Theoretical Study on GSH Activation Mechanism of a New Type of Glutathione Transferase Gtt2

Glutathione transferases(GSTs) play an important role in the detoxification of xenobiotic/endobiotic toxic compounds. The α-, π-, and μ-classes of cytosolic GSTs have been studied extensively, while Gtt2 from Saccharomyces cerevisiae, a novel atypical GST, is still poorly understood. In the present study, we investigated the glutathione( GSH) activation mechanism of Gtt2 using the density functional theory(DFT) with the hybrid functional B3LYP. The computational results show that a water molecule could assist a proton transfer between the GSH thiol and the N atom of His133. The energy barrier of proton transfer is 46.0 kJ/mol. The GSH activation mechanism and the characteristics of active site are different from those of classic cytosolic GSTs.     

Mammalian cytosolic glutathione transferases

Glutathione Transferases (GSTs) are crucial enzymes in the cell detoxification process catalyzing the nucleophilic attack of glutathione (GSH) on toxic electrophilic substrates and producing a less dangerous compound. GSTs studies are of great importance since they have been implicated in the development of drug resistance in tumoral cells and are related to human diseases such as Parkinson's, Alzheimer's, atherosclerois, liver cirrhosis, aging and cataract formation. In this review we start by providing an evolutionary perspective of the mammalian cytosolic GSTs known to date. Later on we focus on the more abundant classes alpha, mu and pi and their structure, catalysis, metabolic associated functions, drug resistance relation and inhibition methods. Finally, we introduce the recent insights on the GST class zeta from a metabolic perspective.     

Substrate Profiling of Glutathione S‐transferase with Engineered Enzymes and Matched Glutathione Analogues

The identification of specific substrates of glutathione S‐transferases (GSTs) is important for understanding drug metabolism. A method termed bioorthogonal identification of GST substrates (BIGS) was developed, in which a reduced glutathione (GSH) analogue was developed for recognition by a rationally engineered GST to label the substrates of the corresponding native GST. A K44G‐W40A‐R41A mutant (GST‐KWR) of the mu‐class glutathione S‐transferases GSTM1 was shown to be active with a clickable GSH analogue (GSH‐R1) as the cosubstrate. The GSH‐R1 conjugation products can react with an azido‐based biotin probe for ready enrichment and MS identification. Proof‐of‐principle studies were carried to detect the products of GSH‐R1 conjugation to 1‐chloro‐2,4‐dinitrobenzene (CDNB) and dopamine quinone. The BIGS technology was then used to identify GSTM1 substrates in the Chinese herbal medicine Ganmaocongji.     

Characterization of glutathione conjugates of chloroacetanilide pesticides using ultra-performance liquid chromatography/quadrupole time-of-flight mass spectrometry and liquid chromatography/ion trap mass spectrometry

Glutathione S-transferases (GSTs) isolated from maize were used to catalyze the conjugation of glutathione (GSH) with chloroacetanilide herbicides, producing stable conjugates that were structurally characterized using ultra-performance liquid chromatography/quadrupole time-of-flight mass spectrometry (UPLC/QqToF-MS) and liquid chromatography/ion trap mass spectrometry (LC/IT-MS). Enzyme-mediated dechlorination of alachlor, metolachlor, and propachlor resulted during GSH conjugation as revealed by the mass spectra of the conjugates, which was confirmed by the loss of the chlorine isotopic signature and from high accurate mass measurements. Several fragmentation patterns in the mass spectra of the chloroacetanilide-GSH conjugates can be used to verify the identities of the enzyme reaction products, such as characteristic ions corresponding to the neutral loss of glutamic acid residue (129 Da) and water (18 Da) observed in the product ion spectrum. For the first time, data are presented showing detection of chloroacetanilides that are conjugated with two GSH molecules, in addition to the known single GSH conjugates.     

