六价铬致肝脏损伤作用机制的生物信息学分析

doi:10.13481/j.1671-587X.20230221

Abstract

Abstract:

Objective To identify the genes related to liver injury induced by hexavalent chromium ［Cr（Ⅵ）］ through the bioinformatics method， and to provide the new direction for further research on the mechanism of liver injury induced by Cr（Ⅵ）. Methods The data sets related to “［Cr （Ⅵ）］ liver” in the Gene Expression Omnibus （GEO） Database were searched， the data set GSE65198 was downloaded； the differentially expressed genes （DEGs） were screened through limma algorithm； Gene Ontology （GO） enrichment analysis and Kyoto Encyclopedia of Genes and Genomes （KEGG） pathway enrichment analysis were performed； STRING Database was used to analyze the protein-protein interaction （PPI） network； Cytohubba plug-in was used to screen the hub genes； the targeted drug molecules were predicted by Drug Characterization Database in Enrichr website. Results Twenty samples from the GSE65198 data set were selected and divided into two groups. In the first group， there were five liver samples 1 d after single exposure to 20 mg·kg^－1 Cr （Ⅵ） and five control samples； in the second group， there were five liver samples 7 d after single exposure to 20 mg.kg^－1 Cr （Ⅵ） and five control samples；the control samples in each group were regarded as the negative control，and 342 and 61 DEGs were screened （|log₂ FC|>1 and P<0.05）. The GO enrichment analysis results showed that the DEGs were mainly enriched in the biological processes such as the drug response， mitosis， senescence and so on； the KEGG analysis results showed that the main signaling pathways included the ribosome biogenesis， cell cycle regulation，and p53 signaling pathway and so on. The hub gene analysis results in the PPI network showed that the EBNA1 binding protein 2 （EBNA1BP2）， nucleolar protein 58 （NOP58）， guanine nucleotide binding protein like 3 （GNL3）， nucleolar protein 56 （NOP56）， and WD repeat domain 12 （WDR12） in 1 d group after single exposure and cyclin B2 （CCNB2）（the identifier in PPI network was ENSRNOP00000017117）， cyclin A2 （CCNA2） cyclin B1 （CCNB1）， cyclin dependent kinase 1 （CDK1）， and kinesin family member 20B （KIF20B） in 7 d group after single exposure were screened as the hub genes. The targeted drug prediction results showed that roscovetine and other drugs were identified as the targeted drugs for liver injury by induced Cr（Ⅵ）. Conclusion The mechanism of liver injury induced by Cr（Ⅵ） may be related to cell cycle regulation-related genes， and roscovitine may be the potential clinical treatment drug.

Key words: Hexavalent chromium, Liver, Bioinformatics, Differentially expressed genes, Injury

CLC Number:

R114

Rui WANG,Ding ZHANG,Ruijian ZHUGE,Qian XUE,Li GUO. Bioinformatics analysis on mechanism of liver injury induced by hexavalent chromium[J].Journal of Jilin University(Medicine Edition), 2023, 49(2): 452-459.

