The Alexipharmic Mechanisms of Five Licorice Ingredients Involved in CYP450 and Nrf2 Pathways in Paraquat-Induced Mice Acute Lung Injury

Liu, Zi-Jing; Zhong, Jing; Zhang, Mei; Chen, Ze-Hui; Wang, Ji-Ye; Chen, Han-Ying; Wang, Xiao-Qin; Zhang, Bo

doi:https://doi.org/10.1155/2019/7283104

Oxidative Medicine and Cellular Longevity

On this page

Abstract Introduction Methods and Materials Results Discussion Conclusion Abbreviations Data Availability Conflicts of Interest Authors’ Contributions Acknowledgments Supplementary Materials References Copyright Related Articles

Research Article | Open Access

Volume 2019 | Article ID 7283104 | https://doi.org/10.1155/2019/7283104

The Alexipharmic Mechanisms of Five Licorice Ingredients Involved in CYP450 and Nrf2 Pathways in Paraquat-Induced Mice Acute Lung Injury

Zi-Jing Liu,^1,2Jing Zhong,¹Mei Zhang,¹Ze-Hui Chen,¹Ji-Ye Wang,¹Han-Ying Chen,^1,2Xiao-Qin Wang,^1,2and Bo Zhang^1,2

Academic Editor: Pablo Muriel

Received21 May 2018

Revised30 Sept 2018

Accepted03 Dec 2018

Published28 Apr 2019

Abstract

Oxidative stress is an important mechanism in acute lung injury (ALI) induced by paraquat (PQ), one of the most widely used herbicides in developing countries. In clinical prophylaxis and treatment, licorice is a widely used herbal medicine in China due to its strong alexipharmic characteristics. However, the corresponding biochemical mechanism of antioxidation and detoxification enzymes induced by licorice’s ingredients is still not fully demonstrated. In this study, the detoxification effect of licorice was evaluated in vivo and in vitro. The detoxification and antioxidation effect of its active ingredients involved in the treatment was screened systematically according to Absorption, Distribution, Metabolism, and Excretion (ADME): predictions and evidence-based literature mining methods in silico approach. Data shows that licorice alleviate pulmonary edema and fibrosis, decrease Malondialdehyde (MDA) contents and increase Superoxide Dismutase (SOD) activity in PQ-induced ALI mice, protect the morphologic appearance of lung tissues, induce cytochrome 3A4 (CYA3A4) and Nuclear factor erythroid 2-related factor 2 (Nrf2) expression to active detoxification pathways, reduce the accumulation of PQ in vivo, protect or improve the liver and renal function of mice, and increase the survival rate. The 104 genes of PPI network contained all targets of licorice ingredients and PQ, which displayed the two redox regulatory enzymatic group modules cytochrome P450 (CYP450) and Nrf2 via a score-related graphic theoretic clustering algorithm in silico. According to ADME properties, glycyrol, isolicoflavonol, licochalcone A, 18beta-glycyrrhetinic acid, and licoisoflavone A were employed due to their oral bioavailability , drug-likeness , and being highly associated with CYP450 and Nrf2 pathways, as potential activators to halt PQ-induced cells death in vitro. Both 3A4 inhibitor and silenced Nrf2 gene decreased the alexipharmic effects of those ingredients significantly. All these disclosed the detoxification and antioxidation effects of licorice on acute lung injury induced by PQ, and glycyrol, isolicoflavonol, licochalcone A, 18beta-glycyrrhetinic acid, and licoisoflavone A upregulated CYP450 and Nrf2 pathways underlying the alexipharmic mechanisms of licorice.

1. Introduction

Paraquat (N,N-dimethyl-4,4-bipyridinium dichloride; PQ) is one of the most widely used herbicides in developing countries. However, it is also a highly toxic compound caused by pulmonary impairment, leading to irreversible pulmonary fibrosis and characteristically occurred between several days and 3 weeks after administration or ingestion, which accounts for 300,000 deaths occurring in the Asia-Pacific region alone each year [1]. The diagnosis of PQ poisoning mainly is according to the PQ concentration in the blood, lung X-ray, and dithionite urine test [2]. With the development of science, a GC-MS-based metabolomic approach was applied to assess the metabolite changes in human plasma following PQ poisoning [3]. According to the literature, SVM discrimination model performed with high classification accuracy can be applied to distinguish the PQ poisoned patients from a healthy person [3]. Also a potential use of ELM methods for PQ poisoning detection in biomedical applications, which possess high classification accuracy, AUC, sensitivity, and specificity, can be applied in clinical practice to distinguish the PQ-poisoned patients from healthy persons [4]. But many of them require a long time, money, or staff. At present, a simple but reliable highly sensitive fluorescence-enhancing method has been developed for the detection of PQ concentration by using host-guest chemistry with cucurbit[8]uril [2]. Management strategies for PQ poisoning include extracorporeal elimination, immunosuppressants, antioxidants, and hemoperfusion (HP) within 2-4 h after intoxication [6–8]. However, there is no sufficient evidence indicating good clinical outcomes, and mortality rates remain very high despite current treatment methods [5, 9]. Thus, it is important to find an antidote and identify a better therapeutic mechanism of PQ poisoning.

Considering the strong detoxification of the liver, the induction of drug-metabolizing enzymes and efflux transporters promotes the detoxification and excretion of toxic substances, which is considered to be one of the important pathways in drug detoxification [10]. Typical phase I metabolic enzymes are cytochrome P450 (phase I metabolic enzymes), ALDH, and so on. In P450, the actual effects of the accumulation of toxic metabolic products of drugs and the detoxification process depend on the balance between phase I and phase II enzymes. In the literature, acute paraquat poisoning may induce the activities of CYP2C19 and inhibit the activities of CYP2B6, CYP2C9, CYP2D6, and CYP3A4 in rats [11]. This may provide a reasonable suggestion for the development of new drugs for acute paraquat poisoning.

Oxidative stress is also thought to participate in the mechanism of PQ-induced ALI [5]. PQ can enter cells and participate in a series of redox reactions. In this process, PQ consumes nicotinamide adenine dinucleotide phosphate and cytochrome P450 reductase, causing oxidative stress reaction. MDA level can indirectly reflect the degree of peroxidation, and elevated MDA level also causes cell metabolism disorders. SOD is the main endogenous antioxidant which can effectively remove O₂^⋅- and reduce oxidation reactions, causing the subsequent acute inflammatory response. When these antioxidants are imbalanced, there will be airway inflammation, airway hyperresponsiveness and tissue damage, neutrophil infiltration, and ultimately the formation of lung injury [12]. It has been found that Nrf2, an important transcription factor of oxidative stress, is known to be essential for the antioxidant responsive element-mediated induction of oxidative stress enzyme genes and plays an important role in the development of PQ-induced ALI. Many studies showed their results by inhibiting oxidative stress to slow down the process of ALI [13].

Detoxification is an important mechanism involved in polypharmacology [14]. And it may be beneficial for detoxification by reducing oxidative stress, minimizing toxicity by regulating the expression CYP450 mRNAs [15]. Licorice is one of the most widely used herbal medicines in China due to its strong alexipharmic characteristics. It appeared in “Shang Han Za Bing Lun” and reduces toxicity of other drugs in prescriptions. There are many active components in licorice, but the mechanism of detoxification is unknown. At present, many components have been proved to exhibit detoxification activity; triterpenoids and flavonoids in the licorice are responsible for combining with toxic substances as their alexipharmic mechanism [16]. Glycyrrhizin obviously induces CYP3A activity in vivo [17]. 18β-Glycyrrhizinate is responsible for the concentration-dependent induction of CYP3A [18]. However, in vivo data disclosed medicagenin (II) and munchiwarin (III) showing low oral bioavailability; other active molecules should be searched to take the alexipharmic role in licorice [19].

Nrf2 is a basic leucine zipper transcription factor and plays a key role in cellular defenses against electrophile induced-oxidative stress [20]. According to the literature, the active ingredients in licorice, such as isoliquiritigenin, stimulate detoxification system via Nrf2 activation, which could be a potential protective mechanism of licorice [21]. A number of compounds such as licochalcone A [22], licochalcone B, glycyrrhetinic acid, glycyrrhizin, and isoliquiritigenin significantly activate Nrf2 [23], induce Nrf2 expression [21], and were potent Nrf2 activators. Furthermore, drug-metabolizing enzymes are essential for most of the biotransformation steps involving xenobiotics and endogenous molecules [24]. Recent studies have found that Nrf2 regulates the expressions of a variety of drug-metabolizing enzymes (phase II metabolic enzymes) and transporters in vivo and also the primary factor inducing the cell survival system under Glutathione (GSH) depletion [21, 25]. At present, hundreds of active ingredients in licorice have been isolated and identified. Many of those molecules have relatively fast metabolism and low bioavailability in the liver, although their content is high, the final duration is short. According to ADME, there are still many compounds including 18beta-glycyrrhetinic acid, glycyrol, licoisoflavone A, and isolicoflavonol with high oral bioavailability values in licorice. But there is hardly any research on the potential detoxification value of these molecules. Molecules with good ADME properties are the important standard for drugs. It is urgent to find the active ingredients with relative higher OB and higher activities targeting both CYP450 and Nrf2/ARE metabolic pathways in the treatment of PQ poisoning [24].