Determination of enzyme kinetics and glutathione conjugates of chlortetracycline and chloroacetanilides using liquid chromatography-mass spectrometry

Glutathione S-transferases (GSTs) isolated from chlortetracycline (CTC)-treated maize catalyzed the conjugation of glutathione (GSH) with CTC, producing stable conjugates that were structurally characterized using liquid chromatography-ion-trap mass spectrometry (LC-IT-MS). Enzyme-mediated dechlorination of CTC resulted during GSH conjugation as revealed by the mass spectra of the CTC-GSH conjugate, which was characterized by the loss of the chlorine isotopic signature, and shorter chromatographic retention time relative to the chlorinated parent compound. Several fragmentation patterns in the mass spectrum of the CTC-GSH conjugate can be used to verify the identity of the enzyme reaction products. The expected molecular ion [M + H](+) of the CTC-GSH conjugate (m/z 751) with chlorine removal was not observed in the positive electrospray ionization. Instead, a base peak of m/z 677, corresponding to the loss of glycine (MW = 75 Da), was observed. When m/z 677 was subjected to further fragmentation, characteristic peaks corresponding to the loss of glutamic acid (m/z = 129) and water (m/z 18) were observed in the MS/MS spectrum. The catalytic activity of the CTC-induced GST towards dechlorination of chloroacetanilide herbicides (alachlor, metolachlor and propachlor), which are known to be detoxified in plants via the glutathione pathway, was also evaluated in vitro. Glutathione conjugates of chloroacetanilides also showed the losses of m/z 129 and m/z 18 that are characteristic of GSH conjugates when characterized by LC-IT-MS. Interestingly, the sensitivity of LC-IT-MS made it possible, for the first time, to detect chloroacetanilides that are conjugated with two GSH molecules, in addition to the known single GSH conjugates. This research demonstrates a more sensitive and specific method of measuring enzyme reaction products using LC-IT-MS.     

AdipoRon,an Orally Active,Synthetic Agonist of AdipoR1 and AdipoR2 Receptors Has Gastroprotective Effect in Experimentally Induced Gastric Ulcers in Mice

Introduction: Adiponectin is a hormone secreted by adipocytes, which exhibits insulin-sensitizing and anti-inflammatory properties and acts through adiponectin receptors: AdipoR1 and AdipoR2. The aim of the study was to evaluate whether activation of adiponectin receptors AdipoR1 and AdipoR2 with an orally active agonist AdipoRon has gastroprotective effect and to investigate the possible underlying mechanism. Methods: We used two well-established mouse models of gastric ulcer (GU) induced by oral administration of EtOH (80% solution in water) or diclofenac (30 mg/kg, p.o.). Gastroprotective effect of AdipoRon (dose 5 and 50 mg/kg p.o.) was compared to omeprazole (20 mg/kg p.o.) or 5% DMSO solution (control). Clinical parameters of gastroprotection were assessed using macroscopic (gastric lesion area) and microscopic (evaluation of the gastric mucosa damage) scoring. To establish the molecular mechanism, we measured: myeloperoxidase (MPO), superoxide dismutase (SOD), catalase (CAT), and glutathione peroxidase (GPX) activities; glutathione (GSH) level; and IL-1β, adenosine monophosphate-activated protein kinase (AMPK), and phosphorylated AMPK expression in gastric tissue. Results: AdipoRon produced a gastroprotective effect in both GU mouse models as evidenced by significantly lower macroscopic and microscopic damage scores. AdipoRon exhibited anti-inflammatory effect by reduction in MPO activity and IL-1β expression in the gastric tissue. Moreover, AdipoRon induced antioxidative action, as demonstrated with higher GSH levels, and increased SOD and GPX activity. Conclusions: Activation of AdipoR1 and AdipoR2 using AdipoRon reduced gastric lesions and enhanced cell response to oxidative stress. Our data suggest that AdipoR1 and AdipoR2 activation may be an attractive therapeutic strategy to inhibit development of gastric ulcers.     

Glutathione transferase: new model for glutathione activation

Glutathione transferases are enzymes of the cellular detoxification system that metabolize a vast spectrum of xenobiotic and endobiotic toxic compounds. They are homodimers or heterodimers and each monomer has an active center composed of a G-site in which glutathione (GSH) binds and an H-site for the electrophilic substrate. When GSH binds to the G-site, the pKa value of its thiol group drops by 2.5 units; this promotes its deprotonation and, therefore, produces a strong nucleophilic thiolate that is able to react with the electrophilic substrate. The mechanism behind the deprotonation of the thiol group is still unknown. Some studies point to the fact that the GSH glutamyl alpha-carboxylate group is essential for GSH activation, whereas others indicate the importance of the active-center water molecules. On the basis of QM/MM calculations, we propose a mechanism of GSH activation in which a water molecule, acting as a bridge, is able to assist in the transfer of the proton from the GSH thiol group to the GSH glutamyl alpha-carboxylate group, after an initial GSH conformational rearrangement. We calculated the potential of mean force of this GSH structural rearrangement that would be necessary for the approach of both groups and we then performed a QM/MM ONIOM scan of water-assisted proton transfer. The overall free-energy barrier for the process is consistent with experimental studies of the enzyme kinetics.     