Figures/Tables 3

Fig. 1

Fig. 2

Tab.1

References 35

1	SUN H， BROCATO J， COSTA M. Oral chromium exposure and toxicity［J］. Curr Environ Health Rep， 2015， 2（3）： 295-303.
2	仪民，仪慧兰，吴丽华. 铬在小鼠体内的蓄积效应与毒性［J］. 生态毒理学报， 2017， 12（6）： 259-265.
3	BALAKRISHNAN R， KUMAR C S V S， RANI M U， et al. An evaluation of the protective role of α-tocopherol on free radical induced hepatotoxicity and nephrotoxicity due to chromium in rats［J］. Indian J Pharmacol， 2013， 45（5）： 490-495.
4	边寰锋. Vit-C对Cr（Ⅵ）诱导大鼠肝毒性的保护作用及其可能机制的研究［D］. 长沙：中南大学， 2007.
5	ZHITKOVICH A. Importance of chromium-DNA adducts in mutagenicity and toxicity of chromium（Ⅵ）［J］. Chem Res Toxicol， 2005， 18（1）： 3-11.
6	NICKENS K P， PATIERNO S R， CERYAK S. Chromium genotoxicity： a double-edged sword［J］. Chem Biol Interact， 2010， 188（2）： 276-288.
7	O’BRIEN T J， CERYAK S， PATIERNO S R. Complexities of chromium carcinogenesis： role of cellular response， repair and recovery mechanisms［J］. Mutat Res， 2003， 533（1/2）： 3-36.
8	LIANG Q， ZHANG Y J， ZENG M， et al. The role of IP3R-SOCCs in Cr（Ⅵ）-induced cytosolic Ca²⁺ overload and apoptosis in L-02 hepatocytes［J］. Toxicol Res （Camb）， 2018， 7（3）： 521-528.
9	XIAO F， FENG X T， ZENG M， et al. Hexavalent chromium induces energy metabolism disturbance and p53-dependent cell cycle arrest via reactive oxygen species in L-02 hepatocytes［J］. Mol Cell Biochem， 2012， 371（1/2）： 65-76.
10	JIN Y X， ZHANG S B， TAO R H， et al. Oral exposure of mice to cadmium （Ⅱ）， chromium （Ⅵ） and their mixture induce oxidative- and endoplasmic reticulum-stress mediated apoptosis in the livers［J］. Environ Toxicol， 2016， 31（6）： 693-705.
11	BARRETT T， WILHITE S E， LEDOUX P， et al. NCBI GEO： archive for functional genomics data sets： update［J］. Nucleic Acids Res， 2013， 41（Database issue）： D991-D995.
12	YI M， HORTON J D， COHEN J C， et al. WholePathwayScope： a comprehensive pathway-based analysis tool for high-throughput data［J］. BMC Bioinformatics， 2006， 7： 30.
13	MADEJCZYK M S， BAER C E， DENNIS W E， et al. Temporal changes in rat liver gene expression after acute cadmium and chromium exposure［J］. PLoS One， 2015， 10（5）： e0127327.
14	SZKLARCZYK D， GABLE A L， NASTOU K C，et al. The STRING database in 2021： customizable protein-protein networks， and functional characterization of user-uploaded gene/measurement sets［J］. Nucleic Acids Res， 2021， 49（D1）： D605-D612.
15	XIE Z R， BAILEY A， KULESHOV M V， et al. Gene set knowledge discovery with enrichr［J］. Curr Protoc， 2021， 1（3）： e90.
16	管冬元，方肇勤，梁超，等. EBNA1BP2基因在肝癌形成过程中的表达及不同中医治法的调控作用［J］. 中西医结合肝病杂志， 2013， 23（1）： 33-35， 70.
17	曲杰，林萍萍，吕喜英，等. NOP56在乳腺癌组织中的表达情况及对临床预后的意义［J］. 生物信息学， 2019， 17（2）： 122-130.
18	ZHANG Y， LIN Z K， LIN X F， et al. A gene module identification algorithm and its applications to identify gene modules and key genes of hepatocellular carcinoma［J］. Sci Rep， 2021， 11（1）： 5517.
19	HE J Y， YU J. Long noncoding RNA FAM83A-AS1 facilitates hepatocellular carcinoma progression by binding with NOP58 to enhance the mRNA stability of FAM83A［J］. Biosci Rep，2019，39（11）： BSR20192550.
20	ZHANG S Y， ZHAO H R， CHEN Y， et al. GNL3 regulates SIRT1 transcription and promotes hepatocellular carcinoma stem cell-like features and metastasis［J］. J Oncol， 2022， 2022： 1555670.
21	MI L J， QI Q H， RAN H W， et al. Suppression of ribosome biogenesis by targeting WD repeat domain 12 （WDR12） inhibits glioma stem-like cell growth［J］. Front Oncol， 2021， 11： 751792.
22	DING K， LI W Q， ZOU Z Q， et al. CCNB1 is a prognostic biomarker for ER+ breast cancer［J］. Med Hypotheses， 2014， 83（3）： 359-364.
23	ZHUANG L P， YANG Z G， MENG Z Q. Upregulation of BUB1B， CCNB1， CDC7， CDC20， and MCM3 in tumor tissues predicted worse overall survival and disease-free survival in hepatocellular carcinoma patients［J］. Biomed Res Int， 2018， 2018： 7897346.
24	XIAO Y N， MA J M， GUO C L， et al. Cyclin B2 overexpression promotes tumour growth by regulating jagged 1 in hepatocellular carcinoma［J］. Aging， 2022， 14（6）： 2855-2867.
25	BAUMANN K. Cyclin’ on mRNA［J］. Nat Rev Mol Cell Biol， 2016， 17（11）： 677.
26	ASGHAR U， WITKIEWICZ A K， TURNER N C，et al. The history and future of targeting cyclin-dependent kinases in cancer therapy［J］. Nat Rev Drug Discov， 2015， 14（2）： 130-146.
27	IZAWA D， PINES J. The mitotic checkpoint complex binds a second CDC20 to inhibit active APC/C［J］. Nature， 2015， 517（7536）： 631-634.
28	KAPANIDOU M， CURTIS N L， BOLANOS-GARCIA V M. Cdc20： at the crossroads between chromosome segregation and mitotic exit［J］. Trends Biochem Sci， 2017， 42（3）： 193-205.
29	LI J， GAO J Z， DU J L， et al. Increased CDC20 expression is associated with development and progression of hepatocellular carcinoma［J］. Int J Oncol， 2014， 45（4）： 1547-1555.
30	FAN C， CHEN L， HUANG Q L， et al. Overexpression of major CDKN3 transcripts is associated with poor survival in lung adenocarcinoma［J］. Br J Cancer， 2015， 113（12）： 1735-1743.
31	DAI W， MIAO H L， FANG S， et al. CDKN3 expression is negatively associated with pathological tumor stage and CDKN3 inhibition promotes cell survival in hepatocellular carcinoma［J］. Mol Med Rep， 2016， 14（2）： 1509-1514.
32	LIU X R， GONG H， HUANG K. Oncogenic role of kinesin proteins and targeting kinesin therapy［J］. Cancer Sci， 2013， 104（6）： 651-656.
33	LIU X R， LI Y K， ZHANG X， et al. Inhibition of kinesin family member 20B sensitizes hepatocellular carcinoma cell to microtubule-targeting agents by blocking cytokinesis［J］. Cancer Sci， 2018， 109（11）： 3450-3460.
34	XIONG Y Y， JU L G， YUAN L S， et al. KNSTRN promotes tumorigenesis and gemcitabine resistance by activating AKT in bladder cancer［J］. Oncogene， 2021， 40（9）： 1595-1608.
35	LIU Y J， LI J C， LIAO L P， et al. Cyclin-dependent kinase inhibitor roscovitine attenuates liver inflammation and fibrosis by influencing initiating steps of liver injury［J］. Clin Sci （Lond）， 2021， 135（7）： 925-941.