Systems biology, such as network pharmacology, promotes an understanding of the function and behavior of a biological system [26], so did the evidence-based analytic platforms and network science algorithm models [27, 28]. Those technological platforms provide holistic approaches to study the essence of herb medicine and the functions of natural products in silico [26]. The liver is where drugs are metabolized; it is the main active place of drug-metabolizing enzymes, and HepG2-derived hepatocellular carcinoma is a hepatoblastoma suitable for the study of hepatocyte metabolism and detoxification. A549 cells are widely used in the model of type II pulmonary epithelial cells in vitro and as transfection hosts. The main target organ of PQ poisoning is the lung, and A549 cells are adenocarcinoma and human alveolar basal epithelial cells. And type II alveolar epithelial cells are specific targets of paraquat toxicity [29]. So, A549 cells and HepG2 cells were chosen to explore the detoxification properties of licorice in vitro. In the present study, we aim to evaluate the detoxification and antioxidation effects of licorice in vivo and characterize the active ingredients and their pharmacological actions in silico and in vitro underlying the mechanism of licorice detoxification.

2. Methods and Materials

2.1. Materials

Licorice extract (Cat#L9030) is a water-soluble powder, extracted from the dried roots and stems of G. uralensis Fisch., G. inflate Bat., and G. glabra L. (Glycyrrhiza Linn., Leguminosae) by water; glycyrol (GLL, purity ≥ 99%, PubChem CID: 5320083), isolicoflavonol (ILF, purity ≥ 98%, PubChem CID: 5318585), licochalcone A (LCA, purity ≥ 99%, PubChem CID: 5318998), licoisoflavone A (LIA, purity ≥ 98%, PubChem CID: 5281789), 18beta-glycyrrhetinic acid (18β-GA, purity ≥ 99%, PubChem CID: 10114), and MTT [3-(4.5-dimethylthiazol-2-yl)-2.5-diphenyl tetrazolium bromide] and Modified Masson’s Trichrome Stain Kit were purchased from Solarbio Co. Ltd. (Beijing, China). The cDNA amplification kit, primers, and RNA extraction kit were purchased from Shanghai Sangon Co. Ltd. (Shanghai, China). Dulbecco’s Modified Eagle’s Medium Nutrient Mixture F-12 (DMEM/F12) and Minimum Essential Medium (MEM) were purchased from Gibco BRL (Grand Island, NY, USA). All of the primary antibodies CYP3A4, Nrf2, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), anti-mouse, and anti-rabbit secondary antibodies were purchased from Cell Signaling Technology Inc. (Danvers, MA, USA). Ketoconazole (KZ, purity ≥ 98%, PubChem CID: 3823) was purchased from Shanghai Yuanye Biological Industries Co. Ltd. (Shanghai, China). The human type II alveolar adenocarcinomic basal epithelial cells (A549) and Human hepatocellular liver carcinoma cell (HepG2) were purchased from the Cancer Cell Repository (Shanghai Cell Bank, Shanghai, China). Nrf2 knockdown A549 cells were transfected with Nrf2shRNA [30]. Paraquat (PQ, Sigma-Aldrich Company) (PubChem CID: 15938) and methylene blue (MB) were purchased from Sigma-Aldrich. The MDA kit, SOD kit, AST/GOT kit, ALT/GPT kit, CRE kit, and BUN kit were purchased from Nanjing Jiancheng Bioengineering Institute (Jiangsu, China). Dexamethasone Sodium Phosphate Injection was purchased from Tianjin King York Group Co. Ltd. Cucurbit[8]uril was obtained by Prof. Shiguo Sun.

2.2. Collection and Library Construction of Active Ingredients of Licorice

The list of licorice chemicals used in the treatment of respiratory diseases was collected from the literature, the Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform (TCMSP, accessed on May 1, 2015, http://lsp.nwu.edu.cn/tcmsp.php), and the Chinese Academy of Sciences’ Chemistry Database (accessed on May 1, 2015, http://www.organchem.csdb.cn). The chemical structures were obtained from the Chemical Book (http://www.chemicalbook.com).

2.3. Network Construction of Protein Interaction in Licorice Ingredients and Paraquat

The ingredients of and in licorice through TCMSP database (Supplementary Table 1) and PQ were submitted to the Agilent Literature Search software v.3.1.1 (http://www.agilent.com/labs/research/litsearch.html), which is a powerful automatic metasearch tool for querying multiple text-based PubMed and USPTO, for associations among genes of interest and constructing a network. A graph theoretic clustering algorithm, MCODE (Molecular Complex Detection), was used to analyze the characteristics of the networks. The equation was used, where is the vertex size of the neighborhood of vertex and is the number of edges in the neighborhood [28]. Interactomes with a module score ≥ 3.3 and at least two nodes were selected as significant predictions [27]. STRING (accessed on May 1, 2015, http://string-db.org/) was used to analyze the results of oxidoreductase.

2.4. ADME Property Prediction of Licorice Ingredients

To identify the detoxifying active ingredients of licorice, we used the TCMSP database to predict OB in vivo (%F) and DL of the ingredients. Using this database, we chose those with and as the candidate ingredients, thus reducing the number of original chemicals from the licorice to a smaller subset significantly [31].

2.5. Evidence-Based Finding of Potential Molecules by QSAR and Molecular Docking Study

The quantitative structure-activity relationship (QSAR) model was used as a tool to screen for ingredients depleted of GSH. Organization for Economic Cooperation and Development QSAR (v. 3.2.0, 2013, http://www.qsartoolbox.org/) was used to quantitatively research the interactions of small organic molecular substance with biomacromolecules. The module of protein-binding potency was used in the current study [32].

Molecular docking was used as a tool to screen for ingredients that have strong energy binding to CYP3A4, which is a member of the cytochrome P450 family of oxidizing enzymes. Several other members of this family are also involved in drug metabolism, but CYP3A4 is the most common and the most versatile one [33]. Ingredients in licorice, together with CYP3A4 to carry out virtual molecular docking, use carbamazepine as a positive control. Docking and scoring of the ingredients in licorice were performed using Surflex-Dock in SYBYL -X 2.0. The models of the ingredients were then docked into the crystal structure protein model with Surflex-Dock (default settings with reign flexibility sampled), and the resulting 10 best poses were sorted by the Surflex-Dock scoring function in -log₁₀(K_d) units to simulate binging affinities [34]. Four ingredients were selected according to these filtering criteria.

2.6. Cell Lines, Culture, and Treatment

A549 and HepG2 cells were maintained in DMEM/F12 and MEM, respectively, containing 10% fetal bovine serum, 100 U/mL penicillin, and 100 U/mL streptomycin at 37°C and 5% CO₂ in a suitable incubator. A549 cells and Nrf2 knockdown A549 cells were seeded in 96-well cell plates (), respectively, and grown for 12 h. PQ (0-40 μM) was mixed with the cells and incubated for 24 h. KZ was the CYP3A4 inhibitor. HepG2 cells were seeded in 96-well cell plates () and grown for 12 h. After that they were pretreated with 10 μM KZ for 4 h and exposed to 0-40 μM PQ for 24 h. Cell proliferation was determined by MTT assay.

A549 cells and HepG2 cells were seeded in 96-well cell plates, respectively (5 × 10⁴/well), and grown for 12 h, after they were pretreated with 10 μM GLL, ILF, LCA, LIA, and 18β-GA for 4 h and exposed to 0-40 μM PQ for 24 h. Cell proliferation was determined by MTT assay.

A549 and HepG2 cells were seeded in 96-well cell plates () and grown for 12 h, after which 0–100 μM GLL, ILF, LCA, LIA, and 18β-GA were separately mixed with the cells and incubated for 24 h. Cell proliferation was determined by MTT assay.

Survival OD in text wells - mean OD in free cell wells/mean OD in control wells - mean OD in free wells [35].

2.7. Reverse Transcription Polymerase Chain Reaction and Western Blot Analysis

A549 cells were plated in six-well tissue culture plates. 5 μM and 10 μM GLL, ILF, LCA, and LIA and 50 μM and 100 μM 18β-GA were separately incubated with the cells for 8 h. The levels of Nrf2, glutathione reductase (GR), glutathione peroxidase (GPX), and NAD (P)H:quinone oxidoreductase (NQO1) mRNA were analyzed by Real-Time PCR (RT-PCR).