Assembly of ligands interaction models for glutathione-S-transferases from Plasmodium falciparum,human and mouse using enzyme kinetics and molecular docking

BackgroundGlutathione-s-transferases (GSTs) are enzymes that principally catalyze the conjugation of electrophilic compounds to the endogenous nucleophilic glutathione substrate, besides, they have other non-catalytic functions. The Plasmodium falciparum genome encodes a single isoform of GST (PfGST) which is involved in buffering the toxic heme, thus considered a potential anti-malarial target. In mammals several classes of GSTs are available, each of various isoforms. The human (human GST Pi-1 or hGSTP1) and mouse (murine GST Mu-1 or mGSTM1) GST isoforms control cellular apoptosis by interaction with signaling proteins, thus considered as potential anti-cancer targets. In the course of GSTs inhibitors development, the models of ligands interactions with GSTs are used to guide rational molecular modification. In the absence of X-ray crystallographic data, enzyme kinetics and molecular docking experiments can aid in addressing ligands binding modes to the enzymes.MethodsKinetic studies were used to investigate the interactions between the three GSTs and each of glutathione, 1-chloro-2,4-dinitrobenzene, cibacron blue, ethacrynic acid, S-hexyl glutathione, hemin and protoporphyrin IX. Since hemin displacement is intended for PfGST inhibitors, the interactions between hemin and other ligands at PfGST binding sites were studied kinetically. Computationally determined binding modes and energies were interlinked with the kinetic results to resolve enzymes-ligands interaction models at atomic level.ResultsThe results showed that hemin and cibacron blue have different binding modes in the three GSTs. Hemin has two binding sites (A and B) with two binding modes at site-A depending on presence of GSH. None of the ligands were able to compete hemin binding to PfGST except ethacrynic acid. Besides bind differently in GSTs, the isolated anthraquinone moiety of cibacron blue is not maintaining sufficient interactions with GSTs to be used as a lead. Similarly, the ethacrynic acid uses water bridges to mediate interactions with GSTs and at least the conjugated form of EA is the true hemin inhibitor, thus EA may not be a suitable lead.ConclusionsGlutathione analogues with bulky substitution at thiol of cysteine moiety or at γ-amino group of γ-glutamine moiety may be the most suitable to provide GST inhibitors with hemin competition.     

电位法测定谷胱甘肽转移酶活性的研究

谷胱甘肽转移酶(GSTs)是生物体内一种重要的解毒酶,催化异源物与谷胱甘肽结合,有多种方法测定其活性,但都基于大分子产物。本实验基于H.Habig方法,探讨用氯离子选择电极,根据反应体系中Cl-浓度的变化来测定谷胱甘肽转移酶的活性。研究结果表明,利用透析膜包裹电极可以消除底物谷胱甘肽(GSH)对电极的干扰,生物反应体系中可能存在的离子、小分子(如Br-I、-、H2O2和Vc)对电极没有影响。此方法重现性良好,相对标准偏差为3.54%。     

Cloning and Characterization of a Biotic-Stress-Inducible Glutathione Transferase from Phaseolus vulgaris