Term	Adjusted P	Odds ratio	Combined score	Gene
LUCANTHONE CTD 00006227	1.05E-08	112.03	2 744.782 18	CCNA2， CDC20， CCNB2，CCNB1， CDK1， KIF20B， CDKN3
1h-pyrazolo（3,4-d）pyrimidine CTD 00000742	6.48E-08	222.44	4 891.445 8	CCNA2， CCNB2，CCNB1，CDK1， CDKN3
2H-1-Benzopyran-2-one, 7-[(3,7- dimethyl-2,6-octadienyl)oxy]- CTD 00003446	1.74E-07	443.71	9 140.298 87	CCNA2， CCNB2， CDK1，KIF20B
CUPRIC OXIDE CTD 00001471	1.91E-07	59.24	1 197.601 47	CCNA2， CDC20， CCNB2， CCNB1，CDK1，KIF20B，KNSTRN
Testosterone CTD 00006844	7.25E-07	34.08	635.816 321	CCNA2， CDC20， CCNB2， NOP58，CCNB1， CDK1， KIF20B， KNSTRN， CDKN3
0173570-0000 PC3 DOWN	9.43E-07	227.33	4 126.964 19	CCNA2， CDC20， CCNB2，CCNB1
Hydrogen peroxide CTD 00006118	9.43E-07	35.80	646.444 475	NOP56，CCNA2，CDC20，CCNB2， NOP58，EBNA1BP2， CCNB1， CDK1，WDR12，KIF20B， GNL3
Dmnq CTD 00002569	1.97E-06	81.56	1 402.062 8	CCNA2，CDC20， CCNB2，KIF20B， CDKN3
Troglitazone CTD 00002415	2.56E-06	35.04	586.243 62	CCNA2，CDC20，CCNB2，CCNB1， CDK1，KIF20B， CDKN3
Roscovitine TTD 00010683	2.56E-06	599.31	9 954.810 48	CCNA2， CCNB1， CDK1
E:indicated cardinality of ten to power.

