Acetaminophen (APAP) hepatotoxicity is characterized by an extensive oxidative stress. However, its source, pathophysiological role and possible therapeutic potential if targeted, have been ...controversially described. Earlier studies argued for cytochrome P450-generated reactive oxygen species (ROS) during APAP metabolism, which resulted in massive lipid peroxidation and subsequent liver injury. However, subsequent studies convincingly challenged this assumption and the current paradigm suggests that mitochondria are the main source of ROS, which impair mitochondrial function and are responsible for cell signaling resulting in cell death. Although immune cells can be a source of ROS in other models, no reliable evidence exists to support a role for immune cell-derived ROS in APAP hepatotoxicity. Recent studies suggest that mitochondrial targeted antioxidants can be viable therapeutic agents against hepatotoxicity induced by APAP overdose, and re-purposing existing drugs to target oxidative stress and other concurrent signaling events can be a promising strategy to increase its potential application in patients with APAP overdose.
Acetaminophen (APAP) hepatotoxicity is characterized by an extensive mitochondrial oxidant stress. However, its importance as a drug target has not been clarified. To investigate this, fasted ...C57BL/6J mice were treated with 300 mg/kg APAP and the mitochondria-targeted antioxidant Mito-Tempo (MT) was given 1.5 h later. APAP caused severe liver injury in mice, as indicated by the increase in plasma ALT activities and centrilobular necrosis. MT dose-dependently reduced the injury. Importantly, MT did not affect APAP-protein adducts formation, glutathione depletion or c-jun N-terminal kinase activation and its mitochondrial translocation. In contrast, hepatic glutathione disulfide and peroxynitrite formation were dose-dependently reduced by MT, indicating its effective mitochondrial oxidant stress scavenging capacity. Consequently, mitochondrial translocation of Bax and release of mitochondrial intermembrane proteins such as apoptosis-inducing factor were prevented, and nuclear DNA fragmentation was eliminated. To demonstrate the importance of mitochondria-specific antioxidant property of MT, we compared its efficacy with Tempo, which has the same pharmacological mode of action as MT but lacks the mitochondria targeting moiety. In contrast to the dramatic protection by MT, the same molar dose of Tempo did not significantly reduce APAP hepatotoxicity. In contrast, even a 3 h post-treatment with MT reduced 70 % of the injury, and the combination of MT with
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-acetylcysteine (NAC) provided superior protection than NAC alone. We conclude that MT protects against APAP overdose in mice by attenuating the mitochondrial oxidant stress and preventing peroxynitrite formation and the subsequent mitochondrial dysfunction. MT is a promising therapeutic agent for APAP overdose patients.
Autophagy is a lysosomal degradation process that degrades long-lived cellular proteins and damaged organelles as a critical cell survival mechanism in response to stress. We recently reported that ...acute ethanol induces autophagy, which then reduces ethanol-induced liver injury. However, the mechanisms by which ethanol induces autophagy are not known. In the present study, ethanol treatment significantly increased both mRNA and protein levels of various essential autophagy-related genes in primary cultured mouse hepatocytes and in mouse liver. Both nuclear translocation of FoxO3a and expression of FoxO3a target genes were increased in ethanol-treated primary hepatocytes and mouse liver. Overexpression of a dominant negative form of FoxO3a inhibited ethanol-induced autophagy-related gene expression and enhanced ethanol-induced cell death in primary hepatocytes, which suggests that FoxO3a is a key factor in regulating ethanol-induced autophagy and cell survival. Resveratrol, a well-known SIRT1 agonist, further enhanced ethanol-induced expression of autophagy-related genes, likely via increased deacetylation of FoxO3a. Moreover, acute ethanol–treated Foxo3a −/− mice exhibited decreased autophagy-related gene expression, but enhanced steatosis and liver injury, compared with wild-type mice. FoxO3a thus plays a critical role in ethanol-induced autophagy in mouse liver. Modulating the FoxO3a autophagy pathway may offer novel therapeutic approaches for treating alcoholic liver pathogenesis.