Nrf2 knockdown A549 cells were plated in six-well tissue culture plates, after which 10 μM GLL, ILF, LCA, and LIA and 50 μM 18β-GA were separately incubated with the cells for 8.0 h. The levels of glutamate cysteine ligase modifier (GCLM) and NQO1 mRNA were analyzed using RT-PCR.

HepG2 cells were plated in six-well tissue culture plates and grown for 12 h, after which 10 μM GLL, ILF, LCA, and LIA and 50 μM 18β-GA were separately incubated with the cells for 24 h. The levels of CYP3A4 mRNA were analyzed by RT-PCR [36].

Quantitative real-time RT-PCR was performed using a single-tube SYBR Green kit (QIAGEN, USA), Rotor Gene Q Real-Time PCR system (Rotor Gene Q, QIAGEN, USA), and specific primer sets (the same primers used in the conventional RT-PCR). Only experiments in which a distinct single peak was observed with a melting temperature different from that of the no-template control were analyzed. The relative amount of target mRNA was calculated by the 2^–△△Ct method. Each sample was analyzed using glyceraldehyde-3-phosphate dehydrogenase (GAPDH) as an endogenous reference gene for mRNA normalization.

HepG2 cell was treated with 10 μM GLL, ILF, LCA, and LIA and 50 μM 18β-GA separately for 24 h, after which the cells were harvested and lysed in RIPA buffer. The levels of CYP3A4 were analyzed by western blot with primary antibody (1 : 1000) and its corresponding secondary antibody (1 : 10000) according to manufacturer’s instructions [36].

2.8. Animal Treatments

KM mice (6-8 weeks old) were purchased from Xinjiang Medical University (Xinjiang, China), weighing 18-25 g (animal qualified number: SCXK 2016-0003). The animals were randomly divided into 6 groups () as follows: (1) control group, (2) PQ group, (3) dexamethasone group, (4) licorice extract (20 mg/kg), (5) licorice extract (40 mg/kg), and (6) licorice extract (60 mg/kg). The animals were housed in a ventilated room at with a 12 h dark/12 h light cycle and provided with free access to fresh water and standard rodent chow. Mice in the control group received saline solution. In the PQ group, mice received PQ (45 mg/kg, i.g.). Licorice extract (20, 40, and 60 mg/kg) groups were treated with licorice extract (20, 40, and 60 mg/kg/d, i.g.) 1 h before mice received PQ. The dexamethasone (DXMS) group was treated with DXMS (0.5 mg/kg/d, ip) 1 h before mice received PQ. The PQ group, PQ+licorice extract group, and DXMS group were treated once with an intragastric infusion of PQ solution (40 mg/kg); licorice extract and DXMS were dissolved in saline (NaCl 0.9%).

The survival of the mice in each group was observed over eight observation periods: 0, 1, 2, 3, 4, 5, 6, and 7 days after treatment administration. Mice were anaesthetized after treatment for 7 days; lung tissues, liver tissues, and renal tissues were collected. And blood samples were then collected from the inferior vena cava from each group and stored at 4°C overnight for serum preparation and PQ concentration detection. Weighing the lung tissue of mice, use lung weight/dry weight to calculate the lung W/D in mice. Histological examination of the lung, liver, and renal tissues from each group was performed to evaluate tissue damage.

Parts of lung tissues were used for measuring oxidative stress biomarkers. Malondialdehyde (MDA) level and Superoxide Dismutase (SOD) activity were determined according to the thiobarbituric acid (TBA) method and xanthine oxidase method as manufacturer’s instructions (Nanjing Jiancheng Bioengineering Institute, China). The levels of CYP3A4 and Nrf2 were analyzed by western blotting according to manufacturer’s instructions [36]. Serum was used for measuring renal and liver function evaluation. Urea nitrogen (BUN), creatinine (CRE), aspartate aminotransferase (AST/GOT), and alanine aminotransferase (ALT/GPT) levels were determined according to the urease and sarcosine oxidase methods as manufacturer’s instructions (Nanjing Jiancheng Bioengineering Institute, China).

According to the literature, for fluorescence detecting of paraquat using host-guest chemistry with cucurbit[8]uril, we used the methods in [2]; 2MB@CB[8] (200 μL, 5 μM) was added into 0.1 mL serum of mice to determine the concentration of PQ in serum. According to the literature, the fluorescence reaction of 2MB@CB[8] and PQ also occurs in live mice. After injecting 2MB@CB[8] solution into mice (0.1-0.2 mL), real-time fluorescence imaging of PQ in vivo was carried out to demonstrate the residual of PQ in each group of mice by using a NightOWL II LB 983 system equipped with a NC 100 CCD deep-cooled camera (Berthold Technologies, Bad Wildbad, Germany).

2.9. Statistical Analysis

Statistical analysis was conducted with SPSS version 18.0 software and GraphPad Prism 5, using one-way analysis of variance (ANOVA) for multiple group comparisons or Student’s -test for two-group comparisons. All data are expressed as the error [37]. was considered statically significant.

3. Results

3.1. Survival Rate of Mice

On the 7^th day, after PQ intoxication, licorice extract treatment had significantly increased the survival rate at day 8, with 60% survival in the PQ+licorice extract group () compared with 20% in the PQ group. Licorice extract treatment improved the survival rate to 60% in the PQ+licorice extract group compared with 20% in the PQ group; the improvements were statistically significant (Figure 1). This result confirmed the protective effect of licorice on mortality in mice with PQ poisoning.

3.2. Licorice Attenuates the PQ-Induced Pulmonary Damage

We used H&E staining to display pulmonary damages in each group of mice (Figure 2). In the control group, the alveoli showed clear boundaries and intact structures. Thickening of alveolar walls and infiltration of inflammatory cells were not observed nor were exudates from alveolar cavities. In the PQ group, incrassation was revealed in alveolar septum accompanied with discontinuous destruction. A large number of inflammatory cells such as neutrophils, macrophages, and lymphocytes infiltrated the alveolar cavities. Thickening alveolar walls, collapsed alveolar diffused pulmonary hemorrhage, and destruction of alveolar epithelial cells were observed significantly. In licorice extract-treated groups, compared with the PQ group, pulmonary damages were significantly reduced with administrated dosages from 20 to 60 mg/kg. The pathological thickening of the alveolar septum by PQ was alleviated. Inflammatory infiltration was significantly limited in the alveolar cavities. Few atrophied alveolar structures and thickened alveolar septum were observed.

(a)

(b)

(c)

(d)

(e)

(f)

Figure 2

Lung histological examination from H&E staining. Histological appearance of the lung sections from the (a) normal group, (b) model group, (c) DXMS group, (d) licorice extract (20 mg/kg), (e) licorice extract (40 mg/kg), and (f) licorice extract (60 mg/kg). Widespread thickening of the alveolar septum and infiltration of inflammatory cells were observed in the model group. Treatment with licorice extract reduced the histological alterations induced by PQ. The lung sections were analyzed by hematoxylin and eosin (H&E) staining (magnification is ×400).

3.3. Licorice Reduced PQ-Induced Pulmonary Edema of Mice

Lung wet/dry weight ratio is used to measure the edema degree of lung tissue in mice. Compared with the control, the lung wet/dry weight ratios were significantly increased after PQ gavage (). The increase of W/D was significantly reduced by licorice extract treatment at high doses () (Figure 3). This result showed licorice extract reduce pulmonary edema in mice in different degrees.

3.4. Licorice Reduced PQ-Induced Oxidative Stress in the Lung Tissues of Mice

To evaluate the effect of licorice on PQ-induced oxidative stress damage, the level of MDA and SOD was measured which were biological indicators of oxidative stress. MDA level in the model group was significantly higher than that in the control group (). Compared with the PQ group, the MDA level in the licorice extract (20, 40, and 60 mg/kg) groups, especially in the licorice extract (60 mg/kg) group, was much lower (). According to Figure 4, the activity of SOD in the model group was significantly lower than that in the control group (). Compared with the PQ group, the licorice extract (60 mg/kg) group has increased SOD activity () remarkably. As we can see, oxidative stress has been shown to be increased in the model group; licorice extract (60 mg/kg) decreased the level of MDA and increased the activity of SOD significantly.

(a)

(b)

3.5. Licorice Alleviated Pulmonary Fibrosis in Mice Induced by PQ

In order to evaluate pulmonary fibrosis degree in mice, western blotting was used to measure the level of TGF-β1, which is a potent profibrotic cytokine, in the foci containing these activated fibroblasts [38]. Compared with the control group, PQ significantly increased the level of TGF-β1 expression (); after the treatment of licorice extract (60 mg/kg), TGF-β1 expression was decreased remarkably (). It suggests that licorice reduces pulmonary fibrosis after PQ intake (Figure 5).