Glutathione transferases (GSTs, EC 2.5.1.18) are ubiquitous proteins in plants that play important roles in stress tolerance and in the detoxification of toxic chemicals and metabolites. In this study, we systematically examined the catalytic diversification of a GST isoenzyme from Phaseolus vulgaris (PvGST) which is induced under biotic stress treatment (Uromyces appendiculatus infection). The full-length cDNA of this GST isoenzyme (termed PvGSTU3-3) with complete open reading frame, was isolated using RACE-RT and showed that the deduced amino acid sequence shares high homology with the tau class plant GSTs. PvGSTU3-3 catalyzes several different reactions and exhibits wide substrate specificity. Of particular importance is the finding that the enzyme shows high antioxidant catalytic function and acts as hydroperoxidase, thioltransferase, and dehydroascorbate reductase. In addition, its K _m for GSH is about five to ten times lower compared to other plant GSTs, suggesting that PvGSTU3-3 is able to perform efficient catalysis under conditions where the concentration of reduced glutathione is low (e.g., oxidative stress). Its ability to conjugate GSH with isothiocyanates may provide an additional role for this enzyme to act as a regulator of the released isothiocyanates from glucosinolates as a response of biotic stress. Molecular modeling showed that PvGSTU3-3 shares the same overall fold and structural organization with other plant cytosolic GSTs, with major differences at their hydrophobic binding sites (H-sites) and some differences at the level of C-terminal domain and the linker between the C- and N-terminal domains. PvGSTU3-3, in general, exhibits restricted ability to bind xenobiotics in a nonsubstrate manner, suggesting that the biological role of PvGSTU3-3, is restricted mainly to the catalytic function. Our findings highlight the functional and catalytic diversity of plant GSTs and demonstrate their pivotal role for addressing biotic stresses in Phaseolus vulgaris.     

人类谷胱甘肽S-转移酶M1a-1a催化的亲核芳香取代反应的理论研究

利用分子力学和量子力学方法研究人类谷胱甘肽S-转移酶M1a-1a催化谷胱甘肽对1-氯-2,4二硝基苯(CDNB)的亲核芳香取代反应的细节.所获得的反应路径显示反应仅经历一个过渡态且能垒很低.电荷布居分析证明电子从谷胱甘肽基团流向二硝基苯,验证了反应的发生.计算结果表明活性位点3个残基(Tyr6,His107和Tyr115)参与了催化反应,尤其是His107,它在反应后期通过与产物形成氢键从而加速了Cl的释放.结果支持了Patskovsky等人提出的机理,并有助于其他谷胱甘肽S-转移酶的研究.     

Protective Properties of Novel S‐Acyl‐Glutathione Thioesters Against Ultraviolet‐induced Oxidative Stress

UV‐induced toxicity is characterized by marked oxidative stress, accompanied by the depletion of key cellular antioxidants, particularly glutathione (GSH). Replenishing cellular GSH may represent a means of counteracting UV‐induced toxicity: however, treatment with free GSH is not therapeutically effective due to its unfavorable pharmacokinetic properties. In this study, we show that S‐acyl‐glutathione (acyl‐SG) derivatives, which consist of an acyl chain (of variable length and saturation) linked via a thioester bond to GSH, increase intracellular levels of reduced GSH in primary skin fibroblasts, adenocarcinoma HeLa and neuroblastoma SH‐SY5Y cells. Consistent with this, acyl‐SG derivatives protect against UV‐induced reactive oxygen species (ROS) production and UV‐B/C‐mediated lipid peroxidation and caspase‐3 activation in the analyzed cell lines, with unsaturated thioesters displaying a significantly greater protective effect. Taken together, our findings suggest that acyl‐SG thioesters may be therapeutically effective in the treatment of UV‐related skin disorders and oxidative stress‐mediated conditions in general.     

Quantum mechanical/molecular mechanical free energy simulations of the glutathione S-transferase (M1-1) reaction with phenanthrene 9,10-oxide

Glutathione S-transferases (GSTs) play an important role in the detoxification of xenobiotics in mammals. They catalyze the conjugation of glutathione to a wide range of electrophilic compounds. Phenanthrene 9,10-oxide is a model substrate for GSTs, representing an important group of epoxide substrates. In the present study, combined quantum mechanical/molecular mechanical (QM/MM) simulations of the conjugation of glutathione to phenanthrene 9,10-oxide, catalyzed by the M1-1 isoenzyme from rat, have been carried out to obtain insight into details of the reaction mechanism and the role of solvent present in the highly solvent accessible active site. Reaction-specific AM1 parameters for sulfur have been developed to obtain an accurate modeling of the reaction, and QM/MM solvent interactions in the model have been calibrated. Free energy profiles for the formation of two diastereomeric products were obtained from molecular dynamics simulations of the enzyme, using umbrella sampling and weighted histogram analysis techniques. The barriers (20 kcal/mol) are in good agreement with the overall experimental rate constant and with the formation of equal amounts of the two diastereomeric products, as experimentally observed. Along the reaction pathway, desolvation of the thiolate sulfur of glutathione is observed, in agreement with solvent isotope experiments, as well as increased solvation of the epoxide oxygen of phenanthrene 9,10-oxide, illustrating an important stabilizing role for active site solvent molecules. Important active site interactions have been identified and analyzed. The catalytic effect of Tyr115 through a direct hydrogen bond with the epoxide oxygen of the substrate, which was proposed on the basis of the crystal structure of the (9S,10S) product complex, is supported by the simulations. The indirect interaction through a mediating water molecule, observed in the crystal structure of the (9R,10R) product complex, cannot be confirmed to play a role in the conjugation step. A selection of mutations is modeled. The Asn8Asp mutation, representing one of the differences between the M1-1 and M2-2 isoenzymes, is identified as a possible factor contributing to the difference in the ratio of product formation by these two isoenzymes. The QM/MM reaction pathway simulations provide new and detailed insight into the reaction mechanism of this important class of detoxifying enzymes and illustrate the potential of QM/MM modeling to complement experimental data on enzyme reaction mechanisms.     

