CN128 – Phorbol12-myristate13-acetate

Green tea activity and iron overload induced molecular fibrogenesis of rat liver

a b s t r a c t
Iron overload toxicity was shown to associate with chronic liver diseases which lead to hepatic fibrosis and subsequently the progression to cancer through oxidative stress and apoptotic pathways. Green tea potential activity as chelating, anti-oxidative, or anti-apoptotic mechanisms against metal toxicity was poorly clarified. Here, we are trying to evaluate the anti-oxidant and anti-apoptotic properties of green tea in the regulation of serum hepcidin levels, reduction in iron overloads, and improve of liver fibrosis in iron overloaded experimental rats. Three groups of male adult rats were randomly classified into three groups and treated as follows: control rats, iron treated rats for two months in drinking water followed by either vehicle or green tea extract (AGTE; 100 mg/kg) treatment for 2 more months. Thereafter, we studied the effects of AGTE on iron overload-induced lipid peroxidation, anti-oxidant depletion, liver cell injury and apoptosis. Treatment of iron-overloaded rats with AGTE resulted in marked decreases in iron accumulation within liver, depletion in serum ferritin, and hepcidin levels. Iron-overloaded rats had significant increase in malonyldialdehyde (MDA), a marker of lipid peroxidation and nitric oxide (NO) in liver when compared to control group.

Also, significant change in cytochrome c and DNA content as apoptotic markers were reported in iron treated rats. The effects of iron overload on lipid peroxidation, NO levels, cytochrome c and DNA content were significantly reduced by the interven- tion treatment with AGTE (P < 0.001). Furthermore, the endogenous anti-oxidant capacities/levels (TAC) in liver were also significantly decreased in chronic iron overload and administration of AGTE restored the decrease in the hepatic antioxidant activities/levels. Also, hepatic hepcidin was shown to be signifi- cantly correlated with oxidative and apoptotic relating biomarkers as well as an improvement in liver fibrosis of iron treated rats following AGTE treatment. In-vitro analysis showed that, the improvement in iron toxicity of the liver depend mainly on antioxidant and protective ability of green tea polyphenolic compounds especiallyepigallocatechin-3-gallate (EGCG). Our study showed that green tea extract (GTE) ameliorates iron overload induced hepatotoxicity, apoptosis and oxidative stress in rat liver via inhibition of hepatic iron accumulation; improve of liver antioxidant capacity, and down regulation of serum hep- cidin as well as reduction in the release of apoptotic relating proteins. 1.Introduction Nutritional deficiency is the main target for iron deficiency in human beings with or without anemia. Thus, for all living cells, both essential roles and toxic actions of iron were reported (Wosten et al., 2000). Also, prolonged and uncontrolled ironadministration should be avoided for the potentially cellular dam- aging effects especially in liver cells (Mollet et al., 2016). Higher epidemic levels were reported as a result of excess iron in living cells.In human and animal research models, iron overload was shown to be related with hereditary hemochromatosis, tha- lassemia, and hepatic diseases such as chronic viral hepatitis, alco- holic hepatitis (Deugnier et al., 2008). Iron (Fe) is stored within liver cells in various forms including, Fe containing enzymes, fer- ritin, hemosiderin, and heme (Jomova and Valko, 2011).As a result of metal binding capacity of iron to some cellular low molecular weight proteins which act as chelators, excess iron was sequestrated, deposited within liver cells, and inducing liver tissuedamage. The deposition of iron in hepatocytes increasing the risk of developing significant fibrosis, cirrhosis, and subsequently increase the rate of morbidity and mortality (Olynyk et al., 2005). Several research studies reported a significant association between the hepatic iron concentration (HIC), hepatotoxicity, and the prog- nosis of liver fibrosis (Olynyk et al., 2005). In iron overload, excess iron promotes the generation of reac- tive oxygen species which stimulates severe oxidative damage to cellular organelles such as lipids, proteins, and nucleic acids (Siah et al., 2006). Also, the liberated oxidative free radicals trigger hep- atic inflammation via production of some proinflammatory cytoki- nes (TNF-a, nuclear factor jB) which participates in the pathogenesis of both acute, chronic liver damage, and even cirrho- sis (Uchiyama et al., 2008).Also, excess iron may have additional toxic effect on mitochon- drial membranes. It may initiates an opening of the mitochondrial pores which conducts solutes into the mitochondria and conse- quently produce more damaging process such as mitochondrial depolarization, uncoupling of oxidative phosphorylation, mito- chondrial