(a)

(b)

(c)

(d)

(e)

Figure 5

Licorice induce CYP3A4 and Nrf2 expression in mice and inhibit TGF-β1 expression. After processing the lung tissue of mice, Nrf2, CYP3A4, and TGF-β1 protein expression in the lung tissues and CYP3A4 protein expression in the liver tissues were measured by western blotting. CYP3A4 (lung): CYP3A4 expression in the lung tissues; CYP3A4 (liver): CYP3A4 expression in the liver tissues. Results show that licorice induce Nrf2 and CYP3A4 expression in a dose-dependent manner but inhibit TGF-β1 expression especially in licorice extract (60 mg/kg) (). Data points and error bars represent the of at least three experiments () for each concentration tested; ().

In order to show more directly that licorice alleviated pulmonary fibrosis after PQ intake, Masson trichrome staining was used to assess collagen deposition. Masson trichrome staining of formalin-fixed tissues revealed greater amounts of collagen deposition in the lung tissues of the model group (Figure 6). Fibrosis was decreased in a dose-dependent manner after the treatment of licorice extract.

(a)

(b)

(c)

(d)

(e)

(f)

3.6. Licorice Induced CYP3A4 and Nrf2 Expression to Detoxify the Toxicity Induced by PQ

To evaluate the detoxification effect of licorice on PQ-induced lung injury, the level of Nrf2 and CYP3A4 expression of lung tissues and CYP3A4 expression of liver tissues was measured by western blotting. Compared with the control group, PQ decreased CYP3A4 and Nrf2 expression remarkably () in the model group. Nrf2 expression was increased after the treatment of licorice extract (60 mg/kg) significantly (). It is speculated that the activation of Nrf2 can induce the activation of detoxification pathways. CYP3A4 expression was increased after the treatment of licorice extract (60 mg/kg) significantly (), suggesting that licorice may promote the detoxification of paraquat in vivo by upregulating CYP3A4, reduce the time of paraquat action in vivo, and reduce or detoxify the toxicity of PQ (Figure 5).

3.7. Licorice Reduces PQ Accumulation in Mice

After calculating the concentration of PQ in mouse plasma using the method in the literature, it can be found that PQ accumulation in plasma of mice decreased in a dose-dependent manner after treatment of licorice extract. This may be related to the upregulated expression of CYP3A4 and Nrf2 underlying the alexipharmic mechanisms of licorice () (Figure 7).

(a)

(b)

Figure 7

Licorice reduces PQ accumulation in mice. (a) 2MB@CB[8] was used to investigate the concentration of PQ in plasma. After calculating the concentration of PQ in mouse plasma using the method in the literature, it can be found that PQ accumulation in plasma of mice decreased in a dose-dependent manner after treatment of licorice extract. (b) Fluorescence imaging of PQ in living mice. Excitation wavelengths of were used and the fluorescence emission was detected at in a Berthold chamber. According to real-time in vivo fluorescence imaging of PQ in the living mice, it can be seen that PQ can be readily tracked by using 2MB@CB[8] in living mice. The fluorescence spectra showed that the accumulation of PQ in the licorice extract (60 mg/kg) group was significantly lower than that in the control group. All data are expressed as the error; . CTR: control; MOD: model. Compared with the CTR group, , ; compared with the MOD group, , .

According to real-time in vivo fluorescence imaging of PQ in the living mice (Figure 7), it can be seen that PQ can be readily tracked by using 2MB@CB[8] in living mice. The fluorescence spectra showed that the accumulation of PQ in the licorice extract (60 mg/kg) group was significantly lower than that in the control group.

3.8. Licorice Improves Liver and Renal Function in PQ-Poisoned Mice

The levels of aspartate aminotransferase (AST/GOT) and alanine aminotransferase (ALT/GPT) in serum can help people diagnose if the liver is injured or not. When the liver is diseased or damaged, additional AST and ALT are released into the bloodstream, causing levels of the enzyme to rise. Therefore, the amount of AST and ALT in the blood is directly related to the extent of the tissue damage [39]. According to the elevated levels of AST/GOT and ALT/GPT in mice in the model group, the liver function of mice after intake of paraquat was damaged (). After treatment with licorice extract, the levels of AST/GOT and ALT/GPT tended to control group and decreased in a dose-dependent manner, especially in licorice extract (60 mg/kg) () (Figure 8(a)). Licorice extract had a protective effect against paraquat-induced liver damage in mice.

(a)

(b)

(c)

(d)

Figure 8

Function and morphology of liver and renal tissues in mice. (a) The levels of alanine aminotransferase (ALT/GPT) and aspartate aminotransferase (AST/GOT) in serum. According to the elevated levels of AST/GOT and ALT/GPT in mice in the model group, the liver function of mice after intake of paraquat was damaged (). After treatment with licorice extract, the levels of AST/GOT and ALT/GPT tended to control group and decreased in a dose-dependent manner, especially in licorice extract (60 mg/kg) (). (b) The level of renal function was reflected by blood urea nitrogen (BUN) and creatinine (CRE) levels. Data are ; . Compared with the CTR group, , ; compared with the MOD group, , . Compared with the control group, the model group had increased BUN and CRE significantly (). Compared with the model group, the licorice extract groups had decreased BUN especially in the licorice extract (60 mg/kg) group (). (c, d) H&E staining results of renal and liver tissues. The pathological results of renal and liver tissues showed that no abnormalities were found in normal control; the morphological injury was severe in the paraquat group, which was alleviated in the licorice extract (60 mg/kg) group. Liver and renal sections were analyzed by hematoxylin and eosin (H&E) staining (magnification is ×200).

The level of renal function was reflected by blood urea nitrogen (BUN) and creatinine (CRE) levels. Compared with the control group, the model group had increased BUN significantly (). Compared with the model group, the licorice extract groups had decreased BUN especially in the licorice extract (60 mg/kg) group (). A significant difference was observed in serum BUN when comparing the licorice extract (60 mg/kg) group with the model group (Figure 8(b)). Serum CRE increased rapidly after treatment of paraquat (). After treatment with licorice extract, CRE level decreased in a dose-dependent manner especially in the licorice extract (60 mg/kg) group (). The result displays a protective effect against paraquat-induced renal damage in mice. The mechanism of the protection appears to be the induction of CYP3A4 and Nrf2 expression.

From the H&E staining results of the renal tissue, normal renal structure was observed in the control group. In the mice with paraquat, tissue necrosis and hemorrhage and significant tissue injury were observed also with tubular and glomerular necrosis. Administration of licorice extract (60 mg/kg) improved tissue structure; glomeruli and tubules were better preserved (Figure 8(c)).

Liver sections were analyzed for histopathological changes. Sections from the control group had radially arranged normal hepatocytes with intact central veins and bile ducts. Increased sinusoidal spaces and congestion, damaged central vein and bile ducts, loss of cell boundaries, variable degrees of vacuolization, degenerating nuclei, and apoptotic cells were present in the paraquat group. Licorice extract treatment, especially at a dosage of 60 mg/kg, somewhat preserved the normal liver histology (Figure 8(d)).

3.9. Potential Active Target Searching and Clustering Analysis of Network Topology Relationship by MCODE

There are 104 common targets between licorice and paraquat. The Agilent Literature Search networks of the expressed genes contained 606 nodes and 1739 edges (Figure 9) (Supplementary Table 1). Connections contain direct interaction partners and interconnections. Cytoscape analysis revealed a great number of close interconnections that can be seen in Figure 5. MCODE was used to identify the hub genes or proteins in the networks with a connectivity degree ≥ 3.333 (Supplementary Table 2). Twenty-eight hub genes were selected from the network, which included Apoptosis regulator NFE2L2 (Nrf2) and CYP2B6. There are 36 oxidoreductases that express string and Nrf2 as the core of the region to CYP450 connected to the network and in the center. Prove two important targets Nrf2 and CYP450 in licorice and PQ (Supplementary Figure 6).

Figure 9

Network construction of protein interaction in licorice ingredients and paraquat. The ingredients of and in licorice through TCMSP database (Supplementary Table 1) and PQ were submitted to the Agilent Literature Search software v.3.1.1 (http://www.agilent.com/labs/research/litsearch.html), which is a powerful automatic metasearch tool for querying multiple text-based PubMed and USPTO, for associations among genes of interest and constructing a network. Agilent Literature Search is a registered plugin and can be used in conjunction with Cytoscape 3.2 (accessed on May 1, 2015, http://www.cytoscape.org/) to realize the visualization and analyzation of the network (parameters: Max Engine Matches = 10; Concept Lexicon = Homo sapiens; Interaction Lexicon = limited). (a) Agilent Literature Search Network of 104 common genes from licorice and PQ based on Cytoscape; red ellipses indicate downstream genes of Nrf2 and CYPs, whose seed genes are included in our list. (b) NFE2L2 (Nrf2) and (c) CYP1A2 seed nodes, respectively. All edges represent physical interactions. And there is a synergy between Nrf2 and CYPs; among them, GSTP1 is the key target to connect the two groups (Supplementary Figure 6).