[1]	Qiaoling YANG,Lu FU,Yu SHI,Yanjue YE,Rifeng LU,Yong LIU,Li YIN. Inhibitory effect of rosiglitazone on ferroptosis of renal tubular epithelial cells in mice with acute renal injury induced by lipopolysaccharide and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2023, 49(2): 351-359.
[2]	Gaofeng ZHOU,Jing XIAO,Jia ZHOU,Junxiu LIU,Guangfu LYU,Yuchen WANG,He LIN,Xiaowei HUANG. Protective effect of Velvet antler polypeptide pretreatment on myocardial H9c2 cell injury induced by TBHP through regulating TGF-β/Smad signaling pathway with miR-133a [J]. Journal of Jilin University(Medicine Edition), 2023, 49(2): 369-376.
[3]	Xiaoyan WANG,Yihong HU,Yucheng HAN,Xianqiong ZOU. Bioinformatics analysis on mechanism of COMMD7 in occurrence and development of brain low-grade glioma [J]. Journal of Jilin University(Medicine Edition), 2023, 49(2): 414-424.
[4]	Zhiyuan XIAO,Bing SONG,Xinyu MA,Lianhui JIN,Tong ZHENG,Fang CHAI. Bioinformatics analysis on expression of apoptosis related gene CD44 in thyroid carcinoma tissue and its relationship with tumor invasion and immune cell infiltration [J]. Journal of Jilin University(Medicine Edition), 2023, 49(2): 473-481.
[5]	Shuai SHAO,Meili LU,Hongxin WANG,Xiuqiu GAO. Protective effect of astragaloside Ⅳ on oxidative injury of MC3T3-E1 cells induced by liposolysaccharide and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2023, 49(1): 1-7.
[6]	Wuyue TANG,Shuojie LI,Lijuan PANG. Bioinformatics analysis of splicing factor-alternative splicing regulatory network based on alternative splicing data in lung adenocarcinoma tissue [J]. Journal of Jilin University(Medicine Edition), 2023, 49(1): 139-149.
[7]	Lincui DA,Beihong ZHENG,Yan SUN,Suzhu CHEN,Yunhong LIN,Qingfen CHEN,Shengrong DU. Method to establish rat model of intrauterine adhesion through chemical and heat conduction dual injury and its evaluation [J]. Journal of Jilin University(Medicine Edition), 2023, 49(1): 215-221.
[8]	Jun ZHU,Nan ZHOU,Deming LI. Improvement effect of propofol postconditioning on focal cerebral ischemia-reperfusion injury in rats and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2023, 49(1): 46-54.
[9]	Nannan HU,Fuxu YANG,Yeteng MU,Chong GUO,Han XUE,Yuxin FAN,Fenglin GUO,Xingang GUAN. Preparation of oxaliplatin-loaded elastin-like polypeptides hydrogel and its killing effect on colon cancer CT26 cells [J]. Journal of Jilin University(Medicine Edition), 2023, 49(1): 94-100.
[10]	Yue WANG,Meili LU,Hongxin WANG. Protective effect of astragaloside Ⅳ on hypoxia-induced vascular injury and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2022, 48(5): 1101-1108.
[11]	Mingliu GU,Fengyuan LIN,Xuefeng WU,Jianing ZHOU,Xuechun LU,Peige DU,Liping AN. Improvement effect of Phellinus igniarius acidic polysaccharide on liver fibrosis induced by bile duct ligation in mice and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2022, 48(5): 1167-1174.
[12]	Hang YANG,Jiaqi CHEN,Shouhan WANG,Hongjun YANG,Bin WANG. Protective effect of ginsenoside Rg1 on cardiac injury in rats with severe acute pancreatitis and its mechanism [J]. Journal of Jilin University(Medicine Edition), 2022, 48(5): 1175-1181.
[13]	Xin LI,Xu DING,Xiaomeng LIU,Xinchan LIU,Zhou WU,Weixian YU. Effect of silencing information regulator 1 on kidney injury in chronic periodontitis model rats [J]. Journal of Jilin University(Medicine Edition), 2022, 48(5): 1200-1208.
[14]	Yuan LIAO,Kaiju WANG,Haoyan LI,Huiping CHEN,Xuanyi LI,Yong HUANG. Improvement effects of neuropeptide PACAP27 on cyclophosphamide-induced testicular injury in rats by inhibiting mitochondria-dependent apoptosis pathway [J]. Journal of Jilin University(Medicine Edition), 2022, 48(5): 1266-1275.
[15]	Xiaoyan WANG,Qiuyue ZHANG,Yujie HU,Zhijing MO. Bioinformatics analysis based on molecular characteristics and mechanism of cystic fibrosis [J]. Journal of Jilin University(Medicine Edition), 2022, 48(5): 1290-1297.

Bioinformatics analysis on mechanism of liver injury induced by hexavalent chromium

RichHTML

PDF (PC)

Like

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 3

References 35

Related Articles 15

Metrics

Comments

Recommended 0