swelling, and depletion in adenosine triphosphate. This finally leads to the release of proapoptotic proteins, like cyto- chrome c which resulting in hepatic cell necrosis or apoptosis (Uchiyama et al., 2008; Moon et al., 2010). This significant hepato- cyte apoptosis plays a significant role in the progression of hepatic fibrogenesis and carcinogenesis (Kowdley, 2004). Although, many mechanisms were present to discuss hepatocellular injury, the estimate pathways involved in liver cell dysfunction and fibrogen- esis remain to be sufficiently elucidated (Hubscher, 2003).Hepcidin is a small 25-amino acid peptide produced withinliver cell and can be estimated easily in tissue, serum or urine sam- ples (Frazer et al., 2002). Most studies reported hepcidin as an iron hormone regulator whereas, deficiency in hepciden level was observed in cases with iron overload, and that overexpression of hepcidin levels were shown in subjects with severe iron deficiency and anemia (Frazer et al., 2002).The up and down regulation of hepcidin was shown to be linked with iron disorders and in turn estimates its importance in sys- temic iron homeostasis. The hyposideremic activity of hepcidin regulates iron levels by inhibiting the intestinal absorption, the release of iron by macrophages, and control of the surface expres- sion of the iron exporter ferroportin. It was shown that hepcidin was be able to bind to ferroportin, leading to the internalization and degrading of the iron exporter (Nemeth et al., 2004a,b), thereby decreasing iron availability in the circulation. So, hepcidin may has a pivotal role in hepatic fibrogenesis and severity of liver diseases (Frazer et al., 2002), and could be used as a diagnostic parameter for staging of liver fibrosis (Frazer et al., 2002).The changes in the expression of hepcidin have been reported in many liver diseases. Lower levels of serum hepcidin/ferritin ratio were reported in iron overloaded chronic hepatitis C patients com- pared to HBV patients (Tan et al., 2012; Fujita et al., 2007). Also, hepatocyte apoptosis induced by iron overload was shown to be linked with the regulation of hepcidin (Ganz, 2011).Recently, it was reported that over expression of p53 and Fas antigens as apoptosis inducing proteins in hepatoma cells partici- pates in the regulation of hepcidin. Whereas, up regulation of these proteins has been shown to induce hepcidin gene transcription and conversely down regulation of p53 and Fas antigens resulted in down regulation of hepcidin expression (Li et al., 2013). Chemically synthesized iron chelators have been proposed for the treatment of many diseases associated with iron overload (Pangjitet al., 2015; Kulprachakarn et al., 2014; Chansiw et al., 2014). However, more adverse effects were represented during the treatment schedules that made many pharmacologists to devote their efforts to study new treatment strategies based on naturally occurred iron chelators of plant origin.Green tea was reported as one of the most naturally present iron chelators which showed both antioxidant and iron chelation activities in vivo and in vitro experimental models (Patel et al., 2012; Saewong et al., 2010). In iron overloaded experimental mod- els, hepcidin levels were regulated with both drug therapy and nat- urally occurred iron chelators (Porter et al., 2014; Gu et al., 2013;). Although, little is known about the exact regulation mechanisms proposed under these conditions, only green tea alone or in combi- nation with other drugs chelating toxic iron in plasma and tissues, and increasing the levels of hepcidin expression (Kautz et al., 2014; Yun and Vincelette, 2015; Upanan et al., 2015). From the previous data, our hypothesis that green tea as naturally occurred iron chelator of plant origin could ameliorates iron overload toxicity and prevent most iron related diseases especially liver diseases. Thus, in this study, we are trying to evaluate the anti-oxidant and anti-apoptotic properties of green tea in the regulation of serum hepcidin levels, reduction in iron overloads, and improve of liver fibrosis in iron overloaded experimental rats. 2.Materials and methods A total of 30 young albinos male Sprague Dawley rats (Rattus norvegicus) weighing 120–150 g have been randomly included in this study. The animals have been housed in healthy atmospheric conditions, normal feeding, drinking, and medical care based on the guidelines of the experimental animal care, college of science, King Saud University, Riyadh, Saudi Arabia. The experimental pro- cedures were approved by the Ethics Committee of the Experimen- tal Animal Care Society at King Saud University (Permit Number: PT 1204).The animals were divided randomly into three groups (n = 10); Control group (rats feed on normal diets without iron), Iron over- loaded group (rats feed with iron in a drinking water for two month and then left without treatment