Elucidation of the mechanism of vitamin A potentiation of carbon tetrachloride-induced liver injury.

El. Sisi, Alaa El. Din El. Sayed.

January 1987

The liver is a target tissue for Vitamin A toxicity. High doses of Vitamin A have been shown to produce hepatomegaly, portal hypertension, fatty liver, and hepatic degeneration and fibrosis. Of concern to us was the potential interactions of Vitamin A with other known or potential hepatotoxicants. Male SD rats (18o-200 gm) were given Vitamin A (retinol, 250,000 IU/Kg) daily for 7 days by oral gavage. 24 hr after the last dose of Vitamin A, they were then challenged with CCl₄ (0.15 ml/Kg, ip). Ethane, as a marker of lipid peroxidation, was measured during the first 2 hr and hepatic injury was assessed at 24 hr after CCl₄. There was approximately 5-fold increase in ethane exhalation and 17-fold increase in Plasma GPT activity in Vitamin A/CCl₄ group. There was also increase in the incidence of hepatocellular necrosis. Vitamin A pretreatment did not increase the metabolism of 14CCl₄ as examined by the amount of exhaled ¹⁴CO₂, and the covalent binding of ¹⁴C-equivalents to liver lipids and proteins. In addition, liver levels of Vitamin E or GSH were not changed by Vitamin A. Electron microscopic analysis of livers from Vitamin A treated rats revealed activated Kupffer cells. To determine if the Kupffer cells were functionally more active, the clearance of intravenously administered colloidal carbon from the blood of Vitamin A treated rats was compared to that of control rats. It was found that Vitamin A treated rats cleared carbon particles three times faster than that of controls. Therefore, we hypothesized that Vitamin A activation of Kupffer cells may be the mechanism of potentiation of liver injury. When stimulated, these activated cells could release active oxygen species which could promote peroxidation of hepatocyte membranes and potentiate CCl₄-induced liver injury. To test this hypothesis animals were treated with superoxide dismutase or catalase to catalyze the degradation of active oxygen species; or with methyl palmitate to deactivate Kupffer cells. Superoxide dismutase, catalase or methyl palmitate completely inhibited the Vitamin A potentiation of CCl₄ induced liver injury, but did not alter the toxicity of CCl₄ in non-Vitamin A treated rats. In addition, these agents inhibited the enhanced lipid peroxidation observed in Vitamin A treated rats administered CCl₄. Therefore, we conclude that the Vitamin A potentiation of CCl₄ induced liver injury results from Vitamin A's ability to activate Kupffer cells. Upon minimal hepatocellular injury produced by CCl₄, these activated Kupffer cells are stimulated to release activated oxygen species. It is these reactive intermediates that induce the enhanced lipid peroxidation that results in the potentiated response.

Vitamin A -- Toxicology.

Liver -- Wounds and injuries.

Protective mechanisms of garlic and wolfberry derivatives on acute and chronic liver injury animal models

