Front. Pharmacol.Frontiers in PharmacologyFront. Pharmacol.1663-9812Frontiers Media S.A.64191710.3389/fphar.2021.641917PharmacologyOriginal ResearchLuteolin Alleviates Methamphetamine-Induced Hepatotoxicity by Suppressing the p53 Pathway-Mediated Apoptosis, Autophagy, and Inflammation in RatsZhang et al.Luteolin Alleviates Methamphetamine-Induced HepatotoxicityZhangKai-Kai1†WangHui2†QuDong1ChenLi-Jian1WangLi-Bin3LiJia-Hao1LiuJia-Li1XuLing-Ling3YoshidaJamie Still4XuJing-Tao56*XieXiao-Li3*LiDong-Ri7*
Department of Forensic Pathology, School of Forensic Medicine, Southern Medical University, Guangzhou, China
Department of Pediatric Surgery, Guangzhou Institute of Pediatrics, Guangzhou Women and Children’s Medical Center, Guangzhou Medical University, Guangzhou, China
Department of Toxicology, School of Public Health, Southern Medical University, Guangzhou, China
Faculty of Health Sciences, Butsuryo College of Osaka, Sakai, Japan
Shanghai Key Laboratory of Forensic Medicine, Institute of Forensic Science, Ministry of Justice, Shanghai, China
Department of Forensic Clinical Medicine, School of Forensic Medicine, Southern Medical University, Guangzhou, China
Department of Forensic Evidence Science, School of Forensic Medicine, Southern Medical University, Guangzhou, China
Edited by:Di Wen, Hebei Medical University, China
Reviewed by:Qian Ren, Hebei Medical University, China
This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
Misuse of the psychostimulant methamphetamine (METH) could induce serious hepatotoxicity. Our previous study revealed the effects of luteolin on alleviating METH-induced hepatotoxicity, however, the detailed mechanisms have not been elucidated. In this study, rats were orally pretreated with 100 mg/kg luteolin or sodium dodecyl sulfate water, and then METH (15 mg/kg, intraperitoneal [i.p.]) or saline was administered. Histopathological and biochemical analyses were used to determine the alleviative effects of luteolin. Based on the RNA-sequencing data, METH induced 1859 differentially expressed genes (DEGs) in comparison with the control group, which were enriched into 11 signaling pathways. Among these DEGs, 497 DEGs could be regulated through luteolin treatment and enriched into 16 pathways. The p53 signaling pathway was enriched in both METH administered and luteolin pretreated rats. Meanwhile, luteolin significantly suppressed METH-induced elevation of p53, caspase9, caspase3, cleaved caspase3, the ratio of Bax/Beclin-2, as well as autophagy-related Beclin-1, Atg5, and LC3-II. Luteolin also relieved METH-induced hepatotoxicity by decreasing inflammation factors, including TNF-α, IL-1β, and IL-18. Moreover, the levels of PI3K, p-Akt, and the normalized ratio of p-Akt/Akt declined after METH administration, whereas luteolin pretreatment failed to reverse these effects. Our results suggest that luteolin alleviates METH-induced hepatic apoptosis, autophagy, and inflammation through repressing the p53 pathway. It further illustrates the protective mechanisms of luteolin on METH-induced hepatotoxicity and provides a research basis for clinical treatment.
Methamphetamine (METH), a highly addictive stimulant, has become a public health problem due to its abuse globally (Centazzo et al., 2019; Xu et al., 2019; Xu and Liu, 2019). METH could cause abnormal behavioral phenotypes and result in neurotoxicity, including mediating oxidative stress, promoting neuroinflammation, stimulating neural apoptosis, and autophagy (Yamamoto and Bankson, 2005; Park et al., 2017; Tan et al., 2020). Increasing evidence shows that METH could also cause multiple organs damage, including the liver (Qu et al., 2020). Complex mechanisms are involved in METH-induced hepatotoxicity, including mediating hepatic metabolic disorders, stimulating oxidative stress, promoting hyperthermia, and inducing mitochondrial impairment (Willson, 2019). Our previous study confirmed that METH-induced hepatic injury was related to the blocking of multiple cellular processes, such as cell division and cycle, which might accelerate hepatic apoptosis (Wang et al., 2017). However, there are limited effective treatments for METH-induced hepatotoxicity.
Luteolin (3,4,5,7-tetrahydroxy flavone), a type of flavonoid, is generally found richly in natural vegetables, fruits, and other plants (Seelinger et al., 2008). Luteolin is extensively utilized to treat multiple diseases in Chinese traditional medicine including tumor, allergy, oxidation, inflammation, apoptosis, and autophagy (Manzoor et al., 2019; Tan et al., 2020). Also, luteolin has been reported to alleviate multiple hepatic injuries. Luteolin protects against galactosamine/lipopolysaccharide-induced hepatic apoptosis, inflammation, and oxidative stress (Lee et al., 2011; Park and Song, 2019). Mercuric chloride-induced hepatotoxicity can also be ameliorated by luteolin through modulating the Nrf2/NF-κB/p53 signaling pathway (Zhang et al., 2017). Our previous study showed that luteolin effectively alleviated METH-induced hepatotoxicity. Multiple pathways could contribute to its protective effects, though the detailed mechanisms haven’t been clarified (Qu et al., 2020).