for another two month), and AGTE treated group (rats feed with iron in a drinking water for two month then treated with 100 mg/kg/day AGTE suspended in drinking water for another two month).Iron was added to drinking water in a quantity exceeds the maximum permissible concentration (MPC; Fe2+ is 0.3 mg per liter) for this chemical in Ministry of Health. Thus, rats of control group supplemented only tap water, whereas iron overloaded and AGTE groups provided with drinking water containing 3 mg/L of Fe2+ (using 8.3 mg/L of FeSO4). The dose of AGTE was selected based on previous studies (Upanan et al., 2015; Kim et al., 2009). In most animal studies, a dose range of 50–200 mg/kg body weight AGTE exhibited a good anti-inflammatory and anti-fibrotic activity and seemed to have no adverse effects on human (Saewong et al., 2010; Kim et al., 2009; Ibrahim et al., 2015). After four months, rats were sacrificed under ether anesthesia. Blood and liver tissue sam- ples were collected and subjected for subsequent histological and biochemical analysis. For biochemical analysis in liver tissues, part of the samples was immediately frozen at —80 °C until reused.A microwave cabinet was used for drying freshly harvested green tea leaves (Camellia sinensis) (Upanan et al., 2015). To pre- pare green tea extract, hot water is used. Epigallocatechin 3- gallate (EGCG) as active constituent was estimated in green tea extract by using HPLC method. The GTE product containing 28% (w/w) EGCG was kept in the dark at —20 °C until studied (Kim et al., 2009; Saewong et al., 2010).Spectrophotometric analysis were reported to estimate total flavonoid (TFC) and phenolic contents (TPC) in green tea water extract by using 2% aluminum chloride and diluted Folin- Ciocalteu as reagents (Djeridane et al., 2006). The absorbance of the reaction mixtures produced was measured at 430 nm and 725 nm respectively. Standard calibrated curves of rutin and Gallic Acid were used to estimate flavonoids and poly phenolic com- pounds in green tea samples. The data obtained were expressed in mg rutin equivalent (RE) per g for flavonoids and Gallic Acid Equivalents/100 mg for poly phenolic compounds respectively (Djeridane et al., 2006).Radical scavenging and antioxidant activities of the AGTE were measured by using spectrophotometric analysis as previously (Brand et al., 1995; Mothana, 2011). Various concentrations from the extracted green tea were prepared in hot water and both rad- ical scavenging and antioxidant activities of green tea against DPPH and b-Carotene-linoleic acid were estimated as absorbance at k = 517 nm according to the following equations:Radical scavenging activity (%)= [(Ac — As)/Ac]× 100 (1)where (Ac) is the absorbance of the control and (As) is the absor- bance of the sample.Antioxidant activity (%)= (Abs0 — Abst)/(Abs * 0 — Abs◦t)× 100(2)where Abs0 and Abs⁄ 0 are the absorbance values measured at 0 time of incubation for sample extract and control, respectively. Abst and Abs⁄ t are the absorbance values for sample extract and control, respectively, at t = 120 min.Commercially available colorimetric assays were performed to estimate liver function tests (ALT, AST, and Bilirubin), and serum ferritin as previously reported in the literature (Thapa and Anuj, 2007; Bardou-Jacquet et al., 2014). Additionally, Serum hepcidin was measured using a validated ELISA kits, as already previously described (Koliaraki et al., 2009; Bardou-Jacquet et al., 2014).Liver tissues of both iron overloaded and AGTE treated rats were investigated histologically and liver cell fibrosis scored as no fibro- sis (0–1) and fibrosis (2–3) as previously reported in literature (Scheuer, 1991).Flame atomic absorption spectroscopy (Perkin-Elmer 2380, Norwalk, CT 06859-0012, USA) was used to analyze iron in liver homogenates after digestion and dissolution in 0.1 mol/L HNO3. A total of 200 ll of liver tissue homogenates were used to esti- mate MDA by using colorimetric assay previously reported. A mix- ture of TBA (1.5 mL), 8.1% SDS (200 ll), 20% acetic acid (1.5 mL), and distilled water (600 ll) were added to the homogenates andthe resultant pink color was measured colorimetrically at 534 nm using a spectrophotometer. MDA concentration per tissue samples was calculated against standard calibration curve (Lefevre et al., 1998; Erdincler et al., 1997).Indicative levels of nitric oxide (NO) in liver tissues were esti- mated as nitrite (NO—) concentrations which considered the most stable metabolic product and can be formed by conversion of nitrate (NO—) molecules by the aids of elementary zinc. To estimate nitrite concentration in liver tissues, a classic colorimetric Griess reaction was performed by adding equal volumes of liver tissue homogenates along with Griess reagent at room temperature. The absorbance of the developed color was measured colorimetri- cally at 570 nm using a spectrophotometer. The