amatoxin and Disease-Models--Animal

Mushroom toxicity is the main branch of foodborne poisoning, and liver damage caused by amatoxin poisoning accounts for more than 90 % of deaths due to mushroom poisoning. Alpha-amatoxin (α-AMA) has been considered the primary toxin from amatoxin-containing mushrooms, which is responsible for hepatotoxicity and death. However, the mechanism underlying liver failure due to α-AMA remains unclear. This study constructed animal and cell models. In the animal experiments, we investigated liver injury in BALB/c mice at different time points after α-AMA treatment, and explored the process of inflammatory infiltration using immunohistochemistry and western blotting. Then, a metabonomics method based on gas chromatography mass spectrometry (GCMS) was established to study the effect of α-AMA on liver metabonomics. The results showed a significant difference in liver metabolism between the exposed and control mice groups that coincided with pathological and biochemical indicators. Moreover, 20 metabolites and 4 metabolic pathways related to its mechanism of action were identified, which suggested that energy disorders related to mitochondrial dysfunction may be one of the causes of death. The significant changes of trehalose and the fluctuation of LC3-II and sqstm1 p62 protein levels indicated that autophagy was also involved in the damage process, suggesting that autophagy may participate in the clearance process of damaged mitochondria after poisoning. Then, we constructed an α-AMA-induced human normal liver cells (L-02 cells) injury model. The above hypothesis was further verified by detecting cell necrosis, mitochondrial reactive oxygen species (mtROS), mitochondrial permeability transition pore (mPTP) opening, mitochondrial membrane potential (Δψ m), and cellular ATP level. Collectively, our results serve as direct evidence of elevated in vivo hepatic mitochondrial metabolism in α-AMA-exposed mice and suggest that mitochondrial dysfunction plays an important role in the early stage of α-AMA induced liver failure.

Topics: Amanitins; Animals; Cell Line; Chemical and Drug Induced Liver Injury; Disease Models, Animal; Energy Metabolism; Humans; Liver; Liver Failure; Metabolomics; Mice, Inbred BALB C; Mitochondria, Liver; Mushroom Poisoning; Time Factors

Amatoxin poisoning induces a delayed onset of acute liver failure which might be explained by the prolonged persistence of the toxin in the enterohepatic circulation. Aim of the study was to demonstrate amanitin kinetics in the enterohepatic circulation.. Four pigs underwent α-amanitin intoxication receiving 0.35 mg/kg (n=2) or 0.15 mg/kg (n=2) intraportally. All pigs remained under general anesthesia throughout the observation period of 72 h. Laboratory values and amanitin concentration in systemic and portal plasma, bile and urine samples were measured.. Amanitin concentrations measured 5h after intoxication of 219±5ng/mL (0.35 mg/kg) and 64±3 (0.15 mg/kg) in systemic plasma and 201±8ng/mL, 80±13ng/mL in portal plasma declined to baseline levels within 24h. Bile concentrations simultaneously recorded showed 153±28ng/mL and 99±58ng/mL and decreased slightly delayed to baseline within 32 h. No difference between portal and systemic amanitin concentration was detected after 24h.. Amanitin disappeared almost completely from systemic and enterohepatic circulation within 24 h. Systemic detoxification and/or interrupting the enterohepatic circulation at a later date might be poorly effective.

Topics: Alpha-Amanitin; Amanitins; Animals; Aspartate Aminotransferases; Disease Models, Animal; Enterohepatic Circulation; Female; Histocytochemistry; Liver Failure, Acute; Prothrombin Time; Swine

The foraging of wild mushrooms can be complicated by toxicity from several mushroom types. Amatoxin, a peptide contained in several mushroom species, accounts for the majority of severe mushroom poisonings by binding to RNA polymerase II irreversibly, leading to severe hepatonecrosis. There is no effective antidote for severe amatoxin poisoning. We compare the effectiveness of 5 potential antidotal therapies in limiting the degree of hepatonecrosis in a randomized, controlled, murine model of amatoxin-induced hepatotoxicity.. One hundred eighty male Institute of Cancer Research mice were randomized into 6 equal groups. Within each group, 21 mice were intraperitoneally injected with 0.6 mg/kg of alpha-amanitin (amatoxin); the remaining 9 were injected with 0.9% normal saline solution. Four hours postinjection, each group of 30 mice was randomized to 1 of 5 intraperitoneal treatments (N-acetylcysteine, benzylpenicillin, cimetidine, thioctic acid, or silybin) or normal saline solution. Repeated dosing was administered intraperitoneally every 4 to 6 hours for 48 hours. After 48 hours of treatment, each subject was killed, cardiac blood was aspirated for hepatic aminotransferase measurements (alanine transaminase and aspartate transaminase), and liver specimens were harvested to evaluate the extent of hepatonecrosis. The degree of hepatonecrosis was determined by a pathologist blinded to the treatment group and divided into 5 categories according to percentage of hepatonecrosis.. Amanitin significantly increased aspartate transaminase in treated mice compared with normal saline solution-treated controls (mean [SD] 2,441 [2,818] IU/L versus 310 [252]; P=.03). None of the antidotal therapies were found to significantly decrease the increase in aminotransferases compared with controls. Further, none of the antidotal therapies demonstrated an important decrease in hepatonecrosis compared with controls when a histologic grading scale was used.. In this murine model, N-acetylcysteine, benzylpenicillin, cimetidine, thioctic acid, and silybin were not effective in limiting hepatic injury after alpha-amanitin poisoning. Increases of aminotransferases and degrees of histologic hepatonecrosis were not attenuated by these antidotal therapies.

Topics: Acetylcysteine; Alanine Transaminase; Amanitins; Animals; Antidotes; Aspartate Aminotransferases; Chemical and Drug Induced Liver Injury; Cimetidine; Disease Models, Animal; Male; Mice; Mushroom Poisoning; Penicillin G; Random Allocation; Silybin; Silymarin; Thioctic Acid

The purpose of this study was to develop a clinically relevant porcine model of fulminant hepatic failure (FHF) by means of administration of amatoxin and endotoxin.. Pigs were intraportally administered only saline in group 1 (n = 3), 1 microg/kg of lipopolysaccharide (LPS) in group 2 (n = 4), 0.1 mg/kg of alpha-amanitin in group 3 (n = 5), and amanitin plus LPS in group 4 (n = 9).. All the pigs in groups 1 and 2 survived with minimal changes in liver function tests. In contrast to the 60% mortality in group 3, all the pigs in group 4 died within 96 h, with a significant increase in aspartate transaminase at 24 h (9,757 +/- 2,167 IU/I). In addition, they demonstrated severe metabolic disorders, such as serum lactate accumulation, hypoglycemia, coagulopathy, plasma amino acid imbalance, and hyperammonemia. The intracranial pressure significantly increased to 17.8 +/- 2.5 mmHg immediately before death. Reversal of FHF in these pigs following orthotopic liver transplantation confirmed that the toxicity is liver-specific and that the graft liver is unaffected.. This porcine model of FHF induced by a combination of amanitin and LPS will be of much use in the development of new therapies for human FHF.

Topics: Amanitins; Animals; Disease Models, Animal; Humans; Intracranial Hypertension; Lipopolysaccharides; Liver; Liver Failure; Liver Transplantation; Male; Swine