The p53 signaling pathway has been recognized as a crucial regulator of multiple biological processes, including tumor growth, cell cycle arrest, DNA repair, cell metabolism, necrosis, and proliferation (Aubrey et al., 2018). The p53 signaling pathway is also a regulator of apoptosis and autophagy (Robin et al., 2019). Meanwhile, p53 shows a close association with PI3K/Akt signaling pathway (Grinkevich et al., 2017), and our previous study has confirmed its key role in luteolin’s protective effects on METH-induced neurotoxicity (Tan et al., 2020). This study examined whether this pathway also participates in the hepatic protection by luteolin.
Rats were pretreated with luteolin, followed by the administration of METH. Histopathological and biochemical analyses were performed to determine the hepatic damages. The potential pathways involved in the protective effects of luteolin were enriched and the detailed mechanisms were investigated based on RNA-sequencing. These findings may lead to the development of therapeutic drugs for METH-induced hepatotoxicity.
Materials and MethodsChemicals and Drugs
METH was obtained from the National Institute for the Control of Pharmaceutical and Biological Products (Beijing, China) and the purity was >99%. The purity of luteolin was >96% (Push Bio-Technology Co., Ltd. (Chengdu, China)), whereas 0.5% Sodium dodecyl sulfate (SDS) water was utilized as its solvent.
Animals and Treatments
Sprague Dawley (SD) rats (6–8 weeks old, male, 200 ± 5 g) were purchased from the Experimental Animal Center of Southern Medical University. All rats were allowed to acclimatize in the SPF animal room for 1 week before the experiment (light/dark cycle, 12 h; room temperature, 22 ± 2°C). Food and water were freely available during this period. All experimental steps strictly followed the National Institute of Health Guide for the Care and Use of Laboratory Animals of the Southern Medical University. The number of the Ethical Committee Approval Code was L2018123.
All the rats were randomly assigned to three groups each having six rats: the Control, METH, and luteolin pretreated group (Figure 1) (Qu et al., 2020; Tan et al., 2020). In brief, rats were orally pretreated with luteolin (100 mg/kg) or 0.5% SDS water (once daily) for 3 days. Subsequently, 15 mg/kg METH or an equal volume of saline (i.p.) were intraperitoneally (i.p.) injected at 12 h intervals for four consecutive days. All rats were sacrificed under deep anesthesia (60 mg/kg i. p. pentobarbital sodium)12 h after the final injection (Xu et al., 2018).
Experimental design for METH exposure and luteolin pretreatment.
Blood samples were centrifuged (3,000 r/mins, 10 min s) at room temperature to separate plasma, and then stored at −80°C for biochemical analysis. One-half of the liver tissues were fixed with 10% phosphate-buffered formalin, whereas the other tissues were rapidly frozen in liquid nitrogen and stored at −80°C for further detection.
Histopathology
After fixing for 24 h, liver tissues were embedded in paraffin and sectioned at a 3 μm thickness on a manual rotary microtome. Hematoxylin and eosin (HandE) staining was conducted for further histopathological examination (Xie et al., 2019).
Biochemical Analysis
An Enzyme-linked immunosorbent assay (CUSABIO Biotechnology, Wuhan, China) was performed to examine the degree of liver damage and evaluate the protective effects of luteolin. This was to determine the levels of aspartate transaminase (AST) and alanine aminotransferase (ALT) in plasma.
RNA-Seq Data Processing, Analysis and Result ReportingPrincipal Component Analysis and Correlation Analysis of Samples
Based on our published RNA-seq data (Qu et al., 2020) [BioProject: PRJNA529763], principal component analysis (PCA) was performed to integrate the principal component and simplify the complexity of the sample reads (http://deweylab.biostat.wisc.edu/rsem/) (Giuliani, 2017). The high similarity samples and the outliers were filtered out according to the relationship and the size of variation among samples.
Similarly, Correlation analysis was conducted to determine the variation of repeat samples and evaluate the reliability of experimental treatment.
Identification of Differentially Expressed Genes
Fragments per Kilobases per Million reads (FPKM) method was performed to avoid the influence of length difference and compare the expression level of genes (Li and Dewey, 2011). The DESeq2 tool was utilized to assess the differential genes to accurately screen out DEGs. The screening parameters were set as: the fold change ≥2 or ≤0.5, p-value < 0.05.
Functional Gene Annotations
The Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis (https://www.genome.jp/kegg/) and Protein-Protein Interaction (PPI) tools (https://string-db. org/and Cytoscape_v3.6.1) were conducted for enrichment analysis and protein interactions respectively to analyze the potential function of the DEGs (Kanehisa et al., 2017; Szklarczyk et al., 2017). Annotations of the DEGs referred to the DAVID (http://david.ncifcrf.gov) and the STRING database (http://string.db.org).
Western Blotting Analysis
The isolated total protein was separated using SDS-PAGE gels (20 ug, per sample) and transferred to polyvinylidene difluoride (PVDF, 0.22uM) membranes (Qu et al., 2019; Zhao et al., 2020). The following steps were then conducted on the membranes orderly: Blocked in 5% skim milk for 2 h at room temperature, incubated with the primary antibodies overnight at 4°C and the secondary antibodies for 1 h at room temperature. Finally, the blots were visualized on the ECL System. The following primary antibodies were utilized: Anti-P53 (diluted 1:1,000; 4 A Biotech), anti-caspase9 (diluted 1:1,000, Proteintech), anti-caspase3 (diluted 1:1,000; ABclonal), anti-cleaved caspase3 (diluted 1:1,000; CST), anti-Bax (diluted 1:1,000; CST), anti-Beclin2 (diluted 1:1,000; Proteintech), anti-Beclin1 (diluted 1:1,000; CST), anti-ATG5 (diluted 1:1,000; HuaAn Biotechnology), anti-LC3 (diluted 1:1,000; Proteintech), anti-TNF-α (diluted 1:1,000, Proteintech), anti-IL-1β (diluted 1:1,000, Proteintech), anti-IL-18 (diluted 1:1,000, Proteintech), anti-PI3K p85 alpha(diluted 1:1,000; Proteintech), anti-AKT (diluted 1:1,000; Proteintech), anti-AKT-phospho-S473 (diluted 1:1,000; Proteintech) and anti-Beta-Actin (diluted 1:1,000; 4 A Biotech). The secondary antibodies (HRP-labeled goat anti-mouse IgG (H + L) or anti-rabbit IgG (H + L), Beijing Dingguo Changsheng Biotechnology) were diluted at the concentration of 1:5,000.