concentration of nitrite was calculated using standard calibrated curve of sodium nitrite standard (Hortelano et al., 1995).Serum samples were used to determine total antioxidant capac- ity (TAC) by using colorimetric assay Kit (BioVision Incorporated, CA, USA). The concentrations of antioxidant capacity were mea- sured at 570 nm using a spectrophotometer. Based on manufac- turer’s instructions equivalents, the results were calculated as a function of Trolox concentration as follows.Sa/Sv = nmol/ll or mM Trolox equivalent,Sa = Sample amount (in nmol) which has been read from the standard curve.Sv = The undiluted sample volume added to the wells.Colorimetric analysis was used to estimate DNA content in liver tissue samples. DNA was extracted by using diphenylamine as organic solvent and the concentration of DNA was measured at 600 nm using a spectrophotometer (Gendimenico et al., 1988). Also, serum cytochrome c concentrations were determined using an immune assay ELISA kit (ZymedR cytochrome c ELISA Kit Cat. No. 99-0040).The data of this study have been analyzed using SPSS version17. All data have been tabulated as mean ± SD. The statistical differences were performed by using one-way analysis of variance (ANOVA) and Student’s t-test. P < 0.05 considered to be statistically significant. 3.Results Green extraction yields of phenolic and flavonoid compounds were listed in Table 1. Both Total phenolic compounds and flavo- noid contents recorded values of 29.8 ± 5.8 mg GAE/100 g, and16.9 ± 2.4 mg rutin/100 g of dry green tea extract respectively (Table 1).In the present study, in vitro antioxidant and radical scavenging activities of phenolic and flavonoid rich green tea extract were measured according to the inhibition rates of linoleic acid oxida- tion and DPPH radicals. AGET recorded free radical scavenging activity of 82.3% and 94.2% at concentrations of 500 and 1000 lg/ mL respectively, while the same extract reported antioxidant activ- ity with mean of 89.7% according to the b-carotene bleaching rate of green tea extract (Table 1).Iron overload produces significant increase in the levels of ALT and AST activity and TB concentration and decrease in the levels of albumin in iron treated rats compared to control group as shown in Fig. 1. In AGET treated rats, significant improvement was reported in the levels of ALT and AST activity and TB concentration and increase in the levels of albumin to words normal values compared to iron overloaded rats (Fig. 2). Non-significant changes were detected for all parameters between the control and group IV (Fig. 2).The data obtained showed no change in water, food consump- tion or behavior of rats during iron overload. In iron treated rats,iron administration produce about 2.8 fold increase in total hepatic iron content when compared to related values of control group as shown in figure (2A). Treatment with green tea resulted in signif- icant reduction in the levels of iron content in the livers of iron overloaded rats by fold change of 1.6 (P < 0.01). Also, serum ferritin was studied as marker of iron overload. Chronic iron loads resulted in a significant increase by about 350-fold change in ferritin when compared to healthy control rats. In AGTE group, green tea admin- istration produces significant reduction by about 125-fold change in the levels of ferritin (P < 0.001) (Fig. 2B).Also, in this study, we trying to study the anti-oxidant activity of green tea against oxidative stress induced by iron overloads. Chronic iron overloads showed significant increase in the levels of hepatic malonyldialdehyde (MDA), a corresponding biological compound commonly used as an index of oxidative stress. Whereas, significant improvement in the levels of MDA towards normal levels was reported in iron overloaded rats following treat- ment with green tea extract (P < 0.01, P < 0.001 Fig. 3A). Addition- ally, the increase in oxidative stress in iron overloaded rats was associated with a marked increase in liver NO levels (P < 0.001), and decrease in total antioxidant capacity (TAC) (P < 0.001). Green tea supplementation significantly reduced the elevation in hepatic NO levels and increase or improve TAC in iron overloaded rats as shown in Figs. 3B and 2C.Hepatic DNA content and serum cytochrome C were esti- mated as markers of apoptosis induced by iron overloads. Chronic iron overloads resulted in significant increase in serum cytochrome C and reduction in DNA content compared to nor- mal control group (P < 0.01). A significant decrease in serum levels of cytochrome c and increase in DNA content were reported in iron overloaded rats following treatment with AGTE(100 mg/kg; P < 0.001) as compared with iron treated rats (Fig. 3D). The improvement of DNA content and reduction in the expression in cytochrome c clearly confirms the preventive and anti-apoptotic role of green tea against iron overload toxicity.3.7.Effects