We previously reported that delayed treatment with Mito-tempo (MT), a mitochondria-targeted superoxide dismutase mimetic, protects against the early phase of acetaminophen (APAP) hepatotoxicity by ...inhibiting peroxynitrite formation. However, whether this protection is sustained to the late phase of toxicity is unknown. To investigate the late protection, C57Bl/6J mice were treated with 300 mg/kg APAP followed by 20 mg/kg MT 1.5 h or 3 h later. We found that both MT treatments protected against the late phase of APAP hepatotoxicity at 12 and 24 h. Surprisingly, MT-treated mice demonstrated a significant increase in apoptotic hepatocytes, while the necrotic phenotype was observed almost exclusively in mice treated with APAP alone. In addition, there was a significant increase in caspase-3 activity and cleavage in the livers of MT-treated mice. Immunostaining for active caspase-3 revealed that the positively stained hepatocytes were exclusively in centrilobular areas. Treatment with the pan-caspase inhibitor ZVD-fmk (10 mg/kg) 2 h post-APAP neutralized this caspase activation and provided additional protection against APAP hepatotoxicity. Treatment with
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-acetylcysteine, the current standard of care for APAP poisoning, protected but did not induce this apoptotic phenotype. Mechanistically, MT treatment inhibited APAP-induced RIP3 kinase expression, and RIP3-deficient mice showed caspase activation and apoptotic morphology in hepatocytes analogous to MT treatment. These data suggest that while necrosis is the primary cause of cell death after APAP hepatotoxicity, treatment with the antioxidant MT may switch the mode of cell death to secondary apoptosis in some cells. Modulation of mitochondrial oxidative stress and RIP3 kinase expression play critical roles in this switch.
Acetaminophen (APAP) overdose causes severe hepatotoxicity in animals and humans. However, the mechanisms underlying the gender differences in susceptibility to APAP overdose in mice have not been ...clarified. In our study, APAP (300mg/kg) caused severe liver injury in male mice but 69–77% lower injury in females. No gender difference in metabolic activation of APAP was found. Hepatic glutathione (GSH) was rapidly depleted in both genders, while GSH recovery in female mice was 2.6 fold higher in the mitochondria at 4h, and 2.5 and 3.3 fold higher in the total liver at 4h and 6h, respectively. This faster recovery of GSH, which correlated with greater induction of glutamate-cysteine ligase, attenuated mitochondrial oxidative stress in female mice, as suggested by a lower GSSG/GSH ratio at 6h (3.8% in males vs. 1.4% in females) and minimal centrilobular nitrotyrosine staining. While c-jun N-terminal kinase (JNK) activation was similar at 2 and 4h post-APAP, it was 3.1 fold lower at 6h in female mice. However, female mice were still protected by the JNK inhibitor SP600125. 17β-Estradiol pretreatment moderately decreased liver injury and oxidative stress in male mice without affecting GSH recovery. Conclusion: The lower susceptibility of female mice is achieved by the improved detoxification of reactive oxygen due to accelerated recovery of mitochondrial GSH levels, which attenuates late JNK activation and liver injury. However, even the reduced injury in female mice was still dependent on JNK. While 17β-estradiol partially protects male mice, it does not affect hepatic GSH recovery.
•Female mice are less susceptible to acetaminophen overdose than males.•GSH depletion and protein adduct formation are similar in both genders.•Recovery of hepatic GSH levels is faster in females and correlates with Gclc.•Reduced oxidant stress in females leads to reduced JNK activation.•JNK activation and mitochondrial translocation are critical in females.
Background & Aims
The outcome of liver injury is dictated by factors that control the accumulation of myofibroblastic (activated) hepatic stellate cells (MF‐HSCs) but therapies that specifically ...block this process have not been discovered. We evaluated the hypothesis that MF‐HSCs and liver fibrosis could be safely reduced by inhibiting the cysteine/glutamate antiporter xCT.
Methods
xCT activity was disrupted in both HSC lines and primary mouse HSCs to determine its effect on HSC biology. For comparison, xCT expression and function were also determined in primary mouse hepatocytes. Finally, the roles of xCT were assessed in mouse models of liver fibrosis.
Results
We found that xCT mRNA levels were almost a log‐fold higher in primary mouse HSCs than in primary mouse hepatocytes. Further, primary mouse HSCs dramatically induced xCT as they became MF, and inhibiting xCT blocked GSH synthesis, reduced growth and fibrogenic gene expression and triggered HSC ferroptosis. Doses of xCT inhibitors that induced massive ferroptosis in HSCs had no effect on hepatocyte viability in vitro, and xCT inhibitors reduced liver fibrosis without worsening liver injury in mice with acute liver injury. However, TGFβ treatment up‐regulated xCT and triggered ferroptosis in cultured primary mouse hepatocytes. During chronic liver injury, xCT inhibitors exacerbated injury, impaired regeneration and failed to improve fibrosis, confirming that HSCs and hepatocytes deploy similar mechanisms to survive chronic oxidative stress.
