In this study, we analyzed the contribution of hydroxyl radical in the liver apoptosis mediated by hyperglycemia through the Bax-caspase pathway and the effects of insulin protection against the apoptosis induced by hyperglycemia. Male adult Wistar rats were randomized in three groups: control (C) (sodium citrate buffer, i.p.), streptozotocin (STZ)-induced diabetic (SID) (STZ 60 mg/kg body weight, i.p.), and insulintreated SID (SIDCI; 15 days post STZ injection, SID received insulin s.c., twice a day, 15 days). Rats were autopsied on day 30. In liver tissue, diabetes promoted a significant increase in hydroxyl radical production which correlated with lipid peroxidation (LPO) levels. Besides, hyperglycemia significantly increased mitochondrial BAX protein expression, cytosolic cytochrome c levels, and caspase-3 activity leading to an increase in apoptotic index. Interestingly, the treatment of diabetic rats with desferoxamine or tempol (antioxidants/ hydroxyl radical scavengers) significantly attenuated the increase in both hydroxyl radical production and in LPO produced by hyperglycemia, preventing apoptosis by reduction of mitochondrial BAX and cytosolic cytochrome c levels. Insulin treatment showed similar results. The finding that co-administration of antioxidants/hydroxyl radical scavengers together with insulin did not provide any additional benefit compared with those obtained using either inhibitors or insulin alone shows that it is likely that insulin prevents oxidative stress by reducing the effects of hydroxyl radicals. Importantly, insulin significantly increased apoptosis inhibitor protein expression by induction of its mRNA. Taken together, our studies support that, at least in part, the hydroxyl radical acts as a reactive intermediate, which leads to liver apoptosis in a model of STZ-mediated hyperglycemia. A new anti-apoptosis signal for insulin is shown, given by an increase of apoptosis inhibitor protein.
To determine whether interferon alfa (IFN-␣) prevents in vivo oncogenesis in very-earlystage cancer cells, we evaluated the action of IFN-␣2b over preneoplastic foci in rats. Animals were divided into 6 groups: subjected to a 2-phase model (diethylnitrosamine [DEN] plus 2-acetylaminofluorene [2-AAF]) of preneoplasia development (group 1), treated with IFN␣2b during the 2 phases (group 2), only during initiation with DEN (group 3), only during administration of 2-AAF (group 4), subjected only to an initiation stage (group 5), and treated with IFN-␣2b during this period (group 6). The numbers of placental form of rat glutathione S-transferase (rGST-P)-positive foci per liver and the foci as percentage of liver were significantly reduced in groups 2, 3, and 6 but not in group 4. Rats treated with IFN-␣2b showed a higher apoptotic index (AI) in altered hepatic foci (AHF). Levels of p53 and Bax protein in liver lysates were significantly increased in those animals. Similarly, levels of antiapoptotic proteins Bcl-2 and Bcl-x L in mitochondrial fraction were decreased. Finally, increased levels of Bax protein were localized in the mitochondria of rats that received IFN-␣2b, at least during the DEN phase (groups 2, 3, and 6), whereas mitochondrial Bax expression was not increased in group 4. In conclusion, the preneoplastic hepatocytes in rats that received IFN-␣2b during the initiation stage undergo programmed cell death as a primary result of a significant increase in the amount and translocation to the mitochondria of Bax protein. (HEPATOLOGY 2002;35:824-833.)
We have shown that aluminum (Al) induces cholestasis associated with multiple alterations in hepatocellular transporters involved in bile secretory function, like Mrp2. This work aims to investigate whether these harmful effects are mediated by the oxidative stress caused by the metal. For this purpose, the capability of the antioxidant agent, vitamin E, to counteract these alterations was studied in male Wistar rats. Aluminum hydroxide (or saline in controls) was administered ip (27 mg/kg body weight, three times a week, for 90 d). Vitamin E (600 mg/kg body weight) was coadministered, sc. Al increased lipid peroxidation (+50%) and decreased hepatic glutation levels (-43%) and the activity of glutation peroxidase (-50%) and catalase (-88%). Vitamin E counteracted these effects total or partially. Both plasma and hepatic Al levels reached at the end of the treatment were significantly reduced by vitamin E (-40% and -44%, respectively; p<0.05). Al increased 4 times the hepatic apoptotic index, and this effect was fully counteracted by vitamin E. Bile flow was decreased in Altreated rats (-37%) and restored to normality by vitamin E. The antioxidant normalized the hepatic handling of the Mrp2 substrates, rose bengal, and dinitrophenyl-S-glutathione, which was causally associated with restoration of Mrp2 expression. Our data indicate that oxidative stress has a crucial role in cholestasis, apoptotic/necrotic hepatocellular damage, and the impairment in liver transport function induced by Al and that vitamin E counteracts these harmful effects not only by preventing free-radical formation but also by favoring Al disposal.
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