of AGTE on expression of hepatic hepcidin in the serum of iron overloaded ratsSerum hepcidin levels were studied as marker of molecular fibrogenesis induced by iron overload. Chronic iron loads resultedin a significant increase by about 235-fold change in hepatic hep- cidin compared to healthy control rats. In AGTE group, green tea administration produces significant reduction by about 185-fold change in the levels of hepcidin as compared with iron loaded rats (P < 0.001) (Fig. 2B).The correlative effect of the expression of hepatic hepcidin in liver tissues was shown to be significantly correlated with liver cell damage, lipid peroxidation, oxidative stress, and apoptosis resulted in relation to iron overloads. The expression of hepcidin in both iron overloaded and green tea treated rats correlated negatively with hepatic iron content, serum ferritin, oxidative stress markers (MDA, NO), apoptosis markers (DNA, cytochrome C), and positively with liver function, TAC, and fibrosis score as shown in Table 2. Also, liver cell fibrosis was shown to be closely related with iron toxicity as measured by hepatic iron content, ferritin, and hepcidin levels in iron overloaded and AGRTE treated rats as shown in Table 3. 4.Discussion In the present study, the effects of excess iron administration on hepatic tissues and cellular functions were evaluated in experi- mental rats. In rats treated with chronic iron the data obtained showed significant increase in hepatic iron contents. This incre- ment was associated with significant changes in liver cell function, lipid peroxidation, and subsequent deficiency in both antioxidant defense mechanisms as well as progression of liver cell apoptosis, and fibrosis. Excess iron deposition demonstrates evidence of tissue damage and alterations in cellular function of most biological organs espe- cially liver tissues (Bancroft and Gamble, 2002). Previous research studies reported that excessive hepatic iron loads lead to the pro- gression of liver fibrosis, significant fibrosis, cirrhosis, and subse- quently increased the rates of morbidity and mortality (Britton, 2000; Olynyk et al., 2005). There are many sources relating to excess iron in human organs such as increased absorption of diet- ary iron, chronic liver and diseases associated with hemolytic ane- mia as well as drinking water with higher amounts of iron which effects on human health (Abou-Seif et al., 2004; Badria et al., 2007). Liver is one of the most important organs for vital biological activities such as metabolism, metal storage and detoxification (Tao and Gitlin, 2003). According to our results, a significant eleva- tion in ALT and AST enzyme activity, TB level, and decrease in albu- min were reported in iron overloaded rats. Also, significant changes in liver tissue cells was reported such as hepatocellular necrosis, mononuclear cells infiltration, activation of Kupffer cells, and sporadic cell necrosis as well as apoptosis. The increment in the levels of liver function may be related to disturbance in the transport function of hepatocytes, leakage, and subsequent release of hepatocellular enzymes out of hepatic cells (Mohammadyari et al., 2014; Aneja et al., 2013). Also, iron loads produce significant damage in hepatic parenchyma which results in the failure of nor- mal uptake, conjugation, excretion, and subsequent increase in TB concentration (Dubey and Mehta, 2014). In the current study significant increase in hepatic iron content and serum ferritin were reported in rats following iron treatment. A greatest iron deposition and density were reported in the hepatic cells of iron treated rats which is closely related to the severity of liver fibrosis scores (0–1 vs 2–3). The deposition of iron was signif- icantly linked with cellular hepatic damage, fibrosis score and ele- vation in liver function. Our data were in accordance with previous research reports which suggested an association between excess iron deposition and hepatic diseases such as chronic viral hepatitis and alcoholic hepatitis (Deugnier et al., 2008). Also, the increase in serum ferritin was significantly related to excess iron which stored within liver cells in various forms especially ferritin and hemosi- derin (Jomova and Valko, 2011), releasing liver tissue damage and initiates fibrosis (Olynyk et al., 2005). Similarly, several research studies reported a significant association between the hepatic iron concentration (HIC), hepatotoxicity, and the prognosis of liver fibrosis (Olynyk et al., 2005). In the current study, oxidative stress markers; MDA, NO and TAC were estimated in iron overloaded rats. The data showed sig- nificant increase in the serum levels MDA, NO, and decrease in the levels TAC in iron treated compared with healthy control rats. The data obtained significantly correlated with hepatic iron content, liver function, and staging of liver fibrosis. In