or 500 mg clofibrate (CFB)/kg, ip, daily for 10 days. They were then fasted overnight and either killed without challenge or at 4 or 12 hr after challenge with 800 mg APAP/kg (in 50% propylene glycol). At 12 hr, hepatotoxicity was evidenced by elevated plasma sorbitol dehydrogenase and histopathology in corn oil but not in CFB-pretreated mice. At 4 hr after APAP treatment, hepatic glutathione (GSH) depletion and selective arylation of the major APAP target proteins were both greatly diminished by CFB pretreatment. Western blot analysis with the anti-58 antibody of liver cytosol from unchallenged mice showed no apparent changes in the levels of the 58-kDa major APAP target protein with CFB treatment. These findings suggest that protection could be the result of diminished net availability of generated electrophile. In vitro, measurements indicated that the specific activity in microsomes for APAP oxidation by cytochrome P450 was not changed by CFB treatment; whereas GSH S-transferase activity in cytosol was decreased by 25%. Pretreatment with CFB also produced a significant elevation in hepatic GSH. These studies indicate that protection by CFB might result from increased availability of hepatic GSH which could trap APAP electrophile nonenzymatically, thereby decreasing covalent binding and preventing toxicity.