Acetaldehyde-collagen adducts in CCl4-induced liver injury in rats

Circulating AC levels as well as antibodies against AC-protein adducts are increased in non-alcoholic liver injury. To identify the adducts, we used rats with CCl4-induced cirrhosis. Liver subcellular fractions were analyzed by immunochemical staining of protein slot blots and of electrophoretically separated proteins, transferred to nitrocellulose, using AC-protein adduct-specific antibodies. One reactive protein of about 200 kD was detected in the liver soluble fraction and in the cytosol of isolated hepatocytes and, to a lesser extent in the liver microsomes of CCl4-treated rats; in control animals, this reactivity was much weaker. The immunopositive AC adduct co-migrated with the beta 1,2 dimer of rat collagen type I; it was sensitive to digestion by a highly purified collagenase and also reacted with anti-rat collagen type I-specific IgG. In addition, comparison of peptides of the CNBr-digested, immunoprecipitated AC adduct with those of rat collagen type I revealed a high degree of similarity. Thus, AC adduct formation occurs in liver injury of non-alcoholic origin, and a target protein appears to be related to collagen type I, most likely the procollagen precursor.     

Role of mitochondria in alcoholic liver injury

Oxidative stress and oxygen-derived free radicals are well known to play an important role in the pathogenesis of ethanol-associated liver injury. Active oxidants produced during ethanol metabolism induce mitochondrial membrane depolarization and permeability changes in cultured hepatocytes. These mitochondrial alterations (loss of DeltaPsim and mitochondrial permeability transition [MPT]) are now recognized as a key step in apoptosis. In recent studies, including ours, the MPT has been identified as a key step for the induction of mitochondrial cytochrome c release and caspase activation by ethanol. In addition, chronic and/or acute ethanol modulates intracellular, especially mitochondrial, antioxidant levels, leading to the increased susceptibility to alcoholic liver injury induced by several apoptotic stimuli. In this review, we address the mechanism of mitochondrial alterations and liver injury induced by ethanol.     

Role of nitric oxide in liver injury

The complex role of nitric oxide (NO) in the liver can be explained by its patterns of regulation and unique biochemical properties. With a broad range of direct and indirect molecular targets, NO acts as an inhibitor or agonist of cell signaling events. In the liver, constitutively generated NO maintains the hepatic microcirculation and endothelial integrity, while inducible NO synthase (iNOS)-governed NO production can be either beneficial or detrimental. For instance, NO potentiates the hepatic oxidative injury in warm ischemia/reperfusion, while iNOS expression protects against hepatic apoptotic cell death seen in models of sepsis and hepatitis. Anti-apoptotic actions are either cyclic nucleotide dependent or independent, including the expression of heat shock proteins, prevention of mitochondrial dysfunction, and inhibition of caspase activity by S-nitrosation. Whether NO protects or injures is probably determined by the type of insult, the abundance of reactive oxygen species (ROS), the source and amount of NO production and the cellular redox status of liver. Through the use of pharmacological NO donors or NOS gene transfer in conjunction with genetically altered knockout animals, the physiological and pathophysiological roles of NO in liver function can be explored in more detail. The purpose of this paper is to review the current understanding of the role of NO in liver injury.     