normal hepatic cells, there was a homeostatic balance between the levels of ROS produced and antioxidant enzymes whereas mitochondria, peroxisomes, and microsomes produce a significant levels of ROS which maintained in a constant levels by action of enzymes like superoxide dismutase, catalase, and glu- tathione peroxidases, which degrade ROS to nontoxic by- products (Britton, 2000; Pietrangelo, 2003). In excess iron condi- tions, severe oxidant damage of cellular macromolecules was reported such as lipid peroxidation of cellular membranes and organelles, amino acid oxidation, DNA strand breaks, and protein fragmentation (Pietrangelo, 2003). Also, increased ROS, and oxida- tive stress were reported in AML-12 mouse hepatocytes following treatment with excess iron (Messner et al., 2013). The increase in hepatic iron was associated with excess ferritin levels which sug- gested behaving like inflammatory cytokine which may activate hepatic stellate cells to initiate the process of fibrogenesis (Ruddell et al., 2009). Recently, excess iron supplementation initiates hepatic oxidative stress, induction of both inflammatory and immune mediators, and hepatocellular ballooning injury which resulting in the prognosis of NASH (Handa et al., 2016). Cell death was recognized as promoters of liver damage and prognosis of hepatic fibrosis in all liver diseases such as acute and chronic viral hepatitis (Jaeschke et al., 2012 Canbay et al., 2004). The studying of biochemical markers of cell death in liver pathophysiology and fibrosis enables in the management of new therapeutic targets of liver diseases (Friedman et al., 2013; Ni et al., 2012). In the current study, cytochrome c and hepatic DNA content as apoptotic markers were estimated in iron overloaded rats. The data showed significant increase in the level of cytochrome c and reduc- tion the hepatic DNA content in rats treated with excess iron com- pared to healthy control rats. Previous research studies showed that excess iron induce dam- age of the mitochondrial inner membrane and initiate opening of the mitochondrial pores via oxidative stress mechanism. This leads to depletion in adenosine triphosphate and the release of cyto- chrome c, a proapoptotic protein of hepatic cell apoptosis (Uchiyama et al., 2008). Thus, excess iron either alone or by exerting oxidative stress synergizes in promoting hepatic cell necrosis or apoptosis (Ni et al., 2012, Moon et al., 2010). These data also clearly show that iron overload can cause apoptotic cell death in isolated hepatocytes via cell DNA fragmentation produced by ROS via oxidative stress mechanism whereas the production of ROS was the first event probably occurs in iron overloaded hepato- cytes (Allameha et al., 2008). Also, it was reported that oxidative damage of DNA resulting from excess iron may lead to the devel- opment of hepatocellular carcinoma (HCC). The increased DNA damage was associated with the increased frequency of mutations in p53, inducing apoptosis and progression of liver cell cancer (Hussain et al., 2000). Iron hemostasis was significantly regulated via synthesis of hepcidin hormone which released into the blood circulation to reg- ulate metabolism of systemic iron (Fung and Nemeth, 2013; Kuhn, 2015). In iron overload conditions, hepcidin was considered recently as one of the novel reliable markers for iron metabolism in tissue, urine, and serum samples (Porter et al., 2014; Chauhan et al., 2014; Ikuta, 2015). In the current study, serum hepcidin was estimated in iron overloaded rats. The data showed a significant increase in the serum levels of hepcidin in iron treated compared with healthy control rats. Liver cells were shown to be the main precursor for the production of hepcidin as pro-hepcidin (inactive form) which subse- quently activated via cleavage of a furin site through prohormone convertase furin process (Gu et al., 2013; Kautz et al., 2014). Under stimulation processes, the role of hepcidin is to control of local iron fluxes within liver cells (Yun and Vincelette, 2015), whereas the increase in its content was shown to be linked with serum ferritin levels in iron overloaded and inflammatory diseases (Nemeth et al., 2004a,b). The expression of hepcidin in iron overload diseases was significantly influenced by many biological factors especially the growth differentiation factor 15 and the twisted gastrulation factor 1(Kautz et al., 2014; Kartikasari et al., 2008). However, the mechanisms by which oxida- tive stress and apoptosis induced by iron overload effects on hep- cidin regulation are still unclear. In the current study, in rats treated with excess iron the expres- sion of hepcidin correlated negatively with hepatic iron content, serum ferritin, oxidative stress markers (MDA, NO), apoptosis markers (DNA, cytochrome C), and positively with liver function, TAC, and staging of liver fibrosis. The expression of hepcidin was