Statistical Analysis
All biochemical analysis and Western Blotting experiments were carried out in triplicate. All values were reported as mean ± SEM. The GraphPad Prism version 6.0 (San Diego, United States) was utilized for statistical analysis. One-way analysis of variance (ANOVA) followed by post-hoc Tukey tests, was used for comparisons of multiple groups. PCA analysis was performed on RSEM software (version 1.3.1) with TPM methods and the Pearson correlation analysis was employed to analyze the correlation among samples, while DESeq2 tool (version 1.24.0) was utilized to screen the DEGs. Values of p < 0.05 were considered statistically significant.
Histopathological analysis showed that 15 mg/kg METH significantly damaged the microstructure of hepatic cells by mediating extensively hepatocyte ballooning in the test group compared to the control group (Figures 2A,B). Compared with the METH group, the pathological changes were alleviated by the pretreatment of luteolin (Figure 2C).
Histopathological and biochemical assessment of liver injury. (A–C) Compared to the control group, METH-induced serious hepatocyte ballooning. Luteolin + METH group alleviated liver injury in comparison to the METH group. (D, E) METH significantly enhanced the level of ALT and AST in plasma relative to the control group. The increasing level was attenuated in the Luteolin + METH group.**p < 0.01, compared with control group, ##p < 0.01, compared with METH group (mean ± SEM). Principal correlation analysis and correlation analysis among groups. (F) According to the principal component, intra-group samples were clustered respectively, and then, three groups were separated distinctly. L_M, luteolin + METH. (G) Correlation analysis among samples. The tree presents the correlation among samples, whereas the color displays the coefficient of correlation.
Biochemical indexes, ALT and AST, can mirror the function and the damage degree of the liver. Therefore, these indexes were also examined in this study. METH significantly elevated the plasma level of ALT and AST. These increased indexes were attenuated by the pretreatment of luteolin (Figures 2D,E).
Screening of the Potentially Protective Mechanisms of LuteolinPrincipal Component (PCA) and Correlation Analysis
The PCA analysis can simplify the RNA-seq reads and directly reflect the principal components. The distance of spots represented the similarity of principal components. Samples of the control group (red circles), METH group (green rhombuses), and luteolin pretreated group (blue triangles) were clustered separately (Figure 2F), which meant that the higher the difference between groups the lower variation intra-group. Correlation analysis produced similar results. Intra-group samples were clustered and shown a higher correlation compared to samples from other groups (Figure 2G).
Screening of DEGs
METH significantly up-regulated 873 DEGs and down-regulated 986 DEGs in comparison to the control group (Figure 3A). Luteolin pretreatment also induced 899 DEGs up-regulation and 978 DEGs down-regulation in the test group compared to the METH group (Figure 3B). Among the METH-induced DEGs, 497 DEGs could be regulated through luteolin treatment (314 up-regulated and 183 down-regulated DEGs).
Identification of DEGs using the Scatter plot method. (A) METH treatment induced the DEGs, relative to the control group; (B) compared to the METH group, luteolin pretreatment produced DEGs (the fold change ≥2 or ≤0.5, p-value < 0.05). The red plots represent the up-regulated DEGs, whereas the down-regulated DEGs are represented by green plots.
Functional Annotation of DEGs
The interactions among these DEGs were analyzed through PPI analysis to investigate the underlying mechanisms of METH hepatotoxicity and luteolin’s protective effects. Genes with direct or indirect connections were linked, whereas the unrelated or unrecognized genes were eliminated automatically. The more the connections between proteins, the closer they were to the center of the circle, which suggested the strong relationships among the identified DEGs (Figures 4A,B).
PPI and KEGG analysis of DEGs in the METH and luteolin pretreated group (A, B) PPI analysis revealed the direct and indirect connections among DEGs. Up-regulated DEGs were represented by red, and down-regulated DEGs were remarked with green (C, D)X-axis; the number of the enriched DEGs, Y-axis; the second level term of gene ontology.
The KEGG analysis further provided the clues of the pathways involved. The METH-induced DEGs were mainly enriched into 11 pathways, whereas the DEGs which could be regulated by luteolin were enriched into 16 pathways (Tables 1,2). Interestingly, the p53 signaling pathway, which has been reported to mediate the toxicity of METH, was enriched in both groups. The DEGs from two groups were further annotated according to the classification of metabolism, genetic information processing, environmental information processing, cellular processes, organismal systems, and human diseases (Figures 4C,D).
Pathway enrichment of the METH group.