Role of caspases in acetaminophen-induced liver injury

The mode of cell death after acetaminophen (AAP) overdose is controversially discussed. A recent study reported a protective effect of the pancaspase inhibitor Z-VAD-fmk against AAP toxicity in vivo but the mechanism of protection remained unclear. Therefore, the objective of this investigation was to assess if Z-VAD-fmk or the low doses of dimethyl sulfoxide (DMSO) used as solvent were responsible for the protection. Treatment with 10 mg/kg Z-VAD-fmk or diluted DMSO (0.25 ml/kg) for 15 min before but not 2.5 h after AAP prevented the oxidant stress (hepatic glutathione disulfide content; nitrotyrosine staining), DNA fragmentation (anti-histone ELISA, TUNEL assay) and liver injury (plasma ALT activities) at 6 h after administration of 300 mg/kg AAP. Even a lower dose (0.1 ml/kg) of DMSO was partially effective. DMSO pretreatment also attenuated the initial decline in hepatic glutathione levels. On the other hand, 10 microM Z-VAD-fmk was unable to prevent AAP-induced cell death in primary cultured mouse hepatocytes. We conclude that Z-VAD-fmk does not protect against AAP-induced liver injury and, therefore, caspases are not involved in the mechanism of AAP-induced liver injury. In contrast, the protection in vivo is caused by the diluted DMSO, which is used to solubilize the inhibitor Z-VAD-fmk. The results emphasize that even very low doses of DMSO, which are generally necessary to dissolve water-insoluble inhibitors, can have a profound impact on the toxicity of drugs and chemicals when metabolic activation is a critical aspect of the mechanism of cell injury.     

Role of stem cells during diabetic liver injury

Diabetes mellitus is one of the most severe endocrine metabolic disorders in the world that has serious medical consequences with substantial impacts on the quality of life. Type 2 diabetes is one of the main causes of diabetic liver diseases with the most common being non‐alcoholic fatty liver disease. Several factors that may explain the mechanisms related to pathological and functional changes of diabetic liver injury include: insulin resistance, oxidative stress and endoplasmic reticulum stress. The realization that these factors are important in hepatocyte damage and lack of donor livers has led to studies concentrating on the role of stem cells (SCs) in the prevention and treatment of liver injury. Possible avenues that the application of SCs may improve liver injury include but are not limited to: the ability to differentiate into pancreatic β‐cells (insulin producing cells), the contribution for hepatocyte regeneration, regulation of lipogenesis, glucogenesis and anti‐inflammatory actions. Once further studies are performed to explore the underlying protective mechanisms of SCs and the advantages and disadvantages of its application, there will be a greater understand of the mechanism and therapeutic potential. In this review, we summarize the findings regarding the role of SCs in diabetic liver diseases.     

Role of nitric oxide in liver ischemia and reperfusion injury

The present study was designed to assess the role of endothelial cell and inducible nitric oxide synthase (eNOS, iNOS)-derived NO in ischemia/reperfusion (I/R)-induced pro-inflammatory cytokine expression and tissue injury in a murine model of hepatic I/R. Forty-five min of partial hepatic ischemia and 3 h of reperfusion resulted in a significant increase in liver injury as assessed by serum alanine aminotransferase and histopathology which occurred in the absence of neutrophil infiltration. Both iNOS and eNOS deficient mice exhibited enhanced liver injury when compared to their wild type (wt) controls again in the absence of neutrophil infiltration. Interestingly, message expression for both tumor necrosis factor-alpha (TNF-) and interleukin 12 (IL-12) were enhanced in eNOS, but not iNOS-deficient mice at 1 h post-ischemia when compared to their wt controls. In addition, eNOS message expression appeared to be up-regulated between 1 and 3 h of reperfusion in wt mice while iNOS deficient mice exhibited substantial increases at 1 but not 3 h. Taken together, these data demonstrate the ability of eNOS and iNOS to protect the post-ischemic liver, however their mechanisms of action may be very different.     

Role of nitric oxide in liver ischemia and reperfusion injury

The present study was designed to assess the role of endothelial cell and inducible nitric oxide synthase (eNOS, iNOS)-derived NO in ischemia/reperfusion (I/R)-induced pro-inflammatory cytokine expression and tissue injury in a murine model of hepatic I/R. Forty-five min of partial hepatic ischemia and 3 h of reperfusion resulted in a significant increase in liver injury as assessed by serum alanine aminotransferase and histopathology which occurred in the absence of neutrophil infiltration. Both iNOS and eNOS deficient mice exhibited enhanced liver injury when compared to their wild type (wt) controls again in the absence of neutrophil infiltration. Interestingly, message expression for both tumor necrosis factor-alpha (TNF-alpha) and interleukin 12 (IL-12) were enhanced in eNOS, but not iNOS-deficient mice at 1 h post-ischemia when compared to their wt controls. In addition, eNOS message expression appeared to be up-regulated between 1 and 3 h ofreperfusion in wt mice while iNOS deficient mice exhibited substantial increases at I but not 3 h. Taken together, these data demonstrate the ability of eNOS and iNOS to protect the post-ischemic liver, however their mechanisms of action may be very different.     