Xiao, Jia, 肖佳

January 2012

Liver is one of the most important organs in the body that maintains the homeostasis of metabolism, immunity, detoxification and hematopoiesis. A large number of acute and chronic intoxications and diseases can influence the normal functions of the liver, leading to irreversible liver damage and even cancer. Currently, applying herbs or herbal derivatives in the prevention and therapy of acute and chronic liver injury receive numerous attentions since they hold great potentials as food supplements in the treatment strategy of liver injuries. There were two major hypotheses of this current work namely: a)In CCl4-inducedacute liver injury animal model, whether pre-treatment with garlic derived S-allylmercaptocysteine (SAMC)or Wolfberry derived Lycium barbarum polysaccharides (LBP)could reduce liver injury, oxidative stress and inflammation partly through a NF-κB-dependent pathway. SAMC or LBP could also promote liver regeneration after acute damage. b)In non-alcoholic steatohepatitis (NASH)-induced chronic liver injury animal model, whether administration of SAMC or LBP along with high-fat diet induction could attenuate liver injury, lipid metabolism dysfunction, fibrosis, oxidative stress, inflammation, apoptosis and transcription factors activities in the liver. In this study, SAMC and LBP were applied in a carbon tetrachloride (CCl4) induced mice acute liver injury model and a high-fat diet induced non-alcoholic steatohepatitis model. In the acute model, an eight-hour CCl4treatment induced severe acute liver injury. Pre-treatment with SAMC or LBP (1) attenuated hepatic histological injury; (2) reduced serum ALT level; (3) ameliorated oxidative stress; (4) reduced expression of inflammatory mediators and chemokines; (5) promoted liver regeneration; and (6) decreased NF-κB activity. Vehicle-treated SAMC or LBP did not exhibit obvious adverse effects on healthy mice. In the chronic NASH model, when compared with control rats, NASH rats showed typical clinical features of human NASH patients, including increased liver injury, lipid content, oxidative stress, inflammation, and apoptosis. In comparison, SAMC or LBP co-treated NASH rats showed (1) reduced fat accumulation, cellular necrosis, collagen formation, as well as reduced serum ALT and free fatty acids levels; (2) restored insulin resistance related kinase phosphorylation status which had been altered during NASH; (3) reduced pro-fibrogenic factors; (4) restored antioxidant enzymes, as well as attenuated end-products of lipid peroxidation and NO production through a cytochrome P450 2E1-dependent pathway; (5) reduced hepatic pro-inflammatory mediators and chemokines production; (6) diminished activities of nuclear transcription factors (NF-κB and AP-1); and (7) ameliorated hepatic cellular apoptosis through a p53-dependentpathwaywhich was under the regulation of LKB1/AMPK axis and PI3K/Akt axis. In conclusion, our data demonstrated that SAMC or LBP consumption protects the liver from acute injury caused by CCl4and chronic damages caused by a high-fat diet. These effects were mainly mediated by the amelioration of hepatic oxidative stress, inflammation, and cell death. In the NASH model, SAMC or LBP also improved hepatic lipid metabolism, fibrosis, and apoptosis. Therefore, the present study proposed that both garlic and Wolfberry, which are novel hepatoprotective herbal products, can be taken as part of the daily dietary supplements in the prevention of acute and chronic liver injury. / published_or_final_version / Anatomy / Doctoral / Doctor of Philosophy

Phytochemicals - Therapeutic use

Liver - Wounds and injuries

The role of glutathione peroxidase 3 (GPx3) : bridging graft injury and tumor invasiveness

Qi, Xiang, 祁翔

January 2014

Background and Objective: Severe inflammation resulted from small-for-size liver graft injury provides favorable environment for tumor growth. The oxidative stress not only accelerates the inflammatory response, but also stimulates the proliferation of cancer cells. Therefore, attenuating oxidative stress after liver surgery may not only ameliorate liver injury, but also suppress tumor growth and metastasis. Glutathione peroxidase 3 (GPx3) is an anti-oxidant which has been reported to be down-regulated in several types of cancer. Here, we aimed to investigate the clinical significance of GPx3 and characterize the role of GPx3 in liver graft injury and hepatocellular carcinoma (HCC). Furthermore, we intended to explore the therapeutic value of GPx3 using hiPSC-MSCs as a delivery vehicle in hepatic ischemia-reperfusion injury and HCC. Materials and methods: To investigate the clinical significance of GPx3, the HCC patients underwent liver transplantation (106 recipients) or hepatectomy (113 patients) were recruited to study the correlation of GPx3 with clinical parameters. To explore the mechanism of GPx3 in liver graft injury, simulated IR injury model and rat liver transplantation model were applied. To examine the effect of GPx3 on HCC, rGPx3 administration and forced-expression of GPx3 within HCC cells were performed in vitro and in vivo. To explore the therapeutic value of GPx3, engineered hiPSC-MSCs delivering GPx3 was established and applied in mice hepatic IR injury model and nude mice liver cancer model. Results: I. The role of GPx3 in graft injury. The intra-graft GPx3 expression was significantly down-regulated in small-for-size graft accompanied with severe graft injury in a rat liver transplantation model. Clinically, the lower plasma GPx3 was mainly observed in the recipients with small-for-size liver graft. Furthermore, the lower plasma GPx3 significantly correlated with higher tumor recurrence post-transplantation. The down-regulation of GPx3 was associated with hepatic senescence in small-for-size graft. GPx3 treatment delivered by hiPSC-MSCs could significantly ameliorated hepatic IR injury through inhibition of macrophages activation followed by decreased production of ROS, TNFα and IL-1. II. The role of GPx3 in HCC. Down-regulation of GPx3 in liver tumor was observed in half of HCC patients (56/113). It significantly correlated with advanced pTNM stage (P = 0.024), presence of venous infiltration (P =0.043) and high AFP level (P = 0.006). The one year (P = 0.038) and five year (P = 0.019) recurrence rate were significantly higher in the patients with lower GPx3 expression. In functional study, rGPx3 administration and over-expression of GPx3 significantly suppressed proliferation and invasiveness of HCC cells in vitro and in vivo. The tumor suppressive activity of GPx3 was mediated by inhibition of EMT through Erk-NFκB-SIP1 pathway. The GPx3 treatment delivered by hiPSC-MSCs could significantly inhibit proliferation of MHCC97L. Conclusions: I. Down-regulation of GPx3 was associated with small-for-size graft injury. Low circulating GPx3 at early phase after transplantation predicted higher tumor recurrence of HCC recipients. II. Down-regulation of GPx3 indicated poor prognosis of HCC patients. GPx3 suppressed tumor growth and invasiveness by inhibition of EMT through Erk-NFκB-SIP1 pathway. III. Engineered hiPSC-MSCs delivering GPx3 may possess therapeutic value in liver graft injury and HCC. / published_or_final_version / Surgery / Doctoral / Doctor of Philosophy