Pathway enrichment
No
Pathway ID
Pathway
Count
%
p-value
1
rno04151
Metabolic pathways
54
0.070,537,522
0.001,386,404
2
rno00190
Oxidative phosphorylation
12
0.015,675,005
0.002,143,915
3
rno00510
N-Glycan biosynthesis
7
0.009,143,753
0.002,439,666
4
rno05012
Parkinson’s disease
12
0.015,675,005
0.003,272,982
5
rno01130
Biosynthesis of antibiotics
14
0.018,287,506
0.00778,871
6
rno03050
Proteasome
6
0.007,837,502
0.009,337,467
7
rno05010
Alzheimer’s disease
12
0.015,675,005
0.012,312,085
8
rno04152
AMPK signaling pathway
9
0.011,756,254
0.025,718,304
9
rno04540
Gap junction
7
0.009,143,753
0.035,091,577
10
rno04115
p53 signaling pathway
6
0.007,837,502
0.044,351,924
11
rno05206
MicroRNAs in cancer
9
0.011,756,254
0.045,162,063
Pathway enrichment of luteolin pre-treated group.
Pathway enrichment
NO
Pathway ID
Pathway
Count
%
p-value
1
rno01100
Metabolic pathways
62
0.086,741,189
9.24344E-06
2
rno00190
Oxidative phosphorylation
16
0.022,384,823
1.03828E-05
3
rno05012
Parkinson’s disease
16
0.022,384,823
1.99834E-05
4
rno05010
Alzheimer’s disease
16
0.022,384,823
0.00016011
5
rno01130
Biosynthesis of antibiotics
17
0.023,783,875
0.000387,545
6
rno05016
Huntington’s disease
15
0.020,985,772
0.001,562,905
7
rno04932
Non-alcoholic fatty liver disease (NAFLD)
13
0.018,187,669
0.001,843,786
8
rno03320
PPAR signaling pathway
7
0.00979,336
0.02,007,818
9
rno00480
Glutathione metabolism
6
0.008,394,309
0.022,249,139
10
rno00270
Cysteine and methionine metabolism
5
0.006,995,257
0.024,500,584
11
rno00900
Terpenoid backbone biosynthesis
4
0.005,596,206
0.025,077,535
12
rno04152
AMPK signaling pathway
9
0.012,591,463
0.026,348,516
13
rno04540
Gap junction
7
0.00979,336
0.035,775,325
14
rno03050
Proteasome
5
0.006,995,257
0.041,183,838
15
rno04115
p53 signaling pathway
6
0.008,394,309
0.045,094,341
16
rno05206
MicroRNAs in cancer
9
0.012,591,463
0.046,195,794
Pretreatment of Luteolin Alleviates METH-Induced Apoptosis via Repressing p53 Pathway
Results from KEGG analysis show a significant alteration of the p53 pathway in both treatment groups. Therefore, the western blotting analysis was employed to study this pathway. For the test group compared to the control group, METH significantly increased the expression of p53 and its downstream apoptosis-related proteins, including caspase9, caspase3, cleaved caspase3, Bax, and the ratio of Bax/Beclin-2, whereas the up-regulation of these proteins were effectively repressed by luteolin pretreatment (Figures 5A,B).
Western blotting analysis for the expression of p53, caspase9, caspase3, cleaved caspase3, Bax, Beclin-2 (A, B) Compared to the control group, METH significantly increased the expression level of p53, caspase9, caspase3, cleaved caspase3, Bax, and the normalized ratio of Bax/Beclin-2. These alterations were eliminated by luteolin pretreatment. *p < 0.05, **p < 0.01, compared with control group, #p < 0.05, compared with METH group (mean ± SEM).
Pretreatment of Luteolin Restrains METH-Induced Autophagy and Inflammation
The expression of autophagy-related proteins was also observed given the close relation between autophagy and the p53 signaling pathway. The expression levels of Beclin-1, Atg5, and LC3-II were increased following METH treatment. Luteolin restrained the up-regulation of these proteins (Figures 6A,B).
Western blotting analysis for the expression of Beclin-1, Atg5, LC3-II, TNF-α, IL-1β, and IL-18 (A, B) Expression of Beclin-1, Atg5, and LC3-II were elevated after METH treatment in comparison with the control group, but these overexpressions were relieved by luteolin treatment (C, D) Similarly, METH also up-regulated the level of TNF-α, IL-1β, and IL-18, but these effects were diminished by luteolin. *p < 0.05, **p < 0.01, compared with control group, #p < 0.05, compared with METH group (mean ± SEM).
There was a significant elevation of inflammatory factors compared to the control group; TNF-α, IL-1β, and IL-18 after METH treatment. Luteolin pretreatment also significantly alleviated the METH-induced high expression of these proteins (Figures 6C,D).
Preatment With Luteolin Fails to Reverse METH-Induced Repression of PI3K/Akt Pathway
Luteolin alleviates METH-induced neurotoxicity by modulating PI3K/Akt pathway (Tan et al., 2020). Here, this pathway was studied. There was a significant decline of related proteins following METH treatment: PI3K, Akt phosphorylation (p-Akt), and the p-Akt/Akt ratio. Interestingly, these low expression proteins weren’t reversed through luteolin pretreatment (Figures 7A,B).
Western blotting analysis for the expression of PI3K, p-Akt, and Akt (A, B) Relative to the control group, PI3K, p-Akt, and the normalized ratio of p-Akt/Akt were enhanced following METH treatment, while these effects weren’t attenuated by luteolin pretreatment. *p < 0.05, **p < 0.01, compared with control group, no sig, there was no statistical significance, compared with METH group (mean ± SEM).