Role of lipopolysaccharide-binding protein in early alcohol-induced liver injury in mice

Cellular responses to endotoxins are enhanced markedly by LPS-binding protein (LBP). Furthermore, it has been demonstrated that endotoxins and proinflammatory cytokines such as TNF-alpha participate in early alcohol-induced liver injury. Therefore, in this study, a long-term intragastric ethanol feeding model was used to test the hypothesis that LBP is involved in alcoholic hepatitis by comparing LBP knockout and wild-type mice. Two-month-old female mice were fed a high-fat liquid diet with either ethanol or isocaloric maltose-dextrin as control continuously for 4 wk. There was no difference in mean urine alcohol concentrations between the groups fed ethanol. Dietary alcohol significantly increased liver to body weight ratios and serum alanine aminotransferase levels in wild-type mice (189 +/- 31 U/L) over high-fat controls (24 +/- 7 U/L), effects which were blunted significantly in LBP knockout mice (60 +/- 17 U/L). Although no significant pathological changes were observed in high-fat controls, 4 wk of dietary ethanol caused steatosis, mild inflammation, and focal necrosis in wild-type animals as expected (pathology score, 5.9 +/- 0.5). These pathological changes were reduced significantly in LBP knockout mice fed ethanol (score, 2.6 +/- 0.5). Endotoxin levels in the portal vein were increased significantly after 4 wk in both groups fed ethanol. Moreover, ethanol increased TNF-alpha mRNA expression in wild-type, but not in LBP knockout mice. These data are consistent with the hypothesis that LBP plays an important role in early alcohol-induced liver injury by enhancing LPS-induced signal transduction, most likely in Kupffer cells.     

Role of carnosine in preventing thioacetamide-induced liver injury in the rat

Carnosine (beta-alanyl-L-histidine) is a dipeptide with antioxidant properties. Free radicals are involved in the pathogenesis of acute liver injury induced by thioacetamide (TAA). In this study, we investigated the effect of carnosine treatment on TAA-induced oxidative stress and hepatotoxicity. Rats were injected intraperitoneally with TAA (500 mg/kg) and carnosine (250 mg/kg, intraperitoneal) was co-administered with TAA. All animals were killed 24 h after injections. TAA administration resulted in hepatic necrosis, significant increases in plasma transaminase activities as well as hepatic lipid peroxide levels. In addition, hepatic antioxidant system was found to be depressed following TAA administration. When carnosine was co-administered with TAA in rats, plasma transaminase activities were found to approach to normal values in rats. Histological findings also suggested that carnosine has preventive effect on TAA-induced hepatic necrosis. Carnosine treatment caused significant decreases in lipid peroxide levels in TAA-treated rats without any changes in enzymatic and non-enzymatic antioxidants except vitamin E in the liver of rats. Our findings indicate that carnosine, in vivo may have a preventive effect on TAA-induced oxidative stress and hepatotoxicity by acting as an non-enzymatic antioxidant itself.     

Role of the functional state of the liver RES in the pathogenesis of toxic liver injury

In rats to which E. coli endotoxin (250 micrograms/kg i.p.) was administered 24 h before they were given tetrachlormethane (CCl4) (1.5 ml/kg intragastrically), stimulation of liver DNA synthesis was observed during the first 48 h after administration of the hepatatoxin. In experimental rats to which prodigiosan (a Serratia marcescens polysaccharide, 250 micrograms/kg i.p.) was administered 24 h before CCl4 (1.5 ml/kg i.p.), liver damage 24 h after CCl4 poisoning was expressed less--judging from the size of liver necrosis and the size of glycogen-free zones in the liver lobules than in the controls. To elucidate the role of activated macrophages in the induction of liver resistance to CCl4, liver injury caused by this hepatotoxin was compared after the pre-administration of protein extract from the Kupffer cells or hepatocytes of prodigiosan-stimulated rats. In rats given the larger dose of Kupffer cell extract (6 mg/ml i.p.), the necrotic foci formed after the administration of CCl4 were significantly smaller. The results confirm the conception that liver macrophages participate in the development of resistance to CCl4.     