3.10. Network Screening of Active Ingredients

There were 101 ingredients in licorice with the filter conditions of and according to the TCMSP website. Fifty-five ingredients could potentially deplete GSH, and 50 ingredients could react with the CYP3A4 substrate according to the admetSAR website (accessed on May 1, 2015, http://lmmd.ecust.edu.cn/admetsar1). Ingredients have high total score binding to CYP3A4. Ultimately, 28 ingredients could react both ways and these were divided into the following five classes: 6 coumarins, 3 flavonoids, 14 isoflavones, 4 chalcones, and 1 triterpene (Supplementary Table 3). We chose GLL, ILF, LCA, LIA, and 18β-GA, the five ingredients in licorice to represent the five classes. GLL was chosen due to the high OB. LCA was chosen due to the high total score in molecular docking. 18β-GA has been reported and is responsible for the concentration-dependent induction of CYP3A and Nrf2 [18].

3.11. Effect of CYP3A4 in Active Ingredients of Licorice Evaluated by Molecular Docking

The virtual docking results indicated that LCA exhibited characteristics of strong binding to the catalytic domain of CYP3A4. The total score was determined to be 6.0907. Other ingredients, namely, GLL, LIA, ILF, and 18β-GA, were also used as ligands to interact with the catalytic domain of CYP3A4 (Figure 10). The total score of ILF, LIA, GLL, 18β-GA, and carbamazepine was determined to be 6.0287, 5.6487, 4.7912, 4.4983, and 4.3030, respectively. LIA and carbamazepine also interact with ARG212. GLL, LIA, and 18β-GA interact with the same ligands ARG105. SER119 was interacted with LCA, LIA, and ILF (Figure 10) (Supplementary Table 4).

(a)

(b)

(c)

(d)

(e)

(f)

3.12. Effects of the Five Ingredients on A549 and HepG2 Cell Proliferation: A549 and HepG2 Cells Are More Sensitive to PQ with Nrf2 and CYP3A4 Inhibitor

HepG2 cell pretreatment with 10 μM KZ significantly reduced viability compared with HepG2 cells without KZ when PQ concentration increased (Figure 11(a)). KZ reversely verified the activation of the hepatic drug-metabolizing enzyme capable of solution of PQ toxicity. Nrf2 knockdown of A549 cell viability was significantly reduced compared with A549 cells with increased PQ concentration (Figure 11(b)). A549 cell pretreatment with 10 μM LCA, LIA, and ILF significantly reduced viability compared with A549 cell control group when PQ concentration increased and LCA increased the viability more than the other ingredients. HepG2 cell pretreatment with 10 μM LCA and ILF also reduced viability (Figures 12(a) and 12(b)). It verified the activation of the hepatic drug-metabolizing enzyme capable of solution of PQ toxicity. With 5 μM and 10 μM of GLL, ILF, LCA, and LIA and 50 μM and 100 μM of 18β-GA added, there was lower cytotoxic activity after 24 h of incubation, whereas higher concentrations of these ingredients decreased the proliferation of HepG2 and A549 cells in a concentration-dependent manner after 24 h of incubation (Figure 13).

(a)

(b)

(a)

(b)

(a)

(b)

(c)

(d)

(e)

(f)

(g)

(h)

(i)

(j)

3.13. Five Ingredients Induced Not Only the Activation of Nrf2, GR, Gpx, and NQO1 mRNA Expression in A549 Cells But Also CYP3A4 mRNA Expression and CYP3A4 Protein in HepG2 Cells

RT-PCR was performed after 8 h of incubation with the five selected ingredients and the levels of mRNA expression were determined. Compared with the control group, Nrf2, GR, GPX, and NQO1 mRNA expressions increased after 8 h exposure to 5 μM and 10 μM GLL, LCA, LIA, and ILF and 50 μM and 100 μM 18β-GA with lower cytotoxic activity. Treatment with GLL and 18β-GA resulted in enhanced expression of Nrf2 in a dose-dependent manner. 5 μM LIA played a critical role in activating Nrf2. Treatment with GLL, LCA, ILF, and 18β-GA resulted in enhanced expression of GR in a dose-dependent manner. 5 μM ILF played a critical role in activating GR (Figure 14). We found that as the concentration of the five ingredients increased, there was a rapid increase in Nrf2, GR, GPX, and NQO1 expression levels (Supplementary Table 5).

(a)

(b)

CYP3A4 was significantly activated by 10 μM GLL, LCA, LIA, and ILF and 50 μM 18β-GA, as detected by RT-PCR after 24 h of incubation with the five ingredients. In particular, LIA played a critical role in activating CYP3A4 (Figure 15). Western blot analysis showed that the protein level of CYP3A4 expression was significantly increased compared to that of the control cells following 24 h of exposure to 10 μM GLL, ILF, LCA, and LIA and that 10 μM LCA increased the protein levels of CYP3A4 more than the other ingredients (Figure 16). The total score of LCA is also more than the other ingredients in molecular docking. In summary, our results indicated that GLL, LCA, LIA, and ILF activation of the Nrf2 signaling pathway and its downstream genes, in addition to the activation of the CYP3A4, could be one of the detoxification mechanisms in licorice.

(a)

(b)

(a)

(b)

3.14. Five Ingredients Downregulated GCLM and NQO1 mRNA Expression in Nrf2-Silenced A549 Cells

In order to understand the alexipharmic role of CYP3A4 and Nrf2, we used Nrf2-silenced A549 cell line for further study. We then transfected cells with Nrf2 siRNA. Compared with the control and shRNA-NC, the Nrf2 gene-silenced two A549 cell clones displayed a declining trend in the expressions of the glutathione pathway genes; GCLM and NQO1 were downregulated. RT-PCR was performed after 8 h of incubation with the five ingredients and mRNA expression levels were determined. Compared with the control group, GCLM mRNA expression did not increase following 8 h of exposure to 10 μM GLL, LCA, LIA, and ILF and 50 μM 18β-GA. NQO1 mRNA expression levels did not increase compared to those of the control vector transfected cells following 8 h of exposure to 10 μM LCA and LIA and 50 μM 18β-GA but did moderately increase with exposure to LIA (Figure 17).

(a)

(b)

4. Discussion

PQ is highly toxic to humans and induces extensive pulmonary injury, including pulmonary edema, hypoxemia, respiratory failure, and pulmonary fibrosis [40]. Generally, acute lung injury is diffused heterogeneous lung injury characterized by hypoxemia, noncardiogenic pulmonary edema, low lung compliance, and widespread capillary leakage [41]. At present, the mechanism of PQ-induced ALI is still not conclusively known. Most scholars believe that PQ induces its toxic effects mainly by oxidative stress which has an important function in this process. In oxidative stress process, PQ consumes nicotinamide adenine dinucleotide phosphate and cytochrome P450 reductase, causing oxidative stress reaction. It told us that antioxidation and detoxification are important in the treatment of paraquat detoxification.

As a famous herbal alexipharmacon, licorice has demonstrated remarkable polypharmcological applications, such as anticancer, anti-inflammatory, and hepatoprotective effects [18]. Recent successful efforts were made on antidotes for various poisonings, including but not limited to, food, herbs, herbicides, pesticides, drugs, and heavy metals [18]. Gene functional classification illustrates correlated expression patterns and because of the importance of networks in system biology, quantitative tools have been developed in recent years for analyzing these networks [28]. In the present study, we use oxidative stress biomarkers and detoxifying enzymes to measure the protective effect of licorice on PQ-induced acute lung injury in vivo. To study the mechanism of detoxification and antioxidation, we use a system pharmacology approach to determine the active components in licorice [42]. As depicted in the results, in vivo studies indicated that licorice alleviate pulmonary edema and fibrosis, decrease MDA contents and increase SOD activity in PQ-induced ALI mice, protect the morphologic appearance of lung tissues, induce CYA3A4 and Nrf2 expression to active detoxification pathways, reduce the accumulation of PQ in vivo, protect or improve the liver and renal function of mice, and increase the survival rate. With the positive effect in vivo, we explore the possible mechanisms of action and obtained four unreported candidate compounds in silico. GLL () is a natural compound extracted from Glycyrrhiza uralensis. IFL () was identified and considered to be an active inhibitor against angiogenesis and a promising compound as a potential cancer chemopreventive agent [43]. LIA () was identified for its antibacterial and gastroprotective properties [44]. At low concentrations, it inhibits MRP-mediated efflux to control MRP-like activity in human erythrocytes. LCA () has been shown to exhibit multiple pharmacological properties [45].