shown to be associated with iron content and oxidative stress parameters in iron overloaded patients with low-risk myelodys- plastic syndrome (Ghoti et al., 2011). Regarding to apoptosis, many studies reported that induction of apoptosis has been suggested in the regulation of hepcidin in most liver diseases linked with iron overload (Schattenberg et al., 2006; Ganz, 2011). Also, it was reported that the expression of over-expression of p53, and Fas antigens in liver cells participate in the down regula- tion of hepcidin expression (Li et al., 2013). In contrary, our results were the first to discuss up regulation of hepcidin expression in iron overloaded models via overexpression of cytochrome C and lower DNA content as markers of apoptosis. This may be due to oxidative stress and inflammatory cytokines produced as result of iron overload (Villarroel et al., 2012; Nemeth et al., 2004a,b). Many therapeutic treatments were reported as iron chelators which characterized by some limitations such as lower specificity, limited capacity to enter cells and higher side effects especially hepatic failure (Gagliardo et al., 2008; Cappellini et al., 2006). Thus, herbal medicine may be evaluated as alternative therapeutic strategies against iron overload. Further we are trying to highlight on the hepatoprotective effects of GTE against iron overloaded-inducing apoptotic effects triggered over the production of ROS. The mechanistic roles under- lying the protective effect of AGTE against excess iron hepatotoxi- city need for more clarifications. Based upon evidences of previous work and our current results, several protective pathways could be drawn. It was recommended that food products of plant origin, especially tea contain high amounts of phenolic and polyphenolic constituents that were reported to reduce the susceptibility to cer- tain human diseases including cancer (He et al., 2001). In the pre- sent study, high levels of polyphenolic (29.8 mg) and flavonoid (16.9 mg) were found in 100 g of AGTE, whereas epigallocatechin-3-gallate (EGCG) constitutes up to 28%. The data obtained were different from previously reported studies which showed higher EGCG contents of the extract (Roomi et al., 2016). This may be related to brewing time, type of tea, commercial brand and producing country (Nash and Ward, 2016). In our study, hepatic cell injury and elevated circulating markers of hepatocyte injury such as serum ALT, AST, bilirubin, and reduction in albumin level caused by iron overload were all restored to normal ranges following treatment with green tea extracts. This may be related to the presence of flavonoids and polyphenols constituents in green tea, whereas its ability to stabi- lize and preserve the integrity of the hepatocyte membrane, stim- ulating hepatocyte regeneration, and hepatocellular protein synthesis, to repair damaged hepatic tissues were estimated previ- ously (Safer et al., 2015; Pezeshki et al., 2016). Also, in the same manner increased hepatic iron content, and both serum ferritin and hepcidin levels in iron treated rats were shown to be normal- ized into normal levels following green tea administration. This may be owing to the chelating activity of green tea against iron and minimizing its content in plasma and liver tissues (Saewong et al., 2010). The hepatoprotective effects of green tea extract were shown to be associated with its considerable antioxidant capacity and anti- free radical activities against excess iron inducing oxidative stress (Tomaszewska et al., 2015; Gramza et al., 2005).So, we further esti- mated the free radical scavenging activity of AGTE by both DPPH (89.2%) and b-carotene (82.3% and 94.2% at 500 and 1000 lg/mL respectively) tests. The data obtained proposed that the phenolic constituents of AGTE have the ability to suppress the chain reac-tions of lipid peroxidation via free radical scavenging mechanism. Our results are in line with other research work which reported that green tea extracts (AGTE) have considerable free radicals scav- enging activity (Panat et al., 2016).Consistent with the in vitro observations, AGTE was able to reverse in vivo lipid peroxidation induced by deposition of excess iron in liver tissue. Thus, this showed that green tea could provide essential antioxidant effects during chronic iron overload alongside to its role as an iron-chelating agent. The antioxidant property of green tea may be related to the presence of more phenolic and polyphenolic constituents especially epigallocatechin-3-gallate (EGCG) (He et al., 2001; Roomi et al., 2016; Nash and Ward, 2016). The increase in MDA as a potential marker for lipid peroxi- dation during iron overload was associated with elevation in hep- atic NO levels which could be an alternative pathway to minimize oxidative stress. This proposed pathway was supported by the fact that green tea activity induced significant decrease in