Role of NADPH oxidase-derived superoxide in reduced size liver ischemia and reperfusion injury

Hepatic resection with concomitant periods of ischemia and reperfusion (I/R) is required to perform reduced size liver transplantation such as split liver or liver donor transplantation. Although great progress has been made using these types of surgeries, there remains substantial risk to both donors and recipients, with a significant number of patients developing liver injury and failure. The objective of this study was to assess the roles of superoxide (O(2)(-)) and tumor necrosis factor-alpha (TNF-alpha) in the pathophysiology of a mouse model of reduced size liver combined with ischemia and reperfusion (RSL+I/R). We found that all male mice subjected to RSL+I/R died within 3-5 days following surgery. Mortality was always preceded by dramatic increases in liver injury and TNF-alpha expression in the absence of neutrophil infiltration. Using a long-lived, polycationic form of human manganese superoxide dismutase (pcMnSOD), NADPH oxidase-deficient mice (gp91(-/-)) or a monoclonal antibody directed against mouse TNF-alpha, we demonstrated that hepatocellular injury (and mortality) were significantly attenuated. In addition, we found that pcMnSOD administration or NADPH deficiency reduced expression of TNF-alpha. Taken together, our data suggest that NADPH oxidase-derived O(2)(-) plays an important role in the pathophysiology of RSL+I/R-induced liver injury via its ability to enhance expression of TNF-alpha. We propose that therapies directed toward scavenging of O(2)(-), inhibiting NADPH oxidase, and/or immuno-neutralizing TNF-alpha may prove useful in limiting the liver injury induced by surgical procedures that require resection and I/R such as split liver or living donor liver transplantation.     

细胞自噬在大鼠肺缺血/再灌注引发肝脏损伤中的作用*

目的: 探讨肺缺血/再灌注(LI/R)时肝脏损伤的影响,并初步探索细胞自噬(Autophagy)在其中发挥的作用。方法: 构建大鼠缺血/再灌注肺损伤(LI/RI)模型,模型制备方法为大鼠麻醉后切开气管进行机械通气,使用动脉夹将肺门夹闭模拟缺血过程,30 min后松开动脉夹,恢复灌注3 h。24只大鼠随机分为伪手术组(Sham组)、缺血/再灌注组(I/R组)、溶剂组(DMSO组)和自噬抑制剂组(3-MA组),每组均6只,后2组大鼠术前分别腹腔注射DMSO和3-MA,造模结束后使用肺湿/干重比判断造模是否成功;抽取静脉血测定肝脏转氨酶指标ALT与AST;取肝脏组织,光镜下观察肝脏形态改变,以及电镜下观察肝细胞超微结构;使用RT-qPCR和Western blot实验分别检测肝脏组织细胞中自噬相关蛋白的基因mRNA表达水平和蛋白表达水平。结果: 与Sham组相比,其余各组肺湿/干重比均升高;血AST和ALT均有大幅升高且肝脏组织损伤明显,其中以I/R组升高最为明显,光镜下组织形态学及电镜下细胞微细结构均有不同程度的破坏;肝脏中自噬相关蛋白的基因表达水平与蛋白表达水平均有明显不同,表现为自噬上升 (P＜0.01或P＜0.05)。I/R组和DMSO组肝脏组织均有较重损伤,肝细胞结构破坏严重,自噬小体形成,而AST、ALT、自噬相关蛋白转录和表达水平等各项指标均无统计学差异(P＞0.05)。而相较于DMSO组,3-MA组肝脏组织损伤有所减轻,肝细胞微细结构损伤程度低,且无自噬小体形成,血中AST和ALT下降,肝脏组织内自噬水平均下降 (P＜0.05)。结论: 肺缺血/再灌注可引起大鼠肝损伤;细胞自噬可介导大鼠肺缺血/再灌注引起的肝损伤,抑制细胞自噬可以有效减轻大鼠LI/R引起的肝损伤。     