Discussion
In our previous study, luteolin showed protective effects on METH-induced hepatotoxicity (Qu et al., 2020), though the potential mechanisms were not clear. In this study, we confirmed that luteolin effectively alleviated METH-induced hepatic-pathological changes and decreased biochemical indexes of ALT and AST. The p53 pathway was enriched in both the METH and luteolin pretreated groups via KEGG analysis, based on the RNA-seq data. Downstream, the expression of apoptosis- and autophagy-related proteins were up-regulated following METH treatment, which was attenuated by luteolin pretreatment. Moreover, METH-induced inflammation was also repressed by luteolin. The PI3K/Akt pathway was suppressed after METH treatment, while this effect wasn’t reversed by luteolin. These results suggested that luteolin could protect against METH mediated hepatic toxicity by repressing the p53 pathway.
RNA-sequencing data provided the detailed mechanisms of METH-induced hepatotoxicity and luteolin’s protective effects. According to the KEGG analysis, eight pathways were both enriched into the METH group and luteolin pre-treated group. Among these pathways, metabolic pathways were the most enriched pathways. Conceivably, METH exposure has been reported to induce the serious disfunction of hepatic metabolism (Zhang et al., 2019). As a conserved master regulator of metabolism, the AMPK signaling pathway has been recognized as the potential therapeutic target of hepatic metabolic diseases (Smith et al., 2016; Garcia et al., 2019). In addition, oxidative phosphorylation provides the most ATP for higher animals and the damage of this pathway could induce the energy metabolism disorder (Wilson, 2017), suggesting the potential mechanism of hyperpyrexia after METH treatment (White, 2002). Interestingly, PD- and AD-related pathways were also enriched in liver tissue. This phenomenon strongly hints the pro-neurodegeneration effects of METH (Shin et al., 2017; Keshavarzi et al., 2019). The reverse regulation of these pathways could be involved in the protective effects of luteolin.
Increasing evidence shows that p53 plays a crucial role in METH-induced toxicity. Here, the p53 signaling pathway was also enriched in METH-induced hepatotoxicity. METH has been reported to mediate neural apoptosis by up-regulating p53 (Imam et al., 2001), whereas special deletion effectively alleviated METH-induced neurotoxicity (Hirata and Cadet, 1997; Lu et al., 2017). Meanwhile, Bax (a cell death effector) and the ratio of Bax/Beclin-2 (molecular markers of cell apoptosis) were also up-regulated after METH treatment, although its liberation regulator Beclin-2 wasn’t altered (Ke et al., 2015; Ali et al., 2018). Activated Bax can mediate the apoptosis cascade of aspartate-specific cysteine proteases by increasing caspase9 (Li et al., 1997; Hakem et al., 1998). Consistently, METH-induced increase of Bax also showed the stimulating effects on apoptosis. METH increased the expression of caspase9 and then elevated the level of caspase3 and cleaved caspase3, which played a crucial role in apoptosis (Porter and Jänicke, 1999). Furthermore, the anti-apoptotic bioactivity of luteolin has been confirmed in multiple in vivo/in vitro models (Zhang et al., 2016; Liu and Meng, 2018). In the current study, luteolin pretreatment effectively repressed METH-mediated stimulation of the p53 pathway. These findings showed that luteolin significantly suppressed METH-induced overexpression of p53 and then, reduced the level of Bax, the ratio of Bax/Beclin-2, caspase9, caspase3, and cleaved caspase3, suggesting that the p53 pathway could play a key role in the protective effects of luteolin.
There is a complex interplay between autophagy and apoptosis. The activation of p53 functionally intertwines with the autophagic pathway (Baehrecke, 2005; Maiuri et al., 2007; White, 2016). In this study, the up-regulation of autophagy-related proteins following METH injections (Beclin-1, Atg5, and LC3-II) was investigated. Autophagy-related 5 (Atg5) is well-known for its proautophagic activation and can stimulate cell death, which is associated with the processing of microtubule-associated protein light chain 3 (LC3), a marker of autophagy (Tanida et al., 2008; Zheng et al., 2019). Activation of Beclin-1 initiates autophagosome formation and is required for Atg5-dependent autophagy (Kang et al., 2011). Luteolin pretreatment effectively alleviated the up-regulation of these proteins, suggesting that luteolin could resist METH-induced autophagy in rat liver, despite that the interaction between apoptosis and autophagy has not been fully illuminated.
Also, the increase of inflammatory factors, TNF-α, IL-1β, and IL-18, was observed after METH treatment, suggesting the activation of hepatic inflammation. Apoptosis/autophagy has a close association with inflammation and plays the role of checkpoint (Messer, 2017). Both apoptosis and autophagy can be triggered by inflammation and cause the process of interaction (Elmore, 2007; Levine and Kroemer, 2008). Interestingly, the findings showed that both apoptosis and autophagy were activated after METH treatment, implying that inflammation could be the origin of these consequences. Moreover, luteolin pretreatment restrained METH-induced hepatic inflammation by decreasing the high level of TNF-α, IL-1β, and IL-18, which was consistent with the anti-inflammatory effects of luteolin (Park and Song, 2019).
It has been confirmed that p53 can subdue the stimulation of the PI3K/Akt pathway, which represses mTOR (Moore et al., 2008; Grinkevich et al., 2017). This reduces mTOR’s negative regulation to apoptosis and autophagy (Feng et al., 2018). Here, the findings also showed the deactivation of the PI3K/Akt pathway after METH administration. The decreasing level of PI3K and the lower p-Akt/Akt ratio implies that apoptosis and autophagy could be stimulated by the suppression of the PI3K/Akt pathway, whereas the overexpression of p53 could initiate it. The blocking effect of METH on the PI3K/AKT pathway was also observed in other in vivo/in vitro models, which mediated apoptosis and oxidative stress (Lee et al., 2020; Meng et al., 2020). Interestingly, luteolin pretreatment failed to reverse the deactivation of the PI3K/AKT pathway, indicating that the protection of luteolin on METH-induced hepatotoxicity was independent of PI3K/AKT pathway.