Liver - Wounds and injuries

Glutathione transferase

Liver - Cancer

Hepatocellular injury induced by endotoxin and galactosamine

Teng, Shuzhi., 滕曙智.

January 2000

published_or_final_version / Pharmacology / Doctoral / Doctor of Philosophy

Endotoxins - Physiological effect.

Liver - Wounds and injuries.

Liver - Effect of drugs on.

An in vivo study on the distinctive role of inducible and endothelial nitric oxide synthase in carbon tetrachloride-induced liver injury

Leung, Tung-ming., 梁東明.

January 2006

published_or_final_version / abstract / Anatomy / Doctoral / Doctor of Philosophy

Nitric-oxide synthase.

Nitric oxide.

Liver - Wounds and injuries.

The significance of hepatic stellate cell activation in small-for-sizefatty liver graft injury

Lam, Shi., 林璽.

January 2007

published_or_final_version / Surgery / Master / Master of Research in Medicine

Fat cells.

Fatty liver.

Liver - Transplantation.

Liver - Wounds and injuries.

Small-for-size graft injury in adult living donor liver transplantation

Chan, See-ching., 陳詩正.

January 2010

published_or_final_version / Surgery / Doctoral / Doctor of Philosophy

Liver - Transplantation.

Living related donor transplantation.

Liver - Wounds and injuries.

The role of interferon-gamma inducible protein 10 (IP10) in early-phase graft injury induced late-phase cisplatin resistance after livertransplantation

Geng, Wei, 耿瑋

January 2012

Background: Hepatocellular carcinoma is one of the most fatal diseases worldwide. Liver transplantation dramatically improved the survival rate of HCC patients. However, tumor recurrence remains a huge threat to HCC patients without any promising curative treatment. Chemotherapy, as one of the potential treatments to recurrent HCC, did not show any significant effect either. Objective: We aim to investigate the role of interferon-gamma inducible protein 10 (IP10) in acute-phase liver graft injury induced late-phase cisplatin resistance after liver transplantation and to explore the underlying mechanism. Furthermore, a potential adjuvant therapy was expected to be identified to sensitize cisplatin treatment in HCC. Materials and methods: A rat orthotopic liver transplantation model was established with applying whole or small-for-size (50%) graft. Afterwards, a rat hepatoma cell (MH7777) was injected via portal vein to generate recurrent tumor. The expressions of genes linked to multi-drug resistance and graft injury were compared between tumors developed after liver transplantation using small and whole grafts. IP10 expression was further validated in clinical samples from two cohorts of patients including HCC patients with hepatectomy and HCC patients with liver transplantation. The extracellular and intracellular roles of IP10 were examined in vitro by using IP10 recombinant protein and IP10 stable transfectants in HCC cell lines. The correlation between IP10 expression and tumor growth was investigated in three in vivo nude mice models including a subcutaneous model, an orthotopic model and ischemia reperfusion injury model. The underlying mechanism was further explored in vitro, in vivo and in clinical samples. IP10 neutralizing antibody was employed as an adjuvant therapy to identify its effect on sensitizing cisplatin treatment in HCC. Results: The expressions of multidrug resistant genes were significantly up-regulated in liver and tumor from small-for-size group in rat liver transplantation model. IP10 was selected as the potential target for its constantly higher expression in liver and tumor tissues in small-for-size group. In clinical studies, IP10 was overexpressed in around 45% HCC patients with hepatectomy. The expression of circulating IP10 well correlated with tumor recurrence and small graft ratio in HCC patients after liver transplantation. In in vitro studies, it was demonstrated that overexpression of IP10 could significantly promote HCC cell proliferation either in short term or in long term cisplatin administration. In in vivo studies, subcutaneous and orthotopic nude mice models showed that the overexpression of IP10 have significant correlations with larger tumor volume and less tumor necrosis after cisplatin treatment. In mechanism studies, IP10 overexpression was found to be well correlated with the activation of endoplasmic reticulum (ER) stress signaling pathways in vitro and further validated in vivo models and in clinical specimens. IP10 neutralizing antibody was identified as a potential therapy which could sensitize cisplatin treatment in vitro and in vivo. Conclusions: The high expression of IP10 was identified in two cohorts of clinical samples and showed significant correlations with tumor recurrence. Graft injury induced IP10 overexpression could significantly increase cisplatin resistance after liver transplantation via ER stress signaling pathways. IP10 neutralizing antibody may be applied as an alternative treatment for recurrent HCC after liver transplantation. / published_or_final_version / Surgery / Doctoral / Doctor of Philosophy

Chemokines.