Conclusions
Inhibiting xCT can suppress myofibroblastic activity and induce ferroptosis of MF‐HSCs. However, targeting xCT inhibition to MF‐HSCs will be necessary to exploit ferroptosis as an anti‐fibrotic strategy.
Study of the effects of natural products, including traditional Chinese Medicines, on acetaminophen hepatotoxicity has gained considerable popularity in recent years, and some of them showed positive ...results and even promising therapeutic potentials. A recent report suggested that Liuweiwuling tablets protect against acetaminophen hepatotoxicity and promote liver regeneration in a rodent model through alleviating the inflammatory response. However, several concerns exist regarding the limitations of the experimental design and interpretation of the data presented in this manuscript.
Mitochondrial biogenesis (MB) is an adaptive response to maintain metabolic homeostasis after mitochondrial dysfunction. Induction of MB during APAP hepatotoxicity has not been studied. To ...investigate this, mice were treated with toxic doses of APAP and euthanized between 0 and 96 h. At early time points, APAP caused both mitochondrial dysfunction and reduction of mitochondrial mass, indicated by reduced activity of electron transport chain (ETC) complexes I and IV and depletion of mitochondrial DNA (mtDNA), respectively. Both ETC activity and mtDNA gradually recovered after 12 h, suggesting that MB occurs at late time points after APAP overdose. Immunofluorescent staining of mitochondria with mitochondrial outer membrane protein Tom20 further demonstrated that MB occurs selectively in hepatocytes surrounding necrotic areas. MB signaling mediators including PPARγ co-activator 1-α (Pgc-1α), nuclear respiratory factor-1 (Nrf-1) and mitochondrial fission protein dynamin-related protein-1 (Drp-1) were induced. Pgc-1α was selectively increased in hepatocytes surrounding necrotic areas. In addition, the time course of MB induction coincides with increased liver regeneration. Post-treatment with the known MB inducer SRT1720 increased Pgc-1α expression and liver regeneration, resulting in protection against late liver injury after APAP overdose. Thus, induction of MB is an important feature during APAP hepatotoxicity and liver regeneration.
•A delayed induction of mitochondrial biogenesis occurs after acetaminophen overdose.•Mitochondrial biogenesis is prominent in hepatocytes surrounding areas of necrosis.•Regions with enhanced mitochondrial biogenesis also upregulate liver regeneration.•Pharmacological induction of mitochondrial biogenesis promotes liver regeneration.
•Resveratrol post-treatment protects against acetaminophen hepatotoxicity.•Resveratrol post-treatment does not affect acetaminophen-protein binding or JNK activation.•Resveratrol reduces oxidative ...stress and nitrotyrosine staining during acetaminophen toxicity.•Resveratrol reduces release of endonucleases from damaged mitochondria during acetaminophen toxicity.
Overdose of acetaminophen (APAP) is a common cause of acute liver injury and liver failure. The mechanism involves formation of a reactive metabolite, protein binding, oxidative stress and activation of c-Jun N-terminal kinase (JNK), mitochondrial dysfunction, and nuclear DNA fragmentation caused by endonucleases released from damaged mitochondria. Previous work has shown that the natural product resveratrol (RSV) can protect against APAP hepatotoxicity in mice through prevention of lipid peroxidation and anti-inflammatory effects. However, these earlier studies did not take into consideration several fundamental aspects of the pathophysiology. To address this, we treated C57Bl/6 mice with 300 mg/kg APAP followed by 50 mg/kg RSV 1.5 h later. Our results confirmed that RSV reduced liver injury after APAP overdose in mice. Importantly, RSV did not inhibit reactive metabolite formation and protein bindings, nor did it reduce activation of JNK. However, RSV decreased protein nitration after APAP treatment, possibly through direct scavenging of peroxynitrite. Interestingly, RSV also inhibited release of apoptosis-inducing factor and endonuclease G from mitochondria independent of Bax pore formation and prevented the downstream nuclear DNA fragmentation. Our data show that RSV protects against APAP hepatotoxicity both through antioxidant effects and by preventing mitochondrial release of endonucleases and nuclear DNA damage.
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