In conclusion, this study showed that the p53 signaling pathway played a key role in METH-induced hepatotoxicity and the protective effects of luteolin. METH stimulates the activation of the p53 pathway, which triggers hepatic apoptosis, autophagy, and inflammation. Notably, these consequences were attenuated by the pretreatment of luteolin by suppressing the p53 pathway (Figure 8). The PI3K/Akt pathway was repressed by METH, though the protection of luteolin on METH-induced hepatotoxicity was independent of PI3K/AKT pathway. This study further investigates the protective mechanisms of luteolin on METH-induced hepatotoxicity, which could serve in the development of treatment drugs.
METH stimulated the activation of p53 pathway in hepatic cell, which subsequently mediated apoptosis, autophagy and inflammation. These toxic effects could be attenuated through luteolin pre-treatment via suppressing p53 pathway.
Data Availability Statement
The datasets presented in this study can be found in online repositories. The names of the repository/repositories and accession number(s) can be found below: https://www.ncbi.nlm.nih.gov/, PRJNA529763.
Ethics Statement
The animal study was reviewed and approved by the National Institutes of Health Guide for the Care and Use of Laboratory Animals of the Southern Medical University.
Author Contributions
J-TX, X-LX, and D-RL contributed to conception and design of the study. K-KZ and HW organized the database. DQ, L-JC, and L-BW performed the statistical analysis. K-KZ and J-LL wrote the first draft of the manuscript. J-HL, L-LX, and JSY wrote sections of the manuscript. All authors contributed to manuscript revision, read, and approved the submitted version.
Funding
This work was supported by the National Natural Science Foundation of China under Grant No. 81971802; Opening Foundation of Shanghai Key Laboratory of Forensic Medicine under Grant No. KF1407, and Natural Science Foundation of Guangdong Province under Grant No. 2018A0303130267.
Conflict of Interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
ReferencesAliD.TripathiA.Al AliH.ShahiY.MishraK. K.AlarifiS. (2018). ROS-dependent Bax/Bcl2 and caspase 3 pathway-mediated apoptosis induced by zineb in human keratinocyte cells. Onco. Targets Ther.11, 489–497. 10.2147/OTT.S140358AubreyB. J.KellyG. L.JanicA.HeroldM. J.StrasserA. (2018). How does p53 induce apoptosis and how does this relate to p53-mediated tumour suppression?. Cell Death Differ.25 (1), 104–113. 10.1038/cdd.2017.169BaehreckeE. H. (2005). Autophagy: dual roles in life and death?. Nat. Rev. Mol. Cell Biol.6 (6), 505–510. 10.1038/nrm1666CentazzoN.FrederickB. M.JacoxA.ChengS. Y.Concheiro-GuisanM. (2019). Wastewater analysis for nicotine, cocaine, amphetamines, opioids and cannabis in New York city. Forensic Sci. Res.4 (2), 152–167. 10.1080/20961790.2019.1609388ElmoreS. (2007). Apoptosis: a review of programmed cell death. Toxicol. Pathol.35 (4), 495–516. 10.1080/01926230701320337FengH.ChengX.KuangJ.ChenL.YuenS.ShiM. (2018). Apatinib-induced protective autophagy and apoptosis through the AKT-mTOR pathway in anaplastic thyroid cancer. Cell Death Dis.9 (10), 1030. 10.1038/s41419-018-1054-3GarciaD.HellbergK.ChaixA.WallaceM.HerzigS.BadurM. G. (2019). Genetic liver-specific AMPK activation protects against diet-induced obesity and NAFLD. Cell Rep.26 (1), 192–e6. 10.1016/j.celrep.2018.12.036GiulianiA. (2017). The application of principal component analysis to drug discovery and biomedical data. Drug Discov. Today22 (7), 1069–1076. 10.1016/j.drudis.2017.01.005GrinkevichV. V.NikulenkovF.ShiY.EngeM.BaoW.MaljukovaA. (2017). Ablation of key oncogenic pathways by RITA-reactivated p53 is required for efficient apoptosis. Cancer Cell31 (5), 724–726. 10.1016/j.ccell.2017.04.014HakemR.HakemA.DuncanG. S.HendersonJ. T.WooM.SoengasM. S. (1998). Differential requirement for caspase 9 in apoptotic pathways in vivo. Cell94 (3), 339–352. 10.1016/s0092-8674(00)81477-4HirataH.CadetJ. L. (1997). p53-knockout mice are protected against the long-term effects of methamphetamine on dopaminergic terminals and cell bodies. J. Neurochem.69 (2), 780–790. 10.1046/j.1471-4159.1997.69020780.xImamS. Z.ItzhakY.CadetJ. L.IslamF.SlikkerW.AliS. F. (2001). Methamphetamine-induced alteration in striatal p53 and bcl-2 expressions in mice. Brain Res. Mol. Brain Res.91 (1-2), 174–178. 