Role of ICAM-1 in chronic ethanol consumption-enhanced liver injury after gut ischemia-reperfusion in rats

Intercellular adhesion molecule-1 (ICAM-1) has been implicated in the hepatic microvascular dysfunction elicited by gut ischemia-reperfusion (I/R). Although the effects of chronic ethanol (EtOH) consumption on the liver are well known, it remains unclear whether this condition renders the hepatic microcirculation more vulnerable to the deleterious effects of gut and/or hepatic I/R. The objectives of this study were to determine whether chronic EtOH consumption alters the severity of gut I/R-induced hepatic microvascular dysfunction and hepatocellular injury and to determine whether ICAM-1 contributes to this response. Male Wistar rats, pair fed for 6 wk a liquid diet containing EtOH or an isocaloric control diet, were exposed to gut I/R. Intravital video microscopy was used to monitor leukocyte recruitment in the hepatic microcirculation, the number of nonperfused sinusoids (NPS), and plasma concentrations of endotoxin and tumor necrosis factor-alpha. Plasma alanine aminotransferase (ALT) levels were measured 6 h after the onset of reperfusion. In control rats, gut I/R elicited increases in the number of stationary leukocytes, NPS, and plasma endotoxin, tumor necrosis factor-alpha, and ALT. In EtOH-fed rats, the gut I/R-induced increases in NPS and leukostasis were blunted in the midzonal region, while exaggerated leukostasis was noted in the pericentral region and terminal hepatic venules. Chronic EtOH consumption also enhanced the gut I/R-induced increase in plasma endotoxin and ALT. The exaggerated responses to gut I/R normally seen in EtOH-fed rats were largely prevented by pretreatment with a blocking anti-ICAM-1 monoclonal antibody. In conclusion, these results suggest that chronic EtOH consumption enhances gut I/R-induced hepatic microvascular dysfunction and hepatocellular injury in the pericentral region and terminal hepatic venules via an enhanced hepatic expression of ICAM-1.     

Evidence for DNA adducts in rat liver after adminstration of N-nitrosopyrrolidine

Liver DNA isolated from rats given N-nitrosopyrrolidine contained amounts of an unidentified fluorescent adduct which were dose dependent. The adduct formed gradually over the first 12 hr after administration and was slowly removed from the DNA $\text{in vivo}$. Fluorescence and chromatographic properties of the adduct suggested the compound was a substituted guanine; also, the putative adduct was readily removed from DNA by neutral thermal hydrolysis, as are 3-alkyladenines and 7-alkylguanines. Evidence was also obtained for the formation of 7-methylguanine in liver DNA of N-nitrosopyrrolidine-treated rats; however, N-nitrosopyrrolidine was not the methyl source for this alkylated guanine.     

Distribution of ethanol-induced protein adducts in vivo: relationship to tissue injury

Generation of oxygen free radicals and reactive aldehydes as a result of excessive ethanol consumption has been well established. Recent studies in human alcoholics and in experimental animal models have indicated that acetaldehyde, the first metabolite of ethanol, and the aldehydic products of lipid peroxidation can bind to proteins in tissues forming stable adducts. The demonstration of such adducts in zone 3 hepatocytes in alcoholics with an early phase of histological liver damage indicates that adduct formation may have an important role in the sequence of events leading to alcoholic liver disease. There may be interference with cellular functions, stimulation of fibrogenesis, and immunological responses. Autoantibodies towards distinct types of adducts have been shown to be associated with the severity of liver disease in alcoholic patients. High fat diet and/or iron supplementation combined with ethanol may increase the amount of aldehyde-derived epitopes and promote fibrogenesis in the liver. Recently, ethanol-derived protein modifications have also been found from other tissues exposed to ethanol and acetaldehyde, including rat brain after lifelong ethanol administration, pancreas, and rat muscle. Elevated adduct levels also occur in erythrocytes of alcoholics, which may be related to ethanol-induced morphological aberrations in hematopoiesis.     