Three‐Dimensional Protein Networks Assembled by Two‐Photon Activation

Spatial and temporal control over chemical and biological processes plays a key role in life and material sciences. Here we synthesized a two‐photon‐activatable glutathione (GSH) to trigger the interaction with glutathione S‐transferase (GST) by light at superior spatiotemporal resolution. The compound shows fast and well‐confined photoconversion into the bioactive GSH, which is free to interact with GST‐tagged proteins. The GSH/GST interaction can be phototriggered, changing its affinity over several orders of magnitude into the nanomolar range. Multiplexed three‐dimensional (3D) protein networks are simultaneously generated in situ through two‐photon fs‐pulsed laser‐scanning excitation. The two‐photon activation facilitates the three‐dimensional assembly of protein structures in real time at hitherto unseen resolution in time and space, thus opening up new applications far beyond the presented examples.     

氧化型谷胱甘肽对还原型谷胱甘肽清除自由基的协同作用

利用分光光度法和基质辅助飞行质谱法研究了谷胱甘肽对1,1-二苯基-2-苦肼基(DPPH)自由基的清除作用.通过比较不同浓度和不同配比的还原型谷胱甘肽(GSH)和氧化型谷胱甘肽(GSSG)以及Na2SeO3混合溶液的自由基清除率,发现GSH/GSSG的配比对自由基清除率有明显影响.当GSH/GSSG的配比大于50∶ 1时,自由基清除率比同浓度的GSH大,且自由基清除率随GSH和GSSG的绝对浓度的增加而明显增加,说明适量的GSSG可协同催化GSH清除自由基过程.质谱测定结果表明: 此协同作用与GSSG 参与自由基清除过程中的自由基反应有关.Na2SeO3对GSH的清除自由基的影响主要是通过与GSH反应生成GSSG来调控GSH/GSSG配比的结果.通过测定和分析一定配比的GSH+GSSG混合溶液与DPPH作用前后的质谱图,提出了少量的GSSG共存下,GSH催化清除DPPH自由基的作用机理.     

Noncovalent associations of glutathione S-transferase and ligands: A study using electrospray quadrupole/time-of-flight mass spectrometry

Human glutathione S-transferase A1-1 was observed predominantly as dimeric ions (51 kDa) during electrospray mass spectrometric analysis from aqueous solution at pH 7.4, in keeping with the known dimeric structure in solution. When analyses were performed on solutions of the enzyme containing glutathione (GSH), noncovalent adducts of protein dimer and one or two ligand molecules were observed; each mass increment, which exceeded the mass of GSH alone, was provisionally interpreted to indicate concomitant association of two water molecules per bound GSH. Noncovalent adducts of ligand and protein dimer were similarly observed for oxidized glutathione and for two glutathione inhibitors, both incorporating substituted thiol structures. In these instances, the mass increments exactly matched the ligand masses, suggesting that the apparent concomitant binding of water was associated with the presence in the ligand of a free thiol group. Collisionally activated decomposition during tandem mass spectrometry analyses of noncovalent adducts incorporating protein dimer and ligands yielded initially the denuded dimer; at higher collision energies the monomer and a protein fragment were formed.     