10.1016/s0169-328x(01)00139-5KanehisaM.FurumichiM.TanabeM.SatoY.MorishimaK. (2017). KEGG: new perspectives on genomes, pathways, diseases and drugs. Nucleic Acids Res.45 (D1), D353–D361. 10.1093/nar/gkw1092KangR.ZehH. J.LotzeM. T.TangD. (2011). The Beclin 1 network regulates autophagy and apoptosis. Cell Death Differ.18 (4), 571–580. 10.1038/cdd.2010.191KeF.GrabowS.KellyG. L.LinA.O’ReillyL. A.StrasserA. (2015). Impact of the combined loss of BOK, BAX and BAK on the hematopoietic system is slightly more severe than compound loss of BAX and BAK. Cell Death Dis.6 (10), e1938. 10.1038/cddis.2015.304KeshavarziS.KermanshahiS.KaramiL.MotaghinejadM.MotevalianM.SadrS. (2019). Protective role of metformin against methamphetamine induced anxiety, depression, cognition impairment and neurodegeneration in rat: the role of CREB/BDNF and Akt/GSK3 signaling pathways. Neurotoxicology72, 74–84. 10.1016/j.neuro.2019.02.004LeeH. S.KimE. N.JeongG. S. (2020). Lupenone protects neuroblastoma SH-SY5y cells against methamphetamine-induced apoptotic cell death via PI3K/Akt/mTOR signaling pathway. Int. J. Mol. Sci.21 (5), 1617. 10.3390/ijms21051617LeeW. C.JungH. A.ChoiJ. S.KimY. S.LeeS. M. (2011). Protective effects of luteolin against apoptotic liver damage induced by D-galactosamine/lipopolysaccharide in mice. J. Nat. Prod.74 (9), 1916–1921. 10.1021/np2003935LevineB.KroemerG. (2008). Autophagy in the pathogenesis of disease. Cell132 (1), 27–42. 10.1016/j.cell.2007.12.018LiB.DeweyC. N. (2011). RSEM: accurate transcript quantification from RNA-Seq data with or without a reference genome. Bmc. Bioinformatics12, 323. 10.1186/1471-2105-12-323LiP.NijhawanD.BudihardjoI.SrinivasulaS. M.AhmadM.AlnemriE. S. (1997). Cytochrome c and dATP-dependent formation of Apaf-1/caspase-9 complex initiates an apoptotic protease cascade. Cell91 (4), 479–489. 10.1016/s0092-8674(00)80434-1LiuX.MengJ. (2018). Luteolin alleviates LPS-induced bronchopneumonia injury in vitro and in vivo by down-regulating microRNA-132 expression. Biomed. Pharmacother.106, 1641–1649. 10.1016/j.biopha.2018.07.094LuT.KimP. P.GreigN. H.LuoY. (2017). Dopaminergic neuron-specific deletion of p53 gene attenuates methamphetamine neurotoxicity. Neurotox. Res.32 (2), 218–230. 10.1007/s12640-017-9723-zMaiuriM. C.ZalckvarE.KimchiA.KroemerG. (2007). Self-eating and self-killing: crosstalk between autophagy and apoptosis. Nat. Rev. Mol. Cell Biol.8 (9), 741–752. 10.1038/nrm2239ManzoorM. F.AhmadN.AhmedZ.SiddiqueR.ZengX. A.RahamanA. (2019). Novel extraction techniques and pharmaceutical activities of luteolin and its derivatives. J. Food Biochem.43 (9), e12974. 10.1111/jfbc.12974MengX.ZhangC.GuoY.HanY.WangC.ChuH. (2020). TBHQ attenuates neurotoxicity induced by methamphetamine in the VTA through the Nrf2/HO-1 and PI3K/AKT signaling pathways. Oxid. Med. Cell Longev.2020, 8787156. 10.1155/2020/8787156MesserJ. S. (2017). The cellular autophagy/apoptosis checkpoint during inflammation. Cell Mol. Life Sci.74 (7), 1281–1296. 10.1007/s00018-016-2403-yMooreT.BeltranL.CarbajalS.StromS.TraagJ.HurstingS. D. (2008). Dietary energy balance modulates signaling through the Akt/mammalian target of rapamycin pathways in multiple epithelial tissues. Cancer Prev. Res. (Phila).1 (1), 65–76. 10.1158/1940-6207.CAPR-08-0022ParkC. M.SongY. S. (2019). Luteolin and luteolin-7-O-glucoside protect against acute liver injury through regulation of inflammatory mediators and antioxidative enzymes in GalN/LPS-induced hepatitic ICR mice. Nutr. Res. Pract.13 (6), 473–479. 10.4162/nrp.2019.13.6.473ParkJ. H.SeoY. H.JangJ. H.JeongC. H.LeeS.ParkB. (2017). Asiatic acid attenuates methamphetamine-induced neuroinflammation and neurotoxicity through blocking of NF-kB/STAT3/ERK and mitochondria-mediated apoptosis pathway. J. Neuroinflammation14 (1), 240. 10.1186/s12974-017-1009-0PorterA. G.JänickeR. U. (1999). Emerging roles of caspase-3 in apoptosis. Cell Death Differ.6 (2), 99–104. 10.1038/sj.cdd.4400476QuD.TanX. H.ZhangK. K.WangQ.WangH. J. (2019). ATF3 mRNA, but not BTG2, as a possible marker for vital reaction of skin contusion. Forensic Sci Int303, 109937. 10.1016/j.forsciint.2019.109937QuD.ZhangK.ChenL.WangQ.WangH. (2020). RNA-sequencing analysis of the effect of luteolin on methamphetamine-induced hepatotoxicity in rats: a preliminary study. Peerj8, e8529. 10.7717/peerj.8529RobinM.IssaA. R.SantosC. C.NapoletanoF.PetitgasC.ChatelainG. (2019). Drosophila p53 integrates the antagonism between autophagy and apoptosis in response to stress. Autophagy15 (5), 771–784. 