Role of JNK translocation to mitochondria leading to inhibition of mitochondria bioenergetics in acetaminophen-induced liver injury

Previously, we demonstrated JNK plays a central role in acetaminophen (APAP)-induced liver injury (Gunawan, B. K., Liu, Z. X., Han, D., Hanawa, N., Gaarde, W. A., and Kaplowitz, N. (2006) Gastroenterology 131, 165-178). In this study, we examine the mechanism involved in activating JNK and explore the downstream targets of JNK important in promoting APAP-induced liver injury in vivo. JNK inhibitor (SP600125) was observed to significantly protect against APAP-induced liver injury. Increased mitochondria-derived reactive oxygen species were implicated in APAP-induced JNK activation based on the following: 1) mitochondrial GSH depletion (maximal at 2 h) caused increased H2O2 release from mitochondria, which preceded JNK activation (maximal at 4 h); 2) treatment of isolated hepatocytes with H2O2 or inhibitors (e.g. antimycin) that cause increased H2O2 release from mitochondria-activated JNK. An important downstream target of JNK following activation was mitochondria based on the following: 1) JNK translocated to mitochondria following activation; 2) JNK inhibitor treatment partially protected against a decline in mitochondria respiration caused by APAP treatment; and 3) addition of purified active JNK to mitochondria isolated from mice treated with APAP plus JNK inhibitor (mitochondria with severe GSH depletion, covalent binding) directly inhibited respiration. Cyclosporin A blocked the inhibitory effect of JNK on mitochondria respiration, suggesting JNK was directly inducing mitochondrial permeability transition in isolated mitochondria from mice treated with APAP plus JNK inhibitor. Addition of JNK to mitochondria isolated from control mice did not affect respiration. Our results suggests that APAP-induced liver injury involves JNK activation, due to increased reactive oxygen species generated by GSH-depleted mitochondria, and translocation of activated JNK to mitochondria where JNK induces mitochondrial permeability transition and inhibits mitochondria bioenergetics.     

Effect of Kupffer cell inactivation on ethanol-induced protein adducts in the liver

Tissue deposition of protein adducts derived from ethanol metabolism and lipid peroxidation, has been suggested to play a role in the initiation of alcoholic liver disease. The mechanisms modulating adduct formation have, however, remained unclear. We used immunohistochemical methods to examine acetaldehyde (AA) and malondialdehyde (MDA) adducts and cytochrome P4502E1 and P4503A2 expression in rats after administration of (i) an ethanol-diet (n = 6), (ii) ethanol-diet plus gadolinium chloride (GdCl(3)), a selective Kupffer cell toxicant (n = 7), or (iii) control diet (n = 6). A 4 week ethanol treatment resulted in liver steatosis, necrosis, and inflammation and deposition of protein adducts with both AA and MDA, which colocalized with areas of fatty change. The intensities (mean +/- SD) of the immunohistochemical reactions for both AA (2.50 +/- 1.23) and MDA (3.00 +/- 1.10) adducts were significantly higher in the ethanol-fed animals than in the controls (0.083 +/- 0.20) (0.16 +/- 0.25) (p <.001). GdCl(3) prevented adduct accumulation, the mean immunohistochemistry scores being 0.86 +/- 1.07 for AA and 1.64 +/- 0.63 for MDA, the former showing a more striking reduction (p <.01). The hepatic cytochrome enzymes were not different in the ethanol-fed groups with or without GdCl(3). The data indicates that Kupffer cells are involved in the generation of protein adducts with both acetaldehyde and ethanol-induced lipid peroxidation products in alcoholic liver disease.