MDA, deple- tion in the levels of hepatic NO along with significant improve in total antioxidant capacity (TAC) of iron overloaded rats. Most studies reported that systemic toxicities of hepatic cellsare associated with the release of many chemical mediators such as NO and proinflammatory cytokines which in turn induce liver cell damage. The presence of these mediators in higher concentra- tions plays an integral part in hepatic fibrogenesis (Ojiako et al., 2015; Poli, 2000; Shuto et al., 2004). The improvement in the levels of lipid peroxides, NO, TAC as well as damaged hepatic cells may be related to the promising antioxidant and antiradical scavenging activity of green tea constituents against harmful oxidative free radicals (Safer et al., 2015). Similarly, other research studies reported that some polyphenol-rich plant extracts have the capa- bility to ameliorate hepatic cell injury induced by LPS (Amat et al., 2010) or iron overload (Badria et al., 2015; Ounjaijean et al., 2008). Thus, green tea extracts have been shown to have a positive effect on hepatocytes via antiradical activity against oxida- tive stress free radicals initiated from excess iron toxicity.In the current study, green tea also showed significant anti-apoptotic activity against the progression of liver cell apoptosis in rats following treatment with excess iron. In green tea treated rats, there was a significant decrease in the levels of cytochrome c and increase in hepatic DNA content as apoptotic relating biomarkers. Pervious research studies showed that the imbalance between oxidative burden and defense mechanism induces severs damage in cell organelles especially, DNA damage and a progres- sion of cell death or apoptosis (Li et al., 2003). It was reported that normal apoptosis plays an important part in development processof multicellular organisms; however its abnormal induction could attributed with motivation of various diseases (Neeta, 2007). Previ- ous research studies showed that excess iron induce damage of the mitochondrial inner membrane and initiate opening of the mito- chondrial pores via oxidative stress mechanism. This leads to depletion in adenosine triphosphate and the release of cytochrome c, a proapoptotic protein of hepatic cell apoptosis (Ni et al., 2012; Uchiyama et al., 2008). Thus, excess iron either alone or by exerting oxidative stress synergizes in promoting hepatic cell necrosis or apoptosis (Ni et al., 2012). The improvement in the levels of cyto- chrome c and hepatic DNA content following treatment with green tea similarly matched with recently published data which showed that GTE offered partial hepatic protection through minimization of DNA fragmentation, apoptotic genes as caspases enzymes along- side with the healing view of hepatic parenchyma, and regenera- tion of hepatocytes or reduction in liver fibrosis (Ibrahim et al., 2015).The anti-apoptotic activity of green tea extract against excessiron may be related to gallate groups of catechins especially EGCG. These phenolic compounds have a radical scavenging ability via chelating divalent transition metal ions via their ortho-hydroxy- phenolic groups, preventing the generation of LPO (Somdet et al., 2012; Leopoldini et al., 2011; Lamberta and Eliasa, 2010). Also, green tea rich catechins minimize damage of DNA molecules by nullifying the effects of ROS through ultra-rapid electron transfer from catechins to ROS free radicals or activation of intracellular signaling cascades which acts as potent anti-apoptotic signaling (Lamberta and Eliasa, 2010; Anderson et al., 2001; Pan et al., 2007). Also, many research studies go in the same line and sup- ported that green tea catechins especially, EGCG compounds and its methylated metabolite protect liver cells against necrosis and apoptosis by suppressing the expression proapoptotic genes (caspase-3) via preventing the cytochrome c release from mito- chondria to cytosol (Kagaya et al., 2002; Al-Refai et al., 2014; Hisamura et al., 2006).More studies concluded that whole GTE was more stable andliable than pure ECGC due to the presence of other antioxidant con- stituents, (Kaszkin et al., 2004) that act synergistically and exert their full beneficial effect as total extracts (Loew and Kaszkin, 2002). This is why we select to work on the natural extracts of green tea rather than its ingredients.Finally, based on our data, the antioxidant, anti-apoptotic, and chelating properties of whole AGTE active constituents may con- tribute in its efficacy as anti-fibrotic when treating iron overload toxicity. 5.Conclusion Our study showed that green tea extract (GTE) ameliorates iron overload induced hepatotoxicity, apoptosis and oxidative stress in rat liver via inhibition of hepatic iron accumulation; improve of liver antioxidant capacity, CN128 and down regulation of serum hepcidin as well as reduction in the release of apoptotic relating proteins.