Cisplatin.

Drug resistance.

Liver - Transplantation.

Liver - Wounds and injuries.

Pharmacological modulation of endotoxin-induced hepatic injury in galactosamine-sensitized mice

許慧慧, Hu, Wai-wai, Stella.

January 1992

published_or_final_version / Pharmacology / Master / Master of Philosophy

Liver - Wounds and injuries.

Endotoxins - Physiological effect.

Mice - Physiology.

The role of graft injury in mobilization of endothelial progenitor cells, myeloid derived suppressor cells and regulatory T cells afterlive transplantation

Ling, Changchun., 凌长春.

January 2012

Liver transplantation is the best therapy for patients with end-stage liver diseases and unresectable early hepatocellular carcinoma (HCC). Living donor liver transplantation (LDLT) has been successfully implemented as an alternative to deceased donor liver transplantation (DDLT) and likewise offers comparable excellent survival rate. However, the inferior post-transplant oncological outcomes are found in LDLT recipients with HCC. The liver grafts used in LDLT are usually small-for-size and less effective in coping with shear stress from transient portal hypertension, which results in small-for-size liver graft injury. Acute phase small-for-size liver graft injury may promote late phase tumor recurrence, whereas the underlying mechanism remains unclear. CXCL10, an inflammatory chemokine, initiates liver inflammatory response during hepatic ischemia-reperfusion (IR) injury and may link acute phase small-for-size liver graft injury and late phase tumor recurrence, yet the precise mechanisms remain elusive. Endothelial progenitor cells (EPCs) participate in tissue repair for graft recovery and also provide an angiogenic environment for tumor growth. Myeloid derived suppressor cells (MDSCs) and regulatory T cells (Tregs) can suppress the activation of the immune system and play a critical role in graft rejection and cancer development. We here established the rat orthotopic liver transplantation with whole graft or small-for-size graft model to study the impact of acute phase small-for-size liver graft injury on the mobilization of EPCs, MDSCs and Tregs, and intragraft CXCL10 and its receptor, CXCR3,gene expressions. We further subjected CXCL10-/-mice and CXCR3-/-mice to hepatic IR injury and major hepatectomy to study the role of CXCL10/CXCR3 signaling on the mobilization of EPCs, MDSCs and Tregs. We also investigated the effect of CXCL10 on EPC migration and tube formation in vitroas well as intratumoral microvessel density (MVD) in the rat liver transplantation with tumor growth model and EPCs on tumor growth in nude mice. Key findings: 1. Liver transplantation with small-for-size graft resulted in severe intragraft vascular injury and higher CXCL10 andCXCR3 gene expressions as well as more EPC, MDSC and Treg cell mobilizationin circulation than whole graft. 2. CXCL10-/-mice and CXCR3-/-mice had less circulating EPCs, MDSCs and Tregs than WT mice after hepatic IR injury and major hepatectomy. 3. CXCL10 recruited EPCs in dose-dependent and CXCR3-dependent manners and promoted EPC tube formation in vitro. 4. Higher intratumoral MVD was observed in small-for-size graft than in whole graft in liver transplantation with tumor growth model. 5. Tumor grew more quickly by combining EPC infusionin nude mouse orthotopic liver tumor model. In conclusion, acute phase small-for-size liver graft injury significantly mobilizes EPCs, MDSCs and Tregs after transplantation through CXCL10/CXCR3 signaling. More EPC mobilization and intragraft differentiation after transplantation with small-for-size liver graft may be related to higher intratumoral MVD in small-for-size liver graft after transplantation with tumor development. Therefore, targeting at post-transplant CXCL10/CXCR3 signaling may not only attenuate early phase liver graft injury but also prevent late phase tumor recurrence. / published_or_final_version / Surgery / Doctoral / Doctor of Philosophy

Liver - Transplantation.

Living related donor transplantation.

Liver - Wounds and injuries.

Vascular endothelium.

Suppressor cells.

T cells.