Molecular interaction between andrographolide and glutathione follows second order kinetics

The intracellular level of glutathione (GSH) was significantly decreased after the addition of andrographolide (1) to cell cultures of HepG2. When the molecular interaction between andrographolide and GSH was investigated under a condition mimicking the in vivo environment, we observed that the level of GSH dropped in the presence of andrographolide. Stoichiometric analysis indicates that the reaction between these two reactants was 1 to 1 at pH 7 and followed second order kinetics. The activation energy of the overall reaction was 41.9+/-10 kJ x mol(-1) according to the Arrhenius equation. Using a micro-liquid-liquid extraction method followed by micellar electrokinetic chromatographic separation, two major products were isolated and identified, and their chemical structures were determined as 14-deoxy-12-(glutathione-amino)-andrographolide (2) and 14-deoxy-12-(glutathione-S-yl)-andrographolide (3). Based on these structural findings, a hypothetical mechanism of reaction between glutathione and andrographolide was proposed. It is concluded that the alpha,beta-unsaturated lactone moiety of andrographolide reacts with GSH through a Michael addition followed by dehydration of the adduct.     

A Glutathione Activatable Ion Channel Induces Apoptosis in Cancer Cells by Depleting Intracellular Glutathione Levels

Cancer cells use elevated glutathione (GSH) levels as an inner line of defense to evade apoptosis and develop drug resistance. In this study, we describe a novel 2,4‐nitrobenzenesulfonyl (DNS) protected 2‐hydroxyisophthalamide system that exploits GSH for its activation into free 2‐hydroxyisophthalamide forming supramolecular M⁺/Cl^? channels. Better permeation of the DNS protected compound into MCF‐7 cells compared to the free 2‐hydroxyisophthalamide and GSH‐activatable ion transport resulted in higher cytotoxicity, which was associated with increased oxidative stress that further reduced the intracellular GSH levels and altered mitochondrial membrane permeability leading to the induction of the intrinsic apoptosis pathway. The GSH‐activatable transport‐mediated cell death was further validated in rat insulinoma cells (INS‐1E); wherein the intracellular GSH levels showed a direct correlation to the resulting cytotoxicity. Lastly, the active compound was found to restrict the growth and proliferation of 3D spheroids of MCF‐7 cells with efficiency similar to that of the anticancer drug doxorubicin.     

1H NMR Study on the Inclusion Complex of Glutathione with a Glutathione Peroxidase Mimic, 2,2′-ditelluro-bridged β-cyclodextrins

The complex formation of 2, 2′-ditelluro-bis(β-cyclodextrin) (2-TeCD) with glutathione (GSH) was investigated in D₂O at room temperature by ¹H nuclear magnetic resonance(¹H NMR) technique. The association constant and stoichiometry between GSH and 2-TeCD was determined from the chemical shifts dependence of the H5 proton in GSH on the concentration of 2-TeCD. The stoichiometry of the inclusion complex was determined by the molar method to be of 2:1 host-to-guest. 2-TeCD showed higher affinity toward GSH than β-cyclodextrin (β-CD). This may be attributed the reason that 2-TeCD which possesses dual hydrophobic cavities in a close vicinity enhances GSH binding ability through the cooperative binding of two cavities. The formation of the (2-TeCD)₂/GSH complex was one of the reason that 2-TeCD showed higher glutathione peroxidase (GPX) activity than Ebselen.     

Involvement of ROS and JNK1 in selenite-induced apoptosis in Chang liver cells

Selenium is a dietary essential trace nutrient with important biological roles. Selenocompounds were reported to induce apoptosis in many types of tumor cells. In this study, we investigated the signaling pathway involved in the selenite-induced apoptosis using Chang liver cells as a non-malignant cell model. The Chang liver cell apoptosis induced by selenite (10 microM) was confirmed by DNA fragmentation and typical apoptotic nuclear changes. Treatment of selenite increased intracellular reactive oxygen species (ROS) level and c-Jun N-terminal kinase1 (JNK1) phosphorylation. The selenite-induced cell death was attenuated by SP600125, a specific inhibitor of JNK, and by dominant negative JNK1 (DN-JNK1). Antioxidants such as glutathione (GSH), N-acetyl cysteine (NAC), curcumin, epigallocatechin gallate (EGCG) and epicatechin (EC) inhibited selenite-induced intracellular ROS elevation and JNK1 phosphorylation. Our results suggest that selenite-induced apoptosis in Chang liver cells was preceded by the ROS generation and JNK1 activation.