Analyzing the network properties of gene expression data might reveal the organizational pattern of gene expression in licorice, which might, in turn, help to identify the mechanisms of molecular detoxification. Drug-metabolizing enzymes such as CYP450, which help bioactivate toxic substances, and phase II enzyme GST, which can reduce the toxicity of electrophilic compounds formed by phase I enzymes [46]. In a series of redox reactions, PQ consumes nicotinamide adenine dinucleotide phosphate and cytochrome P450 reductase, cause oxidative stress reaction. Hence, the actual effects of the accumulation of toxic metabolic products of drugs and the detoxification process depend on the balance between phase I and phase II enzymes.

Nrf2, a master regulator of the detoxifying response, plays a critical role in the expression of many cytoprotective enzymes, including NQO1, HO-1, and glutathione S-transferase (GST). As represented in Figure 9, there are many proteins with the most degrees as hubs, such as AFF4 (AF4/FMR2 family, member 4), Nrf2, and CYP2B6. We selected all oxidoreductase to analyze the bond that linked them. In Supplementary Figure 6, GST is the more important protein as a link between CYP450 and Nrf2. According to the literature, GST may account for the variation in host response to oxidative stress, a key component of airway inflammation [47]. Previous studies have shown that Nrf2 protects against endotoxin-induced hepatic injury through transcriptional upregulation of downstream genes, such as GCL, GR, GPX, and NQO1 [48], which suggest that the protective part of Nrf2 is attributed partly to its involvement in coordinated induction of phase II drug-metabolizing enzymes. Studies have shown that overexpression of GR is capable of increasing stress tolerance. Glutathione peroxidase-1 (GPx-1) is an intracellular antioxidant enzyme that enzymatically reduces hydrogen peroxide to water to limit its harmful effects. NQO1, a phase II metabolic enzyme, is known as a target for bioreductive activation of certain anticancer drugs and antioxidants and as a means of xenobiotic detoxification. GCL, the enzyme that catalyzes the rate-limiting step in the biosynthesis of GSH, can combine with toxic components, leading to the excretion of those toxins [21].

The study has shown that drug metabolism and efflux transporters are considered to play important roles in regulating the body. Concurrently, the subnetwork with the seed gene, Nrf2, is a basic leucine zipper transcription factor and is necessary against oxidative stress and regulates the expressions of a variety of drug-metabolizing enzymes [21, 49]. It has been found that Nrf2, an important transcription factor of oxidative stress, is known to be essential for the antioxidant responsive element-mediated induction of oxidative stress enzyme genes and plays an important role in the development of PQ-induced ALI. Many studies showed their results by inhibiting oxidative stress to slow down the process of ALI [13]. Studies have revealed that Nrf2 knockout mice were more susceptible to butylated hydroxytoluene-induced lung injury and acetaminophen-induced hepatotoxicity at high doses [50]. It was identified that the RNAi-mediated reduction of Nrf2 expression in lung cancer cells induces the generation of ROS, decreases the level of reduced glutathione, and results in an increase in the A549 cell proliferation inhibition rate. In corroboration with GR, GPX and GST gene expression as well as the total GSH levels was significantly reduced in Nrf2 shRNAi A549 cells and in comparison with the shRNA-NC control cells. Nrf2 expression downregulation profoundly decreased the expression of key antioxidative enzyme genes, glutathione pathway genes with a constructive activation of Nrf2 function. Thus, the licorice-induced expression of Nrf2 can enhance detoxification [30]. As shown in the present study, we successfully disclosed that GLL, LCA, ILF, and LIA significantly induce GR, GPX, and NQO1 mRNA expression (Figure 14), and we first indicated that GLL, ILF, LCA, and LIA induce CYP3A4 mRNA expression (Figure 15) and have subsequent effects on CYP3A4 protein levels (Figure 16). On the basis of total score in molecular docking, LCA was found to be a better CYP3A4 agonist than the other ingredients, which is consistent with our results. However, it is noteworthy to mention that all the other ingredients also showed considerable affinities toward CYP3A4. Hence, structures of these ingredients could be used for designing antidotes against toxic medications. The virtual docking results indicated that the five ingredients exhibited characteristics of strong binding to the catalytic domain of CYP3A4. The five compounds induced CYP3A4 mRNA and protein levels further indicating that the five compounds are CYP3A4 agonists (Supplementary Table 4). It verified the activation of hepatic drug-metabolizing enzyme capable of solution of PQ toxicity through GLL, LCA, LIA, and ILF.

We hope low-concentration compounds of licorice as an emerging paradigm emphasizes molecularly targeted approaches for PQ-induced lung injury therapy. In vivo study showed that licorice increase the level of CYP3A4 and Nrf2, alleviate pulmonary edema, injury, and fibrosis, reduce the accumulation of PQ in vivo, protect or improve the liver and renal function of mice, and ultimately improve the survival rate of mice. GLL, ILF, LCA, 18β-GA, and LIA isolated from licorice significantly induce Nrf2 and its downstream detoxification genes GR, GPX, and NQO1. We can infer that the other active components in licorice may also have the potential activity of detoxification on paraquat poisoning through in vivo experiments. And the content of four new compounds of licorice after in silico screening is worth exploring. Perhaps the effect of drug combination between detoxification molecules will be better. Notably, these data might represent, at least in part, a new mechanism by which the traditional use of licorice can alleviate the side effects of toxic TCMs.

5. Conclusion

The current study constitutes the antioxidation and detoxification effects of licorice extract on PQ-induced acute lung injury, alleviating pulmonary edema and fibrosis, reducing the accumulation of PQ in vivo, protecting or improving liver and renal function of mice, and finally, improving the survival rate of mice. For the first report, GLL, ILF, LCA, and LIA increased the level of CYP3A4 and Nrf2 as a mechanism for detoxification. Moreover, GLL was found to be a better CYP3A4 agonist than the other ingredients.

Abbreviations

A549:	The human type II alveolar adenocarcinomic basal epithelial cells
ALI:	Acute lung injury
ADMET:	Absorption, Distribution, Metabolism, Excretion, and Toxicity
AFF4:	AF4/FMR2 family, member 4
AKT-1:	RAC-alpha serine/threonine-protein kinase
BAX:	Apoptosis regulator BAX
CYP450:	Cytochrome P450
CYP3A4:	Cytochrome 3A4
DMEM/F12:	Dulbecco’s Modified Eagle’s Medium Nutrient Mixture F-12
DL:	Drug-likeness
GAPDH:	Glyceraldehyde-3-phosphate dehydrogenase
GCLM:	Glutamate cysteine ligase modifier
GLL:	Glycyrol
GPX:	Glutathione peroxidase
GR:	Glutathione reductase
GSH:	Glutathione
HepG2:	Human hepatocellular liver carcinoma cell
HP:	Hemoperfusion
ILF:	Isolicoflavonol
KZ:	Ketoconazole
LE:	Licorice extract
LCA:	Licochalcone A
LIA:	Licoisoflavone A
MCODE:	Molecular Complex Detection
MDA:	Malondialdehyde
MEM:	Minimum Essential Medium
MTT:	3-(4.5-Dimethylthiazol-2-yl)-2.5-diphenyl tetrazolium bromide
Nrf2, NFE2L2:	Nuclear factor erythroid 2-related factor 2
NQO1:	NAD (P)H:quinoneoxidoreductase
OB:	Oral bioavailability
PQ:	Paraquat
QSAR:	Quantitative structure-activity relationship
RT-PCR:	Real-Time PCR
SFRP4:	Secreted frizzled-related protein 4
SOD:	Superoxide Dismutase
TCMSP:	Traditional Chinese Medicine Systems Pharmacology Database and Analysis Platform
TCM:	Traditional Chinese medicine
18β-GA:	18Beta-glycyrrhetinic acid.

Data Availability

All data generated or analyzed during this study are included in this published article and its supplementary information files.

Conflicts of Interest

The authors declare that there is no conflict of interest regarding the publication of this article.

Authors’ Contributions

Zi-Jing Liu and Jing Zhong wrote the manuscript. Ji-Ye Wang and Ze-Hui Chen made the network pharmacological analysis. Jing Zhong, Xiao-Qin Wang, and Mei Zhang participated in cell culture, RT-PCR, and data analysis. Zi-Jing Liu and Han-Ying Chen performed animal experiments, western blotting, and data analysis. Bo Zhang designed the study and improved the quality of the manuscript. All authors reviewed and approved the final manuscript. Zi-Jing Liu, Jing Zhong, and Mei Zhang contributed equally to this work.