10.1080/15548627.2018.1558001SeelingerG.MerfortI.WölfleU.SchemppC. M. (2008). Anti-carcinogenic effects of the flavonoid luteolin. Molecules13 (10), 2628–2651. 10.3390/molecules13102628ShinE. J.DangD. K.TranT. V.TranH. Q.JeongJ. H.NahS. Y. (2017). Current understanding of methamphetamine-associated dopaminergic neurodegeneration and psychotoxic behaviors. Arch. Pharm. Res.40 (4), 403–428. 10.1007/s12272-017-0897-ySmithB. K.MarcinkoK.DesjardinsE. M.LallyJ. S.FordR. J.SteinbergG. R. (2016). Treatment of nonalcoholic fatty liver disease: role of AMPK. Am. J. Physiol. Endocrinol. Metab.311 (4), E730–E740. 10.1152/ajpendo.00225.2016SzklarczykD.MorrisJ. H.CookH.KuhnM.WyderS.SimonovicM. (2017). The STRING database in 2017: quality-controlled protein-protein association networks, made broadly accessible. Nucleic Acids Res.45 (D1), D362–D368. 10.1093/nar/gkw937TanX. H.ZhangK. K.XuJ. T.QuD.ChenL. J.LiJ. H. (2020). Luteolin alleviates methamphetamine-induced neurotoxicity by suppressing PI3K/Akt pathway-modulated apoptosis and autophagy in rats. Food Chem. Toxicol.137, 111179. 10.1016/j.fct.2020.111179TanidaI.UenoT.KominamiE. (2008). LC3 and autophagy. Methods Mol. Biol.445, 77–88. 10.1007/978-1-59745-157-4_4WangQ.WeiL. W.XiaoH. Q.XueY.DuS. H.LiuY. G. (2017). Methamphetamine induces hepatotoxicity via inhibiting cell division, arresting cell cycle and activating apoptosis: in vivo and in vitro studies. Food Chem. Toxicol.105, 61–72. 10.1016/j.fct.2017.03.030WhiteE. (2016). Autophagy and p53. Cold Spring Harb. Perspect Med.6 (4), a026120. 10.1101/cshperspect.a026120WhiteS. R. (2002). Amphetamine toxicity. Semin. Respir. Crit. Care Med.23 (1), 27–36. 10.1055/s-2002-20586WillsonC. (2019). Sympathomimetic amine compounds and hepatotoxicity: not all are alike-Key distinctions noted in a short review. Toxicol. Rep.6, 26–33. 10.1016/j.toxrep.2018.11.013WilsonD. F. (2017). Oxidative phosphorylation: regulation and role in cellular and tissue metabolism. J. Physiol. (Lond).595 (23), 7023–7038. 10.1113/JP273839XieX. L.ZhouW. T.ZhangK. K.YuanY.QiuE. M.ShenY. W. (2019). PCB52 induces hepatotoxicity in male offspring through aggravating loss of clearance capacity and activating the apoptosis: sex-biased effects on rats. Chemosphere227, 389–400. 10.1016/j.chemosphere.2019.04.077XuB.YeY.LiaoL. (2019). Rapid and simple analysis of amphetamine-type illegal drugs using excitation-emission matrix fluorescence coupled with parallel factor analysis. Forensic Sci Res4 (2), 179–187. 10.1080/20961790.2017.1349600XuF.LiuL. (2019). Simultaneous determination of free methamphetamine, pethidine, ketamine and tramadol in urine by dispersive liquid-liquid microextraction combined with GC-MS. Forensic Sci. Res.4 (2), 188–194. 10.1080/20961790.2017.1377386XuJ.ZhaoR.XueY.XiaoH.ShengY.ZhaoD. (2018). RNA-seq profiling reveals differentially expressed genes as potential markers for vital reaction in skin contusion: a pilot study. Forensic Sci. Res.3 (2), 153–160. 10.1080/20961790.2017.1349639YamamotoB. K.BanksonM. G. (2005). Amphetamine neurotoxicity: cause and consequence of oxidative stress. Crit. Rev. Neurobiol.17 (2), 87–117. 10.1615/critrevneurobiol.v17.i2.30ZhangB. C.ZhangC. W.WangC.PanD. F.XuT. D.LiD. Y. (2016). Luteolin attenuates foam cell formation and apoptosis in ox-LDL-stimulated macrophages by enhancing autophagy. Cell Physiol. Biochem.39 (5), 2065–2076. 10.1159/000447902ZhangH.TanX.YangD.LuJ.LiuB.BaiyunR. (2017). Dietary luteolin attenuates chronic liver injury induced by mercuric chloride via the Nrf2/NF-κB/P53 signaling pathway in rats. Oncotarget8 (25), 40982–40993. 10.18632/oncotarget.17334ZhangY.LiL.WangQ.ShenM.HanW.YangX. (2019). Simultaneous determination of metabolic and elemental markers in methamphetamine-induced hepatic injury to rats using LC-MS/MS and ICP-MS. Anal Bioanal. Chem.411 (15), 3361–3372. 10.1007/s00216-019-01810-5ZhaoD.WangQ.ZhouW. T.WangL. B.YuH.ZhangK. K. (2020). PCB52 exposure alters the neurotransmission ligand-receptors in male offspring and contributes to sex-specific neurodevelopmental toxicity. Environ. Pollut.264, 114715. 10.1016/j.envpol.2020.114715ZhengW.XieW.YinD.LuoR.LiuM.GuoF. (2019). ATG5 and ATG7 induced autophagy interplays with UPR via PERK signaling. Cell Commun. Signal.17 (1), 42. 10.1186/s12964-019-0353-3