Acknowledgments

This study was supported by the National Natural Science Foundation of China (No. U1603122, 81460566), the key Scientific and Technological program of Licorice Planting and Quality Improvement in Xinjiang (No. 2018AB012), and the Young and middle-aged Leading talents funds (No. 2018CB019) of Xinjiang Production & Construction Corps. ADME property predictions were supported by Prof. Yonghua Wang. Cucurbit[8]uril and PQ detection method were supported by Prof. Shiguo Sun. Blood sample and preparation were supported by Prof. Yingchun Li. Virtual molecular docking via Surflex-Dock in SYBYL -X 2.0 was supported by Prof. Yun Tang.

Supplementary Materials

Supplementary Table 1: the ingredients of and in licorice and nodes in Agilent Literature Search. Supplementary Table 2: MCODE scoring for PPI network. Molecular docking was used as a tool to screen for ingredients having strong energy binding to CYP3A4, which is a member of the cytochrome P450 family of oxidizing enzymes. MCODE was used to identify the hub genes or proteins in the networks with a connectivity degree ≥ 3.333. Supplementary Table 3: active compounds which could potentially deplete GSH and have high total score binding to CYP3A4 according to the admetSAR website. Supplementary Table 4: molecular docking score for ingredients that have strong energy binding to CYP3A4. Supplementary Table 5: Real-Time PCR primer sequences. Supplementary Figure 6: there are 36 oxidoreductases that express string and Nrf-2 as the core of the region to CYP450 connected to the network and in the center. Prove two important targets Nrf-2 and CYP450 in licorice and PQ. Supplementary Figure 7: the effect of licorice extract on levels of MDA and SOD. Effects of treatment with licorice extract on the levels of MDA (A) and SOD activity (B) of the lung tissue. Treatment with licorice extract reduced the level of MDA and increased the activity in the lung tissues of PQ-induced lung injury. But in LE (80 mg/kg), MDA and SOD levels were increased compared with LE (60 mg/kg). Data are ; . and compared with the CTR group, and compared with the MOD group. Supplementary Figure 8: DXMS docked to the catalytic site of CYP3A4. (Supplementary Materials)

References

M. Eddleston and M. Phillips, “Self poisoning with pesticides,” BMJ, vol. 328, no. 7430, pp. 42–44, 2004.
View at: Publisher Site | Google Scholar
S. Sun, F. Li, F. Liu, J. Wang, and X. Peng, “Fluorescence detecting of paraquat using host-guest chemistry with cucurbit[8]uril,” Scientific Reports, vol. 4, no. 1, p. 3570, 2014.
View at: Google Scholar
X. Wang, M. Zhang, J. Ma et al., “Metabolic changes in paraquat poisoned patients and support vector machine model of discrimination,” Biological & Pharmaceutical Bulletin, vol. 38, no. 3, pp. 470–475, 2015.
View at: Publisher Site | Google Scholar
L. Hu, G. Hong, J. Ma, X. Wang, and H. Chen, “An efficient machine learning approach for diagnosis of paraquat-poisoned patients,” Computers in Biology and Medicine, vol. 59, pp. 116–124, 2015.
View at: Publisher Site | Google Scholar
H. W. Gil, M. S. Kang, J. O. Yang, E. Y. Lee, and S. Y. Hong, “Association between plasma paraquat level and outcome of paraquat poisoning in 375 paraquat poisoning patients,” Clinical Toxicology, vol. 46, no. 6, pp. 515–518, 2009.
View at: Publisher Site | Google Scholar
M. S. Kang, H. W. Gil, J. O. Yang, E. Y. Lee, and S. Y. Hong, “Comparison between kidney and hemoperfusion for paraquat elimination,” Journal of Korean Medical Science, vol. 24, Supplement 1, p. S156, 2009.
View at: Publisher Site | Google Scholar
S. Y. Hong, J. O. Yang, E. Y. Lee, and S. H. Kim, “Effect of haemoperfusion on plasma paraquat concentration in vitro and in vivo,” Toxicology and Industrial Health, vol. 19, no. 1, pp. 17–23, 2003.
View at: Publisher Site | Google Scholar
C. W. Hsu, J. L. Lin, D. T. Lin-Tan et al., “Early hemoperfusion may improve survival of severely paraquat-poisoned patients,” PLoS One, vol. 7, no. 10, article e48397, 2012.
View at: Publisher Site | Google Scholar
Y. H. Jo, K. Kim, J. E. Rhee et al., “Therapeutic hypothermia attenuates acute lung injury in paraquat intoxication in rats,” Resuscitation, vol. 82, no. 4, pp. 487–491, 2011.
View at: Publisher Site | Google Scholar
G. Zollner, M. Wagner, and M. Trauner, “Nuclear receptors as drug targets in cholestasis and drug-induced hepatotoxicity,” Pharmacology & Therapeutics, vol. 126, no. 3, pp. 228–243, 2010.
View at: Publisher Site | Google Scholar
S. Wang, Z. Wang, D. Chen et al., “Effect of acute paraquat poisoning on CYP450 isoforms activity in rats by cocktail method,” International Journal of Clinical and Experimental Medicine, vol. 8, no. 10, pp. 19100–19106, 2015.
View at: Google Scholar
R. J. Dinis-Oliveira, J. A. Duarte, A. Sanchez-Navarro, F. Remiao, M. L. Bastos, and F. Carvalho, “Paraquat poisonings: mechanisms of lung toxicity, clinical features, and treatment,” Critical Reviews in Toxicology, vol. 38, no. 1, pp. 13–71, 2008.
View at: Publisher Site | Google Scholar
A. Mustafa, A. M. Gado, O. A. Al-Shabanah, and A. M. Al-Bekairi, “Protective effect of aminoguanidine against paraquat-induced oxidative stress in the lung of mice,” Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology, vol. 132, no. 3, pp. 391–397, 2002.
View at: Publisher Site | Google Scholar
A. Lavecchia and C. Cerchia, “In silico methods to address polypharmacology: current status, applications and future perspectives,” Drug Discovery Today, vol. 21, no. 2, pp. 288–298, 2016.
View at: Publisher Site | Google Scholar
A. Rocejanasaroj, T. Tencomnao, and W. Sangkitikomol, “Thunbergia laurifolia extract minimizes the adverse effects of toxicants by regulating P-glycoprotein activity, CYP450, and lipid metabolism gene expression in HepG2 cells,” Genetics and Molecular Research, vol. 13, no. 1, pp. 205–219, 2014.
View at: Publisher Site | Google Scholar
J. C. Chen, T. Y. Ho, Y. S. Chang, S. L. Wu, C. C. Li, and C. Y. Hsiang, “Identification of Escherichia coli enterotoxin inhibitors from traditional medicinal herbs by in silico, in vitro, and in vivo analyses,” Journal of Ethnopharmacology, vol. 121, no. 3, pp. 372–378, 2009.
View at: Publisher Site | Google Scholar
M. Paolini, L. Pozzetti, A. Sapone, and G. Cantelli-Forti, “Effect of licorice and glycyrrhizin on murine liver CYP-dependent monooxygenases,” Life Sciences, vol. 62, no. 6, pp. 571–582, 1998.
View at: Publisher Site | Google Scholar
X. Wang, H. Zhang, L. Chen, L. Shan, G. Fan, and X. Gao, “Liquorice, a unique “guide drug” of traditional Chinese medicine: a review of its role in drug interactions,” Journal of Ethnopharmacology, vol. 150, no. 3, pp. 781–790, 2013.
View at: Publisher Site | Google Scholar
N. Tadigoppula, V. Korthikunta, S. Gupta et al., “Synthesis and insight into the structure-activity relationships of chalcones as antimalarial agents,” Journal of Medicinal Chemistry, vol. 56, no. 1, pp. 31–45, 2012.
View at: Publisher Site | Google Scholar
Y. R. Kim, J. E. Oh, M. S. Kim et al., “Oncogenic NRF2 mutations in squamous cell carcinomas of oesophagus and skin,” The Journal of Pathology, vol. 220, no. 4, pp. 446–451, 2010.
View at: Publisher Site | Google Scholar
H. Gong, B. K. Zhang, M. Yan et al., “A protective mechanism of licorice (Glycyrrhiza uralensis): isoliquiritigenin stimulates detoxification system via Nrf 2 activation,” Journal of Ethnopharmacology, vol. 162, pp. 134–139, 2015.
View at: Publisher Site | Google Scholar
Y. Lin, Y. Kuang, K. Li et al., “Nrf 2 activators from Glycyrrhiza inflata and their hepatoprotective activities against CCl4-induced liver injury in mice,” Bioorganic & Medicinal Chemistry, vol. 25, no. 20, pp. 5522–5530, 2017.
View at: Publisher Site | Google Scholar
S. Ji, Z. Li, W. Song et al., “Bioactive constituents of Glycyrrhiza uralensis (licorice): discovery of the effective components of a traditional herbal medicine,” Journal of Natural Products, vol. 79, no. 2, pp. 281–292, 2016.
View at: Publisher Site | Google Scholar
J. Cai, Q. Zhang, K. Lin, L. Hu, and Y. Zheng, “The effect of MGCD0103 on CYP450 isoforms activity of rats by cocktail method,” BioMed Research International, vol. 2015, Article ID 517295, 7 pages, 2015.
View at: Publisher Site | Google Scholar
H. R. Lee, J. M. Cho, D. H. Shin et al., “Adaptive response to GSH depletion and resistance to L-buthionine-(S,R)-sulfoximine: involvement of Nrf 2 activation,” Molecular and Cellular Biochemistry, vol. 318, no. 1-2, pp. 23–31, 2008.
View at: Publisher Site | Google Scholar
A. Song, for the Alzheimer’s Disease Neuroimaging Initiative, J. Yan et al., “Network-based analysis of genetic variants associated with hippocampal volume in Alzheimer’s disease: a study of ADNI cohorts,” BioData Mining, vol. 9, no. 1, p. 3, 2016.
View at: Publisher Site | Google Scholar
F. Cheng, W. Li, Y. Zhou et al., “admetSAR: a comprehensive source and free tool for assessment of chemical ADMET properties,” Journal of Chemical Information and Modeling, vol. 52, no. 11, pp. 3099–3105, 2012.
View at: Publisher Site | Google Scholar
G. D. Bader and C. W. V. Hogue, “An automated method for finding molecular complexes in large protein interaction networks,” BMC Bioinformatics, vol. 4, no. 1, p. 2, 2003.
View at: Publisher Site | Google Scholar
D. M. Skillrud and W. J. Martin 2nd, “Paraquat-induced injury of type II alveolar cells. An in vitro model of oxidant injury,” American Review of Respiratory Disease, vol. 129, no. 6, pp. 995–999, 1984.
View at: Publisher Site | Google Scholar
B. Zhang, C. Xie, J. Zhong, H. Chen, H. Zhang, and X. Wang, “A549 cell proliferation inhibited by RNAi mediated silencing of the Nrf 2 gene,” Bio-medical Materials and Engineering, vol. 24, no. 6, pp. 3905–3916, 2014.
View at: Publisher Site | Google Scholar
H. Zali and M. Rezaei Tavirani, “Meningioma protein-protein interaction network,” Archives of Iranian Medicine, vol. 17, no. 4, pp. 262–272, 2014.
View at: Google Scholar
S. Shaikh, H. Aaqil, S. M. D. Rizvi et al., “Comparative inhibition study of compounds identified in the methanolic extract of Apamarga Kshara against trichomonas vaginalis carbamate kinase (TvCK): an enzoinformatics approach,” Interdisciplinary Sciences, vol. 8, no. 4, pp. 357–365, 2016.
View at: Publisher Site | Google Scholar
V. H. Teixeira, V. Ribeiro, and P. J. Martel, “Analysis of binding modes of ligands to multiple conformations of CYP3A4,” Biochimica et Biophysica Acta, vol. 1804, no. 10, pp. 2036–2045, 2010.
View at: Publisher Site | Google Scholar
M. C. Zimmermann, S. L. Tilghman, S. M. Boue et al., “Glyceollin I, a novel antiestrogenic phytoalexin isolated from activated soy,” The Journal of Pharmacology and Experimental Therapeutics, vol. 332, no. 1, pp. 35–45, 2010.
View at: Publisher Site | Google Scholar
S. NiPQad, B. Hashemi, Z. M. Hassan, and H. Mozdarani, “The cell survival of F10B16 melanoma and 4T1 breast adenocarcinoma irradiated to gamma radiation using the MTT assay based on two different calculation methods,” Journal of Biomedical Physics & Engineering, vol. 3, no. 2, pp. 29–36, 2013.
View at: Google Scholar
H. Xie, J. Sun, Y. Chen, M. Zong, S. Li, and Y. Wang, “EGCG attenuates uric acid-induced inflammatory and oxidative stress responses by medicating the NOTCH pathway,” Oxidative Medicine and Cellular Longevity, vol. 2015, Article ID 214836, 10 pages, 2015.
View at: Publisher Site | Google Scholar
M. Y. Xu and Y. S. Kim, “Antitumor activity of glycyrol via induction of cell cycle arrest, apoptosis and defective autophagy,” Food and Chemical Toxicology, vol. 74, pp. 311–319, 2014.
View at: Publisher Site | Google Scholar
T. J. Broekelmann, A. H. Limper, T. V. Colby, and J. A. McDonald, “Transforming growth factor beta 1 is present at sites of extracellular matrix gene expression in human pulmonary fibrosis,” Proceedings of the National Academy of Sciences, vol. 88, no. 15, pp. 6642–6646, 1991.
View at: Publisher Site | Google Scholar
X. J. Huang, Y. K. Choi, H. S. Im, O. Yarimaga, E. Yoon, and H. S. Kim, “Aspartate aminotransferase (AST/GOT) and alanine aminotransferase (ALT/GPT) detection techniques,” Sensors, vol. 6, no. 7, pp. 756–782, 2006.
View at: Publisher Site | Google Scholar
P. Mitsopoulos and Z. E. Suntres, “Cytotoxicity and gene array analysis of alveolar epithelial A549 cells exposed to paraquat,” Chemico-Biological Interactions, vol. 188, no. 3, pp. 427–436, 2010.
View at: Publisher Site | Google Scholar
M. Caruso, A. Alamo, E. Crisafulli, C. Raciti, A. Fisichella, and R. Polosa, “Adenosine signaling pathways as potential therapeutic targets in respiratory disease,” Expert Opinion on Therapeutic Targets, vol. 17, no. 7, pp. 761–772, 2013.
View at: Publisher Site | Google Scholar
J. Ru, P. Li, J. Wang et al., “TCMSP: a database of systems pharmacology for drug discovery from herbal medicines,” Journal of Cheminformatics, vol. 6, no. 1, p. 13, 2014.
View at: Publisher Site | Google Scholar
L. Han, Y. Yuan, L. Zhao et al., “Tracking antiangiogenic components from Glycyrrhiza uralensis Fisch. based on zebrafish assays using high-speed countercurrent chromatography,” Journal of Separation Science, vol. 35, no. 9, pp. 1167–1172, 2012.
View at: Publisher Site | Google Scholar
L. Quesada, C. Areche, L. Astudillo, M. Gutierrez, B. Sepúlveda, and A. San-Martín, “Biological activity of isoflavonoids from Azorella madreporica,” Natural Product Communications, vol. 7, no. 9, pp. 1187-1188, 2012.
View at: Google Scholar
T. Fukai, A. Marumo, K. Kaitou, T. Kanda, S. Terada, and T. Nomura, “Anti-Helicobacter pylori flavonoids from licorice extract,” Life Sciences, vol. 71, no. 12, pp. 1449–1463, 2002.
View at: Publisher Site | Google Scholar
L. He, L. Gao, Z. Shi et al., “Involvement of cytochrome P 450 1A1 and glutathione S-transferase P 1 polymorphisms and promoter hypermethylation in the progression of anti-tuberculosis drug-induced liver injury: a case-control study,” PLoS One, vol. 10, no. 3, article e0119481, 2015.
View at: Publisher Site | Google Scholar
M. A. Spiteri, A. Bianco, R. C. Strange, and A. A. Fryer, “Polymorphisms at the glutathione S-transferase, GSTP1 locus: a novel mechanism for susceptibility and development of atopic airway inflammation,” Allergy, vol. 55, no. s61, pp. 15–20, 2000.
View at: Publisher Site | Google Scholar
B. Zhang, X. Q. Wang, H. Y. Chen, and B. H. Liu, “Involvement of the Nrf 2 pathway in the regulation of pterostilbene-induced apoptosis in HeLa cells via ER stress,” Journal of Pharmacological Sciences, vol. 126, no. 3, pp. 216–229, 2014.
View at: Publisher Site | Google Scholar
B. Zhang, N. Chen, H. Chen, Z. Wang, and Q. Zheng, “The critical role of redox homeostasis in shikonin-induced HL-60 cell differentiation via unique modulation of the Nrf 2/ARE pathway,” Oxidative Medicine and Cellular Longevity, vol. 2012, Article ID 781516, 12 pages, 2012.
View at: Publisher Site | Google Scholar
A. Enomoto, K. Itoh, E. Nagayoshi et al., “High sensitivity of Nrf 2 knockout mice to acetaminophen hepatotoxicity associated with decreased expression of ARE-regulated drug metabolizing enzymes and antioxidant genes,” Toxicological Sciences, vol. 59, no. 1, pp. 169–177, 2001.
View at: Publisher Site | Google Scholar

Copyright

Copyright © 2019 Zi-Jing Liu et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

PDF Download Citation

Download other formats

Order printed copies

Views

1404

Downloads

1558

Citations